Comparative studies on the characteristics of proliferation and differentiation of spleen colony-forming cells

Using a single spleen colony transplantation technique and sex chromosome typing as a natural cytogenetic marker, most spleen colony-forming cells (CFC) in adult bone marrow or fetal livers of inbred LACA or C57 mice re-established hemopoiesis in lethally irradiated mice when the spleen colonies were sampled at 13 days after transplantation. However, most of the spleen colony-forming cells in the peripheral blood of normal mice possess little potential for proliferation and are less efficient in the re-establishment of hemopoiesis in lethally irradiated mice. The CFC population is heterogeneous in the mice. From the subsequent retransplantation of colonies from colony-forming cells in the peripheral blood, the simple assessment of spleen colony-forming units (CFU-s) content, based on the number of splenic colonies, does not reliably represent the content of hemopoietic stem cells.     

Heterogeneity of in vitro colony- and cluster-forming cells in the mouse marrow: segregation by velocity sedimentation.

C57BL bone marrow cells were separated on the basis of their sedimentation velocity at unit gravity and cell fractions cultured in agar using three types of colony stimulating factor (CSF). Colony-forming cells separated as a single peak (s equal 4.4 mm/hr) in cultures stimulated by mouse lung conditioned medium (CSFMLCM) or endotoxin serum (CSFES). Cluster-forming cells were separable into two peaks and the majority were larger than colony-forming cells (s equal 5.7 mm/hr). Partial segregation of colony-forming cells was observed according to the morphological types of colonies generated, large cells tending to generate macrophage colonies and small cells, granulocytic colonies. Large colony-forming cells were more responsive to stimulation by CSF than small cells. Human urine (CSFHU) appeared unable to proliferation of most small colony-forming cells. Colony-forming cells appear to be a highly heterogeneous population with intrinsic differences in responsiveness to CSF and with differing capacities to generate colonies whose cells differentiate to granulocytes of macrophages.     

Colony formation in agar by adult bone marrow multipotential hemopoietic cells

Erythroid colony formation in agar cultures of CBA bone marrow cells was stimulated by the addition of pokeweed mitogen-stimulated spleen conditioned medium (SCM). Optimal colony numbers were obtained when cultures contained 20% fetal calf serum and concentrated spleen conditioned medium. By 7 days of incubation, large burst or unicentric erythroid colonies occurred at a maximum frequency of 40–50 per 10⁵ bone marrow cells. In CBA mice the cells forming erythroid colonies were also present in the spleen, peripheral blood, and within individual spleen colonies. A marked strain variation was noted with CBA mice having the highest levels of erythroid colony-forming cells. In CBA mice erythroid colony-forming cells were mainly non-cycling (12.5% reduction in colony numbers after incubation with hydroxyurea or 3H-thymidine). Erythroid colony-forming cells sedimented with a peak of 4.5 mm/hr, compared with CFU-S, which sedimented at 4.25 mm/hr. The addition of erythropoietin (up to 4 units) to cultures containing SCM did not alter the number or degree of hemoglobinisation of erythroid colonies. Analysis of the total number of erythroid colony-forming cells and CFU-S in 90 individual spleen colonies gave a correlation coefficient of r = 0.93 for these two cell types. In addition to benzidine-positive erythroid cells, up to 40% of the colonies contained, in addition, varying proportions of neutrophils, macrophages, eosinophils, and megakaryocytes. Taken together with the close correlation between the numbers of CFU-S in different adult hemopoietic tissues, including individual spleen colonies, the data indicate that the erythroid colony-forming cells expressing multiple hemopoietic differentiation are members of the hemopoietic multipotential stem cell compartment.     

B lymphocyte colony-forming cells in the SJL/J mouse.

Mercatoethanol-induced B lymphocyte cloning in semi-solid agar has been used to study lymphocyte colony formation by cells from the SJL/J mouse thymus. From the 3rd month of life, the SJL/J mouse thymus. From the 3rd month of life, the SJL thymus develops an increasing frequency of cells forming B lymphocyte colonies in agar. The peak frequency in 6- to 12-month-old mice was one colony per 1000 to 2000 cultured thymus cells. In contrast, 10 to 100 times lower frequencies were found in the thymus of five other inbred mouse strains. The rise in B lymphocyte colony-forming cells correlated well with the age-related rise in Ig-positive cells and approximately 50% of the colony cells reacted with anti-micron-serum indicating the B lymphocyte nature of the colony cells. Colony-forming cells from the thymus showed higher sensitivity than colony-forming spleen cells to cortisol and irradiation. Cell transfer experiments and thymus grafting suggested that the increased frequency of colony-forming cells in the thymus is caused by development of special thymus-seeking B lymphocytes in ageing SJL/J mice. Finally, B lymphocyte colony-forming cells were found to be more frequent in the thymus, spleen, and lymph nodes from healthy aged mice than in lymphoid organs from mice with spontaneous reticulum cell tumors.     

The nature of cells generating human myeloma colonies in vitro.

Freshly explanted human myeloma cells formed colonies of monoclonal plasma cells in soft agar in the presence of medium conditioned by the adherent spleen cells of mineral oil-primed BALB/c mice. The medium showed peak activity at a dilution of 1:4. 2-mercaptoethanol or monothioglycerol was necessary for colony formation. Other thiols tested were ineffective in promoting colony growth. Colony-forming cells adhered to nylon wool, but not glass beads or plastic dishes. The presence of E-rosetting cells was not required for myeloma colony formation. Antibody prepared against a human myeloma cell line, RPMI 8226, reduced colony formation. These studies demonstrate the usefulness of this bioassay for determining functional properties of the myeloma colony-forming cell.     

COLONY-FORMING ABILITY OF BONE MARROW CELLS OF W ANAEMIC MICE ON MACROPHAGE LAYER FORMED IN PERITONEAL CAVITY OF MICE

The colony-forming ability of haematopoietic cells of W anaemic mice was examined on the macrophage layer formed in the peritoneal cavity of mice. Bone marrow cells of W anaemic mice formed a considerable number of colonies on the macrophage layer, notwithstanding they did not form any colonies in the spleen of the same recipients. As the colony-forming ability of the bone marrow cells was not reduced by the incubation with ³H-thymidine, most of the cells which formed colonies on the macrophage layer seemed to stay in G₀ state. The interrelationship between the spleen colony-forming cells, the macrophage-layer colony-forming cells, and in vitro colony-forming cells was discussed.     

The effect of erythropoietin on the growth and development of spleen colony-forming cells

The progressive growth and development of spleen colonies was studied in heavily irradiated host mice in which erythropoiesis was modified by various procedures. Erythropoietic activity in non-polycythemic hosts bearing spleen colonies was not increased by injections of exogenous erythropoietin. Detectable levels of erythropoietin were found in the heavily irradiated host mice suggesting that the failure of exogenous erythropoietin to modify erythropoiesis was because the host mice were already maximally stimulated by the high endogenous erythropoietin levels. Spleen colonies do not become erythroid in polycythemic mice. The injection of exogenous erythropoietin into heavily irradiated polycythemic hosts did not decrease the total number of spleen colonies produced by a given bone marrow transplant, as would be expected if erythropoietin acted directly on the colony-forming cells. Comparison of growth curves for colony-forming cells in the spleens of polycythemic hosts either receiving or not receiving erythropoietin indicated that the overall doubling time of colony-forming cells during the first ten days after transplantation was not changed by the daily injection of erythropoietin. These experiments are consistent with the concept that erythropoietin is necessary for the development of erythroid colonies. Erythropoietin acts upon some progeny of the colony-forming cell rather than the colony-forming cell itself.     

Nature of cells forming erythroid colonies in agar after stimulation by spleen conditioned medium

Erythroid colony formation in agar cultures of CBA cells was stimulated by the addition of pokeweed mitogen-stimulated C57BL spleen conditioned medium. Both 48-hour colonies ("48-hour benzidine-positive aggregates") and day 7 large burst or unicentric erythroid colonies ("erythroid colonies") developed, together with many neutrophil and/or macrophage colonies. In CBA mice, the cells forming erythroid colonies occurred with maximum frequency (650/10(5) cells) in 10- to 11-day-old yolk sac and fetal liver but were present also in fetal blood, spleen and bone marrow. The frequency of these cells fell sharply with increasing age and only occasional cells (2/10(5) cells) were present in adult marrow. A marked strain variation was noted, CBA mice having the highest levels of erythroid colony-forming cells. The erythroid colony-forming cells in 12-day CBA fetal liver were radiosensitive (DO 110-125 rads), mainly in cycle and were non-adherent, light density, cells sedimenting with a peak velocity of 6-9 mm/hr. These properties are similar to those of other hemopoietic progenitor cells in fetal tissues. The relationship of these apparently erythropoietin-independent erythroid colony-forming cells to those forming similar colonies after stimulation by erythropoietin remains to be determined.     

Soluble suppressor activity of concanavalin A-activated spleen cells on B-lymphocyte colony formation in vitro.

Supernates from concanavalin A (Con A)-activated mouse spleen cell cultures suppress the formation of B-lymphocyte colonies (BLC) in soft agar culture by 30 to 95%. Con A-induced BLC suppressive culture supernates can be heated at 80 °C for 1 hr without losing activity. The BLC suppressive activity is eliminated totally by trypsin treatment and partly by treatment with β-galactosidase. Activity is unaffected by treatment with DNAse, RNAse, and α-glucosidase. By ultrafiltration the BLC suppressive factor(s) was shown to have a molecular weight greater than 300,000. These data suggest that BLC suppression is mediated by a protein-carbohydrate complex. BLC suppression was obtained when normal spleen cells were preincubated in Con A-activated supernates for only 1 hr at 37 °C. BLC suppressor activity was absent in the supernatant fluid of Con A exposed anti-θ-treated spleen cells, nonadherent spleen cells, extensively washed spleen cells, and spleen cells from nude (athymic) mice suggesting that cells responsible for Con A-induced BLC suppression are adherent, fragile cells of the T lineage. Con A-activated spleen cell supernates do not suppress colony formation in soft agar by normal mouse granulocyte-macrophage precursors, by plasmacytoma cells, T-lymphoma cells, or by carcinoma cells. However, colony formation by Abelson's murine leukemia virus transformed B-lymphoma cells was suppressed by 95% suggesting a relationship between this immature B-lymphoma line and B-lymphocyte colony-forming cells. Con A-activated spleen cell supernates do not suppress lymphocyte activation in liquid culture by phytohemagglutinin, Con A, or lipopolysaccharide. Heat-treated supernates—which inhibited BLC development by 90–95%—did not suppress the plaque formation by spleen cells immunized in vivo or in vitro by sheep red blood cells.     

Ontogeny of B-lymphocyte function with respect to the heterogeneity of antibody affinity-1,2.

Neonatal liver or adult spleen was used as a source of B-lymphocytes in reconstituting lethally irradiated, syngeneic mice. Recipients were all given excess adult, syngeneic thymus cells and were immunized with dinitrophenylated bovine gamma globulin. The distribution of avidities of plaque-forming cells produced by immunized recipients of neonatal liver was highly restricted in comparison with animals reconstituted with adult spleen indicating a restriction of B-lymphocyte heterogeneity in the neonatal mouse.     

Detection of lymphoid leukemia colony-forming cells in abelson virus infected mice: Differences in inbred strains

BALB/c or DBA/2 mice were infected with Abelson murine leukemia virus (A-MuLV), pseudotype Molony murine leukemia virus (M-MuLV). Infection of these mice with 10⁴ focus-forming units of A-MuLV (M-MuLV) induced overt leukemia, detectable grossly or microscopically in 90% of the mice at 20–38 days. However, these methods did not detect leukemia at 17 days or before. Bone marrow cells from A-MuLV-infected leukemic or preleukemic mice were placed in tissue culture in a soft agarose gel. Cells from leukemic or preleukemic BALB/c mice grew to form colonies of 10³ cells or more, composed of lymphoblasts, whereas marrow cells from normal uninfected mice did not. Cells from these colonies grew to form ascitic tumors after intraperitoneal inoculation into pristane-primed BALB/c recipient. Colony-forming leukemia cells could be detected in the marrow of A-MuLV-infected mice as early as 8 days after virus incoluation. The number of colony-forming leukemia cells increased as a function of time after virus inoculation. Colony-forming leukemia cells require other cells in order to replicate in tissue culture. Normal bone marrow cells, untreated or after treatment with mitomycin-C, provide this “helper” function. Only in the presence of untreated or mitomycin-C treated helper cells was the number of colonies approximately proportional to the number of leukemia cells plated. Marrow cells from leukemic BALB/c mice form more colonies than those from leukemic DBA/2 mice. The number of colonies formed per 10³ microscopically identifiable leukemia cells plated was determined to be 2–3 for leukemic BALB/c mice and 0.3 for DBA/2 mice. Cocultivation of leukemic DBA/2 marrow cells with mitomycin-C treated normal BALB/c cells did not increase the number of colonies formed by the DBA/2 leukemic cells. Thus, the decreased ability of DBA/2 leukemia cells to form colonies appears to be a property of the leukemia cell population.     

Development of haematopoietic colonies on the macrophage layer formed in the peritoneal cavity of S1/S1d mice

The colony-forming ability of haematopoietic cells was examined on the macrophage layer formed in the peritoneal cavity of S1/S1d mice. The bone marrow cells of the congenic +/+ mice formed many macroscopic colonies on the macrophage layer of the S1/S1d mice although they did not form macroscopic colonies in the spleens of the same S1/S1d recipients. The size and the differentiation pattern of colonies on the macrophage layer of the S1/S1d mice were comparable to those of the colonies on the macrophage layer of the +/+ mice. There are two possible explanations for these results: (a) The microenvironmental defect of the S1/S1d mice has a more prominent effect on the development of spleen colonies than that of macrophage-layer colonies because 'Steel' locus may not be expressed significantly in the peritoneal macrophages or (b) because the cells that make colonies on the macrophage layer may be more differentiated cells than the multipotential stem cells that make colonies in the spleen.     

Experimental histoplasmosis capsulati in athymic nude mice

Granuloma formation in nude (nu/nu) mice and their heterozygous littermates (nu/+ mice) against Histoplasma capsulatum var. capsulatum infection was studied.A culture of H. capsulatum var. capsulatum, isolated from a granuloma in the nasal cavity of a Japanese patient, was used in this experiment. Sixteen specific-pathogen-free male nu/nu and 32 nu/+ mice were used in this study.The nu/+ mice were divided into two groups. Sixteen nu/+ mice in one group and 16 nu/nu mice were inoculated intraperitoneally with 10⁶ yeast cells of the fungus, those in the other group of nu/+ mice were inoculated intravenously with the same number of the yeast cells. Two mice out of each group were sacrificed 2, 3, 7, 11, 14, 18, 25 and 30 days after inoculation, and each of their organs was examined histopathologically. In addition, pieces of these tissues were cultured on Sabouraud's dextrose agar slants.In the nu/+ mice inoculated intraperitoneally, although the fungus was recovered from the spleen, kidney and lymph nodes during the initial course of the infection, lesions were not detected in their histopathological sections. In the nu/+ mice inoculated intravenously, colonies were recovered from all of the organs examined, other than the brain and thymus, 7 days after inoculation.Histopathologically, a few microfoci consisting chiefly of mononuclear cells with or without yeast cells were found in the liver sections 4 days after inoculation. Seven and 11 days after inoculation the number of lesions had increased. They had large accumulations of mononuclear cells. From day 14 on, almost all of the yeast cells had lost most of their staining affinity or were destroyed in the granuloma. From day 25 on, the granulomatous lesions changed gradually to fibrous tissue.In the nu/nu mice the fungus was readily recovered from the spleen, liver, kidney and lymph nodes. Histopathologically, a few microfoci consisting of mononuclear cells were present in the liver sections 4 days after inoculation. That is to say, during the initial course of infection granulomas were formed. In the liver, from day 7 on, the lesions were large and their number increased. However, there was a definite difference between the nu/nu and nu/+ mice. In the former, the yeast cells were not killed, and they continued to multiply within the granulomas. These granulomas were never transformed into fibrous tissue.     

Correspondence between the development of hemopoietic tissue and the time of colony formation by colony-forming cells

The development of a haemopoietic tissue and the time when colony-forming cells in it formed detectable colonies were studied with in vivo spleen colony-forming units (CFUs) and in vitro high-proliferation-potential colony-forming cells (HPP CFC). Cells that form colonies first are developmentally more mature than those doing so later. Marrow containing mature spleen colony-forming cells formed fewer cells in the femora of recipients than that which contained early colony-forming cells. The growth curve of developmentally early high-proliferation potential-colony-forming cells was steeper than that of later cells. The time period before colony-formation occurs is a property of the colony-forming cell and is not due to regulatory mechanisms in the animal or to regulatory cells in the haemopoietic stroma.     

Colony formation in agar by multipotential hemopoietic cells.

Agar cultures of CBA fetal liver, peripheral blood, yolk sac and adult marrow cells were stimulated by pokeweed mitogen-stimulated spleen conditioned medium. Two to ten percent of the colonies developing were mixed colonies, documented by light or electron microscopy to contain erythroid, neutrophil, macrophage, eosinophil and megakaryocytic cells. No lymphoid cells were detected. Mean size for 7-day mixed colonies was 1,800-7,300 cells. When 7-day mixed colonies were recloned in agar, low levels of colony-forming cells were detected in 10% of the colonies but most daughter colonies formed were small neutrophil and/or macrophage colonies. Injection of pooled 7-day mixed colony cells to irradiated CBA mice produced low numbers of spleen colonies, mainly erythroid in composition. Karyotypic analysis using the T6T6 marker chromosome showed that some of these colonies were of donor origin. With an assumed f factor of 0.2, the mean content of spleen colony-forming cells per 7-day mixed colony was calculated to vary from 0.09 to 0.76 according to the type of mixed colony assayed. The fetal and adult multipotential hemopoietic cells forming mixed colonies in agar may be hemopoietic stem cells perhaps of a special or fetal type.     

M-cholinergic receptors of B-lymphocytes during immune response in mice

The number of M-cholinergic receptors on spleen B-lymphocytes of CBA mice was determined using radioactive blocker 3H-Quinuclidinil benzilate. 3 and 4 days after the animals' immunization with ovalbumin the number of M-cholinergic receptors somewhat increased. Specific antigen attenuated M-cholinergic receptor expression on B-lymphocytes, most pronounced on day 4 after immunization, without affecting the receptor expression in control animals. Possible steric interaction between antigen-binding immunoglobulins and B-lymphocyte M-cholinergic receptors during immune response is suggested.     

The relationship between stem cell seeding efficiency and position in cell cycle.

The seeding efficiency of colony-forming cells from normal, regenerating and velocity-sedimented cycling and non-cycling narrow preparations was compared. Colony-forming cells in cycle were found to exhibit a 50% reduction in splenic seeding when compared to normal marrow or sedimented non-cycling cells. The results of this study indicate that the spleen colony assay underestimates the total number of colony-forming cells by a fraction which is directly related to the number of cells in cycle.     

THE RELATIONSHIP BETWEEN STEM CELL SEEDING EFFICIENCY AND POSITION IN CELL CYCLE

The seeding efficiency of colony-forming cells from normal, regenerating and velocity-sedimented cycling and non-cycling narrow preparations was compared. Colony-forming cells in cycle were found to exhibit a 50% reduction in splenic seeding when compared to normal marrow or sedimented non-cycling cells. The results of this study indicate that the spleen colony assay underestimates the total number of colony-forming cells by a fraction which is directly related to the number of cells in cycle.     

DEVELOPMENT OF HAEMATOPOIETIC COLONIES ON THE MACROPHAGE LAYER FORMED IN THE PERITONEAL CAVITY OF S1/S1D MICE

The colony-forming ability of haematopoietic cells was examined on the macrophage layer formed in the peritoneal cavity of S1/S1^d mice. the bone marrow cells of the congenic +/+ mice formed many macroscopic colonies on the macrophage layer of the S1/S1^d mice although they did not form macroscopic colonies in the spleens of the same S1/S1^d recipients. the size and the differentiation pattern of colonies on the macrophage layer of the S1/S1^d mice were comparable to those of the colonies on the macrophage layer of the +/+ mice. There are two possible explanations for these results: (a) the microenvironmental defect of the S1/S1^d mice has a more prominent effect on the development of spleen colonies than that of macrophage-layer colonies because ‘Steel’ locus may not be expressed significantly in the peritoneal macrophages or (b) because the cells that make colonies on the macrophage layer may be more differentiated cells than the multipotential stem cells that make colonies in the spleen.     

The cellular composition of hemopoietic spleen colonies

The cellular composition of individual hemopoietic spleen colonies has been studied using techniques which tested primarily for cell function rather than cell morphology. Erythroblastic cells were recognized by their capacity to incorporate radioiron, granulocytic cells by their content of peroxidase-positive material, and hemopoietic stem cells by their ability to form spleen colonies in irradiated hosts. It was found that, 14 days after the initiation of spleen colonies, the distribution of these cell types among individual colonies was very heterogeneous, but that most colonies contained detectable numbers of erythroblasts, granulocytes and colony-forming cells. An appreciable proportion of the cells in the colonies could not be identified as any of these three cell types. No strong correlations between numbers of erythroblasts, granulocytes and colony-forming cells in individual colonies were observed, though there was a tendency for colonies containing a high proportion of erythroblasts to contain a low proportion of granulocytes, and for colonies containing a high proportion of granulocytes to contain a higher proportion of colony-forming cells. An analysis of colonies which contained cells bearing radiation-induced chromosomal markers indicated that 83–98% of the dividing cells within 14-day spleen colonies were derived from single precursors.