Stromal cells selectively reduce the growth advantage of human committed CD34+ hematopoietic cells ectopically expressing HOXB4.

Key players in self-renewal of hemopoietic stem cells are homeobox (HOX) transcription factors. In murine cells, overexpression of HOXB4 results in expansion of hematopoietic stem- and committed progenitor cells in vitro without obvious hematopoietic alterations. In vivo, HOXB4 induced HSC expansion continued until stem cell regeneration reached pretransplantation levels. HOXB4 is thus an attractive candidate for amplification of stem cells provided that human HOXB4 overexpressing cells can also be restricted to normal growth in vivo. The stromal microenvironment provides the regulatory mechanisms controlling the balance of stem cell self-renewal and differentiation. Here, we compared the response of HOXB4- and GFP-control vector transduced human CD34(+) cells to stroma encoded signals in vitro. In serum-sustained cocultures MS-5 stroma contact reduced the output of late CD34- HOXB4(+) cells in relation to GFP-controls 9-fold whereas the expansion of early CD34(+)HOXB4(+) cells remained unchanged as compared to liquid cultures. In presence of insulin HOXB4 overexpressing cells do not react to stroma encoded growth-restricting signals. Our results show that ectopic expression of HOXB4 in combination with MS-5 stroma exerts different effects in early and late human cord blood CD34(+) cells resulting in an enhanced proliferation of early CD34(+) cells in absence or presence of MS-5 stroma and an impaired output of late committed CD34(+) cells on MS-5 stroma.

Involvement of CSF-1 in generating a stroma-independent hematopoietic stem cell line.

The hematopoietic stem cell line, Myl-D7, is maintained by a self-renewing stem cell population that spontaneously generates myeloid, lymphoid, and erythroid progeny. MS-5 stromal cells are necessary for the growth of Myl-D7 cells. One component of the Myl-D7 cells proliferation activity released by MS-5 stromal cells was enriched by Q sepharose fractionation and shown to be colony stimulating factor-1 (CSF-1) by Western blotting, BAC1.2F5 cell bioassay and inhibition of Myl-D7 proliferation by CSF-1 antibody. The requirement of Myl-D7 cells for CSF-1 was also demonstrated independently by selecting for rare, stroma-independent Myl-D7 mutant clones able to grow without stroma and additional factors. Eighty-nine stroma-independent mutant clones were obtained and belonged to two classes. The majority of mutants did not secrete any growth promoting activity. The second, rarer class of mutants releases a factor that stimulates proliferation/survival for up to several months and approximately half of the secretors express high levels of CSF-1 mRNA. Wild type Myl-D7 grown with supernatants from the secretor cells retained the stem cell phenotype. These data suggest that CSF-1 may act as a key factor in stroma-regulated hematopoiesis and cell-cell interaction.

Diverse isoforms of colony-stimulating factor-1 have different effects on the development of stroma-dependent hematopoietic cells.

Maintenance and differentiation of hematopoietic stem and progenitor cells are controlled by complex interactions with the stroma microenvironment. Stroma-cell interactions can be supported by locally expressed membrane-spanning cell-surface (cs) growth factors. CSF-1 is expressed by stroma as a soluble glycoprotein, as proteoglycan, or as a membrane-spanning cs glycoprotein. CSF-1 regulates the survival, proliferation, and differentiation of mononuclear phagocytes. Whereas the biological role of soluble CSF-1 is well characterized, the function of the membrane-spanning cell-surface CSF-1 (csCSF-1) remains unclear. To analyze the biological significance of csCSF-1 in vitro, we used an epithelial cell line to ectopically express the different CSF-1 isoforms. In co-cultures of CSF-1 transduced epithelial cells with primary, early hematopoietic progenitor cells we examined whether interaction between csCSF-1 and its receptor mediates cell proliferation, self-renewal, or differentiation. csCSF-1 induces long-lasting proliferation of stimulated cells and furthermore supports self-renewal. Ectopic secretion of soluble CSF-1 does not permit long-term growth of progenitor cells but induces differentiation of monocytes into macrophages. Previously, we showed that the soluble and cs isoforms of stroma-encoded SCF differently affect the development of hematopoietic cells. Cell-surface SCF (csSCF) promotes self-renewal of stimulated cells whereas soluble SCF causes clonal extinction. These results and those presented here for CSF-1 provide evidence for diverse functions of the isoforms of the ligands SCF and CSF-1 for two tyrosine kinase receptors of the subclass III both regulating hematopoiesis on stroma.