Sporomusa silvacetica: Difference between revisions
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''Sporomusa silvacetica'' has also been identified as an anaerobe and homoacetogen. Consequently, the organism catalyzes acetate for energy to be used in its metabolism for growth[5]. Growing conditions of 25-30°C and pH 6.8 were defined as the optimal conditions for ''Sporomusa silvacetica''. Doubling time of the bacteria was 14 hours when grown under these conditions and fructose was used as the substrate. ''Sporomusa silvacetica'' colonies grown on fructose are shiny beige yellow and approximately 2-3 mm in diameter. The bacteria are also capable at growing at temperatures as low as 5-10°C. | ''Sporomusa silvacetica'' has also been identified as an anaerobe and homoacetogen. Consequently, the organism catalyzes acetate for energy to be used in its metabolism for growth[5]. Growing conditions of 25-30°C and pH 6.8 were defined as the optimal conditions for ''Sporomusa silvacetica''. Doubling time of the bacteria was 14 hours when grown under these conditions and fructose was used as the substrate. ''Sporomusa silvacetica'' colonies grown on fructose are shiny beige yellow and approximately 2-3 mm in diameter. The bacteria are also capable at growing at temperatures as low as 5-10°C. | ||
==Genome Structure== | ==Genome Structure== |
Revision as of 14:10, 23 April 2014
Classification
Kingdom: Bacteria
Phylum: Firmicutes
Class: Negativicutes
Order: Selenomonadales
Family: Veillonellaceae
Genus: Sporomusa
Species: Sporomusa silvacetica
Species
NCBI: Taxonomy |
Sporomusa silvacetica
The genus name Sporomusa means “spore-bearing banana,” which describes the slightly curvy rod shaped cells of bacteria belonging to this particular genus.
Description and Significance
Sporomusa silvacetica was first discovered in the late 1990s in Geisberger Forest in east-central Germany. Kuhner and his team isolated the bacteria from a sample of drained forest soil. Like all bacteria belonging to the genus Sporomusa, Sporomusa silvacetica has curvy rod shaped cells and produces spherical shaped spores. The approximate cell size was measured as 3.5 by 0.7 µm. The bacterial cells are motile by means of a flagellum for propulsion, which is located on the concave side of the cell. Sporomusa silvacetica has a multilayered cell wall, however the individual layers that make up the cell wall are not very thick. Consequently, Gram staining causes the bacteria to stain weakly Gram-positive[2].
Sporomusa silvacetica has also been identified as an anaerobe and homoacetogen. Consequently, the organism catalyzes acetate for energy to be used in its metabolism for growth[5]. Growing conditions of 25-30°C and pH 6.8 were defined as the optimal conditions for Sporomusa silvacetica. Doubling time of the bacteria was 14 hours when grown under these conditions and fructose was used as the substrate. Sporomusa silvacetica colonies grown on fructose are shiny beige yellow and approximately 2-3 mm in diameter. The bacteria are also capable at growing at temperatures as low as 5-10°C.
Genome Structure
This genome has not been sequenced, therefore the protein coding and other operations of the genome are speculative.
16s Ribosomal DNA & Related Bacterial Species
Metabolism
Sporomusa silvacetica is an anaerobic bacterium that uses acetogenesis for metabolism. Sporomusa silvacetica can utilize many different substrates in order to grow including ferulate, vanillate, fructose, betaine, fumarate, 2,3-butanediol, pyruvate, lactate, glycerol, ethanol, methanol, formate, and H2-CO2 [2]. Acetate is the primary reduced end product in most of the reactions using these substrates. This bacterium can use electron acceptors other than CO2 in order to conserve energy. Sporomusa silvacetica is the first discovered case in the Sporomusa genus to use fumarate and aromatic acrylate groups as terminal electron acceptors. It also can dismutate fumarate into succinate and acetate [2]. The acetyl-coenzyme A pathway is the primary pathway used when H2-CO2 is present [3]. Small traces of methane have also been produced when Sporomusa silvacetica utilizes H2-CO2. Neither nitrate nor sulfate was found to be the preferred terminal electron acceptor in any of these cases [2].
Oxygen
Oxygen can damage enzymes used in the acetyl-coenzyme A pathway in Sporomusa silvacetica. However, acetate production in Sporomusa silvacetica actually increases due to oxidative stress [1]. The amount of acetate production required for cell growth increases, and allows Sporomusa silvacetica to grow in environments that are not completely anaerobic. This is due to aerotolerance in the cell. Cell extracts of Sporomusa silvacetica contain various levels of perosidase to consume H202, and NADH oxidase to consume O2. The cell then rids itself of these toxic products [1].
Wood-Ljungdahl Pathway
When Sporomusa silvacetica grow in the presence of H2-CO2, the Wood-Ljungdahl Pathway is utilized within the cell [4]. This pathway is also called the acetyl-coenzyme A pathway. CO2 is converted into either cellular carbon, or acetyl phosphate and ATP. Carbon first enters the pathway at the CO2 reduction step and uses H2 as the electron donor. It is then reduced to CO. Acetyl–CoA is then produced by condensing a methyl group with CO using coenzyme A. Acetyl-CoA is then either used to make cellular carbon, or is converted into acetyl phosphate in order to make ATP and acetate for the cell [4].
Ecology
Sporomusa silvacetica is an organism that was isolated from well-drained soil in a beech forest east-central Germany. It uses H2-CO2 from the environment around it, and also utilizes its habitat for various sources of Carbon. It can adapt to environments that are strictly not anaerobic. It also utilizes H2 from various samples of tundra soils, forests, and prairies [1].
References
Author
Page authored by Bevneet Grewal, Jenna Mitchell, & Raajan Naik, students of Prof. Jay Lennon at Michigan State University.