Farrokhzad Roghayeh, Seyedalipour Bagher, Baziyar Payam, Hosseinkhani Saman
Department of Molecular and Cell Biology, Faculty of Basic Science, University of Mazandaran, Babolsar, Iran.
Department of Biochemistry, Faculty of Biological Sciences, Tarbiat Modares University, Tehran, Iran.
Proteins. 2025 Apr;93(4):885-907. doi: 10.1002/prot.26765. Epub 2024 Dec 6.
Disturbances in metal ion homeostasis associated with amyotrophic lateral sclerosis (ALS) have been described for several years, but the exact mechanism of involvement is not well understood. To elucidate the role of metalation in superoxide dismutase (SOD1) misfolding and aggregation, we comprehensively characterized the structural features (apo/holo forms) of WT-SOD1 and P66R mutant in loop IV. Using computational and experimental methodologies, we assessed the physicochemical properties of these variants and their correlation with protein aggregation at the molecular level. Modifications in apo-SOD1 compared to holo-SOD1 were more pronounced in flexibility, stability, hydrophobicity, and intramolecular interactions, as indicated by molecular dynamics simulations. The enzymatic activities of holo/apo-WT SOD1 were 1.30 and 1.88-fold of the holo/apo P66R mutant, respectively. Under amyloid-inducing conditions, decreased ANS fluorescence intensity in the apo-form relative to the holo-form suggested pre-fibrillar species and amyloid aggregate growth due to occluded hydrophobic pockets. FTIR spectroscopy revealed that apo-WT-SOD1 and apo-P66R exhibited a mixture of parallel and intermolecular β-sheet structures, indicative of aggregation propensity. Aggregate species were identified using TEM, Congo red staining, and ThT/ANS fluorescence spectroscopy. Thermodynamic analyses with GdnHCl demonstrated that metal deficit, mutation, and intramolecular disulfide bond reduction are essential for initiating SOD1 misfolding and aggregation. These disruptions destabilize the dimer-monomer equilibrium, promoting dimer dissociation into monomers and decreasing the thermodynamic stability of SOD1 variants, thus facilitating amyloid/amorphous aggregate formation. Our findings offer novel insights into protein aggregation mechanisms in disease pathology and highlight potential therapeutic strategies against toxic protein aggregation, including SOD1.
与肌萎缩侧索硬化症(ALS)相关的金属离子稳态紊乱已经被描述多年,但具体的参与机制尚未完全清楚。为了阐明金属化在超氧化物歧化酶(SOD1)错误折叠和聚集过程中的作用,我们全面表征了WT-SOD1和环IV中P66R突变体的结构特征(脱辅基/全酶形式)。使用计算和实验方法,我们在分子水平上评估了这些变体的物理化学性质及其与蛋白质聚集的相关性。分子动力学模拟表明,与全酶形式的SOD1相比,脱辅基SOD1在柔韧性、稳定性、疏水性和分子内相互作用方面的变化更为明显。全酶/脱辅基-WT SOD1的酶活性分别是全酶/脱辅基P66R突变体的1.30倍和1.88倍。在淀粉样蛋白诱导条件下,脱辅基形式相对于全酶形式的ANS荧光强度降低,表明由于疏水口袋被封闭,预纤维状物种和淀粉样聚集体生长。傅里叶变换红外光谱显示,脱辅基-WT-SOD1和脱辅基-P66R呈现出平行和分子间β-折叠结构的混合,表明具有聚集倾向。使用透射电子显微镜、刚果红染色和硫黄素T/ANS荧光光谱鉴定聚集体种类。用盐酸胍进行的热力学分析表明,金属缺乏、突变和分子内二硫键还原是引发SOD1错误折叠和聚集的关键因素。这些破坏使二聚体-单体平衡不稳定,促进二聚体解离成单体,并降低SOD1变体的热力学稳定性,从而促进淀粉样/无定形聚集体的形成。我们的研究结果为疾病病理学中的蛋白质聚集机制提供了新的见解,并突出了针对有毒蛋白质聚集(包括SOD1)的潜在治疗策略。
