Functional and Structural Analyses of trans C-Methyltransferase in Fungal Polyketide Biosynthesis

Methyltransferase Domain-Focused Genome Mining for Fungal Polyketide Synthases

A comparison of substrate-binding site amino acid residues in the C-methyltransferase (MT) domains of fungal nonreducing polyketide synthases (NR-PKSs) suggests that these residues are correlated with the methylation modes used by the PKSs. A PKS, designated as AsbPKS, with substrate-binding site residues distinct from those of other known PKSs is focused on. The characterization of AsbPKS revealed that it yields an isocoumarin derivative, anhydrosclerotinin B (1), the biosynthesis of which involves a previously unreported methylation pattern. This study demonstrates the utility of MT domain-focused genome mining for the discovery of PKSs with new functions.

Structural enzymology of iterative type I polyketide synthases: various routes to catalytic programming

Time span of literature covered: up to mid-2023Iterative type I polyketide synthases (iPKSs) are outstanding natural chemists: megaenzymes that repeatedly utilize their catalytic domains to synthesize complex natural products with diverse bioactivities. Perhaps the most fascinating but least understood question about type I iPKSs is how they perform the iterative yet programmed reactions in which the usage of domain combinations varies during the synthetic cycle. The programmed patterns are fulfilled by multiple factors, and strongly influence the complexity of the resulting natural products. This article reviews selected reports on the structural enzymology of iPKSs, focusing on the individual domain structures followed by highlighting the representative programming activities that each domain may contribute.

Anammox Bacterial S-Adenosyl-l-Methionine Dependent Methyltransferase Crystal Structure and Its Interaction with Acyl Carrier Proteins

Ladderane lipids (found in the membranes of anaerobic ammonium-oxidizing [anammox] bacteria) have unique ladder-like hydrophobic groups, and their highly strained exotic structure has attracted the attention of scientists. Although enzymes encoded in type II fatty acid biosynthesis (FASII) gene clusters in anammox bacteria, such as S-adenosyl-l-methionine (SAM)-dependent enzymes, have been proposed to construct a ladder-like structure using a substrate connected to acyl carrier protein from anammox bacteria (AmxACP), no experimental evidence to support this hypothesis was reported to date. Here, we report the crystal structure of a SAM-dependent methyltransferase from anammox bacteria (AmxMT1) that has a substrate and active site pocket between a class I SAM methyltransferase-like core domain and an additional α-helix inserted into the core domain. Structural comparisons with homologous SAM-dependent C-methyltransferases in polyketide synthase, AmxACP pull-down assays, AmxACP/AmxMT1 complex structure predictions by AlphaFold, and a substrate docking simulation suggested that a small compound connected to AmxACP could be inserted into the pocket of AmxMT1, and then the enzyme transfers a methyl group from SAM to the substrate to produce branched lipids. Although the enzymes responsible for constructing the ladder-like structure remain unknown, our study, for the first time, supports the hypothesis that biosynthetic intermediates connected to AmxACP are processed by SAM-dependent enzymes, which are not typically involved in the FASII system, to produce the ladder-like structure of ladderane lipids in anammox bacteria.

Screening, cloning and functional characterization of key methyltransferase genes involved in the methylation step of 1-deoxynojirimycin alkaloids biosynthesis in mulberry leaves

The novel C-methyltransferase, MaMT1, could catalyze the conversion of piperidine to 2-methylpiperidine, which may be involved in the methylation step of DNJ biosynthesis in mulberry leaves. Mulberry (Morus alba L.) is a worldwide crop with medicinal, feeding and nutritional value, and 1-deoxynojirimycin ((2R, 3R, 4R, 5S)-2-hydroxymethyl-3, 4, 5-trihydroxypiperidine, DNJ) alkaloid, a potent α-glucosidase inhibitor, is its main active ingredient. Our previous researches clarified the biosynthetic pathway of DNJ from lysine to Δ¹-piperideine, but its downstream pathway is unclear. Herein, eight differential methyltransferases (MTs) genes were screened from transcriptome profiles of mulberry leaves with significant differences in DNJ content (P < 0.01). Subsequently, MaMT1 (OM140666) and MaMT2 (OM140667) were hypothesized as candidate genes related to DNJ biosynthesis by correlation analysis of genes expression levels and DNJ content of mulberry leaves at different dates. Functional characterization of MaMT1 and MaMT2 were performed by cloning, prokaryotic expression and enzymatic reaction in vitro, and it showed that MaMT1 protein could catalyze the conversion of piperidine to 2-methylpiperidine. Moreover, molecular docking confirmed the interaction of MaMT1 protein with piperidine and S-adenosyl-L-methionine (SAM), indicating that MaMT1 had C-methyltransferase activity, while MaMT2 did not. The above results suggested that MaMT1 may be involved in the methylation step of DNJ alkaloid biosynthesis in mulberry leaves, which is a breakthrough in the analysis of DNJ alkaloid biosynthetic pathway. It is worth mentioning that the novel MaMT1, annotated as serine hydroxymethyltransferase, could rely on SAM to perform C-methyltransferase function. Therefore, our findings contribute new insights into the research of DNJ alkaloid biosynthesis and C-methyltransferase family.

Biosynthesis of fungal polyketides by collaborating and trans-acting enzymes

Covering: 1999 up to 2021Fungal polyketides encompass a range of structurally diverse molecules with a wide variety of biological activities. The giant multifunctional enzymes that synthesize polyketide backbones remain enigmatic, as do many of the tailoring enzymes involved in functional modifications. Recent advances in elucidating biosynthetic gene clusters (BGCs) have revealed numerous examples of fungal polyketide synthases that require the action of collaborating enzymes to synthesize the carbon backbone. This review will discuss collaborating and trans-acting enzymes involved in loading, extending, and releasing polyketide intermediates from fungal polyketide synthases, and additional modifications introduced by trans-acting enzymes demonstrating the complexity encountered when investigating natural product biosynthesis in fungi.

Stereocontrolled Synthesis of Pseurotin A2

We report synthesis of two diastereomeric structures previously proposed for the complex secondary metabolite pseurotin A₂. Both structures were accessed from the same building blocks taking advantage of a stereodivergent nickel(II)-diamine-catalyzed 1,4-addition of a chiral 2-alkoxycarbonyl-3(2H)-furanone. Late-stage Csp-Csp³ cross-coupling of a highly functionalized bromoalkyne featured in the pseurotin A₂ side-chain assembly. The work supports the 2016 stereochemical revision of pseurotin A₂ and represents the first chemical synthesis of this natural product.

Biosynthesis of 6-Hydroxymellein Requires a Collaborating Polyketide Synthase-like Enzyme

The polyketide synthase (PKS)-like protein TerB, consisting of inactive dehydratase, inactive C-methyltransferase, and functional ketoreductase domains collaborates with the iterative non reducing PKS TerA to produce 6-hydroxymellein, a key pathway intermediate during the biosynthesis of various fungal natural products. The catalytically inactive dehydratase domain of TerB appears to mediate productive interactions with TerA, demonstrating a new mode of trans-interaction between iterative PKS components.

One Polyketide Synthase, Two Distinct Products: Trans-Acting Enzyme-Controlled Product Divergence in Calbistrin Biosynthesis

Calbistrins are fungal polyketides consisting of the characteristic decalin and polyene moieties. Although the biosynthetic gene cluster of calbistrin A was recently identified, the pathway of calbistrin A biosynthesis has largely remained uninvestigated. Herein, we investigated the mechanism by which the backbone structures of calbistrins are formed, by heterologous and in vitro reconstitution of the biosynthesis and a structural biological study. Intriguingly, our analyses revealed that the decalin and polyene portions of calbistrins are synthesized by the single polyketide synthase (PKS) CalA, with the aid of the trans-acting enoylreductase CalK and the trans-acting C-methyltransferase CalH, respectively. We also determined that the esterification of the two polyketide parts is catalyzed by the acyltransferase CalD. Our study has uncovered a novel dual-functional PKS and thus broadened our understanding of how fungi synthesize diverse polyketide natural products.