Distinct enzymatic strategies for de novo generation of disulfide bonds in membranes.

IF 6.2 2区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Critical Reviews in Biochemistry and Molecular Biology Pub Date : 2023-02-01 Epub Date: 2023-04-25 DOI:10.1080/10409238.2023.2201404
Weikai Li
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Abstract

Disulfide bond formation is a catalyzed reaction essential for the folding and stability of proteins in the secretory pathway. In prokaryotes, disulfide bonds are generated by DsbB or VKOR homologs that couple the oxidation of a cysteine pair to quinone reduction. Vertebrate VKOR and VKOR-like enzymes have gained the epoxide reductase activity to support blood coagulation. The core structures of DsbB and VKOR variants share the architecture of a four-transmembrane-helix bundle that supports the coupled redox reaction and a flexible region containing another cysteine pair for electron transfer. Despite considerable similarities, recent high-resolution crystal structures of DsbB and VKOR variants reveal significant differences. DsbB activates the cysteine thiolate by a catalytic triad of polar residues, a reminiscent of classical cysteine/serine proteases. In contrast, bacterial VKOR homologs create a hydrophobic pocket to activate the cysteine thiolate. Vertebrate VKOR and VKOR-like maintain this hydrophobic pocket and further evolved two strong hydrogen bonds to stabilize the reaction intermediates and increase the quinone redox potential. These hydrogen bonds are critical to overcome the higher energy barrier required for epoxide reduction. The electron transfer process of DsbB and VKOR variants uses slow and fast pathways, but their relative contribution may be different in prokaryotic and eukaryotic cells. The quinone is a tightly bound cofactor in DsbB and bacterial VKOR homologs, whereas vertebrate VKOR variants use transient substrate binding to trigger the electron transfer in the slow pathway. Overall, the catalytic mechanisms of DsbB and VKOR variants have fundamental differences.

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膜中从头生成二硫键的不同酶促策略。
二硫键的形成是一种催化反应,对分泌途径中蛋白质的折叠和稳定性至关重要。在原核生物中,二硫键是由 DsbB 或 VKOR 同源物生成的,它们将半胱氨酸对的氧化与醌还原结合起来。脊椎动物的 VKOR 和类似 VKOR 的酶具有环氧化物还原酶活性,支持血液凝固。DsbB 和 VKOR 变体的核心结构具有相同的结构,即一个支持耦合氧化还原反应的四跨膜螺旋束和一个含有另一对半胱氨酸的柔性区域,用于电子传递。尽管 DsbB 和 VKOR 变体的高分辨率晶体结构有很大的相似性,但它们最近的高分辨率晶体结构显示出显著的差异。DsbB 通过极性残基催化三元组激活半胱氨酸硫酸盐,这让人想起经典的半胱氨酸/丝氨酸蛋白酶。相比之下,细菌的 VKOR 同源物会形成一个疏水袋来激活硫代半胱氨酸。脊椎动物的 VKOR 和类 VKOR 保持了这个疏水袋,并进一步演化出两个强氢键,以稳定反应中间产物并提高醌的氧化还原电位。这些氢键对于克服环氧化物还原所需的较高能量屏障至关重要。DsbB 和 VKOR 变体的电子传递过程使用慢速和快速途径,但它们在原核细胞和真核细胞中的相对贡献可能不同。在 DsbB 和细菌 VKOR 同源物中,醌是一种紧密结合的辅助因子,而脊椎动物的 VKOR 变体则利用瞬时底物结合来触发慢速途径中的电子转移。总之,DsbB 和 VKOR 变体的催化机制有着本质的区别。
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来源期刊
CiteScore
14.90
自引率
0.00%
发文量
6
期刊介绍: As the discipline of biochemistry and molecular biology have greatly advanced in the last quarter century, significant contributions have been made towards the advancement of general medicine, genetics, immunology, developmental biology, and biophysics. Investigators in a wide range of disciplines increasingly require an appreciation of the significance of current biochemical and molecular biology advances while, members of the biochemical and molecular biology community itself seek concise information on advances in areas remote from their own specialties. Critical Reviews in Biochemistry and Molecular Biology believes that well-written review articles prove an effective device for the integration and meaningful comprehension of vast, often contradictory, literature. Review articles also provide an opportunity for creative scholarship by synthesizing known facts, fruitful hypotheses, and new concepts. Accordingly, Critical Reviews in Biochemistry and Molecular Biology publishes high-quality reviews that organize, evaluate, and present the current status of high-impact, current issues in the area of biochemistry and molecular biology. Topics are selected on the advice of an advisory board of outstanding scientists, who also suggest authors of special competence. The topics chosen are sufficiently broad to interest a wide audience of readers, yet focused enough to be within the competence of a single author. Authors are chosen based on their activity in the field and their proven ability to produce a well-written publication.
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