Abstract
In the biosynthesis of natural products, methylation is a common and essential transformation to alter molecules’ bioavailability and bioactivity. The main methylation reaction is performed by S-adenosylmethionine (SAM)-dependent methyltransferases (MTs). With advancements in genomic and chemical profiling technologies, novel MTs have been discovered to accept complex substrates and synthesize industrially valuable natural products. However, to achieve a high yield of small molecules in microbial hosts, many methyltransferase activities have been reported to be insufficient. Moreover, inadequate co-factor supplies and feedback inhibition of the by-product, S-adenosylhomocysteine (SAH), further limit MTs’ activities. Here, we review recent advances in SAM-dependent MTs to produce and diversify natural products. First, we surveyed recently identified novel methyltransferases in natural product biosynthesis. Second, we summarized enzyme engineering strategies to improve methyltransferase activity, with a particular focus on high-throughput assay design and application. Finally, we reviewed innovations in co-factor regeneration and diversification, both in vitro and in vivo. Noteworthily, many MTs are able to accept multiple structurally similar substrates. Such promiscuous methyltransferases are versatile and can be tailored to design de novo pathways to produce molecules whose biosynthetic pathway is unknown or non-existent in nature, thus broadening the scope of biosynthesized functional molecules.
Highlights
Methylation plays multiple critical roles, such as diversifying natural products, increasing bioavailability and stability of small molecules, altering the potency and cytotoxicity of natural products, and regulating biological processes, such as epigenetics and initiation of metamorphosis in insects (Shinoda and Itoyama 2003; Niwa et al 2008; Liscombe et al 2012; Mo et al 2017; Li et al.2018)
We mainly focus on natural product methyltransferases (NPMTs)
Many of methyltransferases are ubiquitous in various natural product biosynthetic pathways, and sometimes a network of methyltransferases participates concertedly in diversifying the natural product
Summary
Methylation plays multiple critical roles, such as diversifying natural products, increasing bioavailability and stability of small molecules, altering the potency and cytotoxicity of natural products, and regulating biological processes, such as epigenetics and initiation of metamorphosis in insects (2021) 8:72 are nearly 400 methyltransferase reactions reported in BRENDA They are mainly divided in DNA/RNA, protein and small molecule methyltransferases. The specificity is contrasted by their ability to accept structurally similar molecules This permissiveness allows enzyme engineers to modify and improve methyltransferases to methylate related products and design alternative pathways. We will cover recent advances in biotechnological applications of SAM-dependent methyltransferases for natural product biosynthesis and diversification. It generally involves three important aspects: first, to identify the desired methyltransferases in natural product biosynthetic pathway; second, to engineer higher methyltransferase activities through enzyme engineering and high-throughput screening; to improve cofactor regeneration.
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