Publications

• Evidence that glutamine transaminase and omega-amidase potentially act in tandem to close the methionine salvage cycle in bacteria and plants.

  Ellens K.W., Richardson L.G., Frelin O., Collins J., Ribeiro C.L., Hsieh Y.F., Mullen R.T., Hanson A.D.

  S-Adenosylmethionine is converted enzymatically and non-enzymatically to methylthioadenosine, which is recycled to methionine (Met) via a salvage pathway. In plants and bacteria, enzymes for all steps in this pathway are known except the last: transamination of α-ketomethylthiobutyrate to give Met ... >> More

  S-Adenosylmethionine is converted enzymatically and non-enzymatically to methylthioadenosine, which is recycled to methionine (Met) via a salvage pathway. In plants and bacteria, enzymes for all steps in this pathway are known except the last: transamination of α-ketomethylthiobutyrate to give Met. In mammals, glutamine transaminase K (GTK) and ω-amidase (ω-Am) are thought to act in tandem to execute this step, with GTK forming α-ketoglutaramate, which ω-Am hydrolyzes. Comparative genomics indicated that GTK and ω-Am could function likewise in plants and bacteria because genes encoding GTK and ω-Am homologs (i) co-express with the Met salvage gene 5-methylthioribose kinase in Arabidopsis, and (ii) cluster on the chromosome with each other and with Met salvage genes in diverse bacteria. Consistent with this possibility, tomato, maize, and Bacillus subtilis GTK and ω-Am homologs had the predicted activities: GTK was specific for glutamine as amino donor and strongly preferred α-ketomethylthiobutyrate as amino acceptor, and ω-Am strongly preferred α-ketoglutaramate. Also consistent with this possibility, plant GTK and ω-Am were localized to the cytosol, where the Met salvage pathway resides, as well as to organelles. This multiple targeting was shown to result from use of alternative start codons. In B. subtilis, ablating GTK or ω-Am had a modest but significant inhibitory effect on growth on 5-methylthioribose as sole sulfur source. Collectively, these data indicate that while GTK, coupled with ω-Am, is positioned to support significant Met salvage flux in plants and bacteria, it can probably be replaced by other aminotransferases. << Less

  Phytochemistry 113:160-169(2015) [PubMed] [EuropePMC]

• Methionine regeneration and aminotransferases in Bacillus subtilis, Bacillus cereus, and Bacillus anthracis.

  Berger B.J., English S., Chan G., Knodel M.H.

  The conversion of ketomethiobutyrate to methionine has been previously examined in a number of organisms, wherein the aminotransferases responsible for the reaction have been found to be members of the Ia subfamily (L. C. Berger, J. Wilson, P. Wood, and B. J. Berger, J. Bacteriol. 183:4421-4434, 2 ... >> More

  The conversion of ketomethiobutyrate to methionine has been previously examined in a number of organisms, wherein the aminotransferases responsible for the reaction have been found to be members of the Ia subfamily (L. C. Berger, J. Wilson, P. Wood, and B. J. Berger, J. Bacteriol. 183:4421-4434, 2001). The genome of Bacillus subtilis has been found to contain no subfamily Ia aminotransferase sequences. Instead, the analogous enzymes in B. subtilis were found to be members of the If subfamily. These putative aspartate aminotransferases, the yugH, ywfG, ykrV, aspB, and patA gene products, have been cloned, expressed, and characterized for methionine regeneration activity. Only YkrV was able to convert ketomethiobutyrate to methionine, and it catalyzed the reaction only when glutamine was used as amino donor. In contrast, subcellular homogenates of B. subtilis and Bacillus cereus utilized leucine, isoleucine, valine, alanine, phenylalanine, and tyrosine as effective amino donors. The two putative branched-chain aminotransferase genes in B. subtilis, ybgE and ywaA, were also cloned, expressed, and characterized. Both gene products effectively transaminated branched-chain amino acids and ketoglutarate, but only YbgE converted ketomethiobutyrate to methionine. The amino donor preference for methionine regeneration by YbgE was found to be leucine, isoleucine, valine, phenylalanine, and tyrosine. The B. subtilis ybgE gene is a member of the family III of aminotransferases and falls in a subfamily designated here IIIa. Examination of B. cereus and Bacillus anthracis genome data found that there were no subfamily IIIa homologues in these organisms. In both B. cereus and B. anthracis, two putative branched-chain aminotransferases and two putative D-amino acid aminotransferases were discovered as members of subfamily IIIb. These four sequences were cloned from B. cereus, expressed, and characterized. Only the gene product from the sequence designated Bc-BCAT2 was found to convert ketomethiobutyrate to methionine, with an amino donor preference of leucine, isoleucine, valine, phenylalanine, and tyrosine. The B. anthracis homologue of Bc-BCAT2 was also cloned, expressed, and characterized and was found to be identical in activity. The aminooxy compound canaline was found to be an uncompetitive inhibitor of B. subtilis YbgE and also inhibited growth of B. subtilis and B. cereus in culture. << Less

  J. Bacteriol. 185:2418-2431(2003) [PubMed] [EuropePMC]