Anabaena

For Anabaena A.Juss., a plant genus of the Euphorbiaceae, see its synonym Romanoa.
Anabaena
Anabaena flos-aquae
Scientific classification
Kingdom: Bacteria
Phylum: Cyanobacteria
Class: Hormogoneae
Order: Nostocales
Family: Nostocaceae
Genus: Anabaena
Bory de Saint-Vincent ex Bornet & Flahault, 1886[1]
Species

A. aequalis
A. affinis
A. angstumalis angstumalis
A. angstumalis marchita
A. aphanizomendoides
A. azollae
A. bornetiana
A. catenula
A. cedrorum
A. circinalis
A. confervoides
A. constricta
A. cyanobacterium
A. cycadeae
A. cylindrica
A. echinispora
A. felisii
A. flos-aquae flos-aquae
A. flos-aquae minor
A. flos-aquae treleasei
A. helicoidea
A. inaequalis
A. lapponica
A. laxa
A. lemmermannii
A. levanderi
A. limnetica
A. macrospora macrospora
A. macrospora robusta
A. monticulosa
A. nostoc
A. oscillarioides
A. planctonica
A. raciborskii
A. scheremetievi
A. sphaerica
A. spiroides crassa
A. spiroides spiroides
A. subcylindrica
A. torulosa
A. unispora
A. variabilis
A. verrucosa
A. viguieri
A. wisconsinense
A. zierlingii

Anabaena spiroides

Anabaena is a genus of filamentous cyanobacteria that exist as plankton. They are known for nitrogen-fixing abilities, and they form relationships with certain plants, such as the mosquito fern. They are one of four genera of cyanobacteria that produce neurotoxins, which are harmful to local wildlife, as well as farm animals and pets. Production of these neurotoxins is assumed to be an input into its symbiotic relationships, protecting the plant from grazing pressure.

A DNA sequencing project was undertaken in 1999, which mapped the complete genome of Anabaena, which is 7.2 million base pairs long. The study focused on heterocysts, which convert nitrogen into ammonia. Certain species of Anabaena have been used on rice paddy fields, proving to be an effective natural fertilizer.

Nitrogen fixation by Anabaena

Under nitrogen-limiting conditions, vegetative cells differentiate into heterocysts at semiregular intervals along the filaments. Heterocyst cells are terminally specialized for nitrogen fixation. The interior of these cells is micro-oxic as a result of increased respiration, inactivation of O2-producing photosystem (PS) II, and formation of a thickened envelope outside of the cell wall. Nitrogenase, sequestered within these cells, transforms dinitrogen into ammonium at the expense of ATP and reductant—both generated by carbohydrate metabolism, a process supplemented, in the light, by the activity of PS I. Carbohydrate, probably in the form of glurose, is synthesized in vegetative cells and moves into heterocysts. In return, nitrogen fixed in heterocysts moves into the vegetative cells, at least in part in the form of amino acids.[2]

Primitive vision pigments studied in Anabaena

Anabaena is used as a model organism to study simple vision. The process in which light changes the shape of molecules in the retina, thereby driving the cellular reactions and signals that cause vision in vertebrates, is studied in Anabaena. Anabaena sensory rhodopsin, a specific light-sensitive membrane protein, is central to this research.[3]

References

  1. Anabaena Bory de Saint-Vincent ex Bornet & Flahault, 1886: 180, 224
  2. Herrero, Antonia; Flores, Enrique, eds. (2008). The Cyanobacteria: Molecular Biology, Genomics and Evolution (1st ed.). Caister Academic Press. ISBN 978-1-904455-15-8.
  3. Schapiro, Igor (May 2014). "Ultrafast photochemistry of Anabaena Sensory Rhodopsin: Experiment and theory". Biochimica et Biophysica Acta. 1837 (5): 589–597. doi:10.1016/j.bbabio.2013.09.014. Retrieved 2014-06-25.

Further reading

External links

Guiry, M.D.; Guiry, G.M. (2008). "Anabaena". AlgaeBase. World-wide electronic publication, National University of Ireland, Galway. 

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