The evolution of the human mitochondrial bc1 complex- adaptation for reduced rate of superoxide production?

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Hagai Rottenberg
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Abstract

The mitochondrial bc1 complex is a major source of mitochondrial superoxide. While bc1-generated superoxide plays a beneficial signaling role, excess production of superoxide lead to aging and degenerative diseases. The catalytic core of bc1 comprises three peptides -cytochrome b, Fe-S protein, and cytochrome c1. All three core peptides exhibit accelerated evolution in anthropoid primates. It has been suggested that the evolution of cytochrome b in anthropoids was driven by a pressure to reduce the production of superoxide. In humans, the bc1 core peptides exhibit anthropoid-specific substitutions that are clustered near functionally critical sites that may affect the production of superoxide. Here we compare the high-resolution structures of bovine, mouse, sheep and human bc1 to identify structural changes that are associated with human-specific substitutions. Several cytochrome b substitutions in humans alter its interactions with other subunits. Most significantly, there is a cluster of seven substitutions, in cytochrome b, the Fe-S protein, and cytochrome c1 that affect the interactions between these proteins at the tether arm of the Fe-S protein and may alter the rate of ubiquinone oxidation and the rate of superoxide production. Another cluster of substitutions near heme bH and the ubiquinone reduction site, Qi, may affect the rate of ubiquinone reduction and thus alter the rate of superoxide production. These results are compatible with the hypothesis that cytochrome b in humans (and other anthropoid primates) evolve to reduce the rate of production of superoxide thus enabling the exceptional longevity and exceptional cognitive ability of humans.

Abstract Image

人类线粒体bc1复合体的进化——对超氧化物生成速率降低的适应?
线粒体bc1复合体是线粒体超氧化物的主要来源。虽然bc1产生的超氧化物起着有益的信号作用,但过量的超氧化物产生会导致衰老和退行性疾病。bc1的催化核心由细胞色素b、Fe-S蛋白和细胞色素c1三个多肽组成。所有三个核心肽在类人猿灵长类动物中都表现出加速的进化。有人认为,类人猿细胞色素b的进化是由减少超氧化物产生的压力驱动的。在人类中,bc1核心肽表现出类人猿特异性的取代,这些取代聚集在可能影响超氧化物产生的功能关键位点附近。在这里,我们比较了牛、小鼠、羊和人类bc1的高分辨率结构,以确定与人类特异性替代相关的结构变化。人类细胞色素b的几个替换改变了它与其他亚基的相互作用。最重要的是,在细胞色素b、Fe-S蛋白和细胞色素c1中存在7个取代簇,这些取代簇影响了Fe-S蛋白系链臂上这些蛋白之间的相互作用,并可能改变泛醌氧化的速率和超氧化物的产生速率。血红素bH和泛素还原位点Qi附近的另一个取代簇可能会影响泛素还原的速率,从而改变超氧化物的生成速率。这些结果与人类(和其他类人猿灵长类动物)细胞色素b的进化降低了超氧化物的产生速度,从而使人类具有超长的寿命和超长的认知能力的假设是一致的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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