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Portrait of Bicosoeca petiolata, a colorless loricate flagellate (synonymous with Poteriodendron petiolatum). This species is colonial with daughter cells forming stalks attached to the mother lorica after division. Most species of this genus are solitary. The cells of this colony are retracted with the long hair bearing flagellum tightly coiled on the anterior end of the cell (seen well in the cell on your left in this image). The second short smooth flagellum is directed posteriorly attaching the cell to its lorica. The lorica is organic. From fresh water marsh with Typha (Cattail) near Boise, Idaho. Differential interference contrast.
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San Martin De Castaneda, Castille and Leon, Spain
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Pseudodendromonas spec. Scale bar indicates 25 µm. The specimen was gathered in a tiny freshwater pond called Suploch on the island of Hiddensee (Baltic Sea, Germany). Sampling date 10/2018. The image was built up using several photomicrographic frames with manual stacking technique. Images were taken using Zeiss Standard with Olympus OM-D M5 MKII. Image under Creative Commons License V 3.0 (CC BY-NC-SA). Place name: Pond Suploch, Hiddensee (Germany) Latitude: 54,538638 Longitude: 13,097802 Multiebenen-Abbildung, manuell gestapelt. Der Messbalken markiert eine Länge von 25 µm. Probe aus dem Suploch, einem kleinen Süßwasserteich auf der Insel Hiddensee. Datum der Aufsammlung: 10/2018. Mikrotechnik: Zeiss Standard, Kamera: Olympus OM-D M5 MKII. Creative Commons License V 3.0 (CC BY-NC-SA). For permission to use of (high-resolution) images please contact postmaster@protisten.de.
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Portrait of Bicosoeca petiolata, a colorless loricate flagellate (synonymous with Poteriodendron petiolatum). This species is colonial with daughter cells forming stalks attached to the mother lorica after division. Most species of this genus are solitary. The cells of this colony are retracted. The second short smooth flagellum is directed posteriorly attaching the cell to its lorica. The lorica is organic. From fresh water marsh with Typha (Cattail) near Boise, Idaho. Differential interference contrast.
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Phase contrast micrograph showing the two short anterior flagella, the nucleus and the mitochondrion close to the base of the flagella.
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Bicosoeca spec. Scale bar indicates 10 µm. Sample from a tropical freshwater aquarium. The image was built up using several photomicrographic frames with manual stacking technique. Images were taken using Zeiss Axioplan with Canon EOS 600D.Image under Creative Commons License V 3.0 (CC BY-NC-SA). Place name: Tropical freshwater aquarium Latitude: 54,3018013 Longitude: 10,07120132 Der Messbalken markiert eine Länge von 10 µm. Probe aus einem Süßwasseraquarium für tropische Fische. Mikrotechnik: Zeiss Axioplan Kamera: Canon EOS 600D. Creative Commons License V 3.0 (CC BY-NC-SA). For permission to use of (high-resolution) images please contact postmaster@protisten.de.
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Bicosoeca epiphytica Hilliard, 1971. Bicosoeca cells with a body 3.5-6.5 x 2.5-4.5 microns long, lorica 8-10x3.5-5 microns The lorica of this species has an undulating surface. The lorica has about 8-10 ridges and is rounded at the posterior. It tapers slightly at the anterior, before a flared aperture. The lorica has a short pedicel, which is 0.5-1 times the lorica length, and terminates with a distal button as is characteristic in this genus.
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Bicosoeca vacillans Stole, 1888. Bicosoeca cells located in a stalked lorica, the chamber of which measured 17-25 microns long. The lorica chamber was approximately cylindrical with a slightly pointed posterior and a pedicel of 1-1.5 times the lorica length. Loricas may differ slightly in shape. The lorica wall was most frequently curved slightly outwards at the aperture to a greater or lesser extent and in some cases the lorica was waisted below the aperture. The lorica had fine horizontal bands spaced about 0.4 microns apart, with numerous fine perpendicular fibres in each band. Cells were sub-spherical and had a flattened indistinct peristome. The anterior flagellum was about 3 times the cell length and held at an angle to the longitudinal axis of the cell. The posterior flagellum was attached to the base of the lorica via a fine thread.
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This image was of material in samples taken during a scientific cruise in the Pacific. Water was filtered to concentrate the organisms that were present, then dried onto a thin sheet of plastic and then shadowed with a fine layer of metal to provide contrast. The preparation was then observed with an electron-microscope. This technique has been used to document the diversity of marine microbes, especially, protists in the oceans.
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Cafeteria (cafeteria) is probably the most abundant heterotrophic flagellate in marine ecosystems. It is a voracious bacterivore. Sessile feeding cells are D-shaped, 1.5 to 10 microns long, and laterally compressed. There is a ventral groove, and the flagella insert at the head of the groove. The anterior flagellum draws a current of water towards the cell, or pulls the cell forward when it is swimming around. Feeding cells are usually attached to the substrate by the tip of the second flagellum. This cell is a little swollen. Animations by Rosemary Arbur of flagellar beat patterns are available
here.Phase contrast.
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Cafeteria (cafeteria) is probably the most abundant heterotrophic flagellate in marine ecosystems. It is a voracious bacterivore. Sessile feeding cells are D-shaped, 1.5 to 10 microns long, and laterally compressed. There is a ventral groove, and the flagella insert at the head of the groove. These cells have been disturbed, and are not feeding. The anterior flagella have the sine-wave beat pattern that is characteristic of stramenopiles. The posterior flagella are shorter. Phase contrast.
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Cafeteria (cafeteria) is probably the most abundant heterotrophic flagellate in marine ecosystems. It is a voracious bacterivore. Sessile feeding cells are D-shaped, 1.5 to 10 microns long, and laterally compressed. There is a ventral groove, and the flagella insert at the head of the groove. The anterior flagellum draws a current of water towards the cell, or pulls the cell forward when it is swimming around. Feeding cells are usually attached to the substrate by the tip of the second flagellum. Phase contrast. Rotten picture.
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Cafeteria (cafeteria) roenbergensis Fenchel and Patterson, 1988. Cells are D-shaped, 2 to 5 microns long, and laterally compressed. There is a shallow groove on the left side of the cell. Two flagella of similar length emerge subapically and are slightly longer than the cell. The anterior flagellum is directed perpendicular to the ventral face of the cell of attached cells. The posterior flagellum is reflexed, passing over one face of the cell and then attaching to the substrate by the tip. In swimming cells, the anterior flagellum is directed forwards and beats with a sine-wave, and the posterior flagellum is directed backwards and trails. Usually the cells move fast following a spiral path, but sometimes move slowly. Bacteria may be ingested near the anterior part or posterior part of the ventral groove. Not common in sediments, widespread and abundant in the water column.
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Cafeteria roenbergensis Fenchel and Patterson, 1988. Cells are D-shaped, 2 to 5 microns long, and laterally compressed. There is a shallow groove on the left side of the cell. Two flagella of similar length emerge subapically and are slightly longer than the cell. The anterior (= feeding = hairy - the hairs are not visible by light microscopy) flagellum is directed perpendicular to the ventral face of the cell of attached cells. The posterior flagellum is reflexed, passing over one face of the cell and then attaching to the substrate by the tip. In swimming cells, the anterior flagellum is directed forwards and beats with a sine-wave, and the posterior flagellum is directed backwards and trails. Usually the cells move quickly following a spiral path, but sometimes they move slowly. Bacteria may be ingested near the anterior part or posterior part of the ventral groove.
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Cafeteria is a weed. When plenty of bacterial food is available, species of this genus will grow in great profusion. Dozens of cells are seen here near a piece of detritus. Animations by Rosemary Arbur of flagellar beat patterns are available
here. Phase contrast microscopy.
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Cafeteria (cafeteria) marsupialis Larsen and Patterson, 1990. Cells are D-shaped and somewhat variable in shape. When attached the cells are 5 to 12 microns long (mostly about 7 to 8 microns) and 5 to 10 microns wide, When swimming the cells are up to 7 to 10 microns long and 3 to 5 microns wide. The cells attach to the substrate by the tip of the posterior flagellum, which lies in a deep ventral groove. The anterior flagellum is directed normal to the groove. The organism may feed on suspended bacteria, which are drawn towards the body by the activity of the anterior flagellum, entering along a curved channel at the posterior end of the ventral groove. The anterior flagellum of the attached cell is about 1.5 to 2 times the cell length and the posterior flagellum is slightly longer than the cell. A single nucleus with a rounded nucleolus lies just below the insertion of the flagella. The cell body may include many - sometimes large - food vacuoles. Undigested residues of food are egested by the fusion of old food vacuoles with the plasma membrane. Swimming cells are more rounded, with anterior flagellum directed to the anterior, recurrent flagellum trailing. It often occurs with Carpediemonas membranifera and C. bialata. More frequent in slightly anaerobic preparations.
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Cafeteria marsupialis Larsen and Patterson, 1990. Cells are normally D-shaped but may be somewhat variable in shape. When attached the cells are 5 to 12 microns long (mostly about 7 to 8 microns) and 5 to 10 microns wide, When swimming the cells are up to 7 to 10 microns long and 3 to 5 microns wide. The cells attach to the substrate by the tip of the posterior flagellum, which lies in a deep ventral groove. The anterior flagellum is directed at right-angles to the groove. The organism may feed on suspended bacteria, which are drawn towards the body by the activity of the anterior flagellum, entering along a curved channel at the posterior end of the ventral groove. The anterior flagellum of the attached cell is about 1.5 to 2 times the cell length and the posterior flagellum is slightly longer than the cell. A single nucleus with a rounded nucleolus lies just below the insertion of the flagella. The cell body may include many - sometimes large - food vacuoles. Undigested residues of food are egested by the fusion of old food vacuoles with the plasma membrane. Swimming cells are more rounded, with anterior flagellum directed to the anterior, recurrent flagellum trailing. Common and widespread.
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Cafeteria (cafeteria) minuta (Ruinen, 1938) Larsen and Patterson, 1990. Cells are about 4 - 6 microns long with a small ventral groove. Two flagella emerge from the anterior end of the groove. The long anterior flagellum is about 2.5 - 4 times the cell length and beats with a sine-wave, and the posterior flagellum is about 1 - 1.5 times the cell length. When the cells swim, the anterior flagellum is directed forward and the posterior one trails. The cells may attach to the substrate by the tip of the posterior flagellum. Not common.
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Cafeteria minuta (Ruinen, 1938) Larsen and Patteron, 1990. Cells are almost globular, 3.5-4 microns but with a subapical ventral depression from which the flagella emerge. The hairy or feeding flagellum (the hairs are not visible with the light microscope), which projects in front of the swimming cell, measures 10-12 microns, and may beat with more than one complete sine wave along its length. Second flagellum about 5 microns, curves over the side of the body and may attach by its tip to the substratum.
