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Symbiotic bacteria

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Symbiotic bacteria are bacteria living in symbiosis with another organism or each other. For example, Zoamastogopera, found in the stomach of termites, enable them to digest cellulose.

Contents

• 1Definition

• 2Terms associated with "symbiosis"

• 3Types of symbiosis

• 4Symbiotic relationships

• 5Characteristics

• 6References

Definition[edit source]

Symbiosis was first defined by Anton de Bary in 1869 in a work entitled "Die Erscheinung der Symbiose"^[1] in which he defined the term as "namely, the living together of parasite and host".

Terms associated with "symbiosis"[edit source]

Associated with the term "symbiosis" are terms: mutualism, commensalism, parasitism, and amensalism.^[2] This may define or limit the type of "living together" of two organisms, be they plant, animal, protist or bacteria they practice.

Types of symbiosis[edit source]

Some types of cyanobacteria are endosymbiont.

Symbiotic relationships[edit source]

Certain plants establish a symbiotic relationship with bacteria, enabling them to produce nodules that facilitate the conversion of atmospheric nitrogen to ammonia. In this connection, cytokinins have been found to play a role in the development of root fixing nodules.^[3] It appears that not only must the plant have a need for nitrogen fixing bacteria, but they must also be able to synthesize cytokinins which promote the production of root nodules, required for nitrogen fixation.

Symbiotic bacteria are able to live in or on plant or animal tissue. In digestive systems, symbiotic bacteria help break down foods that contain fiber. They also help produce vitamins. Symbiotic bacteria can live near hydrothermal vents. They usually have a mutual relationship with other bacteria. Some live in tube worms.

Characteristics[edit source]

Corals have been found to form characteristic associations with symbiotic nitrogen-fixing bacteria.^[4] Corals have evolved in oligotrophic waters which are typically poor in nitrogen. Corals must therefore form a mutualistic relationship with nitrogen fixing organism, in this case the subject of this study, namely Symbiodinium. In addition to this dinoflagellate, coral also form relationships with bacteria, archae and fungi.^[5]The problem is that these dinoflagellates are also nitrogen limited and must form a symbiotic relationship with another organism; here it is suggested to be diazotrophs. In addition, cyanobacteria have been found to possess genes that enable them to undergo nitrogen fixation.^[6] This particular study goes further to investigate the possibility that in addition to the named dinoflagellate and certain cyanobacteria, endosymbiotic algae and the coral contain enzymes enabling them to both undergo ammonium assimilation.

Due to the small size of the genome of most endosymbionts, they are unable to exist for any length of time outside of the host cell, thereby preventing a long-term symbiotic relationship. However, in the case of the endonuclear symbiotic bacterium Holospora, it has been discovered^[7] that Holospora species can maintain their infectivity for a limited time and form a symbiotic relationship with Paramecium species.

It is well accepted and understood that there is a mutualistic relationship between plants and rhizobial bacteria and mycorrhizal fungi enabling the plants to survive in an otherwise nitrogen-poor soil environment. Co-evolution is described as a situation where two organisms evolve in response to one another. In a study reported in Functional Ecology,^[8] these scientists investigated whether such a mutualistic relationship conferred an evolutionary advantage to either plant or symbiont. They did not find that the rhizobial bacteria studied had any evolutionary advantage with their host but did find great genetic variation among the populations of rhizobial bacteria studied.

Organisms typically establish a symbiotic relationship due to their limited availability of resources in their habitat or due to a limitation of their food source. Triatomine vectors have only one host and therefore must establish a relationship with bacteria to enable them to obtain the nutrients required to maintain themselves.^[9]

A use for symbiotic bacteria is in paratransgenesis for controlling important vectors for disease, such as the transmission of Chagas disease by Triatome kissing bugs. Symbiotic bacteria in legume roots provide the plants with ammonia in exchange for the plants' carbon and a protected home.

Symbiotic, chemosynthetic bacteria that have been discovered associated with mussels (Bathymodiolus) located near hydrothermal vents have a gene that enables them to utilize hydrogen as a source of energy, in preference to sulphur or methane as their energy source for production of energy.^[2]

References[edit source]

1. ^ "Symbiosis and Mutualism". The American Naturalist. 27 (318): 509. June 1893. doi:10.1086/275742.

2. ^ Jump up to:^a b Petersen, Jillian M.; Frank U. Zielinski; Thomas Pape; Richard Seifert; Cristina Moraru; et al. (2011-08-11). "Hydrogen is an energy source for hydrothermal vent symbioses". Nature. 476 (7359): 176–180. doi:10.1038/nature10325. ISSN 0028-0836. PMID 21833083. 

3. ^ Frugier, Florian; Kosuta, Sonja; Murray, Jeremy D.; Crespi, Martin; Szczyglowski, Krzystztof (March 2008). "Cytokinin". Trends in Plant Science. 13 (3): 115–120. doi:10.1016/j.tplants.2008.01.003.

4. ^ Applied and Environmental Microbiology, May 2012, vol 78, no 9, pages 3136–3144, Kimberly A. Lema, Bette L. Willis, and David G. Bourne

5. ^ Multispecies microbial mutualizes on coral reefs: the host as a habitat. Am. Nat. 162:S51-S62, Knowlton N., Rohwer F.

6. ^ Lema et al. article

7. ^ European Journal of Protistology, Volume 48, Issue 2, May 2012, pages 124–137, Masahiro Fujishima and Yuuki Kodama

8. ^ Functional Ecology, Vo. 26, Issue 2, pages 457–468, Luke G. Barrett, Linda M. Broadhurst, and Peter H. Thrall

9. ^ Beard, C.B.; Dotson, E.M.; Pennington, P.M.; Eichler, S.; Cordon-Rosales, C.; Durvasula, R.V. (May 2001). "Bacterial symbiosis and paratransgenic control of vector-borne Chagas disease". International Journal for Parasitology. 31 (5–6): 621–627. doi:10.1016/s0020-7519(01)00165-5.

Categories: 

• Symbiosis

• Bacteriology

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• This page was last edited on 4 November 2018, at 13:59.