Evaluation of the marrow culture on the macrophage layer covering intraperitoneally implanted membrane as an assay for hemopoietic progenitor cells

When cellulose acetate membranes are implanted into abdominal cavity of mice they turn into a foreign body overgrown with macrophages. Such macrophage layer has been shown by other authors to be able to support the growth of hemopoietic colonies formed by intraperitoneally injected hemopoietic cells. This study confirms and extends this observation by showing that both granulopoietic and erythropoietic colonies may be observed. The number of colonies grown is in linear correlation with that of injected hemopoietic cells. The frequency of erythropoietic colonies was greatly enhanced by blood letting of the host mice. Colony forming cells were most numerous in the bone marrow then in the spleen and peripheral blood and hardly in the thymus. Prior irradiation of the host mice was essential for obtaining colony growth and the optimal dose was determined to be 6.0 Gy. This technique opens the way to studies into hemopoietic progenitor cells for laboratories having no sophisticated tissue culture equipment and where necessary reagents are easily available.     

Postnatal liver hemopoiesis in mice: generation of pre-B cells, granulocytes, and erythrocytes in discrete colonies

Morphologic analysis of hemopoietic tissue in mouse liver reveals the persistence of erythropoietic, granulopoietic, and lymphopoietic activity for approximately 2 wk after birth. Near the end of the first postnatal week, we noted a remarkable reorganization of the hemopoietic cells that was characterized by a transition from a diffuse distribution of mixed erythroid, myeloid, and lymphoid elements to a focal pattern of discrete hemopoietic colonies scattered among the cords of hepatic parenchymal cells. Each hemopoietic focus contained cells progressing along a single differentiation pathway (i.e., erythroid, myeloid, or lymphoid cells). Megakaryocytes were seen as solitary cells surrounded by hepatocytes. This pattern of colonization was observed in all strains of mice examined. In the livers of mice with known hemopoietic defects, however, differences were found in the duration of postnatal hemopoiesis. Accessory cells with macrophage-like features were consistently observed in erythropoietic foci, but were rarely seen in lymphoid foci. The latter were formed by pre-B cells identifiable by the presence of cytoplasmic mu-heavy chains and the absence of light chain expression. The occurrence of discrete colonies of erythroid, myeloid, and pre-B lymphoid cells in the postnatal liver suggests that each is derived from a single, committed precursor cell. This anatomical compartmentalization according to cell type offers a useful model system for analysis of hemopoietic differentiation and of the generation of clonal diversity among B lineage cells.     

Erythropoietic progenitors capable of colony formation in culture: state of differentiation

The differentiated state of mouse erythropoietic progenitor cells (CFU-E), detected by their ability to form erythropoietin-dependent colonies in vitro, has been investigated. Transfusion-induced plethora was found to reduce the population size of CFU-E in both spleen and femoral marrow, which indicates that a significant number of CFU-E arise by differentiation processes that are themselves erythropoietin-dependent. Individual spleen colonies were found to be heterogeneous in their content of CFU-E, and the numbers of CFU-E per colony were not correlated either positively or negatively with the numbers of granulocyte-macrophage progenitors (CFU-C) present in the same colonies. The absence of a negative correlation between CFU-E and CFU-C indicates that the erythropoietic and granulopoietic pathways of differentiation are not mutually exclusive within individual spleen colonies. The numbers of CFU-E per spleen colony were also found to vary independently of the numbers of pluripotent stem cells (CFU-S) per colony; in contrast, as found previously, the numbers of CFU-C and CFU-S per colony were positively correlated. These results indicate that more randomizing events separate CFU-E from CFU-S than separate CFU-C from CFU-S, and are consistent with the view that CFU-E occupy a position on the erythropoietic pathway of differentiation that is more remote from the pluripotent stem cells than is the corresponding position of CFU-C on the granulopoietic pathway.     

Effect of Erythropoietic Stimulation of the Chamber Host On the Growth of Haemopoietic Colonies In Plasma Clot Diffusion Chambers (PCDC)

Murine marrow cells were cultured in Millipore diffusion chambers implanted into the peritoneal cavity of variously conditioned murine hosts. Preirradiation (350 cGy), bleeding (0.5 ml) and phenylhydrazine injection (75 mg/kg i.v.) when performed together on the chamber host, induced better growth of erythropoietic and granulopoietic colonies inside the PCDCs than either of these manoeuvres alone. Small erythrocytic colonies (CFU-E derived) and small granulocytic colonies were observed at day 3 of marrow culture. Erythropoietic bursts and large granulocytic colonies were observed at day 8 of chamber culture. Colonies of macrophage-like cells, fibroblast-like cells, mixed erythro-granulopoietic colonies and megakaryoblasts were observed less regularly in chambers incubated in these conditions. the study provides a standardized, relatively reproducible PCDC culture system for studies of both erythro- and granulopoiesis, and does not require a hypoxic chamber.     

Effect of erythropoietic stimulation of the chamber host on the growth of haemopoietic colonies in plasma clot diffusion chambers (PCDC)

Murine marrow cells were cultured in Millipore diffusion chambers implanted into the peritoneal cavity of variously conditioned murine hosts. Preirradiation (350 cGy), bleeding (0.5 ml) and phenylhydrazine injection (75 mg/kg i.v.) when performed together on the chamber host, induced better growth of erythropoietic and granulopoietic colonies inside the PCDCs than either of these manoeuvres alone. Small erythrocytic colonies (CFU-E derived) and small granulocytic colonies were observed at day 3 of marrow culture. Erythropoietic bursts and large granulocytic colonies were observed at day 8 of chamber culture. Colonies of macrophage-like cells, fibroblast-like cells, mixed erythro-granulopoietic colonies and megakaryoblasts were observed less regularly in chambers incubated in these conditions. The study provides a standardized, relatively reproducible PCDC culture system for studies of both erythro- and granulopoiesis, and does not require a hypoxic chamber.     

Differences between exogenous and endogenous hemopoietic spleen colonies

Histologic examination of the spleens in RFM/Un mice killed 6 to 9 days after 350 to 800 R whole-body x-irradiation revealed hemopoietic colonies, the numbers of which decreased exponentially with increasing radiation dose. In such animals, myelocytic colonies were the predominant type on the sixth to the eighth day. However, they decreased in number with time, being fewer than erythropoietic colonies by the ninth day after irradiation. In C57BL mice, erythropoietic colonies were relatively more numerous, markedly predominating on both the eighth and the thirteenth days. RFM/Un mice injected with nonirradiated syngeneic bone marrow cells within 24 hours after 750 R developed colonies, predominantly of erythropoietic and undifferentiated types, the numbers of which were proportional to the numbers of marrow cells injected. The number of colonies formed from exogenous marrow cells increased slightly between the sixth and ninth days after inoculation, possibly because of a greater likelihood of counting them due to an increase in their size.     

Effect of estradiol on splenic repopulation by endogenous and exogenous hemopoietic cells in irradiated mice

Estradiol treatment of irradiated mice during repopulation of their spleens by endogenous hemopoietic cells reduced the number of myelocytic colonies and increased the numbers of erythropoietic and undifferentiated colonies. The inhibitory effects of the hormone on myelopoiesis were not dependent on stimulation of erythropoiesis, since they occurred in the absence of erythropoiesis in mice made polycythemic by hypertransfusion. Treatment of bone marrow donors with estradiol reduced the ability of their marrow cells to form spleen colonies, particularly reducing the proportion of myelopoietic colonies relative to the total number of colonies of all types. Conversely erythropoietic colonies, though reduced in absolute number, were increased in relative number. Such treatment also decreased the volume and cell content of the marrow cavity through stimulation of endosteal bone formation. Estradiol treatment of lethally irradiated recipient mice did not detectably alter the total numbers or types of hemopoietic spleen colonies formed in these animals from transplanted marrow cells; however, without estradiol treatment, myelopoietic colonies were so few and erythropoietic colonies so numerous that the effects of the hormones may have been undetectable by the methods employed. The sex of the donor or recipient mouse did not affect the numbers or types of colonies formed, suggesting that endogenous levels of estradiol were too low to exert effects dectectable by the methods used. However, since our mice were only 8 weeks old, the data do not exclude the possibility that older female mice, with higher levels of estradiol, would have differed from males in relative numbers of myelopoietic as compared with erythropoietic colonies.     

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.     

人卵黄囊造血的探讨

采用卵黄囊组织切片、涂片的形态学、细胞化学染色、造血干/祖细胞体外培养及CD_(34)单克隆抗体免疫荧光检测等方法研究表明:人卵黄囊中存在造血岛,造血岛内由于造血微环境的特点致使此期造血主要向红系分化。血岛中检测出CD_(34)~ 细胞,比例高于胎肝及成人骨髓,干/祖细胞于体外培养形成红系集落。结论:人胚胎期造血源于卵黄囊。     

Dependence of the functional activity of immunocompetent mouse spleen cells on their hemopoietic microenvironment

Accumulation of erythropoietic, granulopoietic cell elements, a change in the ration and absolute count of the T, B cells, and "null" lymphocytes, as well as a sharp inhibition of primary immune response were found in the spleen of CBA mice treated with antierythrocyte sera. The inductive phase of immunogenesis proved to be sensitive to the action of antierythrocyte sera. The data obtained apparently demonstrated the existence of a functional relationship between the immunocompetent spleen cells and their non-lymphoid hemopoietic microenvironment.     

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.     

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.     

In vitro effect of glucan on mouse hemopoietic committed progenitor cells

In vitro methylcellulose clonal cell culture assays of granulopoietic and erythropoietic colonies were used to study the primary effect of glucan on the hematopoietic stem cells. Addition of glucan to the cultures inhibits the formation of colony-forming units-erythrocytic (CFU-E), enhances the production of burst forming units-erythrocytic (BFU-E) and has no effect on colony-forming unit-culture (CFU-C). These results indicate that glucan has a direct effect on late and early erythroid precursor cells.     

Effects of lymphocytes from the thymus and lymph nodes on differentiation of hemopoietic spleen colonies in irradiated mice

Hemopoietic colonies were counted macroscopically and microscopically in spleens of hybrid mice seven or eight days after they had been irradiated and given parental bone marrow in donor-host combinations exhibiting poor growth. Colonies counted microscopically were classified as to differentiation pathway. Lymphocytes from the thymus or lymph nodes were injected into some recipients at several different dosages and lymphocyte: bone marrow (L:B) ratios. In confirmation of earlier work it was found that thymocytes increased the number and size of colonies in recipients of marrow. A shift of differentiation toward granulopoiesis was also seen when thymocytes were given, although erythropoietic colonies were still the most frequently seen type except at very high L:B ratios. Lymph node lymphocytes shifted the pattern more markedly toward granulopoiesis, even at low L:B ratios. When lymphocytes from either source were given without marrow, only a few colonies could be found in recipients, and if differentiated they were almost exclusively granulopoietic. Irradiation (900 R) of lymphocyte donors reversed the shift so that a normal pattern of differentiation, like that resulting from marrow alone, was seen; irradiated lymphocytes were nonetheless capable of augmenting the size and total number of hemopoietic colonies.     

Transient erythropoietic spleen colonies: effects of erythropoietin in normal and genetically anemic W/Wv mice.

Properties of the cells (TE-CFU) that give rise within four to six days to transient endogenous erythropoietic spleen colonies in irradiated mice have been investigated. The results obtained indicate that (1) erythropoietic maturation within such colonies is highly erythropoietin-dependent, (2) the population size of TE-CFU is not erythropoietin-dependent, (3) initial exposure to a high dose of erythropoietin followed by continuing exposure to lower doses is required for maximal efficiency of colony formation by TE-CFU, (4) successful transplantation of TE-CFU has not been achieved, but they appear among the progeny of transplanted hemopoietic cells, (5) TE-CFU are defective in mice of genotype W/Wv. These findings are consistent with the view that the TE-CFU assay detects a class of early erythropoietin-sensitive progenitor cells committed to erythropoietic diffferentiation, rather than "abortive" colony formation by pluripotent stem cells.     

Microenvironmental studies of pre-B and B cell development in human and mouse fetuses

Immunofluorescence techniques were used to trace the development of cells expressing mu heavy chains in humans and mice. IgM B cells were distinguished from pre-B cells by their additional expression of kappa or lambda light chains. Generation of pre-B and progeny B cells was evident in hemopoietic fetal liver and bone marrow, but not in thymus, heart, lung, spleen, kidney, and placental tissues. Pre-B and B cells, in a ratio of 2 to 1, were abundant in sections of hemopoietic liver and in bone marrow from 12- to 15-wk-old human fetuses, whereas these cells were rare in nonhemopoietic liver samples obtained beyond the 34th week. In mouse fetal liver mu+ cells appeared first around the 12th day of gestation and increased in frequency throughout the third trimester. On day 17 of gestation, kappa light chain expression by 1% of mu+ cells was noted, and the percentage of kappa+/mu+ cells increased progressively to more than 80% by 5 days after birth. Pre-B and B cells were interspersed among myeloid and more abundant erythropoietic cellular elements in the extrasinusoidal areas adjacent to hepatic cords. A loose clustering or "starburst" distribution pattern of pre-B cells became evident around day 17. These observations suggest a model for in situ generation of pre-B and progeny B cells in the hemopoietic fetal liver. In the midst of more numerous erythropoietic elements, immunoglobulin-negative precursors divide to generate a loose colony of mu+ pre-B cells that divide again before giving rise to a wave of IgM B cells.     

Effect of myleran on murine hemopoiesis. I. Granulocytic cell line specificity of action on progenitor cells.

Time- and dose-dependent patterns of depletion and regeneration of hemopoietic progenitor cells in mouse femora and spleens following treatment with the antileukemic agent Myleran (Busulphan, MY) were studied using the murine spleen colony system and the agar gel in vitro colony system. MY was found to depress granulopoiesis selectively, as manifested by the development of marked prolonged neutropenia, hypoplasia of the bone marrow and (to a lesser degree) of the spleen, reduction of the incidence of multipotential hemopoietic progenitor cells (CFU-S) and of granulocytic progenitor cells (CFU-C) in both femora and spleens, and impairment of the capacity of CFU-S from either tissue to generate granulocytic colonies in the spleens of irradiated hosts. The severity and duration was greatest at high dose levels of MY (800 microgram). The action of MY on CFU-S was more pronounced than that on CFU-C, suggesting that MY is a cycle-independent agent. Repopulation of the CFU-C pool preceded that of the CFU-S pool. Development of neutropenia and maximal marrow hypoplasia followed the onset of depression of CFU-S and CFU-C incidence, while recovery of normal nucleated cellularity in the blood, femur and spleen preceded repopulation of the CFU-S and CFU-C pools. MY treatment resulted in transitory stimulation of colony stimulating factor (CSF) generation by the femur but had no effect on serum CSF levels. The peak of femoral CSF generation coincided with the nadir of CFU-C depression. These findings indicated that the prolonged neutropenia following MY treatment was secondary to depletion of the progenitor cell pools, that during recovery granulopoietic repopulation took precedence over self-maintenance of the hemopoietic progenitor cell pools, and that increased generation of CSF may play a role in the early phase of granulopoietic recovery.     

Effect of Myleran On Murine Hemopoiesis

Time- and dose-dependent patterns of depletion and regeneration of hemopoietic progenitor cells in mouse femora and spleens following treatment with the antileukemic agent Myleran (Busulphan, MY) were studied using the murine spleen colony system and the agar gel in vitro colony system. MY was found to depress granulopoiesis selectively, as manifested by the development of marked prolonged neutropenia, hypoplasia of the bone marrow and (to a lesser degree) of the spleen, reduction of the incidence of multipotential hemopoietic progenitor cells (CFU-S) and of granulocytic progenitor cells (CFU-C) in both femora and spleens, and impairment of the capacity of CFU-S from either tissue to generate granulocytic colonies in the spleens of irradiated hosts. the severity and duration was greatest at high dose levels of MY (800 μ). the action of MY on CFU-S was more pronounced than that on CFU-C, suggesting that MY is a cycle-independent agent. Repopulation of the CFU-C pool preceded that of the CFU-S pool. Development of neutropenia and maximal marrow hypoplasia followed the onset of depression of CFU-S and CFU-C incidence, while recovery of normal nucleated cellularity in the blood, femur and spleen preceded repopulation of the CFU-S and CFU-C pools. MY treatment resulted in transitory stimulation of colony stimulating factor (CSF) generation by the femur but had no effect on serum CSF levels. the peak of femoral CSF generation coincided with the nadir of CFU-C depression. These findings indicated that the prolonged neutropenia following MY treatment was secondary to depletion of the progenitor cell pools, that during recovery granulopoietic repopulation took precedence over self-maintenance of the hemopoietic progenitor cell pools, and that increased generation of CSF may play a role in the early phase of granulopoietic recovery.     

Flexible association of hemopoietic differentiation programs in multilineage colonies

Pluripotent hemopoietic progenitors lose potentialities during the process of differentiation. We have examined events that lead to lineage restriction by determining the cellular composition of 785 multilineage colonies grown from peripheral blood samples of glucose-6-phosphate-dehydrogenase (G-6-PD) heterozygous volunteers. Of these colonies, 762 contained only one isoenzyme type and were considered to be of clonal origin. A considerable heterogenity was observed. Some colonies were composed of cells belonging to two different lineages, while other colonies contained three or more different cell types. A small number of colonies consisted—in addition to myeloid cells—of T-lymphocytes. The variable association within individual colonies of members belonging to different hemopoietic lineages suggests a flexible determination and expression of differentiation programs by early progenitors.     

Formation of hematopoietic colonies of the donor type in the bone marrow of irradiated chickens after transplantation of the cells of the yolk sac and hindlimb of the quail embryo]

The ability of yolk sac and primary bone marrow cells of the quail to form hemopoietic colonies at 6 hours of incubation (i. e. before establishment of circulation) was studied in the bone marrow of 3-week sublethally irradiated chickens. The experiments were based on the possibility of differentiating between quail and chicken cells from the natural cell marker (Pheulgen-positive nucleolus). The number of hemopoietic colonies produced by cells transplanted from the primary bone marrow was three times greater than that consequent on transplantation of yolk sac cells. With the given dose of irradiation the bone marrow shows about 75% exogenous (quail) and 25% endogenous (chicken) hemopoietic colonies.