Query: NC_009328:2161116 Geobacillus thermodenitrificans NG80-2 chromosome, complete genome Lineage: Geobacillus thermodenitrificans; Geobacillus; Bacillaceae; Bacillales; Firmicutes; Bacteria General Information: Geobacillus thermodenitrificans NG80-2 was isolated from oil reservoir formation water taken at a depth of 2000 m and a temperature of 73 degrees C. This strain can use crude oil as a sole carbon source and can degrade 16 to 36 carbon alkanes. Geobacillus thermodenitrificans NG80-2 produces an emulsifier which may be useful for high temperature biodegradation or other industrial purposes. Members of this genus were originally classified as Bacillus. Recent rDNA analysis and DNA-DNA hybridization studies using spore-forming thermophilic subsurface isolates provided enough evidence to define the phylogenetically distinct, physiologically and morphologically consistent taxon Geobacillus. Geobacillus species are chemo-organotrophic, obligately thermophilic, motile, spore-forming, aerobic or facultatively anaerobic.
- Sequence; - BLASTN hit (Low score = Light, High score = Dark) - hypothetical protein; - cds: hover for description
General Information: Country: United Kingdom; Isolation: Sick cider; Temp: Mesophile. The natural habitat of this organism includes sugar-rich plant saps where the bacterium ferments sugar to ethanol. The high conversion of sugars to ethanol makes this organism useful in industrial production systems, particularly in production of bioethanol for fuel. A recombinant strain of this bacterium is utilized for the conversion of sugars, particularly xylose, which is not utilized by another common sugar-fermenting organism such as yeast, to ethanol. Since xylose is a common breakdown product of cellulose or a waste component of the agricultural industry, it is an attractive source for ethanol production. Zymomonas mobilis was chosen for this process as it is ethanol-tolerant (up to 120 grams of ethanol per litre) and productive (5-10% more ethanol than Saccharomyces). This bacterium ferments using the Enter-Doudoroff pathway, with the result that less carbon is used in cellular biomass production and more ends up as ethanol, another factor that favors this organism for ethanol production.