从热力学稳定和动力学受困的枯草杆菌蛋白中探索能量景观的序列和结构决定因素:ISP1和SbtE

Miriam Rose Hood, Susan Marqusee
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引用次数: 0

摘要

蛋白质的能谱、所有可获得的构象、构象群及其相互转换的动力学,都编码在蛋白质的主序列中。虽然我们对蛋白质的主序列如何编码其原生状态有了很好的了解,但我们对序列如何编码动力学障碍(如展开和重折叠)的了解要薄弱得多。在这里,我们研究了枯草芽孢杆菌(Bacillus subtilis)的两种亚纤酶同源物--胞内亚纤酶蛋白酶 1(ISP1)和亚纤酶蛋白 E(SbtE),它们预计具有非常不同的动力学特性。作为一种细胞内蛋白,ISP1 有一个小的前结构域,被认为只是起到酶原的作用,而细胞外的 SbtE 则有一个折叠所需的大的前结构域。我们研究了成熟蛋白酶的全局和局部能量,以及每个前结构域如何影响它们的景观。我们发现,ISP1 的前结构域对能量景观的影响有限,而成熟的 SbtE 在热力学上不稳定,并存在动力学陷阱。原结构域的影响对蛋白质核心的灵活性具有相反的作用。ISP1 的核心变得更灵活,而 SbtE 的核心变得更僵硬。ISP1 包含一个细胞外枯草蛋白酶中不存在的保守氨基酸插入物,这表明这些差异的潜在来源。这些同源物是一个极端的例子,说明主序列的变化如何极大地改变蛋白质的能量景观、稳定性和动力学,并突出了对主序列与构象动力学之间关系进行大规模、高通量研究的必要性。
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Exploring the sequence and structural determinants of the energy landscape from thermodynamically stable and kinetically trapped subtilisins: ISP1 and SbtE
A protein′s energy landscape, all the accessible conformations, their populations, and their dynamics of interconversion, is encoded in its primary sequence. While we have a good understanding of how a protein′s primary sequence encodes its native state, we have a much weaker understanding of how sequence encodes the kinetic barriers such as unfolding and refolding. Here we have looked at two subtiliase homologs from the Bacillus subtilis, Intracellular Subtilisin Protease 1 (ISP1) and Subtilisin E (SbtE) that are expected to have very different dynamics. As an intracellular protein, ISP1 has a small pro-domain thought to act simply as a zymogen, whereas the extracellular SbtE has a large pro-domain required for folding. We examined the global and local energetics of the mature proteases and how each pro-domain impacts their landscapes. We find that ISP1′s pro-domain has limited impact on the energy landscape while the mature SbtE is thermodynamically unstable and kinetically trapped. The impact of the pro-domain has opposite effects on the flexibility of the core of the protein. ISP1′s core becomes more flexible while SbtE′s core becomes more rigid. ISP1 contains a conserved amino-acid insertion not present in extracellular subtilisin proteases, which points to a potential source for these differences. These homologs are an extreme example of how changes in the primary sequence can dramatically alter a proteins energy landscape, both stability and dynamics, and highlight the need for large scale, high throughput studies on the relationship between primary sequence and conformational dynamics.
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