Stimulation of heme accumulation and erythroid colony formation in cultures of chick bone marrow cells by chicken plasma

A fibrin clot culture system with high plating efficiency is described for the growth of erythroid cells from chick bone marrow. Erythroid colonies grown in the absence of adult chicken plasma (spontaneous colonies) were either benzidine-negative or weakly benzidine-positive. Colonies grown in the presence of chicken plasma were 90% strongly benzidine-positive and 40% more abundant than spontaneous colonies. Plasma from anemic chickens was more effective than control plasma in inducing heme accumulation (heme-stimulating activity) and in increasing the number of erythroid colonies (colony-stimulating activity). Spontaneous colonies from 48-h cultures were transformed into benzidine-positive colonies by exposing them for 6-10 h to chicken plasma.     

Diffusion chamber colony-forming unit (CFU-d): a primitive stem cell

Assay of hematopoietic precursor cells in diffusion chambers (DCs) implanted intraperitoneally in experimental animals provides a powerful tool for studying stem cell kinetics in vivo. In this system, the effect of cell migration (which complicates whole animal studies) is eliminated because the membranes utilized in the construction of the chambers are impermeable for cells, while permitting free passage of molecules present in the humoral phase of the host. As judged by light microscopy, conditions in the DC cultures primarily favor macrophage and granulocyte growth. However, the use of in vitro and in vivo subculture to further analyze chamber contents has demonstrated that the system supports proliferation of early hematopoietic progenitors. Additionally, cells capable of rescuing lethally irradiated mice proliferate in DC cultures. Development of the plasma clot DC technique has revealed that most of the growth occurs in colonies which are derived from single cells (CFU-d). Characterization of these cells indicates that they are at least as primitive as other colony-forming cells and, also based on subculture studies, can differentiate along several hematopoietic lineages. In addition to normal CFU-d, both embryonal and leukemic cells can give rise to granulocytes, macrophages, megakaryocytes and erythroid cells in the DC cultures. Evaluation of the effects of humoral factors on hematopoietic cell proliferation and differentiation in the system has led to the identification of both stimulators and inhibitors that may be different from the well-characterized cytokines. Thus, the system seems to be useful for detecting molecules controlling the most primitive stages of hematopoiesis. We believe that the DC culture technique holds enormous potential in the study of stem cell proliferation and differentiation in vivo.     

A quantitative assay for mouse granulocyte (CFU-g) and macrophage (CFU-m) precursors using plasma clots

Cytochemical procedures were used to identify and quantitate granulocyte and macrophage precursors from mouse bone marrow cells in plasma clot cultures. Excellent clonal morphology and cellular enzyme activity were obtained when using plasma clots as the support matrix and buffered formalin acetone as the fixative. For cytochemical identification, naphthol AS acetate esterase staining was used for macrophages and peroxidase for granulocytes. These enzyme properties were confirmed by inactivation studies with a variety of inhibitors, group specific chemical modifications, and pinocytotic affinity for horseradish peroxidase. When mouse bone marrow cells (3 X 10(4) cells/dish) were cultured in plasma clots with human placental or L-cell-conditioned medium, 70 to 110 colonies were produced. Both pure granulocyte (CFU-g) and pure macrophage colonies (CFU-m) were observed, but approximately 5% of the total colony number was composed of mixed granulocyte/macrophage colonies (CFU-gm). The number of plated cells correlated strongly with the colony number (0.990 less than r less than 0.999).     

GROWTH OF MOUSE AND HUMAN BONE MARROW IN DIFFUSION CHAMBERS IN MICE

Both murine and human bone marrow cells were cultured in plasma clots which were formed inside diffusion chambers implanted into cyclophosphamide- and saline-treated mice. After an initial fall, the number of mouse bone marrow cells and numbers of mouse myeloid stem cells (CFU-C) and agar cluster-forming units rose faster in the cyclophosphamide-treated animals. These hosts also favored formation of myeloid (CFU-D-G) and erythroid (CFU-D-E) colonies and myeloid clusters in the plasma clot. The number and growth rate of mouse CFU-D-G were higher than those of CFU-C from the same marrow population. These observations suggest the existence of humoral factors stimulating granulocyte progenitor cell replication and differentiation. At its best the increment of CFU-D-E number was equivalent to that caused by a single 0·1 unit erythropoietin dose. Culture of normal human marrow cells resulted in colonies in the plasma clot containing only granulocytes and macrophages. Cyclophosphamide-treated host animals were essential for human CFU-D-G development. Plating efficiency for human marrow myeloid colonies was better in the conventional in vitro agar cultures than in diffusion chambers.     

Influence of albumin on granulocyte and macrophage colony-forming efficiency

Mouse granulocyte and macrophage precursors were assayed in plasma clot and fibrin clot cultures, and the effect of bovine serum albumin (BSA) on colony formation was investigated. The number of granulocyte colonies (CFU-g) and clusters increased as the albumin concentration was increased and the number of macrophage colonies (CFU-m) and clusters concomitantly decreased. The albumin-mediated suppression of macrophage colony formation was overcome by the addition of more than 10% fetal bovine serum (FBS) to the plasma clot culture. The effect of BSA and fatty-acid-free BSA on colony-forming efficiency was also tested in fibrin clot cultures containing 10% FBS. Both BSA and fatty-acid-free BSA at a final concentration of 0.5-2% enhanced CFU-g colony formation, while both forms of BSA reduced the number of CFU-m colonies. However, neither BSA nor fatty-acid-free BSA had any effect on colony formation in FBS-free fibrin clot cultures, and only BSA enhanced colony formation when transferrin, linoleic acid, alpha-thioglycerol and dextran were added to the culture. The number of CFU-g (15.6 +/- 3.1) was higher in cultures containing BSA, transferrin, etc., than the number (9.8 +/- 2.5) in cultures without BSA and including transferrin, etc., than the number (9.8 +/- 2.5) in cultures without BSA and including transferrin, etc. (p less than 0.01). The number of CFU-m (32.0 +/- 6.8) in cultures containing BSA and the other four factors was lower than the number (72.2 +/- 5.6) in the culture without BSA (p less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunosuppression by spleen cells from Moloney leukemia. III. Evidence for a suppressor cell that is not the leukemic, virus-producing cell.

Spleens of mice bearing MuLV (Moloney)-induced leukemia contain cells that inhibit the antibody response of normal syngeneic lymphocytes to sheep RBC in Marbrook cultures. In order to determine whether these immunosuppressive cells are virus-infected tumor cells or normal cells we pretreated leukemic spleen cell suspensions with syngeneic mouse antiserum to Moloney leukemia antigen(s) (plus complement) and with rat anti-Moloney serum (plus complement). The cytotoxic treatment killed approximately 20% to 30% and 60% to 70% of the cells, respectively. The remaining viable cell population was tested for MuLV production (in an infectious center assay on S+L-fibroblasts), for lethal effect on newborn mice, and for immunosuppressive activity. After the treatment with anti-Moloney sera the number of MuLV-releasing cells decreased 10-fold and the leukemogenic potential in vivo decreased 100-fold as compared to leukemic spleen cells pretreated with nonimmune mouse and rat sera (plus complement). In contrast, the ability of the antisera-treated cells to inhibit anti-SRBC response remained undiminished. This indicates that, in part, the immunosuppressive cells in the leukemic spleen are normal, noninfected cells, involved, perhaps, in immune regulation.     

Growth of mouse and human bone marrow in diffusion chambers in mice. Development of myeloid and erythroid colonies and proliferation of myeloid stem cells in cyclophosphamide- and erythropoietin-treated mice.

Both murine and human bone marrow cells were cultured in plasma clots which were formed inside diffusion chambers implanted into cyclophosphamide- and saline-treated mice. After an initial fall, the number of mouse bone marrow cells and numbers of mouse myeloid stem cells (CFU-C) and agar cluster-forming units rose faster in the cyclophosphamide-treated animals. These hosts also favored formation of myeloid (CFU-D-G) and erythroid (CFR-D-E) colonies and myeloid higher than those of CFU-C from the same marrow population. These observations suggest the existence of humoral factors stimulating granulocyte progenitor cell replication and differentiation. At its best the increment of CFU-D-E number was equivalent to that caused by a single 0.1 unit erythropoietin dose. Culture of normal human marrow cells resulted in colonies in the plasma clot containing only granulocytes and macrophages. Cyclophosphamide-treated host animals were essential for human CFU-D-G development. Plating efficiency for human marrow myeloid colonies was better in the conventional in vitro agar cultures than in diffusion chambers.     

Immunosuppression by spleen cells from Moloney leukemia. Comparison of the suppressive effect on antibody response and on mitogen-induced response.

The inhibitory effect of cells from leukemic spleens on the immune functions of normal lymphocytes was studied. Suppressor cells were obtained as the nonadherent fraction (NA) from splenic tumors of mice infected with MuLV-Moloney. This fraction (NA MuLV- M) contained less than 10% membrane Ig-positive (Ig+) cells, 45 to 60% theta-positive cells (theta+) and 40 to 50% naught cells (theta-, Ig-). Similarly prepared fractions from normal control spleens (NAc) containing 75 to 90% theta+cells and less than 10% Ig+ and naught cells were utilized in control cultures. Addition of the NA MuLV- M cells into cultures (Marbrook system) of normal spleen cells with sheep red blood cells suppressed the specific antibody response determined by the number of hemolytic plaque forming cells (PFC). The PFC response was significantly suppressed at a suppressor cell to responder cell ratio of 1:100, and was completely abolished at a ratio of 1:10 or higher. The control NAc fraction showed some inhibitory effect only at high suppressor to responder ratios (1:2 or 1:1). In contrast, the suppressive effect of NAMuLV-M on mitogen-induced 3H-thymidine incorporation in normal B and T cells was much weaker. Very little, if any, suppression occurred at the ratio of 1:100 or 1:10, however, about 50% decrease in DNA synthesis was observed at the ratio 1:2 or 1:1. On the basis of this differential suppressive effect, it is suggested that leukemic spleen cells can suppress the function of immunocompetent cells by more than one mechanism.     

Regulation of angiogenesis in vitro by collagen metabolism

Summary The role of collagen in microvascular growth was investigated using the aortic ring model of angiogenesis. Collagen production by vasoformative outgrowths in plasma clot culture of rat aorta was either stimulated with ascorbic acid or inhibited with the proline analogue cis-hydroxyproline. Microvessels proliferating in the absence of ascorbic acid supplements became ectatic and developed large lumina. In contrast, newly formed microvessels in the presence of ascorbic acid remained small and maintained thin lumina throughout the angiogenic process. Biochemical studies demonstrated enhanced collagen production and deposition in cultures treated with ascorbic acid. Ultrastructural studies of these cultures showed a marked increase in newly formed interstitial collagen in the perivascular matrix and in regions of the plasma clot containing nonendothelial mesenchymal cells. Small microvessels with thin lumina similar to the ones observed in ascorbic acid-treated plasma clot cultures were obtained by growing aortic explants in gels of interstitial collagen in the absence of ascorbic acid. Inhibition of collagen production with the proline analogue cis-hydroxyproline had a marked anti-angiogenic effect in both plasma clot and collagen gel cultures. The anti-angiogenic effect of cis-hydroxyproline was abolished by addingl-proline to the culture medium, thereby restoring normal metabolism. These results support the hypothesis that angiogenesis is regulated by collagen production and suggest that the size of newly formed microvessels is influenced by the degree of collagenization of the extracellular matrix.     

Absence of erythroblastic islands in plasma clot culture and their possible reconstitution after clot lysis

Ultrastructural studies of erythroid colonies derived from human peripheral blood and growing in plasma clot culture have confirmed the absence of a macrophage inside each colony of erythroblasts. However, when macrophages and erythroblasts were liberated from the semisolid media by clot lysis, these two types of cells rapidly acquired intimate contacts, suggesting the reconstitution of any erythroblastic island. The possible significance of this phenomenon is discussed.     

Hemoglobin switching in sheep and goats. V. Effect of erythropoietin concentration on in vitro erythroid colony growth and globin synthesis

Erythroid colonies were generated in response to erythropoietin in plasma clot cultures of sheep and goat bone marrow cells. At low concentration erythropoietin only hemoglobin A (betaA globin) was synthesized in goat cultures, but at high concentrations 50% of the hemoglobin synthesized was hemoglobin C (betaC globin). This effect of erythropoietin on the expression of a specific beta globin gene was manifested only after 72 h in vitro and followed the development of erythroid colonies. Sheep colonies behaved differently from those of goat in that little or no betaC globin synthesis occurred even at high erythropoietin concentration. To investigate this difference, sheep marrow cells were fractionated by unit gravity sedimentation. The erythroid colony-forming cells sedimented more rapidly (3.5-6mm/h) than the hemoglobinized eththroid precursors (1-3.5 mm/h), suggesting that the colonies were formed from an early erythroid precursor, However, the colonies formed from the sheep marrow fractions synthesized only betaA globin even at concentrations of erythropoietin sufficient to stimulate betaC globin synthesis in goat colonies. Morphologically, the goat colonies were larger and more mature than those of the sheep. By 96 h in vitro three-fourths of the goat colonies contained enucleated red cells compared to only 3% of the sheep colonies. Thus, erythropoietin had an equivalent effect in stimulating erythroid colony growth from the marrow of both species although there were both biochemical and morphological differences between the colonies. Hemoglobin switching appeared to require exposure of an early precursor to high erythropoietin concentration, but the results with sheep marrow suggested that the rate of colony growth and cellular maturation might also be important.     

Modulation of microvascular growth and morphogenesis by reconstituted basement membrane gel in three-dimensional cultures of rat aorta: A comparative study of angiogenesis in Matrigel,collagen, fibrin,and plasma clot

Summary Rings of rat aorta cultured in Matrigel, a reconstituted gel composed of basement membrane molecules, gave rise to three-dimensional networks composed of solid cellular cords and occasional microvessels with slitlike lumina. Immunohistochemical and ultrastructural studies showed that the solid cords were composed of endothelial sprouts surrounded by nonendothelial mesenchymal cells. The angiogenic response of the aortic rings in Matrigel was compared to that obtained in interstitial collagen, fibrin, or plasma clot. Morphometric analysis demonstrated that the mean luminal area of the microvascular sprouts and channels was significantly smaller in Matrigel than in collagen, fibrin, or plasma clot. The percentage of patent microvessels in Matrigel was also markedly reduced. Autoradiographic studies of³H-thymidine-labeled cultures showed reduced DNA synthesis by developing microvessels in Matrigel. The overall number of solid endothelial cords and microvessels was lower in Matrigel than in fibrin or plasma clot. A mixed cell population isolated from Matrigel cultures formed a monolayer in collagen or fibrin-coated dishes but rapidly reorganized into a polygonal network when plated on Matrigel. The observation that gels composed of basement membrane molecules modulate the canalization, proliferation, and organization into networks of vasoformative endothelial cells in three-dimensional cultures supports the hypothesis that the basement membrane is a potent regulator of microvascular growth and morphogenesis. This work was supported by grants from the W. W. Smith Charitable Trust and grants CA14137 and HL43392 from the National Institutes of Health, Bethesda, MD.     

Use of the plasma coagulation method for ultrastructural analysis of biological specimens]

Biological particulate specimens, including Saccharomyces cerevisiae yeast, bovine spermatozoa and human blood cells (normal erythrocytes and leukemic cells) were processed for scanning and transmission electron microscopy using the coagulated plasma technique. The specimens were suspended in frozen and thawed plasma; later, coagulation was induced by adding CaCl2. The clot was cut into small pieces and processed as tissue fragments. The technique is an useful tool when processing biological particulate specimens for electron microscopy.     

Factors affecting the generation of mast cells from multipotential colony-forming cells

The cells responsible for the long-term in vitro generation of murine mast cells have been examined. Sequential analysis of all colony types obtained from cultures of spleen or bone marrow cells showed that only colonies derived from multipotential cells (mixed-erythroid colonies) or mast cell progenitors, contained cells responsible for mast cell generation in liquid cultures. Primary colony growth and subsequent maintenance of mast cells in liquid cultures was dependent upon pokeweed mitogen-stimulated spleen cell-conditioned medium (SCM). Mixed-erythroid colonies from 14-day cultures of spleen cells had the greatest capacity for mast cell generation. Analysis by clone splitting and transfer to high (20%) and low (2.5%) concentrations of SCM showed that the concentration of SCM used in either the primary colony culture or subsequent liquid culture phase altered both the proliferative capacity of the mast cells generated and the frequency of mast cell progenitors within individual mixed-erythroid colonies. Thus, mixed-erythroid colonies stimulated with 2.5% SCM contained the highest proportion of mast cell progenitors (34% of colonies) and when stimulated with 20% SCM, approximately fourfold higher numbers of mast cells were produced at weekly intervals from liquid cultures maintained in 2.5% SCM compared to parallel liquid cultures containing 20% SCM. These studies confirm the hemopoietic origin of mast cells and demonstrate that a factor(s) in SCM is able to modulate their proliferative potential.     

In vitro response of chicken spleen cells to sheep red blood cells

A modification of the Marbrook system for obtaining both primary and anamnestic responses from chicken spleen cells in vitro is described. The patterns of responsiveness of chicken spleen cell cultures resembled those previously described for the mouse. However, the requirement for normal chicken serum (NCS) to support the response could not be replaced by foetal calf serum (FCS). Cell survival, response kinetics, antigen dose requirements, antibody class, and temporal development of memory are described. The requirement for cooperation of B and T cells in the SRBC response was demonstrated by the use of specific anti-T and anti-B sera.     

Inhibition of marrow granulocytic colony formation by phytohemagglutinin

The effect of phytohemagglutinin (PHA) on the growth and number of granulocytic colonies (GC) developing on agar from bone marrow and spleen cells of normal and erythroleukemic mice inoculated with Rauscher leukemogenic virus was studied. Equal number of marrow cells from erythroleukemic mice produced twice as many colonies as those from normal mice. The number of GC developing from either normal and leukemic spleen cells was only 20% to 25% of that arising from marrow cells. The number of cells within each colony was significantly larger in GC formed by myelogenous leukemic cells than those arising from normal cells even though they had similar morphologic features. The addition of 100 μg of PHA per 10⁵ cells reduced the number of GC arising from normal and leukemic cells by 35% and 50%, respectively. Treatment with periodate which mainly inhibits its mitogenic activity, abolished the inhibitory effects of PHA on proliferation of granulocytic cells.     

Formation of eosinophilic-like granulocytic colonies by mouse bone marrow cells in vitro

Formation of granulocytic and macrophage colonies in agar cultures of mouse marrow or spleen cells was stimulated by the addition of medium from pokeweed mitogen-stimulated cultures of mouse spleen cells (PKW-CM). Approximately 5% of the colonies developing were large, dispersed granulocytic colonies (DG-colonies) composed of cells with eosinophilic cytoplasmic granules. The capacity to stimulate DG-colonies was shown by media conditioned by PKW-treated lymphoid and peritoneal cells but not by other cells or organ fragments. Velocity sedimentation studies indicated that cells generating DG-colonies were separable from cells generating regular granulocytic or macrophage colonies. DG-colonies did not survive if transfered to cultures containing other forms of CSF. The active colony stimulating factor in pokeweed mitogen-conditioned medium which stimulates DG-colony formation was antigenically distinct from the factor stimulating granulocytic and macrophage colony formation, was separable electrophoretically from the latter factor and on gel filtration had an apparent molecular weight of 50,000. Although the cells in DG-colonies have not been established to be eosinophils, DG-colonies represent an interesting new system for analysing further aspects of the control of growth and differentiation in hemopoietic populations.     

Similarities in long-term cultures of blood and bone marrow from patients with acute myelogenous leukemia

Dexter-type long-term cultures (LTC) were initiated with peripheral blood (PB) and/or bone marrow cells from 11 patients with acute myelogenous leukemia (AML), and 2 with myelodysplastic syndrome in blastic transformation. Marrow and PB cells from normal subjects served as controls. Assessment of nucleated cells and clonogenic progenitors in the adherent and nonadherent fractions of LTC revealed active hemopoiesis for greater than 5 wks in 4 of 8 cultures of AML blood, and 4 of 7 of AML marrow. The morphology and kinetics of nucleated cells and progenitors with putative normal (granulocyte-macrophage colony-forming units or CFU-gm), and abnormal (blast) phenotype in LTC from AML blood were similar to those from AML marrow, and adherent cells positive for collagen I and III and vimentin were found in both types of LTC. Growth of CFU-gm colonies ceased by wk 5-8 in AML cultures, significantly earlier than in LTC of normal marrow cells (survival of greater than 10 wks), which may indicate derivation of the CFU-gm from a transformed clone or deficiency of stromal function in the leukemic state. In most AML blood and AML marrow LTCs, growth of abnormal (blast) colonies continued until wk 4-6. This study demonstrates certain similarities of morphology and function between LTC of AML blood and AML marrow cells. LTC may provide a useful model for further analysis of circulating primitive hemopoietic progenitor cells in leukemic states.     

Improvement of human myeloma stem cell growth in a liquid culture system supplemented with phytohemagglutinin

A highly efficient cloning system for in vitro myeloma colony growth could be valuable for screening antineoplastic agents in resistant patients and for testing the effects of purging methods in the context of autologous bone marrow transplantation. In this paper we report the results of experiments intended to improve the myeloma cloning system in plasma clot originally described by Ludwig et al. We tested the effects of the addition of phytohemagglutinin (PHA), coupled with a transformation of the original plasma clot method into a liquid culture system. A statistically higher number of myeloma colonies was observed in the liquid system in the presence of PHA (20 cases, median 84.5 vs. 9.5; p = 0.005), whereas a single variant (either PHA alone or liquid system alone) did not determine any significant growth variation. The increase in the cloning efficiency was evident even in the cases characterized by low bone marrow plasma cell infiltration, suggesting that this method is suitable for the described purposes.     

Ultrastructural aspects of the primary in vitro antibody response of mononuclear cells in human blood

Investigations on the morphology of cells that participate in immune responses in vitro have been limited because the recovery and identification of immunocompetent cells growing dispersely in conventional liquid cultures are technically difficult and allow only the observation of individual antibody-forming cells. Here we used a system in which focal proliferation of antisheep erythrocyte antibody-secreting cells has been induced in semisolid cultures of peripheral blood mononuclear cells. By this method, intact colonies can be observed by light microscopy at the center of each hemolytic area and then processed for electron microscopy without disrupting the connections existing among the cells. Two types of colonies develop: type I colonies which grow deeply into the agar and contain cells that undergo a complete process of differentiation from blast to mature plasma cell, and type II colonies which grow more superficially and do not seem to be directly involved in antibody production.