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ABSTRACT: Sucrose isomerase (SI) activity is used industrially for the conversion of sucrose into isomers, particularly isomaltulose or trehalulose, which have properties advantageous over sucrose for some food uses. All of the known microbial SIs are TIM barrel proteins that convert sucrose without need for any cofactors, with varying kinetics and product specificities. The current analysis was undertaken to bridge key gaps between the information in patents and scientific publications about the microbes and enzymes useful for sucrose isomer production. This analysis shows that microbial SIs can be considered in 5 structural classes with corresponding functional distinctions that broadly align with the taxonomic differences between producing organisms. The most widely used bacterial strain for industrial production of isomaltulose, widely referred to as "Protaminobacter rubrum" CBS 574.77, is identified as Serratia plymuthica. The strain producing the most structurally divergent SI, with a high product specificity for trehalulose, widely referred to as "Pseudomonas mesoacidophila" MX-45, is identified as Rhizobium sp. Each tested SI-producer is shown to have a single SI gene and enzyme, so the properties reported previously for the isolated proteins can reasonably be associated with the products of the genes subsequently cloned from the same isolates and SI classes. Some natural isolates with potent SI activity do not catabolize the isomer under usual production conditions. The results indicate that their industrial potential may be further enhanced by selection for variants that do not catabolize the sucrose substrate.
Enzyme and microbial technology. 01/2012; 50(1):57-64.
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ABSTRACT: Albicidins are potent DNA-gyrase-inhibiting antibiotics and phytotoxins synthesised by Xanthomonas albilineans. Functions have been deduced for some clustered biosynthetic genes, including a PKS-NRPS megasynthase, methyltransferases and regulatory genes, and resistance genes including a transporter and a gyrase-binding protein. More puzzling is the presence in this cluster of apparent aromatic metabolism genes. Here, we describe functional analysis of several such genes and propose a model for their role. An apparent benzoate CoA ligase (xabE) proved essential for albicidin production and pathogenicity. A neighbouring operon includes genes for p-aminobenzoate (PABA) metabolism. A PABA synthase fusion (pabAB) restored prototrophy in pabA and pabB mutants of Escherichia coli, proving functionality. Inactivation of pabAB increased susceptibility to sulphanilamide but did not block albicidin production. X. albilineans contains a remote pabB gene which evidently supplies enough PABA for albicidin biosynthesis in culture. Additional capacity from pabAB may be advantageous in more demanding environments such as infected plants. Downstream from pabAB are a known resistance gene (albG) and ubiC which encodes a p-hydroxybenzoate (PHBA) synthase. PHBA protects X. albilineans from inhibition by PABA. Therefore, coordinated expression may protect X. albilineans against toxicity of both the PABA intermediate and the albicidin product, under conditions that induce high-level antibiotic biosynthesis.
Applied Microbiology and Biotechnology 05/2010; 87(4):1475-85. · 3.42 Impact Factor
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ABSTRACT: The sugarcane pathogen Xanthomonas albilineans produces a family of antibiotics and phytotoxins termed albicidins, which inhibit plant and bacterial DNA gyrase supercoiling activity, with a 50% inhibitory concentration (50 nM) comparable to those of coumarins and quinolones. Here we show that X. albilineans has an unusual, antibiotic-resistant DNA gyrase. The X. albilineans gyrA and gyrB genes are not clustered with previously described albicidin biosynthesis and self-protection genes. The GyrA and GyrB products differ from Escherichia coli homologues through several insertions and through changes in several amino acid residues implicated in quinolone and coumarin resistance. Reconstituted X. albilineans DNA gyrase showed 20- to 25-fold-higher resistance than E. coli DNA gyrase to albicidin and ciprofloxacin and 8-fold-higher resistance to novobiocin in the supercoiling assay. The X. albilineans DNA gyrase is unusual in showing a high degree of distributive supercoiling and little DNA relaxation activity. X. albilineans GyrA (XaA) forms a functional gyrase heterotetramer with E. coli GyrB (EcB) and can account for albicidin and quinolone resistance and low levels of relaxation activity. XaB probably contributes to both coumarin resistance and the distributive supercoiling pattern. Although XaB shows fewer apparent changes relative to EcB, the EcA.XaB hybrid relaxed DNA in the presence or absence of ATP and was unable to supercoil. A fuller understanding of structural differences between albicidin-sensitive and -resistant gyrases may provide new clues into features of the enzyme amenable to interference by novel antibiotics.
Antimicrobial Agents and Chemotherapy 05/2008; 52(4):1382-90. · 4.84 Impact Factor
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ABSTRACT: Xanthomonas albilineans produces a family of polyketide-peptide compounds called albicidins which are highly potent antibiotics and phytotoxins as a result of their inhibition of prokaryotic DNA replication. Here we show that albicidin is a potent inhibitor of the supercoiling activity of bacterial and plant DNA gyrases, with 50% inhibitory concentrations (40 to 50 nM) less than those of most coumarins and quinolones. Albicidin blocks the religation of the cleaved DNA intermediate during the gyrase catalytic sequence and also inhibits the relaxation of supercoiled DNA by gyrase and topoisomerase IV. Unlike the coumarins, albicidin does not inhibit the ATPase activity of gyrase. In contrast to the quinolones, the albicidin concentration required to stabilize the gyrase cleavage complex increases 100-fold in the absence of ATP. The slow peptide poisons microcin B17 and CcdB also access ATP-dependent conformations of gyrase to block religation, but in contrast to albicidin, they do not inhibit supercoiling under routine assay conditions. Some mutations in gyrA, known to confer high-level resistance to quinolones or CcdB, confer low-level resistance or hypersensitivity to albicidin in Escherichia coli. Within the albicidin biosynthesis region in X. albilineans is a gene encoding a pentapeptide repeat protein designated AlbG that binds to E. coli DNA gyrase and that confers a sixfold increase in the level of resistance to albicidin in vitro and in vivo. These results demonstrate that DNA gyrase is the molecular target of albicidin and that X. albilineans encodes a gyrase-interacting protein for self-protection. The novel features of the gyrase-albicidin interaction indicate the potential for the development of new antibacterial drugs.
Antimicrobial Agents and Chemotherapy 02/2007; 51(1):181-7. · 4.84 Impact Factor
