Computational analysis of propeptide-containing proteins and prediction of their post-cleavage conformation changes.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-01 Epub Date: 2024-05-22 DOI:10.1002/prot.26702
Jimin Pei, Lisa N Kinch, Qian Cong
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Abstract

A propeptide is removed from a precursor protein to generate its active or mature form. Propeptides play essential roles in protein folding, transportation, and activation and are present in about 2.3% of reviewed proteins in the UniProt database. They are often found in secreted or membrane-bound proteins including proteolytic enzymes, hormones, and toxins. We identified a variety of globular and nonglobular Pfam domains in protein sequences designated as propeptides, some of which form intramolecular interactions with other domains in the mature proteins. Propeptide-containing enzymes mostly function as proteases, as they are depleted in other enzyme classes such as hydrolases acting on DNA and RNA, isomerases, and lyases. We applied AlphaFold to generate structural models for over 7000 proteins with propeptides having no less than 20 residues. Analysis of residue contacts in these models revealed conformational changes for over 300 proteins before and after the cleavage of the propeptide. Examples of conformation change occur in several classes of proteolytic enzymes in the families of subtilisins, trypsins, aspartyl proteases, and thermolysin-like metalloproteases. In most of the observed cases, cleavage of the propeptide releases the constraints imposed by the covalent bond between the propeptide and the mature protein, and cleavage enables stronger interactions between the propeptide and the mature protein. These findings suggest that post-cleavage propeptides could play critical roles in regulating the activity of mature proteins.

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含肽蛋白质的计算分析及其裂解后构象变化的预测。
前肽从前体蛋白质中去除,生成其活性或成熟形式。肽在蛋白质折叠、运输和活化过程中起着至关重要的作用,在 UniProt 数据库中约有 2.3% 的受检蛋白质含有肽。它们通常存在于分泌蛋白或膜结合蛋白中,包括蛋白水解酶、激素和毒素。我们在蛋白质序列中发现了各种球状和非球状的 Pfam 结构域,这些结构域被命名为前肽,其中一些与成熟蛋白质中的其他结构域形成分子内相互作用。由于其他酶类(如作用于 DNA 和 RNA 的水解酶、异构酶和裂解酶)中的含量较低,因此含有前肽的酶大多具有蛋白酶的功能。我们应用 AlphaFold 生成了 7000 多个蛋白质的结构模型,这些蛋白质中含有不少于 20 个残基的肽。对这些模型中残基接触的分析表明,有 300 多种蛋白质的构象在前肽裂解前后发生了变化。构象变化的例子出现在枯草蛋白酶、胰蛋白酶、天冬氨酰蛋白酶和类热溶解金属蛋白酶家族的几类蛋白水解酶中。在大多数观察到的情况下,前肽的裂解解除了前肽与成熟蛋白质之间共价键的限制,裂解使前肽与成熟蛋白质之间的相互作用更强。这些研究结果表明,裂解后的丙肽可能在调节成熟蛋白质的活性方面发挥关键作用。
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CiteScore
7.20
自引率
4.30%
发文量
567
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