Induced Pluripotent Stem Cell-Derived Mesenchymal Stromal Cells Promote Muscle Regeneration in a Diabetic Mouse Model of Critical Limb Threatening Ischemia

Abstract

Critical limb threatening ischemia (CLTI), the end stage of peripheral arterial disease (PAD), is diagnosed in 500,000 patients each year, often results in amputation, and has a ~50% 5-year mortality rate. Diabetic CLTI patients experience especially high morbidity and mortality, and no effective non-surgical therapy exists for this population. Our Phase II MOBILE trial demonstrated that autologous bone marrow nucleated cells were unable to prevent amputations in diabetic patients; however, data from a Phase I trial shows that allogeneic bone marrow-derived mesenchymal stromal cells (BMD-MSC) stimulated angiogenesis in ischemic muscle, including diabetics. While allogeneic MSC may be an effective cell preparation to treat diabetic CLTI, passaging-related cell senescence prevents generation of sufficient cell numbers for therapeutic use. The development of induced pluripotent stem cell (iPSC)-derived MSC overcomes cell senescence issues and offers the possibility of genetic modifications to enhance cell function. The current study was designed to determine potential mechanisms by which iPSC-MSC stimulate muscle regeneration in a rodent CLTI model. The CLTI mouse model was created by ligation/excision of the femoral artery in male polygenic diabetic TallyHo mice. Mice with intramuscular administration of iPSC-MSC displayed positive indicators of muscle regeneration compared to vehicle control mice. Real-time PCR performed with gastrocnemius muscle obtained 7- or 30-days post iPSC-MSC injection showed an increase in mRNA expression for MyH3, MyoD1, Mrc1, FoxP3, and VEGF-A vs. vehicle treated muscle, indicating promotion of muscle regeneration, M2-biased macrophage expression, T regulatory cell (Treg) expansion, and vascular proliferation. Downregulation of the NADPHoxidase subunit p47phox indicated a decrease in oxidative stress in the treated mice. The results are consistent with iPSC-MSC  promotion of muscle regeneration via a Treg mediated stimulation of the M1-M2 macrophage phenotypic shift. Thus, human iPSC-MSC could be an effective treatment to stimulate muscle regeneration and ameliorate CLTI in diabetic patients.