Fuente: Biomolecules - Revista científica (MDPI) Biomolecules, Vol. 16, Pages 148: Bifunctional Peptides Generated by Optimising the Antimicrobial Activity of a Novel Trypsin-Inhibitory Peptide from Odorrana schmackeri
Biomolecules doi: 10.3390/biom16010148
Authors:
Ying Wang
Xinchuan Chai
Ying Zhang
Xueying Xing
Yangyang Jiang
Tao Wang
Xiaoling Chen
Lei Wang
Mei Zhou
James F. Burrows
Na Li
Xiaofei Zhang
Tianbao Chen

Drug-resistant bacteria cause millions of global infections each year, and the development of alternative antimicrobial drugs has become a serious undertaking. Currently, peptides with antimicrobial activity represent potential candidates for new antibiotic discovery as they are less likely to cause drug resistance in bacteria. In this study, bifunctional peptides with potent trypsin-inhibitory activity and antimicrobial activity were obtained by rational computation-based structural modifications to a novel Bowman–Birk-type inhibitor (BBI) peptide. The analogues not only displayed potent bacterial killing ability against two drug-resistant bacteria strains of E. coli but also an excellent safety profile, as assessed by low haemolytic activity and low anti-proliferation activity on HaCaT cells. Throughout the molecular dynamics simulations, the peptides exhibited stable adsorption onto the mixed POPE/POPG membrane; most amino acid residues of the AMPs remained bound to the membrane surface, with a few amino acid residues partially penetrating the membrane interior. This showed that the electrostatic interactions were the dominant driving force mediating the peptide–membrane associations. In addition, the tested peptides displayed a degree of stability in the presence of salt ions, serum, and trypsin. These modified peptides thus possess potential as clinical antibacterial agents, and the strategies used in structural modification may also provide a different path to developing new antimicrobial peptides.