Mononuclear phagocyte colony formation of human spleen cells in liquid culture

We found that mononuclear phagocytes formed a distinct number of clusters and colonies on the bottom of a culture dish 7 days later but granulocytes did not, when a large number of human spleen cells were cultured in liquid medium. In all gastric cancer bearers and patients with portal hypertension operated on, however, colony formation was restricted to spleen cells from patients with advanced gastric cancer and from a group of patients with portal hypertension. These spleen cells formed mononuclear phagocyte colonies without the help of exogeneous colony stimulating factor (CSF). We further demonstrated that the colony-forming cells were glass non-adherent and nylon wool adherent, and that spontaneous colony formation required cooperation between the colony-forming cells and colony-stimulating cells adherent to a plastic surface.     

KINETICS OF GROWTH OF HAEMOPOIETIC COLONY CELLS IN AGAR

Cell kinetic parameters of mouse granulocytic and mononuclear cells growing in colonies in agar cultures have been measured. Analysis of flash and continuous labelling studies with ³H-thymidine together with determinations of colony size, growth fraction and mitotic indices, gave the following values for the phases of the cell cycle: G₁= 6·3 1·6 hr, S = 5·8 ± 1·4 hr, G₂= 1·7 ± 0·1 hr and M = 0·7 ± 0·1 hr (42 ± 8 min). No difference in the cell cycle parameters of granulocytic and mononuclear cells were found in this study.
Colonies of different size from cultures of the same age group had similar labelling indices, indicating that the size of a colony is not a function of the rate of proliferation of cells in the colony. Rather, variation in colony size is probably representative of an initial delay in the onset of colony development.     

Analysis of colonies developing in vitro from mouse bone marrow cells stimulated by kidney feeder layers or leukemic serum

An analysis has been made of cell colonies developing in agar cultures from mouse bone marrow cells following stimulation either by neonatal kidney cell feeder layers or AKR lymphoid leukemia serum. Colonies arose by cell proliferation and were mixtures of granulocytic and mononuclear cells. Colonies stimulated by kidney feeder layers reached a mean size of 2000 cells by day 10 of incubation and remained predominantly granulocytic in nature. When bovine serum was substituted for fetal calf serum, cell colonies grew to a smaller size and lost their granulocytic nature, finally becoming almost pure populations of mononuclear cells. Colonies stimulated by AKR leukemic serum reached a mean size of 350 cells by day 10 of incubation. Although these colonies initially were granulocytic in nature, they finally became almost pure populations of mononuclear cells. The colony mononuclear cells actively phagocytosed carbon, and contained metachromatic granules probably derived from ingestion of agar. The mononuclear cells in these colonies may not have been members of the original colony, but may have been incorporated in the colony as it expanded in size, subsequently proliferating in the favourable environment of the colony.     

Characteristics of the differentiation of hematopoietic stem cells of the bone marrow in experimental lesions of the liver

The liver lesion in the CBA mice has been induced by administration of one of three agents five times every day; gamma-globulin fraction of antihepatocytotoxic serum in doses of 4.8 and 7.7 mg of protein per 100 g of body mass; gamma-globulin fraction of normal rabbit serum and bovine serum albumin in a dose of 4.8 mg of protein; three- four- or five-fold introduction of carbon tetrachloride in a dose of 0.5 ml per 100 g of body mass with oil (1:1) each three days; calibrated stenosis of the portal vein was produced. The total number of hemopoietic stem cells in the bone marrow was estimated by the colony-forming unit/spleen assay. Histological analysis of the colony-forming units was applied. The liver lesion was accompanied by a decrease in the ratio of the erythroid/granulocytic colonies.     

Primitive progenitor cells in the blood of patients with chronic granulocytic leukemia

We measured the number of blast colony-forming cells (Bl-CFC) in the blood of 11 patients with untreated chronic granulocytic leukemia (CGL). The culture system used detects three types of Bl-CFC (Types I, II and III) in normal marrow, of which Bl-CFC (I) are the most primitive and might represent the putative hemopoietic stem cell. The mean numbers of Bl-CFC (I) in CGL blood, normal bone marrow and normal blood were 134 +/- 29 (+/- SEM), 127 +/- 21 and 1.5 +/- 0 respectively per 1 X 10(6) mononuclear cells. These findings are consistent with the concept that CGL is due to a primary increase in stem cell numbers with secondary increases in committed progenitor and leukocyte numbers.     

Clonal growth in vitro by mouse Kupffer cells.

Mouse liver Kupffer cells were induced to proliferate and form discrete colonies of mononuclear phagocytes in vitro. These colony-forming cells from the liver are similar to other mononuclear phagocyte colony-forming cells in that they require a colony-stimulating factor present in medium conditioned by L cells for proliferation in vitro. Cells in the colonies were phagocytic and had IgG receptors on the membrane. For this class of colony-forming cells, the D₀ value to gamma irradiation in vitro was 108 rads.     

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.     

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.     

Changes in membrane-bound aminopeptidase on bone marrow-derived macrophages during their maturation in vitro

Myeloid colonies obtained by culturing mouse bone marrow cells with mouse lung conditioned medium were kept for up to 21 days in culture and the aminopeptidase content in single cells measured after staining with leucine 4-methoxy-2-naphthylamide. The enzyme was detectable only in mononuclear and not in granulocytic cells. The number of cells carrying the enzyme and the concentration of the enzyme in the mononuclear cells taken from whole dishes or single colonies increased remarkably but not uniformly from 7 days to maximal values at 13 days of culture, and then decreased again. The timing varied for individual colonies. Maximal enzyme concentrations were found in cells intermediate between the center and the fringe of a colony. However, most cells in a given colony showed concentration increases up to 13 days of culturing. During its life span in culture the mononuclear cell appears to gain aminopeptidase at the cell membrane and lose it again prior to death.     

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.     

Hemopoietic progenitor cells of W anemic mice studied in vivo and in vitro

The proliferation and differentiation of hemopoietic cells from genetically anemic W^v/W^x,W/W^v, and W^v/W^v mice, and from nonanemic carrier W/+, W^b/+, and W^v/+ mice have been evaluated in vivo by transplantation techniques and in vitro by the agar gel culture method. Marrow from anemic and carrier mice contained progenitor cells which were decreased in number and formed small, often rudimentary, colonies in the spleens of irradiated recipient mice. Proliferation and differentiation of both erythropoietic and leukopoietic progenitor cells were delayed and reduced, but erythropoiesis was more severely affected than leukopoiesis. The severity of the hemopoietic impairment was gene-dose dependent. The W gene effect on leukopoietic progenitor cells was not secondary to anemia or to abnormal erythropoiesis. The marrow cells of anemic and carrier mice which form colonies of granulocytic and mononuclear cells in vitro were neither decreased in number nor impaired in proliferation and differentiation. Hypertransfusion of red blood cells increased the frequency of in vitro colony-forming cells, but not that of in vivo progenitor cells. The data demonstrate that colony-forming cells which proliferate in the agar gel cultures in vitro are distinct from the in vivo colony-forming cells and suggest that the former are primitive members of the granulocytic cell line. Perhaps in vitro CFU are in an intermediate stage of differentiation between in vivo CFU and myeloblasts, analogous to that which has been suggested for the erythropoietin-sensitive cell in the red cell series. W mutant alleles appear to act, therefore, at or very near the beginning of hemopoietic differentiation.     

Mononuclear phagocyte maturation: a cytotoxic monoclonal antibody reactive with postmonoblast stages

The rat IgM monoclonal antibody B23.1 was found to bind to mononuclear phagocytes that had matured beyond the monoblast stage. Macrophages from several anatomical sites, elicited by different means, as well as those cultured from bone marrow precursors, bound B23.1 antibody. The increase, with time, of B23.1-positive cells in the nonadherent fraction of cultured bone marrow paralleled that of immature mononuclear phagocytes as detected by esterase staining. Treatment of freshly explanted bone marrow cells with B23.1 and complement did not reduce the number of macrophage colony-forming cells (monoblasts) in that population. Treatment with B23.1 antibody alone did not alter the activation of macrophages for tumor cell killing; however, with added complement, B23.1 reduced activated macrophage-mediated cytotoxicity to background levels. In similar studies B23.1 and complement did not affect antibody production by B cells, the cytotoxic capacity of T cells, or NK cell-mediated lysis. These data indicate that antibody B23.1 is useful for either the detection or elimination of mouse mononuclear phagocytes from the promonocyte stage to that of the mature macrophage.     

Endotoxin-induced size change in bone marrow progenitors of granulocytes and macrophages

Injection of 5 μg endotoxin to adult C₅₇BL mice caused a marked increase in the sedimentation velocity of granulocytic and macrophage progenitor (colony-forming) cells in the bone marrow. This change was maximal two days after injection and was not accompanied by corresponding changes in total marrow nucleated cell populations. The endotoxin-induced shift was not dependent on the presence of the thymus but did not occur in mice challenged after preinjection with endotoxin. No changes in buoyant density, cell cycle status, pattern of differentiation and responsiveness of granulocytic and macrophage progenitor cells were observed after the injection of endotoxin. The increased sedimentation velocity of progenitor cells appears to indicate an increase in cell volume but the mechanisms involved have not been identified.     

A non-rotational, computer-controlled suspension bioreactor for expansion of umbilical cord blood mononuclear cells

The proliferation and differentiation characteristics of umbilical cord blood mononuclear cells were examined in a non-rotational suspension bioreactor with a fishtail mixer. The system consisted of a glass vessel, a mixer that moved vertically, a data acquisition and control system to continuously monitor pH, temperature and dissolved O₂. The bioreactor provided superior expansion of total HSCs and not total cell number, as well as expression of stemness-related genes which followed with increasing in number of colony-forming cells during 14 days of culture compared to T -lask culture. Vertical agitation thus reduces the total cell number, which may be related to increased shear stress, but has no effect on HSC function.     

In vitro natural cell-mediated cytotoxicity against Candida albicans: macrophage precursors as effector cells

Bone marrow cells, cultured in L-929 CSF, consist of cells of granulocyte and macrophage lineages. Cells of the granulocyte lineage are known to be cytotoxic for Candida albicans. In this paper we report that macrophage precursor cells also display strong cell-mediated cytotoxicity against the yeast form of the dimorphic fungus C. albicans. The macrophage precursors responsible for this activity are nylon wool-nonadherent, nonphagocytic cells and lack asialo GM1 surface antigen. A purified population of macrophage precursors (greater than 95%) was obtained by means of Percoll density centrifugation. The interaction of these purified effectors with the target yeast cells was analyzed at a single cell level, and their activity was compared with that displayed by cells of the granulocytic series derived from the same bone marrow culture. Macrophage precursor cells proved to be more effective in binding the target cells and showed the same killing ability as the granulocytes: macrophage precursors were not damaged by contact with the target, in contrast to that which happened with granulocytes. In a long-term colony-forming unit assay, in fact, granulocytic cells showed a decrease over time in their ability to inhibit the growth of C. albicans, probably due to cell damage and death after the interaction with the target. In contrast, no loss of activity was observed with the macrophage precursor fraction. The same macrophage precursor cells also proved able to exert good natural killer activity against YAC-1 lymphoma cells, but not against P815 mastocytoma cells, as reported previously. The macrophage precursor cells, when cultivated in vitro to mature macrophages, lost completely their natural cytotoxicity against C. albicans and YAC-1 cells. The implications of these findings, as well as the possible role in vivo of such a precursor cell population during an infection, are discussed.     

Infection of bone marrow cells in vitro with FLV: Effects on stem cell proliferation,differentiation and leukemogenic capacity

Long-term cultures of proliferating hematopoietic stem cells derived from bone marrow permit the study of the interaction between murine leukemia virus (MuLV) infection and the proliferation and differentiation of stem cells. We have used this system to analyze the replication of different biological variants of MuLV in bone marrow cells; the effect of MuLV infection upon pluripotent stem cell (CFU-S) proliferation; and the effect of MuLV on differentiation of CFU-S along different hematopoietic pathways. Two MuLV variants were studied in detail: the Moloney strain of lymphatic leukemia virus (Mol-MuLV) and the erythroleukemic Friend virus complex (FLV) consisting of the lymphoid leukemia helper virus and the defective spleen focus-forming virus (SFFV). Mol-MuLV and its sarcoma virus pseudotype, MSV(Mol-MuLV), replicate efficiently in the bone marrow cultures; however, CFU-S are lost more readily than in uninfected cultures, and the cultures are soon represented by a majority population of mononuclear macrophages. On the other hand, infection with FLV produces a prolonged survival of the spleen colony-forming cells, CFU-S, and CFU-C (the committed granulocytic precursor cells). Production of erythroleukemogenic SFFV is maintained in these cultures for more than 40 weeks. No erythroblastic differentiation was observed in vitro, however, neither erythroblast precursor cells (CFU-E) nor hemoglobin-producing cells could be detected. This suggests that the target cell for FLV is an earlier precursor cell.     

INFLUENCE OF AGE AND ANTIGENIC STIMULATION ON GRANULOCYTE AND MACROPHAGE PROGENITOR CELLS IN THE MOUSE SPLEEN

The frequency and proliferative activity of granulocytic and macrophage progenitor cells were determined in the spleens of C₅₇BL, BALD/c, NZB and CBA mice. These cells were detected by their capacity to form granulocytic and/or macrophage colonies ( in vitro colony-forming cells, CFC) in agar culture. In vitro CFCs were low in frequency in the adult spleen (4–28/10⁵ cells) compared with the bone marrow (180–280/10⁵ cells). However, the neonatal spleen, both in germfree and conventional mice, contained high levels of in vitro CFCs. From the low suiciding index with tritiated thymidine and the small numbers of cluster-forming cells in relation to colony numbers, many in vitro CFCs in the adult C₅₇BL spleen appear to be in a non-cycling state. The level and activity of in vitro CFCs were extremely low in the spleen of adult germfree CBA mice but were greatly increased in conventional mice following the injection of a bacterial antigen.     

Studies on in vitro colony formation by mouse bone-marrow cells using different sources of colony-stimulating factor

Summary Conditioned media of a primary mouse embryo and a mouse cell line were compared as sources of colony-stimulating factor. The incorporation of embryo cell conditioned medium into semisolid cultures of mouse bone-marrow cells induced the formation of a larger number of in vitro colonies than did the addition of equal volumes of LM cell conditioned medium. This finding did not appear to be the result of quantitative differences in the levels of C.S.F. between the sources since concentration of the LM cell conditioned preparation did not enhance effectively the number of colonies produced. Both the colonial morphology and the cellular components of the developing colonies were found to differ in accordance with the C.S.F. source employed for stimulation. Colonies that developed under the influence of embryo cell conditioned medium were typically larger and more disperse than were those produced in cultures stimulated with the LM cell conditioned source. The latter colonies were smaller, more compact and contained fewer cells. Differences also were noted in the relative proportion of granulocytes to mononuclear cells comprising the colonies. Those colonies stimulated with LM cell conditioned medium rapidly underwent a transition from primarily a granulocytic composition to one comprised principally of mononuclear cells. Cultures stimulated with embryo cell conditioned medium contained a greater number of granulocytic colonies which persisted for a protracted period during cultivation. The addition of 2-mercaptoethanol to cultures stimulated with embryo cell conditioned medium increased the number of colonies produced. Such synergy did not occur in cultures stimulated with the LM cell conditioned medium. Supported by United States Public Health Service Research Grant CA 13752.     

T-cell depletion of bone marrow does not inhibit in vitro hematopoiesis

One approach to overcome the problem of histoincompatibility in bone marrow transplantation is to use T cell depleted marrow from a haploidentical donor in an attempt to ameliorate graft-versus-host disease. Since the T cell requirements for normal hematopoiesis are uncertain, experiments were performed to study the effects of E rosette-T cell depletion on in vitro growth of hematopoietic progenitor cells. Marrow mononuclear cells were cultured in a modified CFU-GEMM assay before and after T cell depletion. The number of 7 day granulocytic and erythrocytic colonies, and 14 day granulocytic, erythrocytic and mixed colonies were enumerated and expressed in terms of colonies per 10(5) non T cells plated. T cell depletion did not result in decreased proliferation of any of these progenitors save possibly for 14 day granulocytic colonies in one of four experiments. In two cases, T cell depletion resulted in increased growth of progenitor cells. Three of four patients transplanted with T cell depleted haploidentical marrow cells engrafted. It is concluded that E rosette depletion of T cells from marrow does not decrease the potential of these cells to establish hematopoiesis in vitro or in vivo.