Pre_GI: SWBIT SVG BLASTN

Query: NC_004663:2437760 Bacteroides thetaiotaomicron VPI-5482, complete genome

Lineage: Bacteroides thetaiotaomicron; Bacteroides; Bacteroidaceae; Bacteroidales; Bacteroidetes; Bacteria

General Information: This is the type strain for this organism and was isolated from the feces of a healthy adult. Common gastrointestinal bacterium. This group of microbes constitute the most abundant members of the intestinal microflora of mammals. Typically they are symbionts, but they can become opportunistic pathogens in the peritoneal (intra-abdominal) cavity. Breakdown of complex plant polysaccharides such as cellulose and hemicellulose and host-derived polysaccharides such as mucopolysaccharides is aided by the many enzymes these organisms produce. Bacteroides thetaiotaomicron is one of the two major Bacteroidesspecies found in the intestine. This organism has been used in studies on gut microflora composition and succession.

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BLASTN Alignment.txt

Subject: NC_002932:440191 Chlorobium tepidum TLS, complete genome

Lineage: Chlorobaculum tepidum; Chlorobaculum; Chlorobiaceae; Chlorobiales; Chlorobi; Bacteria

General Information: This green-sulfur bacterium is a thermophile and was isolated from a New Zealand high-sulfide hot spring. Photosynthetic thermophile. Chlorobium tepidum is a member of the green-sulfur bacteria. It has been suggested that the green-sulfur bacteria were among the first photosynthetic organisms since they are anaerobically photosynthetic and may have arisen early in the Earth's history when there was a limited amount of oxygen present. This organism utilizes a novel photosynthetic system, and harvests light energy using an unusual organelle, the chlorosome, which contains an aggregate of light-harvesting centers surrounded by a protein-stabilized galactolipid monolayer that lies at the inner surface of the cytoplasmic membrane. Unlike many other photosynthetic organisms, the green-sulfur bacteria do not produce oxygen and tolerate only low levels of the molecule. This organism also fixes carbon dioxide via a reverse tricarboxylic acid cycle, using electrons derived from hydrogen or reduced sulfur to drive the reaction, instead of via the Calvin cycle like many other photosynthetic organisms.