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The effect of structural modification of antimicrobial peptides on their antimicrobial activity, hemolytic activity, and plasma stability

Taoran Wang, Cunbin Zou, Wen Na, Xingdong Liu, Zhao Hui Meng, Siliang Feng, Zhibing Zheng, Qingbin Meng, Chenhong Wang

2021Journal of Peptide Science60 citationsDOI

Abstract

W, including altering the amino acid sequence, introducing cysteine and other typical amino acids, developing peptide dimers via disulfide bonds, and conjugating with mPEG, in order to enhance the antimicrobial activity, plasma stability, and reduce the hemolytic activity of peptides. The results showed that mPEG conjugation could significantly improve the plasma stability and reduce the hemolytic activity of peptides, while the antimicrobial activity decreased meanwhile. However, altering the sequence of the peptide without changing its amino acid composition had little impact on its antimicrobial activity and plasma stability. The introduction of cysteine enhanced the plasma stability of peptides conspicuously, but at the same time, the increased hydrophobicity of peptides increased their hemolysis. The antimicrobial mechanism and cytotoxicity of the peptides with relatively high antimicrobial activity were also studied. In general, this study provided some ideas for the rational design and structure optimization of antimicrobial peptides.

Topics & Concepts

AntimicrobialPeptideHemolysisChemistryAntimicrobial peptidesCysteineAmino acidBiochemistryPeptide sequenceCombinatorial chemistryBiologyEnzymeOrganic chemistryGeneImmunologyAntimicrobial Peptides and ActivitiesProtein Hydrolysis and Bioactive PeptidesImmunotherapy and Immune Responses
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