Recombinant gibbon interleukin-3 stimulates megakaryocyte colony growth in vitro from human peripheral blood progenitor cells

Gibbon interleukin-3 (rIL-3) has recently been cloned and found to have a high degree of homology with the human IL-3 molecule. In this investigation, we evaluated the effects of gibbon rIL-3 on normal human peripheral blood megakaryocyte progenitor cell growth in vitro. Gibbon rIL-3 exhibited substantial megakaryocyte colony stimulatory activity (Meg-CSA), supporting peak colony numbers at a concentration of 1 U/ml. Megakaryocyte colony growth induced by rIL-3 reached 58% of the maximum achieved with the active, Meg-CSA-containing protein fraction of aplastic canine serum. Increasing gibbon rIL-3 concentrations also stimulated a 4-5-fold increase in megakaryocyte colony size and resulted in a decrease in geometric mean megakaryocyte ploidy. Ploidy values fell from 8.5N +/- 1.4 (+/- SEM) at an rIL-3 concentration of 0.1 U/ml to a minimum of 2.9N +/- 0.3 at 10 U/ml. In the presence of rIL-3 at 1.0 U/ml, megakaryocyte colony growth was linear with cell plating density and the regression line passed approximately through the origin. The effects of rIL-3 on megakaryocyte colony growth were independent of the presence of T-lymphocytes in the cultures. Cross-species evaluation of murine and gibbon IL-3 indicated that its bioactivity is species restricted. Murine IL-3 did not support colony growth from human megakaryocyte progenitors and gibbon rIL-3 showed no activity in stimulating acetylcholinesterase production by murine bone marrow cells. Gibbon rIL-3 is a potent stimulator of the early events of human megakaryocyte progenitor cell development promoting predominantly mitosis and early megakaryocytic differentiation.     

The humoral nature of the colony-stimulating action of bone marrow cells on stromal colony formation in bone marrow cultures

In 24 hours adherent marrow cell cultures (AMCC) were represented by single stretched fibroblasts. In non-feeder-supplemented AMCC most of the CFU-f remained single fibroblasts or passed through 1-3 cell doublings [correction of dudlings]. The colony stimulating activity of irradiated marrow cells was found to be diffuse across the Millipore filter, which seems to indicate that haemopoietic marrow cells produce a colony stimulating factor which is required for triggering the CFU-f from the Go-period of the cell cycle into cell proliferation.     

Effect of L-phenylalanine methyl ester on the colony formation of hematopoietic progenitor cells from human bone marrow

We have previously shown that L-phenylalanine methyl ester (PME) is capable of removing monocytes and enhancing the growth of hematopoietic colonies from human peripheral blood (PB) mononuclear cells (MNC). In the present study, we further compared the effect of PME on the colony formation of bone marrow (BM) and PB. Low density (less than or equal to 1.077 g/ml) MNC were obtained by Ficoll-diatrizoate density gradient centrifugation. Granulocyte/macrophage colony-forming units (CFU-gm) and erythroid burst-forming units (BFU-e) were cultured in agarose with conditioned media (CM) and/or interleukin 3 (IL-3), granulocyte colony-stimulating factor (G-CSF) and granulocyte/macrophage-CSF (GM-CSF). Treatment of BM MNC with 5 mM PME for 15 min at room temperature yielded a nucleated cell recovery of 44.8 +/- 5.0% (mean +/- SE; N = 8). CFU-gm were enriched 2.7-fold (range 2.0 to 4.8). Using CM or CM supplemented with G-CSF or GM-CSF has minimal effect on the enrichment. Leukocyte differentials revealed that 94.3 +/- 3.05% of the monocytes, as well as 91.2 +/- 1.60% of the cells in the neutrophilic maturation series were removed by PME. Incubation for 40 min in PME abolished CFU-gm formation. BFU-e were not enriched by the PME treatment. In contrast, 40 min incubation of PB MNC produced higher enrichment of CFU-gm than that obtained from 15 min of treatment, although lower cell recovery was obtained with the longer treatment time. In conclusion, we have demonstrated that phagocytic cells can be removed from BM or PB MNC by PME treatment.(ABSTRACT TRUNCATED AT 250 WORDS)     

A gene-controlling response of bone marrow progenitor cells to granulocyte-macrophage colony stimulating factors

The production of granulocytes and macrophages from progenitor cells in the bone marrow is controlled, in part, by a family of humoral regulators, termed colony stimulating factors (CSF). We have examined genetic factors controlling this process using in vitro cloning techniques. The inbred mouse strain LP/J showed elevated colony formation (CFU-C) in response to one subtype of CSF (G,M-CSF) compared to other strains of mice examined including the strain C57BL/6J. This variation resulted in a shift to the left of the CFU-C dose-response curve for LP/J. No difference between LP/J and C57BL/6J was seen with another subtype of CSF (CSF-1). Maximal CFU-C response was similar in the two mouse strains with both types of CSF, and mixing experiments with both types of CSF gave the same maximal level of colony formation as the individual CSF. (C57BL/6J X LP/J)F1 progeny exhibited a CFU-C dose-response curve to CSF-2 that was intermediate between the parental types, indicating additive inheritance. Genetic analysis of backcross progeny suggested that the variation in CFU-C response is probably determined by a single primary gene, although the variability of the colony formation assay has complicated interpretation of genetic studies. These results suggest that CSF-1 and G,M-CSF act independently on a single bone marrow progenitor cell population. The properties of the genetic variation for G,M-CSF response are consistent with an alteration in cellular receptors for G,M-CSF.     

Studies on colony formation in vitro by mouse bone marrow cells. II. Action of colony stimulating factor

An analysis was made of some of the processes involved in the stimulation by colony stimulating factor (CSF) of cluster and colony formation by mouse bone marrow cells in agar cultures in vitro. Colony formation was shown to be related to the concentration and not the total amount of CSF. The concentration of CSF determined the rate of new cluster initiation in cultures and the rate of growth of individual clusters. Colony growth depleted the medium of CSF suggesting that colony cells may utilise CSF during proliferation. Bone marrow cells incubated in agar in the absence of CSF rapidly died or lost their capacity to proliferate and form clusters or colonies. CSF appears (a) to be necessary for survival of cluster-and colony-forming cells or for survival of their proliferative potential, (b) to shorten the lag period before individual cells commence proliferation and (c) to increase the growth rate of individual clusters and colonies.     

The possible pathways of IL-2 stimulation of colony formation by bone marrow cells irradiated in vitro

The authors have made an attempt to find out the reasons of IL-2 stimulation of spleen colony growth by in vitro (1 Gy) irradiated bone marrow cells. It was shown that the effect of IL on haemopoiesis manifests itself with merely small radiation doses implying that the influence of the preparation makes the process of haemopoietic organ repopulation start at a higher level of cell survival, which is presumably related to a more active repair of radiation-induced CFUs damages: this leads, with other things being equal (e.g. proliferation rate and f factor), to a higher yield of colonies than it is observed with the recipients protected with the exposed bone marrow only.     

The effects of cyclosporin and hydrocortisone on human T lymphocyte colony formation

The immunosuppressive activities of two compounds, cyclosporin A and hydrocortisone, were evaluated using a human T lymphocyte colony assay. Both compounds produced a dose-related reduction in colony formation. With cyclosporin, concentrations of 1.0–100 μg/ml virtually abolished PHA-induced lymphocyte growth; as little as 0.01 μg/ml decreased clonal growth by 48%. Suppression was observed as late as 4 days after the addition of PHA. The addition of exogenous IL-2 did not completely restore clonal growth to normal. Similarly, hydrocortisone, in concentrations of 0.4 μg/ml, produced a 96% inhibition in clonal growth. Partial suppression could also be obtained if the drug was added as late as 4 days after PHA. Exogenous IL-2 completely reversed the inhibitory effects of hydrocortisone. By contrast, IL-1 was able to only partially restore growth potential. Parallel studies using TPA indicated that both immunosup-pressants inhibited responses to this mitogen. However, in plates containing both TPA and PHA, hydrocortisone failed to impair clonal growth.     

Stimulation by normal and leukemic mouse sera of colony formation in vitro by mouse bone marrow cells

Using a modification of the agar gel method for bone marrow culture, serum from various strains of mice has been tested for colony stimulating activity. Ninety percent of sera from AKR mice with spontaneous or transplanted lymphoid leukemia and 40–50% of sera from normal or preleukemic AKR mice stimulated colony formation by C57B1 bone marrow cells. Sera from 6% of C3H and 30% of C57B1 mice stimulated similar colony formation. The incidence of sera with colony stimulating activity rose with increasing age. All colonies were initially mainly granulocytic in nature but later became pure populations of mononuclear cells. Bone marrow cells exhibited considerable variation in their responsiveness to stimulation by mouse serum. Increasing the serum dose increased the number and size of bone marrow cell colonies and with optimal serum doses, 1 in 1000 bone marrow cells formed a cell colony. Preincubation of cells with active serum did not stimulate colony formation by washed bone marrow cells. The active factor in serum was filterable, non-dialysable and heat and ether labile.     

Remission of acute myeloid leukemia: studies of in vitro colony formation by bone marrow cells

Human bone marrow contains cells which form leukocyte colonies in semisolid culture media. Each leukocyte colony arises from a single colony-forming cell which is thought to be a unipotential stem cell, and which is subject to regulation in vitro by colony-stimulating factor. In acute myelogenous leukemia variable abnormalities in colony formation by marrow cells occur. Usually colony formation either fails to occur or the colonies that are formed are small and contain fewer than 50 cells. Similar abnormalities have been described in bone marrow dysfunction preceding overt leukemia. Usually remission of leukemia is accompanied by improved cloning by marrow cells. In this study three patients are reported in whom remission was associated with impaired cloning, and one of these patients has remained in continuous remission for a further 18 months. These observations suggest that remission status is not necessarily associated with repopulation of the bone marrow by normal hematopoietic cells.     

Antibody-mediated suppression of bone marrow colony formation in vitro.

Antisera to mouse brain reacts with hematopoietic stem cells in the mouse bone marrow. We have examined the effect of anti-mouse brain serum (AMBS) on the development of in vitro colonies from mouse bone marrow cells. The addition of 5% AMBS to the cultures markedly decreased the numbers of colonies formed to an average of 10% of the number obtained with normal rabbit serum. AMBS suppressed formation induced by colony stimulating factors (CSF) derived from three different sources; serum from endotoxin treated mice, mouse L-cell conditioned media, and human peripheral mononuclear cell conditioned media. The suppressive activity was quantitatively recovered in the IgG fraction of AMBS. Divalent F(ab')2 fragments were as effective as the intact IgG in decreasing colony formation. Fab fragments were not suppressive. These results suggest that colony formation is induced via a dynamic interaction between CSF and the progenitor cell membrane, and that antibody directed at cell membrane antigen(s) interferes with the generation of the induction signal.     

Diabetes alters subsets of endothelial progenitor cells that reside in blood, bone marrow, and spleen

Circulating endothelial progenitor cells (EPCs) derived from the bone marrow (BM) participate in maintaining endothelial integrity and vascular homeostasis. Reduced EPC number and function result in vascular complications in diabetes. EPCs are a population of cells existing in various differentiation stages, and their cell surface marker profiles change during the process of mobilization and maturation. Hence, a generally accepted marker combination and a standardized protocol for the quantification of EPCs remain to be established. To determine the EPC subsets that are affected by diabetes, we comprehensively analyzed 32 surface marker combinations of mouse peripheral blood (PB), BM, and spleen cells by multicolor flow cytometry. Ten subsets equivalent to previously reported mouse EPCs significantly declined in number in the PB of streptozotocin-induced diabetic mice, and this reduction was reversed by insulin treatment. The PI(-)Lin(-)c-Kit(-)Sca-1(+)Flk-1(-)CD34(-)CD31(+) EPC cluster, which can differentiate into mature endothelial cells in vitro, was the highest population in the PB, BM, and spleen and occurred 61 times more in the spleen than in the PB. The cell number significantly decreased in the BM as well as in the PB but paradoxically increased in the spleen under diabetic conditions. Insulin treatment reversed the decrease of EPC subsets in the BM and PB and reversed their increase in spleen. A similar tendency was observed in some of the major cell populations in db/db mice. To the best of our knowledge, we are the first to report spatial population changes in mouse EPCs by diabetes in the blood and in the BM across the spleen. Diminished circulating EPC supply by diabetes may be ascribed to impaired EPC production in the BM and to decreased EPC mobilization from the spleen, which may contribute to vascular dysfunction in diabetic conditions.     

Potentiation of bone marrow colony growth in vitro by the addition of lymphoid or bone marrow cells

Colony formation and growth in vitro by C57B1 mouse bone marrow cells were analysed following stimulation by a standard dose of serum colony stimulating factor. Under restricted conditions, colony crowding was observed to potentiate colony growth rates. The addition of thymic or lymph node lymphoid cells or nonviable bone marrow cells also potentiated colony growth. Extensive reutilisation of nuclear material by bone marrow colony cells was observed when labeled lymphoid and bone marrow cells were added to the culture system. The results provide evidence that lymphocytes can exert trephocytic effects on proliferating hematopoietic cells.     

Studies on colony formation in vitro by mouse bone marrow cells. I. Continuous cluster formation and relation of clusters to colonies

Colony formation in vitro by mouse bone marrow cells following stimulation by human urine was analysed over a 7-day incubation period. There was a linear increase with time in the number of cell aggregates (clusters) developing in such plates. Early in the incubation period all clusters were granulocytic although later macrophage clusters developed. Although most fully developed colonies were composed of macrophages, mapping and transfer studies showed that at least half of these had initially arisen early in the incubation period as granulocytic clusters.     

Enrichment of progenitor cells from human bone marrow by flow cytometry

Mononuclear cells, harvested from fresh human bone marrow specimens by density gradient separation, were suspended in phosphate buffered saline and analyzed by flow cytometry in terms of the forward and right angle scattering of the incident light. The rectilinear distribution, obtained by plotting the intensity of light scattered in the forward and right angle directions, contained three regions of interest in which the percentage of cells (Mean ± standard deviation) with respect to the total was as follows: Region 1: 17.6±9.9; region 2: 5.3±1.4; region 3: 71.7±9.4. Cells from each region were sorted by flow cytometry and plated in semi-solid agar containing cell conditioned medium supportive of myeloid colony formation. Cells from region 2 contained the majority of progenitor cells that gave rise to such colonies at a plating efficiency that rose in proportion to the extent by which the region 2 cells in samples was increased through sorting. This increase in plating efficiency was 6 to 43 fold. Thus, region 2 of the cytometric distribution of cells from normal, unstained human bone marrows was a good source of myeloid progenitor cells.     

Enhancement of gamma-glutamyl transpeptidase expression in bone marrow cells by colony stimulating factors

Studies on blood serum from mammary carcinoma (MC) hosts, which promoted gamma-glutamyl transpeptidase (GGT) expression by normal rat bone marrow cells in liquid culture, were extended to various granulocyte-macrophage colony stimulating factors (CSFs). GGT concentration per cell was found to increase (without change in total cell number) by incubation for 48 h with purified CSF-2 gamma and CSF-1 (but not interleukin-3), with human giant cell elaborated GM-CSF and L-cell conditioned medium, as well as with the 3 MC preparations (host serum, MC extract and MC conditioned medium). GGT-inducing ability (per milligram protein) ranked the 7 preparations in the same order as did their proliferative effect (number of colonies per milligram protein) in the standard mouse bone marrow agar culture system. The quantitative correlation between these two kinds of activities (linear for their logarithmic values) was highly significant, r = 0.976, p less than 0.001. The alkaline phosphatase concentration of bone marrow cells in liquid culture was also increased in the presence of the same 7 preparations, and this again was proportional (r = 0.985, p less than 0.001) to their colony stimulating potential.     

Inhibition of mouse bone marrow granulocyte-macrophage colony formation by factors derived from natural killer cells: an in vitro model for hybrid resistance

Investigations were performed to study whether soluble factors produced by NK-cells could mediate "hybrid resistance" in vitro. NK-cells enriched from spleens of B6D2F1 hybrid mice were incubated with parental B6 bone marrow, and the effect of the derived supernatants on the development of granulocyte-macrophage colony forming cells (GM-CFC) was assessed. Cell free supernatants obtained from low density cells (LDC) of B6D2F1 hybrids stimulated with bone marrow cells (BMC) from B6 mice inhibited GM-CFC formation. The inhibition was similar using B6, D2 or B6D2F1 bone marrow cells as the targets for GM-CFC growth. Our findings suggest that NK cells from F1 hybrid mice when stimulated with BMC from B6 mice release inhibitory factors, different from IFN-gamma and that this production may represent a mechanism of natural resistance to parental H-2b bone marrow grafts.