Spinach protein-capped silver nanoparticles with low hemolytic activity inhibit methicillin-resistant Staphylococcus aureus biofilm formation as a new therapeutic approach

Abstract

BackgroundThe methicillin-resistant Staphylococcus aureus (MRSA) was designated as a high-priority pathogen by the World Health Organization. Cardiovascular and thoracic surgery complications frequently involve MRSA infection. Treatment of newly emerging resistant S. aureus strains is clinically challenging due to the natural tendency of MRSA survival through biofilm formation. The failure of traditional antibiotic therapy necessitates development of next-generation therapeutic molecules. ObjectivesSilver nanoparticles were investigated to treat MRSA in order to overcome the challenges of antibiotic therapy. MethodsSpinach protein functionalized silver nanoparticles (SPAgNPs) were synthesized by reducing with sodium borohydride. The resazurin microtiter assay was used to determine the minimum inhibitory concentration (MIC) of SPAgNPs against MRSA. The antibiofilm activity was investigated using a crystal violet assay at sub-MIC levels and validated using scanning electron microscopy. To demonstrate the mechanism of action of SPAgNPs, the virulence factors involved in MRSA biofilm formation were examined. SEM was used to evaluate the hemocompatibility of human red blood cells. Results and conclusionThe synthesized SPAgNPs showed characteristic yellow colour with surface Plasmon resonance maximum at 418 nm. Powder X-ray diffraction and transmission electron microscopy analysis confirmed that the particles are crystalline with a size range from 14 to 40 nm. SPAgNPs have antibacterial activity at a minimum inhibitory concentration (MIC) of 1.25 mM, killing MRSA via disrupting membrane integrity and producing excess reactive oxygen species. Strikingly, SPAgNPs inhibit MRSA biofilm formation at sub-MIC (0.625 mM). Scanning electron microscopy study reveals that SPAgNPs trigger biofilm inhibition without causing cell damage. Hence the NPs are very effective in preventing pathogens from triggering stress responses. SPAgNPs suppress exopolysaccharide production, cell surface hydrophobicity, and staphyloxanthin biosynthesis. Testing SPAgNPs against human red blood cells reveals that NPs do not harm human cells, suggesting that the SPAgNPs are biocompatible. The findings show that SPAgNPs could be explored as next-generation materials for treating MDR pathogenic infection linked with biofilms.