Difference between revisions of "Wolinella succinogenes"
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Revision as of 19:52, 5 June 2007
A Microbial Biorealm page on the genus Wolinella succinogenes
Higher order taxa
cellular organisms; Bacteria; Proteobacteria; delta/epsilon subdivisions; Epsilonproteobacteria; Campylobacterales; Helicobacteraceae; Wolinella
=Description and significance
Wolinella succinogenes belongs to th epsilon subclass of proteobacteria along with its close relatives Helicobacter pylori, Helicobacter hepaticus, and Campylobacter jejuni. H.pyori and C. jejuni are of the groups Helicobacteraceae and Campylobacteraceae respectively which are harmful pathogens in humans and animals. H. pylori has been associated with ulcers and gastric cancer and C. jejuni has been found to cause the illness guillain-Barre syndrome. Although Wolinella succinogenes has been coined as a member of Helicobacteraceae, it exists phylogenetically as an intermediate between the two groups mentioned. It was originally isolated from cattle rumen where it inhabits and then was reisolated by other molecular methods. Although it is found to be a nonpathogenic host asociated organism, it contains many virulance genes that are identical to those in throughout the rest of the Helicobacteraceae and Campylobacteraceae groups.(3)
Shotgun sequencing of Wolinella succinogenes revealed that it is composed of a circular chromosome of 2,110,355 base pairs. No plasmids were found (1). Having a larger genome content than relatives H. pylori, H. hepiticus,and C.jejuni, enables W.succinogenes to adapt to its bovine host rather its counterparts that occupy humans and rodents. "The close relatedness W.succinogenes has to the other three species, [H.pylori, H. hepiticus, C.jejuni], has been demonstrated using morphological, physiological, and molecular classification methods, and this reflected in their gene content as they share ~50% of their genes". (2) This large range of uniformity in genomic content along with W.succinogenes having a larger genomic content suggests that the four relatives stem from a larger ancestral genome. Flexibe genomic islands and islets have been observed in particular regions of the genome suggesting that recent gene transfer into W. succinogenes may have occured. Therefore, "The 29% larger genome of W. succinogenes codes for genes not found in any of its epsilon-proteobacterial relatives...seem[ing] likely that W. succinogenes may not be restricted to its ecological niche in the bovine rumen."(1)
Cell structure and metabolism
Wolinella succinogenes is a cylindrical shaped organism with a single flagella at one of its poles. It is a nonfermenting bacterium with fumurate as its sole carbon source. Therefore it undergoes anaerobic fumerate respiration. There is no evidence for Wolinella succinogenes also contains protective enzymes that allow the bacteria to deal with reactive oxygen that may alter the cell. There is no evidence for glucose fermentation however the phosofructokinase-encoding gene provides a pathway from glucose-6 phosphate to pyruvate suggesting that "W.succinogenes uses glycolytic enzynes solely for gluconeogenisis." (1)
Describe any interactions with other organisms (included eukaryotes), contributions to the environment, effect on environment, etc.
There is no current evidence indicating that Wolinella succinogenes iteslf is pathogenic although its close relatives are. There are however identical virulance factors seen in W. succinogenes that are also seen elsewhere. Although H. pylori is a very close relative, it has be found that W.succinogenes contains many genes that have been identified as virulance factors in C.jujeni. In particular, the key pathogen agent of C.jejuni, "antigen B", is also found in W.succinogenes but not in any of the other close relatives. (1)
Application to Biotechnology
Does this organism produce any useful compounds or enzymes? What are they and how are they used?
1. Stephan C. Schuster, Associate Professor of Biochemistry and Molecular Biology has provided much information of his work on Wolinella succinogenes. Current research in his lab at Penn State University is working toward identifying genes unique to w. succinogenes, C. jejuni, and H. pylori. He states that "by studying those genes that are being shared by all three organisms, [he] can identify essential molecular mechanisms used by symbiotic, commensal or pathogenic bacteria to maintain themselves in a vertebrate host environment.(4)
(1) Baar C et al. (2003)
Baar, C., Eppinger, M., Raddatz, G., Simon, J., Lanz, C., Klimmek, O., Nandakumar, R., Gross, R., Rosinus, A., Keller, H., Jagtap, P., Linke, B., Meyer, F., Lederer, H., and Schuster, S.C. "Complete genome sequence and analysis of Wolinella succinogenes." Proc. Natl. Acad. Sci. USA (2003) 100:11690-11695.
(2)Epinge, M., Baar, C., Raddarz, G., Huson, D., Schuster, S. "Comparative Analysis of Four Campylobacterales." Nature Reviews Microbiology, 2, 872-885.
(3)Mileni, M., MacMillan, F., Tziatzios, C., Zwicker, K., Haas, A., Mäntele, W., Simon, J., Lancaster, C. "Heterologous production in Wolinella succinogenes and characterization of the quinol:fumarate reductase enzymes from Helicobacter pylori and Campylobacter jejun." Biochem J. 2006 April 1; 395(Pt 1): 191–201.
Published online 2006 March 15. Prepublished online 2005 December 21. doi: 10.1042/BJ20051675.
Copyright The Biochemical Society, London.
(4) Stephan C. Schuster. Associate Professor of Biochemistry and Molecular Biology. "Genome evolution in host-adapted bacteria." website: http://www.bmb.psu.edu/faculty/schuster/schuster.html
Edited by Desiree Navadeh, student of Rachel Larsen and Kit Pogliano