Assessment of amino acid charge states based on cryo-electron microscopy and molecular dynamics simulations of respiratory complex I

IF 3.4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY Biochimica et Biophysica Acta-Bioenergetics Pub Date : 2024-09-24 DOI:10.1016/j.bbabio.2024.149512

Jonathan Lasham , Amina Djurabekova , Georgios Kolypetris , Volker Zickermann , Janet Vonck , Vivek Sharma

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Abstract

The charge states of titratable amino acid residues play a key role in the function of membrane-bound bioenergetic proteins. However, determination of these charge states both through experimental and computational approaches is extremely challenging. Cryo-EM density maps can provide insights on the charge states of titratable amino acid residues. By performing classical atomistic molecular dynamics simulations on the high resolution cryo-EM structures of respiratory complex I from Yarrowia lipolytica, we analyze the conformational and charge states of a key acidic residue in its ND1 subunit, aspartic acid D203, which is also a mitochondrial disease mutation locus. We suggest that in the native state of respiratory complex I, D203 is negatively charged and maintains a stable hydrogen bond to a conserved arginine residue. Alternatively, upon conformational change in the turnover state of the enzyme, its sidechain attains a charge-neutral status. We discuss the implications of this analysis on the molecular mechanism of respiratory complex I.

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基于低温电子显微镜和呼吸复合体 I 分子动力学模拟的氨基酸电荷状态评估。

可滴定氨基酸残基的电荷状态对膜结合生物能蛋白质的功能起着关键作用。然而，通过实验和计算方法确定这些电荷状态极具挑战性。低温电子显微镜密度图可以让人们深入了解可滴定氨基酸残基的电荷状态。通过对来自脂溶性亚罗维氏菌（Yarrowia lipolytica）的呼吸复合体 I 的高分辨率低温电子显微镜结构进行经典原子分子动力学模拟，我们分析了其 ND1 亚基中一个关键酸性残基（天冬氨酸 D203）的构象和电荷状态，该残基也是线粒体疾病的突变位点。我们认为，在呼吸复合体 I 的原生状态下，D203 带有负电荷，并与一个保守的精氨酸残基保持稳定的氢键。或者，在酶的转换状态发生构象变化时，其侧链会达到电荷中性状态。我们讨论了这一分析对呼吸复合体 I 分子机制的影响。

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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.