Osteoblastic differentiation and mRNA analysis of STRO-1-positive human bone marrow stromal cells using primary in vitro culture and poly (A) PCR.

Abstract

Investigation of osteoblast dysfunction in osteoporosis has been hampered by a poor understanding of normal early osteoblast differentiation, due to a relative lack of markers for the earliest cells in the lineage. Attempts to identify such markers have used cultures of animal or immortalized human cells, of uncertain relevance to human biology, or heterogeneous cultures in which genetic variability precludes the isolation of stage-specific genotypic markers. Primary in vitro generation of clonal populations of human bone marrow stromal cells was used in order to overcome these problems. Fibroblast-like stromal cells were isolated from human sternal bone marrow. They showed differentiation to an osteoblastic phenotype when stimulated with dexamethasone (10(-7) M) and fluorescence activated cell analysis demonstrated immunopositivity for STRO-1 (an antibody that recognizes osteoprogenitor stem cells of the colony-forming unit-fibroblastic) in from 8 to 40 per cent of the cells, dependent on time post-harvest. Cells positive for STRO-1 were immunoselected using magnetic activated cell sorting and seeded at low density (10 cells/cm2) to produce clones. Each clone was subpassaged, osteoblastic differentiation stimulated with dexamethasone, and mRMA-extracted at time points post-stimulation (0 h and 1-14 days). A novel poly (A) reverse transcriptase-polymerase chain reaction (RT-PCR) was used to amplify cDNA representative of all transcripts expressed at each time point. Differential gene expression within the amplified cDNA was assessed using 3' end cDNA probes to osteocalcin, osteopontin, and collagen type I (positive), demonstrating the acquisition of an osteoblastic phenotype. Time-specific gene products for early osteoblast differentiation have been generated from primary human cultures, utilizing very low density seeding and poly (A) RT-PCR. These products overcome the problems associated with animal, immortalized or heterogeneous culture and can be used to study normal and altered early osteoblast differentiation, indicating the possibility of using the same system to study other disease states.