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氧亚氨基取代的硼酸和β-内酰胺与 CMY-2 衍生的扩展谱头孢菌素酶 CMY-30 和 CMY-42 的相互作用。

Interactions of oximino-substituted boronic acids and β-lactams with the CMY-2-derived extended-spectrum cephalosporinases CMY-30 and CMY-42.

机构信息

Laboratory of Bacteriology, Hellenic Pasteur Institute, Athens, Greece.

出版信息

Antimicrob Agents Chemother. 2013 Feb;57(2):968-76. doi: 10.1128/AAC.01620-12. Epub 2012 Dec 10.

DOI:10.1128/AAC.01620-12
PMID:23229484
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3553701/
Abstract

CMY-30 and CMY-42 are extended-spectrum (ES) derivatives of CMY-2. ES characteristics are due to substitutions of Gly (CMY-30) and Ser (CMY-42) for Val211 in the Ω-loop. To characterize the effects of 211 substitutions, we studied the interactions of CMY-2, -30, and -42 with boronic acid transition state inhibitors (BATSIs) resembling ceftazidime and cefotaxime, assessed thermal stability of the enzymes in their free forms and in complexes with BATSIs and oximino-β-lactams, and simulated, using molecular dynamics (MD), the CMY-42 apoenzyme and the CMY-42 complexes with ceftazidime and the ceftazidime-like BATSI. Inhibition constants showed that affinities between CMY-30 and CMY-42 and the R1 groups of BATSIs were lower than those of CMY-2. ES variants also exhibited decreased thermal stability either as apoenzymes or in covalent complexes with oximino compounds. MD simulations further supported destabilization of the ES variants. Val211Ser increased thermal factors of the Ω-loop backbone atoms, as previously observed for CMY-30. The similar effects of the two substitutions seemed to be due to a less-constrained Tyr221 likely inducing concerted movement of elements at the edges of the active site (Ω-loop-Q120 loop-R2 loop/H10 helix). This inner-protein movement, along with the wider R1 binding cleft, enabled intense vibrations of the covalently bound ceftazidime and ceftazidime-like BATSIs. Increased flexibility of the ES enzymes may assist the productive adaptation of the active site to the various geometries of the oximino substrates during the reaction (higher frequency of near-attack conformations).

摘要

CMY-30 和 CMY-42 是 CMY-2 的扩展谱(ES)衍生物。ES 特性归因于 Ω 环中 Val211 被 Gly(CMY-30)和 Ser(CMY-42)取代。为了研究 211 位取代的影响,我们研究了 CMY-2、-30 和-42 与类似于头孢他啶和头孢噻肟的硼酸过渡态抑制剂(BATSIs)的相互作用,评估了酶在游离形式及其与 BATSIs 和肟基-β-内酰胺复合物中的热稳定性,并使用分子动力学(MD)模拟了 CMY-42 脱辅基酶和 CMY-42 与头孢他啶和头孢他啶类似的 BATSIs 的复合物。抑制常数表明,CMY-30 和 CMY-42 与 BATSIs 的 R1 基团之间的亲和力低于 CMY-2。ES 变体无论是作为脱辅基酶还是与肟基化合物形成共价复合物,其热稳定性也降低。MD 模拟进一步支持 ES 变体的失稳。与之前观察到的 CMY-30 一样,Val211Ser 增加了 Ω 环骨架原子的热因素。这两种取代的相似影响似乎归因于 Tyr221 的限制较小,可能导致活性位点(Ω 环-Q120 环-R2 环/H10 螺旋)边缘元件的协同运动。这种内蛋白运动,以及更宽的 R1 结合裂缝,使共价结合的头孢他啶和头孢他啶类似的 BATSIs 能够剧烈振动。ES 酶的灵活性增加可能有助于在反应过程中(近攻击构象的频率更高)使活性位点适应肟基底物的各种几何形状。

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