Changes of bone marrow stromal cells (MSC) in mice after drug induced eradication of hematopoietic cells: in vitro effects on normal bone marrow.

This study deals with murine marrow stromal cells (MSC) during hematopoietic regeneration. Regenerative marrow was induced in infant mice by two consecutive i. p. injections of hydroxyurea (HU) (2 X 1,000 mg/kg) which kill most cells in DNA synthesis. Two days later the marrow becomes enriched in pluripotent stem cells (CFU-S) and committed progenitors. It was found that fibroblastoid colony-forming-units (CFU-F) become concentrated approximately four fold above controls and give rise to significantly larger fibroblastoid colonies than CFU-F in control marrow. In split-phase semisolid agar cultures, i. e. adherent cells of HU-treated marrow (in under layers) and normal bone marrow cells (in upper layers), inhibition of G/M colonies in the upper layer in observed. In control split-phase cultures of both under layers and upper layers of normal bone marrow, CFU-C inhibition is by far less pronounced. In liquid cultures, pre-established adherent layers of HU-treated marrow have a stimulatory effect on normal marrow CFU-C. It is concluded that during increased demand for pluripotent stem cells and progenitors, such as after HU administration, marrow stromal cells and possibly other adherent cells produce inhibitory factor(s) of CFU-C differentiation. The inhibitory activity possibly is an effective mechanism for stem cell pool preservation. The differing effect of adherent cells of HU-treated marrow on CFU-C in liquid and in semi-solid medium suggests production of two different factors with opposing influences on CFU-C, depending upon the culture conditions.