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Closterium
Closterium sp.
Scientific classification Edit this classification
(unranked): Viridiplantae
(unranked): Charophyta
Class: Zygnematophyceae
Order: Desmidiales
Family: Closteriaceae
Genus: Closterium
Nitzsch ex Ralfs, 1848
Species

See text.

Closterium is a genus of desmid, a group of charophyte green algae. [1] It is placed in the family Closteriaceae. [2] Species of Closterium are a common component of freshwater microalgae flora worldwide. [3]

Description

Closterium is a diverse genus consisting of solitary cells, each made of two identical halves called semicells. Usually they are microscopic, but the largest can become easily visible to the naked eye. Cells are many times longer than broad, and are variously elongate to lunate (crescent-shaped). The poles are rounded, truncated, or pointed. The surface of the cell may be smooth or decorated with various features, such as striations or punctae. The cell wall is transparent, but with age it may become dark brown due to accumulated iron and manganese compounds. [2] The cell nucleus is located in the middle of the cell. Each semicell contains a single axial chloroplast dotted with several pyrenoids. [4]

At either end of the cell, there is a generally a polar vacuole. The vacuoles often contain conspicuous barium sulfate crystals. [4]

Taxonomy

Closterium regulare was first described from Lower Normandy by Brebisson. [5]

Species

Closterium sp. during a miotic phase (upper-left is a diatom)
Closterium sp.
Closterium sp.

Closterium includes the following species:

Reproduction

Asexual: binary fission from a partitioned parent cell.

Sexual: Conjugation to form a hypnozygote.

The Closterium peracerosum-strigosum-littorale (C. psl) complex is a unicellular, isogamous charophycean alga cells that is the closest unicellular relative to land plants. These algae are capable of forming two types of dormant diploid zygospores. Some populations form zygospores within single clones of cells ( homothallic), whereas others form zygospores between different clones of cells ( heterothallic). The heterothallic strains have two mating types, mt(-) and mt(+). When cells of opposite mating types are mixed in a nitrogen-deficient mating medium, mt(-) and mt(+) cells pair with each other and release protoplasts. This release is then followed by protoplast fusion (conjugation) leading to formation of a diploid zygospore. Sex pheromones termed protoplast-release inducing proteins produced by mt(-) and mt(+) cells facilitate this process. [6]

A homothallic strain of Closterium forms selfing zygospores via the conjugation of two sister gametangial cells derived from one vegetative cell. [7] Conjugation in the homothallic strain occurs mainly at low cell density and is regulated by an ortholog of a heterothallic sex-specific pheromone.

Although self-fertilization employs meiosis, it produces minimal genetic variability. Homothallism is thus a form of sex that is unlikely to be adaptively maintained by a benefit related to producing variability. However, homothallic meiosis may be maintained in Closterium peracerosum as an adaptation for surviving under stressful conditions such as growth in nitrogen depleted media at low cell density. A proposed adaptive benefit of meiosis is the promotion of homologous recombinational repair of DNA damages that can be caused by a stressful environment [8]

Habitats

Like other desmids, Closterium is found in freshwater habitats. Closterium is usually attached to sediments or aquatic plants, but may sometimes be planktonic, i.e. free-floating in the water column, or found in wet soils. [4] Most species prefer oligotrophic and slightly acidic waters, but a few species (for example Closterium aciculare) prefer eutrophic, slightly alkaline lakes. [3]

References

  1. ^ See the NCBI webpage on Closterium. Data extracted from the "NCBI taxonomy resources". National Center for Biotechnology Information. Retrieved 2007-03-19.
  2. ^ a b Bicudo, Carlos E. M.; Menezes, Mariângela (2006). Gêneros de Algas de Águas Continentais do Brasil: chave para identificação e descrições (2 ed.). RiMa Editora. p. 508. ISBN  857656064X.
  3. ^ a b Bellinger, Edward G.; Sigee, David C. (23 February 2015). Freshwater Algae: Identification, Enumeration and Use as Bioindicators (2nd ed.). Wiley. ISBN  978-1-118-91716-9.
  4. ^ a b c Hall, John D.; McCourt, Richard M. (2014). "Chapter 9. Conjugating Green Algae Including Desmids". In Wehr, John D.; Sheath, Robert G.; Kociolek, J. Patrick (eds.). Freshwater Algae of North America: Ecology and Classification (2 ed.). Elsevier Inc. ISBN  978-0-12-385876-4.
  5. ^ Carter, C.F. and Williamson, D.B. (2008) A rediscovered UK desmid: Closterium regulare Breb The Phycologist. Autumn 2008 No.75:24
  6. ^ Sekimoto H, Satoh S, Fujii T (1990). "Biochemical and physiological properties of a protein inducing protoplast release during conjugation in theClosterium peracerosum-strigosum-littorale complex". Planta. 182 (3): 348–54. doi: 10.1007/BF02411384. PMID  24197184. S2CID  1999634.
  7. ^ Tsuchikane Y, Kokubun Y, Sekimoto H (2010). "Characterization and molecular cloning of conjugation-regulating sex pheromones in homothallic Closterium". Plant Cell Physiol. 51 (9): 1515–23. doi: 10.1093/pcp/pcq110. PMID  20656896.
  8. ^ Mirzaghaderi G, Hörandl E (2016). "The evolution of meiotic sex and its alternatives". Proc. Biol. Sci. 283 (1838). doi: 10.1098/rspb.2016.1221. PMC  5031655. PMID  27605505.

External links