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sulfurreducens has only one. None of the seventeen enoyl-CoA hydratases of G. metallireducens is an ortholog of GSU1377, the sole enoyl-CoA hydratase of G. sulfurreducens. Vorinostat concentration G. metallireducens also possesses eleven acyl-CoA thioesterases, of which G. sulfurreducens has orthologs of five plus the unique thioesterase GSU0196. Of the ten acyl-CoA thiolases of G. metallireducens, only Gmet_0144 has an ortholog (Serine/CaMK inhibitor GSU3313) in G. sulfurreducens. BLAST searches and phylogenetic analyses demonstrated that several of these enzymes of

acyl-CoA metabolism have close relatives in G. bemidjiensis, Geobacter FRC-32, Geobacter lovleyi and Geobacter uraniireducens, indicating that their absence from G. sulfurreducens is due to gene loss, and that this apparent metabolic versatility is largely the result of expansion of enzyme families within the genus Geobacter (data not shown). The ability of G. metallireducens and other Geobacteraceae to utilize carbon sources that G. sulfurreducens cannot utilize may be due to stepwise breakdown

of multicarbon organic acids to simpler compounds by these enzymes. Growth of G. metallireducens on butyrate may be attributed to reversible phosphorylation by either of two butyrate kinases (Gmet_2106 and Gmet_2128), followed by reversible CoA-ligation by phosphotransbutyrylase (Gmet_2098), a pathway not present in G. sulfurreducens, which cannot grow on butyrate [24]. These gene products are 42–50% identical to the Z-DEVD-FMK enzymes characterized in Oxymatrine Clostridium beijerinckii and Clostridium acetobutylicum [28, 29]. An enzyme very similar to succinyl:acetate CoA-transferase is encoded by Gmet_1125

within the same operon as methylisocitrate lyase (Gmet_1122), 2-methylcitrate dehydratase (Gmet_1123), and a citrate synthase-related protein hypothesized to be 2-methylcitrate synthase (Gmet_1124) [30] (Figure 2a), all of which are absent in G. sulfurreducens. This arrangement of genes, along with the ability of G. metallireducens to utilize propionate as an electron donor [31] whereas G. sulfurreducens cannot [24], suggests that the Gmet_1125 protein could be a succinyl:propionate CoA-transferase that, together with the other three products of the operon, would convert propionate (via propionyl-CoA) and oxaloacetate to pyruvate and succinate (Figure 2b). Upon oxidation of succinate to oxaloacetate through the TCA cycle and oxidative decarboxylation of pyruvate to acetyl-CoA, the pathway would be equivalent to the breakdown of propionate into six electrons, one molecule of carbon dioxide, and acetate, followed by the succinyl:acetate CoA-transferase reaction (Figure 2b).

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