Abstract
Diabetes mellitus is associated with a high risk of hindlimb ischemia (HLI) progression and an inevitably poor prognosis, including worse limb salvage and mortality. Skeletal muscle cells can secrete angiogenic factors, which could promote neovascularization and blood perfusion recovery. Thus, paracrine function of skeletal muscle cells, which is aberrant in diabetic conditions, is crucial for therapeutic angiogenesis in diabetic HLI. Dapagliflozin is a well-known anti-hyperglycemia and anti-obesity drug; however, its role in therapeutic angiogenesis is unknown. Herein, we found that dapagliflozin could act as an angiogenesis stimulator in diabetic HLI. We showed that dapagliflozin enhances the viability, proliferation, and migration potentials of skeletal muscle cells and promotes the secretion of multiple angiogenic factors from skeletal muscle cells, most plausibly through PHD2/HIF-1α axis. Furthermore, we demonstrated that conditioned medium from dapagliflozin-treated skeletal muscle cells enhances the proliferation and migration potentials of vascular endothelial and smooth muscle cells, which are two fundamental cells of functional mature vessels. Finally, an in vivo study demonstrated that intramuscular administration of dapagliflozin effectively enhances the formation of mature blood vessels and, subsequently, blood perfusion recovery in diabetic HLI mice. Hence, our results suggest a novel function of dapagliflozin as a potential therapeutic angiogenesis agent for diabetic HLI.
Highlights
In 2014, diabetes mellitus was affecting more than 400 million adults worldwide
First we investigated whether dapagliflozin could increase skeletal muscle cells’ viability and proliferation potentials under hyperglycemia
To investigate the molecular mechanism of dapagliflozin regulation on the expression levels of angiogenic factors in the skeletal muscle cells, we investigated the effect of dapagliflozin treatment on the expression level of hypoxia-inducible factor-1a (HIF-1a), a key regulator of the angiogenic process which could activate the transcription of numerous factors, including VEGF-A and PDGF-BB (Kelly et al, 2003)
Summary
In 2014, diabetes mellitus was affecting more than 400 million adults worldwide. more than 640 million adults are predicted to have diabetes in 2040, as the trend keeps increasing (Wiviott et al, 2019b). HLI is indicated by the obstruction of the lower limb arteries, causing ischemic conditions in the lower limbs, which could lead to tissue damage, necrosis, amputation, and even mortality (Annex, 2013) Standard revascularization approaches, such as bypass surgery and vascular stents, which are effective in the majority of non-diabetic HLI patients, are largely inappropriate for diabetic HLI patients due to larger wound surface areas and higher rates of relapse compared to those of non-diabetic patients (Jude et al, 2010; Hoffstad et al, 2015; Ariyanti et al, 2017). Therapeutic angiogenesis aims to stimulate neovessel formation and blood perfusion in order to alleviate hypoxic damages (Deveza et al, 2012; Annex, 2013) It is regarded as an effective strategy for HLI disease, especially for nonrevascularizable patients. Hyperglycemia disrupts the internal angiogenic potential, creating a larger obstacle in applying therapeutic angiogenesis for diabetic HLI patients (Howangyin and Silvestre, 2014)
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