A comparative morphometric study on the ultrastructure of adherent cells in long-term bone marrow culture from normal and congenitally anemic mice

The relationship between structure and function of bone marrow stromal tissue in adherent layers of long-term bone marrow cultures (LTBMCs) from normal and congenital anemic mice (C57BL, Sl/Sld, Sl+/Sl+, W/Wv, and W+/W+) was investigated. Many previously reported features were confirmed. However, in LTBMC from all strains of mice examined, isolated cilia with the axonemal structure of a 9 + O pattern with obvious dynein arms were observed in the blanket cells. The frequency of cilia was approximately 2%-5% of total number of profiles of blanket cells examined. Crystalloid inclusions (CI) were observed in cultured macrophages similar to those reported in vivo in all strains of murine LTBMC. The CI could be classified into four types according to their structure in the same way as in vivo (type A to type D), with a predominance of type A in the cultures. Viral particles were also apparent in adherent cells of all strains (except W/Wv and W+/W+), which were compatible with a type C retrovirus. Gap junctions occurred regularly between the adherent cells of LTBMC, particularly between blanket cells and preadipocytes. The most frequent appearance of gap junctions was found in Sl/Sld cultures. The phenomena of normal and abnormal hematopoiesis appear to be accurately reproduced in culture, thus retaining the same relationship between function and structure as occurs in vivo. The surface of isolated cilia of blanket cells, CI of macrophages, viral particles among adherent cells, and gap junctions between blanket cells and preadipocytes is discussed.     

Sl/Sld mice have an increased number of gap junctions in their bone marrow stromal cells

To study the defect of the hematopoietic inductive microenvironment (HIM) in Sl/Sld mice, femoral bone marrow tissue of 10 of each mutant, (Sl/Sld and W/Wv) their normal littermates (Sl+/Sl+ and W+/W+), and 20 normal C57BL mice were examined by electron microscopy using morphometric and statistical methods. Gap junctions were observed in all strains of mice, in the following stromal cell types: 1) reticular cells, 2) between reticular cells and periarterial adventitial cells, and 3) between periarterial adventitial cells. The frequency of gap junctions in bone marrow stromal cells of Sl/Sld mice (mean = 2.2/9.4 X 10(-3) mm2) was significantly higher than in control mice. It is suggested that there is a relationship between the increased numbers of gap junctions in bone marrow stromal cells of Sl/Sld mice and the defect in HIM function in these genetically anemic animals.     

Regulation of murine megakaryocyte size and ploidy by non-platelet-dependent mechanisms in radiation-induced megakaryocytopenia

Megakaryocytic macrocytosis was evaluated in mice after irradiation with 6.5 Gy 60Co gamma rays. During the second and third months after sublethal irradiation, one or more of the following abnormalities of thrombocytopoiesis was present: thrombocytopenia, megakaryocytopenia, macromegakaryocytosis, a shift to higher ploidies, and enlargement of cells within ploidy groups. After transfusion-induced thrombocytosis, reductions in megakaryocyte size were delayed or absent relative to non-irradiated mice, and there was more of a tendency to shift to lower values for megakaryocyte ploidy. Mice with radiation-induced megakaryocytopenia failed to show rebound thrombocytosis during recovery from immunothrombocytopenia, in spite of further increases in megakaryocyte size and ploidy. The findings support the hypotheses that numbers of megakaryocytes may influence the regulation of megakaryocytopoiesis even when there is an excess of platelets and that ploidy distribution is not the sole determinant of the average size of a population of megakaryocytes. After irradiation, persistent megakaryocytopenia may not severely affect platelet production under steady-state conditions, but the ability of the marrow to respond to homeostatic regulation is compromised.     

Infertility due to growth arrest of ovarian follicles in Sl/Slt mice

Sl, Sld, and Slt are mutant alleles at the steel locus. All Sl/Sld and most Sl/Slt female mice are infertile, but the cause of the infertility is different. Germ cells are absent in Sl/Sld ovaries but present in Sl/Slt ovaries. The infertility of Sl/Slt female mice was attributed to the growth arrest of ovarian follicles, and the mechanism was analyzed by producing aggregation chimeras between Sl/Slt and +/+ embryos. Sl/Slt oocytes were ovulated and fertilized in Sl/Slt----+/+ chimeras. We investigated the origin of granulosa cells in the growing follicles and that of granulosa-derived luteal cells in the chimeras by using the electrophoretic pattern of phosphoglycerate kinase-1 and the histochemical activity of beta-glucuronidase as markers. Granulosa cells of Sl/Slt genotype developed and constituted pregnant corpora lutea in Sl/Slt----+/+ chimeras. Therefore, the growth arrest of Sl/Slt ovarian follicles may not be due to an intrinsic defect in granulosa cells but may instead be due to an intrinsic defect in ovarian stromal cells. This suggests that normal stromal cells are essential for the development of ovarian follicles.     

Haemopoietic stem cell proliferation in the bone marrow of S1/S1d mice

In marrow from Sl/Sld mice (but not +/+ mice) day 7 and day 8 CFU-S proliferate whilst day 10 and day 12 CFU-S exhibit negligible proliferation. Media conditioned by both +/+ and Sl/Sld marrow contains an inhibitor of CFU-S proliferation but day 8 CFU-S in +/+ and Sl/Sld marrow show marked dose-response differences to this factor. To inhibit the proliferation of Sl/Sld CFU-S required approximately ten times the concentration of inhibitor that inhibited the proliferation of +/+ CFU-S. Thus abnormally responsive day 8-CFU-S were shown to proliferate in an inhibitory environment. Abnormalities in Sl/Sld CFU-S function were also demonstrated in heterotopic transplantation experiments using +/+ and Sl/Sld donors and hosts to obtain ectopic bone marrow with various stromal (donor) and haemopoietic (host) combinations. Day 8 Sl/Sld CFU-S were seen to proliferate, irrespective of whether the stromal environment was derived from Sl/Sld or +/+ marrow. Sl/Sld mice are generally regarded as animals in which there is a genetically determined defect in haemopoiesis due to an abnormality in the haemopoietic environment. It is difficult, however, to attribute the abnormal CFU-S behaviour in these experiments to environmental factors and the results are consistent with mutation at the Sl locus affecting the responses of CFU-S to regulatory signals, i.e. the genetic defect is not confined to the stromal environment.     

Biochemical and functional characterization of proteoglycans produced by Sl/Sld murine bone marrow stromal cell lines

The Steel anemia of mice results from an inherited defect in the hematopoietic microenvironment. Proteoglycans synthesized by bone marrow stromal cells are an important functional component of the hematopoietic microenvironment in normal animals. It is thus possible that Steel anemia results from a molecular abnormality involving bone marrow stromal proteoglycans. To investigate this possibility, we studied proteoglycan synthesis in three stromal cell lines from Steel anemic (Sl/Sld) animals and two control stromal cell lines, one (+/+2.4) from a non-anemic littermate, and one (GBl/6) from a normal mouse. Proteoglycans were precursor labelled with 35S sulfate and separated by ion exchange HPLC, CsCl density gradient centrifugation, and molecular sieve HPLC. Glycosaminoglycan (GAG) moieties were characterized by molecular sieve HPLC and enzyme sensitivity. There were no consistent differences in total proteoglycan synthesis, proteoglycan heterogeneity, GAG hydrodynamic size, or enzyme sensitivity among the cell lines studied. Growth factor binding to stromal extracellular matrix (ECM) was studied by co-culture of an IL-3-dependent cell line (FDC-P1) with cell-free ECM preparations from an Sl/Sld and a control (GBl/6) stromal cell line, with and without pre-incubation with IL-3. Cell-free ECM preparations from Sl/Sld and control cell lines supported FDC-P1 growth to an approximately equal extent after pre-incubation with IL-3. FDC-P1 growth support by ECM preparations from both cell lines was also observed without IL-3 pre-incubation, although to a lesser extent, suggesting ECM binding of endogenous growth factors synthesized by the stromal cells.     

Studies of Sl/Sld in equilibrium with +/+ mouse aggregation chimaeras. I. Different distribution patterns between melanocytes and mast cells in the skin

In spite of their different origin, both melanocytes and mast cells are deficient in the skin of mutant mice of the Sl/Sld genotype. Since the neural crest and the liver of Sl/Sld embryos contain normal precursors of melanocytes and mast cells, respectively, the deficiency is attributed to a defect in tissue environment necessary for migration and/or differentiation of precursor cells. We investigated whether the tissue environment used for differentiation of melanocytes and mast cells was identical by producing aggregation chimaeras from Sl/Sld and +/+ embryos. Chimaeric mice with apparent pigmented and nonpigmented stripes were obtained. In the nonpigmented stripes of these Sl/Sld in equilibrium with +/+ chimaeras, melanocytes were not detectable in hair follicles but were detectable in the dermis. In contrast, melanocytes were detectable neither in hair follicles nor in the dermis of nonchimaeric Sl/Sld mice. Concentrations of mast cells were comparable in the pigmented and nonpigmented stripes of Sl/Sld in equilibrium with +/+ chimaeras, but the average concentration of mast cells significantly varied in the chimaeras (from 8% to 74% of the value observed in control +/+ mice). The present result suggests that mesodermal cells that support the migration and differentiation of both melanocyte precursors and mast-cell precursors mix homogeneously in the dermis and that ectodermal cells that influence the invasion of differentiating melanocytes into hair follicles make discrete patches.     

Recombinant murine steel factor stimulates in vitro production of granulocyte-macrophage progenitor cells.

The ability of murine Steel factor to promote the in vitro production of granulocyte-macrophage progenitor cells (CFU-GM) was examined in short-term liquid cultures. Bone marrow from C57BL/6J or Sl/Sld mice was placed in culture for seven days with either Steel factor alone or in the presence of IL-3. CFU-GM responsive to GM-CSF, IL-3, and CSF-1 were measured in the input population and again after 3 or 7 days in culture. Steel factor alone increased the number of all CFU-GM types as early as 3 days after culture initiation, with further increases at day 7. This effect was potentiated by the addition of IL-3. Production of CFU-GM by C57BL/6J or Sl/Sld marrow was comparable except for enhanced production of CSF-1 responsive progenitors by Sl/Sld marrow. A recombinant Sld protein was also shown to be equivalent to the wild-type protein in its capacity to promote CFU-GM production from normal bone marrow.     

Studies of Sl/Sld in equilibrium with +/+ mouse aggregation chimaeras. II. Effect of the steel locus on spermatogenesis

Mutant mice of Sl/Sld genotype are deficient in melanocytes, erythrocytes, mast cells and germ cells. Deficiency of melanocytes, erythrocytes and mast cells is not attributable to an intrinsic defect in their precursor cells but to a defect in the tissue environment that is necessary for migration, proliferation and/or differentiation. We investigated the mechanism of germ cell deficiency in male Sl/Sld mice by producing aggregation chimaeras from Sl/Sld and +/+ embryos. Chimaeric mice with apparent white stripes were obtained. Two of four such chimaeras were fertile and the phenotypes of resulting progenies showed that some Sl/Sld germ cells had differentiated into functioning sperms in the testis of the chimaeras. In cross sections of the testes of chimaeras, both differentiated and nondifferentiated tubules were observed. However, the proportions of type A spermatogonia to Sertoli cells in both types of tubules were comparable to the values observed in differentiated tubules of normal +/+ mice. We reconstructed the whole length of four tubules from serial sections. Differentiated and nondifferentiated segments alternated in a single tubule. The shortest differentiated segment contained about 180 Sertoli cells and the shortest nondifferentiated segment about 150 Sertoli cells. These results suggest that Sertoli cells of either Sl/Sld or +/+ genotype make discrete patches and that differentiation of type A spermatogonia does not occur in patches of Sl/Sld Sertoli cells.     

Radiation and haematopoiesis in Harwell steel mice

Haematological information on steel (Sl) mice is limited largely to Sl/Sld mice of Bar Harbor stock (WC.B6 F1). Therefore, two Harwell alleles, SlgbH and Slcon, were investigated. In the steady state both heterozygotes were modestly anaemic, homozygous Slcon and compound Slcon/SlgbH more so. On perturbation by X-irradiation Slcon/SlgbH showed a decrease in median lethal dose (MLD)--6.5 Gy, Slcon/+ and Slcon/Slcon slightly less change (7.5 Gy) compared with +/+, 8 Gy. In recovery from sublethal doses single heterozygotes, double heterozygotes with Wv, and compounds showed no delay in restoration of the count of red blood corpuscles (RBC) such as that seen in typical W mice (e.g. Wv/+, W/Wv). Effects on Slcon/Slcon and Slcon/SlgbH differ from those reported for Sl/Sld in that they show normal growth of spleen colonies when used as lethally irradiated recipients of bone marrow, they support growth of implanted bone marrow to form radiation chimaeras. When Harwell steel mice are donors of bone marrow to lethally irradiated +/+ mice the chimaeras ultimately are not anaemic; when lethally irradiated Harwell steel mice are recipients of +/+ marrow they remain macrocytically anaemic. One deduces that, for normal development and production of normal RBC in the steady state, the erythron requires intrinsic factors determined by wild type alleles at the W locus and extrinsic factors determined by wild type alleles at the Sl locus. Mutant alleles at either locus may determine macrocytosis. Two mutant alleles at either locus are still more deleterious, often lethal. Whereas mutant W alleles may also influence the pluripotent haematopoietic stem cell (HSC) leading to reduced MLD on X-irradiation, a similarly reduced MLD for Sl mutants may represent an increased need for and consumption of products of the haematopoietic stem cells rather than truly increased radiosensitivity, since the Do for spleen colony-forming units is the same for Slcon/SlgbH as +/+ mice.     

Stem cell factor is encoded at the Sl locus of the mouse and is the ligand for the c-kit tyrosine kinase receptor.

We have cloned a partial cDNA encoding murine stem cell factor (SCF) and show that the gene is syntenic with the Sl locus on mouse chromosome 10. Using retroviral vectors to immortalize fetal liver stromal cell lines from mice harboring lethal mutations at the Sl locus (Sl/Sl), we have shown that SCF genomic sequences are deleted in these lines. Furthermore, two other mutations at Sl, Sld and Sl12H, are associated with deletions or alterations of SCF genomic sequences. In vivo administration of SCF can reverse the macrocytic anemia and locally repair the mast cell deficiency of Sl/Sld mice. We have also provided biological and physical evidence that SCF is a ligand for the c-kit receptor.     

Organ interactions in the regulation of hematopoiesis: in vitro interactions of bone, thymus, and spleen with bone marrow stem cells in normal, Sl/Sld and W/Wv mice.

Hematopoietic cell differentiation is influenced by organ-dependent microenvironmental factors as well as humoral regulators. A technique is described for examining certain aspects of the hemopoietic inductive microenvironment in vitro. Suspension and agar cultures of mouse bone marrow were used to study the effects of organ stromal factors on cellular proliferation and differentiation. Bone, spleen, and thymus fragments from irradiated mice were placed in direct contact with or separated by a Nuclepore membrane from syngeneic marrow cells growing in suspension cultures. Normal adult mouse bone and spleen influenced granulocytic differentiation as well as cell proliferation. In this system, bone marrow and organ fragments from W/Wv and SlSld mice behaved like those of their non-anemic littermates. The most prominent difference between W/Wv and Sl/Sla mice and their normal counterparts was observed in the inductionof CFU-C from splenic precursors un-er the influence of CSA. In both types of anemic mice, in vitro generation of CFU-C from spleen was abnormal in young animals but was corrected by four months of age.     

Disparate effects of interleukin 11 and thrombopoietin on megakaryocytopoiesis in vitro

The effects of interleukin-11 (IL-11) and thrombopoietin (TPO) on murine megakaryocytopoiesis were studied using a serum-free culture system. Acting alone, both IL-11 and TPO increased the number of acetylcholinesterase (AchE)(+)cells (megakaryocytes), the latter being more potent than the former. TPO, but not IL-11, increased the mean AchE activity per megakaryocyte (AchE activity/megakaryocyte). TPO increased both the number of megakaryocytes with high ploidy, and of those with low ploidy. In contrast, IL-11 increased only the number of megakaryocytes with high ploidy. The effect of TPO on megakaryocyte ploidy was stronger than that of IL-11. Both IL-11 and TPO increased the proportion of large megakaryocytes, but the latter was more potent than the former. While the stimulatory effects of IL-11 and TPO on the number of megakaryocytes were enhanced by IL-3 or stem cell factor (SCF), synergism of IL-11 or TPO with IL-3 or SCF in stimulating AchE activity/megakaryocyte was inconsistent. IL-11 and TPO stimulated the formation of colony-forming units of megakaryocyte in the presence of IL-3, but not alone, with similar maximum colony numbers for both cytokines. Our findings thus demonstrate that IL-11 principally stimulates megakaryocyte maturation rather than the proliferation of megakaryocytes, whereas TPO stimulates both.     

Stromal cells from murine developing hemopoietic organs: comparison of colony-forming unit of fibroblasts and long-term cultures.

The adherent stromal layer in long-term marrow cultures is essential to the proliferation and differentiation of hemopoietic cells. Adhering cells are heterogeneous and morphologically not adequately characterized. Comparative morphological studies were conducted on adherent cells in short-term clonal assays and long-term cultures derived from liver and bone marrow. Liver and bone marrow at different developmental ages have different hemopoietic activities in vivo and in vitro, as tested via CFU-GM recovery in long-term cultures. Adherent cells from each organ were recovered at an age with high hemopoietic activity (fetal liver and adult bone marrow) and at an age with low hemopoietic activity (neonatal liver and bone marrow). The presence of macrophages, alkaline phosphatase, acid phosphatase, myeloperoxidase, sulfated and non-sulfated glycosaminoglycans (GAGs) and fibronectin was compared. For a given organ, CFU-f colonies showed characteristics similar to those of the confluent adherent stromal layer in long-term cultures. The presence of macrophages and GAGs (sulfated and non-sulfated) in the adherent layer were directly related to the hemopoietic activity. The amount of alkaline phosphatase-positive cells and the amount of fibronectin showed no correlation with the hemopoietic activity of the cultures.     

The dependence of the formation of stromal CFU-f colonies on the stimulating action of hematopoietic cells

CFU-f-derived stromal colony formation was accomplished in adherent marrow cell cultures (AMCC) with serum-rich medium. It turned out to require additional stimulation by hemopoietic feeder cells: by irradiated marrow cells and spleen cells if they possess megakaryocytes and platelets or by platelets from the blood. PDGF, EGF and IL-3 did not substitute the colony stimulating activity of feeder cells. Thymus, lymph node cells and blood leucocytes had no colony stimulating activity. At low oxygen concentrations which improve colony formation the stimulating activity of hemopoietic feeder cells was expressed, as well. Thus, CFU-f colony formation depends on stimulation by hemopoietic cells in addition to serum growth factors. In full populations of marrow cells the CFU-f colony formation is stimulated by marrow cells which accompany the CFU-f.     

The effect of cytokines on the ploidy of megakaryocytes

The effects of recombinant cytokines on the ploidy of human megakaryocytes derived from megakaryocyte progenitors were studied using serum-free agar cultures. Nonadherent and T cell-depleted marrow cells were cultured for 14 days. Megakaryocyte colonies were identified in situ by the alkaline phosphatase anti-alkaline phosphatase technique, using monoclonal antibody against platelet IIb/IIIa. The ploidy of individual megakaryocytes in colonies was determined by microfluorometry with DAPI (4',6-diamidino-2-phenylindole) staining. Recombinant human interleukin 3 (rhIL-3) and recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) supported megakaryocyte colony formation in a dose-dependent manner. However, both rhIL-3 and rhGM-CSF had no definite ability to increase the ploidy values. Recombinant human erythropoietin (rhEpo) or recombinant human macrophage colony-stimulating factor (rhM-CSF) by itself did not stimulate the growth of megakaryocyte progenitors. rhEpo or rhM-CSF, however, stimulated increases in the number, size and ploidy values of megakaryocyte colonies in the presence of rhIL-3 or rhGM-CSF. Recombinant human interleukin 6 (rhIL-6) showed no capacity to generate or enhance megakaryocyte colony formation when added to the culture alone or in combination with rhIL-3. rhIL-6, however, increased the ploidy values in colonies when added with rhIL-3. These results show that rhEpo, rhM-CSF and rhIL-6 affect endomitosis and that two factors are required for megakaryocyte development.     

P-selectin,and not E-selectin,negatively regulates murine megakaryocytopoiesis

To assess the role of P-selectin and E-selectin in megakaryocytopoiesis, in vitro assays were performed in animal models deficient in both adhesion receptors. There was a significantly greater number of IL-3-responsive megakaryocyte progenitors CFU (CFU-MK) and an increase in immature megakaryoblasts in response to IL-6 in the P-selectin-null mice compared with the wild-type controls. Furthermore, P-selectin-null mice showed a greater number of CFU-MK colonies derived from CD34(+) cells in response to IL-3 or IL-3 plus stem cell factor. A significant shift in baseline ploidy with a reduction in 8N cells and an increase in 32N cells was also observed in the P-selectin-null mice. Secretion of the inhibitory growth factor TGF-beta1 and not TGF-beta2 was significantly lower in the supernatants of cultures containing bone marrow cells from P-selectin-deficient mice as compared with those from the wild-type control bone marrow cells. No differences in the responsiveness of murine CFU-MK, immature megakaryocytes, or 5-fluorouracil-selected stem cells to cytokines were observed in E-selectin-null mice as compared with the control mice. These studies indicate that the absence of P-selectin, and not E-selectin, resulted in an altered adhesion environment with subsequent expansion of megakaryocyte progenitors and immature megakaryoblasts, enhanced secretion of TGF-beta1, and apparent increased responsiveness to inflammatory cytokines.     

Regulatory mechanisms of mast cell differentiation

Mast cells are a progeny of the multipotential hematopoietic stem cell. Most of progenies of the stem cell complete their differentiation within the bone marrow, but precursors of mast cells leave the bone marrow, migrate in blood, and invade into tissues. After the invasion, precursors proliferate and differentiate into mast cells. An appreciable proportion of mast cells retain proliferative potential after differentiation, and even after degranulation, some mast cells can proliferate and recover the original morphology. Proliferation of mast cells are regulated by both T cell-derived factors (i.e., IL-3 and IL-4) and fibroblast-derived factor(s). Mice of either W/Wv or Sl/Sld genotype lack mast cells, but mast cells do develop when bone marrow cells of W/Wv or Sl/Sld mice were cultured in the presence of T cell-derived factors. Mast cells derived from W/Wv mice cannot respond fibroblast-derived factor(s) and fibroblasts derived from Sl/Sld mice cannot support mast cells of normal mouse origin. Phenotypes of mast cells are determined by the environment in which the mast cells differentiated. However, when mast cells are transplanted into a new environment which is different from the original one, the mast cells acquire the phenotype which are dependent on the second environment.     

A stromal cell line from myeloid long-term bone marrow cultures can support myelopoiesis and B lymphopoiesis

The production of B lymphocytes and myeloid cells occurs in the bone marrow in association with a supporting population of stromal cells. To determine whether these processes are dependent upon the same or different populations of stromal cells, stromal cell lines were generated from the adherent layer of a Dexter type long-term bone marrow culture. These cultures support myeloid cells and their precursors, a B cell precursor, and the adherent layer cells with support B cell differentiation under appropriate conditions. Two of the lines examined, S10 and S17, express class I histocompatibility antigens but not other hemopoietic cell surface determinants such as Thy-1, Lyt-1, Ig, Ia, Mac-1, or BP-1. Both lines could support myelopoiesis under Dexter conditions upon seeding with nylon wool-passed bone marrow. The nylon wool passage depletes stromal cells capable of forming adherent layers in vitro but retains hemopoietic precursors. The number of cells and colony-forming units-granulocytes/macrophages in the nonadherent cell population recovered 3 wk post-seeding had increased 19-fold and 10-fold, respectively, in the reseeded cultures of S10 and S17. After 3 wk of growth in Dexter conditions, the reseeded cultures were transferred to conditions optimal for B cell differentiation described by Whitlock and Witte. After 4 wk of growth, hemopoietic cells were consistently recovered from S17 cultures but not those of S10. A proportion of these cells from S17 cultures expressed the 14.8 antigen and were surface IgM positive. Surviving hemopoietic cells present in cultures of S10 were primarily macrophages. These findings indicate that S17 but not S10 can support both myelopoiesis and B lymphopoiesis and suggest that one stromal cell population has the capacity to form a hemopoietic microenvironment for both lineages.