Generation and Characterization of Human Embryonic Stem Cells-Derived Skeletal Muscle Progenitors

Abstract

The long-term treatment of injured, aging, or pathological skeletal muscle using stem cell therapy requires an abundant source of skeletal muscle progenitors (SMP) that are capable of self-replenishment. While adult SMPs—known as satellite cells and marked by PAX7 expression—can be collected from healthy donors, these satellite cells have limited replication potential once extracted, and may have difficulties providing sufficient numbers for therapy. Therefore, we sought to utilize the near-unlimited replication potential of human embryonic stem cells (hESC) to generate large quantities of SMPs in vitro. We developed a 50-day directed hESC differentiation that produced cultures with up to 90% myogenic identity; roughly 43 ± 4% become PAX7+ SMPs, and 47 ± 3% of cells become skeletal myocytes. We also performed gene expression profiling on our differentiating cultures to better understand in vitro skeletal myogenesis, and to better characterize in vitro hESC-derived SMPs, which remain poorly understood relative to adult satellite cells. 50-day cultures shared gene expression profiles more similar to quiescent rather than activated satellite cells, featuring a number of genes related to FOS/JUN, NOTCH, and TGFB-signaling. Day 50 cultures also expressed surface proteins known to mark adult or embryonic SMPs: CD82, CXCR4, ERBB3, NGFR, and PDGFRA. Transplanting 50-day cultures into cardiotoxin or BaCl2 injured immunodeficient murine muscle showed donor human cells persisted within the host muscle for 1 – 2 months post-injection; however, donor cells were confined to the interstitial space and did not contribute to host myofibers or the satellite cell niche. Together, these studies provide a tool for generating large quantities of embryonic skeletal muscle, and a gene expression resource that can provide insight into signaling factors that might improve or accelerate SMP development, or provide putative new surface receptors that may isolate embryonic SMPs better suited for in vivo transplantation.