“The Good into the Pot,the Bad into the Crop!”—A New Technology to Free Stem Cells from Feeder Cells

A variety of embryonic and adult stem cell lines require an intial co-culturing with feeder cells for non-differentiated growth, self renewal and maintenance of pluripotency. However for many downstream ES cell applications the feeder cells have to be considered contaminations that might interfere not just with the analysis of experimental data but also with clinical application and tissue engineering approaches. Here we introduce a novel technique that allows for the selection of pure feeder-freed stem cells, following stem cell proliferation on feeder cell layers. Complete and reproducible separation of feeder and embryonic stem cells was accomplished by adaptation of an automated cell selection system that resulted in the aspiration of distinct cell colonies or fraction of colonies according to predefined physical parameters. Analyzing neuronal differentiation we demonstrated feeder-freed stem cells to exhibit differentiation potentials comparable to embryonic stem cells differentiated under standard conditions. However, embryoid body growth as well as differentiation of stem cells into cardiomyocytes was significantly enhanced in feeder-freed cells, indicating a feeder cell dependent modulation of lineage differentiation during early embryoid body development. These findings underline the necessity to separate stem and feeder cells before the initiation of in vitro differentiation. The complete separation of stem and feeder cells by this new technology results in pure stem cell populations for translational approaches. Furthermore, a more detailed analysis of the effect of feeder cells on stem cell differentiation is now possible, that might facilitate the identification and development of new optimized human or genetically modified feeder cell lines.     

Synergistic interaction between interleukin-6 and interleukin-3 in support of stem cell proliferation in culture

Interleukin-6 (Il-6), also known as B cell stimulatory factor 2/interferon beta 2, has been found to support colony formation by murine granulocyte-macrophage progenitors. We have reported that Il-6 also acts synergistically with interleukin-3 (Il-3) in the support of the proliferation of multipotential stem cells in the quiescent, Go phase of the cell cycle. Our serial observations (mapping studies) of the development of blast cell colonies from spleen cells harvested from mice 4 days after the injection of 150 mg/kg 5-fluorouracil revealed that the blast cell colonies appeared earlier in culture in the presence of Il-6 and Il-3 than with either factor alone. Because the combination of factors did not alter the rate of growth of the colony, this effect must result from an early exit from Go. In the human system using purified, My-10+ bone marrow progenitors in a culture system with delayed addition of growth factors, the combination of Il-6 and Il-3 yielded twice as many colonies as did Il-3 alone. The human blast cell colonies also appeared at earlier times when grown in the presence of Il-6 and Il-3 as compared to either factor alone. These results suggested that human Il-6 acts synergistically with Il-3 in the support of the proliferation of human and murine hemopoietic stem cells in Go and that part of the effect appears to be a shortening of the Go residence time of the hemopoietic stem cells.     

Haemopoietic spleen colony growth: a versatile, parsimonious, predictive model

Abstract. Substantial support has been obtained for the stochastic model for stem cell differentiation first proposed by Till, McCulloch & Siminovitch (1964), over 20 years ago. By adding a cell maturation pathway, it is possible to predict (by computer simulation) the total number of cells and consequently the time at which individual colonies appear and disappear.
Only a few uncontroversial assumptions are required to predict that cells, uniform with respect to self-renewal, are capable of producing the high proportions of late disappearing and late appearing colonies observed experimentally in the spleens of irradiated mice that have been injected with normal haemopoietic cells. It is shown that differences in stem cell self-renewal only slightly influence the time of appearance of colonies; whereas changes in the kinetics of the maturing cells, by changing the size of colonies, has a marked effect on the time of appearance and disappearance of colonies and on the average doubling-time of colony-forming cells per colony (but not the doubling-time of individual colonies).
These results (1) seriously question the prevailing view that spleen colonies scored at 8 days measure a separate population (without the capacity for self-renewal), from those scored at 12 days; (2) argue against the existence of multiple sub-populations of stem cells with differing self-renewal and toxicity to cytotoxic agents; (3) help to identify those experiments for which it is obligatory to postulate heterogeneity, and (4) are consistent with self-renewal being regulated by a feedback control of stem cell differentiation, to which only proliferating stem cells can respond and where the stimulus for differentiation decreases at a time when the bone marrow is known to be depleted.     

Effect of various factors on the differentiation of hematopoietic stem cells]

The treatment in vitro of bone marrow cells in mice by phytohemagglutinin, concanavaline, or antilimphocytic globulin resulted in the suppression of exogenous hemopoietic colonies in the spleen of lethally irradiated (830r) syngenic recipients, whereas lipopolysaccharide, tuberculin, anti-theta serum or nati-gamma-globulin serum exerted no influence on the colony-forming function of hemopoietic stem cells. The morphological analysis of the ratio and cell composition of hemopoietic colonies has revealed no marked differences between the experimental and control groups. The suppression of hemopoietic stem cells by mitogens might be due both to their direct effect and indirect one, possibly, through a humoral factor.     

Clonogenicity of human endometrial epithelial and stromal cells

The human endometrium regenerates from the lower basalis layer, a germinal compartment that persists after menstruation to give rise to the new upper functionalis layer. Because adult stem cells are present in tissues that undergo regeneration, we hypothesized that human endometrium contains small populations of epithelial and stromal stem cells responsible for cyclical regeneration of endometrial glands and stroma and that these cells would exhibit clonogenicity, a stem-cell property. The aims of this study were to determine 1) the clonogenic activity of human endometrial epithelial and stromal cells, 2) which growth factors support this clonogenic activity, and 3) determine the cellular phenotypes of the clones. Endometrial tissue was obtained from women undergoing hysterectomy. Purified single- cell suspensions of epithelial and stromal cells were cultured at cloning density (300-500/cm(2)) in serum medium or in serum- free medium supplemented with one of eight growth factors. Small numbers of epithelial (0.22%) and stromal cells (1.25%) initiated colonies in serum-containing medium. The majority of colonies were small, containing large, loosely arranged cells, and 37% of epithelial and 1 in 60 of stromal colonies were classified as large, comprising small, densely packed cells. In serum-free medium, transforming growth factor-alpha (TGF alpha), epidermal growth factor (EGF), platelet-derived growth factor-BB (PDGF-BB) strongly supported clonogenicity of epithelial cells, while leukemia-inhibitory factor (LIF), hepatocyte growth factor (HGF), stem-cell factor (SCF), insulin-like growth factor-I (IGF- I) were weakly supportive, and basic fibroblast growth factor (bFGF) was without effect. TGF alpha, EGF, PDGF-BB, and bFGF supported stromal cell clonogenicity, while HGF, SCF, LIF, and IGF- I were without effect. Small epithelial colonies expressed three epithelial markers but not stromal markers; however, large epithelial colonies showed little reactivity for all markers except alpha(6)-integrin. All stromal colonies contained fibroblasts, expressing stromal markers, and in some colonies, myofibroblasts were also identified. This analysis of human endometrium has demonstrated the presence of rare clonogenic epithelial and stromal cells with high proliferative potential, providing the first evidence for the existence of putative endometrial epithelial and stromal stem cells.     

Efficiency of adult mouse spermatogonial stem cell colony formation under several culture conditions

The aim of this study was to compare the in vitro effects of glial cell line-derived neurotrophic factor, stem cell factor, granulocyte macrophage-colony stimulating factor, and co-culture with Sertoli cells on the efficiency of adult mouse spermatogonial stem cells colony formation. For these purpose, both Sertoli and spermatogonial cells were isolated from adult mouse testes. The identity of the cells was confirmed through analysis of alkaline phosphatase activity, immunocytochemistry against OCT-4, c-kit, and vimentin, and also by transplantation of these cells in the recipient testes. The isolated spermatogonial cells were treated either with various concentrations of the above mentioned factors or co-cultured with Sertoli cells for 3 wk. The spermatogonial cells of the resulting colonies were transplanted via rete testis into the mouse testes, which were irradiated with 14 Gy. The results indicated that glial cell line-derived neurotrophic factor is the most appropriate factor for in vitro colonization of adult mice spermatogonial cells compared with other cytokines and growth factors. A short-term co-culture with Sertoli cells showed a significant increase in the number and diameter of the colonies compared with the treated growth factors and the control group. We have also demonstrated that mouse spermatogonial stem cells in the colonies after co-culturing with Sertoli cells could induce spermatogenesis in the recipient testes after transplantation.     

Permissive role of interleukin 3 (IL-3) in proliferation and differentiation of multipotential hemopoietic progenitors in culture

We studied the effects of interleukin-3 (IL-3) on colony formation by hemopoietic progenitors in methylcellulose cultures of spleen cells from 5-fluorouracil (FU)-treated mice. Purified IL-3 supported the growth of various types of multilineage colonies including blast cell colonies. The types of colonies were similar to those supported by pokeweed-mitogen spleen cell conditioned medium (PWM-SCM), except that IL-3 supported eosinophil and neutrophil expression better. Delayed addition of IL-3 to cultures 7 days after cell plating decreased the number of colonies to one-half the number in cultures with IL-3 added on day 0. It did not alter the proliferative and differentiation characteristics of late emerging multipotential blast cell colonies. These observations suggest that IL-3 does not trigger hemopoietic progenitors into active cell proliferation but is necessary for their continued proliferation. This permissive role of IL-3 is consistent with a stochastic model of stem cell proliferation which features random entry into cell cycle. IL-3 also supported the growth of multilineage colonies from single cells isolated from blast cell colonies by micromanipulation. This result shows that IL-3 acts directly on multipotential progenitors. Analysis of colonies derived from paired progenitors revealed disparate lineage expression and was in accordance with the stochastic model of stem cell differentiation.     

The role of recombinant stem cell factor in early B cell development. Synergistic interaction with IL-7.

The cDNA for stem cell factor was recently isolated from Buffalo rat liver cells (BRL-3A) and recombinant rat stem cell factor produced from Escherichia coli (rrSCF164). rrSCF164 synergizes with rhIL-7 to stimulate pre-B clonal growth in agar culture of mouse bone marrow cells, and in this study we have characterized the role of rrSCF164 in B cell development. The combination of rrSCF164 plus rhIL-7 stimulated increased colony numbers compared with the sum of colonies stimulated by rrSCF164 and rhIL-7 alone. Also, increased cell proliferation per colony was stimulated by the combination of rrSCF164 plus rhIL-7 compared with rhIL-7 or rrSCF164 alone. The colonies formed with rrSCF164 plus rhIL-7 and rhIL-7 alone contained exclusively pre-B cells, which expressed B220 Ag and cytoplasmic mu-chain, but were negative for surface Ig expression. Morphological examination of the cells in the colonies showed blast-like characteristics. rrSCF164 alone and in combination with rhIL-7 stimulated generation of B220+ cells in liquid culture of B220- cells, whereas rhIL-7 alone had no stimulatory effect on B220- cells. Both stem cell factor mRNA and bioactivity were detected in a mouse bone marrow-derived stromal cell line, termed OZ-11. We propose that stem cell factor is a stromal-derived factor that synergizes with IL-7 to stimulate the proliferation and differentiation of pro-B cells to pre-B cells, which become responsive to IL-7 alone.     

How does cellular senescence prevent cancer?

It is widely believed that cellular senescence is a tumor suppressor mechanism; however, it has not been understood why it is advantageous for organisms to retain mutant cells is a postmitotic state rather than simply eliminating them by apoptosis. It has recently been proposed that the primary role of cellular senescence is in mitotic compartments of fixed size in which spatial considerations dictate that a deleted cell is replaced by a neighboring cell. In these situations, rather than eliminating the neoplastic clone, deletion of mutant cells can paradoxically lead to their increased turnover. If mutant cells become senescent, then the compartment is instead progressively filled by senescent cells until the mutant clone is eliminated. Since most of the genetic alterations responsible for malignancy arise in stem cells, this mechanism may have particular relevance to the stem cell niche. In this article the implications of this hypothesis are examined in detail and related to experimental results. It is further proposed here that blockage of stem cell niches by senescent stem cells may account for some of the functional alterations observed in stem cell compartments at old age. Clearly, the existence of senescent stem cells is central to the proposed hypothesis, and although there is preliminary evidence for this assertion it has yet to be proven in vivo. An experimental strategy involving double labeling of stem cells with a nucleotide label is described that can address this question.     

Hematopoietic changes and altered reactivity to IL-17 in Syphacia obvelata-infected mice

Pinworm parasites commonly infect laboratory mice with high prevalence even in well-managed animal colonies. Although often considered as irrelevant, these parasites if undetected may significantly interfere with the experimental settings and alter the interpretation of final results. There are a few reports documenting the effects of pinworms on research and the effects of pinworms on the host hematopoiesis have not yet been investigated. In this study we examined the changes within various hematopoietic cell lineages in the bone marrow, spleen, peripheral blood and peritoneal space during naturally acquired Syphacia obvelata infection in inbred CBA mice. The data obtained showed significant hematopoietic alterations, characterized by increased myelopoiesis and erythropoiesis in S. obvelata-infected animals. In order to additionally evaluate if this pinworm infection modifies hematopoietic cells' reactivity, we examined the effect of murine interleukin-17, T cell-derived cytokine implicated in the regulation of hematopoiesis and inflammation, on the growth of bone marrow progenitor cells and demonstrated that bone marrow myeloid and erythroid progenitors from S. obvelata-infected mice displayed altered sensitivity to IL-17 when compared to non-infected controls. Taken together the alterations presented pointed out that this rodent pinworm is an important environmental agent that might significantly modify the hosts' hematopoietic response, and therefore interfere with the experimental settings and alter the interpretation of the final results. However, the results obtained also contributed new data concerning the activity of IL-17 on bone marrow hematopoietic cells, supporting our previous reports that depending on physiological/pathological status of the organism IL-17 exerts differential effects on the growth of progenitor cells.     

狗骨髓长期培养的贴壁层细胞及条件培养液对粒系祖细胞的影响

本文报告狗骨髓长期培养的初步研究结果。采用马血清与狗血清混合加入培养体系中,可建立起比较稳定的贴壁细胞层,可以维持19周以上。但是,这种贴壁层不能有效地维持造血干细胞的增殖与分化,上清液中血细胞与GM-CFU_C的数目,在第二次接种骨髓后2—3周即迅速下降。狗骨髓培养的条件液中存在着抑制GM-CFU_C生长的物质,但它对小鼠骨髓GM-CFU_C和CFU-S无影响。如以贴壁细胞作为底层,用双层琼脂平皿培养法与正常狗骨髓共同培养,发现贴壁细胞不仅没有抑制反而有加强CSF刺激GM-CFU_C生长的作用。因此对狗骨髓长期培养体系不能长期支持造血干细胞生长和繁殖的可能原因尚须作进一步探索。     

Functional analysis of spermatogonial stem cells in Steel and cryptorchid infertile mouse models

Spermatogenesis is a complex and productive process that originates from stem cell spermatogonia and ultimately results in formation of mature spermatozoa. The stem cell undergoes self-renewal throughout life, but study of its biological characteristics has been difficult because a very small number (2 to 3 in 10(4) cells) exist in the testis and they can only be identified by function. Although the development of the spermatogonial transplantation technique has provided an assay system for stem cells, efficient methods to enrich stem cells have not been available. Here, we examined two infertile mouse models, Steel/Steel(Dickie)(Sl/Sl(d)) and experimental cryptorchid, as a source of testis cell populations enriched in stem cells. The Sl/Sl(d) testis showed little enrichment, which raises questions about how adult stem cell number is determined and about the currently accepted belief that adult stem cells are independent of Sl factor. The cells recovered from cryptorchid testes were enriched for stem cells 25-fold (colonies) or 50-fold (area) compared to wild-type testes. The cryptorchid condition does not affect stem cell activity, but eliminates almost all differentiated cells, and about 1 in 200 cells is a stem cell. Thus, cryptorchid testes provide an important approach for purification and characterization of spermatogonial stem cells.     

Isolation and characterization of a multipotent clone of human embryonal carcinoma cells

Histopathological studies suggest that the stem cells of human teratomas may be classified into two major categories: nullipotent stem cells, and multipotent stem cells, capable both of self-renewal and differentiation into a wide range of somatic and extraembryonic cell types. We have isolated a multipotent stem cell clone from the human teratoma cell line GCT 27, and compared its properties to a nullipotent clone derived from the same strain. The multipotent clone GCT 27 X-1 gave rise to colonies of mixed cell morphology in vitro. Analysis of cell surface, cytostructural and extracellular matrix markers in GCT 27 X-1 cells showed that the stem cells of this line were very similar in phenotype to nullipotent cells. The two cell clones were predominantly hypotriploid, and contained several marker chromosomes in common. GCT 27 X-1 was feeder-cell-dependent for continuous growth in vitro; removal of the feeder layer resulted in differentiation of the stem cells into a variety of cell types, some with characteristics of extraembryonic endoderm, others showing neuronal properties. When transplanted into nude mice, GCT 27 X-1 cells gave rise to teratocarcinomas containing embryonal carcinoma stem cells, and many other cell types: yolk sac carcinoma cells; cells producing alphafetoprotein or human chorionic gonadotrophin; glandular, columnar, cuboidal, and squamous epithelium; primitive mesenchyme and cartilage; neuroectodermal cells. Nullipotent GCT 27 C-1 cells could form colonies in the absence of feeder layers, but multipotent GCT 27 X-1 cells could not. While a range of known growth factors and related substances failed to substitute for feeder layers in supporting the growth of GCT 27 X-1 stem cells, supernatants from yolk sac carcinoma cell line GCT 44 could partially replace the feeder cell requirement. Thus, the results revealed a basic difference in growth control between these multipotent and nullipotent human embryonal carcinoma cells, and suggested a possible paracrine regulatory pathway between multipotent stem cells and yolk sac carcinoma cells.     

Neonatal mouse gonocyte proliferation assayed by an in vitro clonogenic method

Survival and proliferation of mouse gonocytes was studied using a single cell clonogenic assay in vitro. The effect of growth factors and extracellular matrix on clonogenic development was quantitated. Fundamental requirements for growth of neonatal gonocytes included addition of fetal calf serum and coating culture wells with collagen IV alone or with added fibronectin. After 4-5 days, colonies ranged in size from four to > 128 cells, and some contained very elongated cells indicating migratory behaviour. Soluble stem cell factor did not have any effect on clonogenicity, although STO (subline of SIM mouse fibroblasts) cells, which produce membrane-bound stem cell factor, reduced colony formation from 79 +/- 5.9% to 20 +/- 3.3% without added growth factor. The majority of gonocytes and type A spermatogonia express the c-kit receptor according to in situ hybridization studies. However, the results indicate that the receptor may not be functional in neonatal gonocytes and their immediate progeny. The current assay for gonocytes can be extended to test new growth factors or proliferation-inducing agents directly, as well as to study cell-cell interactions. This assay and long-term propagation of neonatal germ cells will provide the much needed resources to enable greater understanding of the early development of germ cells.     

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.     

Restoration of nonclonal hematopoiesis in chronic myelogenous leukemia with interferon alpha

Studies have shown that recombinant human alpha interferon (rIFN alpha) inhibits the growth of colonies of multipotential stem cells from human bone marrow. This report demonstrates that rIFN alpha inhibits the growth of such colonies from the bone marrow of patients with chronic myelogenous leukemia (CML) to a greater extent than from bone marrow of healthy individuals. It also shows that T lymphocyte colonies subcloned with interleukin 2 (IL-2) from CML mixed colonies were inhibited more by rIFN alpha than were similar colonies subcultured from normal mixed colonies. The report demonstrates that the Ph' chromosome is present in such T cell colonies subcultured from CML mixed colonies. When mixed colonies were grown from CML bone marrow in the presence of rIFN alpha, Ph' negative colonies were observed, whereas no such Ph' negative mixed colonies grew from a similar number of bone marrow cells incubated without rIFN alpha. These observations confirm that T lymphocytes derived from bone marrow stem cells are from the CML clone, and that the inhibition of growth of Ph' positive colonies, by rIFN alpha permits the growth of residual normal stem cells. The disappearance of the Ph-chromosome in subclones of T lymphocytes supports the notion of nonclonal hematopoiesis in patients with CML.     

Mitochondrial DNA deletion mutations in adult mouse cardiac side population cells

We investigated the presence and potential role of mitochondrial DNA (mtDNA) deletion mutations in adult cardiac stem cells. Cardiac side population (SP) cells were isolated from 12-week-old mice. Standard polymerase chain reaction (PCR) was used to screen for the presence of mtDNA deletion mutations in (a) freshly isolated SP cells and (b) SP cells cultured to passage 10. When present, the abundance of mtDNA deletion mutation was analyzed in single cell colonies. The effect of different levels of deletion mutations on SP cell growth and differentiation was determined. MtDNA deletion mutations were found in both freshly isolated and cultured cells from 12-week-old mice. While there was no significant difference in the number of single cell colonies with mtDNA deletion mutations from any of the groups mentioned above, the abundance of mtDNA deletion mutations was significantly higher in the cultured cells, as determined by quantitative PCR. Within a single clonal cell population, the detectable mtDNA deletion mutations were the same in all cells and unique when compared to deletions of other colonies. We also found that cells harboring high levels of mtDNA deletion mutations (i.e. where deleted mtDNA comprised more than 60% of total mtDNA) had slower proliferation rates and decreased differentiation capacities. Screening cultured adult stem cells for mtDNA deletion mutations as a routine assessment will benefit the biomedical application of adult stem cells.     

Clustering of mutant mitochondrial DNA copies suggests stem cells are common in human bronchial epithelium

Tissue maintenance stem cells, as opposed to transition and/or terminal cells in the epithelium, are possible progenitor cells for human tumors, but little is known about their frequency in human tissues. It occurred to us that the colonies of mutants that should be created when a stem cell mutates and transmits the rare mutation to its descendent transition and terminal cells should, given a quantitative mutation assay, define the average number of cells in a maintenance turnover unit and permit calculation of stem cell number. To test this concept we used a combination of high fidelity PCR and constant denaturant capillary electrophoresis to enumerate mitochondrial point mutations and define their number and distribution among multiple small samples of approximately one million cells containing about 400 million copies of mitochondrial DNA. The bulk of the data were best explained by a model in which most stem cells, defined here as long-lived cells, give rise to colonies of approximately 8-128 cells. In addition, we found that about 1.5% of colonies contained hundreds or even thousands of homoplasmic mutant cells. These expanded turnover units suggest the bronchial epithelium may contain large clusters of cells with mutations, and possibly phenotypic alterations as well.     

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.