H2 production under stress: [FeFe]‑hydrogenases reveal strong stability in high pressure environments

IF 3.3 3区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biophysical chemistry Pub Date : 2024-03-11 DOI:10.1016/j.bpc.2024.107217

Kristina Edenharter , Michel W. Jaworek , Vera Engelbrecht , Roland Winter , Thomas Happe

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Abstract

Hydrogenases are a diverse group of metalloenzymes that catalyze the conversion of H₂ into protons and electrons and the reverse reaction. A subgroup is formed by the [FeFe]‑hydrogenases, which are the most efficient enzymes of microbes for catalytic H₂ conversion. We have determined the stability and activity of two [FeFe]‑hydrogenases under high temperature and pressure conditions employing FTIR spectroscopy and the high-pressure stopped-flow methodology in combination with fast UV/Vis detection. Our data show high temperature stability and an increase in activity up to the unfolding temperatures of the enzymes. Remarkably, both enzymes reveal a very high pressure stability of their structure, even up to pressures of several kbars. Their high pressure-stability enables high enzymatic activity up to 2 kbar, which largely exceeds the pressure limit encountered by organisms in the deep sea and sub-seafloor on Earth.

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压力下的 H2 生成：[FeFe]-氢化酶在高压环境中显示出强大的稳定性

氢化酶是一组催化 H2 转化为质子和电子以及逆反应的多种金属酶。由[FeFe]-氢化酶组成的亚群是微生物中催化 H2 转化最有效的酶。我们采用傅立叶变换红外光谱法和高压停流法，结合快速紫外/可见光检测法，测定了两种[FeFe]-氢化酶在高温高压条件下的稳定性和活性。我们的数据显示，这两种酶在高温下具有稳定性，并且在解折温度下活性仍在增加。值得注意的是，这两种酶都显示出其结构具有非常高的压力稳定性，甚至可以达到几千巴的压力。它们的高压力稳定性使酶的活性可高达2千巴，这大大超过了地球深海和海底下生物所遇到的压力极限。

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

Biophysical chemistry 生物-生化与分子生物学

CiteScore

6.10

自引率

10.50%

发文量

121

审稿时长

20 days

期刊介绍： Biophysical Chemistry publishes original work and reviews in the areas of chemistry and physics directly impacting biological phenomena. Quantitative analysis of the properties of biological macromolecules, biologically active molecules, macromolecular assemblies and cell components in terms of kinetics, thermodynamics, spatio-temporal organization, NMR and X-ray structural biology, as well as single-molecule detection represent a major focus of the journal. Theoretical and computational treatments of biomacromolecular systems, macromolecular interactions, regulatory control and systems biology are also of interest to the journal.