Abstract
Osteoarthritis is characterised by the loss and damage of cartilage in synovial joints. Whilst joint replacement is the gold standard for end stage disease, repair or regenerative strategies aim to slow disease progression, maintain joint function and defer the need for joint replacement. One approach seeks to target endogenous repair after drilling or microfracture (a type of trauma induced repair) in the area of cartilage loss – connecting the defect to the underlying bone marrow niche. The rationale of this approach is that cells delivered to the defect site, from the bone marrow, will bring about cartilage repair.
Bone marrow contains multipotent cells, including stem and stromal populations, of both the haematopoietic and skeletal systems. Bone marrow mesenchymal stromal cells (BMSCs) are characterised by tri-lineage differentiation (bone, cartilage and adipose tissue) and contribute to the formation of the bone marrow niche, which maintains haematopoietic stem cell quiescence. This quiescence ensures life-long haematopoiesis and the supply of mature blood cells to the haematopoietic system. In this study we investigate the interactions between haematopoietic and BMSCs (in both human and mouse cultures) specifically to understand the consequences on BMSCs during tissue repair.
A murine MSC cell-line model was co-cultured with enriched fractions of primary murine haematopoietic progenitor cells isolated based on c-Kit, Sca-1, and lineage markers. Similarly, human bone marrow derived MSCs were co-cultured with primary bone marrow haematopoietic fractions isolated based on CD34, CD38 and lineage markers. Using confocal microscopy, we demonstrated that the two cell populations directly interact through cell-cell contact with haematopoietic cells located above and below the MSC monolayer. Cultures were then pushed to differentiate down the osteogenic lineage. Results indicate that MSCs co-cultured with haematopoietic cells exhibited significant inhibition of osteogenesis when analysed by functional assay of matrix mineralisation and gene expression analysis for transcripts including Runx2, Osterix and type I collagen.
These data support the hypothesis that hematopoietic progenitor cells influence both the local homeostasis of the bone marrow as well as the repair potential of stromal cells. Such interactions could be important for the resolution of injury after trauma induced repair. Furthermore, manipulation of these interactions, such as the administration of haematopoietic cell stimulating agents, could be used to improve treatment outcomes.
