16 research outputs found
Cr(III) removal by a microalgal isolate, Chlorella miniata: effects of nitrate, chloride and sulfate
Metamorphic enzyme assembly in polyketide diversification
Natural product chemical diversity is fuelled by the emergence and ongoing evolution of biosynthetic pathways in secondary metabolism. However, co-evolution of enzymes for metabolic diversification is not well understood, especially at the biochemical level. Here, two parallel assemblies with an extraordinarily high sequence identity from Lyngbya majuscula form a Β-branched cyclopropane in the curacin A pathway (Cur), and a vinyl chloride group in the jamaicamide pathway (Jam). The components include a halogenase, a 3-hydroxy-3-methylglutaryl enzyme cassette for polyketide Β-branching, and an enoyl reductase domain. The halogenase from CurA, and the dehydratases (ECH"1s), decarboxylases (ECH"2s) and enoyl reductase domains from both Cur and Jam, were assessed biochemically to determine the mechanisms of cyclopropane and vinyl chloride formation. Unexpectedly, the polyketide Β-branching pathway was modified by introduction of a -chlorination step on (S)-3-hydroxy-3-methylglutaryl mediated by Cur halogenase, a non-haem Fe(ii), α-ketoglutarate-dependent enzyme. In a divergent scheme, Cur ECH"2 was found to catalyse formation of the α,Β enoyl thioester, whereas Jam ECH"2 formed a vinyl chloride moiety by selectively generating the corresponding Β, enoyl thioester of the 3-methyl-4-chloroglutaconyl decarboxylation product. Finally, the enoyl reductase domain of CurF specifically catalysed an unprecedented cyclopropanation on the chlorinated product of Cur ECH"2 instead of the canonical α,Β C ≤ C saturation reaction. Thus, the combination of chlorination and polyketide Β-branching, coupled with mechanistic diversification of ECH"2 and enoyl reductase, leads to the formation of cyclopropane and vinyl chloride moieties. These results reveal a parallel interplay of evolutionary events in multienzyme systems leading to functional group diversity in secondary metabolites. © 2009 Macmillan Publishers Limited. All rights reserved
Molecular Insights into the Biosynthesis of Guadinomine: A Type III Secretion System Inhibitor
Guadinomines are a recently discovered family of anti-infective compounds produced by Streptomyces sp. K01-0509 with a novel mode of action. With an IC(50) of 14 nM, guadinomine B is the most potent known inhibitor of the Type III Secretion System (TTSS) of Gram-negative bacteria. TTSS activity is required for the virulence of many pathogenic Gram-negative bacteria including Escherichia coli, Salmonella spp., Yersinia spp., Chlamydia spp., Vibrio spp., and Pseudomonas spp. The guadinomine (gdn) biosynthetic gene cluster has been cloned and sequenced, and includes 26 open reading frames spanning 51.2 kb. It encodes a chimeric multimodular polyketide synthase – nonribosomal peptide synthetase, along with enzymes responsible for the biosynthesis of the unusual aminomalonyl-ACP extender unit and the signature carbamoylated cyclic guanidine. Its identity was established by targeted disruption of the gene cluster, as well as by heterologous expression and analysis of key enzymes in the biosynthetic pathway. Identifying the guadinomine gene cluster provides critical insight into the biosynthesis of these scarce but potentially important natural products