Chickpea-Derived Modified Antimicrobial Peptides KTA and KTR Inactivate Staphylococcus aureus via Disrupting Cell Membrane and Interfering with Peptidoglycan Synthesis.
Xinhui ZhangPeipei MaBalarabe B IsmailZhehao YangZhipeng ZouYujuan SuoXingqian YeDonghong LiuMingming GuoPublished in: Journal of agricultural and food chemistry (2024)
The widespread bacterial contamination caused by foodborne pathogens has continuously driven the development of advanced and potent food antimicrobial agents. In this study, two novel antimicrobial peptides (AMPs) named KTA and KTR were obtained by modifying a natural AMP, Leg2, from chickpea storage protein legumin hydrolysates. They were further predicted to be stable hydrophobic cationic AMPs of α-helical structure with no hemolytic toxicity by several online servers. Moreover, the AMPs exerted superior antibacterial activity against two representative Staphylococcus aureus strains thanks to the increased hydrophobicity and positive charge, with minimum inhibition concentration value (4.74-7.41 μM) significantly lower than that of Leg2 (>1158.70 μM). Further, this study sought to elucidate the specific antimicrobial mechanism against Gram-positive bacteria. It was found that the electrostatic interactions of the AMPs with peptidoglycan were vital for peptide activity in combating Gram-positive bacteria. Subsequently, the cell membrane of S. aureus cells was irreversibly disrupted by increasing permeability and impairing membrane components, which led to the massive release of intracellular substances and eventual cell death. Overall, this work demonstrated that KTA and KTR were active against Gram-positive bacteria via peptidoglycan targeting and membrane-disruptive mechanisms and paved the way for expanding their application potential to alleviate food contamination.
Keyphrases
- staphylococcus aureus
- gram negative
- cell death
- human health
- risk assessment
- escherichia coli
- cell cycle arrest
- biofilm formation
- induced apoptosis
- multidrug resistant
- healthcare
- oxidative stress
- cell wall
- social media
- bacillus subtilis
- cystic fibrosis
- ionic liquid
- reactive oxygen species
- small molecule
- pseudomonas aeruginosa
- functional connectivity
- protein protein
- candida albicans
- amino acid