Antibody formation and B-cell migration from bone marrow to spleen in mice under conditions of stimulation and suppression of erythropoiesis]

The effect of erythropoietic stimulation and suppression on the production of antibody-forming cells (AFC) in the spleen and on the B-cell migration from the bone marrow to the spleen was investigated in the CBA mice. Erythropoiesis stimulation proved to sharply increase the AFC count in the spleen and the B-cell migration from the bone marrow to the spleen 1 and 4 days after the bleeding. Erythropoiesis suppression resulted in a slight increase of the AFC count in the spleen 4 and 7 days after the transfusion of syngeneic red blood cells. However, the erythropoietic suppression inhibited the B-cell migration from the bone marrow to the spleen. Possible mechanisms of the effect of the erythropoietic stimulation and suppression on the antibody production are discussed.     

A mathematical model of erythropoiesis in mice and rats. Part 4: Differences between bone marrow and spleen

In a preceding analysis we hypothesized that the most important parameter controlled by erythropoietic regulation in vivo is the degree of amplification (number of cell divisions) in the CFU-E and erythroblast cell stages. It was concluded that erythropoietic amplification in vivo is controlled according to a sigmoidal dose-response relationship with respect to the control parameter which is the haematocrit (or haemoglobin concentration). Here, this hypothesis is extended to include the differences in murine bone marrow and splenic erythropoiesis that are described and quantified by different dose-response relationships. Comparing several sets of experimental data with mathematical model simulations, this approach leads to the following conclusions: (i) in the unperturbed normal steady state at least one extra erythropoietic cell division takes place in the spleen compared with the bone marrow; (ii) a strong erythropoietic stimulus, such as severe bleeding or hypoxia, can induce five to six additional cell divisions in the spleen but only two to three additional divisions in the bone marrow; this results in a considerable increase in the spleen's contribution to erythropoiesis from about 10% in normal animals to over 40% during strong stimulation; (iii) under erythropoietic suppression, such as red cell transfusion, a similar number of cell divisions is skipped in both organs and the splenic contribution to erythropoiesis remains unchanged. In conclusion, the concept that bone marrow and spleen microenvironments differ in the dose-response relationship for erythropoietic regulation provides an explanation for the changing contribution of splenic murine erythropoiesis following a variety of experimental treatments.     

A mathematical model of erythropoiesis in mice and rats. Part 4: Differences between bone marrow and spleen

Abstract. In a preceding analysis we hypothesized that the most important parameter controlled by erythropoietic regulation in vivo is the degree of amplification (number of cell divisions) in the CFU-E and erythroblast cell stages. It was concluded that erythropoetic amplification in vivo is controlled according to a sigmoidal dose-response relationship with respect to the control parameter which is the haematocrit (or haemoglobin concentration). Here, this hypothesis is extended to include the differences in murine bone marrow and splenic erythropoiesis that are described and quantified by different dose-response relationships. Comparing several sets of experimental data with mathematical model simulations, this approach leads to the following conclusions: (i) in the unperturbed normal steady state at least one extra erythropoietic cell division takes place in the spleen compared with the bone marrow; (ii) a strong erythropoietic stimulus, such as severe bleeding or hypoxia, can induce five to six additional cell divisions in the spleen but only two to three additional divisions in the bone marrow; this results in a considerable increase in the spleen's contribution to erythropoiesis from about 10% in normal animals to over 40% during strong stimulation; (iii) under erythropoietic suppression, such as red cell transfusion, a similar number of cell divisions is skipped in both organs and the splenic contribution to erythropoiesis remains unchanged. In conclusion, the concept that bone marrow and spleen microenvironments differ in the dose-response relationship for erythropoietic regulation provides an explanation for the changing contribution of splenic murine erythropoiesis following a variety of experimental treatments.     

AN ANALYSIS OF BONE MARROW ERYTHROPOIESIS IN THE MOUSE

Following the model of the erythropoietic system developed in the rat by Tarbutt and Blackett, the authors have carried out a kinetic analysis of bone marrow erythropoiesis in the mouse.
Using ⁵⁹Fe labelling techniques the size of the recognizable precursor cells and of the functional cell compartments have been estimated, while the flow-rate from the unrecognized precursor cells to the recognizable cells and from the latter compartment to the circulating erythrocytes have been evaluated by ⁵⁵Fe autoradiography.
Differences in the kinetic parameters of the erythropoietic mouse bone marrow compared with the rat bone marrow are reported, whose interpretation has required a more detailed analysis of the original model.     

Organ interactions in the regulation of hematopoiesis: in vitro interactions of bone, thymus, and spleen with bone marrow stem cells in normal, Sl/Sld and W/Wv mice.

Hematopoietic cell differentiation is influenced by organ-dependent microenvironmental factors as well as humoral regulators. A technique is described for examining certain aspects of the hemopoietic inductive microenvironment in vitro. Suspension and agar cultures of mouse bone marrow were used to study the effects of organ stromal factors on cellular proliferation and differentiation. Bone, spleen, and thymus fragments from irradiated mice were placed in direct contact with or separated by a Nuclepore membrane from syngeneic marrow cells growing in suspension cultures. Normal adult mouse bone and spleen influenced granulocytic differentiation as well as cell proliferation. In this system, bone marrow and organ fragments from W/Wv and SlSld mice behaved like those of their non-anemic littermates. The most prominent difference between W/Wv and Sl/Sla mice and their normal counterparts was observed in the inductionof CFU-C from splenic precursors un-er the influence of CSA. In both types of anemic mice, in vitro generation of CFU-C from spleen was abnormal in young animals but was corrected by four months of age.     

In vitro production of CFU-S and cells with erythropoiesis repopulating ability by 5-fluorouracil treated mouse bone marrow

Mouse bone marrow, obtained from donors three days after treatment with 5-fluorouracil, had a very low ability to form macroscopic spleen colonies in irradiated mice at 10 days after transplantation of the cells (CFU-S10); such marrow also had no detectable erythropoiesis repopulating ability but did have near normal marrow repopulating ability and spleen megakaryocyte repopulating ability. Incubation of this marrow in vitro for 7 days with medium containing growth factor preparations (a) pregnant mouse uterus extract plus human spleen conditioned medium or (b) mouse spleen conditioned medium, resulted in marked increases in CFU-S10 and in cells with erythropoietic repopulating ability together with maintenance of cells with marrow repopulating ability. These responses were not observed in cultures with control medium alone. Spleen megakaryocyte repopulating ability was also maintained in the presence of the factor preparations.     

Effect of tissue macrophage destruction products on hematopoietic stem cells]

Products of mouse peritoneal macrophage destruction (PMD) obtained by aseptic freezing-thawing of the cells, repeated thrice, were found to elicit in syngeneic mice injected with PMD intraperitoneally an increase of CFUs count in the hemopoietic bone marrow tissue and the spleen, as demonstrated by the Till and McCullooch technique. This proved to be a true increase since the transplatned stem cell fraction sorbed by the recipient's spleen was relatively lower in donor mice given PMD than in the control. Although PMD caused an increase of both erythropoietic (E) and granulocytopoietic-monocytic (G) colonies number, the E/G ratio was decreased; one of the mechanisms of the described effect could be the influence of PMD on the hemopoiesis-inducing microenvironment, as the same effects were obtained in mice injected repeatedly with PMD prior to the transplantation of bone marrow tissue of normal donors. Other possible mechanisms of these effects were analyzed, with consideration to the fact that in experiments with preincubation of bone marrow tissue with PMD prior to injection to the lethally irradiated mice no direct stimulating influence of PMD on the stem cell could be revealed.     

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.     

Effects of starvation and refeeding on erythropoiesis in mice

Summary Erythropoiesis has been studied in the mouse following acute starvation and refeeding. Starvation produced a depression of erythropoiesis in both spleen and bone marrow. Refeeding, however, resulted in marked erythropoiesis in the spleen and relatively little erythropoiesis in the marrow. It is suggested that the spleen may be the primary organ in the mouse for the reestablishment of erythropoietic homeostasis.Dedicated to Professor B erta Scharrer with best personal wishes on the occasion of her 60th birthday.This study was supported by United States Public Health Service Grant No Ca-03071 Hem. from the National Cancer Institute.I wish to express my thanks to Mr. A. Scorza, Dept. of Pathology, for his excellent technical assistance in the preparation of the histological material.     

Use of a mathematical model of erythropoiesis to study the recovery process in mice exposed to acute x-ray irradiation]

The model described in the preceding paper was used (after introducing several further presumptions of a radiobiological nature) for the interpretation of the dynamics of erythropoietic recovery, experimentally studied by the authors in mice after acute X-irradiation. The solution of equations in the model was carried out by a digital computer, finding some (not yet experimentally determined) quantitative characteristics of the system by trial and error. A satisfactory degree of agreement in the behaviour of the model with the experimentally determined course of recovery seems to indicate the validity of the basic assumptions of the model, esp. the existence of the negative feedback between erythroid populations of the bone marrow and spleen.     

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.     

An erythropoietic stimulating factor similar to erythropoietin released by macrophages after treatment with silica

An erythropoietic stimulating factor (ESF) can be detected in the supernatant from fetal liver and adult bone marrow and spleen cells when preincubated with the macrophage-specific cytotoxic agent, silica. Stimulation is observed in 12-day fetal liver CFU-E cultures in the absence of added erythropoietin (Ep). The concentration of ESF in the supernatant added to CFU-E cultures is dependent on the preincubated cell dose and the volume added. The stimulating activity is abolished when mice are hypertransfused and increased above normal values when mice are bled. A concentrated silica-treated spleen supernatant was able to stimulate erythropoiesis in the polycythemic mouse bioassay. It is concluded that the ESF is similar, if not identical, to Ep.     

Mice homozygous for the ablm1 mutation show poor viability and depletion of selected B and T cell populations

The c-abl gene, originally identified as the cellular homolog of the transforming gene of the Abelson murine leukemia virus, encodes a protein-tyrosine kinase of unknown function that is expressed in all mammalian tissues. We have previously described the introduction of a mutation in the c-abl gene into the mouse germline via targeted gene disruption of embryonic stem cells. We now show that mice homozygous for this mutation are severely affected, displaying increased perinatal mortality, runtedness, and abnormal spleen, head, and eye development. We have examined components of the immune system and have found major reductions in B cell progenitors in the adult bone marrow, with less dramatic reductions in developing T cell compartments.     

The frequency of bone marrow cells that bind erythropoietin

The frequencies of rat and mouse bone marrow cells capable of binding erythropoietin were studied by both direct fluorescence and indirect immunofluorescence. We found that between 1-2% of the cells bound erythropoietin, that the binding was specific, and that the number of cells that bound erythropoietin was, in part, a function of the erythropoietic state of the donor animal. A statistical method for evaluating the data obtained is included.     

Stem cell kinetics in spleen and bone marrow after single and fractionated irradiation of infant mice

Summary The number and type of stem cells in spleen and bone marrow of mice were determined after exposure to a single dose of 150 R on day 6, to a single dose of 500 R on day 6 or day 9 or to a fractionated dose of 150 R + 350 R on day 6 and 9. The stem cells were assayed on the basis of colony forming units (CFU) in spleen and of incorporation of iododeoxyuridine in spleen and bone marrow of lethally irradiated host mice. During the first month of life, the number of stem cells in non-irradiated mice increases markedly in bone marrow and slightly in spleen. Irradiation causes a long-lasting depression in stem cells, particularly in bone marrow and affecting preferentially erythropoietic precursor cells. Following a dose of only 150 R, the number of CFU in bone marrow is still below control levels 24 days later. An exposure to 500 R fractionated between day 6 and 9 has a markedly greater effect on stem cells in the spleen than the same dose given in a single application either at day 6 or 9.Supported by the Schutzkommission am Ministerium des Innern der BRD and contract B232-76-1BIOB of the Biology Division of the Commission of the European Community (Publikation No. 1727)     

Stimulator of proliferation of spleen colony-forming cells in acute sterile inflammation

The presence and activity of a spleen colony-forming cell (CFU-S) proliferation stimulator was investigated in rat bone marrow after induction of sterile inflammation. Wistar rats were treated intraperitoneally with two 15 ml injections of 3.5% polyvinylpyrrolidone (PVP) at 18 h intervals, and the presence of CFU-S proliferation stimulator determined in bone marrow 6, 20 and 24 h after the first injection. The marrow of these mice was used to condition medium which was then fractionated using Amicon Diaflo ultrafiltration membranes. The 30–50 kDa fraction, taken from 20 h post-PVP-bone marrow extract, was found to induce cycling of d8-CFU-S in normal mouse bone marrow. This activity was not related to the presence of interleukins-1, -2 or -6 like activities in the material tested. The results demonstrate the existence of CFU-S proliferation stimulator in the bone marrow of rats with sterile inflammation (i.e. in an in vivo tissue response to non-specific cell stimulation), similar to that originally described as a macrophage product in mouse bone marrow after treatment with a variety of cytotoxic agents.     

小鼠体内脾脏,骨髓及精原细胞姐妹染色单体交换的比较研究

本文对几种化学诱变剂诱发小鼠体内脾脏、骨髓和精原细胞的SCE进行了比较研究,同时分析了几类常见化合物在小鼠脾脏细胞中诱发SCE的活力。结果显示诱变剂在脾脏细胞中诱发SCE比骨髓和精原细胞敏感。几类化合物都能显著地诱发小鼠脾脏SCE的增加,与对照相比差异显著(P<0.05)或极显著(P<0.01),说明利用小鼠脾脏细胞检测环境诱变物是相当灵敏的。     

Regulation of B-lymphocyte production in the bone marrow: mediation of the effects of exogenous stimulants by adoptively transferred spleen cells

The cellular mechanism by which an injection of sheep red blood cells (SRBC) results in an increased production of B lymphocytes in mouse bone marrow has been studied by adoptive cell transfer and the use of two in vivo assays of bone marrow B-cell genesis. Proliferation of B progenitor cells was examined by immunofluorescent labeling combined with mitotic arrest, while small lymphocyte renewal was measured by [3H]thymidine labeling and radioautography. In C3H/HeJ mice the administration of SRBC resulted in increased proliferation among bone marrow pre-B cells which contained cytoplasmic mu heavy chains but lacked kappa light chains and surface mu chains. The turnover of small lymphocytes also increased. These stimulatory effects were transferred to naive recipient mice by organ fragments and by cell suspensions harvested from the spleens of donor mice injected with SRBC. In contrast, spleen cells and thymus cells from saline-injected donors and thymus cells from SRBC-injected donors had no such stimulatory effects. The results demonstrate that spleen cells mediate the stimulatory effect of SRBC on bone marrow B-lymphocyte production. Spleen cell transfer provides a system to study further the cells and factors involved in the regulation by external environmental agents of the rate of primary B-cell genesis in vivo.     

Modulation of murine hemopoiesis in vivo by a synthetic hemoregulatory pentapeptide (HP 5b)

A synthetic pentapeptide analogous to an inhibitory factor associated with human granulocytes was tested in vivo on female C3H mice. The relative and absolute numbers of myelopoietic and erythropoietic cells in the bone marrow were measured following injections as well as the continuous infusion of the pentapeptide in dose ranges between 10(-8)M and 10(-4)M (0.12 micrograms to 1.2 mg/mouse). In low doses, the pentapeptide reduced the number of myelopoietic cells in the bone marrow, and this was accompanied by reduced numbers of granulocytes and monocytes and peripheral blood. Elevated doses also decreased erythropoiesis. In contrast, continuous infusion of 14 micrograms/h for 19 days seemed to make the myelopoietic cells refractory to further action. A regulatory function of the pentapeptide is proposed.     

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.