Clinical and histomorphometric studies have shown that aging is associated with decreased bone mass and bone formation potential. However, the cellular and molecular mechanisms underlying the decreased bone formation potential are under explored. In the marrow, stromal osteoblasts and adipocytes share a common precursor, bone marrow mesenchymal stem cells. It is well known the volume of marrow adipocyte increases with a decreased bone forming potential in the elder marrow. This phenomenon may be resulted from a comparatively favor of adipogenesis and diminished ability of osteoblastogenesis in the elder’s BM-MSCs. Therefore, it is reasonable to assume the equilibrium of osteogenic and adipogeneic potential in marrow may be shifted by the aging of MSCs. However, the molecular basis of the equilibrium shift is unclear. To examine the equilibrium in the aged BM-MSC, we compared the osteogenic and adipogenic differentiation potentials of BM-MSCs isolated from healthy young (age 20-40, n =4) and elder (age 60-80, n = 4) marrows. The osteogenic potential is obviously higher in BM-MSC of young donors than the elder ones. This phenomenon was demonstrated by the Von Kossa’s Staining and calcium precipitate quantitation in the culture . To identify the transcriptional changes of the osteoclast formation genes, semi-quantitative RT-PCR were performed, and increased expression of hepatocyte growth factor (HGF) mRNA were found in the elder donors. Keeping in line with the upregulation of HGF gene in the elder BM-MSC, HGF have been known as a major factor controlling both migration and proliferation of osteoclasts at the sites of bone resorption. Furthermore , by using Human Cytokine Antibody Array analysis, we found IL-6 and MCP-1 were increased in the aged donors. These osteotropic factors that induce osteoclast formation act indirectly by binding marrow stromal cells, which in turn induce upregulation of RANK ligand expression.