速度与效率的对立压力引导分子机器的进化。

Opposing Pressures of Speed and Efficiency Guide the Evolution of Molecular Machines.

机构信息

Laufer Center for Physical and Quantitative Biology, Stony Brook University, Stony Brook, NY.

Department of Chemistry, Stony Brook University, Stony Brook, NY.

出版信息

Mol Biol Evol. 2019 Dec 1;36(12):2813-2822. doi: 10.1093/molbev/msz190.

DOI:10.1093/molbev/msz190

PMID:31432071

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6878954/

Abstract

Many biomolecular machines need to be both fast and efficient. How has evolution optimized these machines along the tradeoff between speed and efficiency? We explore this question using optimizable dynamical models along coordinates that are plausible evolutionary degrees of freedom. Data on 11 motors and ion pumps are consistent with the hypothesis that evolution seeks an optimal balance of speed and efficiency, where any further small increase in one of these quantities would come at great expense to the other. For FoF1-ATPases in different species, we also find apparent optimization of the number of subunits in the c-ring, which determines the number of protons pumped per ATP synthesized. Interestingly, these ATPases appear to more optimized for efficiency than for speed, which can be rationalized through their key role as energy transducers in biology. The present modeling shows how the dynamical performance properties of biomolecular motors and pumps may have evolved to suit their corresponding biological actions.

摘要

许多生物分子机器需要既快速又高效。进化是如何沿着速度和效率之间的权衡来优化这些机器的呢？我们使用沿着合理进化自由度坐标的可优化动力学模型来探索这个问题。11 个马达和离子泵的数据与以下假设一致，即进化寻求速度和效率之间的最佳平衡，在这种平衡下，任何一个数量的微小增加都会对另一个数量造成巨大的损失。对于不同物种的 FoF1-ATP 酶，我们还发现 c 环中亚基数量的明显优化，这决定了每合成一个 ATP 泵出的质子数量。有趣的是，这些 ATP 酶似乎比速度更注重效率，这可以通过它们在生物学中作为能量转换器的关键作用来解释。本研究表明，生物分子马达和泵的动力学性能是如何进化以适应其相应的生物学作用的。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/78ad/6878954/7408456ed1d6/msz190f1.jpg

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速度与效率的对立压力引导分子机器的进化。

Opposing Pressures of Speed and Efficiency Guide the Evolution of Molecular Machines.

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