无轴 F1-ATP 酶的分子结构。

IF 3.4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biochimica et Biophysica Acta-Bioenergetics Pub Date : 2024-10-18 DOI:10.1016/j.bbabio.2024.149521

Emily J. Furlong , Ian-Blaine P. Reininger-Chatzigiannakis , Yi C. Zeng , Simon H.J. Brown , Meghna Sobti , Alastair G. Stewart

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引用次数: 0

摘要

F1Fo ATP 合酶是一种分子旋转马达，可利用跨膜质子动力产生 ATP。分离的 F1-ATP 酶催化核心可以水解 ATP，并通过一系列构象状态，包括中心 γ 转子亚基的旋转和催化 β 亚基的开合。长期以来，人们一直认为 F1-ATP 酶的协同作用是通过 γ 亚基实现的，并已发现 γ 和 β 亚基之间有三个关键的相互作用位点。单分子研究表明，缺少γ轴的F1复合物仍能 "旋转 "并水解ATP，但效率较低。我们解决了无轴芽孢杆菌 PS3 F1-ATP 酶的低温电子显微镜结构。该结构意想不到的结合-停留构象，以及观察到的无轴γ和开放β亚基之间缺乏相互作用的现象表明，完整的γ亚基对于协调F1-ATP酶有效的ATP结合非常重要。

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The molecular structure of an axle-less F1-ATPase

F₁F_o ATP synthase is a molecular rotary motor that can generate ATP using a transmembrane proton motive force. Isolated F₁-ATPase catalytic cores can hydrolyse ATP, passing through a series of conformational states involving rotation of the central γ rotor subunit and the opening and closing of the catalytic β subunits. Cooperativity in F₁-ATPase has long thought to be conferred through the γ subunit, with three key interaction sites between the γ and β subunits being identified. Single molecule studies have demonstrated that the F₁ complexes lacking the γ axle still “rotate” and hydrolyse ATP, but with less efficiency. We solved the cryogenic electron microscopy structure of an axle-less Bacillus sp. PS3 F₁-ATPase. The unexpected binding-dwell conformation of the structure in combination with the observed lack of interactions between the axle-less γ and the open β subunit suggests that the complete γ subunit is important for coordinating efficient ATP binding of F₁-ATPase.

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来源期刊

Biochimica et Biophysica Acta-Bioenergetics 生物-生化与分子生物学

CiteScore

9.50

自引率

7.00%

发文量

363

审稿时长

92 days

期刊介绍： BBA Bioenergetics covers the area of biological membranes involved in energy transfer and conversion. In particular, it focuses on the structures obtained by X-ray crystallography and other approaches, and molecular mechanisms of the components of photosynthesis, mitochondrial and bacterial respiration, oxidative phosphorylation, motility and transport. It spans applications of structural biology, molecular modeling, spectroscopy and biophysics in these systems, through bioenergetic aspects of mitochondrial biology including biomedicine aspects of energy metabolism in mitochondrial disorders, neurodegenerative diseases like Parkinson''s and Alzheimer''s, aging, diabetes and even cancer.