Computational re-engineering of Amylin sequence with reduced amyloidogenic potential

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology
Mohamed R Smaoui, Jérôme Waldispühl
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引用次数: 1

Abstract

The aggregation of amyloid proteins into fibrils is associated with neurodegenerative diseases such as Alzheimer’s and Type II Diabetes. Different methods have explored ways to impede and inhibit amyloid aggregation. Most attempts in the literature involve applying stress to the environment around amyloids. Varying pH levels, modifying temperature, applying pressure through protein crowding and ligand docking are classical examples of these methods. However, environmental stress usually affects molecular pathways and protein functions in the cell and is challenging to construct in vivo. In this paper, we explore destabilizing amyloid proteins through the manipulation of genetic code to create beneficial substitute molecules for patients with certain deficiencies.

To unravel sequence mutations that destabilize amyloid fibrils yet simultaneously conserve native fold, we analyze the structural landscape of amyloid proteins and search for potential areas that could be exploited to weaken aggregation. Our tool, FibrilMutant, analyzes these regions and studies the effect of amino acid point mutations on nucleation and aggregation. This multiple objective approach impedes aggregation without stressing the cellular environment. We identified six main regions in amyloid proteins that contribute to structural stability and generated amino acid mutations to destabilize those regions. Full length fibrils were built from the mutated amyloid monomers and a dipolar-solvent model capturing the effect of dipole-dipole interactions between water and very large molecular systems to assess their aqueous stability was used to generate energy plots.

Our results are in agreement with experimental studies and suggest novel targeted single point mutations in the Amylin protein, potentially creating a better therapeutic agent than the currently administered Pramlintide drug for diabetes patients.

Abstract Image

降低淀粉样蛋白生成潜能的胰淀素序列的计算重组
淀粉样蛋白聚集成原纤维与神经退行性疾病,如阿尔茨海默氏症和II型糖尿病有关。不同的方法已经探索了阻碍和抑制淀粉样蛋白聚集的方法。文献中的大多数尝试都涉及对淀粉样蛋白周围的环境施加压力。改变pH值,改变温度,通过蛋白质拥挤和配体对接施加压力是这些方法的经典例子。然而,环境应激通常会影响细胞内的分子途径和蛋白质功能,并且在体内构建具有挑战性。在本文中,我们通过操纵遗传密码来探索不稳定的淀粉样蛋白,为某些缺陷的患者创造有益的替代分子。为了揭示破坏淀粉样蛋白原纤维稳定的序列突变,同时保存天然折叠,我们分析了淀粉样蛋白的结构景观,并寻找可能被利用来削弱聚集的潜在区域。我们的工具FibrilMutant分析了这些区域,并研究了氨基酸点突变对成核和聚集的影响。这种多目标方法在不增加细胞环境压力的情况下阻碍了聚合。我们确定了淀粉样蛋白中有助于结构稳定性的六个主要区域,并产生了氨基酸突变来破坏这些区域的稳定。利用突变的淀粉样蛋白单体构建了全长原纤维,并利用捕获水和超大分子体系之间的偶极-偶极相互作用效应的偶极-溶剂模型来评估其水稳定性,从而生成能量图。我们的结果与实验研究一致,并提出了新的靶向Amylin蛋白单点突变,有可能创造出比目前给药的Pramlintide更好的治疗糖尿病患者的药物。
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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来源期刊
BMC Structural Biology
BMC Structural Biology 生物-生物物理
CiteScore
3.60
自引率
0.00%
发文量
0
期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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