Abstract
Bone formation proceeds through two distinct processes. One involves the deposition of bone by osteoblasts (intramembranous ossification) and another through the remodeling of an intermediate cartilaginous matrix formed by chondrogenic differentiation of mesenchymal stem/stromal cells (MSCs) aggregates – a process called endochondral ossification (EO). EO is responsible for formation of long bones during development and most prevalent during facture repair upon callus formation. In adult bone injuries MSCs from periosteum form bone via EO whereas MSCs from bone marrow are primarily differentiate to osteoblast in vivo. We hypothesized that the unique biophysical and biochemical properties of bone mineral phase has a role in programming MSCs. Using a biomimetic bone like apatite (BBHAp) as surrogate for bone mineral phase, we studied the chondrogenic differentiation of human marrow derived MSCs and observed that the BBHAp dictates MSCs fate and strictly dictates the pathway of bone formation in vivo. Through exhaustive dissection of the signaling pathways at play, a prominent role of PTH1R in modulating the effects imposed by the BBHAp has been unraveled. These fundamental insights gained in how bone microenvironment might alter fate of MSCs has important implications for bone repair and regeneration therapies.
