Modification of the peroxygenative: peroxidative activity ratio in the unspecific peroxygenase from Agrocybe aegerita by structure-guided evolution

D. Maté, M. A. Palomino, Patricia Molina-Espeja, Javier Martin-Diaz, M. Alcalde
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引用次数: 24

Abstract

Unspecific peroxygenase (UPO) is a heme-thiolate peroxidase capable of performing with high-selectivity C-H oxyfunctionalizations of great interest in organic synthesis through its peroxygenative activity. However, the convergence of such activity with an unwanted peroxidative activity encumbers practical applications. In this study, we have modified the peroxygenative:peroxidative activity ratio (P:p ratio) of UPO from Agrocybe aegerita by structure-guided evolution. Several flexible loops (Glu1-Pro35, Gly103-Asp131, Ser226-Gly243, Gln254-Thr276 and Ty293-Arg327) were selected on the basis on their B-factors and ΔΔG values. The full ensemble of segments (43% of UPO sequence) was subjected to focused evolution by the Mutagenic Organized Recombination Process by Homologous IN vivo Grouping (MORPHING) method in Saccharomyces cerevisiae. Five independent mutant libraries were screened in terms of P:p ratio and thermostability. We identified several variants that harbored substitutions at positions 120 and 320 with a strong enhancement in the P:p ratio albeit at the cost of stability. The most thermostable mutant of this process (S226G with an increased T50 of 2°C) was subjected to further combinatorial saturation mutagenesis on Thr120 and Thr320 yielding a collection of variants with modified P:p ratio and recovered stability. Our results seem to indicate the coexistence of several oxidation sites for peroxidative and peroxygenative activities in UPO.
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结构导向进化对绿草草非特异性过氧酶过氧活性比的修饰
非特异性过氧酶(Unspecific peroxygenase, UPO)是一种血红素硫酸过氧化物酶,能够通过其过氧活性进行高选择性的C-H氧官能化,在有机合成中具有重要意义。然而,这种活性与不需要的过氧化活性的融合阻碍了实际应用。在本研究中,我们通过结构引导进化的方法修改了绿草草(Agrocybe aegerita)中UPO的过氧:过氧化活性比(P: P ratio)。根据其b因子和ΔΔG值选择了几个柔性环(Glu1-Pro35, Gly103-Asp131, Ser226-Gly243, Gln254-Thr276和Ty293-Arg327)。以酿酒酵母(Saccharomyces cerevisiae)为研究对象,采用同源体内分组(MORPHING)方法进行诱变组织重组过程(Mutagenic Organized Recombination Process)的集中进化(43%的UPO序列)。根据P: P比和热稳定性筛选了5个独立的突变文库。我们发现了几个在位置120和320处进行替换的变体,尽管以稳定性为代价,但P: P比明显增强。该过程中最耐热的突变体(T50增加到2°C的S226G)对Thr120和Thr320进行了进一步的组合饱和诱变,产生了一系列P: P比改变并恢复了稳定性的突变体。我们的结果似乎表明,在UPO中存在几个氧化位点的过氧化和过氧活性共存。
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