Pre_GI: SWBIT SVG BLASTP

Query: NC_008593:1461771 Clostridium novyi NT, complete genome

Lineage: Clostridium novyi; Clostridium; Clostridiaceae; Clostridiales; Firmicutes; Bacteria

General Information: This strain (NT) was created so that it lacks the lethal toxin. Injection of spores of this organism into mice harboring tumors resulted in an increased immune response and destruction of the tumor tissue in a method known as COBALT (combination bacteriolytic therapy) when the spores along with chemotherapeutic agents or radiation are co-administered. The anaerobic bacteria preferentially target hypoxic cancer tissue and stimulate immune responses to that tissue. This genus comprises about 150 metabolically diverse species of anaerobes that are ubiquitous in virtually all anoxic habitats where organic compounds are present, including soils, aquatic sediments and the intestinal tracts of animals and humans. This shape is attributed to the presence of endospores that develop under conditions unfavorable for vegetative growth and distend single cells terminally or sub-terminally. Spores germinate under conditions favorable for vegetative growth, such as anaerobiosis and presence of organic substrates. It is believed that present day Mollicutes (Eubacteria) have evolved regressively (i.e., by genome reduction) from gram-positive clostridia-like ancestors with a low GC content in DNA. Some species are capable of producing organic solvents (acetone, ethanol, etc,), molecular hydrogen and other useful compounds. Clostridium novyi is an anaerobic bacterium found in soil, aquatic sediments, and intestinal tract of both animals and humans. Some types produce lethal toxins.

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Subject: NC_014328:1307490 Clostridium ljungdahlii ATCC 49587 chromosome, complete genome

Lineage: Clostridium ljungdahlii; Clostridium; Clostridiaceae; Clostridiales; Firmicutes; Bacteria

General Information: This strain was isolated from chicken yard waste and is studied for its ability to produce ethanol. This acetogenic species has the ability to convert carbon monoxide into ethanol. The yield of this process has been increased substantially in the laboratory by using a dual-fermentation system. A methanogenic conversion step has also been designed for utilizing some of the waste products generated during the synthetic process.