Requirement of Bacillus subtilis succinate:menaquinone oxidoreductase activity for membrane energization depends on the direction of catalysis

IF 3.4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biochimica et Biophysica Acta-Bioenergetics Pub Date : 2024-11-08 DOI:10.1016/j.bbabio.2024.149522

Natalia V. Azarkina

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引用次数: 0

Abstract

Succinate:quinone oxidoreductases (SQR) from Bacilli catalyze reduction of menaquinone by succinate, as well as the reverse reaction. The direct activity is energetically unfavorable and lost upon ΔμН⁺ dissipation, thus suggesting ΔμН⁺ to be consumed during catalysis. Paradoxically, the generation of ΔμН⁺ upon fumarate reduction was never confirmed. Thus, the exact role of ΔμН⁺ in the operation of bacillary-type SQRs remained questionable. The purpose of this work was to clarify this issue.

We have described the different operating modes of the membrane-bound SQR from Bacillus subtilis. Tightly coupled membrane vesicles from both wild-type cells and the mutant containing cytochrome bd as the only terminal oxidase were studied. This made it possible to compare the respiratory chains with 2 versus 1H⁺/e⁻ stoichiometry of ΔμН⁺ generation. Direct and reverse activities of SQR were determined under either energized or deenergized conditions.

The wild-type membranes demonstrated high succinate oxidase activity very sensitive to uncoupling. On the contrary, the mutant showed extremely low succinate oxidase activity resistant to uncoupling. ΔμН⁺ generation at the cost of ATP hydrolysis restored the uncoupling sensitive succinate respiration in the mutant. Membranes of the both types effectively reduced fumarate by menaquinol. This activity was not affected by energization or uncoupling, neither it was followed by ΔμН⁺ generation.

Thus, B. subtilis SQR demonstrates two regimes: ΔμН⁺-coupled and not coupled. This behavior can be explained by assuming the presence of two menaquinone binding sites which drastically differ in affinity for the oxidized and reduced substrate.

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枯草芽孢杆菌琥珀酸：甲萘醌氧化还原酶活性对膜能量的要求取决于催化作用的方向。

芽孢杆菌中的琥珀酸：醌氧化还原酶（SQR）可催化琥珀酸还原甲萘醌以及反向反应。直接活性在能量上是不利的，并且在ΔμН+耗散时会丧失，因此表明ΔμН+在催化过程中会被消耗掉。矛盾的是，富马酸还原时产生的 ΔμН+ 从未得到证实。因此，ΔμН+ 在芽胞型 SQR 运行中的确切作用仍然存在疑问。这项工作的目的就是要澄清这个问题。我们描述了枯草芽孢杆菌膜结合型 SQR 的不同运行模式。我们研究了野生型细胞和含有细胞色素 bd 作为唯一末端氧化酶的突变体的紧密耦合膜囊泡。这样就可以比较呼吸链在ΔμН+生成过程中 2 和 1H+/e- 的化学计量。在通电或断电条件下测定了 SQR 的直接和反向活性。野生型膜显示出很高的琥珀酸氧化酶活性，对解偶联非常敏感。相反，突变体表现出极低的琥珀酸氧化酶活性，对解偶联具有抵抗力。以 ATP 水解为代价产生的 ΔμН+ 恢复了突变体对解偶联敏感的琥珀酸呼吸。两种类型的细胞膜都能通过甲萘醌有效地减少富马酸。这种活性不受能量化或解偶联的影响，也不会产生ΔμН+。因此，枯草芽孢杆菌 SQR 表现出两种状态：ΔμН+ 耦合和非耦合。这种行为可以通过假设存在两个对氧化底物和还原底物的亲和力截然不同的甲萘醌结合位点来解释。

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

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.