Publications

• Biosynthesis of 3'-deoxy-carbamoylkanamycin C in a Streptomyces tenebrarius mutant strain by tacB gene disruption.

  Yu Y., Hou X., Ni X., Xia H.

  Streptomyces tenebrarius H6 mainly produces three kinds of antibiotics: apramycin, carbamoyltobramycin and some carbamoylkanamycin B. In our present study, a dehydrogenase gene tacB in the tobramycin biosynthetic gene cluster was disrupted by in-frame deletion. The result of TLC bio-autograph anal ... >> More

  Streptomyces tenebrarius H6 mainly produces three kinds of antibiotics: apramycin, carbamoyltobramycin and some carbamoylkanamycin B. In our present study, a dehydrogenase gene tacB in the tobramycin biosynthetic gene cluster was disrupted by in-frame deletion. The result of TLC bio-autograph analysis demonstrated the disruption mutant strain produced apramycin and a new antibiotic. The new antibiotic was identified as 3'-deoxy-carbamoylkanamycin C by MS and NMR analysis after isolation and purification. The disruption mutant was restored to produce carbamoyltobramycin in a complementation experiment by the intact tacB gene. Our studies suggested that the tacB gene encodes a 6'-dehydrogenase, which reduces the 6'-hydroxyl group of paromamine to a keto group, thus facilitating the transfer of an aminogroup to form neamine. This study is the first report on the generation of a tobramycin derivative by gene engineering, and will contribute to clarify the complete biosynthetic pathway of tobramycin. << Less

  J Antibiot (Tokyo) 61:63-69(2008) [PubMed] [EuropePMC]

• The oxidoreductases LivQ and NeoQ are responsible for the different 6'-modifications in the aminoglycosides lividomycin and neomycin.

  Clausnitzer D., Piepersberg W., Wehmeier U.F.

  <h4>Aims</h4>The 2-deoxystreptamine-containing aminoglycoside antibiotics (AGAs) constitute the largest subgroup of the aminoglycosides. Neomycin (NEO) and lividomycin (LIV) are both representatives of the pseudo-tetrasaccharide group among the NEO-type AGAs. While NEO contains a 6'-NH(2) group, t ... >> More

  <h4>Aims</h4>The 2-deoxystreptamine-containing aminoglycoside antibiotics (AGAs) constitute the largest subgroup of the aminoglycosides. Neomycin (NEO) and lividomycin (LIV) are both representatives of the pseudo-tetrasaccharide group among the NEO-type AGAs. While NEO contains a 6'-NH(2) group, the 6'-position remains unmodified in LIV. The aim of the study was to characterize the substrate specificities of the enzymes involved in the C-6'- and C-6‴-modification in order to explain the different amination patterns.<h4>Methods and results</h4>We overproduced and purified the enzymes NeoQ (bifunctional 6'- and 6‴-oxidoreductase) and NeoB (bifunctional 6'-and-6‴-aminotransferase), which had been analysed before (Huang et al. 2007), and compared the enzymatic properties with the corresponding enzymes LivQ (postulated 6‴-oxidoreductase, 72% identity to NeoQ) and LivB (postulated 6‴-aminotransferase, 71% identity to NeoB) from the LIV pathway. By applying a newly established photometric assay, we proved that LivQ oxidized only pseudotetrasaccharidic substrates at the 6‴-position. In contrast, NeoQ accepted also the pseudodisaccharidic paromamine as a substrate and oxidized the 6'- and 6‴-positions on two different precursors of NEO. The aminotransferases LivB and NeoB both transfer NH(2) groups to the 6'-position in the precursor 6'-oxo-paromamine and to the 6‴-position of 6‴-oxo-neomycin C.<h4>Conclusions</h4>The difference in the modification pattern of NEO and LIV at their 6'-positions is based only on the difference in the substrate specificities of the oxidoreductases LivQ and NeoQ, respectively. The aminotransferases LivB and NeoB share identical biochemical properties, and both are capable to transaminate the 6' and also the 6‴-position of the tested AGAs.<h4>Significance and impact of the study</h4>Our data provide information to understand the structural variations in aminoglycosides and may be helpful to interpret variations in other natural product bisoynthesis pathways. << Less

  J. Appl. Microbiol. 111:642-651(2011) [PubMed] [EuropePMC]

  This publication is cited by 3 other entries.

• Elaboration of neosamine rings in the biosynthesis of neomycin and butirosin.

  Huang F., Spiteller D., Koorbanally N.A., Li Y., Llewellyn N.M., Spencer J.B.

  The proteins Neo-11 and Neo-18 encoded in the neomycin gene cluster (neo) of Streptomyces fradiae NCIMB 8233 have been characterized as glucosaminyl-6'-oxidase and 6'-oxoglucosaminyl:L-glutamate aminotransferase, respectively. The joint activity of Neo-11 and Neo-18 is responsible for the conversi ... >> More

  The proteins Neo-11 and Neo-18 encoded in the neomycin gene cluster (neo) of Streptomyces fradiae NCIMB 8233 have been characterized as glucosaminyl-6'-oxidase and 6'-oxoglucosaminyl:L-glutamate aminotransferase, respectively. The joint activity of Neo-11 and Neo-18 is responsible for the conversion of paromamine to neamine in the biosynthetic pathway of neomycin through a mechanism of FAD-dependent dehydrogenation followed by a pyridoxal-5'-phosphate-mediated transamination. Neo-18 is also shown to catalyze deamination at C-6''' of neomycin, thus suggesting bifunctional roles of the two enzymes in the formation of both neosamine rings of neomycin. The product of the btrB gene, a homologue of neo-18 in the butirosin biosynthetic gene cluster (btr) in Bacillus circulans, exhibits the same activity as Neo-18; this indicates that there is a similar reaction sequence in both butirosin and neomycin biosynthesis. << Less

  ChemBioChem 8:283-288(2007) [PubMed] [EuropePMC]

  This publication is cited by 3 other entries.