Marine Protozoa from Woods Hole eBook

Marine Protozoa from Woods Hole

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Table of Contents

Table of Contents
Section Page

Start of eBook1
Author:  Gary N. Galkins1
Genus TRICHOSPHAERIUM Schneider ’784
KEY TO ORDERS OF FLAGELLIDIA.7
KEY TO THE FAMILIES OF MONADIDA.8
KEY TO MARINE GENERA OF MONADIDA.*8
KEY TO MARINE QENERA OF CHOANOFLAGELLIDA.8
KEY TO MARINE GENERA OF POLYMASTIGIDA.9
Genus MONAS (Ehr.) Stein ’7810
Genus ANISONEMA Buetschli13
KEY TO FAMILIES OF DINOFLAGELLIDIA.14
KEY TO MARINE GENERA OF PERIDINIDAE.14
KEY TO MARINE GENERA OF DINOPHYSIDAE.15
KEY TO INFUSORIA.19
KEY TO FAMILIES OF THE HOLOTRICHIDA.19
KEY TO MARINE GENERA OF ENCHELINIDAE20
KEY TO MARINE GENERA OF TRACHELINIDAE.24
KEY TO MARINE GENERA OF CHLAMYDODONTIDAE.27
Genus NASSULA Ehr. ’3327
KEY TO MARINE GENERA OF CHILIFERIDAE.30
Genus COLPIDIUM Stein ’6031
KEY TO MARINE GENERA OF PLEURONEMIDAE.33
KEY TO MARINE GENERA OF OPALINIDAE.37
KEY TO FAMILIES OF HETEROTRICHIDA.38
KEY TO THE MARINE GENERA OF PLAGIOTOMIDAE.38
KEY TO THE MARINE GENERA OF BURSARIDAE.39
39
KEY TO THE MARINE GENERA OF STENTORIDAE.40
KEY TO THE MARINE GENERA OF TINTINNIDAE.42
KEY TO FAMILIES OF HYPOTRICHIDA.43
KEY TO THE MARINE GENERA OF OXYTRICHIDAE.43
KEY TO THE MARINE GENERA OF EUPLOTIDAE.46
KEY TO FAMILIES OF PERITRICHIDA.50
KEY TO THE MARINE GENERA OF VORTICELLIDAE.52
Genus VORTICELLA (Linnaeus 1767) Ehr. ’3852
KEY TO FAMILIES OF SUCTORIA.55
LIST OF REFERENCES.58

Page 1

Author:  Gary N. Galkins

Release Date:  May 5, 2006 [eBook #18320]

Language:  English

Character set encoding:  ISO-646-us (us-ASCII)

***Start of the project gutenberg EBOOK marine protozoa from Woods Hole***

E-text prepared by Ronald Calvin Huber, while serving as Penobscot Bay
Watch, Rockland, Maine, and Joseph E. Loewenstein, M.D.

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Contributions from the Biological Laboratory of the U. S. Fish
Commission, Woods Hole, Massachusetts.

Marine protozoa from Woods Hole.

by

Gary N. Galkins,
Department of Zoology, Columbia University.

Bulletin of the United States Fish Commission 21:415-468, 1901

Comparatively little has been done in this country upon marine Protozoa.  A few observations have been made by Kellicott, Stokes, and Peck, but these have not been at all complete.  With the exception of Miss Stevens’s excellent description of species of Lichnophora I am aware of no single papers on individual forms.  Peck (’93 and ’95) clearly stated the economic position of marine Protozoa as sources of food, and I need not add to his arguments.  It is of interest to know the actual species of various groups in any locality and to compare them with European forms.  The present contribution is only the beginning of a series upon the marine Protozoa at Woods Hole, and the species here enumerated are those which were found with the algae along the edge of the floating wharf in front of the Fish Commission building and within a space of about 20 feet.  Many of them were observed in the water and algae taken fresh from the sea; others were found only after the water had been allowed to stand for a few days in the laboratory.  The tow-net was not used, the free surface Protozoa were not studied, nor was the dredge called into play.  Both of these means of collecting promise excellent results, and at some future time I hope to take advantage of them.

My observations cover a period of two months, from the 1st of July to the 1st of September.  During that time I was able to study and describe 72 species representing 55 genera, all from the limited space mentioned above.  In addition to these there are a few genera and species upon which I have insufficient notes, and these I shall reserve until opportunity comes to study them further.

I take this opportunity to express my thanks to Dr. Hugh M. Smith for many favors shown me while at Woods Hole.

Page 2

In dealing with these marine forms from the systematic standpoint, two courses are open to the investigator.  He may make numerous new species based upon minor differences in structure, or he may extend previous descriptions until they are elastic enough to cover the variations.  The great majority of marine protozoa have been described from European waters, and the descriptions are usually not elastic enough to embrace the forms found at Woods Hole.  I have chosen, however, to hold to the conservative plan of systematic work, and to make as few new species as possible, extending the older descriptions to include the new forms.

The different classes of Protozoa, and orders within the classes, are distributed more or less in zones.  Thus the Infusoria, including the Ciliata and the Suctoria, are usually littoral in their habitat, living upon the shore-dwelling, or attached, water plants and upon the animals frequenting them.  It is to be expected, therefore, that in forms here considered there should be a preponderance of Infusoria.  Flagellated forms are also found in similar localities, but on the Surface of the sea as well; hence the number described in these pages is probably only a small proportion of the total number of Mastigophora in this region.  The Sarcodina, including the Foraminifera and the Radiolaria, are typically deep-sea forms and would not be represented by many types in the restricted locality examined at Woods Hole.  Two species, Gromia lagenoides and Truncatulina lobatula, alone represent the great order of Foraminifera, while the still larger group of Radiolaria is not represented at all.

The Protozoa described are distributed among the different orders as follows:*

Class Sarcodina
   Subclass RHIZOPODA. 
      Order AMOEBIDA.
            1. Amoeba guttula Duj
            2. Amoeba sp.
            3. Trichosphaerium sieboldi Schn. 
      Order RETICULARIIDA. 
         Suborder IMPERFORINA.
            4. Gromia lagenoides Gruber. 
         Suborder PERFORINA.
            5. Truncatulina lobatula Walker & Jacob. 
   Subclass HELIOZOA. 
      Order APHROTHORACIDA.
            6. Actinophrys sol Ehr. 
      Order CHLAMYDOPHORIDA.
            7. Heterophrys myriapoda Archer. 
Class MASTIGOPHORA. 
   Subclass FLAGELLIDIA. 
      Order MONADIDA.
            8. Mastigamoeba simplex, n. sp.
            9. Codonoeca gracilis, n. sp.
           10. Monas sp. 
      Order CHOANOFLAGELLIDA.
           11. Monosiga ovata S. Kent.
           12. Monosiga fusiformis S. Kent.
           13. Codonosiga botrytis (Ehr.) J. Cl. 
      Order HETEROMASTIGIDA.
           14. Bodo globosus Stein.
           15. Bodo caudatus (Duj.) Stein.
           16. Oxyrrhis marina Duj. 

Page 3

      Order EUGLENIDA.
           17. Astasia contorta Duj.
           18. Anisonema vitrea Duj. 
      Order SILICOFLAGELLIDA.
           19. Distephanus speculum Stoehr. 
   Subclass DINOFLAGELLIDIA. 
      Order ADINIDA.
           20. Exuviaella lima Clenk.
           21. Exuviaella marina Clenk. 
      Order DINIFERIDA.
           22. Gymnodinium gracile Bergh.
           23. Glenodinium cinctum Ehr.
           24. Glenodinium compressa, n. sp.
           25. Peridinium digitale Pouchet.
           26. Peridinium divergens Ehr.
           27. Ceratium tripos Nitsch.
           28. Ceratium fusus Ehr.
           29. Amphidinium operculatum Clap. & Lach. 
Class INFUSORIA. 
   Subclass CILIATA. 
      Order HOLOTRICHIDA. 
         Family ENCHELINIDAE.
           30. Lacrymaria lagenula Cl. & Lach.
           31. Lacrymaria coronata Cl. & Lach.
           32. Trachelocerca phoenicopterus Cohn.
           33. Tiarina fusus Cl. & Lach.
           34. Mesodinium cinctum, n. sp. 
         Family TRACHYLINIDAE.
           35. Lionotus fasciola Ehr.
           36. Loxophyllum setigerum Quenn. 
         Family CHLAMYDODONTIDAE.
           37. Nassula microstoma Cohn.
           38. Chilodon cucullulus Muell.
           39. Dysteria lanceolata Cl. & Lach. 
         Family CHILIFERIDAE.
           40. Frontonia leucas Ehr.
           41. Colpidium colpoda Ehr.
           42. Uronema marina Duj. 
         Family PLEURONEMIDAE.
           43. Pleuronema chrysalis Ehr.
           44. Pleuronema setigera, n. sp.
           45. Lembus infusionum, n. sp.
           46. Lembus pusillus Quenn. 
         Family OPALINIDAE.
           47. Anoplophrya branchiarum Stein. 
      Order HETEROTRICHIDA. 
         Family BURSARIDAE.
           48. Condylostoma patens Muell. 
         Family HALTERIDAE.
           49. Strombidium caudatum From. 
         Family TINTINNIDAE.
           50. Tintinnopsis beroidea Stein.
           51. Tintinnopsis davidoffi Daday. 
      Order HYPOTRICHIDA. 
         Family PERITROMIDAE.
           52. Peritromus emmae Stein. 
         Family OXYTRICHIDAE.
           53. Epiclintes radiosa Quenn.
           54. Amphisia kessleri Wrzes. 
         Family EUPLOTIDAE.
           55. Euplotes charon Ehr.
           56. Euplotes harpa Stein.
           57. Diophrys appendiculatus Stein.
           58. Uronychia setigera, n. sp.
           59. Aspidisca hexeris Quenn.
           60. Aspidisca polystyla Stein. 

Page 4

      Order PERITRICHIDA. 
         Family LICHNOPHORIDAE.
           61. Lichnophora macfarlandi Stevens. 
         Family VORTICELLIDAE.
           62. Vorticella marina Greeff.
           63. Vorticella patellina Mueller.
           64. Zoothamnium elegans D’Udek.
           65. Cothurnia crystallina Ehr.
           66. Cothurnia nodosa Cl. & Lach.
           67. Cothurnia imberbis Ehr. 
   Subclass SUCTORIA. 
         Family PODOPHRYIDAE.
           68. Podophrya gracilis, n. sp.
           69. Ephelota coronata Wright. 
         Family ACINETIDAE.
           70. Acineta divisa Fraip.
           71. Acineta tuberosa Ehr. 
         Family DENDROSOMIDAE.
           72. Trichophrya salparum Entz.

* This classification includes only the orders and families
  represented at Woods Hole

Genus AMOEBA Auct.

The pseudopodia are lobose, sometimes absent, the body then progressing by a flowing movement; the body consists of ectoplasm and endoplasm, the latter being granular and internal, the former hyaline and external.  There is always one nucleus and one vacuole, but both may be more numerous.  Reproduction takes place by division or by spore-formation.  Fresh-water and marine.

Amoeba guttala Duj.  Fig. 1.

A minute form without pseudopodial processes, extremely hyaline in appearance, and characterized by rapid flowing in one direction.  The body is club-shape and moves with the swollen end in advance.  A comparatively small number of large granules are found in the swollen portion, while the smaller posterior end is quite hyaline.  Contractile vacuole absent, and a nucleus was not seen.  Frequent in decomposing vegetable matter.  Length 37 mu.  Traverses a distance of 160 mu in one minute.

The fresh-water form of A. guttula has a vacuole, otherwise
Dujardin’s description agrees perfectly with the Woods Hole forms.

[Illustration:  Fig. 1.—­Amoeba guttala.]

Amoeba?  Fig. 2.

A more sluggish form than the preceding, distinguished by its larger size, its dense granulation, and by short, rounded pseudopodia, which, as in Amoeba proteus, may come from any part of the body.  A delicate layer of ectoplasm surrounds the granular endoplasm, and pseudopodia formation is eruptive, beginning with the accumulation of ectoplasm.  Movement rapid, usually in one direction, but may be backwards or sideways, etc.  Contractile vacuole absent; the nucleus is spherical and contains many large chromatin granules.  Length 80 mu; diameter 56 mu.

[Illustration:  Fig. 2.—­Amoeba sp.]

Genus TRICHOSPHAERIUM Schneider ’78

Synonym:  Pachymyxa hystrix Gruber.

Page 5

Marine rhizopods, globular or irregular in form, and slow to change shape.  Dimorphic.  Both forms multinucleate during vegetative life.  Pseudopodia are long, thin, and thread-form, with rounded ends.  Their function is neither food-getting nor locomotion, but probably tasting.  The plasm of both forms is inclosed in a soft gelatinous membrane.  In one form the jelly is impregnated with needles of magnesium carbonate (Schaudinn), but these are absent in the other form.  The membrane is perforated by clearly defined and permanent holes for the exit of the pseudopodia.  Reproduction occurs by division, by budding or by fragmentation, but the parts are invariably multinucleate.  At the end of vegetative life the needle-bearing form fragments into numerous mononucleate parts; these develop into adults similar to the parent, but without the spines.  At the end of its vegetative life this new individual fragments into biflagellated swarm-spores which may conjugate, reproducing the form with needles.  Size up to 2 mm.

Trichosphaerium sieboldi Schneider.  Fig. 3.

With the characters of the genus.  A form which I have taken to be a young stage of this interesting rhizopod is described as follows: 

A minute, almost quiescent, form which changes its contour very slowly.  The membrane is cap-like and extends over the dome-shaped body, fitting the latter closely.  The endoplasm is granular and contains foreign food-bodies.  Nucleus single, spherical, and centrally located.  Pseudopodia short and finger-form, emerging from the edge of the mantle-opening and swaying slowly from side to side or quiescent.  The most characteristic feature is the presence of a broad, creeping sole, membranous in nature and hyaline in appearance.  This membrane is the only evidence of ectoplasm, and it frequently shows folds and wrinkles, while its contour slowly changes with movements of body.  The pseudopodia emerge from the body between this membrane and the shell margin.  Contractile vacuole absent.  Length 42 mu, width 35 mu.  In decomposing seaweeds, etc.

Only one specimen of this interesting form was seen, and I hesitate somewhat in placing it on such a meager basis.  It is so peculiar, however, that attention should be called to it in the hope of getting further light upon its structure and mode of life.  Its membranous disk recalls the genus Plakopus; its mononucleate condition, its membranous disk, and the short, sometimes branched, pseudopodia make it difficult to identify with any phase in the life-history of Trichosphaerium.  I shall leave it here provisionally, with the hope that it may be found more abundantly another time.

[Illustration:  Fig. 3.—­Trichosphaerium sieboldi]

Genus GROMIA Dujardin ’35.

(Dujardin 1835; M. Schultze ’62; F. E. Schultze ’74; Leidy ’77;
Buetschli ’83; Gruber ’84.)

Page 6

The form is ovoid or globular, and the body is covered by a tightly fitting, plastic, chitin shell, which, in turn, is covered by a fine layer of protoplasm.  The flexibility of the shell makes the form variable as in the amoeboid types.  The thickness of the shell is quite variable.  The pseudopodial opening is single and terminal.  The pseudopodia are very fine, reticulate, granular, and sharply pointed, and form a loose network outside of the shell opening.  Nucleus single or multiple.  Contractile vacuole is usually absent.  Fresh and salt water.

Gromia lagenoides Gruber ’84.  Fig. 4.

This species is not uncommon about Woods Hole, where it is found upon the branches of various types of algae.  The body is pyriform, with the shell opening at the larger end.  The chitinous shell is hyaline and plastic to a slight extent, so that the body is capable of some change in shape.  The shell is thin and turned inwards at the mouth-opening, forming a tube (seen in optical section in fig. 4) through which the protoplasm passes to the outside.  The walls of this tube are thicker than the rest of the shell, and in optical section the effect is that of two hyaline bars extending into the body protoplasm.  A thin layer of protoplasm surrounds the shell and fine, branching, pseudopodia are given off in every direction.  The protoplasm becomes massed outside of the mouth-opening and from here a dense network of pseudopodia forms a trap for diatoms and smaller Protozoa.  The nucleus is spherical and contains one or two large karyosomes.  The protoplasm is densely and evenly granular, without regional differentiation.  I have never observed an external layer of foreign particles, such as Gruber described in the original species.

Length of shell 245 mu; largest diameter 125 mu.

[Illustration:  Fig. 4.—­Gromia lagenoides.]

Genus TRUNCATULINA D’Orbigny.

A group of extremely variable foraminifera in which the shell is rotaline; i. e., involute on the lower side and revolute on the upper (Brady).  The shell is calcareous and coarsely porous in older forms.  The characters are very inconstant, and Brady gives up the attempt to distinguish the group by precise and constant characters.

Truncatulina lobatula Walker & Jacob.

Synonyms:  See Brady ’84 for a long list.

“It is impossible to define by any precise characters the morphological range of the present species.  Its variations are infinite.” (Brady, p. 660.)

This very common form, which occurs in all latitudes, was found frequently among the algae at Woods Hole.  Its characters are so difficult to define that for the present I shall limit my record to this brief notice.  Size of shell 230 mu by 270 mu.

Genus ACTINOPHRYS Ehr.

The body is spherical and differentiated into granular endoplasm and vacuolated ectoplasm, but the zones are not definitely separated.  There is one central nucleus and usually one contractile vacuole.  The pseudopodia have axial filaments that can be traced to the periphery of the nucleus.  Fresh and salt water.

Page 7

Actinophrys sol Ehr., variety.  Fig. 5.

Synonyms:  See Schaudinn ’95.

The diameter is about 50 mu; the vacuolated ectoplasm passes gradually into the granular endoplasm.  This is the characterization given A. sol by Schaudinn, and it applies perfectly to the freshwater forms.  If I am correct, however, in placing an Actinophrys-like form found at Woods Hole in this species, the description will have to be somewhat modified.  In this form (fig. 5) there is no distinction between ectoplasm and endoplasm, and there is an entire absence of vacuoles.  The nucleus is central, and axial filaments were not seen.  The single specimen that I found looked much like a Suctorian of the genus Sphaerophrya, but the absence of a firm cuticle and the presence of food-taking pseudopodia with granule-streaming makes it a very questionable Suctorian, and 1 place it here until further study throws more light upon it.

Diameter of body 40 mu; length of pseudopodia 120 to 140 mu.

[Illustration:  Fig. 5.—­Actinophrys sol.]

Genus HETEROPHRYS Archer.

The body is globular with but slight differentiation into ectoplasm and endoplasm; one nucleus in the latter; contractile vacuoles one or many; pseudopodia on all sides, thin, and with peripheral granule-streaming; surrounded by a globular, rather thick coat of jelly, which is hyaline inside and granular on the periphery.  Fresh and salt water.

Heterophrys myriapoda Archer.  Fig. 6.

Synonym:  H. marina Hert. & Less. ’74.

Diameter 25 to 80 mu; pseudopodia twice as long as the body diameter; the plasm often contains chlorophyll bodies (Zoochlorella).  The granular part of the gelatinous layer is thick (up to 10 mu).  The spine-like processes are very thin and short. (Schaudinn ’95.) The marine form found at Woods Hole probably belongs to this species, as described by Schaudinn.  The short pseudopodia which give to the periphery a fringed appearance are quite regularly placed in connection with the pseudopodia.  The latter are not so long as twice the body diameter, the longest being not more than equal to the diameter of the sphere.  The body inside of the gelatinous covering is thickly coated with bright yellow cells similar to those on Radiolaria.  The animal moves slowly along with a rolling motion similar to that described by Penard ’90, in the case of Acanthocystis.  Diameter of entire globe 35 mu; of the body without the jelly 18 mu.  The extremely fine granular pseudopodia are 8 to 35 mu long.  Common among algae.

This form was probably meant by Peck ’95, when be figured “a heliozooen.”

[Illustration:  Fig. 6.—­Heterophrys myriapoda.]

KEY TO ORDERS OF FLAGELLIDIA.

Small, body usually amoeboid; 1 or more Order MONADIDA. flagella; no mouth

Small; plasmic collar around the Order CHOANOFLAGELLIDA. flagellum

Page 8

With 2 or more flagella; one trails Order HETEROMASTIGIDA. behind

With 3 or more flagella, none of which Order POLYMASTIGIDA. trails

Large; firm body wall; 1 or 2 flagella; Order EUGLENIDA. mouth or pharynx, or both

Medium size; with chlorophyll, Order PHYTOFLAGELLIDA. no mouth, usually colonial

Small; silicious skeleton; parasitic Order SILICOFLAGELLIDA. on Radiolaria or free (One genus,
          
                                Distephanus Stoehr)

KEY TO THE FAMILIES OF MONADIDA.

No mouth; 1 or 2 flagella:  amoeboid Family Rhizomastigidae with lobose or ray-like pseudopodia

Mouth at base of single flagellum; Family Cercomonadidae plastic; no pseudopodia

One flagellum; inclosed in gelatinous Family Codonoecidae or membranous cups

One flagellum; tentacle like process Family Bikoecidae at base of flagellum; inclosed in cup

One main flagellum and 1 or 2 Family Heteromonadidae accessory flagella

KEY TO MARINE GENERA OF MONADIDA.*

Family Rhizomastigidae

1.  Flagellum repeatedly thrown off     Genus *_Mastigamoeba_
and reassumed                       in part

   2.  Flagellum never thrown off 3

   3. a.  Pseudopodia lobose Genus Mastigamoeba

      b.  Pseudopodia ray-like Genus Mastigophrys

Family Codonoecidae

   1.  Goblet-shaped cups adherent Genus *_Codonoeca_
      by stalk

Family Heteromonadidae

   1.  The long flagellum vibratory Genus *_Monas_

   2.  The long flagellum rigid; Genus Sterromonas
      shorter one vibrates

   * Presence at Woods Hole indicated by asterisk.

KEY TO MARINE QENERA OF CHOANOFLAGELLIDA.

1.  Without gelatinous 3
or membranous test

2.  With gelatinous 4
or membranous test

3. a.  Attached forms: 

1.  Without a stalk, or with Genus *_Monosiga_
a very short one

2.  With a long, simple, stalk Genus *_Codonosiga_

3.  With a long, branched, stalk Genus Codonocladium

b.  Free-swimming Genus Desmarella

4.  Colonial, and with a gelatinous Genus Proterospongia
covering

* Presence at Woods Hole indicated by asterisk.

KEY TO FAMILIES AND MARINE GENERA OF HETEROMASTIGIDA.

   1.  Two flagella nearly equal in size Family Bodonidae

      One main and 2 accessory flagella Family Trimastigidae

Page 9

Family Bodonidae

   1.  Body very plastic, Genus *_Bodo_
      almost amoeboid

      Body not plastic; with large Genus *_Oxyrrhis_
      anterior cavity, holding flagella

Family Trimastigidae

   1.  With an undulatory membrane Genus Trimastix
      between accessory flagella

      Without such membrane; flagella Genus Costia
      contained in a ventral groove
      while at rest

   * Presence at Woods Hole indicated by asterisk.

KEY TO MARINE GENERA OF POLYMASTIGIDA.

   1.  Body flattened; ends rounded; Genus Trepomonas
      sides hollowed; often with
      wing-like processes; cross
      section S-shaped

   2.  Body pyriform; one large Genus Tetramitus
      asymmetrical groove; 4 flagella

   3.  Body spherical; many flagella Genus Multicilia
      equally distributed

KEY TO FAMILIES AND MARINE GENERA OF EUGLENIDA.

   1.  With deeply-insunk pharynx; 2
      no mouth

      With pharynx and distinct mouth Family Peranemidae

   2.  Body plastic; usually with Family Euglenidae
      chromatophores and eye-spot

      Body plastic; no chromatophores; Family Astastidae
      no eye-spot

Family Euglenidae

      Body Euglena-like, inclosed Genus Trachelomonas
      in shell with round opening for
      exit of flagellum

Family Astastidae

      Body with one flagellum Genus *_Astasia_

Family Peranemidae

   1.  Body striped; plastic; Genus Heteronema
      two diverse flagella

   2.  Body striped; not plastic; Genus *_Anisonema_
      posterior flagellum longer
      than the other

   3.  Body striped; not plastic; Genus Entosiphon
      with rod-like organ in pharynx

   * Presence at Woods Hole indicated by asterisk.

Genus MASTIGAMOEBA F. E. Schultze ’75.

(Kent ’81; Buetschli ’86; Klebs ’92; Senn 1900.)

In general the form is oval and either regular in outline or irregular through the presence of many pseudopodia.  One flagellum usually quite large and distinct.  Differentiation of ectoplasm and endoplasm distinct or wanting.  One to several contractile vacuoles.  The pseudopodia are occasionally withdrawn, and the flagellum is the sole means of locomotion.  In some cases the flagellum turns into a pseudopodium, and, conversely, the pseudopodium at one end may become a flagellum (see below).  In some rare cases the ectoplasm secretes a gelatinous mantle.  Reproduction not observed.

Page 10

Fresh and salt water.

Mastigamoeba simplex, n. sp.  Fig. 7.

A very small form, first seen in the flagellated stage, aroused my interest by reason of the fact that its flagellum lost its regular outline and became amoeboid, turning to a pseudopodium, while at the same time other pseudopodia were protruded from different parts of the periphery.  In this condition ectoplasm and endoplasm could be made out with the clearest definition.  After the pseudopodia were well formed, the body became flat and closely attached to the glass slide.  In a short time one of the pseudopodia became longer than the rest; the body became more swollen; the pseudopodia were gradually drawn in, with the exception of the more elongate one; this became active in movement and finer in diameter, until ultimately it formed a single flagellum at the anterior of a small monadiform flagellate.  The process was repeated two or three times under my observation, so that I am convinced that it was not a developmental form of some rhizopod.  Several of them were seen at different times during the summer, and they were always of the same size and form in the flagellated or amoeboid condition.  I did not make out their reproduction, and I shall not be satisfied that this is a good species until their life history is known.

In decaying algae.  Length 10 mu.

[Illustration:  Fig. 7.—­Mastigamoeba simplex.]

Genus CODONOECA James Clark ’66.

(Kent ’81.)

Small forms inclosed in cup or “house” of ovoid or goblet shape, colorless and probably gelatinous (chitin?) in texture, and borne upon a stalk.  The monad does not completely fill the test.  Contractile vacuole single, posterior.

Codonoeca gracilis, n. sp.  Fig. 8.

The cup is urn-shaped with a well-defined neck or collar borne upon a shoulder-like end of the body.  It is hyaline, colorless, and carried upon a stalk equal in length to the cup or shorter than this.  The animal does not fill the cup, nor is it attached by a filament to the latter.  There is a single flagellum.  The nucleus is minute and lateral in position; the contractile vacuole is in the posterior end of the body.  Total length of cup and stalk 21 mu; of cup alone 12 mu.  This minute form looked so much like a choanoflagellate that I supposed it to be one until I discovered an empty case (Fig. 8).

[Illustration:  Fig. 8.—­Codonoecea gracilis.]

Genus MONAS (Ehr.) Stein ’78

(Kent ’81; Buetschli ’86; Klebs ’97; Senn 1900.)

The body is small, globular or oval and either free-swimming or fastened by one of the two flagella.  The body is sometimes a little amoeboid, with short pseudopodial processes.  In addition to the main flagellum, there are usually one or two small flagella at the basis of the larger one.  The nucleus is usually anterior, and one or two contractile vacuoles are present.

Page 11

Monas sp.  Fig. 9.

An extremely small form (3 mu) attached by a thread of protoplasm—­perhaps a flagellum, to algae.  The body is ovoid and the main flagellum is about four times the length of the body.  The contractile vacuole is posterior.  Only one specimen was seen and upon this I shall not attempt to name the species.

[Illustration:  Fig. 9.—­Monas sp.]

Genus MONOSIGA Kent ’81.

(Buetschli ’86; France ’97; Senn 1900.)

Small colorless forms of Choanoflagellida, always naked and solitary.  The posterior end is attached directly to the substratum, or there is a short stalk not exceeding the body in length.  Kent ’81 distinguished nine species, but Buetschli questioned the accuracy of many of these, and in this he was followed by France ’97, who recognized three species—­Monosiga ovata, M. fusiformis, and M. augustata.  Fresh and salt water.

Monosiga ovata S. Kent ’81.  Fig. 10.

Synonyms:  M. brevipes S. K.; M. consociata S. K.; M. limnobia
Stokes.

The individuals are unstalked or provided with a very short stalk less than the body in length.  The form is spherical or ovate, broadest at the base and tapering to the extremity.  The collar is somewhat variable in size.  In the Woods Hole forms it was about the length of the body.  Oil particles present.  Contractile vacuole posterior, nucleus anterior.

Fresh and salt water.  Length of body without the collar 5 mu.

[Illustration:  Fig.10.—­Monosiga ovata.]

Monosiga fusiformis S. K. Fig. 11.

Synonyms:  M. steinii S. K.; M. longicollis S. K.

The individuals are unstalked, minute, and of a general flask-shape.  The body is swollen centrally and tapers slightly at each end.  There is no stalk, the body being fixed by the attenuate posterior end.  There are two contractile vacuoles and one nucleus, which is situated a little above the body center.  Fresh and salt water.  Length without collar 9 mu; length of collar 3 mu.

[Illustration:  Fig. 11.—­M. fusiformis.]

Genus CODONOSIGA (Jas. Clark ’67).

(Buetschli ’78; Kent ’81; France ’97; Senn 1900.)

This genus, as modified by France, is distinguished from the preceding by the possession of an unbranched stalk much longer than the body length.  The body is naked and of various shapes, and the individuals are solitary or colonial upon a single stalk.  Kent ’81 enumerates no less than 10 species, which were cut down by Buetschli to 1.  France admits 4—­C. botrytis Jas. Clark; C. grossularia; C. pyriformis, and C. furcata, all S. Kent—­but regards the second and third as merely form varieties of the first.

Codonosiga botrytis (Ehr. sp.) Jas. Clark ’67.  Fig. 12.

France gives the following synonyms:  Epistylia botrytis Ehr.; E. digitalis Stein, Zoothamnium parasitica Stein; Anthophysa solitaria Fresenius; Codonosiga pulcherrima Jas. Clark; Monosiga gracilis S. Kent; M. globulosa S. Kent; Codonosiga pyriformis Kent; C. grossularia Kent; (France).

Page 12

The individuals are small and provided with a long unbranched, or terminal, simply split stalk.  The individuals are single or colonial.  The Woods Hole form measured 22 mu over all; the body was 5 mu, the collar 3 mu, and the stalk 14 mu.  No colonies were seen, and only a few individuals upon red algae.

[Illustration:  Fig. 12.—­Codonosiga botrytis.]

Genus BODO (Ehr.) Stein.

(Stein ’59, Buetschli ’83; Klebs ’92; Senn 1900.)

The body is naked, usually amoeboid in its changes, and provided with two flagella, one of which is usually trailed along under and behind the animal.  The anterior end is usually pointed, with the flagella arising from a minute depression; the posterior end is rounded.  Specific characters very difficult to analyze.  Fresh and salt water.

Bodo globosus Stein.  Fig. 13.

The body during movement is globular or ovoid, without any anterior process.  The trailing flagellum is invariably much longer than the vibratory one.  The contractile vacuole lies in the anterior half of the body.  Solid food particles are taken in near base of flagella.

Length of body 9 to 12 mu; diameter 8 to 11 mu.  Common.

[Illustration:  Fig. 13.—­Bodo globosus.]

Bodo caudatus (Duj.) Stein.  Fig. 14.

Synonyms:  Amphimonas caudatus Duj.; Diptomastix caudata Kent.

The body is variable in shape, but usually flattened and pointed posteriorly.  An anterior process is almost always present, and below this the flagella are inserted in a minute depression.  The contractile vacuole is close to the base of the flagella.  The flagella are about the same size, the anterior one usually somewhat longer.  Common.  Length 12 to 18 mu.

This species was seen by Peck ’95 and described as a small flagellate.

[Illustration:  Fig. 14.—­Bodo caudatus.]

Genus OXYRRHIS Duj.

(Kent ’81; Buetschli ’86; Klebs ’92; Senn 1900.)

Medium-sized forms, somewhat oval in shape, with a rounded posterior end.  The anterior end is continued dorsally in a somewhat attenuate pointed process.  At the base of this process is a large cavity or funnel, on the dorsal wall of which, or on a projection from this wall, are two equal-size flagella.  When at rest, the flagella are directed backwards.  The nucleus is central.  In moving, the posterior end is invariably in advance.  This genus is exceptional among Mastigophora in that division is transverse instead of longitudinal.

Oxyrrhis marina Duj.  Fig. 15.

With the characters of the genus.  Contractile vacuole not seen. 
Length 28 to 40 mu.

[Illustration:  Fig. 15.—­Oxyrrhis marina.]

Genus ASTASIA Ehr.

Flagellates with one flagellum, a spindle-form body and a high degree of plasticity, the contour constantly changing.  A distinct, usually striped cuticle is invariably present.  “Eye-spots” are absent.  Fresh and salt water.

Page 13

Astasia contorta Duj.  Fig. 16.

Astasia inflata Duj. ’41.

The body is colorless, transparent, and flexible.  It is largest in the center, thence tapering at the two extremities.  The surface of the cuticle is obliquely striated, giving to the animal a distinctly twisted appearance.  The contractile vacuole is in the anterior neck-like portion of the body.  The flagellum is inserted in a distinct oesophageal tube, into which the contractile vacuole empties.  This tube is continued into a deeper pharyngeal apparatus of unknown function.

Common in decaying algae.  Length 60 mu; greatest diameter 30 mu.

[Illustration:  Fig. 16.—­Two aspects of Astasia contorta.]

Genus ANISONEMA Buetschli

Flagellates with two flagella, of which one is directed forwards and is concerned with the locomotion of the animal, while the other is directed backwards and drags after the animal when in motion.  Body slightly compressed dorso-ventrally (fig. 17, section).  An oral furrow is present on the ventral side and the two flagella originate in it (fig. 17, at left).  The vacuole is on the left side.  Food vacuoles are present in the posterior part.  The nucleus is central.  Movement creeping.

Fresh and salt water.

Anisonema vitrea (Duj.) Fig. 17.

Synonyms:  Tropidoscyphus octocostatus Stein ’83; Sphenomonas Kent ’81; Ploeotia vitrea Senn 1900.

With the characteristics of the genus.  It differs from freshwater forms in having eight furrowed surfaces running somewhat spirally from the posterior to the oral end.  Length 50 mu; width 23 mu.  This attractive flagellate was quite common in decaying algae at Woods Hole; its shaking movement, its peculiar furrowed surfaces, and, above all, its perfectly transparent, vitreous appearance, were well described by Dujardin.  Stein’s Tropidoscyphus octocostatus is a fresh-water form which may possibly be a distinct species, especially as it is described with both flagella directed forwards.

[Illustration:  Fig. 17.—­Anisonema vitrea.]

Genus DISTEPHANUS Stoehr.

An aberrant flagellate bearing a single flagellum and a silicious skeleton resembling those of the Radiolaria.  The skeleton consists of two rings of different diameter parallel with one another and connected by silicious bars.  From the wider ring half a dozen bars radiate outwards and a similar number of short thorn-like bars point inwards obliquely.  The color is yellow, and except for the flagellum the form might easily be mistaken for a Radiolarian, as has been the case repeatedly.

Distephanus speculum Stoehr.

Dictyocha speculum Stoehr; Dictyocha Auc.

With the characters of the genus.

A single specimen only of this very interesting form was seen at Woods Hole.  It occurred in a collection of tow made near the end of the wharf during the evening.

Page 14

KEY TO FAMILIES OF DINOFLAGELLIDIA.

   1.  No crossfurrow; two free flagella Family Prorocentridae

   2.  One or more cross-furrows 3

   3.  Cross-furrow nearly central Family Peridinidae
      (cf. Oxytoxum)

      Cross-furrow close to Family Dinophysidae
      anterior end

Several cross-furrows               Family Polydinidae
and flagella                        (One genus, Polykrikos.)

KEY TO MARINE GENERA OF PROROCENTRIDAE.

Diagnostic characters:  The transverse furrow is absent and the two flagella arise from the anterior end of the body.  The shell may be bivalved.

   1.  No tooth-like process dorsal Genus *_Exuviaella_
      to the flagellum

   2.  With tooth-like process dorsal Genus Prorocentrum
      to the flagellum

   * Presence at Woods Hole indicated by asterisk.

KEY TO MARINE GENERA OF PERIDINIDAE.

Diagnostic characters:  The cross-furrow is nearly central (see, however, Oxytoxum); the body may or may not have a shell; the shell may or may not be composed of distinct plates; the plates are distinguished as equatorial (i.e., bordering the cross-furrow), apical, and antapical, while still another, the “rhombic plate”, may be present, extending from the cross-furrow to the apex.

   1.  Without distinct shell Genus *_Gymnodinium_

      With a distinct shell 2

   2.  Shell not composed of definite 3
      plates

      Shell composed of definite plates 4

   3.  Cross-furrow replaced by Genus Ptychodiscus
      thin-skinned band

      Cross-furrow well defined; Genus Protoceratium
      reticulate markings raised
      on shell-surface

      Cross-furrow well defined; Genus *_Glenodinium_
      no markings

   4.  Two parts of shell equal or 5
      nearly equal

      Two parts of shell very unequal 11

   5.  With transverse flagellum in 6
      a distinct furrow

      Transverse flagellum not in a 10
      furrow

   6.  With horns, or with wing-like 7
      processes

      Without processes of any kind 9

   7.  Processes small, wing-like, Genus Diplopsalis
      around flagellum-fissure

      Processes horn-like 8

   8.  Anterior part with 7 equatorial Genus *_Peridinium_
      and 1 rhombic plates

      Anterior part with 5 equatorial Genus Gonyaulax
      and no rhombic plates

Page 15

      Anterior part with 3 equatorial Genus *_Ceratium_
      and no rhombic plates

   9.  Anterior part with 14 equatorial Genus Pyrophacus
      and 1 rhombic plates

      Anterior part with 7 equatorial Genus Goniodoma
      plates

      Anterior part with 4 equatorial Genus Amphidoma
      plates

  10.  Apical extremity drawn out Genus Podolampas
      into a tube

      Apical extremity not drawn out Genus Blepharocysta
      into a tube

  11.  Cross-furrow deep, with great Genus Ceratocorys
      ledge-like walls

      Cross-furrow wide, no ledge-like Genus Oxytoxum
      walls

   * Presence at Woods Hole indicated by asterisk.

KEY TO MARINE GENERA OF DINOPHYSIDAE.

Diagnostic characters:  The cross-furrow is above the center of the body, and its edges, as well as the left edge of the longitudinal furrow, are usually produced into characteristic ledges; those of the cross-furrow usually form great funnel-like anterior processes, while those of the longitudinal furrow usually form great, lateral, wing-like processes ornamented by ribs and other markings.

   1.  Without shell; longitudinal Genus *_Amphidinium_
      furrow may open & close

   2.  With shell; longitudinal furrow 3
      unchangeable

   3.  With distinct apical funnel 4

      No apical funnel Genus Phalacroma

   4.  With great wing-like ledge 5

      Ledges very small; body long, Genus Amphisolenia
      needle-like

   5.  Ledge of longitudinal furrow 6
      extends to posterior end

Ledge of longitudinal furrow Genus Dinophysis does not extend to posterior end (Recorded by Peck (’93-’95) as very abundant at Woods Hole and in Buzzards Bay.)

   6.  Ledge is continued dorsally to Genus Ornithocercus
      the cross-furrow

      Ledge is not continued dorsally 7

   7.  With deep dorsal cavity; Genus Citharistes
      secondary funnel not notched

      No dorsal cavity; secondary Genus Histioneis
      funnel deeply notched

   * Presence at Woods Hole indicated by asterisk.

Genus EXUVIAELLA Cienkowsky ’82.

(Klebs ’81; Pouchet ’83, ’86.)

The form varies from globular to ovoid, with occasionally a sharp posterior end.  Shells are usually somewhat compressed, and consist of two valves, which frequently slide one over the other in such a manner as to show the structure with great clearness.  The right shell may have a distinct indentation in the anterior edge.  There are two lateral, discoid, brown chromatophores, each of which possesses a central amylum granule.  The nucleus is posterior.  Salt water.

Page 16

Exuviaella lima Ehr.  Fig. 18.

Synonyms Pyxidicula Ehr.; Cryptomonas Ehr.; Prorocentrum lima
Kent; Amphidinium Pouchet.

The shell is ovate, rounded and swollen posteriorly.  The anterior border of both shells is slightly indented.  The shell is quite thick.  The animal moves through the water very slowly.  Dark brown in color.  Length 48 mu; width 44 mu.

[Illustration:  Fig. 18.—­Exuviaella lima.]

Exuviaella marina Cienkowsky.  Fig. 19.

A smaller form than the preceding, more elliptical in outline, with a thinner shell and with large granules throughout the endoplasm.  The nucleus is spherical and subcentral in position and possesses a distinct central granule.  This may be a small variety of E. lima.

[Illustration:  Fig. 19.—­Exuviaella marina.]

Genus GYMNODINIUM Stein ’78.

(Bergh ’81; Kent ’81; Pouchet ’83, ’85; Entz ’84; Schuett ’95.)

The general structure of these forms is similar to that of Glenodinium; the most striking and positive difference is the absence of a shell.  The animals are, as a rule, spherical, yet they may be pointed at the two ends or at one of them.  They are also frequently flattened dorso-ventrally.  The transverse furrow may be either circular and straight around the body or may describe a spiral course, passing even twice around the body.  The flagella arise near cross-furrow or, in some cases, in longitudinal furrow.  Chromatophores may or may not be present and food-taking is holozoic, in many cases at least.  In some cases ectoplasm and endoplasm can be distinguished.  Fresh and salt water.

Gymnodinium gracile Bergh ’82, var. sphaerica, n.  Fig. 20.

The body is divided by the transverse furrow into a shorter anterior and a longer posterior part.  The longitudinal furrow is broader at the posterior extremity than at the cross-furrow.  The structural feature upon which this new variety is made is the unvarying plumpness of the body, making it almost spherical, except for a slight flattening dorso-ventrally.  The nucleus is large and ellipsoidal, with characteristic longitudinal markings of chromatin.  The endoplasm is evenly granular, with a number of large ingested food bodies.  The color is brown, not rose-red as in Bergh’s species, nor is the Woods Hole form as large as the latter.  Length of body 68 mu; width 55 mu.  Common.

[Illustration:  Fig. 20.—­Gymnodinium gracile, var. sphaerica.]

Genus GLENODINIUM (Ehr.), Stein ’83.

(Bergh ’82; Buetschli ’86; Pouchet ’85; Daday ’86.)

Small globular forms with two distinct furrows, one transverse around the body, the other longitudinal upon the face only.  The shell is soft and structureless with a distinct aperture near the meeting point of the two furrows.  The endoplasm usually, but not always, contains a bright red eye-spot.

Page 17

Fresh and salt water.

Glenodinium compressa, n. sp.  Fig. 21, a, b, c.

This species resembles G. acuminata of Ehrenberg except that it is strongly compressed laterally.  The longitudinal furrow extends nearly to the extremity of the animal.  It begins as a narrow slit and widens as it progresses upon the left side; it also becomes much deeper on this side and at the bottom of the depression the longitudinal flagellum is inserted.  The transverse furrow runs evenly around the body near the upper pole, giving to the shell almost the aspect of an Amphidinium.  Brown chromatophores may or may not be arranged radially about a central amylum granule.  One striking characteristic is the depth of the two furrows.  The nucleus is elongate and somewhat curved; it lies against the posterior wall of the rather thick shell.  Not uncommon.

Length 40 mu; breadth 32 mu; width 18 mu.

The posterior end of the animal is often somewhat pointed and this point frequently becomes attached, so that the animal whirls around upon it as upon a pivot.

[Illustration:  Fig. 21 a, b, c.—­Glenodinium compressa, n. sp.]

Glenodinium cinctum Ehr.  Fig. 22.

The body is globular, smooth, and homogeneous.  Brown chromatophores arranged radially, each in the form of a cone, the base of which rests against the shell while the points turn inward.  A bright-red eye-spot may or may not be present; when present it is placed near the junction of the two furrows.  The longitudinal furrow is small.  Fresh water and salt.

Length and diameter the same, 21 mu.

This species was observed by Peck ’93.

[Illustration:  Fig. 22.—­Glenodinium cinctum.]

Genus PERIDINIUM Ehr. ’32, Stein ’83.

(Claparede & Lachmann ’58; Bergh ’81; Pouchet ’83; ’85; Gourret ’88;
Buetschli ’86.)

The form is globular, ovoid or elongate, the apex frequently drawn out into a long tube.  The transverse and longitudinal furrows are quite distinct, the former having often a spiral course about the body.  The two halves of the body are similar, the posterior being somewhat shorter; the anterior half has seven equatorial plates, an oral plate, two lateral apical plates, and one or two dorsal plates.  The two antapical plates frequently have a tooth-like process.  The bodies are colorless, green or brown.

Fresh and salt water.

Peridinium digitale Pouchet.  Fig. 23.

Synonyms:  Protoperidinium digitale Pouchet; Protoperidinium Bergh p. p.; P. divergens Peck.

The shell is covered with pits of large size.  The posterior part is hemispherical and surmounted by a single horn or spine.  The transverse furrow is very oblique, and its two extremities are united by a sigmoid longitudinal furrow.  The anterior half bears two spines or horns of different size, and variable.  The nucleus is spherical or ellipsoidal and placed in the posterior half of the shell.

Page 18

Length 68 mu; diameter 54 mu.  Common.

Although the description of Pouchet’s P. digitale differs in some respects from a careful description of the Woods Hole form, I think the species are the same.  The chief difference is in the single horn of the posterior half; in Pouchet’s form this is furrowed by a narrow groove which runs to the S-shaped longitudinal furrow.  In the Woods Hole form I was unable to make out such a furrow.  The flagella, also, were not seen.  This same form was pictured by Peck ’95 as P. divergens.

[Illustration:  Fig. 23.—­Peridinium digitale.]

Peridinium divergens Ehr.  Fig. 24.

Synonym:  Ceratium divergens Kent.

The shell is spheroidal, widest centrally, attenuate and pointed posteriorly; the anterior portion is armed with two short, pointed horns, each of them having a toothed process at the basal portion of the inner margin.  They are frequently colorless and beautifully transparent, the body being free from large opaque granules; again they are colored brown or yellow.  The nucleus is large and elongate and finely granular. 75 mu long and 68 mu in diameter.  Common.

[Illustration:  Fig. 24.—­Ventral and dorsal aspects of Peridinium divergens.]

Genus CERATIUM (Schrank).

(Stein ’78; Perty ’52; Clap & Lach. ’58; Bergh ’82; Pouchet ’83;
Gourret & Roeser ’88; Buetschli ’85; Kent ’81; Senn 1900; Schuett ’98.)

The general shape is a flattened sphere with three long processes or horns.  The cross-furrow is either spiral or circular; the longitudinal furrow is usually wide and occupies the greater part of the anterior half of the shell.  The shell is thick, reticulate or striped, and sometimes provided with short spines; often distinctly porous.  The anterior half is composed of 3 equatorial and 3 apical plates, the latter being continued into the horn-like process.  The posterior half is composed of 3 equatorial and one apical plate continued into the posterior horn.  The right posterior plate is continued into a similar horn which may remain rudimentary or be continued into a considerable process.  Similarly the left posterior horn is usually developed, but remains small.  There may be from 2 to 3, 4, and 5 horns.  Chromatophores usually present, green to yellow brown.

Fresh and salt water.

Ceratium tripos Ehr.  Fig. 25.

The body is somewhat triangular and bears three horns, two of which are shorter than the other one and slightly curved upward.

Length, including the horns, 290 mu.

[Illustration:  Fig. 25.—­Ceratium tripos.]

Ceratium fusus Ehr.  Fig. 26.

Synonym:  Peridinium fusus Ehr.

The animal is very elongate, due to the presence of two long horns at the extremities of the body.  Color, yellow with chromatophores.  Length 285 mu; width 23 mu.

Both of these species are common in the tow and in the algae at the edge of the wharf.  Both of them are mentioned by Peck in ’93 and ’95.

Page 19

[Illustration:  Fig. 26.—­Ceratium fusus.]

Genus AMPHIDINIUM Clap. & Lach.

The body is ovoid to globular and usually much flattened dorso-ventrally.  The anterior portion is very much reduced and is somewhat head-like or cap-like.  The longitudinal furrow extends through the entire posterior body length and is apparently capable of widening and narrowing.  It is probably naked (see here Klebs, Pouchet, Buetschli), although Stein maintained that there is a delicate cuticle-like shell.  Chromatophores of brown or green colors present and usually grouped radially about a central amylum granule.  The nucleus is posterior.

Fresh and salt water.

Amphidinium operculatum Clap. & Lach.  Fig. 27.

The body is oval and flattened.  The transverse furrow is at the extremity (posterior) of the body and the small portion, which is thus apparently cut off, is the cap-like or operculum-like structure which gives the name to the species.  Klebs maintains that the two furrows are not connected, but in this he is certainly mistaken, provided we have the same species under consideration.  Very common about Woods Hole.

Length from 40 to 50 mu; width 30 mu; thickness 15 mu.

[Illustration:  Fig. 27.—­Amphidinium operculatum.]

KEY TO INFUSORIA.

1.  With cilia Subclass Ciliata. 3

2.  Without cilia (in adult state) Subclass Suctoria
   tentacles

3. a.  Without a specialized fringe of Order Holotrichida
      large cilia (ad. zone)

   b.  With general covering of cilia Order Heterotrichida
      + adoral zone

   c.  With cilia on ventral side Order Hypotrichida
      + adoral zone

   d.  With cilia in region of adoral Order Peritrichida
      zone, and about mouth only

KEY TO FAMILIES OF THE HOLOTRICHIDA.

A. Mouth closed except during food 1
   ingestion; no undulating membrane

Mouth always open; with undulating 2
membrane

1. Gymnostomina.

a.  Mouth terminal or subterminal.  Family Enchelinidae
Food is swallowed and not
introduced by currents

b.  Mouth terminal or subterminal; Family Trachelinidae
body frequently drawn out into
long process; mouth may have
specialized framework.

c.  Mouth central or posterior; Family Chlamydodontidae
pharynx with supporting
framework

2. Trichostomina.

a.  Mouth anterior or central; Family Chiliferidae
pharynx short or absent;
peristomial depression faint
or absent

b.  Mouth central; pharynx long, Family Urocentridae
tubular; cilia in two broad
zones

Page 20

c.  Mouth posterior; form Family Microthoracidae
asymmetrical; cilia dispersed
or limited to oral region

d.  Mouth anterior or central. Paramoecidae
Peristomial depression (One genus, Paramoecium)
clearly marked.

e.  Mouth at end of long peristome Family Pleuronemidae
running along ventral side;
body dorso-ventrally or
laterally compressed; left edge
of peristome with great, sail-
like undulating membrane

f.  Mouth and pharynx distinct, Family Isotrichidae
posterior; cilia uniform. 
Parasites in ruminants.

g.  Mouth absent; body vermiform, Family Opalinidae
cilia uniform.  Usually
parasites.

KEY TO MARINE GENERA OF ENCHELINIDAE

Diagnostic characters:  Form ellipsoid or ovoid; the mouth is invariably terminal and is usually round—­more rarely slit-formed; it is closed except when food is taken.  An oesophagus when present is a short, invariably non-ciliated tube which is usually surrounded by a more or less clearly defined buccal armature.  The anus is usually terminal.  Large food particles are swallowed, never introduced by currents.

1.  Body naked 3

2.  Body inclosed in a shell or coat 7

3. a.  Cilia uniform about the entire 4
body; body symmetrical

b.  Cilia in the mouth region 5
longer than the others; body
symmetrical

c.  Bristles, or tentacles, in 6
addition to cilia

4.  Mouth terminal; body ellipsoidal Genus Holophrya
to ovoid

5. a.  Mouth terminal; body elongate, Genus Chaenia
flexible, and elastic

b.  Mouth terminal; “neck” highly Genus *_Lacrymaria_
elastic; entire body
flexible; conical “head”

c.  Mouth terminal; “neck” highly Genus *_Trachelocerca_
elastic; entire body
flexible; “head” square

d.  Mouth terminal; “neck” highly Genus Lagynus
elastic; no separate
mouth-bearing portion

6. a.  Body asymmetrical; bristles Genus Stephanopogon
in addition to cilia

b.  Body symmetrical; 4 small Genus *_Mesodinium_
tentacles from mouth; cilia
and cirri in girdles

7.  Shell composed of small Genus *_Tiarina_
sculptured pieces; cilia long,
uniform

* Presence at Woods Hole indicated by asterisk.

Genus LACRYMARIA Ehr. ’30.

(Ehrenberg, C. G., 1838; Perty ’52; Claparede & Lachmann ’58; Stein 59-83; Quennerstedt ’66, ’67; Fromentel ’74; Kent ’81; Gruber ’84; Gourret & Roeser ’86; Buetschli ’88; Schewiakoff ’89.)

Body short to very long flask-shape; for the most part contractile, especially in the neck region.  The posterior end is rounded or pointed.  The main character is the mouth-bearing apex, which “sets like a cork in the neck of the flask.”  One or more circles of long cilia at the base of the mouth portion or upon it.  The body is spirally striped.  Contractile vacuole terminal, with sometimes one or two further forward.  Macronucleus central, globular to elongate, sometimes double.  Food mainly bacteria.  Fresh and salt water.

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Lacrymaria lagenula Clap. & Lach.  Fig. 28, a, b.

Synonym:  L. tenuicula Fromentel ’74.

Body more or less flask-shape, two or three times as long as broad, with conical apex, which is slightly elastic and protrusible; surface obliquely striate, with well-defined lines, 14 to 16 in number; cilia uniform on the body, with a crown of longer ones at the base of the conical proboscis.  The body cilia are not thickly placed except around the proboscis.  The endoplasm is thickly packed with large granules (food particles) in the anterior half and with finely granular particles in the posterior half.  The elongate macronucleus lies a little above the center among the larger granules; the contractile vacuole is double, one on each side of the median line and at the posterior end of the body among the finer granules.  The anus is posterior.  Length 90 mu to 160 mu; greatest width assumed 65 mu.  When fully expanded the posterior end assumes a curious polyhedral form. (Fig. 28 b.)

This form differs slightly from others of the same species as described by different observers, the most striking difference being the presence of two contractile vacuoles in place of the usual one.  These are very slow to fill and grow to a large size before diastole.  The membrane is very tough and retains its form easily under pressure of the cover glass.  Another characteristic feature is the flattening of the surfaces between the striae.  Decaying algae.

[Illustration:  Fig. 28.—­Lacrymaria lagenula.]

Lacrymaria coronata Cl. & Lach. ’58.  Fig. 29.

Synonyms:  L. lagenula Cohn ’66; Moebius ’88; L. cohnii ?  Kent ’81; L. versatilis Quen. ’67.

Form flask-like and similar to L. lagenula, contractile but tough.  The contractile vacuole is terminal, the proboscis is short, slightly raised and separated from the body by a deep cleft; the buccal cilia are inserted part way up on the proboscis.  Form changeable, from short, sac-like to elongate and vermiform.  Length 85 mu.

This species is not very different from L. lagenula, but I noted that in addition to the elongate nucleus, the body striae are much more apparent here and seem to sink into the cuticle, giving the periphery, especially at the collar region, a curious crenulated effect.  The endoplasm is very densely granular and colored a blue-green, probably from food particles.  The number of striae is much larger than in the preceding species.  The membrane is very tough and retains the shape of the body, even with the full pressure of the cover glass.  Micronucleus and trichocysts were not observed.

[Illustration:  Fig. 29.—­Lacrymaria coronata.]

Genus TRACHELOCERCA (Ehr. ’83) Cohn ’66.

(Quennerstedt ’67; Gruber ’87; Entz ’84; Kent ’81; Gourret & Roeser ’88; Buetschli ’88; Schewiakoff ’89; Shevyakov ’96.)

The only well-known representative is very elongate, large (up to 3 mm.  Van Beneden), and very contractile.  The main feature of importance in distinguishing it is the 4-part structure of the mouth region, which, however, may not be obvious.  Pharynx faint and smooth.  Contractile vacuole terminal.  Macronucleus in one central body or in numerous pieces scattered throughout the cell.  Salt water.

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Trachelocerca phoenicopterus Cohn ’66.  Fig. 30.

Synonyms:  T. sagitta Ehr. ’40, Stein ’59; T. tenuicollis
Quennerstedt ’67, Kent ’81; T. minor Gruber ’87, Shevyakov ’96.

The body is extremely elongate and ribbon-like, and this, combined with its wonderful power of extension and retraction, makes it one of the most curious and interesting of microscopic forms.  The anterior end is square or cylindrical; the type species has a four-sided mouth, but many specimens may be found which have a plain cylindrical mouth region.  One reason for this may be the fact that the extremity gets broken off.  In one instance I noticed a very large form with the anterior end under some debris, which evidently held it tight, for the body of the ciliate was thrashing back and forth and twisting itself into knots, etc., like a nematode worm.  Finally, the anterior end broke off with about one-tenth of the body; the remainder, in an hour, had regenerated a new anterior end with long cilia, but with no indication of four sides.  The small anterior piece was also very lively, moving about and eating like the normal animal; its history, however; was not followed.  This species appears to be variable in other ways as well; thus, in some cases the posterior end is rounded (cf.  Entz ’84); in others it is pointed (cf.  Kent ’81, Cohn ’66, et al.).

Again, the macronucleus may be a single round body (Entz ’84, Buetschli ’88) or in two parts (Kent ’81), or in many parts scattered about the body (Gruber).  In the Woods Hole forms the tail is distinctly pointed and turned back sharply, forming an angle at the extremity.  The cilia on this angular part are distinctly longer than the rest.  The function of this posterior part is apparently to anchor the animal while it darts here and there upon the tail as a pivot, contracting and expanding the while.  The body is finely striated with longitudinal markings; when contracted there are no transverse markings nor annulations.  The nucleus is in the form of many fragments scattered throughout.  Length of large specimen 1.7 mm.

[Illustration:  Fig. 30.—­Trachelocerca phoenicopterus.]

Genus MESODINIUM Stein ’62.

(Maupas ’82, ’84; Entz ’84; Shevyakov ’96.)

The main part of the body is globular or conical, with a short, platform-like oral region, and a deep annular groove about the middle of the body.  The oesophagus is rather long, and smooth or longitudinally striped.  One or more rings of cirri rise in the groove.  If more than one ring of cirri are present, the anterior set usually point forward and lie close to the anterior part of the body.  The posterior set, on the other hand, cling close to the posterior region of the body and give to it a peculiar encapsuled appearance.  The most characteristic feature is the presence of four short tentacle-like processes which can be protracted and retracted from the oral region. (Mereschowsky says that the entire anterior half is more or less contractile.) The macronucleus is horseshoe-shaped or ovoid and is situated in the posterior half of the body.  The contractile vacuole is also posterior.

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Movement consists in rapid swimming, with rotation on its axis, or in creeping by means of its anterior cirri, or in sudden jumping, by which it apparently clears a distance of 20 times its diameter in one bound.  Mouth parts may also be used for attachment to foreign bodies.  The moving periods alternate with quiescent periods, during which the organisms with their outstretched and radiating cirri resemble the heliozooen Actinophrys.

Mesodinium cinctum, n. sp.  Fig. 31.

Body spherical to pyriform, constricted near the middle, the constriction dividing the body into dissimilar parts.  The anterior part is broadly pyriform, somewhat plastic and hyaline, with an oral extremity which is sometimes hollow, sometimes evaginated and convex.  Upon this flexible anterior part there are four short but distensible tentacles.  The posterior part is granular and usually filled with food particles; it is well rounded and holds the nucleus and contractile vacuole.  The entire body is surrounded by a fine cuticle.  The nucleus is elongate and extends through the greater part of the posterior half.  The contractile vacuole lies on one side, near the girdle.  The mouth is on the anterior pole in the tentacle region.  The motile organs are cirri and cilia, all inserted in the constriction.  There are two sets of cirri and one of cilia; the latter stand out radially from the girdle and are usually in motion.  The cirri of one set, the anterior, extend forward about twice the length of the anterior half; those of the posterior set closely engirdle the lower half, reaching not quite to the posterior extremity.  These are somewhat hyaline and are closely approximated, giving the impression of a tight-fitting crenulate casing about the lower half.  The cirri are sharply pointed, much broader at the base, and the two sets are so placed that, looked at from above, they have the appearance of a twisted cord. (Fig. 31 b.) Movement erratic; sometimes the animal swims steadily forward with mouth in front; again it shoots across the field of the microscope, either backward or forward or sideways, through the action of its powerful cirri.  It is often quiet, usually mouth downward, and is held in place by adhesion of the tentacles.  In this position it looks strikingly like a heliozooen.

Length 35 mu; greatest width 30 mu.  Not uncommon.

The chief features by which this species is distinguished from the frequently described M. pulex of Europe are the number of anterior cirri and the ring of true cilia in place of the central girdle of cirri.  The European form is described with four anterior bristles; the present form has from 28 to 32.  The radial cilia differ decidedly from the more powerful cirri and they are not in one plane, so that counting is difficult; they are not closely set.  The presence of tentacles makes these forms of especial theoretical interest, especially in the light of the origin of Suctoria.

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[Illustration:  Fig. 31.—­Side and top views of Mesodinium cinctum.]

Genus TIARINA R. S. Bergh ’79.

(Claparede & Lachmann ’58.)

Body subcylindrical, pointed posteriorly, two and one-half times as long as broad; encased in covering composed of separate pieces arranged in five girdles.  The pieces bear processes which rest against neighboring pieces of the girdle.  Mouth large, anus terminal near contractile vacuole.  The macronucleus is simple and round.  Salt water.

Tiarina fusus (Cl. & Lach.) emend R. S. Bergh.

Synonyms:  Coleps fusus Cl. & Lach. ’58; Daday ’86; Moebius ’88,
Lauterborn ’94; Shevyakov ’86.

This form, which resembles Coleps rather closely, was placed as a separate genus by R. S. Bergh.  The skeletal parts consist of five zones of needles composed of an organized substance and embedded in the cortical plasm, the last zone coming to a point at the posterior end.  The needles have lateral processes, which give a latticed appearance to the casing.  The cilia are long, with a specialized crown of still longer ones at the oral end; they arise outside of the skeletal elements and do not pass between them, as in Coleps.

KEY TO MARINE GENERA OF TRACHELINIDAE.

Diagnostic characters:  Body bilateral, or asymmetrical by local prolongations; usually compressed or flattened laterally, the left side more convex than the right.  The essential feature is the position and character of the mouth.  This is either a long slit extending from the anterior end well down the ventral surface, or the posterior part only of a ventral furrow remains open as a round or elongate mouth some distance from the anterior end.  The entire mouth region of the body is usually drawn out into an elongate tapering proboscis which is generally curved dorsally at the extremity.  An oesophagus is short or absent altogether; when present it is supported by a stiff buccal armature.  Cilia are uniform about entire body or limited to the flat right side.  Food is swallowed.

1. a.  Proboscis easily distinguished 2
      from the main body

   b.  Proboscis not marked off from Genus *_Loxophyllum_
      main body; body flat;
      both surfaces striated

2. a.  Mouth runs the entire length Genus Amphileptus
      of proboscis; entire body
      uniformly ciliated

   b.  Mouth runs the entire length Genus *_Lionotus_
      of proboscis; body flat; right
      side only is ciliated

   c.  Proboscis much drawn out, Genus Dileptus
      flexible; mouth at its base

   * Presence at Woods Hole indicated by asterisk.

Genus LOXOPHYLLUM Dujardin ’41.

(Duj. ’41; Wrzesniowski ’69; Quennerstedt ’65; ’67; Cohn ’66; Entz ’84; Gourret & Roeser ’88; Buetschli ’88; Shevyakov ’96.)

Page 25

The body is flat and somewhat leaf-shape, flexible, and elastic.  The anterior end is somewhat proboscis-like and flexible, but is not sharply demarcated as in Lionotus.  The central portion of the body is developed into a more or less arched dorsal mass, which usually contains the nuclei and contractile vacuoles.  As a result of this local thickening, the body is surrounded by a thin hyaline margin.  This, however, may be absent on the right side in some species.  The mouth reaches from the anterior extremity to a short distance from the end, and usually approaches the left edge.  An anus is present near the posterior end of the dorsal swelling.  Trichocysts are numerous on the ventral surface, and often on the dorsal surface, where they are inclosed in minute papilla-like swellings.  Cilia-distribution controverted.  Maupas and Buetschli hold that ventral surface alone is ciliated; others (Kent and Dujardin) that cilia are uniformly distributed.  The entire body, dorsal and ventral surfaces alike, are uniformly striated.  The contractile vacuole lies posteriorly, on the right side and in the dorsal swelling.  In the fresh-water form L. meleagris, it is connected with a long canal whose swellings are frequently taken for additional contractile vesicles (Buetschli); in the marine form described below the canal is not developed and a series of vacuoles takes its place; these are all contractile.  The macronucleus may be single, double, quadruple, band-formed, or rosette-formed.  Movement is steadily progressive and peculiarly gliding.  Fresh and salt water.

Loxophyllum setigerum Quenn. ’67.

Synonyms:  Litosolenus armatus Stokes ’93; Litosolenus verrucosa
Stokes ’93.

The body is flattened, irregular in outline, obtusely pointed anteriorly, the point being turned to the right; rounded posteriorly.  The left edge is nearly straight, the right considerably arched with a few setae on the posterior half.  Contractile vacuoles are numerous, dorsal in position and on the right side.  The macronueleus is beaded, the several spheres connected.

Variety armatum (Cl. & Lach.) Fig. 32.

Under the name Litosolenus armatus, Stokes described a form from brackish water near New York, which should unquestionably be referred to the genus Loxophyllum, and I believe to Quennerstedt’s species setigerum.  While the latter possesses only a few setae, the former has a number of them, and Stokes described his species as having a variable number.  For this reason I include the Woods Hole form under the tentative name armatum, as a variety of Quennerstedt’s L. setigerum.  The flat margins are distinctly striated longitudinally, and faintly marked radially, on the dorsal surface.  Longitudinal elevated striae also run the length of the dorsal hump and upon the entire ventral surface.  The ventral surface is alone ciliated.  Upon the edges of the flat border are sharp-pointed, colorless,

Page 26

spine-like processes, situated at equal distances around the entire periphery except at the anterior end.  Each spine is thick at the base and tapers to a full point which is curved upward—­i. e., dorsally (fig. 32, a, b).  The entire body is plastic and contractile, turning its leaf-like edge readily over objects upon which it creeps.  The cilia are fine and uniform, with a tendency to lengthen in the oral region.

Length 100 mu; greatest width assumed on contraction 85 mu; when normal about 50 mu.

[Illustration:  Fig. 32.—­Loxophyllum setigerum, var. armatum. a, b, c, ventral, dorsal, and lateral aspects.]

Genus LIONOTUS Wrzesniowski ’70.

(Incorrectly called Litonotus by many.  Entz ’84; Gruber ’84;
Buetschli ’88; Kent ’81; Schewiakoff ’89; Shevyakov ’96.)

The body is elongate and somewhat lance-shaped, widest at the central part and tapering to a point at the anterior end.  The posterior end may be similarly tapered or rounded.  The anterior end frequently proboscis-like, flat, and flexible, while the entire body is more or less elastic and contractile.  The right side is flattened and alone provided with cilia, while the left side of the body proper is arched; on the left side of the proboscis is a row of coarse cilia resembling an adoral zone, and a row of trichocysts.  A long peristome stretches down the thin, ventral side of the proboscis, and the mouth proper is situated at the junction of the proboscis and body; the mouth, as a rule, is invisible.  The ciliated right side alone is striated in the majority of species.  The contractile vacuole may be single or multiple, usually in the posterior region of the body and dorsal in position.  The macronucleus is usually double, rarely single or quadruple, but may occasionally break into numerous smaller pieces.  Movement, free-swimming or gliding, with especial tendency to get under clumps of foreign matter.

Fresh and salt water.

Lionotus fasciola Ehr.  Fig. 33.

Synonyms. Amphileptus fasciola Ehr. ’38; Dujardin ’41; Lachmann
          ’56; Cohn ’66, Diesing ’65.
          Loxophyllum fasciola Claparede & Lachmann ’58;
          Balbiani ’61.
          Loxophyllum duplostriatum Maupas ’83.  Shevyakov ’96.

Body frequently brown or brilliant yellow in color, somewhat sigmoid in form with tapering anterior end, the extremity of which is turned dorsally.  The proboscis is about half the entire length and is not sharply marked from the rest of the body but tapers gradually, its base being equal to the diameter of the body at its middle point.  The body is slightly contractile and the posterior end is carried to a rounded point, but not into a distinct tail.  Unlike the fresh-water variety, this one has no hyaline margin nor hyaline caudal region, and the contractile vacuole is double or multiple on the dorsal side near the posterior end.  Cilia are present only on the under

Page 27

(right) side, with, however, a row of large cilia marking the course of the elongate mouth, upon its left side.  The right side is striated, the left arched and without markings.  The endoplasm is finely granular with, however, larger food particles in the process of digestion, while specimens are occasionally seen with the natural form completely lost through distortion caused by over-large captures (Cf. also Wrzesniowski ’70, p.  XXIII, fig. 32).  Movement continuous, slow, and gliding; very little tendency to jerking movements.  Macronucleus double, both parts spherical, and placed in about the center of the larger part of the body; closely approximated but not, as Schewiakoff described, connected.  In conjugation, a large form unites with a smaller one, the mouth parts being connected.  Details of conjugation and macronuclei not made out.  Length 200 mu to 600 mu.

[Illustration:  Fig. 33.—­Lionotus fasciola.]

KEY TO MARINE GENERA OF CHLAMYDODONTIDAE.

Diagnostic characters:  Form usually ellipsoid, never very elongate.  Transverse section of body circular or elliptical.  The mouth is usually some distance from the anterior end and may be in the posterior part.  Sometimes it is in the center of the ventral surface, again on the right side.  The oesophagus invariably has a well-developed buccal armature, or a smooth peculiarly built oesophageal tube.  Food particles of large size.

1.  Body cylindrical.  Cilia about Genus *_Nassula_
   entire body

   Body flat 2

2. a.  Without a caudal process 3

   b.  With a caudal process 5

3. a.  Anterior end angular 4
      on left side

   b.  Anterior end rounded Genus Chlamydodon

4. a.  Dorsal striae and cilia present, Genus Orthodon
      ventral cilia longer

   b.  Dorsal striae and cilia absent; Genus *_Chilodon_
      posterior end not pointed

   c.  Dorsal striae and cilia absent; Genus Scaphidiodon
      posterior end pointed

5. a.  Caudal spine with posterior 6
      bristle-like cilia

   b.  Caudal spine without posterior Genus Trochilia
      bristle-like cilia;
      ventral cilia reduced

6. a.  With pigment spot on anterior Genus AEgyria
      angle

   b.  Without such pigment spot Genus Onychodactylus

   c.  Cilia on right edge only of Genus *_Dysteria_
      greatly reduced ventral surface

   * Presence at Woods Hole indicated by asterisk.

Genus NASSULA Ehr. ’33

(Dujardin ’41; Stein ’67; Cienkowsky ’55; Cohn ’66; Clap. et Lach. ’58; Kent ’81; Maupas ’83; Entz ’84; Fabre-Domergue ’88; Buetschli ’88; Shevyakov ’96.)

Page 28

The body is ovoid or cylindrical, with well-rounded ends, and in some cases slightly flattened.  The mouth is ventral and placed some distance from anterior end (1/4 to 1/3 total length).  A slight depression on the ventral surface marks the mouth region, which is further indicated by larger and more powerful cilia.  The rest of the body is uniformly ciliated.  The entire body is marked by clearly defined spiral stripes.  The mouth is circular and the oesophagus is supported by a considerable armature, which usually extends dorsally and to the left, rarely to the right.  In some cases the structure of this armature is indistinct; again it can be clearly seen to consist of definite rods (Staebchen).  The anus is probably always terminal.  Contractile vacuoles are variable in different species.  In some cases there is but one, which is placed at the posterior end or centrally on the ventral side; in others there may be four—­two dorsal and two ventral.  In many cases trichocysts are uniformly distributed.  Sometimes the body is colorless; again, and more often, it is brightly colored with red, blue, brown, or black pigment.  The macronucleus is globular and central, occasionally band-form and with numerous attached micronuclei.  Food substance varied, usually vegetable matter, see, however, below.  Cysts are globular.  Movement is a steady progression, combined with rolling.

Nassula microstoma Cohn ’66.  Fig. 34.

Synonyms:  Paramoecium microstomum Cl. et Lach. ’58, Gourret et
Roeser ’88; Isotricha microstomum Kent ’81.

Body subcylindrical, rounded at each extremity, not quite twice as long as broad.  A slight depression on one surface marks the position of the mouth, this depression being indicated by a row of longer cilia.  The mouth is extremely small and is surrounded by a curious buccal armature.  This is not made up of bars or rods, as in most species of Nassula, but appears perfectly smooth and uniform except for the considerable swelling at the inner end.  The cuticle is firm and unyielding and marked by longitudinal and somewhat spiral rows of cilia and trichocysts.  Under the microscope this is one of the most pleasing forms found at Woods Hole.  Its color is yellowish brown from the presence of brilliant particles of coloring matter held in the cortical plasm, and, as it slowly rolls along, these particles and the black trichocysts give to the organism a peculiar sparkling effect.  The macronucleus is almost central; the contractile vacuole posterior.  The endoplasm appears well filled with food bodies, some of which could be distinguished as Amphidinium and Glenodinium.

Length 55 mu; greatest diameter 30 mu.

[Illustration:  Fig. 34.—­Nassula microstoma.]

Genus CHILODON Ehr.

(Dujardin ’41; Engelmann ’78; Stein ’54, ’58; Kent ’81; Buetschli ’88;
Gruber ’83; Cienkowsky ’55; Moebius ’88; Clap. et Lach ’58;
Wrzesniowksi ’65; Shevyakov ’96.)

Page 29

Small forms, greatly flattened dorso-ventrally and almost egg-form in outline.  The anterior end is bent distinctly to the left and forms a characteristic process, which, together with the entire margin of the body, is soft and flexible.  The posterior end is, as a rule, broadly rounded.  The ventral surface is finely striate, and this surface alone is ciliated.  The lines of cilia converge at the mouth, and at this region the cilia are somewhat larger and more distinct, thus forming a functional adoral zone.  The mouth is median and is situated in the anterior half of the body.  It is surrounded by a well-defined armature, composed usually of from 10 to 16 rods.  The contractile vacuoles are quite varied and from one to many in number, the number increasing with the size of the individual.  The macronucleus is usually single, elliptical in form, and centrally placed; one micronucleus.  Reddish granular pigment and trichocysts are occasionally present.

Chilodon cucullulus Muell., sp.  Fig. 35.

Synonyms; Colpoda cucullus O. F. Mueller; Loxodes cucullulus; Chilodon uncinatus Ehr. ’58, Perty ’52, Dujardin ’41; L. dentatus Duj., etc.

This extremely variable form has received so many different names that it hardly pays to enumerate them.  It is one of the commonest and most widely spread ciliates known, although at Woods Hole I was surprised to see it so rarely.  It is the type species of the genus and needs no further description.  The specimens observed at Woods Hole had numerous contractile vacuoles and were 42 to 45 mu long and from 28 to 32 mu wide.

[Illustration:  Fig. 35.—­Ventral and dorsal aspects of Chilodon cucullulus.]

Genus DYSTERIA Huxley ’57.

(Cl. et Lach. ’58; Entz ’84; Moebius ’88; Shevyakov ’96.)

Small forms, firm in outline, and colorless or slightly colored.  The body is somewhat clam-shaped, flattened, slightly curved or straight on the right side, the other more convex.  The true ventral side is only a narrow strip along the right and anterior edge of the body, the apparent ventral side being a fold of the very large dorsal surface which comes around ventrally, forming a valved structure somewhat analogous to a clam shell.  Cilia are limited to the outer edge of the small ventral surface, which also bears a peculiar spine at the posterior end.  Behind this spine are larger cilia.  The mouth opening lies in the anterior widened portion of the ventral surface and is connected with a smooth tubular pharynx.  The right half of the dorsal side, i.e., the apparent dorsal side, is arched and bears longitudinal ridges.  Two to four contractile vacuoles are placed on the ventral side.  The macronucleus is usually dorsal, elliptical, and cleft, with one micronucleus attached.  Fresh and salt water.

Dysteria lanceolata Cl. et Lach.  Fig. 36.

Synonym:  Cypridium lanceolatum Kent ’81.

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Outline of the flattened body ovoid; body consists of two valve-like portions; the edge of the right valve is nearly straight, that of the left valve more or less sinuous; anteriorly it is cut away, obliquely and posteriorly it has a deep indentation in which the seizing spine rests.  The cilia are confined to the ventral surface, here reaching, however, from the anterior dorsal extremity to below the posterior indentation.  Posteriorly the cilia become larger, corresponding to the larger cirri of D. armata, which are posterior to the spine.  The mouth lies between the two valves and is surrounded by a long and smooth buccal armature which passes downward and backward to the left a distance equal to about half the entire body length.  The macronucleus is situated in the dorsal region in the central part of the body.  There are two contractile vacuoles, one behind the center of the buccal armature, the other near the inner end of this organ.  Movement is in circles, the animal moving around quite rapidly when not attached by its posterior process.  It is colorless and measures 45 mu in length by 27 mu in width.  Claparede & Lachmann and Shevyakov describe it as 70 mu long.

[Illustration:  Fig. 36.—­Dysteria lanceolata.]

KEY TO MARINE GENERA OF CHILIFERIDAE.

Diagnostic characters:  Mouth never lies behind the middle of the body; the oesophagus is but slightly developed.  The undulating membranes are placed either on the edge of the mouth or in the oesophagus.  A peristomial depression leading to the mouth is absent or very slightly indicated.

1.  Mouth in the anterior half, Genus *_Frontonia_
   undulating membrane on left edge
   only; right edge continued in a
   long ventral furrow

2.  Two undulating membranes; mouth Genus *_Colpidium_
   central; no caudal bristles

3.  Two undulating membranes; caudal Genus *_Uronema_
   bristle

Genus FRONTONIA Ehr. (Cl. & Lach. ’58?).

(Ehrenberg, subgenus of Bursaria ’38; Claparede & Lachmann ’58;
Buetschli ’88; Shevyakov ’96.)

Form elongate and cylindrical, or often flattened dorso-ventrally, with round or pointed ends.  It is usually plastic and contractile.  Cilia are evenly distributed about the body and are similar in length.  The large, open mouth lies on the anterior half of the ventral surface, and is elongate and oval in outline.  On its left edge is a well-defined membrane which stretches across to the right side of the mouth.  On the right edge is a small, longitudinally striped tract which is free from trichocysts and smooth in appearance.  This tract is continued posteriorly in a long furrow, which in some cases reaches the posterior end of the animal.  A few rows of cilia in this furrow vibrate differently from the others and give the effect of a membrane (Buetschli).  The oesophagus is extremely short and hard to make

Page 31

out.  The body is usually covered uniformly with trichocysts, often of considerable size.  There are 1 or 2 vacuoles with long canals radiating throughout the endoplasm.  The macronucleus is oval and centrally placed.  Micronuclei vary from one to many.  An anal opening is placed at the end of the long ventral furrow.  The plasm is colorless or green by the presence of Zoochlorella, or colored brown or black by pigments.  In these cases there is a considerable pigment mass on the anterior end.  Movement is regular, forward, and combined with rotation.  Food consists of foreign objects, diatoms, other protozoa and the like.  Fresh and salt water.

Frontonia leucas Ehr.  Fig. 37.

Synonyms:  Frontonia vernalis Ehr. ’38; Bursaria leucas Allman ’55, Carter ’56; Panophrys leucas Duj. ’41, Stein ’67; Panophrys vernalis Dujardin ’41, Stein ’67; P. chrysalis Duj. ’41, Fromentel ’74; Cyrtostomum leucas Stein ’67, Kent ’81.

Form ovoid, elongate, occasionally a little flattened dorso-ventrally.  Mouth in the anterior third of the body.  The left edge of the mouth carries a distinct undulating membrane; the right edge is plain, longitudinally striated and bears cilia.  It is slightly depressed and the depression is carried posteriorly in the form of a shallow furrow which reaches to the posterior end.  The contractile vacuole is on the left side, the spheroidal nucleus on the right side of the furrow.  The body is uniformly covered with fine cilia, and the periphery is uniformly studded with large trichocysts, except along the furrow.  Food consists of dinoflagellates and other small forms.  Color dark brown to black.

Length 330 mu; width 200 mu.

This form differs considerably from the fresh-water Frontonia leucas as described by Schewiakoff ’89, especially in the extreme length of the peristomial furrow, in the position of the nucleus and contractile vacuole, and in the nature of the water canals.  These in the Woods Hole form are very irregular in size and very much branched, not uniform as in Lieberkuehn’s (see Buetschli) figure of Frontonia leucas, nor radiating as in Schewiakoff’s description.  This may be the same species as Frontonia marina, of Fabre-Domergue ’91, whose description and figure I have not seen.

[Illustration:  Fig. 37.—­Frontonia Leucas.]

Genus COLPIDIUM Stein ’60

(Buetschli ’88; Maupas ’83.)

The general form is oval, slightly compressed laterally with the dorsal side strongly arched.  The ventral side is slightly incurved.  The anterior end is somewhat smaller than the posterior end, which is broadly rounded.  The mouth is placed some distance from the anterior end in an oral depression and opens into a tubular oesophagus.  There are usually two undulating membranes which do not extend beyond the mouth borders.  The right undulating membrane extends down into the oesophagus and appears to be attached to the walls of the latter.  The body stripes in front of the mouth are twisted to the left.  The anus is terminal and the contractile vacuole may be terminal or situated forwards in the dorsal region.  The macronucleus is spherical and has one micronucleus attached.  Food consists mainly of bacteria.  Movement rapid, but interrupted.

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Fresh and salt water, common in infusions.

Colpidium colpoda Ehr., sp.  Fig. 38.

Synonyms:  Colpidium cucullus Kent ’81; C. striatus Stokes ’85; Kolpoda cucullus Duj. ’41; Paramoecium colpoda Ehr. ’38, Quennerstedt ’67; Plagyiopyla nasula Kent ’81, G. & R. ’86; Glaucoma pyriformis G. & R. ’86; Tillina campyla Stokes ’85, ’88.

The body is oval, somewhat larger posteriorly, and a little compressed dorso-ventrally.  The anterior end is twisted a little from the right to the left (more evident in fresh-water forms), and leans somewhat toward the ventral side.  Under this portion, on the ventral side, lies the mouth in a large depression just above the middle of the body.  The entire body is covered with uniform and delicate cilia, which are placed in longitudinal rows.  These rows are almost straight on the dorsal side, but bend on the ventral surface, following the contour of the twisted anterior portion.  The endoplasm is finely granular; the oesophagus leading into it is very distinct.  Schewiakoff (’89) describes two membranes, an inner and an outer; Maupas (’83) describes them as right and left.  In the present species I was able to make out only one.  The macronucleus is central, spherical in form, and bears a single minute micronucleus.  The contractile vacuole is posterior and dorsal to the long axis of the body.  The anus is ventral to this axis and also posterior.  Length 45 mu, width 20 mu.  Common.

This marine variety is much smaller than the fresh-water form and the form differs in a number of respects, viz, in the anterior torsion and in the structure of the mouth.  These may be, however, only individual variations of a widely spread species, and I believe it is perfectly safe to describe this as Colpidium colpoda.

[Illustration:  Fig. 38.—­Colpidium colpoda.]

Genus URONEMA Duj. ’41.

(Quennerstedt ’69; Cohn ’66; Kent ’81; Buetschli ’81; Schewiakoff ’89;
Shevyakov ’96.)

Minute forms; colorless and constant in body form.  The form is oval, slightly compressed on the ventral side, while the dorsal side is distinctly arched.  The membrane is distinctly marked by rather widely separated striae.  These occasionally have a spiral course about the body; in all cases they can be easily counted.  The mouth is large and placed near the center of the ventral surface.  It is sometimes approached by a very shallow depression or peristome from the anterior end, and marked by two rows of cilia.  An undulating membrane extends down the mouth.  Oesophagus absent.  A long, stiff bristle extends outwards from the posterior end.  The contractile vacuole is terminal or subterminal and near the anal opening.  The macronucleus is spherical, centrally placed, and with one micronucleus closely applied.  Movement is rapid and usual forwards in a straight line, often found resting, however, with outstretched cilia in contact with some foreign body.  Food mainly bacteria.  Fresh and saltwater, usually in decomposing vegetable substances.

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Uronema marina Duj.  Fig. 39.

Synonyms:  Enchelys triquetra Dujardin; E. corrugata Duj.; Cryptochilum griseolum Maupas ’83; Philaster digitiformis Fabre-Domergue ’85.

Small animals with ellipsoidal form and about twice as long as broad.  The mouth lies in the upper half of the body and bears a well-developed undulating membrane upon its left edge.  The membrane is longitudinally striped and covered with long and vibratile cilia.  The right edge of the mouth bears cilia which are about the same in size as the body cilia, but are more closely inserted (Schewiakoff).  The most characteristic feature is the long caudal bristle, which is extremely delicate and about two-thirds the length of the body.  Schewiakoff thinks this bristle has a sensory function.  I could not make this out, for although other protozoa ran against this bristle, often bending it well over to one side, the animal showed no sign of irritability but lay quiescent.  A spherical macronucleus with attached micronucleus lies in the center of the body.  The contractile vacuole is posterior in front of the bristle.  The macronucleus was found to be double, as though just divided, in a large percentage of cases.  This may be a precocious division of the nucleus long before signs of the body division are evident.  Such a phenomenon, however, is rare, the macronucleus usually dividing at a late stage of cell division.  Length 30 to 50 mu; width 15 to 20 mu.  Common in decomposing algae.

[Illustration:  FIG. 39.—­Uronema marina.]

KEY TO MARINE GENERA OF PLEURONEMIDAE.

Diagnostic characters:  The mouth is at the end of a long peristome running along the ventral side; the body is dorso-ventrally or laterally compressed.  The entire left edge of the peristome is provided with an undulating membrane which occasionally runs around the posterior end of the peristome to form a “pocket” leading to the mouth.  The right edge of the peristome is provided with a less-developed membrane.  There may or may not be a well-developed pharynx.

Body small; not produced into Genus *_Pleuronema_ neck-like elongation

Body medium-sized; anterior end Genus *_Lembus_ produced into neck-like elongation

   * Presence at Woods Hole indicated by asterisk.

Genus PLEURONEMA Dujardin ’41.

(Perty ’52; Clap. & Lach. ’58; Stein ’59, vol.  I; Quennerstedt ’67;
Kent ’81; Buetschli ’88; Schewiakoff ’89; Shevyakov ’96.)

Small to medium-sized ciliates, with an unchanging form.  They are somewhat lens-shape and laterally compressed, the two surfaces about equally arched.  The ventral surface is nearly straight or but slightly arched; the dorsal is quite convex.  The anterior and posterior extremities are equally rounded.  The peristome begins as a small depression, but becomes larger until it takes in nearly all of the ventral

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surface.  The depression becomes much deeper at about the center of the body, and is especially marked on the left side of the peristome.  In this deeper portion is the mouth, with an almost imperceptible oesophagus.  Upon the left edge of the peristome is a high, undulating membrane, sail-like in appearance when extended.  This may stretch around the posterior edge of the peristome and upon the right aide, thus forming a pocket by means of which the food particles are directed into the mouth.  The rest of the right edge of the peristome is occupied by closely approximated powerful cilia (Buetschli) or a second undulating membrane (Stein).  The body cilia are relatively long.  Trichocysts and caudal bristles may be present.  The contractile vacuole is subterminal and dorsal; it is questionable whether there are canals leading to it.  A round macronucleus with one micronucleus is in the anterior half of the body.  The anus is terminal.  Food is chiefly bacteria.  Movement combines springing with swimming and rotation.  Fresh and salt water.

Pleuronema chrysalis Ehr., sp.  Fig. 40.

Synonyms:  Pleuronema crassa Dujardin ’41; P. marina Duj. ’41;
Fabre-Domergue ’85; P. coronata Kent ’81; Paramoecium chrysalis
Ehr. ’38; Lembadion orale G. & R. ’88; Histiobalantium agile
Stokes ’85, ’88.

The body is ovoid, slightly flattened, rounded at both ends, the anterior end sharper than the posterior.  The ventral surface is almost entirely taken up by a peristome which extends from the anterior end posteriorly three-quarters of the body length.  The posterior end of the peristome is straight, the left curved, following the depressed portion.  The body is covered with fine cilia in longitudinal lines, except on the peristome.  The mouth is small and situated in the hollow of the peristome near the left border.  On the left peristome edge is a large undulating membrane.  It begins near the anterior end of the body and increases in height posteriorly following the peristome edge around on the right side.  This posterior bend of the membrane causes the appearance of a full sail, so often seen.  It can be entirely withdrawn and folded together in the peristome.  On the right edge of the peristome are large, powerful cilia.  The contractile vacuole is central and dorsal; the macronucleus is in the anterior half of the body, with one attached micronucleus.  Food consists of bacteria.  Not very common.  Fresh and salt water.  It often remains quiet, with membrane and cilia outstretched, as though dead, but suddenly gives a spring and is gone.

[Illustration:  Fig. 40.—­Pleuronema chrysalis.]

Pleuronema setigera, n. sp.  Fig. 41.

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Body colorless, elongate, and with the general form of a cucumber, the posterior end being somewhat pointed.  The mouth and relatively small peristome are situated in the lower third of the body.  The peristome begins as a shallow furrow at the center of the ventral surface and dips sharply into the buccal depression, which is deep and turned toward the posterior end.  The left edge of the peristome bears a high undulating membrane, which extends anteriorly only as far as the center of the body; posteriorly it passes around to the right edge of the peristome, thus forming the characteristic membranous pocket.  Inside the oral depression is a second undulating membrane, running down to the mouth.  This is small and without an oesophagus.  The body is clothed with long setose cilia which are frequently fully outstretched when the animal is resting, a slight tremor of the large membrane alone indicating vitality.  Posteriorly these appendages are drawn out into long filiform setae, the number varying in different individuals from three to nine or ten.  These are extremely fine and difficult to see without a high power (e.g. 1/12 oil) and careful focussing of the substage condensor.  Like P. chrysalis, the resting periods are terminated by sudden springs, otherwise the movements are steady and forward.  The macronucleus is central, and the contractile vacuole posterior and terminal.  Length 45 mu to 50 mu; greatest diameter 17 mu.  In decaying algae.

It was this form, I believe, that Peck ’95 described as a “ciliate.”

[Illustration:  Fig. 41.—­Pleuronema setigera.]

Genus LEMBUS Cohn ’66.

(Cohn ’66; Quennerstedt ’69; Kent ’81; Fabre-Domergue ’85; Gourret &
Roeser ’88; Buetschli ’88; Shevyakov ’96.)

Free-swimming animals of elongate form, more or less elastic, and flexible, bending readily to avoid obstacles, etc.  The anterior half is usually drawn out into a slightly curved neck-like portion.  The peristome is a small groove leading from the anterior end to the mouth about midway down the ventral side of the body.  Buetschli, following Quennerstedt, describes an undulating membrane on each side of the peristome groove.  Other observers, however, usually describe but one, the left, which is clearly defined and stretches out some distance from the body, while the right border is described as having smaller but very active cilia.  The general body surface is clothed with fine, uniform cilia, and body striae are usually absent.  One or more caudal bristles may be present.  The contractile vacuole is posterior and terminal, and may be multiple.  The macronucleus is spherical and perhaps double (Kent).  Food is chiefly bacteria, and the animals are frequently found with the anterior end embedded in zoogloea masses.  Salt water, usually in infusions.

Lembus infusionum, n. sp.  Fig. 42.

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The body is elongate, lancet-shaped, with a tapering anterior extremity.  The dorsal outline is concave through the bending of the anterior end, while the ventral outline presents an even, convex curve.  The mouth lies slightly above the center of the body and marks the posterior limit of the ventral peristomial groove, which curves slightly from the anterior extremity.  Each side of this groove bears an undulating membrane, the left being much larger and conspicuously striated.  The general form of this left membrane is triangular, the widest part is anterior, the narrowest at the mouth.  The right membrane is similar in form, but smaller and more active.  The endoplasm is colorless and finely granular, not regionally differentiated.  The ectoplasm consists of a relatively thick cortical plasm specially noticeable in the posterior half of the body and a delicate cuticle which bears almost imperceptible longitudinal markings—­the insertion points of the fine cilia.  The body is covered with uniform cilia except at the anterior extremity.  Here they are much larger and bristle-like.  I was unable to find any cilia in the peristome.  One long caudal bristle, one-quarter of the length of the body, trails out behind.  The macronucleus is spheroidal and placed near the center of the body; a conspicuous micronucleus lies near it.  A row of contractile vacuoles extends from the posterior end.  I have seen as many as six of nearly equal size and one or two smaller ones.  The intervals of contraction are quite long.  Length 70 to 75 mu; greatest diameter 10 to 12 mu.

L. infusionum resembles L. elongatus in its general form and in its mode of life, for it excavates a retreat in zoogloea masses and lies there for considerable periods perfectly quiet.  It differs from L. elongatus and from L. velifer (probably the same as L. elongatus of Claparede & Lachmann) in the presence of the caudal bristle, in the absence of annular markings, number of contractile vacuoles, and in the slightly smaller size.  It resembles Lembus verminus (Mueller) as described by Kent (Proboscella vermina), and L. intermedius as described by Gourret & Roeser (Lembus verminus syn.)in the absence of annular markings and in the presence of a caudal bristle.  It differs from the former, however, in the absence of a tentacle-like process, and from both in the absence of a double nucleus and in the presence of many vacuoles.  These features are so characteristic of all the specimens examined that I have concluded, somewhat reluctantly, to give it a specific name.  It is common in old infusions of algae, especially after decomposition is well advanced.  Its food consists of bacteria.

[Illustration:  Fig. 42.—­Lembus infusionum.]

Lembus pusillus Quennerstedt 1869.  Fig. 43.

Synonym:  L. subulatus Kent 81.

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This species is much smaller than the preceding, and might easily be mistaken for Uronema marina.  It is subcylindrical in form, the anterior end bluntly pointed, the posterior end rounded.  The oral apparatus is quite different from Uronema.  The mouth, as in the preceding species, is at the end of a long peristomial groove extending from the anterior end to the middle of the body.  The edges of the peristome bear undulating membranes as in L. infusionum.  Like the latter, there is one caudal bristle, but unlike it there is only one posterior contractile vacuole, while the endoplasm is filled with large granules or food balls.  The cuticle is distinctly striated with longitudinal markings, and the cilia are uniform in length.

Habitat similar to that of L. infusionum, in zoogloea masses. 
Length 26 to 30 mu; diameter 7 to 8 mu.

Although Quennerstedt’s description of L. pusillus makes no mention of a caudal bristle, the size and other characters are so closely similar that I hesitate to make a new species.  The bristle is extremely delicate, scarcely thicker than a cilium, and easily overlooked, yet with proper focussing of the condenser I found it on every specimen examined.

[Illustration:  Fig. 43.—­Lembus pusillus.]

KEY TO MARINE GENERA OF OPALINIDAE.

Diagnostic characters:  The form is oval, and the body may be short or drawn out to resemble a worm.  They are characterized mainly by the absence of mouth and pharynx.

Anterior end not pointed; body Genus *_Anoplophrya_ cylindrical; tapering

Anterior end pointed; body elongate; Genus Opalinopsis cylindrical; tapering

   * Presence at Woods Hole indicated by asterisk.

Genus ANOPLOPHRYA Stein ’60.

(Stein ’60; Claparede ’60; Leidy ’77; Vejdovsky ’79; Kent ’81;
Balbiani ’85; Buetschli ’88; Shevyakov ’96.)

The general form is elongate, cylindrical or slightly flattened, with rounded ends, the posterior end tapering.  The body is striated with clearly defined, often depressed lines, which run longitudinally and sometimes spirally.  The contractile vacuoles are usually placed in rows upon the edges.  The macronucleus is almost always long and band-formed, rarely oval, and generally extending through the entire length of the body.  Micronuclei have been made out in one case.  Reproduction is effected by simple cross division or by budding at the posterior end, and is frequently combined with chain formation.  The main characteristic is the entire absence of mouth and oesophagus, the animals being parasitic in the digestive tract of various annelids.  Parasites, salt-water forms.

Anoplophrya branchiarum.  Stein ’52.  Fig. 44.

A. circulans Balbiani.

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The body is cylindrical to pyriform, in the latter case broadened anteriorly.  Cuticle distinctly marked by longitudinal striations which take the form of depressions and give to the body a characteristic melon shape.  The endoplasm contains a number of large refringent granules—­probably body products.  The nucleus is elongate, somewhat curved, and coarsely granular.  A micronucleus lies in the concavity.  The cilia are long, inserted rather widely apart along the longitudinal markings.  The contractile vacuole is single and is located at the pointed end, which is directed backwards during locomotion.  One specimen found free swimming among some algae.

Length 104 mu; greatest diameter 36 mu.

I was much surprised to find this form swimming about freely in the water; its mouthless condition showed it to belong to the family of parasites, the Opalinidae.  As the name indicates, however, this species is an ectoparasite upon the gills, and Stein gave the name branchiarum to a fresh-water form parasitic upon Gammarus pulex.  The Woods Hole form is so strikingly similar to the figure of G. branchiarum that, although the name was given to a fresh-water form, it obviously applies to this marine variety.  One important difference is the presence of only one contractile vacuole in the marine form.

[Illustration:  Fig. 44.—­Anoplophrya branchiarum.]

KEY TO FAMILIES OF HETEROTRICHIDA.

Cilia cover the body 1

Cilia reduced to certain 2
localized areas

1. Polytrichina.

   a.  The mouth terminates a long Family Plagiotomidae
      peristomial furrow having an
      adoral zone along the entire
      left edge

   b.  Peristomial area a broad Family Bursaridae
      triangular area ending in mouth

   c.  Peristomial depression short; Family Stentoridae
      limited to the anterior end; its
      plane at right angles to the
      long axis of body; surface of
      peristome striated and ciliated;
      no undulating membranes

2. Oligotrichina.

   a.  Peristome without cilia; cilia Family Halteriidae
      limited to one or more girdles
      about body

      One marine genus *_Strombidium_

   b.  Thecate forms; the body is Family Tintinnidae
      attached by a stalk to the cup;
      within the adoral zone is a ring
      of cilia.

   c.  The peristomial depression is Family Ophryoscolecidae
      deep and funnel-like; cuticle
      thick, with posterior spine-like
      processes.

   * Presence at Woods Hole indicated by asterisk.

KEY TO THE MARINE GENERA OF PLAGIOTOMIDAE.

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Diagnostic characters:  The peristome is a narrow furrow which begins, as a rule, close to the anterior end and runs backward along the ventral side, to the mouth, which is usually placed between the middle of the body and the posterior end.  A well-developed adoral zone stretches along the left side of the peristome, and is usually straight.

1.  Body cylindrical; size medium; Genus Metopus
   peristome long and turns sharply
   to the left at the extremity

2.  No torsion in the peristome; Genus Blepharisma
   undulating membrane is confined
   to the posterior part of peristome

3.  No peristomial torsion; Genus Spirostomum
   body highly contractile;
   no undulating membrane

KEY TO THE MARINE GENERA OF BURSARIDAE.

Diagnostic characters:  The body is usually short and pocket-like, but may be elongate.  The chief characteristic is the peristome, which is not a furrow, but a broad triangular area deeply insunk and ending in a point at the mouth.  The adoral zone is usually confined to the left peristome edge, or it may cross over to the right anterior edge.

1.  The anterior half of the body Genus Balantidium
   tapers to nearly a point in front;
   the peristome is narrowest at the
   apex; the mouth is the entire
   peristome base.

2.  The anterior end does not taper; Genus *_Condylostoma_
   the peristome is widest at the end
   of the body; the mouth is clearly
   defined.

   * Presence at Woods Hole indicated by asterisk.

Genus CONDYLOSTOMA (KONDYLOSTOMA Bory de St. Vincent 1824) Dujardin ’41

(Dujardin ’41; Claparede & Lachmann ’58; Stein ’59, ’67; Cohn ’66; Quennerstedt ’67; Wrzesniowski ’70; Buetschli ’76, ’88; Kent ’81; Maupas ’83; Shevyakov ’96.)

Colorless and more or less flexible animals of medium size.  The general form is elongate and cylindrical or somewhat smaller anteriorly.  The posterior end is broadly rounded, the anterior end somewhat truncate and oblique.  The peristome is broad and triangular, the base of the triangle being the entire anterior end of the body.  The entire length of the peristome is one-fourth or less of the body length.  The mouth is large and placed at the apex of the peristomial triangle and opens into a comparatively small oesophagus.  The right edge of the peristome is lamellate and bears a clearly defined undulating membrane.  The adoral zone is well developed upon the left edge of the peristome, from which it passes around anteriorly to the right edge.  The surface of the peristome is free from cilia, but the rest of the body is uniformly coated with small active cilia.  Contractile vacuoles are not safely determined.  Buetschli thinks there is probably one terminal vacuole, but some observers

Page 40

deny this (e.g. Maupas).  Others describe them on the dorsal side of the posterior end (Quennerstedt).  The macronucleus is long and beaded and placed upon the right side.  Micronuclei are numerous and scattered along the macronucleus.  The anus is terminal and dorsal.  Food consists of large and small particles.  Movement rapid, free swimming, alternating with resting periods; in some cases an undulating or wriggling movement is seen, showing clearly the flexibility of the body.  Fresh and salt water.

Condylostoma patens Mueller.  Fig. 45.

The body is elongate, somewhat sac-like, five or six times as long as broad, plastic, and frequently contains brightly colored food granules.  The triangular peristome takes up the greater part of the anterior end, and the mouth is situated at the sharper angle of the triangle, about one-fourth of the total length from the anterior end.  The cuticle is longitudinally striated, the lines having a slightly spiral course.  They are not closely set, and fine cilia are thickly inserted along their edges.  The endoplasm is granular and viscous.  The motile organs consist of an adoral zone of membranelles, which stretch along the left edge of the peristome and the front edge of the body.  The right edge of the peristome supports an undulating membrane.  The nucleus is moniliform and extends the full length of the left side; a number of micronuclei are distributed along its course (Maupas).

Length 400 mu; diameter at widest part 105 mu.  Maupas gives the length from 305 mu to 495 mu; and Stein 376 mu to 564 mu.  Very common.

For a more extended account of the structures, see the excellent description by Maupas ’83.

[Illustration:  Fig. 45.—­Condylostoma patens.]

KEY TO THE MARINE GENERA OF STENTORIDAE.

Diagnostic characters:  The peristome is relatively short and limited to the front end of the animal, so that its plane is nearly at right angles to that of the longitudinal axis of the body.  The adoral zone of cilia either passes entirely around the peristome edge or ends at the right-hand edge.  The surface of the peristome is spirally striated and provided with cilia.  Undulating membranes are absent.

1.  Peristome circular in outline; Genus Stentor
   limited to the anterior end

2.  The peristome is drawn out into two Genus Folliculina
   wing-like processes; tube-dwelling

Genus STROMBIDIUM Cl. & Lach. ’58.

(Stein ’67; Buetschli ’73; Fromentel ’74; Kent ’81; Gruber ’84; Entz ’84; Maupas ’83.  Buetschli ’88.)

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Small, colorless (except for ingested food) animals with characteristic springing movements.  The form is usually constant, but in some cases may be plastic like Astasia; it is usually globular or conical, the posterior end being more or less pointed, the anterior end broadest.  The latter is surrounded by a complete circle of the adoral zone, the oral end of which passes into a peristomial depression which extends deep into the middle of the body.  The mouth, with a very small oesophagus, lies at the bottom of the inturned peristome.  The region surrounded by the adoral zone is frequently drawn out into an anterior process, occasionally bearing a pigment mass.  The ventral surface in some cases bears cilia, which may be distributed or restricted to a row of large cilia.  Trichocysts are usually present and may be widely spread, limited to the posterior region, or arranged in a girdle about the middle.  The contractile vacuole is simple, and posterior in position.  The macronucleus is spherical and usually central in position.  Movement is rapid swimming, combined with resting and floating periods, the latter usually terminated by a sudden leap.

Fresh and salt water; more common in the latter.

Strombidium caudatum Fromentel ’74.  Fig. 46, a, b, c.

Fromentel described a fresh-water form of this genus with a caudal appendage.  The body is pyriform, broadly truncate on the anterior end, in the middle of which rises a papilliform process (Schnabel).  On this process is a heap of pigment granules, which, however, are not constant.  A ring of long cirri surround the anterior end and pass into the peristome, and from the left edge of this line of cirri a large adoral zone continues down to the mouth.  The peristome is elongate and sac-form, and the mouth lies at the posterior extremity.  With the exception of a caudal filament there are no other motile organs; this is about half as long as the body, structureless, hyaline, and sharply pointed.  It splits up into a bundle of fine fibers upon treatment with caustic potash (c).  The cirri emerge from minute hollows in the edge of the anterior border.  The cortical plasm contains peculiar rod-like bodies, which look more like lines or markings than like rods or trichocysts.  The nucleus is large, spherical, and placed in the center of the body.  The contractile vacuole is posterior.

Length without appendage is about 35 mu; greatest diameter 15 to 18 mu. 
In decaying vegetable matter.  Common.

[Illustration:  Fig. 46.—­Strombidium caudatum.]

Although Fromentel’s species is incompletely described, it is very evident that the organism corresponds fairly well with the Woods Hole variety.  His was a fresh-water type; this is marine, but the caudal filament and the contractile vacuole are similar.  Certainly in this case the organism can not be regarded as a Vorticella broken off its stalk, as Kent ’81 suspected.  The anterior process with its pigment spot; the cirri, the spherical nucleus, the position of the vacuole, etc., are all opposed to such an interpretation which Kent applied to the original species.  Neither can it be a Tintinnoid.  I place it provisionally as S. caudatum.

Page 42

KEY TO THE MARINE GENERA OF TINTINNIDAE.

Diagnostic characters:  Body attached by a stalk to a cup.  Inside the zone of membranelles is a ring of cilia (par-oral).

1.  The test is gelatinous and more or Genus Tintinnidium
   less covered by foreign particles

2.  The test is chitinous and clear.  Genus Tintinnus
   No foreign particles.

3.  The test is chitinous; covered by Genus *_Tintinnopsis_
   foreign particles, growth rings
   frequent

4.  The test is chitinous, often Genus Codonella
   covered by foreign particles. 
   The test is marked by discoid,
   circular, or hexagonal spots.

5.  The test is perforated by pores Genus Dictyocysta
   of circular or hexagonal form.

   * Presence at Woods Hole indicated by asterisk.

Genus TINTINNOPSIS Stein ’67.

(Stein ’67; Kent ’81; Daday ’87; Buetschli ’88.)

Medium-sized ciliates, inclosed in a chitinous lorica with embedded sand crystals.  The form of the house, or lorica, varies greatly.  In some cases the mouth opening is wide, giving the lorica a bell form; it may be long and tubular, short and spherical, or variously indented.  The animal is attached, as in the closely allied genus Tintinnus, by a peduncle to the bottom of the lorica.  The anterior end of the animal is inclosed by two complete circles of cilia; one, the outer, forming the adoral zone, is composed of thick tentacle-like membranelles, the other consists of shorter cilia within the adoral zone.  The mouth leads into a curved oesophagus containing rows of downward-directed cilia (Daday).  The entire body is covered with cilia, but as the lorica is always opaque these can be made out only when the animal is induced to leave the house.  The only difference between this genus and Tintinnus is the covering of foreign bodies—­usually sand crystals.  Movement is rapid and restless, and peculiarly vibratory, owing to the apparent awkwardness in moving the house.  Salt water.

Tintinnopsis beroidea Stein, var. plagiostoma Daday.  Fig. 47.

Synonym:  Codonella beroidea Entz ’84.

The shell is colorless, thimble-shaped, with a broadly rounded posterior end.  The body is cylindrical.  The internal organs were not observed.  Membranelles 24 in number.  Length 50 mu; greatest diameter 40 mu.

[Illustration:  Fig. 47.—­Tintinnopsis beroidea.]

Var. compressa Daday ’87.

The posterior end of the shell is pointed, the lower third of the shell is swollen, the upper third is uniform in diameter and without oral inflation or depression.  Nucleus not seen.

Length 70 mu; greatest diameter 48 mu.

Tintinnopsis davidoffi Daday.  Fig. 48.

The shell is large, elongated, and provided with a considerable spine.  The chitin of the shell is covered with silicious particles of diverse size.  The internal structures were not observed.

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Length of shell and spine 230 mu; diameter of the oral aperture 54 mu.

[Illustration:  Fig. 48.—­Tintinnopsis davidoffi.]

The variations of these species are considerable, and as the internal structures, such as the nucleus, are essential in fixing their systematic position, I place them as above, provisionally, and until further observations can be made.

KEY TO FAMILIES OF HYPOTRICHIDA.

a.  Peristome indistinct; cilia on Family Peritromidae
   ventral surface uniform and not One genus, *_Peritromus_
   differentiated into cirri

b.  Peristome more or less indistinct; Family Oxytrichidae
   cilia reduced to a few rows on the
   ventral surface; anal and frontal
   cirri present

c.  Cilia entirely reduced; frontal Family Euplotidae
   and anal cirri present or reduced;
   macronucleus band-formed or spherical

d.  Peristome reduced to left edge and Family Aspidiscidae
   does not reach over the anterior One genus, *_Aspidisca_
   margin

   * Presence at Woods Hole indicated by asterisk.

Genus PERITROMUS Stein ’62.

(Stein ’62, ’67; Maupas ’83.)

The body is flat, colorless or tinged with yellow, and contractile.  It is elliptical in outline, with broadly rounded ends; in some cases the left edge is slightly incurved, the right edge convex.  The ventral surface is flat, the dorsal surface is arched in the middle region of the body.  The edges being flat are somewhat more transparent than the remainder of the body.  The ventral surface is striated by longitudinal straight or slightly curved lines, the dorsal surface is smooth and without cilia. (Maupas describes bristles on the back, but this is not corroborated.) The adoral zone is fairly well developed, but not distinctly marked off from the remaining ventral surface.  It begins on the right side and extends entirely around the frontal margin and down the left side below the middle of the body, where it turns suddenly to the right, entering the slightly insunk peristome.  The mouth leads into a short, indistinct oesophagus.  One contractile vacuole is situated in the dorsal swelling at the posterior end of the animal.  Macronucleus double, one in each side of the dorsal swelling.  Movement is slow and creeping, with a peculiar method of contracting the more hyaline edge, which may turn upward or around a foreign object.

Fresh (?) and salt water.

Peritromus emmae Stein.  Fig. 49.

With the characters of the genus.

[Illustration:  Fig. 49.—­Peritromus emmae, ventral and lateral aspects.]

KEY TO THE MARINE GENERA OF OXYTRICHIDAE.

Page 44

Diagnostic characters:  The peristome is not always marked off from the frontal area.  In the most primitive forms the cilia on the ventral surface are similar to those of the preceding family (Peritromidae).  Usually some of the anterior and some of the posterior cilia are fused into cirri, distinguished as the frontal and anal cirri, respectively.  In the majority of forms all of the cilia are thus differentiated; strong marginal cirri are formed in perfect rows, and ventral cirri in imperfect rows.  In addition to the adoral zone there is an undulating membrane on the right side of the peristome, and in some cases a row of cilia between the membrane and the adoral zone.  These are the par-oral cilia and they form the par-oral zone.

1.  The posterior end is pointed or 2
   tail-like

   The posterior end is rounded; 5
   not tail-like

2.  The front end is pointed 3

   The front end is rounded 4

3.  Frontal and anal cirri absent; Genus Stichotricha
   often tube-forming

   Eight frontal and 3 caudal cirri; Genus Gonostomum
   not tubiculous

4.  Anal cirri present; with or Genus *_Epiclintes_
   without short lateral bristles

   Anal cirri absent; no bristles Genus Uroleptus

5.  With frontal cirri 6

   No frontal cirri; 2 to 3 rows of Genus Holosticha
   ventral cirri; anal cirri small

6.  Right margin of peristome straight Genus Oxytricha
   as far as the anterior end; 5 rows
   ventral cirri; 5 anal cirri

   Right margin of peristome curved 7

7.  Five rows or less of ventral cirri 8

   More than 5 rows of ventral cirri Genus Urostyla

8.  Membranelles normal; 5-10 anal Genus *_Amphisia_
   cirri; no caudal cirri

   Membranelles normal; 5 to 10 anal Genus Stylonychia
   cirri; 3 caudal cirri

   Membranelles very large and Genus Actinotricha
   powerful; adoral zone not
   continued to mouth; 5 anal cirri

   * Presence at Woods Hole indicated by asterisk.

Genus EPICLINTES Stein ’62.

(Stein ’62, ’64, ’67; Mereschowsky ’79; Gruber ’87; Buetschli ’88.)

Very active, contractile, colorless forms of rather small size.  In the fully expanded condition the body is oval and long, with its greatest width in the center or at the front half of the body.  The posterior end is always drawn out into a relatively long tail, which is extremely elastic.  The peristome is short and stretches around the front end of the animal.  In the frontal region are from one to three rows of cirri.  The ventral surface is covered with longitudinal rows of cilia, the number of rows being in dispute (6 to 7 according to Stein; 9 according to Mereschowsky and Rees) Some of these cilia project from the lateral edges and from the posterior end, where they are slightly elongated.  The anus is dorsal and placed at the beginning of the posterior process.  Macronucleus probably double.  Movement is rapid and restless, the tail process contracting to jerk the body backward.  Salt water.

Page 45

Epiclintes radiosa Quenn.  Fig. 50.

Synonym:  Metra radiosa Quenn.

The body is elongate, slightly narrowed anteriorly, and drawn out posteriorly into a long, retractile, tail-like portion.  Five large cirri extend outward from the anterior extremity.  The caudal portion may be extended to a distance equal to twice the length of the body or contracted to half the length.  The peculiar nervousness of this form made it extremely difficult to study, and the oral region was imperfectly made out.  The anterior cirri appear to line the upper left border of the peristome, which is marked by a row of large cilia.  The peristome begins upon the right side of the anterior end and passes backward and to the left, narrowing at this point.  The mouth is very small and difficult to see.  It is apt to stay in one locality under zoogloea, switching back and forth with great vivacity, or hanging on by the posterior cilia while the anterior end stretches out in the surrounding medium.  Nucleus and contractile vacuole were not observed.  Length 45 mu.

[Illustration:  Fig. 50.—­Epiclintes radiosa.]

Genus AMPHISIA Sterki ’78.

(Sterki ’78; Kent ’81; Buetschli ’88.)

The body is plastic and soft, colorless or slightly tinged with yellow or red.  In form it is oval or elongate, the posterior end is rounded and slightly reduced in diameter, but does not form a distinct tail.  The anterior end is also rounded and similarly reduced in width.  There are two rows of marginal cirri (Randcirren), which may be placed some distance from the edge, and two or three rows of ventral cirri between them.  There are from 3 to 5 frontal cirri of larger size than those of the ventral rows, and from 5 to 10 anal cirri. (The genus Holosticha is similar in all respects save the presence of frontal cirri.) The macronucleus is double; the contractile vacuole is central and on the left side.  The peristome is long and rather narrow and carries an undulating membrane on its right margin.  Fresh and salt water.

Amphisia kessleri Wrzes. ’77.  Fig. 51.

Synonyms:  Trichoda gibba Mueller; Oxytricha gibba Stein ’59; O. velox? Quen. ’69; O. kessleri Wrzes. ’77.

Body elongate, slightly sigmoid and swollen in the center, about 3-1/2 times as long as broad; the rounded anterior end is turned to the left, the similarly rounded posterior end to the right; both ends taper slightly.  The peristome is long and narrow, with a distinct adoral zone which appears broken in its course.  To the right of this adoral zone is a single line of preoral cilia.  On the right border of the peristome is an undulating membrane.  The three frontal cirri form a triangle and the five smaller anal cirri form a continuous line with the broken row of ventral cirri.  There are two and one-half rows of ventral cirri and the marginal cirri are drawn in until they are ventral in position.

Page 46

Length 135 mu; greatest width 40 mu.

[Illustration:  Fig. 51.—­Amphisia kessleri.]

This variety differs from O. kessleri as described by Wrzesniowski in having three frontal cirri instead of four.  Another difference is in the structure of the nuclei and in their position.  These differences are too minute to warrant a specific name. O. velox of Quennerstedt is probably the same as 0. kessleri, but differs in having three complete rows of ventral cirri. O. velox has three frontal cirri in a line, thus differing from the Woods Hole form.

KEY TO THE MARINE GENERA OF EUPLOTIDAE.

Diagnostic characters:  Cilia, as well as the frontal, marginal, and ventral cirri, very much reduced; the anal cirri, on the other hand, are always present.  The macronucleus is band-form.

1.  Frontal cirri more than 8 2

   Frontal cirri less than 8 3

2.  Eleven marginal cirri on the left Genus Certesia
   side; 11 frontal cirri

   Four marginal cirri, 2 on each Genus *_Euplotes_
   side; 9 to 10 frontal cirri

3.  Seven frontal, 5 anal, 3 right Genus *_Diophrys_
   marginal, and 2 left marginal
   cirri

   No frontal, 5 anal, 3 right, Genus *_Uronychia_
   and 2 left marginal cirri

   * Presence at Woods Hole indicated by asterisk.

Genus EUPLOTES (Ehr. 1831) Stein ’59.

(Ehrenberg ’31, ’38; Stein ’59; Cl. & Lach. ’58; Quennerstedt ’65, ’67, ’69; Buetschli ’88; Kent ’81; Gourret & Roeser ’88; Moebius ’88.)

Small to medium-sized forms.  Rigid in form, colorless, or green by chlorophyl.  They are quite flat on the ventral surface but decidedly arched dorsally, and the contour is usually oval.  The anterior end is broadly rounded to truncate; the posterior end is similarly rounded, or may be somewhat pointed.  The mouth is placed centrally or near the left margin, and from it the right edge of the peristome forms a curved line to the left, which bends forward, thus making the greater part of the left edge the peristomial area.  In front the peristome bends sharply to the right and extends as far as the right end of the adoral zone.  Upon the frontal and median ventral surface are 9 to 10 great cirri (Bauchwimpern of Stein).  Posteriorly five great anal cirri stretch out beyond the posterior body margin.  In addition to these there are two smaller marginal cirri upon the left body edge, and two similar ones on the hinder part of the body.  The dorsal surface is rarely smooth, but usually is marked by longitudinal ridges, and rows of dorsal bristles have been described.  The single contractile vacuole lies on the right side in the region of the anal cirri, sometimes just above them, sometimes below.  The anus is posterior and on the right side.  The characteristic macronucleus is long and band-form, its main portion being usually on the left side with an anterior and a posterior arm toward the right.  Movement is rapid swimming, which, however, is frequently broken by creeping periods, during which the animals appear to be examining the foreign body on which they creep.

Page 47

Fresh and salt water.

Euplotes charon Ehr.  Fig. 52.

Synonyms:  Trichoda charon Mueller; Ploesconia charon; P. affinis, subrotunda, radiosa, longiremis, Dujardin ’41.

The body is oval, small, and somewhat variable in length.  The carapace is strongly marked upon the dorsal side by deep longitudinal grooves, 6 to 8 in number; the grooves may be absent, however.  The adoral zone extends to the posterior third of the body, the mouth and oesophagus are directed anteriorly.  There are 10 ventral cirri, 7 of which are on or near the frontal border and 3 near the right edge.  There are 5 posterior cirri and 4 anal cirri, of much smaller size.  The cirri may or may not be fimbriated, the latter condition indicating the approaching disintegration of the body and is abnormal.  The macronucleus is long and band-formed or horseshoe shape.  The contractile vacuole lies on the right side dorsal to the posterior cirri.

Fresh and salt water.  Length 45 mu; diameter 25 mu.

[Illustration:  Fig. 52.—­Euplotes charon, dorsal and ventral aspects.]

Euplotes harpa Stein.  Fig. 53.

The body is elongate, oval, somewhat widened anteriorly, and has rounded ends.  The frontal margin is three-toothed.  Ten ventral cirri.  Dorsal surface provided with 8 longitudinal markings.  The peristome is long and broad, with considerable variation.  The adoral zone consists of powerful membranelles arranged in a continuous curve from the mouth to the extreme right frontal margin.  Seven of the 10 ventral cirri are situated at the anterior extremity; the remainder are arranged in a triangle on the right edge.  The anal cirri, 5 in number, are long and stiff; the marginal cirri smaller and finer.  The nucleus and contractile vacuole are similar to those of the preceding species.

Length 95 mu; width 54 mu.

[Illustration:  Fig. 53.—­Euplotes harpa.]

Genus DIOPHRYS Dujardin ’41.

(Buetschli ’88.)

Medium size, colorless to yellow, rigid in form.  The body contour is oval, the anterior end being rounded or slightly reduced, the posterior end usually cut in on the right side.  The peristome is broad but less extensive than in Euplotes, and may extend beyond the middle of the body.  Its right edge is convex toward the right side, extends forward and does not turn again to the right.  The anterior ventral surface has 7 to 8 scattered cirri and just behind the mouth is a transverse row of large anal cirri.  In the sharp in-cut of the posterior end are three great angular cirri.  Two lateral cirri are placed on the left of the median line between the mouth and the anal cirri, and usually in a slight hollow.  The contractile vacuole is on the right side in the vicinity of the anal cirri.  The macronucleus is in two parts, each band-form, one anterior, the other posterior in position.  Movement is rapid and steady.  Salt water.

Page 48

Diophrys (Styloplotes) appendiculatus Stein ’59.  Fig. 54.

Synonyms:  Styloplotes appendiculatus Stein ’59; Kent ’81;
Quennerstedt ’67, etc.

The general form resembles Euplotes.  Its outline is oval and regular except at the posterior end on the right side, where there is a considerable indentation.  The frontal margin is characterized by a row of powerful membranelles, which become smaller at the peristome and at the mouth they are of characteristically small size.  The ventral cirri are 7 in number.  Five of them are in one row from the anterior end down the right side nearly to the anal cirri; 1 is on the frontal border between the first two; 1 lies just anterior to the second anal cirrus from the right side.  The 5 anal cirri are large and powerful and extend some distance beyond the posterior end of the body.  In all specimens observed these cirri curve to the left.  Dorsal to the anal cirri and placed deep into the dorsal pit are 3 large, sharply curved cirri, which in most cases are fimbriated, but when the specimens are normal these are pointed and curve abruptly to the right.  Two smaller cirri lie to the left of the group of anal cirri.  The peristome is well-marked by the adoral zone, and upon its right border there is a row of cilia, and a similar row of cilia runs along the base of the oral membranelle.  The macronucleus is double and consists of two elongate cylindrical masses lying parallel with one another.  One of these is in the anterior region; the other is posterior.  The contractile vacuole lies dorsal to the anal cirri and anterior to the three dorsal cirri.  The movement and general activities resemble those of Euplotes.

Length 50 mu; diameter 25 mu.

[Illustration:  Fig. 54.—­Diophrys appendiculatus.]

Genus URONYCHIA Stein ’52.

(Stein ’59, ’67; Quennerstedt ’67; Kent ’81; Buetschli ’88.)

Medium-sized colorless ciliates of usually constant body form.  The body is somewhat short and oval in outline.  The anterior end is broadly truncate, the posterior end rounded or slightly pointed.  The ventral and dorsal surfaces are considerably arched and the latter usually has a number of rows of longitudinal stripes.  The open peristome is broad and reaches back to the middle of the ventral surface and beyond.  According to Stein, the two edges can approach each other, thus opening and closing the peristomial area.  Its right edge forms a greater angle with the front edge than in the genus Euplotes, and the left edge forms a greater angle with the front edge than in that genus.  The left edge also appears to cover over the adoral zone slightly.  There are no ventral cirri in front, but on the posterior ventral surface are 7 great springing cirri.  Five of these are inserted on the right aide in a deep in-sinking, and the other 2 in a similar depression on the left ventral surface.  Above the 5 right-side cirri, i.e., dorsal to them, but in the same depression, are 3 angular cirri.  A few edge cirri are found to the left of them and another to the right of the 5 cirri.  The contractile vacuole is on the left side between the main groups of cirri.  The macronucleus is band-form or spherical, and is situated in the middle region of the body.  Movement consists in forward swimming with sudden springs.

Page 49

Salt water.

Uronychia setigera, n. sp.  Fig. 55.

This species is very common in the Woods Hole waters.  It is small, colorless, and very active.  The most characteristic feature is the posterior end with its relatively enormous cirri, which are apparently large enough for an animal four times its size.  The form is ovoid, widened posteriorly.

The ventral surface is flat and has two excavations in the posterior end.  The right hollow is larger and contains 5 great cirri of unequal size, the extreme right one being the largest.  The left hollow contains 2 cirri, also of dissimilar size.  Dorsal to the 5 right cirri are 3 sickle-formed cirri, which are usually fimbriated.  These are pointed and curve regularly to the left.  The peristome is wide and open, and a small pocket-like hollow on its left border indicates the region of the mouth.  The adoral zone runs into this pocket and the mouth is located in its lower right-hand corner.  In U. transfuga the right border is generally described as having a membrane of extreme delicacy.  I was unable to see such a membrane in this form, but in its place there are 2 flagella-like cirri extending from the margin of the mouth-opening into the peristome, and these vibrate slowly.  I do not believe these could be the moving edge of an undulating membrane, for they are quite distinct.  The macronucleus is spherical instead of band-form, and a single micronucleus is closely attached.  This is unlike the European species U. transfuga, in which the nucleus is elongate.  The contractile vacuole lies between the two sets of posterior cirri.  There are no marginal folds like those of the European species.

Length 40 mu; width 25 mu.  Common.

[Illustration:  Fig. 55.—­Uronychia setigera.]

Genus ASPIDISCA Ehr. 1830.

(Perty ’52; Cl & Lach. ’58; Stein ’59; Quennerstedt ’65, ’67, ’69;
Mereschowsky ’79; Kent ’81; Buetschli ’88.)

Small, colorless, and rigid forms, with nearly circular to oval contour.  The left side is usually straight, or at least but slightly convex.  The right side is much more convex, and the right margin is considerably thickened.  The ventral side is flat, the dorsal surface convex, with from one to several longitudinal ridges which run more or less parallel with the right edge.  The peristome is limited to the left edge, where it forms a small depression which may or may not reach the anterior border, but which in no case runs around the anterior margin.  The left peristome margin in some cases grows over the peristome depression toward the right, thus making a sort of cover for the peristome.  In the posterior region is a deep depression, from which 5 to 12 cirri take their origin.  Seven or 8 cirri are placed in the anterior half of the ventral surface and are arranged more or less in rows.  The anus is on the right side in the region of the anal cirri (Stein).  The contractile vacuole is generally on the right side and similarly located.  The macronucleus is a horseshoe-shaped body.  Movement rapid, somewhat in circles, and rather uniform.

Page 50

Fresh and salt water.

Aspidisca hexeris Quennerstedt ’67.  Fig. 56.

The carapace is elliptical, about 1-1/2 times as long as broad, rounded at the extremities.  The left border of the carapace bears a spur-like projection.  The ventral cirri are short and thick, and are very characteristic of the species.  When moving slowly they look much like nicely-pointed paint brushes, but when the animal is compressed they quickly become fibrillated, and then look like extremely old and worn brushes.  These cirri are placed in depressions in the ventral surface and each one appears to come from a specific shoulder.  At the posterior end an oblique hollow bears 6 unequal cirri placed side by side.  The extreme right cirrus is the largest, and they become progressively smaller to the opposite end.  Dorsal to these lies the contractile vacuole.  The peristome is in the posterior half of the body and an undulating membrane extends from it into the oesophagus.  The dorsal surface is longitudinally striated by 5 or 6 lines, which are usually curved.  The nucleus is horseshoe-shaped and lies in the posterior half of the body.  Length 68 mu; diameter 48 mu.

[Illustration:  Fig. 56.—­Aspidisca hexeris.]

This form was incorrectly mentioned as Mesodinium sp. by Peck ’95: 

In the figure given by Quennerstedt there are only 7 ventral cirri.  In the Woods Hole form there are 8, 7 of which are anterior, 6 of them about one central one.  The eighth cirrus is by itself, near the base of the largest posterior cirrus.  These cirri, in spite of their size, are easily overlooked and more easily confused, but by using methylene blue they can be seen and counted.

Aspidisca polystyla Stein.  Fig. 57.

This species is similar to A. hexeris, but is smaller, very transparent, and without the spur-like process on the left edge of the carapace.  The chief difference, however, lies in the number of anal cirri.  These are 10 in number and they are arranged obliquely as in the preceding species, with the largest one on the right and the smallest on the left.  The ventral cirri are 8 in number, and are arranged in two rows, one of which, the right, has 4 cirri closely arranged, the other having 3 cirri close together and one at some distance, near the largest anal cirrus.  The peristome, contractile vacuole, and nucleus are similar to the preceding.  Length 36 mu; width 22 mu.

[Illustration:  Fig. 57.—­Aspidisca polystyla.]

Stein assigns only 7 ventral cirri to this species, but he also describes 2 very fine bristle like cilia (p. 125) and pictures them in figs. 18, 19, 20, and 21 of his Taf.  III in the same relative position as my eighth cirrus.  I am positive that cilia do not occur on the ventral face of this form, and that the characteristic cirri are the sole locomotor organs.

KEY TO FAMILIES OF PERITRICHIDA.

Page 51

a.  Peristome drawn out into Family Spirochonidae
   funnel-like process; parasitic

b.  Adoral zone and circlet of cilia Family Lichnophoridae
   at opposite end.  Adoral zone (one genus, *_Lichnophora_)
   left-wound.  Parasitic.

c.  Adoral zone a left-wound spiral.  Family Vorticellidae
   Attached or unattached forms.

   * Presence at Woods Hole indicated by asterisk.

Genus LICHNOPHORA Claparede ’67.

(Gruber ’84; Fabre-Domergue ’88; Buetschli ’88; Wallengren ’94;
Stevens 1901.)

Small or medium-sized colorless animals, extremely elastic and flexible.  The anterior part, bearing the adoral zone, is round or oval in ventral view, and has a flat ventral and a highly arched dorsal surface.  The posterior end of the animal is reduced to a stalk-like structure which is broadened at the extremity to form a sucking disk.  The surface of this disk and the surface of the peristome may be brought into the same plane by the characteristic bending of the stalk portion.  A ciliated girdle is placed at the edge of the sucking disk.  A well-developed adoral zone incloses the peristome; it begins at the mouth on the left side and includes nearly all of the peristome in its left-wound spiral, the extremity approaching closely the end near the mouth.  The macronucleus is a long-beaded structure, or it may be in several parts connected by strands (Gruber).  The contractile vacuole is on the left side in the region of the mouth.  Salt water.

Lichnophora macfarlandi Stevens.  Fig. 58.

The body is elongate; oral disk variable in form, attachment disk clearly defined and constant.  The stalk is very contractile and elastic, constantly changing in shape.  When detached from the host the animal moves with a very irregular and indefinite motion.  When attached it moves freely over the surface on its pedal disk.  The latter is bordered by four membranes composed of cilia.  A distinct axial fiber extends from the pedal disc to the peristome and gives off a number of branches.  This fiber is analogous to the myonemes in Vorticella.  An indistinct longitudinal furrow can be made out occasionally.  The nucleus is in 5 or 6 separate pieces, of which 1 is found in the pedal disk and 1 or 2 in the neck.

On the egg capsules of Crepidula plana; also reported upon annelids at Woods Hole.

Length 60 mu from disk to extremity of the peristomial disk.

[Illustration:  Fig. 58.—­Lichnophora macfarlandi.]

This form does not agree in all respects with Stevens’s species, but the agreement is so close in other respects that I believe it can be safely identified as L. macfarlandi.  The mode of life is different, and the macronucleus is different, there being from 25 to 30 fragments in Stevens’s form and only 5 or 6 in the present one.  There is, however, the same evidence of chain formation in both of them.  The length of the oral cilia in Stevens’s form is 18 mu in fixed and 30 mu in living forms.  In the Woods Hole form the cilia are not more than half that length.

Page 52

KEY TO THE MARINE GENERA OF VORTICELLIDAE.

Diagnostic characters:  Attached or unattached forma of peritrichous ciliates in which the adoral zone seen from above forms a right-wound spiral.  A secondary circlet of cilia around the posterior end may be present either permanently or periodically.

1.  Posterior ciliated girdle 3
   permanent around an attaching disk

2.  Posterior ciliated girdle, 4
   temporary during motile stage

3.  Body cylindrical: 

(a) With ring of stiff bristles Genus Cyclochaeta
above the ciliated girdle

(b) Without accessory ring of Genus Trichodina
bristles; with velum

Body conical; general Genus Trichodinopsis
surface ciliated

4.  No test and no stalk Genus Scyphidia

5.  No test; with stalk containing 8
   contractile thread

6.  No test; with stalk but without Genus Epistylis
   contractile thread

7.  With a test; with or without Genus *_Cothurnia_
   a stalk

8.  Individuals solitary Genus *_Vorticella_

   Individuals colonial; Genus *_Zoothamnium_
   entire colony contractile

   Individuals colonial; parts Genus Carchesium
   only of the colony contractile

   * Presence at Woods Hole indicated by asterisk.

Genus VORTICELLA (Linnaeus 1767) Ehr. ’38

(Bell Animalcule Leeuwenhoek 1675; Ehrenberg ’38; Dujardin ’41; Stein ’51; Cl. & Lach. ’58; Greeff ’70; Buetschli ’88; Kent ’81; Stokes ’88; etc.)

Medium-sized ciliates of general bell-like form.  They may be colorless, or yellow and green through the presence of Zoochlorella.  When not contracted, the peristome end is widespread, rarely narrowed.  The adoral zone and peristome agree with the details given in the family characteristics.  The chief character is the attachment of the posterior end by means of a single, longer or shorter, stalk, which contains a highly contractile thread easily distinguished in the living animal.  Another character is the absence of colony formation.  Contractile vacuole, single or double, usually connected with a sac-like reservoir.  The macronucleus is invariably long and band-formed, with attached micronucleus.  Fresh and salt water.

So many species of Vorticella have been described that the task of collecting data and of arranging the synonyms is extremely irksome and difficult.  Stokes enumerates 66 species, inhabiting fresh and salt water, and several other new species have been added since his work.  I am impressed with the fact that new species have been created without proper regard for the manifold variations which nearly all of the Ciliata show, and I believe the 66 species might be safely reduced to 12 or 15.

Page 53

Vorticella patellina Mueller.  Fig. 59.

Body campanulate, widest at anterior border, from which it tapers directly to the pedicle.  The diameter of the peristome is a little larger than the length of the body.  The ciliary disk is but little elevated.  The cuticle is not striated and the body plasm is quite transparent.  Length 52 mu.

[Illustration:  Fig. 59.—­Vorticella patellina.]

Vorticella marina Greeff.  Fig. 60.

The body is conical but variable, and may he short or elongate, so that relative length and breadth offer no chance of identification.  In general the body is campanulate.  The distinguishing feature is the transverse annulation of the bell.

Small, but common, and grows in small social groups.  Length 35 mu.

[Illustration:  Fig. 60.—­Vorticella marina.]

Genus ZOOTHAMNIUM (Bory de St. Vincent 1824) Stein ’38, ’54.

Colorless and highly contractile forms growing in small or large colonies.  The form and structure of the individuals is not different from Vorticella.  The colonies are usually richly branched upon the dichotomous plan and the entire colony is contractile.  The main character is that with each division of the individual the stalk also divides, each daughter cell getting one-half of the parent stem.  The stems therefore remain in communication, so that a simultaneous contraction results, and the colony as a whole is withdrawn.  In some species so-called macrogonidia, or larger sexual individuals, are developed alongside the usual ones.  Fresh and salt water.

Zoothamnium elegans D’Udekem ’64?  Fig. 61.

The bodies are variable—­peristomial border widely dilated, tapering and attenuate posteriorly.  The pedicle is slender, smooth, and transparent, and branches sparsely at its distal extremity.  There are but few zooids (3 to 4).  The ciliary disk projects conspicuously beyond the peristomial border.  The pharyngeal cleft is very distinct and extends beyond center of body.  Length of body 80 mu.

[Illustration:  Fig. 61.—­Zoothamnium elegans.]

Genus COTHURNIA (Ehr. ’31) Clap. & Lach. ’58.

Colorless forms of medium size-in some cases they may be green by Zoochlorella.  The general structure is similar to that of Vorticella, but the individuals are elongate and occupy houses.  The macronucleus is invariably long and band-form.  The distinguishing character is the colorless or brownish lorica of quite variable form but always attached.  These houses may be finger-formed, with widened center, or widened mouth, or constricted mouth, and the like.  Ring-formed swellings are frequently developed.  Sometimes the mouth becomes twisted and the lorica is therefore bilateral.  The houses are attached either directly to some foreign object or by means of a short stalk.  The animals are similarly fastened to the lorica, sometimes directly, sometimes by means of a short stalk.  When they contract they draw back to the bottom of the lorica; when expanded they usually stretch out of the mouth opening.  In some forms there is an operculum, by means of which the opening of the shell can be closed when the animal is retracted.  Fresh and salt water.

Page 54

The number of species of Cothurnia has become so great that the difficulty in placing forms is almost sufficient to discourage the systematist; as Buetschli well remarks, the variations in the theca have been made the basis of new species so many times that the genus is almost as confused as Difflugia among the rhizopods or Campanularia among the hydroids.  The length of cup, of stalk, the presence of annulations on stalk or cup, etc., have given rise to many specific names, the majority of which I believe can be discarded.  According to such differentials the same branch of an alga holding a hundred specimens of Cothurnia crystallina yield 10 or 12 species, whereas they are merely growth stages of one and the same form.

Cothurnia crystallina Ehr.  Fig. 62.

Synonyms:  Vaginicolla crystallina Ehr., Perty, Eichwald; V. grandis Perty; V. pedunculata Eichwald; Cothurnia crystallina Claparede & Lachmann, D’Udek.; C. gigantea D’Udek; C. maritima, C. crystallina Cohn; C. grandis Meresch.

The form of the cup shows the greatest differences; sometimes it is cylindrical, sometimes elongate thimble-shape, sometimes pouch-shape, corrugated or smooth on the sides, and wavy or smooth on border.  Frequently the basal part becomes stalk-like, but this is very short.  When present, the stalk may or may not have a knob-like swelling.  The animal within the cup may or may not be borne on a stalk, and this stalk may or may not be knobbed.  The cups are colorless or brown.  The animal is very contractile and may stretch half its length out of the cup or retract well into it.  There is no operculum.  The length of the cup varies from 70 mu to 200 mu (C. gigantea; Vag. grandis, etc.).  From Entz.

There is nothing to add to Entz’s characterization of this species, which is found both in fresh and salt water.  The variability of the cup and stalk is quite noticeable in the Woods Hole forms.

[Illustration:  Fig. 62.—­Cothurnia crystallina.]

Cothurnia imberbis Ehrenberg, var. curvula Entz.  Fig. 63.

Synonyms:  C. imberbis Kent et al.; C. curvula Entz; C. socialis
Gruber?

The lorica is swollen posteriorly, narrowest at the oral margin, bent on its axis and is supported on a short stalk.  It is perfectly smooth and without annulations.  The animal itself has no definite stalk.  When fully expanded the animal emerges but slightly from the margin of the cup.  Fresh and salt water.  On red algae.  Dimensions of Woods Hole form:  Cup 50 to 55 mu long; greatest diameter 22 mu; length of stalk 4 to 5 mu.

[Illustration:  Fig. 63.—­Cothurnia imberbis.]

Cothurnia nodosa Claparede & Lachmann.  Fig.64.

   A. Smooth cup.—­Cothurnia maritima Ehr., Eichwald, Stein, Kent.

   B. Cross-ringed cup.—­C. pupa Eichwald, Stein, Cohn; C. nodosa
      Cl & L.; V. crystallina Entz ’78; C. pontica Meresch.,
      Kent; C. cohnii and pupa Kent; C. longipes Kellicott ’94.

Page 55

The cup is elongated, swollen centrally, tapering at oral end and conical at base or rounded.  Oral opening either circular or elliptical.  Cross rings may or may not be present, and the cup is either smooth or annulate.  Length of cup 70 mu to 80 mu.  The stalk which supports the cup is extremely variable in length.  The animal is borne upon a stalk of variable length within the cup.

Entz states that the many variations which this species exhibits run into each other so gradually that he does not believe it wise to separate them.  The Woods Hole forms which I found on algae of various kinds were nearly of a size, and did not vary much from the one figured.  Kellicott ’94 described a Cothurnia from Woods Hole under the name of C. longipes, which I believe is only a long-stemmed variety of C. nodosa.  My form has the following dimensions:  Cup 75 mu; cup stalk 38 mu; animal stalk 14 mu.

[Illustration:  Fig. 64.—­Cothurnia nodosa.]

KEY TO FAMILIES OF SUCTORIA.

a.  Unattached forms; ventral cilia Hypocomidae
   present; one suctorial tentacle

b.  Attached forms; thecate and Urnulidae
   athecate tentacles simple,
   one or two in number

c.  Thecate; posterior end of cup Metacinetidae
   drawn out into stalk; walls
   perforated for exit of tentacles

d.  Stalked or unstalked; globular; Podophryidae
   tentacles of different kinds, some (2 genera *_Ephelota_,
   knobbed, others pointed *_Podophrya_)

e.  Naked or thecate; stalked or not; Acinetidae
   tentacles numerous, usually
   knobbed and all alike

f.  Naked; athecate; tentacles Dendrosomidae
   numerous, all alike, knobbed and
   grouped in tufts.  They may be
   simple or branched.

g.  Sessile forms resting on basal Dendrocometidae
   surface or on a portion raised
   like a stalk; tentacles many;
   short and knobbed; distributed
   on apical surface or localized
   on branched arms

h.  Stalked or sessile; tentacles Ophryodendridae
   long, rarely knobbed, supported
   on proboscis-like processes

   * Presence at Woods Hole indicated by asterisk.

Genus PODOPHRYA Ehr. ’33.

(Buetschli ’88; Stein ’59; Perty ’52; Cienkowsky ’55; Quenn. ’69;
Hertwig ’77; Maupas ’81.)

The body is globular, with tentacles radiating in all directions.  The tentacles may be very short or very long.  The stalk also is either short or long, and some species form stalks but rarely (P. libera).  The macronucleus is centrally placed and globular to ovoid in form.  The contractile vacuole is usually single.  Reproduction takes place by division; the distal half developing cilia and becoming a swarm-spore.  Fresh and salt water.

Page 56

Podophrya gracilis, n. sp.  Fig. 65.

Of all the Podophrya that have been described not one approaches this minute form in the relative length of the stalk.  The body is spherical and is covered with short capitate tentacles.  The stalk is extremely slender, bent, and without obvious structure.  There are one or two contractile vacuoles in the distal half of the body.  The nucleus is small and is situated near the insertion-point of the stalk.  Reproduction not observed.  Diameter of body 8 mu; length of stalk 40 mu.  Only one specimen seen.

[Illustration:  Fig. 65.—­Podophrya gracilis.]

Genus EPHELOTA Str.  Wright ’78.

(Buetschli ’88; Ishikawa ’96; Sand ’98.)

Small to medium-sized and large forms; colorless to brown.  The body is globular or oval or wedge-shape, sometimes quadrangular.  The stalk is variable, sometimes 1 mm. in length.  The diameter of the stalk increases from the point of attachment to the body of the animal; it is usually striated either longitudinally or transversely, or both.  The tentacles are of two kinds and are usually confined to the anterior half of the body.  Some are long and sharp-pointed and adapted for piercing; others are short, cylindrical, usually retracted and capitate, adapted for sucking.  Contractile vacuoles vary from one to many.  The macronucleus is nearly central in position and usually of horseshoe shape, but is frequently branched and irregular.  Reproduction is accomplished by external multiple budding, usually from the anterior half of the body.  Salt water.

Ephelota coronata Str.  Wright.  Fig. 66.

Synonyms:  Hemiophrya gemmipara S. K.; Podophrya gemmipara
Hertwig.

The body is spheroidal, ovate, or pyriform, with numerous sharp-pointed tentacles and a few straight, uniform tentacles.  The stalk is about three times the length of the body and tapers from its widest part at the insertion in the body to the narrowest part at the point of attachment.  It may or may not be longitudinally striated.  This is one of the commonest of the Suctoria found at Woods Hole.  It is usually present on Campanularian hydroids, but may be found on algae and Bryozoa.

Length of body 90 mu to 200 mu.

[Illustration:  Fig. 66.—­Ephelota coronata.]

Genus ACINETA Ehr. ’33, Buetschli ’88.

(Stein ’54, ’59; Claparede & Lachman ’58; Quennerstedt ’67; Hertwig ’76; Mereschowsky ’79; Entz ’84; Kent ’81; Maupas ’83; Gruber ’84; Gourret & Roeser ’86, and others.)

Small to medium-sized forms.  The distinguishing feature is that the stalk is swollen at the distal extremity to form a cup or basin in which the animal rests.  The cup may be developed until the body is nearly inclosed.  The macronucleus is spherical or band form.  The contractile vacuole is usually single.  Budding, so far as known, is endogenous.  Fresh and salt water.

Page 57

Acineta divisa Fraipont ’79.  Fig. 67.

This extremely graceful form is common on Bryozoa at Woods Hole.  The cup is shaped like a wine glass and is specifically characterized by a cup-formed membrane upon which the animal rests.  The animal thus has the appearance of being suspended on the edge of the cup.  The stalk is slender and about 4 times the length of the body.  The tentacles are all capitate and distributed, and about 2-1/2 times the body length.  They sway back and forth very slowly.  The nucleus is spherical and central in position.  The contractile vacuole lies near the periphery.

Length of body 27 mu; of stalk 100 mu; of extended tentacle 65 mu.

[Illustration:  Fig. 67.—­Acineta divisa.]

Acineta tuberosa Ehr.  Fig. 68.

Large forms of Suctoria with tentacles arranged in fascicles.  The stalk is variable in length and the cup is frequently so delicate that it can barely be made out.  A specific characteristic is the break in continuity of the cup at different points, and through these places the tentacles emerge in bundles.  The tentacles are capitate and in the Woods Hole form, 15 in number in each of the two bundles.  The endoplasm is granular and yellowish in color.  The coloring matter is frequently arranged in patterns.  The nucleus is spheroidal.  The contractile vacuole is in the anterior third of the body about midway between the bundles of tentacles.  Reproduction not observed.

Length of body 330 mu.

[Illustration:  Fig. 68.—­Acineta tuberosa.]

Genus TRICHOPHRYA Clap. & Lach. ’58.

(See Kent ’81; Entz ’84; Buetschli ’88; Sand 1901.)

Small forms to medium size; no cups or stalks.  The body is spherical to elongate, usually, however, more or less irregularly lobed and changeable.  The tentacles are in fascicles which are usually borne upon lobed or swollen places.  The body is always more or less spread out.  Contractile vacuoles variable.  The macronucleus is spherical, elongate, band-formed or horseshoe-shaped.  Reproduction takes place by endogenous budding, and the swarm spores are flat or lenticular with a distinct ciliary girdle.  They are frequently parasitic.  Fresh and salt water.

Trichophrya salparum Entz ’84.  Fig. 69.

Buetschli ’88; Schewiakoff ’93; Trichophrya ascidiarum Lachmann ’59;
Rene Sand 1901.

The body is somewhat cup-form, with a large, flat base.  The anterior border is rounded, each of the ends being somewhat truncate and carrying a bundle of tentacles all capitate and similar.  These may be continued internally as far as the nucleus (Sand).  The cytoplasm is uncolored, but may contain some brilliant granules.  The nucleus is granular, and spherical, band or horseshoe formed.

[Illustration:  Fig. 69.—­Trichophrya salparum.]

This species was found by Dr. G. Hunter on the branchial bars of the Ascidian Molgula manhattensis, where great numbers of them are often parasitic.

Page 58

LIST OF REFERENCES.

AUERBACH, L. ’54.  Ueber Encystierung von Oxytricha pellionella.  Zeit.
      wiss.  Zool., V, 1854.

——­ ’55.  Ueber die Einzelligkeit der Amoeben.  Zeit. wiss.  Zool.,
      VII, 1855.

BALBIANI E. G. ’61.  Recherches sur les phenomenes sexuelles des
      Infusoires.  Jour. de la physiol:, IV, 1861.

——­ ’85.  Sur un Infusoire parasite du sang de l’Aselle aquatique. 
      Rec. zool.  Suisse, II, 1885.

BERGH, R. S. ’79. Tiarina fusus Cl. & Lach.  Vid.  Med. f. d.  Nat. 
      Foren.  Kjobenhavn.

——­ ’82.  Der Organismus der Cilioflagellaten.  Morph.  Jahr., VII, p.
      177.

BRADY, H. B. ’79.  Report on the Foraminifera dredged by H. M. S.
      Challenger during the years 1873-1876.  Challenger Reports,
      Zoology, IX.

BRANDT, K. ’96.  Die Tintinnodeen.  Bibliot.  Zoolog., XX, 1896.

BUETSCHLI, O. ’76.  Studien ueber die ersten Entwickelungsvorg. der
      Eizelle, die Zelltheilung, und die Conjugation der Infusorien. 
      Abhand. der Senck. naturf.  Ges.  Freiburg, X, 1876.

——­ ’83-’88.  Die Protozoen.  Bronn’s Klassen u.  Ord. des Tierreichs.

CARPENTER, W. B. ’56.  Researches on the Foraminifera.  Phil.  Trans.
      (2), p. 547.

CARTER, H. J. ’56.  Notes on the fresh-water Infusoria of the island
      of Bombay.  Ann.  Mag.  Nat.  Hist. (2), XVIII.

——­ ’63.  On the coloring matter of the Red Sea.  Id. (3), XI.

——­ ’63a.  On Amoeba princeps and its reproductive cells.  Id. (3),
      XII.

——­ ’64.  On fresh-water Rhizopods of England and India.  Id. (3),
      XIII, p. 13.

——­ ’65.  On the fresh- and salt-water Rhizopods of England and
      India.  Id. (3), XV, p. 277.

CIENKOWSKY, L. ’55.  Bemerkungen ueber Stein’s Acinetenlehre.  Bull. 
      Phys.  Math.  Acad., St. Petersburg, XIII, p. 297 (also in Ann. 
      Mag.  Nat.  Hist. (3), XIII).

——­ ’55.  Ueber Cystenbildung bei Infusorien.  Zeit. wiss.  Zool., VI,
      p. 301.

——­ ’61.  Beitraege zur Kenntniss der Monaden.  Arch. f. mik.  Anat., I,
      1865, p. 203.

CLAPAREDE, E. ’54.  On Actinophrys sol.  Ann.  Mag.  Nat.  Hist. (2),
      XV, 1854.

——­ ’60.  Recherches sur les annelides, etc., observes dans les
      Hebrides.  Mem.  Soc. phys. d’hist. nat., Geneve, XVI, 1860.

——­ ’67.  Miscellanees zoologiques.  Ann. d. sc. nat. zool. (5), VIII,
      1867.

CLAPAREDE ET LACHMANN ’58-’60.  Etudes sur les Infusoires et les
      Rhizopodes.  Mem.  Inst. genevoise, V, VI, VII.

COHN, F. ’54.  Beitraege z.  Entwicklungsges. der Infusorien.  Zeit.
      wiss.  Zool.  III, 1851; IV, 1853.

——­ ’57.  Ueber Fortpflanzung von Nassula elegans Ehr.  Zeit. wiss. 
      Zool., IX, 1857, p. 143.

Page 59

COSTE, M. ’64.  Developpement des Infusoires cilies dans une
      maceration de foin.  Ann. d. ac. nat. zool.(5), II.

DADAY, E. v. ’86.  Ein kleiner Beitrag der Infusorien-Fauna des
      Golfes v.  Neapel.  Mitt.  Zool.  St. Neap., VI, p. 481.

——­ ’88.  Monographie der Familie der Tintinnodeen.  Mitt.  Zool.  St.
      Neap., VIII, p. 473.

DAVIS, J. ’79.  On a new species of Cothurnia.  Jour.  Roy.  Mic.  Soc.,
      II, 1879.

DUJARDIN, F. ’35.  Recherches sur les organismes inferieures.  Ann. d.
      sc. nat. zool. (2), IV, p. 343.

——­ ’41.  Histoire naturelle des Zoophytes infusoires.  Paris, 1841.

EHRENBERG, C. G. ’31.  Ueber die Entwickelung und Lebensdauer d. 
      Infusionsthiere.  Abhand. d.  Berlin Ak., 1831, p. 1.

——­ ’38.  Die Infusionsthierchen als vollkommne Organismen.  Leipzig,
      1838.

ENGELMANN, Th.  W. ’78.  Zur Physiologie der Contractilen Vacuolen der
      Infusionsthiere.  Zool.  Anz., I, p. 121.

ENTZ, G. ’84.  Ueber Infusorien d.  Golfes v.  Neapel.  Mitt.  Zool.  St.
      Neap., V, p. 289.

——­ ’85.  Zur naheren Kenntniss der Tintinnodeen.  Mitt.  Zool.  St.
      Neap., VI, p. 185.

FABRE-DOMERGUE, P. ’85.  Note sur les Infusoires cilies de la baie de
      Concarneau.  Jour. d. l’anat. et de la phys., XXI, p. 554.

——­ ’91.  Materiaux pour servir a l’histoire des Infusoires cilies. 
      Ann. d. mic., III, 1890-91, p. 49.

FOL, H. ’83.  Further contribution to the knowledge of the
      Tintinnodea.  Ann.  Mag.  Nat.  Hist. (5), XII, p.73.

FRANCE, R. H. ’97.  Der organismus der Craspedomonaden.  Budapest.

FROMENTEL.  E. DE. ’74.  Etudes sur les microzoaires, etc.  Paris, 1874.

GOURRET ET ROESER. ’88.  Contributions a l’etude des Protozoaires de
      la Corse.  Arch. d. biol., VIII p. 139.

GREEFF, R. ’66.  Ueber einige in der Erde lebende Amoeben und andere
      Rhizopoden.  Arch. f. mik.  Anat., II, p. 299.

——­ ’70.  Untersuchungen ueber den Bau u. d.  Naturgeschichte d. 
      Vorticellen.  Arch. f.  Naturges., XXXVI, XXXVII.

——­ ’71.  Ueber die Actinophryens oder Sonnenthierchen des
      Suessenwassers als echte Radiolarien.  Sitz.  Ber. d.  Niederrh. 
      Ges. i.  Bonn, XXVIII, p. 4.

——­ ’75.  Ueber Radiolarien u.  Radiolarienartige Rhizopoden des
      Suessenwassers 2.  Arch. f. mik.  Anat., XI.

——­ ’88.  Studien ueber Protozoen.  Sitz.  Ber.  Ges. z.  Bef. d. ges. 
      Nat., Marburg, 1888, p. 91.

GRENACHER, H. ’68.  Ueber Actinophrys sol Ehr.  Verh. phys.-med. 
      Ges.  Freiburg (n.  F.), I.

GRUBER, A. ’83.  Beobachtungen an Chilodon curvidentis n. sp. 
      Festschr. 56.  Vers.  Deutsch.  Naturf. gewid. v. d.  Naturf.  Ges. 
      Freiburg, II, p. 1.

Page 60

——­ ’84.  Die Protozoen des Hafens v.  Genua.  Nova Act. d.  K.
      Leop.-Car.  Deutsch.  Akad. d.  Naturf., XLVI, p. 475.

——­ ’87.  Ueber der Bedeutung der Conjugation bei den Infusorien. 
      Ber. d.  Naturf.  Ges.  Freiburg, II, p. 31.

HAECKEL, E. ’73.  Zur Morphologie der Infusorien.  Jena Zeit., VII, p.
      516.

HERTWIG, R. ’76.  Ueber Podophrya gemmipara, nebst Bemerkungen zum
      Bau u. d. systemat.  Stellung d.  Acineten.  Morph.  Jahr., IV,
      p. 20.

HERTWIG U. LESSER.  Ueber Rhizopoden u. denselben nahe stehende
      Organismen.  Arch.  F. mik.  Anat., X, Suppl., p. 35.

HUXLEY, T. H. ’57.  On Dysteria, a new genus of Infusoria.  Jour.  Mic. 
      Sci., V, p. 78.

ISHIKAWA, C. Ueber eine in Misaki vorkommende Art v.  Ephelota, etc
      Journ.  Coll.  Sci.  Imp.  Univ.  Tokyo, Japan, X, pt. 2.

JAMES-CLARK, H. ’66.  On the Spongiae ciliatae as Infusoria flagellata,
      etc.  Mem.  Bost.  Soc.  Nat.  Hist. (3), I, p. 1.

KENT, W. SAVILLE. ’81.  Manual of the Infusoria.  London, 1881.

KLEBS, G. ’84.  Ein kleiner Beitrag z.  Kenntniss d.  Peridineen.  Bot. 
      Zeit., XLII, p. 721.

——­ ’92.  Flagellaten Studien 1.  Zeit. wiss.  Zool., LV.

LABBE, A. ’95.  Sur les Protozoaires marins de Roscoff.  Arch. d. zool.
      exper. (3), N. et R., p.  XIV.

LAUTERBORN, R. ’94.  Beitraege z.  Suesswasserfauna der Insel Helgoland. 
      Wiss.  Meeresunt.  Komm. wiss.  Unt. d.  Meere Kiel (2), I, p. 215.

LEIDY, J. ’77.  Remarks upon Rhizopods and notice of a new form.  Proc. 
      Ac.  Sci.  Phila., 1877, p. 293.

——­ ’79.  Fresh water Rhizopods of North America.  Washington, 1879.

LIEBERKUEHN, N. ’56.  Ueber Protozoen.  Notes from a letter to C. Th.
      v.  Siebold.  Zeit. wiss.  Zool., VIII, p. 307.

MAUPAS, E. ’81.  Contributions a l’etude des Acinetiens.  Arch. d.
      zool. exper. (1), IX, p. 299.

——­ ’83.  Contributions a l’etude morphologique et anatomique des
      Infusoires cilies.  Id. (2), I.

——­ ’83a.  Les sucto-cilies de M. Mereschowsky.  Comp.  Ren., XCV, p.
      1381.

——­ ’88.  Recherches experimentales sur la multiplication des
      Infusoires cilies.  Arch. d. zool. exper. (2), VI, p. 165.

MERESKOWSKY, C. ’78.  Studien ueber Protozoen des nordlichen Russland. 
      Arch. f. mik.  Anat., XVI, p. 163.

——­ ’81.  On some new or little-known Infusoria.  Ann.  Mag.  Nat.  Hist.
      (5), VII, 1881.

MOEBIUS, K. ’88.  Bruchstuecke einer Infusorienfauna der Kieler Bucht. 
      Arch. f.  Naturg., 1888.

PECK, J. I. ’93.  On the food of the menhaden.  Bull.  U. S. Fish Com.,
      1893, p. 113.

——­ ’95.  The sources of marine food.  Bull.  U. S. Fish Com., 1895, p.
      351.

Page 61

PERTY, M. ’49.  Mikrosk.  Organ. der Alpen u. d.  Italien.  Schweiz. 
      Mitt. d.  Naturf.  Ges. in Bern, 164-165.

——­ ’52.  Zur Kenntniss kleinster Lebensformen, etc., Bern.

POUCHET, G. ’83; ’85.  Contributions a l’histoire des Peridiniens
      marins.  Jour. de l’anat. et de la phys., XIX, XXI.

QUENNERSTEDT, A. ’65; ’67; ’69.  Bidrag till Sveriges Infusorie-fauna. 
      Lunds Univ.  Aersskrift, II, IV, VI.

SAND, R. 1901.  Etude monographique sur le groupe des Infusoires
      tentaculiferes.  Ann. d. la Soc. belge de microscopie, XXIV,
      XXV, XXVI.

SCHAUDINN, F. ’95.  Die Heliozoen.  Das Tierreich, 1895.

SCHEWIAKOFF, W. ’89.  Beitraege z.  Kenntniss der Holotrichen Ciliaten. 
      Bib.  Zool., V, p. 1.

——­ ’93.  Ueber einige ecto- u. ento-parasitische Protozoen der
      Cyclopiden.  Bull.  Soc. nat.  Moscou, 1893.  I.

SCHUETT, F. ’95.  Die Peridineen d.  Plankton-Expedition, 1.  Kiel u. 
      Leipzig.

SCHULTZE, F. E. ’74; 75.  Rhizopodenstudien.  Arch. f. mik.  Anat., X,
      XI, XIII.

SCHULTZE, M. ’62.  Ueber d.  Organismus d.  Polythalamien.  Leipzig,
      1862.

SHEVYAKOV ?. ’96.  Monograph on Holotrichous ciliates. (In Russian.)
      Mem. of the St. Petersburg Acad., VII.

STEIN, F. ’59; ’78; ’83.  Der Organismus der Infusionsthiere.  I.
      Infusoria, ’59; II.  Infusoria, ’78; III.  Flagellata, ’83.

——­ ’49.  Untersuchung ueber die Entwicklungs d.  Infusorien.  Arch. f. 
      Natur., I, p. 92.

——­ ’54.  Die Infusionsthiere auf ihre Entwicklungsgeschichte
      untersucht.  Leipzig, 1854.

——­ ’60.  Ueber Leucophrys patula u. ueber 2 neue
      Infusoriengattungen Gyrocoris u.  Lophomonas.  Sitz.  Ber. d. 
      K.-boehm.  Ges. d.  Wiss. d.  Prag, 1860, p. 4.

——­ ’64.  Ueber die neue Gattung Epiclintes.  Id., 1864, I.

STERKI, V. ’78.  Beitraege z.  Morphologie der Oxytrichinen.  Zeit.
      wiss.  Zool., XXXI, p. 29.

——­ ’98.  On the classification of ciliate Infusoria.  Amer.  Natur.,
      XXXII, p. 425.

STEVENS, N. M. 1901.  Studies on ciliate Infusoria.  Proc.  Calif. 
      Acad.  Sciences, III, 1.

STOKES, A. C. ’84.  Notices of some new parasitic Infusoria.  Amer. 
      Nat., XVIII, p. 1081.

——­ ’85.  Some apparently undescribed Infusoria from fresh water. 
      Id., XIX, p. 18.

——­ ’87.  Some new hypotrichous Infusoria from American fresh waters. 
      Ann.  Mag.  Nat.  Hist. (5), 20.

TATEM, T. G. ’67.  New species of microscopic animals.  Q. J. M. S.
      (n.s.), VII, p. 251.

VEJDOWSKY, F. ’79.  Monographie der Enchytraeiden.  Prag, 1869.

WALLENGREN, H. ’94.  Studier ofver ciliata Infusorier, 1.  Slagtet
      Lichnophora.  Lund, 1894.

Page 62

WALLICH, G. C. ’63.  Observations on an undescribed indigenous Amoeba. 
      Ann.  Mag.  Nat.  Hist. (3), XI, XII.

WESTON, J. ’56.  On the Actinophrys sol.  Q. J. M. S., IV, p. 116.

WRZESNIOWSKI A. ’61.  Observations sur quelques Infusoires.  Ann. d.
      sc. nat. zool. (6), XVI.

——­ ’69.  Ein Beitrag zur Anatomie der Infusorien.  Arch. f. mik. 
      Anat., V, p. 25.

——­ ’70.  Beobachtungen ueber Infusorien a. d.  Umgebung v.  Warschau. 
      Zeit. wiss.  Zool., XX, p. 467.