Mpro-C蛋白三维结构域交换的机理:来自分子模拟的线索

SARS coronavirus main protease (Mpro) is a key enzyme involved in the extensive proteolytic processing of the virus? polyproteins. The crystal structure of Mpro reveals that the enzyme exists in two different homo-dimeric forms: a three-dimensional (3D) domain-swapped form; and a non-3D domain-swapped form. The isolated C-terminal domain (Mpro-C) also forms a 3D domain-swapped structure similar to the ful-length protein. Unlike conventional 3D domain-swapped structures, in which the swapped regions are located on the surface, Mpro-C swaps a helix at the core of a folded domain. In this work, we used molecular dynamics simulations and 3D domain-swapping predictions to investigate how a highly buried core helix in the helix bundle structure of Mpro-C can be swapped. We found that both structure-and sequence-based methods failed to predict the location of the hinge loop in Mpro-C and Mpro. Extensive molecular dynamics simulations were performed to investigate the structural properties of the unfolded monomer and the 3D domain-swapped dimer of Mpro-C. We found that, although the swapped region was buried in the native state, it was exposed in the unfolded monomer. Our results suggest that the opening of the swapped region in the ful y or partial y unfolded state may promote interactions between monomers and the formation of domain-swapped dimers.     

天然无序蛋白质:序列-结构-功能的新关系

天然无序蛋白质是一类新发现的蛋白质,它们在天然条件下没有确定的三维结构,却具有正常的生物学功能,广泛参与信号传递、DNA转录、细胞分裂和蛋白质聚集等重要的生理与病理过程.无序蛋白质的发现是对传统的蛋白质"序列-结构-功能"范式的挑战.在这篇综述里,我们首先回顾了蛋白质的传统范式以及无序蛋白质的发现过程,然后介绍无序蛋白质在结构、序列、功能等方面的特征与相互作用,并以分子识别过程为例,进一步阐述目前国际上对无序蛋白质所具有优势的一些认识与观点.我们还分析了无序蛋白质研究在生命科学和医学等领域的应用前景,并介绍了国内在无序蛋白质领域的研究现状.     

Mpro-C蛋白三维结构域交换的机理: 来自分子模拟的线索

SARS冠状病毒主蛋白酶(M^pro)在病毒的蛋白酶切过程中发挥着重要作用. M^pro的晶体结构显示它存在两种形式的二聚体: 一种是发生三维结构域交换的形式, 另一种是非交换的形式. M^pro的C端结构域(M^pro-C)单独表达时也能形成与全长M^pro类似的三维结构域交换二聚体. 三维结构域交换通常发生在蛋白质的表面, 但M^pro-C 的结构域交换却发生在疏水核心. 在本文中, 我们利用分子动力学模拟及三维结构域交换预测算法研究了M^pro-C 中被高度埋藏的核心螺旋片段发生交换的机理. 我们发现基于结构与基于序列的已有算法都不能正确预言出M^pro-C和M^pro中发生结构域交换的铰链区位置. 分子模拟结果表明M^pro-C中的交换片段在天然态下埋藏得很好, 但在变性单体中则会被释放并暴露在外面. 因此, 在完全或部分解折叠状态下交换片段的打开有助于促进单体间的相互作用及结构域交换二聚体的形成.