Inhibition of microRNA-181c-5p rescues diabetes-impaired angiogenesis through activation of key mediators of angiogenesis, cell survival and novel genes, elmo3 and trib1

Abstract Introduction Patients with diabetes have impaired angiogenesis and poor coronary collateral vessel formation post-myocardial infarction (MI), which associates with higher mortality. There is a significant unmet clinical need for new agents that stimulate angiogenesis in response to ischaemia in diabetes. We have identified that miR-181c-5p has anti-angiogenic properties, but it’s role in diabetes remains unknown. Aim To elucidate the role of miR-181c-5p in diabetes-impaired angiogenesis. Methods Human coronary artery endothelial cells were transfected with a miR-181c-5p inhibitor (antimiR-181c-5p) or negative control (antimiR-Neg), exposed to glucose (5–25mM, 48h) then underwent Matrigel tubulogenesis assay or Boyden Chamber migration assay. Levels of proteins important for angiogenesis (e.g., VEGFA, p-ERK2, p-eNOS) were determined by Western Blot. Whole transcriptome sequencing was performed in vitro to identify novel gene targets of miR-181c-5p. In vivo, diabetic mice underwent hindlimb ischaemia or wound healing surgery and were injected with antimiR-181c-5p or antimiR-Neg. Tissues were extracted early (day 3) and late (days 10-14) post-surgery. Hindlimb blood-flow reperfusion was measured by Laser Doppler imaging. Hindlimb apoptosis was assessed by TUNEL and necrotic area was assessed by H&E. Wound area was calculated daily. Neovascularisation was assessed by CD31 (capillaries) and α-actin (arterioles) immunostaining. Results Inhibition of miR-181c-5p increased endothelial tubule number (+28%, P<0.01), tubule length (+12%, P<0.01) and cell migration (+67%, P<0.05). This associated with increased VEGFA (+21%, P<0.05) and p-ERK2 (+32%, P<0.05). Whole transcriptome and pathway analysis revealed changes to angiogenesis pathways and identified a first-time involvement of genes Elmo3 and Trib1 in the pro-angiogenic action of antimiR-181c-5p in diabetes. In vivo, inhibition of miR-181c-5p increased blood flow reperfusion to ischaemic hindlimbs (+30%, P<0.001) and arteriolar density (+45%, P<0.05) in diabetic mice. Mechanistically, this was associated with early changes to mediators of angiogenesis, Erk2 mRNA (+35%, P<0.05), p-ERK2 (+35%, P<0.05) and Trib1 mRNA (+80%, P<0.05); cell survival, Bcl-2 mRNA (+44%, P<0.05); and late apoptotic clearance, Elmo3 mRNA (+57%, P<0.001). Furthermore, this was also associated with an increase in late stage hindlimb apoptosis (+94%, P<0.05) and reduced necrotic area (-90%, P<0.05) in diabetic mice. Inhibition of miR-181c-5p increased diabetic wound closure (+22%, P<0.01), wound capillaries (+61%, P<0.05), Bcl-2 mRNA (+52%, P<0.05) and Elmo3 mRNA (+50%, P<0.05) in diabetic wounds. Conclusions Inhibition of miR-181c-5p rescues diabetes-impaired angiogenesis by activation of angiogenesis and cell survival mediators, and through novel genes, Trib1 and Elmo3. Our findings have implications for a novel miRNA-based strategy that improves myocardial neovascularisation and the prognosis of diabetic patients post-MI.