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半胱氨酸β-合酶介导的 HS 生物合成:氨基氧乙酸的抑制机制和丝氨酸的意外作用。

HS biogenesis by cystathionine beta-synthase: mechanism of inhibition by aminooxyacetic acid and unexpected role of serine.

机构信息

Department of Pharmacology, Faculty of Science and Medicine, University of Fribourg, Chemin du Musee 18, PER17, 1700, Fribourg, Switzerland.

Structural Biology Unit, Evotec Ltd, 114 Innovation Drive, Abingdon, OX14 4RZ, UK.

出版信息

Cell Mol Life Sci. 2022 Jul 21;79(8):438. doi: 10.1007/s00018-022-04479-9.

DOI:10.1007/s00018-022-04479-9
PMID:35864237
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9304066/
Abstract

Cystathionine beta-synthase (CBS) is a pivotal enzyme of the transsulfuration pathway responsible for diverting homocysteine to the biosynthesis of cysteine and production of hydrogen sulfide (HS). Aberrant upregulation of CBS and overproduction of HS contribute to pathophysiology of several diseases including cancer and Down syndrome. Therefore, pharmacological CBS inhibition has emerged as a prospective therapeutic approach. Here, we characterized binding and inhibitory mechanism of aminooxyacetic acid (AOAA), the most commonly used CBS inhibitor. We found that AOAA binds CBS tighter than its respective substrates and forms a dead-end PLP-bound intermediate featuring an oxime bond. Surprisingly, serine, but not cysteine, replaced AOAA from CBS and formed an aminoacrylate reaction intermediate, which allowed for the continuation of the catalytic cycle. Indeed, serine rescued and essentially normalized the enzymatic activity of AOAA-inhibited CBS. Cellular studies confirmed that AOAA decreased HS production and bioenergetics, while additional serine rescued CBS activity, HS production and mitochondrial function. The crystal structure of AOAA-bound human CBS showed a lack of hydrogen bonding with residues G305 and Y308, found in the serine-bound model. Thus, AOAA-inhibited CBS could be reactivated by serine. This difference may be important in a cellular environment in multiple pathophysiological conditions and may modulate the CBS-inhibitory activity of AOAA. In addition, our results demonstrate additional complexities of using AOAA as a CBS-specific inhibitor of HS biogenesis and point to the urgent need to develop a potent, selective and specific pharmacological CBS inhibitor.

摘要

胱硫醚β-合酶(CBS)是转硫途径中的关键酶,负责将同型半胱氨酸分流到半胱氨酸的生物合成和硫化氢(HS)的产生。CBS 的异常上调和 HS 的过度产生导致了包括癌症和唐氏综合征在内的多种疾病的病理生理学。因此,药理学 CBS 抑制已成为一种有前途的治疗方法。在这里,我们描述了氨基氧乙酸(AOAA)的结合和抑制机制,AOAA 是最常用的 CBS 抑制剂。我们发现,AOAA 与 CBS 的结合比其各自的底物更紧密,并形成一个具有肟键的无出路的 PLP 结合的中间产物。令人惊讶的是,丝氨酸而不是半胱氨酸取代 CBS 中的 AOAA 并形成一个氨基丙烯酸反应中间产物,这允许催化循环继续进行。事实上,丝氨酸挽救并基本上使 AOAA 抑制的 CBS 的酶活性正常化。细胞研究证实,AOAA 降低了 HS 的产生和生物能量,而额外的丝氨酸挽救了 CBS 活性、HS 产生和线粒体功能。AOAA 结合的人 CBS 的晶体结构显示与丝氨酸结合模型中发现的 G305 和 Y308 残基缺乏氢键。因此,AOAA 抑制的 CBS 可以被丝氨酸重新激活。这种差异在多种病理生理条件下的细胞环境中可能很重要,并可能调节 AOAA 对 CBS 抑制活性的影响。此外,我们的结果表明,使用 AOAA 作为 HS 生物合成的 CBS 特异性抑制剂存在更多的复杂性,并指出迫切需要开发一种有效的、选择性和特异性的药理学 CBS 抑制剂。

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