Human skeletal stem cells that become bone, cartilage, or stroma cells have been isolated from fetal and adult bones. This is the first time that skeletal stem cells, which had been observed in rodent models, have been identified in humans. The researchers were also able to derive the skeletal stem cells from human induced pluripotent stem cells, opening up new therapeutic possibilities.
"Given the tremendous medical burden imposed by degenerative, neoplastic, post-traumatic, and post-surgical skeletal disorders, we believe that identifying this human skeletal stem cell and elucidating its lineage map will enable the molecular diagnosis and treatment of skeletal diseases," says Michael Longaker, Stanford University School of Medicine.
Skeletal tissues such as bone possess exceptional regenerative potential. Bone defects heal readily, and some vertebrates can regenerate entire portions of their limbs. But the regenerative capacities of skeletal tissues in other vertebrates are more restricted. For example, bones in mice and humans can recover from small- to moderate-sized defects, but adult cartilage tissues possess little to no regenerative ability. In addition, both mice and humans display severe age-related degeneration of skeletal tissues over time.
Skeletal dysfunction can lead to a broad spectrum of health conditions ranging from age-related diseases such as osteoporosis and osteoarthritis to non-healing skeletal injury, blood disorders, and even cancer. Despite its significant impact on health and disease, treatment options aimed at improving skeletal function are currently limited. One major hurdle is that stem cell regulation in the human skeletal system remains largely unexplored.
In the new study, Longaker and his collaborators addressed this gap in knowledge by identifying and characterizing human skeletal stem cells and downstream bone and cartilage progeny in a variety of tissues. These self-renewing and multipotent cells were present in both fetal and adult human bone marrow tissues and could be derived from induced pluripotent stem cells (iPSCs). By defining the relationships between human skeletal stem cells and downstream skeletal progenitors, the researchers created a detailed lineage map of stem-cell-mediated formation of skeletal tissues in humans.
Moreover, transcriptomic and epigenetic comparisons with mouse skeletal stem cells revealed evolutionarily conserved pathways regulating the stem-cell-mediated formation of skeletal tissues, as well as divergent molecular pathways that may regulate species-specific differences in bone development and skeletal structure.
"By comparing the molecular and functional differences in specific types of stem cells between different species of vertebrates, it may be possible to uncover convergent and divergent mechanisms that underlie tissue growth and regeneration and apply this understanding towards enhancing health and rejuvenation in humans," says Charles Chan, Stanford University School of Medicine.
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