Abstract
Lysobacter are ubiquitous environmental bacteria emerging as novel biocontrol agents and new sources of anti-infectives. So far, very little effort has been invested in the study of the biology of these Gram-negative gliding bacteria. Many Lysobacter species are characterized by their yellow-orange appearance. Using transposon mutagenesis, we identified a stand-alone polyketide synthase (PKS) gene cluster required for the pigment production in L. enzymogenes OH11. The yellow pigments were abolished in the “white” mutants generated by target-specific deletions of ketosynthase (KS), acyl carrier protein, or ketoreductase. Spectroscopic data suggested that the pigments belong to xanthomonadin-like aryl polyenes. Polyene-type polyketides are known to be biosynthesized by modular PKS (Type I), not by stand-alone PKS (Type II) which always contain the heterodimer KS-CLF (chain-length factor) as the key catalytic component. Remarkably, this aryl polyene PKS complex only contains the KS (ORF17), but not the CLF. Instead, a hypothetical protein (ORF16) is located immediately next to ORF17. ORF16–17 homologs are widespread in numerous uncharacterized microbial genomes, in which an ORF17 homolog is always accompanied by an ORF16 homolog. The deletion of ORF16 eliminated pigment production, and homology modeling suggested that ORF16 shares a structural similarity to the N-terminal half of CLF. A point-mutation of glutamine (Q166A) that is the conserved active site of known CLF abolished pigment production. The “white” mutants are significantly more sensitive to UV/visible light radiation or H2O2 treatment than the wild type. These results unveil the first example of Type II PKS-synthesized polyene pigments and show that the metabolites serve as Lysobacter “sunscreens” that are important for the survival of these ubiquitous environmental organisms.
Highlights
The genus Lysobacter is one of the most ubiquitous environmental microorganisms, existing in such diverse habitats as marine thermovents, tar pits, compost sludge and volcanic ash, as well as soil and aquatic environments [1,2,3]
L. enzymogenes is the best studied species [2,6,7]. It exhibited field efficacy against diseases of Bipolaris leaf spot of turfgrass caused by Bipolaris sorokiniana [8], brown patch caused by Rhizoctonia solani [6,9], stem rust caused by Puccinia graminis and bean rust caused by Uromyces appendiculatus [10]
Our study revealed that the Lysobacter yellow pigments are non-carotenoid polyene compounds and their biosynthesis involves an unusual type II polyketide mechanism
Summary
The genus Lysobacter is one of the most ubiquitous environmental microorganisms, existing in such diverse habitats as marine thermovents, tar pits, compost sludge and volcanic ash, as well as soil and aquatic environments [1,2,3]. L. enzymogenes is the best studied species [2,6,7] It exhibited field efficacy against diseases of Bipolaris leaf spot of turfgrass caused by Bipolaris sorokiniana [8], brown patch caused by Rhizoctonia solani [6,9], stem rust caused by Puccinia graminis and bean rust caused by Uromyces appendiculatus [10]. In greenhouse experiments, it exhibited efficacy against summer patch of Kentucky bluegrass caused by Magnaporthe poae [11] and suppressed damping-off of sugar beet caused by Pythium ultimum [12]
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