Multifunctional activities of KSLW synthetic antimicrobial decapeptide: Implications for wound healing.

摘要

Wound healing is a complex process leading to the maintenance of skin integrity. Stress is known to increase susceptibility to bacterial infection, alter proinflammatory cytokine expression, and delay wound closure. Recently, antimicrobial peptides have generated interest due to their prokaryotic selectivity, decreased microbial resistance and multifunctional roles in wound healing, including fibroblast stimulation, keratinocyte migration and leukocyte migration. The objective of this dissertation project was to evaluate the effect of a synthetic antimicrobial decapeptide (KSLW) on bacterial clearance inflammation, and wound closure during stress-impaired healing.;SKH-1 mice were randomly assigned to either control or restraint-stressed (RST) groups. Punch biopsy wounds (3.5 mm in diameter) were created bilaterally on the dorsal skin. Wounds were injected with 50 microL of empty carriers or KSLW prepared in Pluronic-F68, phospholipid micelles, or saline. Bacterial assays of harvested wounds were conducted on BHI agar. Wound closure was determined by photoplanimetry. Cytokine and growth factor mRNA expression was assessed with real-time RT-PCR. Human neutrophil migration assays and checkerboard analyses were performed using Transweli plates, and counting on hemacytometer. Oxidative burst activity was measured by spectrophotometric analysis of 2,7-dichlorofluorescein oxidation.;KSLW-treatment resulted in significant reductions in bacterial load among RST mice, with no difference from control after 24h. The effect was sustained 5 days post- wounding, in RST mice treated with KSLW-F68. Temporal analysis of gene induction revealed reversals of stress-induced altered expression of growth factors, proinflammatory cytokines, and chemokines essential for favorable wound healing, at various time points. KSLW-treatment in RST mice demonstrated faster wound closure throughout the stress period. KSLW, at micromolar concentrations, demonstrated a significant effect on neutrophil migration and oxidative burst.;These data suggest KSLW enhances bacterial clearance and promotes proinflammatory activity during early wound healing in stressed mice. Peptide delivery in Pluronic-F68 demonstrated increased substantivity, with faster wound closure, compared to other delivery systems. In addition to its antimicrobial activity, KSLW was shown to enhance neutrophil chemotaxis and sustain cell viability by inhibition of oxidative burst responses. Taken together, the cationic peptide may be implicated in the management of infection in different systems demonstrating impaired healing, including diabetes, age, hormone-imbalance, and bum models.