Doctoral Thesis
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S-adenosyl-L-methionine- (SAM) dependent methyltransferases (MTs) catalyse methylation of halide ions and the C, O, N, S, Se, and As atoms of biomolecules ranging from biopolymers to small molecules. They display different chemo-, regio- and stereoselectivity according to their specific functions. This thesis focuses on the engineering of O-methyltransferases (OMTs) and halide methyltransferases (HMTs) through rational design and directed evolution to study their structure-function relationship and to explore their catalytic promiscuity. The influence of substrate binding residues on the substrate scope and regioselectivity of a plant OMT against various phenolic substrates (Article I) and flavonoids (Article II) has been investigated. Article III describes the directed evolution of an HMT for the biocatalytic synthesis of diverse SAM analogues. With the evolved HMT, regioselective alkylation of phenolic compounds and flavonoids, as well as the SAM analogue regeneration, were achieved through an HMT-MT cascade reaction.
Article I Specific residues expand the substrate scope and enhance the regioselectivity of a plant O-methyltransferase.
It was reported in literature that an isoeugenol 4-OMT (IeOMT) can be engineered to a caffeic acid 3-OMT (CaOMT) by replacing three consecutive residues. In this article, we investigated the effect of these residues on substrate preference and regioselectivity of IeOMT. The triple mutant T133M/A134N/T135Q and the respective single mutants were constructed and tested against a series of phenolic compounds. The variant T133M had a universal effect to improve enzymatic activities against all tested substrates while the mutant A134N had enhanced regioselectivity. The triple mutant T133M/A134N/T135Q benefits from these two mutations, which not only expanded the substrate scope, but also enhanced the regioselectivity of IeOMT. On the basis of this work, regiospecific methylated phenolics can be produced in high purity by different IeOMT variants.
Article II Influence of substrate binding residues on the substrate scope and regioselectivity of a plant O-methyltransferase against flavonoids
Flavonoid OMTs (FOMTs), isoflavonoid OMTs (IOMTs) and phenylpropanoid OMTs (POMTs) display different substrate preferences. Sequence comparison showed that the substrate binding residues at positions 322 and 326 are different between these OMT groups and might be critical for the substrate discrimination. Residues at positions 322 and 326 in IeOMT (a POMT) were mutated to the commonly presented residues in FOMT and IOMT. The introduced mutants, in cooperation with the variant T133M, have improved or brought novel activities and regioselectivity against the tested flavonoids eriodictyol, naringenin, luteolin, quercetin, and also the isoflavonoid genistein compared to the wild-type IeOMT. On the basis of this work, methylated flavonoids that are rare in nature were produced in high purity.
Article III Directed evolution of a halide methyltransferase enables biocatalytic synthesis of diverse SAM analogs
Biocatalytic alkylations to obtain chemo‐, regio‐ and stereoselectively alkylated compounds can be achieved by MTs with the supply of SAM analogues. It was recently discovered that SAM can be directly synthesized from S adenosyl-L homocysteine (SAH) and methyl iodide, catalysed by an HMT. To explore the promiscuity of HMT in the synthesis of SAM analogues, we performed directed evolution of the Arabidopsis thaliana HMT based on a sensitive, colorimetric iodide assay. The identified variant V140T displayed activities against ethyl‐, propyl‐, and allyl iodides to produce the corresponding SAM analogues. With this HMT variant, regioselective ethylation of luteolin and allylation of 3,4‐dihydroxybenzaldehyde, as well as the SAM analogue regeneration, were achieved through this HMT-MT one-pot cascade reaction.