Long-term type 1 diabetes influences haematopoietic stem cells by reducing vascular repair potential and increasing inflammatory monocyte generation in a murine model.

AIMS/HYPOTHESIS: We sought to determine the impact of long-standing type 1 diabetes on haematopoietic stem/progenitor cell (HSC) number and function and to examine the impact of modulating glycoprotein (GP)130 receptor in these cells. METHODS: Wild-type, gp130(-/-) and GFP chimeric mice were treated with streptozotocin to induce type 1 diabetes. Bone marrow (BM)-derived cells were used for colony-formation assay, quantification of side population (SP) cells, examination of gene expression, nitric oxide measurement and migration studies. Endothelial progenitor cells (EPCs), a population of vascular precursors derived from HSCs, were compared in diabetic and control mice. Cytokines were measured in BM supernatant fractions by ELISA and protein array. Flow cytometry was performed on enzymatically dissociated retina from gfp(+) chimeric mice and used to assess BM cell recruitment to the retina, kidney and blood. RESULTS: BM cells from the 12-month-diabetic mice showed reduced colony-forming ability, depletion of SP-HSCs with a proportional increase in SP-HSCs residing in hypoxic regions of BM, decreased EPC numbers, and reduced eNos (also known as Nos3) but increased iNos (also known as Nos2) and oxidative stress-related genes. BM supernatant fraction showed increased cytokines, GP130 ligands and monocyte/macrophage stimulating factor. Retina, kidney and peripheral blood showed increased numbers of CD11b(+)/CD45(hi)/ CCR2(+)/Ly6C(hi) inflammatory monocytes. Diabetic gp130(-/-) mice were protected from development of diabetes-induced changes in their HSCs. CONCLUSIONS/INTERPRETATION: The BM microenvironment of type 1 diabetic mice can lead to changes in haematopoiesis, with generation of more monocytes and fewer EPCs contributing to development of microvascular complications. Inhibition of GP130 activation may serve as a therapeutic strategy to improve the key aspects of this dysfunction.

Control of lymphopoiesis by p50csk, a regulatory protein tyrosine kinase.

The csk gene encodes a nonreceptor protein tyrosine kinase that acts in part by regulating the activity of src-family protein tyrosine kinases. Since the src-family kinases p56lck and p59fyn play pivotal roles during lymphocyte development, it seemed plausible that p50csk might contribute to these regulatory circuits. Using a gene targeting approach, mouse embryonic stem cell lines lacking functional csk genes were generated. These csknull embryonic stem cells proved capable of contributing to many adult tissues, notably heart and brain. However, although csknull progenitors colonized the developing thymus, T and B cell differentiation were both blocked at very early stages. This represented a relatively selective interdiction of lymphocyte maturation, since csknull hematopoietic progenitors supported the development of normal-appearing MAC-1+ blood leukocytes, and the successful maturation of granulocyte/macrophage-colony-forming units from fetal liver progenitors. We conclude that p50csk regulates normal lymphocyte differentiation, but that it almost certainly does so by acting on targets other than p56lck and p59fyn.

In vivo and in vitro characterization of long-term repopulating primitive hematopoietic cells isolated by sequential Hoechst 33342-rhodamine 123 FACS selection.

Subpopulations of very primitive hematopoietic cells were isolated by fluorescence-activated cell sorter (FACS) selection of density gradient-enriched, lineage-depleted marrow cells with blast cell light scatter characteristics that bound low levels of the DNA binding dye, Hoechst 33342 (Hö) and retained differential amounts of the mitochondrial binding dye, rhodamine 123 (Rh-123). The dyes were used sequentially in a single sorting operation. The subfractions of cells that stained most weakly with both dyes were highly coenriched for long-term repopulating cells (LTRC) and for in vitro high proliferative potential colony-forming cells (HPP-CFC). Furthermore, as populations of cells were progressively selected on the basis of decreasing Hö and Rh-123 fluorescence, first the CFU-S-8, then the CFU-S-12 diminished or disappeared entirely in the lowest Rh-123 fraction. In these low fluorescent populations, plating efficiency for HPP-CFC was very high when cultured in the combined presence of recombinant rat stem cell factor (rrSCF), recombinant human interleukin-1 (rhIL-1), recombinant murine interleukin-3 (rmIL-3) and recombinant human colony-stimulating factor-1 (rhCSF-1), apparently reaching 100% in some instances. When 20 male donor cells from this lowest fluorescent Hö/Rh-123 fraction were injected into lethally irradiated female recipients, along with a "compromised" marrow cell population (3x previously transplanted nonsorted female bone marrow cells), the sorted male donor cells were able to completely and exclusively repopulate the myeloid and the lymphoid B and T cell compartments of the recipients for at least 10 months posttransplant. Assays of cell fractions that were relatively more Rh-123 fluorescent demonstrated the presence of cell with progressively less repopulating capacity. When descendants of transplanted low fluorescent Rh-123 selected cells, as found in 12-day spleen colonies, were assayed for the capacity to provide long-term survival in secondary recipients, they were able to do so in a high proportion of lethally irradiated recipients. However, spleen colonies derived from the mid-high fluorescence fraction were completely unable to do so. In summary, we have demonstrated with a sequential Hö/Rh-123 sorting system that a subset of HPP-CFC cofractionate with LTRC with high frequency. Using this system, the enrichment of LTRC in the lowest Rh-123 compartment of the sequentially Hö/Rh-123 selected cells appears to be the greatest demonstrated thus far. In addition, this study further supports previous ones that identify a compartment of LTRC that are largely distinct from CFU-S-12.

Interleukin 1 plus interleukin 3 plus colony-stimulating factor 1 are essential for clonal proliferation of primitive myeloid bone marrow cells.

The clonal growth in nutrient agar at low cell densities of high-proliferative potential colony-forming cells (HPP-CFC) of bone marrow obtained from mice treated 2 days earlier with 5-fluorouracil (FU) (FU2dBM) has been shown to require a combination of three growth factors, interleukin 1 (IL-1), interleukin 3 (IL-3), and macrophage colony-stimulating factor (CSF-1). These HPP-CFC have been enriched 140-fold from FU2dBM by fluorescence-activated cell sorting of 7/4-, B220-, and L3T4-negative cells. The mean of the plating efficiencies of these enriched populations was 4.4% and no growth was observed when the factors were used singly. Similarly, enrichments of 16-fold were obtained from FU2dBM using immunomagnetic Dynabeads with anti-7/4 plus anti-B220 (meaning plating efficiency 0.5%). The further additions of human granulocyte CSF or mouse granulocyte-macrophage CSF or both to IL-1 plus IL-3 plus CSF-1 did not increase HPP-CFC colony formation, but both augmented the small colony formation with IL-1 plus IL-3, IL-3 plus CSF-1, or IL-1 plus CSF-1.

Transforming growth factor beta, pleiotropic regulator of hematopoietic stem cells: potential physiological and clinical relevance.

Transforming growth factor beta (TGF-beta) is a pleiotropic regulator of all stages of hematopoieis. Depending on the differentiation stage of the target cell, the local environment, and the concentration of TGF-beta, TGF-beta can be proproliferative or antiproliferative, proapoptotic or antiapoptotic, and/or prodifferentiative or antidifferentiative. TGF-beta is the major regulator of stem cell quiescence and can act directly or indirectly through effects on the marrow microenvironment. In addition, paracrine and autocrine actions of TGF-beta have overlapping but distinct regulatory effects on hematopoietic stem/progenitor cells. Neutralization of autocrine TGF-beta has therapeutic potential.

Synergism between hemopoietic growth factors (HGFs) detected by their effects on cells bearing receptors for a lineage specific HGF: assay of hemopoietin-1.

The preceding paper describes a new approach to the detection and assay of growth factors for developmentally early multipotent hemopoietic cells (Bartelmez et al., J. Cell. Physiol., 1985). This approach, involving measurement of the increase in the number of receptors for the mononuclear phagocyte specific hemopoietic growth factor (HGF), colony stimulating factor-1 (CSF-1), in cultures of developmentally early murine cells incubated with putative HGFs, has been used to define and assay hemopoietin-1. Hemopoietin-1 (Mr approximately 20,000) is found in the medium derived from serum-free cultures of cells of the human urinary bladder carcinoma line 5637. In contrast to both hemopoietin-2 and CSF-1, which also stimulate an increase in CSF-1 receptor numbers in cultures of developmentally early hemopoietic cells, hemopoietin-1 alone has no detectable effect. However, hemopoietin-1 exhibits dramatic synergism with CSF-1. In the presence of CSF-1, hemopoietin-1 stimulates the proliferation of developmentally earlier cells than those that respond to either CSF-1 alone or hemopoietin-2 alone or their combination. These cells proliferate for at least 3 days with no alteration of the average CSF-1 receptor density. However, by 5 days of incubation, the progeny of developmentally early hemopoietic cells that have proliferated in response to hemopoietin-1 + CSF-1 exhibit an approximately tenfold increase in the average CSF-1 receptor density per cell, which immediately precedes their differentiation to adherent mononuclear phagocytes. As hemopoietin-1 does not possess colony stimulating or burst promoting activities for murine bone marrow cells, but acts on multipotent hemopoietic cells, the analysis of the mechanism of its synergistic effects with HGFs such as CSF-1 are of special relevance to the regulation of early events in hemopoiesis.

Lineage specific receptors used to identify a growth factor for developmentally early hemopoietic cells: assay of hemopoietin-2.

A new approach, based on the occurrence of receptors for the mononuclear phagocyte lineage specific hemopoietic growth factor (HGF) colony stimulating factor-1 (CSF-1) on developmentally early multipotent cells, is utilized to detect and assay rapidly another HGF, hemopoietin-2. This method is also used to determine the relative maturity of hemopoietin-2 target cells, to investigate synergism between hemopoietin-2 and CSF-1, and to measure CSF-1 receptor levels on maturing cells. While the target cell specificities of hemopoietin-2 and CSF-1 overlap, hemopoietin-2 causes the appearance of developmentally earlier 125I-CSF-1 binding cells de novo in the absence of CSF-1. Increased CSF-1 receptor densities are observed on cells incubated with either HGF, consistent with acquisition of the capacity for increased expression of the receptor by mononuclear phagocyte progenitor cells just prior to their differentiation to adherent mononuclear phagocytes. Together, both HGFs have a synergistic effect on the generation of 125I-CSF-1 binding cells with elevated CSF-1 receptor densities. Preliminary characterization of hemopoietin-2 from medium conditioned by WEHI-3 cells indicates that it is very similar to, if not identical with, interleukin-3 (IL-3) and the HGF(s) acting on multipotential cells and cells giving rise to erythroid cells, granulocytes, mononuclear phagocytes, and megakaryocytes. Purified IL-3 was shown to possess hemopoietin-2 activity.

Antigen-mediated release of eosinophil growth stimulating factor from Trichinella spiralis sensitized spleen cells: a comparison of T. spiralis stage-specific antigen preparations.

When non-adherent, Trichinella spiralis-sensitized mouse spleen cells were challenged in vitro with T. spiralis antigens, an eosinophil growth factor (Eo-GSF) was released into the culture medium. This factor was assayed by its ability to initiate eosinophil production in liquid cultures of syngeneic, non-adherent marrow cells obtained from unsensitized mice. Extracts of each parasite stage as well as excretory-secretory (ES) products of adult and muscle larva stages were compared for their ability to stimulate spleen cells to release Eo-GSF. All stages and ES products had this ability but most of the preparations had unique dose-optima and there was a very wide range with regard to the optimum dose (in microgram protein/ml): (i) preadult stage, 1 x 10(-5); (ii) muscle stage ES products, 1 x 10(-3); (iii) muscle stage, 1 x 10(-2); (iv) adult stage, 1 x 10(-2); (v) adult ES products, 1 x 10(-1); and (vi) newborn stage, 1.0. When the Eo-GSF-containing conditioned media derived from spleen cell cultures exposed to the optimum dosages were tested on the same population of marrow cells, three potency groups were identified. The rank order of potency was: muscle stage ES products greater than preadult, newborn and adult stages greater than muscles stage and adult ES products. Preliminary experiments revealed that this ranking was not maintained with regard to the release of neutrophil and macrophage growth factors by these preparations.

Specific growth inhibition of primitive hematopoietic progenitor cells mediated through monoclonal antibody binding to major histocompatibility class II molecules.

In a previous study using a canine model, we reported that a certain anti-class II monoclonal antibody (MoAb H81.9), which recognizes an epitope formed by the alpha and beta subunits of HLA-DR, prevented long-term engraftment of autologous marrow cells if administered intravenously during the first 4 days after 9.2 Gy of total body irradiation. Another MoAb (B1F6), reactive with only the beta subunit of HLA-DR and -DP, had no adverse effect on engraftment, although both MoAbs detect antigens on hematopoietic long-term repopulating cells as determined from complement-mediated lysis experiments. In the present study, continuous exposure of unfractionated human marrow to MoAb H81.9 specifically inhibited the growth of primitive progenitor cells that require multiple hematopoietic growth factors for proliferation (high proliferative potential colony forming cells [HPP-CFC] and burst-forming units-erythroid [BFU-e]), but had no effect on more mature, single factor responsive (CFU-GM), progenitor cells. In contrast, MoAb B1F6 did not impair primitive progenitor cell growth cultured as unfractionated marrow. However, when cell dose-response experiments were performed using CD34-positive cells plated at low cell densities, the marked inhibitory effects of MoAb H81.9 on HPP-CFC and BFU-e colony formation were not seen. These findings suggest that MoAb H81.9 may not inhibit primitive hematopoietic cells directly, but rather indirectly through the action of potent mediators derived from other HLA-DR-positive marrow cells.

Differential regulation of spleen cell-mediated eosinophil and neutrophil-macrophage production.

Nonadherent spleen cells of mice infected with Trichinella spiralis released growth stimulatory factors (GSFs) in vitro when challenged with excretory/secretory products of muscle stage larvae. The assay of GSF was based on proliferation of normal, nonadherent syngeneic marrow cells in liquid tube cultures. Media conditioned for 1 day by challenged spleen cells stimulated eosinophil production but failed to stimulate production of other cell types. In contrast, media conditioned for 5 days supported eosinophil, neutrophil, and macrophage production. The kinetics of cell production were also different. Eosinophil production started within 1 day, reached a peak at day 2, and was down to control levels by day 4. In contrast, neutrophil/macrophage production began between 2 and 4 days and reached a peak at 6--8 days. The short duration of eosinophil production was evidently due to depletion of growth-factor-responsive cells.

Increased Qa-m7 antigen expression is characteristic of primitive hemopoietic progenitors in regenerating marrow.

Developmentally early murine hemopoietic progenitor cells of high proliferative potential (HPP-CFC), which are detectable in clonal agar culture in the presence of the lineage-specific hemopoietic growth factor, colony-stimulating factor-1 (CSF-1) plus hemopoietin-1 (H-1), or interleukin 3 (IL 3), express relatively high levels of the Qa-m7 antigenic determinant. This determinant is progressively lost during differentiation, and the more committed progenitors which grow in the presence of CSF-1 alone are essentially devoid of Qa-m7. Significant increases in both the proportion of Qa-m7-positive myeloid cells and the level of Qa-m7 antigen expression have been observed in bone marrow cells regenerating after the administration of the cytotoxic agent 5-fluorouracil (5-FU). By exploiting this increase in Qa-m7 antigen expression during regeneration and the HPP-CFC-sparing properties of 5-FU, we have been able to enrich HPP-CFC from marrows 8 days post-5-FU treatment (FU8d) to purities of greater than 20%. Furthermore, discontinuous gradient centrifugation and fluorescence-activated cell sorting of FU8d bone marrow cells on the basis of their light-scattering properties and Qa-m7 expression has unmasked a further subset of HPP-CFC which strictly requires the combined stimulus of three hemopoietic growth factors (H-1, IL 3, and CSF-1) for clonal growth. These highly enriched subsets of HPP-CFC are either identical to or co-fractionate with transplantable multipotential hemopoietic progenitors capable of reconstituting the hemopoietic system of lethally irradiated mice. Up to one in three cells in these highly enriched fractions is an HPP-CFC, and up to one in two cells may be CFU-S assayed 13 days post-transplantation. In addition, these fractions contain progenitors capable of reconstituting the platelet, erythroid, and myeloid compartments of the marrow.

Stimulation of eosinophil production in vitro by eosinophilopoietin and spleen-cell-derived eosinophil growth-stimulating factor.

Eosinophilopoietin (EPP) was previously characterized by the ability to stimulate eosinophil production in vivo, but these studies could not ascertain whether EPP had a direct effect on the bone marrow or acted indirectly by causing release of eosinophilopoietic activity by other tissues. The present studies demonstrate that EPP stimulates eosinophil growth in liquid culture of mouse bone marrow in vitro. The timing of stimulation by EPP in vivo and in vitro were parallel, with maximal eosinophil growth after 48 hr. Moreover, EPP appears similar to, and possible identical with, the eosinophil growth-stimulating substance (EO-GSF) released by antigenic stimulation of immune nonadherent spleen cells. Both EPP and EO-GSF are of low molecular weight, both produce stimulation of eosinophil growth with identical kinetics, and both produced similar dose-response curves in the liquid culture system.

Transforming growth factor beta 1 directly and reversibly inhibits the initial cell divisions of long-term repopulating hematopoietic stem cells.

Hematopoiesis appears to be regulated, in part, by a balance between extracellular positive and negative growth signals. Transforming growth factor beta-1 (TGF-beta 1) has been shown to be a negative regulator of primitive hematopoietic cells. This study examined the direct effect of TGF-beta 1 on the proliferation and differentiation of long-term repopulating hematopoietic stem cells (LTR-HSC) in vitro. We previously reported a cell fractionation approach that includes the selection of low Hoescht 33342/low Rhodamine 123 (low Ho/Rh) cell fractions that are highly enriched for long-term repopulating cells (LTR-HSC) and also clone to a very high efficiency in the presence of stem cell factor (SCF) + interleukin-3 (IL-3) + IL-6: 90% to 100% of individually cultured low Ho/Rh cells formed high proliferative potential clones. This high cloning efficiency of an LTR-HSC enriched cell population enabled proliferation inhibition studies to be more easily interpreted. In this report, we show that the continuous presence of TGF-beta 1 directly inhibits the cell division of essentially all low Ho/Rh cells (in a dose-dependent manner) during their 0 to 5th cell division in vitro. Therefore, it follows that TGF-beta 1 must directly inhibit the proliferation of LTR-HSC contained within these low Ho/Rh cells. The time required for some low Ho/Rh cells to undergo their first cell division in vitro was also prolonged in the presence of TGF-beta 1. Furthermore, when low Ho/Rh cells were exposed to TFG-beta 1 for varying lengths of time before neutralization of the TGF-beta 1 by monoclonal antibody, the ability to form macroclones was markedly decreased after approximately 4 days of TGF-beta 1 exposure. In addition, 1 to 10 ng/mL of TGF-beta 1 resulted in a maintenance of high proliferative potential-colony-forming cell (HPP-CFC) during 8 days of culture compared with loss of HPP-CFC in cultures with no added TGF-beta 1. In conclusion, this study shows that TGF-beta 1 directly inhibits the initial stages of proliferation of LTR-HSC and appears to slow the differentiation of daughter cells of low Ho/Rh cells.

Changes in cell surface antigen expression during murine bone marrow cell regeneration in vivo and proliferation in vitro.

Modulations in surface antigen expression during marrow regeneration in vivo, and proliferation in vitro in response to haemopoietic growth factors, were studied using a panel of monoclonal antibodies recognizing antigenic determinants expressed by primitive multipotential progenitor cells (Thy-1, Qa-m7), or lineage antigens restricted to committed progenitors and differentiated cells of the neutrophil/macrophage (7/4) and B lymphocyte (B220) lineages. These two categories of antigen exhibited differing responses to marrow perturbation and proliferation. Following administration of a cytotoxic dose of 5-fluorouracil, or lethal irradiation and transplantation of normal donor marrow, the levels of Thy-1 and Qa-m7 antigen expression rapidly increase, reaching a peak at the onset of regeneration: the nadir of marrow cellularity. Expression of these antigens returns to normal as regeneration proceeds and marrow is reconstituted. 7/4 and B220 antigen expression reflect the presence or absence of maturing cells bearing these markers: antigen expression declining following perturbation, and re-emerging during the course of regeneration. In vitro, when marrow cells taken from mice 8 days following treatment with 5-FU are grown in liquid culture in the presence of colony-stimulating factor-1 plus bladder cell carcinoma cell line 5637 conditioned medium, marrow cells are stimulated to proliferate and differentiate along the neutrophil/macrophage lineage. 7/4 antigen expression increases throughout the culture period, and B220 antigen is undetectable after the fifth day of culture. Thy-1 antigen expression also rises and remains elevated, and Qa-m7 antigen expression remains stable.

A c-kit ligand, recombinant human stem cell factor, mediates reversible expansion of multiple CD34+ colony-forming cell types in blood and marrow of baboons.

The ligand for the human c-kit, recombinant human stem cell factor (SCF), was administered to baboons at doses of 200, 100, 50, 25, and 10 micrograms/kg/d. SCF induced a dose-dependent expansion of hematopoietic colony-forming cells (CFC) of multiple types in both blood and marrow, including colony-forming unit (CFU) granulocyte-monocyte, burst-forming unit-erythroid, CFU-MIX, and high proliferative potential-CFC. These changes were associated with a dose-dependent leukocytosis, involving all leukocyte lineages, a reticulocytosis, and increases in marrow cellularity. At 200 micrograms/kg/d of SCF, CFC in blood were increased 10-fold to greater than 100-fold. This correlated with an increased frequency of CD34+ cells in blood. The frequency of CFC in blood approached that of marrow in some animals. These changes were reversed within 7 to 14 days of stopping SCF. The results of these studies suggest a role for the c-kit ligand in stimulating the expansion of multiple CFC types in blood and marrow for potential therapeutic purposes.

CD34+ marrow cells, devoid of T and B lymphocytes, reconstitute stable lymphopoiesis and myelopoiesis in lethally irradiated allogeneic baboons.

CD34+ cells devoid of detectable mature and immature T and B lymphocytes, expressing the CD2, CD10, and CD20 antigens, were isolated from marrows of three pairs of sex-mismatched, mixed lymphocyte culture (MLC) nonreactive, sibling baboons. Reciprocal transplants were performed between members of each pair, using the sex chromosomes, identified by standard cytogenetic techniques, as markers of the transplanted cells. Five animals from these three pairs were transplanted with 0.6 to 2.1 x 10(6)/kg of isolated cryopreserved and/or fresh isolated cells that were greater than 95% to 97% CD34+. Before transplantation, animals were treated with either single (920 or 1,020 cGy) or split (700 cGy x 2) dose total body irradiation. All animals engrafted with donor cells, as demonstrated by cytogenetic analysis of bone marrow metaphase cells 4 weeks after transplantation, with days to white blood cell count (WBC) greater than 500 being 19 +/- 2, to WBC greater than 1,000 23 +/- 2, to absolute neutrophil count greater than 500 24 +/- 3, and to platelets greater than 20,000 30 +/- 7. Three animals died of infectious-related complications at 34, 42, and 109 days after transplantation with evidence of host and donor cells (mixed chimerism) in marrow. Two animals remain alive and healthy more than 545 and 455 days after transplantation with stable mixed chimerism in marrow and blood. For these two animals, cytogenetic analysis of granulocyte/macrophage and erythroid colonies derived from marrow precursors between weeks 25 and 42 posttransplant showed evidence of mixed chimerism. Cytogenetic studies of CD2+ T cells and CD20+ B cells isolated from blood of these two animals between weeks 21 and 51 posttransplant showed the presence of mixed chimerism in both lymphocyte populations. Thus, isolated allogeneic CD34+ marrow cells devoid of detectable mature and immature T and B lymphocytes can engraft and reconstitute stable long-term myelopoiesis and lymphopoiesis in lethally irradiated baboons. These results are consistent with the hypothesis that CD34+ marrow cells contain pluripotent hematopoietic stem cells capable of fully reconstituting lymphohematopoiesis in the transplanted host.

The ligand for c-kit, stem cell factor, stimulates the circulation of cells that engraft lethally irradiated baboons.

Recombinant human stem cell factor (SCF), the ligand for c-kit, has been shown to stimulate increased numbers of hematopoietic progenitor cells of multiple types to circulate in the blood of baboons, but it was not known if the cells stimulated to circulate by SCF contained cells capable of engrafting and rescuing lethally irradiated baboons. Peripheral blood mononuclear cells (PBMNC) were collected by leukapheresis from four untreated control baboons and from three baboons on the 10th or 11th day of treatment with SCF (200 micrograms/kg/d). All animals were transplanted with 1.00 to 1.04 x 10(8)/kg of cryopreserved autologous PBMNC after treatment with a single dose of 1,020 cGy total body irradiation (TBI). Three animals were transplanted with PBMNC that had been collected during SCF treatment, 24 to 38 days after the last dose of SCF. Rapid trilineage engraftment was documented by bone marrow biopsy in all three. The mean time to a total white blood cell count (WBC) > or = 500/microL, WBC > or = 1,000/microL, and an absolute neutrophil count (ANC) > or = 500/microL was 15 +/- 3 (mean +/- SD), 19 +/- 1, and 19 +/- 2 days, respectively. Two animals remain alive with stable engraftment more than 180 and 245 days posttransplant. The third died of sepsis 32 days posttransplant with a hypercellular marrow showing trilineage engraftment. The surviving animals were transfusion independent by 10 and 59 days posttransplant. Four control animals were transplanted with PBMNC collected in the absence of SCF stimulation. One was treated for 11 days with SCF (200 micrograms/kg/d) after PBMNC were collected. This animal was transplanted 25 days after the last dose of SCF. None of the four control animals engrafted and they died 13, 16, 28, and 38 days posttransplant with marrow aplasia. Treatment with SCF stimulates the circulation of cells that engraft and rescue lethally irradiated baboons. The characteristics of the transplantable cells present in the circulation are now amenable to direct study.

Distinct and overlapping direct effects of macrophage inflammatory protein-1 alpha and transforming growth factor beta on hematopoietic progenitor/stem cell growth.

Both transforming growth factor beta (TGF beta) and macrophage inflammatory protein 1 alpha (MIP-1 alpha) have been shown to be multifunctional regulators of hematopoiesis that can either inhibit or enhance the growth of hematopoietic progenitor cells (HPC). We report here the spectrum of activities of these two cytokines on different hematopoietic progenitor and stem cell populations, and whether these effects are direct or indirect. MIP-1 alpha enhances interleukin-3 (IL-3)/and granulocyte-macrophage colony-stimulating factor (GM-CSF)/induced colony formation of normal bone marrow progenitor cells (BMC) and lineage-negative (Lin-) progenitors, but has no effect on G-CSF or CSF-1/induced colony formation. Similarly, TGF beta enhances GM-CSF/induced colony formation of normal BMC and Lin- progenitors. In contrast, TGF beta inhibits IL-3/ and CSF-1/induced colony formation of Lin- progenitors. The effects of MIP-1 alpha and TGF beta on the growth of Lin- progenitors were direct and correlate with colony formation in soft agar. Separation of the Lin- cells into Thy-1 and Thy-1lo subsets showed that the growth of Thy-1lo Lin- cells is directly inhibited by MIP-1 alpha and TGF beta regardless of the cytokine used to stimulate growth (IL-3), GM-CSF, or CSF-1). In contrast, two other stem cell populations (0% to 15% Höechst 33342/Rhodamine 123 [Hö/Rh123] and Lin-Sca-1+ cells) were markedly inhibited by TGF beta and unaffected by MIP-1 alpha. Furthermore, MIP-1 alpha has no effect on high proliferative potential colony-forming cells 1 or 2 (HPP-CFC/1 or /2) colony formation in vitro, whereas TGF beta inhibits both HPP-CFC/1 and HPP-CFC/2. Thus, MIP-1 alpha and TGF beta are direct bidirectional regulators of HPC growth, whose effects are dependent on other growth factors present as well as the maturational state of the HPC assayed. The spectrum of their inhibitory and enhancing activities shows overlapping yet distinct effects.

Recombinant human stem cell factor, a c-kit ligand, stimulates hematopoiesis in primates.

Recombinant human stem cell factor (SCF) is homologous with recombinant rat SCF (rrSCF) and is a ligand for c-kit. We determined the influence of SCF on hematopoiesis in vitro and in vivo in baboons. In vitro, SCF alone stimulated little growth of hematopoietic colony-forming cells from baboon marrow, but did increase the number of colonies formed in response to erythropoietin (Epo), interleukin-3 (IL-3), and granulocyte-macrophage colony-stimulating factor (GM-CSF). In vivo, SCF caused an increase in the peripheral blood of the number of erythrocytes, neutrophils, lymphocytes, monocytes, eosinophils, and basophils. In marrow, it caused an increase in marrow cellularity and in the absolute number of colony-forming unit-granulocyte-monocyte (CFU-GM) and burst-forming unit-erythroid (BFU-E) in marrow following infusion of SCF. The in vivo stimulation of multiple lymphohematopoietic lineages corroborates previous in vitro studies and suggests a potentially important clinical role for SCF.