化学
胍
预酸化
环肽
肽
催化作用
突变
化学选择性
立体化学
组合化学
生物化学
突变体
基因
酶
作者
Kei Fujita,Yuito Yamada,Tomo Taniguchi,Daisuke Fujinami,Takahiro Mori,Kenichi Matsuda,Ikuro Abe,Toshiyuki Wakimoto
摘要
Lipidation is a promising strategy to enhance the membrane affinity and the serum stability of peptide drugs. Cyanobactin prenyltransferases catalyze the prenylation of peptides with diverse chemoselectivity. Among these enzymes, AutF and AgcF catalyze the mono- and bisprenylations of Arg-Nω, respectively, although the structural basis for these distinct prenylation modes remained unknown. Through genome mining, we herein identified a new Arg-Nω-bisprenyltransferase, DciF, from Dolichospermum circinale AWQC310F. Crystallographic analysis and subsequent mutagenesis studies identified key active site residues that play pivotal roles in Arg-Nω-bisprenylation. Manipulations of the active site pocket successfully converted an Arg-Nω-bisprenyltransferase into an Arg-Nω-monoprenyltransferase, and vice versa, elucidating its role as a determinant factor for prenylation rounds. DciF efficiently catalyzed Arg-Nω-bisprenylation on various cyclic and linear peptides, demonstrating its remarkable potential as a biocatalytic tool for site-selective peptide modification. This study broadens the scope of biocatalytic peptide modifications and establishes a new framework for engineering cyanobactin prenyltransferases to control their prenylation rounds.
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