Isolation of spleen-colony forming cells (CFU-s) using wheat germ agglutinin and rhodamine 123 labeling

Mouse pluripotent hemopoietic stem cells could be enriched 100 to 200-fold by a procedure consisting of three steps: 1) equilibrium density centrifugation, 2) light-activated cell sorting on the basis of light scatter characteristics and fluorescence due to wheat germ agglutinin binding, 3) cell sorting after subsequent rhodamine 123 staining. The new isolation procedure does not make use of antibodies with mouse-strain restricted applicability, which were employed in earlier described methods. Therefore, it is more versatile. It is also faster due to diminished incubation time. Rhodamine 123 can also be used as a photosensitizer. The experimental conditions were, however, designed to prevent this action of the dye. Between 80% and 100% of the selected spleen-colony forming cells survived the labeling and sorting treatments. The procedure enriches for two types of stem cells. The rhodamine-dull fraction contains stem cells that form spleen colonies in lethally irradiated mice at 12-16 days and no spleen colonies at 8 days after transplantation. The rhodamine-bright fraction contains stem cells that give day-8 and day-12 spleen colonies. These latter cells, however, have a low radioprotective capacity and it can be argued that these are not self-renewing pluripotent stem cells. The heterogeneity of day-12 CFU-s (colony-forming unit spleen) that can be detected after labeling with rhodamine 123 has been observed earlier after treatment of bone marrow donor mice with 5-fluorouracil, and has led to the postulation of pre-CFU-s and a "generation-age" hypothesis for stem cells. Our presently sorted rhodamine dull cells resemble such pre-CFU-s.     

Effect of a neutrophilia-inducing tumor on hemopoietic stem cells in mice

The influence of neutrophilic stimulation on hemopoietic stem cells was studied in mice with tumor-induced neutrophilia. Transfusions of marrow cells from normal and neutrophilic tumor-bearing mice into lethally irradiated normal and tumor-bearing mice were performed. The number and the erythroid:granuloid (E:G) ratio of day 7 colonies in the recipient spleens and bones as well as the size of spleen colonies of recipient animals were determined. The E:G ratio of spleen and bone marrow colonies between normal and tumor-bearing mouse recipients and the number of spleen colonies did not differ significantly in either experiment. However, spleen colonies which developed in tumor-bearing irradiated mice were significantly larger than those which developed in normal recipients in both experiments. These studies indicated that while the line of differentiation taken by hemopoietic stem cells was not affected by the neutrophilic influence of the tumor, the tumor-bearing host environment appeared to enhance proliferation of transfused stem cells and/or their descendants. The stimulators of granulocytopoiesis in this model of neutrophilia appear to act on a population of progenitor cells more mature than the stem cells capable of forming 7-day colonies in the spleen and bone marrow of irradiated recipient mice.     

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.     

Diffusion chamber and spleen colony assay of murine haematopoietic stem cells

Mouse bone marrow cells have been cultured in diffusion chambers and their capacity to form spleen colonies in irradiated mice investigated after different culture periods. The number of spleen colony-forming units (CFU) in the chambers decreased during the first day of culture. The number then increased rapidly to a level significantly above the original chamber value on the third to fifth day of culture. By that time large numbers of granulocytes and macrophages had also appeared. Histological examination of spleen colonies showed that prior culturing did not alter the ratio between the different types of colonies. Cultured bone marrow cells which were transferred to new chambers retained granulopoietic capacity. This capacity increased between the first and second day of primary culturing. At this time hydroxyurea injections to chamber hosts revealed that the progenitor cells were proliferating. The results show that the granulopoietic progenitor cells of the chambers are stem cells, and that one progenitor cell type is identical with the CFU.     

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.     

Role of thymus-dependent cells in splenic colony formation]

It was shown that treatment of the bone marrow with the serum reacting with the theta-antigen, irrespective of the presence of the complement, sharply decreases the capacity of its cells to form splenic colonies. Administration of the thymus cells together with the bone marrow to the recipient largely elminates the effect of this system, significantly increasing the splenic colony formation. It is supposed that the antiserum in the bone marrow inactivates the population of cells necessary for the formation of the colonies in the spleen, but differing from the pluripotent stem cells, possibly the population of T-cells.     

Mock retroviral infection alters the developmental potential of murine bone marrow stem cells.

Retroviral vectors were used to introduce an activated ras gene into murine pluripotent hemopoietic stem cells. We attempted to reconstitute the hemopoietic system of lethally irradiated mice with isolated spleen colonies obtained in vivo after injection of infected bone marrow cells. Spleen colonies derived from infected bone marrow were inefficient in promoting long-term survival of irradiated hosts. This loss of reconstitutive capacity of spleen colonies was not due to the retroviral infection per se but to the in vitro culture of spleen colony precursors. Incubation for 24 h in the presence of fetal calf serum and interleukin-3 without virus-producing cells was sufficient to abolish completely the reconstitutive capacity of spleen colonies while maintaining both self-renewal and pluripotential capacities of spleen colony precursors. These results show that the in vitro manipulation of stem cells that is included in current protocols for retroviral infection can modify the developmental potential of these cells. This finding clearly indicates that the use of retroviral vectors can introduce a bias in the analysis of hemopoiesis.     

Haemopoietic stem cells in the foetal mouse thymus.

The presence of haemopoietic stem cells (HSC) in the foetal mouse thymus was assessed to determine whether all cells which enter the developing organ are precommitted to thymocyte differentiation, or if stem cell multipotentiality still exists. The Till and McCulloch spleen colony assay was used to delineate foetal-thymus derived HSC in lethally irradiated recipients. Of the range examined, between 13 days of gestation to birth, a peak of stem cell activity occurs in 15-day foetal thymus. The surface colonies produced by the thymus-derived HSC are small compared to colonies produced by the liver derived HSC, although well within the range of the latter. Histologically, five types of colonies were identifiable which were produced by the thymus-derived HSC, indicating that these cells retain the potential to form a wide range of differentiated colonies.     

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.     

Physical separation of hemopoietic stem cells from cells forming colonies in culture

Mouse bone marrow cells in suspension were separated into a number of fractions on the basis of cell density by equilibrium density gradient centrifugation, or on the basis of cell size by velocity sedimentation. After each type of separation, the cells from the various fractions were assayed for their ability to form macroscopic spleen colonies in irradiated recipient mice, and for their ability to form colonies in a cell culture system. The results from either separation technique demonstrate that cells in some fractions formed more colonies in vivo than in the culture system, while cells in other fractions formed more colonies in culture than in the spleen. The results of control experiments indicate that this separation of the two types of colony-forming cells was not an artifact of the separation procedures. From these experiments it was concluded that the population of cells which form colonies in culture under the conditions used is not identical to the population of cells detected by the spleen colony assay.     

A stochastic model of self-renewal and commitment to differentiation of the primitive hemopoietic stem cells in culture

We recently identified a murine hemopoietic stem cell colony which consists of undifferentiated (blast) cells and appears to be more primitive than CFU-GEMM in the stem cell hierarchy. The progenitors for the colony which we termed “stem cell colony” possess an extensive self-renewal capacity and the ability to generate many secondary multipotential hemopoietic colonies in culture. We replated a total of 68 stem cell colonies from cultures of murine spleen cells and analyzed the number of stem cell–and granulocyte(neutrophil)-erythrocyte-macrophage-megakaryocyte (GEMM) colony-forming cells in individual stem cell colonies. Of the 68 stem cell colonies, 35 contained progenitors (abbreviated as “S”-cells) for stem cell colonies. The distributions of S-cells and CFU-GEMM in individual stem cell colonies were extremely heterogeneous. Neither the frequency distributions of S-cells nor CFU-GEMM in stem cell colonies could be fitted well by Poisson distribution. Rather, the frequency distribution of the s-cells could be approximated by a geometric distribution and that of CFU-GEMM by an exponential distribution, both of which are variates of the gamma distribution. Our observations are in agreement with those on the distributions of CFU-S in individual spleen colonies and provided support for a stochastic model for stem cell self-renewal and commitment in culture. Application of the theory of the branching process to the distribution of S-cells revealed a distributional parameter “p” of 0.589 which is also in agreement with the earlier report on the p value for reproduction of CFU-S.     

Characterization of spleen colonies derived from mice with mutations at the W locus.

Mice with mutations at the W locus have a hemopoietic stem cell defect characterized by an apparent deficiency of spleen colony forming cells (CFU-S). In the present report, we provide evidence that mutant cells form colonies and we compare the characteristics of the colonies derived from mutant and normal cells. To perform the colony-derivation studies, marrow cells were transferred into lethally irradiated congenic hosts that differed from the donors in the ubiquitous genetic marker, glucose phosphate isomerase (GPI-1). Donor GPI-1 comprised over 50% of the marker in the host spleen and marrow by 12 days post injection, regardless of whether the donor was mutant or normal. To characterize the colonies, serially sectioned host spleens were examined microscopically. Colonies are present by 8 days post-transplantation regardless of donor genotype, but mutant colonies are distinctly different from normal colonies. The proportion of blast and granulocyte colonies is always greater in W/Wv than in +/+ recipients. Unlike the W/Wv donors, the +/+ donors generate primarily erythrocyte colonies at 8, 10, and 14 days and mixed colonies at 12 days post-injection. Colonies from the mutant mice are generally smaller but visible colonies do appear by 12 days. The results are consistent with the notion that the anemia in W/Wv mice is caused by the early restriction of differentiating cells to a non-erythrocyte lineage accompanied by the delayed amplification of mutant hemopoietic cells. Whether this means erythrocyte-committed cells are absent or are present but unable to respond to the appropriate cytokines is not possible to determine from the current experiments.     

STUDIES OF HEMATOPOIESIS IN MURINE SPLEENS: SIGNIFICANCE OF HEMATOPOIETIC COLONIES FORMED ON THE SURFACE OF SPLEENS

Conies of hematopoietic tissue are formed in spleens of lethally irradiated mice by the injection of small numbers of hematopoietic cells. Some of these colonies appear as surface colonies, others can be identified only in serial sections of the spleen. The present studies have related the number and cellular composition of total hematopoietic colonies in the murine spleen to their visual recognition on the splenic surface. These studies demonstrate that only 50% of the total colonies in a spleen are recognized as surface colonies and that of those colonies on the surface, approximately 80% contain erythroid elements. At least four factors play important roles in the recognition of hematopoietic colonies as splenic surface colonies: (1) dose of repopulating cells or hematopoietic stem cells injected into the irradiated animal; (2) location of colonies within the spleen; (3) size of colonies; and (4) cellular content of the colonies. These studies demonstrate that surface colony formation reflects primarily erythropoiesis and not total hematopoiesis.     

Magnetic field exposure of marrow donor mice can increase the number of spleen colonies (CFU-S 7d) in marrow recipient mice

Transplantation of bone marrow cells of magnetic-field-exposed mice led to increased numbers of spleen colonies (CFU-S 7d) in conditioned recipient mice (Peterson et al. 1986). Here we report on the dependence of this phenomenon on body temperature, field strength and exposure time. It was found that the effect can only be seen when the body temperature is 27 degrees C, the field strength not less than 1.4 T and the exposure time at least 15 min. It is suggested that the magnetic field increases the number of spleen colonies either directly by affecting membrane components (receptors) responsible for the seeding of the transplanted stem cells to the recipient spleens or indirectly affecting radical/redox-systems that may have a regulatory function in the stem cells.     

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.     

Effect of the U-2 fraction of splenic extract from Horsfield's terrapin on the hematopoiesis of mammals

Intraperitoneal administration of a spleen extract from Testudo horsfieldi and its U-2 fraction increases the number of endogenous splenic haemopoietic colonies. The U-2 fraction administered to irradiated (4 Gy) mice increases the number of bone marrow CFUs. Bone marrow cells of exposed (4 Gy) mice preincubated in vitro with the U-2 fraction also increase the number of exogenous colonies in the recipient's spleen.     

Murine acute leukemia cell line with megakaryocytic differentiation (MK-8057) induced by whole-body irradiation in C3H/He mice: cytological properties and kinetics of its leukemic stem cells

Five cases of murine leukemia with megakaryocytic differentiation were observed among the 417 cases of radiation-induced leukemias which developed in 30% of C3H/HeMs mice exposed at 8 to 10 weeks to 0.5 to 5 gy total body irradiation. Cells from individual leukemic colonies in the spleen of the irradiated mice, and cells from colonies in methylcellulose (MC) culture in vitro, derived from one of these leukemias, MK-8057, were injected into mice; both types of cells caused the deaths of the recipient mice by inducing the same type of leukemia. MK-8057 can be maintained in Dexter-type liquid culture with a feeder layer of irradiated bone marrow cells. There was a linear reciprocal relationship between the increasing number of MK-8057 cells injected versus the survival of the recipient mice. A reciprocal relationship also was seen between an increasing number of leukemic stem cells, corresponding to the number of MK-8057 cells, and the survival of mice injected with MK-8057. Giant nuclear megakaryocytes developed during the course of colony growth in the spleen as they did in the MC culture. Such megakaryocytes were acetylcholinesterase positive, whereas leukemic cells in the peripheral blood showed no sign of platelet production nor of a positive reaction to acetylcholinesterase. Cells maintained in culture were entirely positive in platelet glycoprotein IIb/IIIa when anti-human antibody was used. The larger cells in a splenic cell suspension derived from a moribund mouse were separated and enriched by velocity sedimentation using centrifugal elutriation (CE), and then subjected to flow cytometry using propidium iodide staining. Cells with up to 32N-DNA content were detected. After separating MK-8057 by counter-flow CE, the larger cell fraction (mode at 540 microns3) produced more leukemic colonies when injected into irradiated mice than did the small cell fraction (mode at 240 microns3). A higher percent of the larger cell fraction (61.9%) was killed by the addition of tritiated thymidine cytocide than in the smaller cell fraction (14.9%). Thus, the smaller cell fraction is considered to have more leukemic spleen colony-forming units (L-CFU-s) in the resting state.     

Evidence for the existence of multipotential lympho-hematopoietic stem cells in adult rat

Rats were given near-lethal doses of x-ray to produce clones of hemic cells marked by radiation-induced chromosome abnormalities. Subsequently, bone marrow from these rats was injected into lethally irradiated mice to form erythropoietic spleen colonies; and peripheral blood lymphocytes from the same rats were stimulated to proliferate in a mixed lymphocyte interaction (MLI), an immunological response to histocompatibility isoantigens. Chromosome markers indicated that in several instances the cells of an erythroid spleen colony and a proportion of the lymphocytes reacting in the MLI were progeny of the same stem cell in the donor rat. In addition, lymphocytes of the same radiation-marked clone were shown to proliferate in response to several different histocompatibility isoantigens. The data indicate the presence in the adult rat of a primitive lymphohematopoietic stem cell capable of yielding both erythroid and lymphoid progeny. The findings also suggest that immunological specificity is determined during lymphoid differentiation, subsequent to the stem cell stage.     

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.     

The in vitro radiosensitivity of hemopoietic stem cells from control and preirradiated infant mice

Summary The radiosensitivity of hemopoietic stem cells isolated from infant mice (6 or 9 days of life), of infant preirradiated mice (exposed to 126 rad on day 6 and assayed at day 9 of life) and of adult C57/B1 mice was assayed on the basis of their capacity to form spleen colonies and to incorporate iododeoxyuridine after transplantation into heavily irradiated hosts. Stem cells of infant non-irradiated mice have a D₀ of 115 rad compared to 72 rad for adult mice whereas the D₀ of preirradiated infant mice has diminished to 80 rad. No significant difference in D₀ was seen between spleen and bone marrow cells or between total cells and cells not sensitive to³H-thymidine. It is postulated that this sensitization of stem cells caused by a preirradiation is responsible for the greater mortality of infant mice after fractionated exposure compared to a single one.