The effect of denaturants on protein thermal stability analyzed through a theoretical model considering multiple binding sites

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-07-01 DOI:10.1016/j.bbapap.2023.140920
M. Ines Burgos , Sergio A. Dassie , Gerardo D. Fidelio
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Abstract

A novel mathematical development applied to protein ligand binding thermodynamics is proposed, which allows the simulation, and therefore the analysis of the effects of multiple and independent binding sites to the Native and/or Unfolded protein conformations, with different binding constant values. Protein stability is affected when it binds to a small number of high affinity ligands or to a high number of low affinity ligands. Differential scanning calorimetry (DSC) measures released or absorbed energy of thermally induced structural transitions of biomolecules. This paper presents the general theoretical development for the analysis of thermograms of proteins obtained for n-ligands bound to the native protein and m-ligands bound to their unfolded form. In particular, the effect of ligands with low affinity and with a high number of binding sites (n and/or m > 50) is analyzed. If the interaction with the native form of the protein is the one that predominates, they are considered stabilizers and if the binding with the unfolded species predominates, it is expected a destabilizing effect. The formalism presented here can be adapted to fitting routines in order to simultaneously obtain the unfolding energy and ligand binding energy of the protein. The effect of guanidinium chloride on bovine serum albumin thermal stability, was successfully analyzed with the model considering low number of middle affinity binding sites to the native state and a high number of weak binding sites to the unfolded state.

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通过考虑多结合位点的理论模型分析了变性剂对蛋白质热稳定性的影响
提出了一种应用于蛋白质配体结合热力学的新数学发展,该发展允许模拟,并因此分析具有不同结合常数值的多个独立结合位点对天然和/或未折叠蛋白质构象的影响。当蛋白质与少量高亲和力配体或与大量低亲和力配体结合时,其稳定性受到影响。差示扫描量热法(DSC)测量生物分子的热诱导结构转变释放或吸收的能量。本文介绍了分析与天然蛋白质结合的n-配体和与其未折叠形式结合的m-配体的蛋白质热谱图的一般理论进展。特别是,分析了低亲和力和高结合位点数(n和/或m>;50)的配体的影响。如果与蛋白质的天然形式的相互作用占主导地位,则它们被认为是稳定剂,如果与未折叠物种的结合占主导地位则预计会产生不稳定作用。这里提出的形式可以适用于拟合程序,以便同时获得蛋白质的展开能和配体结合能。氯化胍对牛血清白蛋白热稳定性的影响已成功分析,该模型考虑了低数量的与天然状态的中等亲和力结合位点和高数量的与未折叠状态的弱结合位点。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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