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噬菌体P22外壳蛋白的压力变性及其在二十面体外壳中的熵稳定作用。

Pressure denaturation of the bacteriophage P22 coat protein and its entropic stabilization in icosahedral shells.

作者信息

Prevelige P E, King J, Silva J L

机构信息

Boston Biomedical Research Institute, Massachusetts 02114.

出版信息

Biophys J. 1994 May;66(5):1631-41. doi: 10.1016/S0006-3495(94)80955-5.

DOI:10.1016/S0006-3495(94)80955-5
PMID:8061212
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1275883/
Abstract

The pressure stability of bacteriophage P22 coat protein in both monomeric and polymeric forms under hydrostatic pressure was examined using light scattering, fluorescence emission, polarization, and lifetime methodology. The monomeric protein is very unstable toward pressure and undergoes significant structural changes at pressures as low as 0.5 kbar. These structural changes ultimately lead to denaturation of the subunit. Comparison of the protein denatured by pressure to that in guanidine hydrochloride suggests that pressure results in partial unfolding, perhaps by a domain mechanism. Fluorescence lifetime measurements indicate that at atmospheric pressure the local environments of the tryptophans are remarkably similar, suggesting they may be clustered. In contrast to the monomeric protein subunit, the protein when polymerized into procapsid shells is very stable to applied pressure and does not dissociate with pressure up to 2.5 kbar. However, under applied pressure the procapsid shells are cold-labile, suggesting they are entropically stabilized. The significance of these results in terms of virus assembly are discussed.

摘要

利用光散射、荧光发射、偏振和寿命测定方法,研究了噬菌体P22衣壳蛋白在静水压力下单体和聚合形式的压力稳定性。单体蛋白对压力非常不稳定,在低至0.5千巴的压力下就会发生显著的结构变化。这些结构变化最终导致亚基变性。将压力变性的蛋白质与盐酸胍中的蛋白质进行比较表明,压力可能通过结构域机制导致部分解折叠。荧光寿命测量表明,在大气压下,色氨酸的局部环境非常相似,这表明它们可能聚集在一起。与单体蛋白亚基不同,聚合形成原衣壳壳的蛋白质对施加的压力非常稳定,在高达2.5千巴的压力下不会解离。然而,在施加压力下,原衣壳壳对冷敏感,这表明它们是通过熵稳定的。讨论了这些结果在病毒组装方面的意义。

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