Rational engineering of an antimalarial peptide with enhanced proteolytic stability and preserved parasite invasion inhibitory activity.

IF 4.2 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Abhisek Kar, Akash Narayan, Vishal Malik, Kalyaneswar Mandal
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Abstract

We describe rational chemical engineering to enhance the proteolytic stability of a chimeric peptide using a combination of unique strategies that involve the incorporation of a series of d-amino acids into the parent l-peptide sequence and restricting the conformational freedom of the peptide by covalent stitching. We hypothesize that replacing a stretch of sequence of an unstructured peptide motif with d-amino acids would increase its proteolytic stability without significantly affecting its affinity to the target protein. Also, considering the Cβ-Cβ distances, replacing an appropriate pair of residues with cysteine to form an additional disulfide bond in the molecule would provide additional stability to the engineered peptide. To verify this hypothesis, we have implemented these strategies to a previously reported peptidic inhibitor RR, against P. falciparum invasion into red blood cells (RBCs) and designed two novel heterochiral chimeric peptides, RR-I and RR-II. We have demonstrated that these peptides exhibit remarkable inhibitory activity with dramatically enhanced proteolytic stability. Finally, we have designed a cyclic analog, RR-III, to enhance the stability of the peptide against endopeptidases. The RR-III peptide exhibits the same inhibitory activity as RR-II while demonstrating impressive resistance to enzymatic degradation and prolonged stability in human plasma. These developments hold promise for a new generation of peptide-based therapeutics, showcasing the potential of residue selection for tailored modifications, as demonstrated in this work.

合理设计一种抗疟多肽,增强其蛋白水解稳定性并保持其抑制寄生虫入侵的活性。
我们介绍了如何通过合理的化学工程来提高嵌合肽的蛋白水解稳定性,该方法结合了一系列独特的策略,包括在母肽序列中加入一系列 d-氨基酸,以及通过共价拼接来限制肽的构象自由度。我们假设,用 d- 氨基酸取代一段非结构化多肽主题的序列,可以提高其蛋白水解稳定性,而不会显著影响其与目标蛋白质的亲和力。此外,考虑到 Cβ-Cβ 间距,用半胱氨酸取代适当的一对残基,在分子中形成额外的二硫键,也会增加工程肽的稳定性。为了验证这一假设,我们对以前报道过的一种抑制恶性疟原虫侵入红细胞(RBC)的多肽抑制剂 RR 实施了这些策略,并设计了两种新型异链嵌合多肽 RR-I 和 RR-II。我们已经证明,这些肽具有显著的抑制活性,而且蛋白水解稳定性大大提高。最后,我们设计了一种环状类似物 RR-III,以增强肽对内肽酶的稳定性。RR-III 肽具有与 RR-II 相同的抑制活性,同时表现出惊人的抗酶降解能力和在人体血浆中的长期稳定性。这些进展为新一代基于多肽的疗法带来了希望,展示了残基选择进行定制修饰的潜力,正如这项工作所证明的那样。
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
CiteScore
6.10
自引率
0.00%
发文量
128
审稿时长
10 weeks
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