DOI: 10.1128/spectrum.04219-25 ISSN: 2165-0497

Arginine-substituted Mastoparan-C derivatives combat dual bacterial pathogens: in vitro mechanistic insights and in vivo efficacy in polymicrobial wounds

Luyao Zhang, Anqi Huang, Mingyu Lu, Jingjing Wang, Yingyu Wang, Fei Mo, Mingchun Liu

ABSTRACT

The synergistic interactions in multi-pathogen infections compromise wound healing and limit therapeutic efficacy. In this study, we designed and synthesized arginine-substituted derivatives of the antimicrobial peptide Mastoparan-C (MP-C). Among them, Arg²MP-C and Arg 4.11.12 MP-C exhibited potent, broad-spectrum activity against both Escherichia coli and Staphylococcus aureus . Their enhanced antibacterial activity is associated with increased positive charge and optimized hydrophobicity. Mechanistically, both peptides employ a dual-target strategy, disrupting bacterial membranes and binding genomic DNA; Arg²MP-C acted most rapidly against the E. coli envelope, while Arg 4.11.12 MP-C caused the strongest membrane damage to S. aureus . In a murine polymicrobial wound model, Arg²MP-C treatment nearly achieved complete wound closure by day 10, significantly reduced bacterial loads, and promoted tissue regeneration. This study demonstrates that arginine engineering can yield peptides with potent, multi-mechanistic action, identifying Arg²MP-C as a promising candidate for combating polymicrobial wound infections.

IMPORTANCE

Wounds infected with multiple bacterial species are notoriously difficult to treat, often leading to poor healing and limited effectiveness of existing therapies. In this study, we developed new antimicrobial peptides by introducing arginine substitutions into a natural peptide called Mastoparan-C. Two of our engineered peptides, Arg²MP-C and Arg 4.11.12 MP-C, showed potent activity against two common wound pathogens, Escherichia coli and Staphylococcus aureus . These peptides work through a dual mechanism: disrupting bacterial membranes and binding to bacterial DNA. In a mouse model of mixed-infection wounds, treatment with Arg²MP-C led to nearly complete wound closure by day 10, drastically reduced bacterial counts, and promoted tissue repair. Our findings highlight arginine engineering as a promising strategy to create next‑generation antimicrobial agents that can effectively combat complex polymicrobial wound infections, addressing a critical unmet need in clinical wound care.

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