Abstract
O-methylation of small molecules is a common modification widely present in most organisms. Type III polyketides undergo O-methylation at hydroxyl end to play a wide spectrum of roles in bacteria, plants, algae, and fungi. Mycobacterium marinum harbours a distinctive genomic cluster with a type III pks gene and genes for several polyketide modifiers including a methyltransferase gene, mmar_2193. This study reports functional analyses of MMAR_2193 and reveals multi-methylating potential of the protein. Comparative sequence analyses revealed conservation of catalytically important motifs in MMAR_2193 protein. Homology-based structure-function and molecular docking studies suggested type III polyketide cores as possible substrates for MMAR_2193 catalysis. In vitro enzymatic characterization revealed the capability of MMAR_2193 protein to utilize diverse polyphenolic substrates to methylate several hydroxyl positions on a single substrate molecule. High-resolution mass spectrometric analyses identified multi-methylations of type III polyketides in cell-free reconstitution assays. Notably, our metabolomics analyses identified some of these methylated molecules in biofilms of wild type Mycobacterium marinum. This study characterizes a novel mycobacterial O-methyltransferase protein with multi-methylating enzymatic ability that could be exploited to generate a palette of structurally distinct bioactive molecules.
Highlights
Methylation is an important biological activity with implications in several cellular processes including DNA repair, signal transduction, regulation of hormones and neurotransmitters, and secondary metabolites biosynthesis
Comparative sequence analysis has revealed a plethora of genomic clusters specific to pathogenic mycobacterial strains
Biofilm pellicles were developed for Mycobacterium marinum (Mmar) cells (Fig 2 in S1 Text) and Pathogenic mycobacterial genomes reveal several genomic clusters dedicated to virulent lipid biosynthesis
Summary
Methylation is an important biological activity with implications in several cellular processes including DNA repair, signal transduction, regulation of hormones and neurotransmitters, and secondary metabolites biosynthesis. Methyltransferases (MTases) in an enzymatic mechanism catalyze nucleophilic substitution reaction by the transfer of methyl group from universal donor S-Adenosyl L-methionine (SAM) to a nucleophile containing carbon (C), sulfur (S), nitrogen (N) and oxygen (O) [1]. Methylation in secondary metabolic pathways occurs on several biological molecules affecting the natural properties of the final products [2]. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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