Department of Chemistry, University of Nebraska-Lincoln, Lincoln, Nebraska, 68588-0304, USA.
Department of Biochemistry, University of Nebraska-Lincoln, Lincoln, Nebraska, 68588-0664, USA.
Biopolymers. 2024 Jan;115(1):e23534. doi: 10.1002/bip.23534. Epub 2023 Mar 27.
DJ-1 is a homodimeric protein that is centrally involved in various human diseases including Parkinson disease (PD). DJ-1 protects against oxidative damage and mitochondrial dysfunction through a homeostatic control of reactive oxygen species (ROS). DJ-1 pathology results from a loss of function, where ROS readily oxidizes a highly conserved and functionally essential cysteine (C106). The over-oxidation of DJ-1 C106 leads to a dynamically destabilized and biologically inactivated protein. An analysis of the structural stability of DJ-1 as a function of oxidative state and temperature may provide further insights into the role the protein plays in PD progression. NMR spectroscopy, circular dichroism, analytical ultracentrifugation sedimentation equilibrium, and molecular dynamics simulations were utilized to investigate the structure and dynamics of the reduced, oxidized (C106-SO ), and over-oxidized (C106-SO ) forms of DJ-1 for temperatures ranging from 5°C to 37°C. The three oxidative states of DJ-1 exhibited distinct temperature-dependent structural changes. A cold-induced aggregation occurred for the three DJ-1 oxidative states by 5°C, where the over-oxidized state aggregated at significantly higher temperatures than both the oxidized and reduced forms. Only the oxidized and over-oxidized forms of DJ-1 exhibited a mix state containing both folded and partially denatured protein that likely preserved secondary structure content. The relative amount of this denatured form of DJ-1 increased as the temperature was lowered, consistent with a cold-denaturation. Notably, the cold-induced aggregation and denaturation for the DJ-1 oxidative states were completely reversible. The dramatic changes in the structural stability of DJ-1 as a function of oxidative state and temperature are relevant to its role in PD and its functional response to oxidative stress.
DJ-1 是一种同二聚体蛋白,它在包括帕金森病(PD)在内的各种人类疾病中起着核心作用。DJ-1 通过对活性氧(ROS)的稳态控制来保护细胞免受氧化损伤和线粒体功能障碍。DJ-1 病理学源于功能丧失,其中 ROS 容易氧化高度保守且功能必需的半胱氨酸(C106)。DJ-1 C106 的过度氧化导致其动态失稳和生物失活。分析 DJ-1 的结构稳定性作为氧化状态和温度的函数可能会进一步了解该蛋白在 PD 进展中的作用。利用 NMR 光谱学、圆二色性、分析超速离心沉降平衡和分子动力学模拟研究了还原态、氧化态(C106-SO )和过氧化态(C106-SO )DJ-1 的结构和动力学,温度范围为 5°C 至 37°C。DJ-1 的三种氧化态表现出明显的温度依赖性结构变化。三种 DJ-1 氧化态在 5°C 时发生冷诱导聚集,其中过氧化物态在明显高于氧化态和还原态的温度下聚集。只有氧化态和过氧化物态的 DJ-1 表现出一种混合态,其中包含折叠和部分变性的蛋白质,可能保留了二级结构含量。随着温度降低,这种变性形式的 DJ-1 的相对含量增加,与冷变性一致。值得注意的是,DJ-1 氧化态的冷诱导聚集和变性是完全可逆的。DJ-1 的结构稳定性随氧化状态和温度的显著变化与其在 PD 中的作用及其对氧化应激的功能响应有关。
