Plant defensins as a model to study the thermostability of surface hydrophobic clusters: The Pisum sativum defensin 2 (Psd2)

IF 2.624
Ramon Pinheiro-Aguiar , Caroline Corrêa-Almeida , Eleonora Kurtenbach , Fabio C.L. Almeida
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引用次数: 1

Abstract

Plant defensins (PDs) display a CSαβ-fold that lacks a canonical hydrophobic core. They display almost all hydrophobic residues on the protein surface. The exposed hydrophobic residues form surface clusters stabilized by the vicinity of hydrophilic residues and the hydration shell. Here, we used Psd2 as a model to study the formation and stabilization of these local foldons named surface hydrophobic clusters (SHC). We characterized the temperature dependence of 15N CPMG relaxation dispersion profiles to describe the complex dynamics of Psd2 and indirectly study the thermodynamics of SHCs in PDs. We show a correlation between residues undergoing conformational exchange and the SHCs. Chemical shift changes between the native ground state and the first thermally accessible excited state enabled us to map the major conformational changes in Psd2 conformational equilibrium. The observation of a cold-driven excited state revealed that SHCs are stabilized by hydrophobic contacts, which are exposed at low temperatures, leading to a favorable decrease in enthalpy compensated by an unfavorable entropy reduction. At higher temperatures, we detected another excited conformer that may play a role in membrane-specific interaction, as previously described for other defensins.

Abstract Image

植物防御素作为研究表面疏水簇热稳定性的模型:Pisum sativum防御素2 (Psd2)
植物防御素(pd)显示缺乏典型疏水核心的cs αβ-折叠。它们在蛋白质表面显示了几乎所有的疏水残基。暴露的疏水残基在亲水性残基和水化壳附近形成稳定的表面团簇。在这里,我们以Psd2为模型,研究了这些被称为表面疏水簇(SHC)的局部折叠的形成和稳定性。我们表征了15N CPMG弛豫色散曲线的温度依赖性,以描述Psd2的复杂动力学,并间接研究了Psd2中SHCs的热力学。我们展示了构象交换的残基与SHCs之间的相关性。在原生基态和第一热可达激发态之间的化学位移变化使我们能够绘制Psd2构象平衡的主要构象变化。对冷驱动激发态的观察表明,在低温下暴露的疏水接触稳定了SHCs,导致有利的焓降低被不利的熵降低所补偿。在较高的温度下,我们检测到另一种激发的构象,可能在膜特异性相互作用中发挥作用,如前所述的其他防御蛋白。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.90
自引率
0.00%
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