RESUMEN
OBJECTIVE: This study focuses on dose-response investigation using a codon-optimized and de novo -synthesized E-Selectin/AAV2 (E-Sel/AAV2) vector in preparation for Investigational New Drug (IND)-enabling of subsequent clinical studies. BACKGROUND: Gene therapy is a potential solution for patients suffering from chronic limb-threatening ischemia (CLTI). Understanding the dose for effective gene delivery is crucial for future IND-enabling studies. METHODS: Expression of the codon-optimized E-Selectin gene was assessed by flow cytometry following in vitro cell transfection assay and RT-qPCR for murine limbs injected in vivo with AAV-m-E-Selectin (E-Sel/AAV2). Dose-response studies involved three cohorts of FVB/NJ mice (n=6/group) with escalating log doses of E-Selectin/AAV2 injected intramuscularly (IM) in divided aliquots, ranging from 2×10 9 VG to 2×10 11 VG, into ischemic limbs created by left femoral artery/vein ligation/excision and administration of nitric oxide synthase inhibitor, L-NAME. Limb perfusion, extent of gangrene free limb, functional limb recovery and therapeutic angiogenesis were assessed. RESULTS: Codon-optimized E-Sel/AAV2 gene therapy exhibits superior expression level than WT E-Sel/AAV2 gene therapy both in vitro and in vivo . Mice treated with a high dose (2×10 11 VG) of E-Sel/AAV2 showed significantly improved perfusion indices, lower Faber's scores, increased running stamina and neovascularization compared with lower doses tested with control groups, indicating a distinct dose-dependent response. No toxicity was detected in any of the animal groups studied. CONCLUSION: E-Sel/AAV2 Vascular Regeneration Gene Therapy (VRGT) holds promise for enhancing the recovery of ischemic hindlimb perfusion and function, with the effective dose identified in this study as 2×10 11 VG aliquots injected IM.
RESUMEN
Fibroblasts are stromal cells ubiquitously distributed in the body of nearly every organ tissue. These cells were previously considered to be "passive cells", solely responsible for ensuring the turnover of the extracellular matrix (ECM). However, their versatility, including their ability to switch phenotypes in response to tissue injury and dynamic activity in the maintenance of tissue specific homeostasis and integrity have been recently revealed by the innovation of technological tools such as genetically modified mouse models and single cell analysis. These highly plastic and heterogeneous cells equipped with multifaceted functions including the regulation of angiogenesis, inflammation as well as their innate stemness characteristics, play a central role in the delicately regulated process of wound healing. Fibroblast dysregulation underlies many chronic conditions, including cardiovascular diseases, cancer, inflammatory diseases, and diabetes mellitus (DM), which represent the current major causes of morbidity and mortality worldwide. Diabetic foot ulcer (DFU), one of the most severe complications of DM affects 40 to 60 million people. Chronic non-healing DFU wounds expose patients to substantial sequelae including infections, gangrene, amputation, and death. A complete understanding of the pathophysiology of DFU and targeting pathways involved in the dysregulation of fibroblasts are required for the development of innovative new therapeutic treatments, critically needed for these patients.