Blepharisma

Blepharismin C
Names
	IUPAC name 5,7,11,13,17,19,23,25-octahydroxy-15-(4-hydroxyphenyl)-6,24-di(propan-2-yl)octacyclo[14.11.1.12,10.03,8.04,26.020,28.022,27.014,29]nonacosa-1,3,5,7,10(29),11,13,16,18,20(28),22,24,26-tridecaene-9,21-dione
Identifiers
CAS Number	129898-49-3 ;
3D model (JSmol)	Interactive image ;
ChemSpider	9942356 ;
PubChem CID	11767671 ;
	InChI InChI=1S/C41H30O11/c1-11(2)19-36(47)32-30-28-26-22(15(43)9-17(45)24(26)40(51)34(30)38(19)49)21(13-5-7-14(42)8-6-13)23-16(44)10-18(46)25-27(23)29(28)31-33(32)37(48)20(12(3)4)39(50)35(31)41(25)52/h5-12,21,42-50H,1-4H3 Key: FRDONCXLMWOCKJ-UHFFFAOYSA-N;
	SMILES CC(C)C1=C(C2=C3C4=C5C6=C(C(=CC(=C6C(C7=C(C=C(C(=C74)C(=O)C3=C1O)O)O)C8=CC=C(C=C8)O)O)O)C(=O)C9=C(C(=C(C2=C59)O)C(C)C)O)O;
Properties
Chemical formula	C41H30O11
Molar mass	698.680 g·mol−1
	Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). Infobox references

Blepharisma
	Blepharisma japonicum
Scientific classification
Domain:	Eukaryota
Clade:	Diaphoretickes
Clade:	SAR
Clade:	Alveolata
Phylum:	Ciliophora
Class:	Heterotrichea
Order:	Heterotrichida
Family:	Blepharismidae
Genus:	Blepharisma ; Perty, 1852

Last updated February 02, 2024

Blepharisma is a genus of unicellular ciliate protists found in fresh and salt water. The group includes about 40 accepted species, and many sub-varieties and strains. While species vary considerably in size and shape, most are easily identified by their red or pinkish color, which is caused by granules of the pigment blepharismin.^[1]

All members of the genus possess a long series of membranelles on the left side of the oral groove, and an "undulating membrane" (a structure resembling a flap, scarf or small sail, composed of long cilia fused together as a single sheet) on the right side of the peristome, toward the posterior.^[2]

Certain species of Blepharisma have served as model organisms for scientific research. Since some varieties are easily cultured and readily available from scientific supply houses, they are a common object of study in school science classes.

Appearance

Blepharisma may be as small as 50 micrometres in length, or as large as 1 mm (though normal size range is between 75 and 300 micrometres).^[2] Body shape varies within the genus. The type species of the genus, B. persicinum, is ellipsoidal. Blepharisma lateritium is teardrop-shaped, with a rounded posterior; while Blepharisma elongatum and Blepharisma sphagni are long and thin, tapering at the posterior into a tail-like point.^[3]

All species are uniformly ciliated, with the cilia arranged in longitudinal rows, and stripes of pigment alternating between rows of cilia. Cilia, short hairlike organelles, sweep food into its mouth and are used for movement.^[4] The pink or red pigmentation may be quite pale, and in certain cases it is absent altogether.^[5] A contractile vacuole, often quite large, is located in the posterior. The Macronuclei can take a variety of forms. Depending on species and phase of life, they may be rod-shaped, ovoid, spherical, or moniliform (like a rosary, or string of beads).

Reproduction and sexual phenomena

Like all ciliates, Blepharisma reproduce asexually, by binary fission, dividing transversally. Fission may occur spontaneously, as part of the vegetative cell cycle, or it may follow a sexual phenomenon called conjugation, a process through which genetic material is exchanged between cells. In conjugation, two organisms come into close contact, and a temporary cytoplasmic bridge forms between them. The micronuclei of each cell then undergo meiosis, and haploid micronuclei pass from one individual to the other. This permits the reshuffling of hereditary characteristics, as in other types of sexual reproduction. Conjugation is immediately followed by binary fission of the two conjugants.^[6]

In Blepharisma, as in some other ciliates, chemical substances called gamones are used to induce conjugation by stimulating interaction between compatible mating partners.^[7]

Although clonal cells of Blepharisma are sometimes able to conjugate with one another (a phenomenon known as selfing),^[8] conjugation ordinarily involves the interaction of cells of different mating types. In the species Blepharisma japonicum, there are two mating types (I and II), each type excreting a specific pheromone (termed gamone 1 and gamone 2, respectively).^[8]^[9] When sexually mature mating-type I cells are moderately starved, they autonomously produce and secrete gamone I.^[8] Gamone 1 specifically acts on mating-type II cells, transforming them so that they can unite with type I cells, and inducing them to secrete gamone 2. Gamone 2 then transforms type I cells so that they can unite with type II cells. Cells that can unite may then undergo conjugation. Conjugation of opposite mating types promotes outcrossing and the masking of deleterious recessive mutations in the diploid phase of the sexual cycle.^[10]

Feeding and behavior

Blepharisma feed on a variety of smaller organisms, including bacteria, flagellate algae, rotifers, other ciliates and even smaller members of the same species. Experiments with Blepharisma undulans have shown that cannibalism causes gigantism. When individuals are given a diet of smaller Blepharisma, or certain ciliates (particularly Colpidium colpoda or Tetrahymena ), they grow to a relatively enormous size. As long as their diet remains unchanged, cannibal giants will divide to produce more giants. When large prey become unavailable, the offspring will revert to normal size.^[11]

Photobiology

Blepharisma are markedly photophobic, and when light levels are increased will seek out darkened areas. The ability to detect light is accomplished with photosensitive pigment granules located just under the plasma membrane of the cell. The pigment in these granules is blepharismin, the same substance that gives Blepharisma their characteristic pinkish color.^[12]Blepharisma are usually pink when collected in nature, but when grown in darkness with abundant food they turn red. Exposure to light or starvation causes them to lose their color, but deeply-pigmented cells can even be killed by strong light.^[13]

List of species

Blepharisma americanum swimming in a drop of pond water, with other microorganisms.

B. americanum Suzuki, 1954
B. bimicronucleatum Villeneuve-Brachon 1940
B. bothrostoma Mermod 1914
B. botezati Lepsi, 1926
B. coeruleum Gajevskaja, 1927
B. caudatus Dumas 1937
B. clarissimum Kahl, 1928
B. dawsoni Christie & Hirshfield 1967
B. dileptus Kahl, 1928
B. elegans Vuxanovici 1963
B. elongatum (Stokes, 1884) Kahl, 1926
B. falcatum Gelei 1954
B. galianoi Fernandez-Leborans 1979
B. grayi Hartwig & Parker, 1977
B. halophila Ruinen 1938
- Found to be a phylogenetic outlier under the orthographical variant Blepharisma halophilum.^[14]
B. hyalinum Perty, 1852
B. intermedium Bhandary, 1962
B. ichthyoides V. Gelei, 1933
B. japonicum (Suzuki, 1954) Giese, 1973
B. lateritium (Ehrenberg, 1831) Kahl, 1932
B. lentis Gelei 1954
B. melana Borror, 1963
B. minima Lepsi, 1926
B. multinucleata Dragesco, 1960
B. musculus Penard, 1922
B. ovalis Dumas 1937
B. ovatum Penard, 1922
B. parasalinarum Dragesco 1997
B. persicinum Perty, 1849
B. salinarum Florentin, 1899
B. seshachari Bhandary, 1962
B. sphagni Lepsi, 1926
B. steini Kahl, 1932
B. tardum Kahl, 1928
B. undulans Stein, 1868
B. velatum Vacelet, 1961
B. vestitum Kahl, 1928
B. violaceae Tucolesco 1962
B. vitreum Lepsi 1957
B. wardsi Hirshfield, Isquith & Bhandary, 1965

Related Research Articles

Tetrahymena, a unicellular eukaryote, is a genus of free-living ciliates. The genus Tetrahymena is the most widely studied member of its phylum. It can produce, store and react with different types of hormones. Tetrahymena cells can recognize both related and hostile cells.

The heterotrichs are a class of ciliates. They typically have a prominent adoral zone of membranelles circling the mouth, used in locomotion and feeding, and shorter cilia on the rest of the body. Many species are highly contractile, and are typically compressed or conical in form. These include some of the largest protozoa, such as Stentor and Spirostomum, as well as many brightly pigmented forms, such as certain Blepharisma.

<i>Paramecium</i> Genus of unicellular ciliates, commonly studied as a representative of the ciliate group

Paramecium is a genus of eukaryotic, unicellular ciliates, commonly studied as a model organism of the ciliate group. Paramecium are widespread in freshwater, brackish, and marine environments and are often abundant in stagnant basins and ponds. Because some species are readily cultivated and easily induced to conjugate and divide, they have been widely used in classrooms and laboratories to study biological processes. The usefulness of Paramecium as a model organism has caused one ciliate researcher to characterize it as the "white rat" of the phylum Ciliophora.

In biology, mating is the pairing of either opposite-sex or hermaphroditic organisms for the purposes of sexual reproduction. Fertilization is the fusion of two gametes. Copulation is the union of the sex organs of two sexually reproducing animals for insemination and subsequent internal fertilization. Mating may also lead to external fertilization, as seen in amphibians, fishes and plants. For most species, mating is between two individuals of opposite sexes. However, for some hermaphroditic species, copulation is not required because the parent organism is capable of self-fertilization (autogamy); for example, banana slugs.

Stentor, sometimes called trumpet animalcules, are a genus of filter-feeding, heterotrophic ciliates, representative of the heterotrichs. They are usually horn-shaped, and reach lengths of two millimeters; as such, they are among the largest known extant unicellular organisms. They reproduce asexually through binary fission.

<i>Vorticella</i> Genus of single-celled organisms

Vorticella is a genus of bell-shaped ciliates that have stalks to attach themselves to substrates. The stalks have contractile myonemes, allowing them to pull the cell body against substrates. The formation of the stalk happens after the free-swimming stage.

<i>Didinium</i> Genus of single-celled organisms

Didinium is a genus of unicellular ciliates with at least ten accepted species. All are free-living carnivores. Most are found in fresh and brackish water, but three marine species are known. Their diet consists largely of Paramecium, although they will also attack and consume other ciliates. Some species, such as D. gargantua, also feeds on non-ciliate protists, including dinoflagellates, cryptomonads, and green algae.

Spirostomum is a genus of ciliated protists in the class Heterotrichea. It is known for being very contractile. Having been first identified by Christian Gottfried Ehrenberg in 1834, further research has identified eight additional true morphospecies. This bacterivore genus mainly lives in the sediment deposits at the bottom of various aquatic habitats, and members possess rquA genes that could be responsible for their ability to survive in these hypoxic and anoxic environments. They are identifiable by their relatively large tubular/flat vermiform bodies. Their life cycle consists of a growth stage, in which they mature, and asexual and sexual reproduction stages. Some species are model organisms for studies on human pathogenic bacteria, while others are sensitive and accurate bioindicators for toxic substances.

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<i>Nassula</i> Genus of single-celled organisms

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The ciliates are a group of alveolates characterized by the presence of hair-like organelles called cilia, which are identical in structure to eukaryotic flagella, but are in general shorter and present in much larger numbers, with a different undulating pattern than flagella. Cilia occur in all members of the group and are variously used in swimming, crawling, attachment, feeding, and sensation.

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<i>Climacostomum</i> Genus of single-celled organisms

Climacostomum is a genus of unicellular ciliates, belonging to the class Heterotrichea.

Blepharisma japonicum is a species of protozoan that can be found either in water or soil in Japan.

<i>Dileptus margaritifer</i> Species of single-celled organism

Dileptus margaritifer is a species of ciliates in the family Dileptidae. It is common in freshwater streams, lakes and ponds, as well as mosses and soil. The species has been found on every continent except Antarctica.

Condylostoma is a genus of unicellular ciliate protists, belonging to the class Heterotrichea.

Parduczia is a genus of karyorelict ciliates in the family Geleiidae.

Halteria, sometimes referred to as the jumping oligotrich, is a genus of common planktonic ciliates that are found in many freshwater environments. Halteria are easy to locate due to their abundance and distinctive behaviour with observations of Halteria potentially dating back to the 17th century and the discovery of microorganisms. Over time more has been established about their morphology and behavior, which has led to many changes in terms of classification.

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References

↑ Miyake, Akio; et al. (June 29, 1990). "Defensive Function of Pigment Granules in Blepharisma japonicum". European Journal of Protistology. 25 (4): 310–315. doi:10.1016/S0932-4739(11)80122-7. PMID 23196043.
1 2 Hirshfield; et al. (1965). "A proposed organization of the genus Blepharisma Perty and description of four new species". The Journal of Protozoology. 12 (1): 136–144. doi:10.1111/j.1550-7408.1965.tb01826.x.
↑ Kahl, Alfred (1930–1935). F. Dahl (ed.). Urtiere oder Protozoa I: Wimpertiere oder Ciliata (Infusoria) In: Die Tierwelt Deutschlands. Vol. 3 Spirotricha. Jena: G. Fischer. pp. 442–448.
↑ Hanna, Jannette. "Blepharism". Micscape Magazine. Retrieved 29 June 2017.
↑ Giese, Arthur (Jan 1938). "Reversible bleaching of Blepharisma". Transactions of the American Microscopical Society. 57 (1): 77–81. doi:10.2307/3222804. JSTOR 3222804.
↑ Lynn, Denis H. (2007). The Ciliated Protozoa: Characterization, Classification and Guide to the Literature (3 ed.). Springer. p. 23.
↑ Sugiura, M.; et al. (31 May 2005). "Developmentally and environmentally regulated expression of gamone 1: the trigger molecule for sexual reproduction in Blepharisma japonicum". Journal of Cell Science. 118 (12): 2735–41. doi: 10.1242/jcs.02359 . PMID 15928050.
1 2 3 Miyake A. (1981). Cell interaction by gamones in Blepharisma In: Sexual Interactions in Eukaryotic Microbes (O’Day, D.H. editor), pp. 95-129 New York: Academic Press. ISBN 978-0124312975
↑ Sugiura M, Shiotani H, Suzaki T, Harumoto T (2010). "Behavioural changes induced by the conjugation-inducing pheromones, gamone 1 and 2, in the ciliate Blepharisma japonicum". Eur. J. Protistol. 46 (2): 143–9. doi:10.1016/j.ejop.2010.01.002. PMID 20167456.
↑ Bernstein C, Bernstein H (1997). "Sexual communication". J. Theor. Biol. 188 (1): 69–78. Bibcode:1997JThBi.188...69B. doi:10.1006/jtbi.1997.0459. PMID 9299310.
↑ Giese, Arthur (1938). "Cannibalism and Gigantism in Blepharisma". Transactions of the American Microscopical Society. 57 (3): 245–255. doi:10.2307/3222693. JSTOR 3222693.
↑ Matsuoka; et al. (2000). "Analyses of Structure of Photoreceptor Organelle and Blepharismin associated Protein in Unicellular Eukaryote Blepharisma". Photochemistry and Photobiology. 57 (3): 245–255. doi:10.1562/0031-8655(2000)0720709AOSOPO2.0.CO2. PMID 11107859. S2CID 204166047.
↑ Giese, Arthur C. (1981). "The Photobiology of Blepharisma". Photochemical and Photobiological Reviews. Springer, Boston, MA. pp. 139–180. doi:10.1007/978-1-4684-7003-1_4. ISBN 978-1-4684-7005-5.
↑ Chi, Yong; Chen, Xiangrui; Li, Yuqing; Wang, Chundi; Zhang, Tengteng; Ayoub, Alex; Warren, Alan; Song, Weibo; Wang, Yuanyuan (1 April 2021). "New contributions to the phylogeny of the ciliate class Heterotrichea (Protista, Ciliophora): analyses at family-genus level and new evolutionary hypotheses". Science China Life Sciences. 64 (4): 606–620. doi:10.1007/s11427-020-1817-5. PMID 33068287. S2CID 223558791.