| Abstract |
The gene context in microorganism genomes is of considerable help for identifying potential substrates. The C785_RS13685 gene in Herbaspirillum huttiense IAM 15032 is a member of the d-altronate dehydratase protein family, and which functions as a d-arabinonate dehydratase in vitro, is clustered with genes related to putative pentose metabolism. In the present study, further biochemical characterization and gene expression analyses revealed that l-xylonate is a physiological substrate that is ultimately converted to α-ketoglutarate via so-called Route II of a non-phosphorylative pathway. Several hexonates, including d-altronate, d-idonate and l-gluconate, which are also substrates of C785_RS13685, also significantly up-regulated the gene cluster containing C785_RS13685, suggesting a possibility that pyruvate and d- or l-glycerate were ultimately produced (novel Route III). On the contrary, ACAV_RS08155 of Acidovorax avenae ATCC 19860, a homologous gene to C785_RS13685, functioned as a d-altronate dehydratase in a novel l-galactose pathway, through which l-galactonate was epimerized at the C5 position by the sequential activity of two dehydrogenases, resulting in d-altronate. Furthermore, this pathway completely overlapped with Route III of the non-phosphorylative l-fucose pathway. The 'substrate promiscuity' of d-altronate dehydratase protein(s) is significantly expanded to 'metabolic promiscuity' in the d-arabinose, sugar acid, l-fucose and l-galactose pathways.
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