Aims: This study aims to investigate the function of positive feedback loops involving noncoding RNA in diabetic wound healing. Methods: We developed a mouse diabetic wound model to confirm that hyperglycemia can impair wound healing. We also used an in vitro keratinocyte model in high-glucose conditions to investigate the mechanism of delayed wound healing. Results: MALAT1 was decreased in diabetic mouse wound tissue and can promote keratinocyte biological functions. MALAT1 could bind to miR-106a-5p to modulate the expression of ZNF148, a target gene of miR-106a-5p. Surprisingly, ZNF148 bound to a region in the MALAT1 promoter to stimulate gene expression. Conclusion: ZNF148-activated MALAT1 increases ZNF148 expression by competitively binding miR-106a-3p, generating a positive feedback loop that enhances keratinocyte function.
Keywords: MALAT1; ZNF148; diabetic wound healing; feedback loop; miR-106a-5p.
Delayed wound repair is a leading cause of diabetic foot ulcers. However, the molecular mechanism underlying impaired wound healing in diabetes is unclear. In our study we found that a positive feedback loop consisting of MALAT1, miR-106a-5p and ZNF148 could promote chronic wound repair. In diabetic skin tissues, MALAT1 levels were lower, causing impairments in skin cell function. On a molecular level, MALAT1 can bind miR-106a-5p to increase ZNF148 levels. Surprisingly, ZNF148 can bind the promoter of MALAT1 to reverse the decline of MALAT1 levels in diabetic wounds. Our findings advance our understanding of chronic diabetic wounds and, more crucially, open new therapeutic possibilities for this disease.