Conformational ensembles reveal the origins of serine protease catalysis

IF 45.8 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES Science Pub Date : 2025-02-14

Siyuan Du, Rachael C. Kretsch, Jacob Parres-Gold, Elisa Pieri, Vinícius Wilian D. Cruzeiro, Mingning Zhu, Margaux M. Pinney, Filip Yabukarski, Jason P. Schwans, Todd J. Martínez, Daniel Herschlag

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Abstract

Enzymes exist in ensembles of states that encode the energetics underlying their catalysis. Conformational ensembles built from 1231 structures of 17 serine proteases revealed atomic-level changes across their reaction states. By comparing the enzymatic and solution reaction, we identified molecular features that provide catalysis and quantified their energetic contributions to catalysis. Serine proteases precisely position their reactants in destabilized conformers, creating a downhill energetic gradient that selectively favors the motions required for reaction while limiting off-pathway conformational states. The same catalytic features have repeatedly evolved in proteases and additional enzymes across multiple distinct structural folds. Our ensemble-function analyses revealed previously unknown catalytic features, provided quantitative models based on simple physical and chemical principles, and identified motifs recurrent in nature that may inspire enzyme design.

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构象集合揭示丝氨酸蛋白酶催化的起源

酶以多种状态存在，这些状态编码了其催化作用背后的能量学。从17种丝氨酸蛋白酶的1231个结构中构建的构象集成揭示了它们在反应状态下的原子水平变化。通过比较酶促反应和溶液反应，我们确定了提供催化的分子特征，并量化了它们对催化的能量贡献。丝氨酸蛋白酶精确地将它们的反应物定位在不稳定的构象中，创造一个下坡的能量梯度，选择性地有利于反应所需的运动，同时限制非通路构象状态。相同的催化特征在蛋白酶和其他酶中反复进化，跨越多个不同的结构折叠。我们的集合功能分析揭示了以前未知的催化特征，提供了基于简单物理和化学原理的定量模型，并确定了自然界中反复出现的基序，可能会启发酶的设计。

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来源期刊

Science 综合性期刊-综合性期刊

CiteScore

61.10

自引率

0.90%

发文量

审稿时长

2.1 months

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