盐霉素生物合成中吡喃环A形成的酶学研究。

Hanna Luhavaya, Marcio V B Dias, Simon R Williams, Hui Hong, Luciana G de Oliveira, Peter F Leadlay
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引用次数: 4

摘要

四氢吡喃环是复杂聚酮天然产物的共同特征,但其形成的酶学仍有待研究。盐碱霉素生物合成途径中的SalBIII酶类似于MonB家族的其他聚醚环氧化物水解酶/环化酶,但SalBIII酶在常规的环打开/关闭级联中不起作用。salBIII基因的突变产生了一种代谢物,其中a环不形成。在体外使用这种代谢物作为底物类似物,SalBIII已被证明形成吡喃环a。我们已经确定了SalBIII的x射线晶体结构,并且对假定的活性位点残基的结构引导诱变已经确定了Asp38和Asp104是必不可少的催化二联体。SalBIII的吡聚糖合成酶活性进一步扩展了α+β桶折叠蛋白令人印象深刻的催化多功能性。
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Enzymology of Pyran Ring A Formation in Salinomycin Biosynthesis.

Tetrahydropyran rings are a common feature of complex polyketide natural products, but much remains to be learned about the enzymology of their formation. The enzyme SalBIII from the salinomycin biosynthetic pathway resembles other polyether epoxide hydrolases/cyclases of the MonB family, but SalBIII plays no role in the conventional cascade of ring opening/closing. Mutation in the salBIII gene gave a metabolite in which ring A is not formed. Using this metabolite in vitro as a substrate analogue, SalBIII has been shown to form pyran ring A. We have determined the X-ray crystal structure of SalBIII, and structure-guided mutagenesis of putative active-site residues has identified Asp38 and Asp104 as an essential catalytic dyad. The demonstrated pyran synthase activity of SalBIII further extends the impressive catalytic versatility of α+β barrel fold proteins.

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