三功能金银花和双功能球形红杆菌甲基辅酶a裂解酶的晶体结构及其与city -like超家族酶和苹果酸合成酶的比较

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology BMC Structural Biology Pub Date : 2013-11-09 DOI:10.1186/1472-6807-13-28
Jan Zarzycki, Cheryl A Kerfeld
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引用次数: 13

摘要

甲基辅酶a裂解酶(MCL)是一种混杂的碳-碳键裂解酶,催化结构相关的辅酶a (CoA)硫酯的可逆裂解。该酶在3-羟基丙酸双循环中起着重要的多功能作用。其次,在系统发育上与球形红杆菌不同的MCL参与乙酸同化的乙基丙二酰辅酶A途径。这两个mcl都属于CitE类酶的大超家族,其中包括柠檬酸裂解酶(CitE)的命名β-亚基、甲基辅酶a硫酯酶和其他生理功能未知的酶。类cite酶超家族在序列和结构上也与苹果酸合成酶相似。所有这些不同的酶都具有高度保守的催化残基,尽管它们催化的反应截然不同:C-C键形成和裂解,硫酯水解,或两者兼而有之(苹果酸合成酶)。在这里,我们报告了两个不同系统发育亚群的载脂蛋白和底物结合形式的mcl的第一个晶体结构。C. aurantiacus和R. sphaeroides MCL均含有典型β8/α8 TIM桶状褶皱,并形成六聚体组合。配体结合后,mcl c端结构域的变化导致活性位点关闭,一个单体的c端结构域形成一个盖子,并为相邻单体的活性位点提供侧链。将两个MCL亚群的独特特征与其他类似cite的超家族酶和苹果酸合成酶的已知结构进行了比较,从而深入了解了这些酶的功能多样性背后的结构微妙之处。虽然aurantiacus和R. sphaeroides的一级结构不同(~37%相同),但它们的三级和四级结构非常相似。可以假设,由mcl催化的C-C键形成发生在苹果酸合酶中。然而,两种MCL结构与已知苹果酸合成酶的比较提出了为什么MCL也不能水解CoA硫酯键的问题。我们的结果表明,以前提出的苹果酸合成酶的反应机制可能是不完整或不完全正确的。为了解决这个令人困惑的问题,可能需要进一步的研究,包括基于这些结构的定点诱变。
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The crystal structures of the tri-functional Chloroflexus aurantiacus and bi-functional Rhodobacter sphaeroides malyl-CoA lyases and comparison with CitE-like superfamily enzymes and malate synthases

Malyl-CoA lyase (MCL) is a promiscuous carbon-carbon bond lyase that catalyzes the reversible cleavage of structurally related Coenzyme A (CoA) thioesters. This enzyme plays a crucial, multifunctional role in the 3-hydroxypropionate bi-cycle for autotrophic CO2 fixation in Chloroflexus aurantiacus. A second, phylogenetically distinct MCL from Rhodobacter sphaeroides is involved in the ethylmalonyl-CoA pathway for acetate assimilation. Both MCLs belong to the large superfamily of CitE-like enzymes, which includes the name-giving β-subunit of citrate lyase (CitE), malyl-CoA thioesterases and other enzymes of unknown physiological function. The CitE-like enzyme superfamily also bears sequence and structural resemblance to the malate synthases. All of these different enzymes share highly conserved catalytic residues, although they catalyze distinctly different reactions: C-C bond formation and cleavage, thioester hydrolysis, or both (the malate synthases).

Here we report the first crystal structures of MCLs from two different phylogenetic subgroups in apo- and substrate-bound forms. Both the C. aurantiacus and the R. sphaeroides MCL contain elaborations on the canonical β88 TIM barrel fold and form hexameric assemblies. Upon ligand binding, changes in the C-terminal domains of the MCLs result in closing of the active site, with the C-terminal domain of one monomer forming a lid over and contributing side chains to the active site of the adjacent monomer. The distinctive features of the two MCL subgroups were compared to known structures of other CitE-like superfamily enzymes and to malate synthases, providing insight into the structural subtleties that underlie the functional versatility of these enzymes.

Although the C. aurantiacus and the R. sphaeroides MCLs have divergent primary structures (~37% identical), their tertiary and quaternary structures are very similar. It can be assumed that the C-C bond formation catalyzed by the MCLs occurs as proposed for malate synthases. However, a comparison of the two MCL structures with known malate synthases raised the question why the MCLs are not also able to hydrolyze CoA thioester bonds. Our results suggest the previously proposed reaction mechanism for malate synthases may be incomplete or not entirely correct. Further studies involving site-directed mutagenesis based on these structures may be required to solve this puzzling question.

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BMC Structural Biology
BMC Structural Biology 生物-生物物理
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期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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