Asialogangliosides as differentiation markers of rat erythropoietic and granulopoietic cells in rat bone marrow. Flow cytometric analysis of rat bone marrow cells using anti-asialoganglioside antibodies

Flow cytometric analysis using anti-glycolipid antiserum was used on rat bone marrow cells to determine the relation between the glycolipid species expressed on cell surfaces and cell differentiation. Four kinds of antibodies against gangliotriaosylceramide (Gg3Cer), gangliotetraosylceramide (Gg4Cer), fucogangliotetraosylceramide (IV2 alpha Fuc-Gg4Cer) and IV3 alpha Gal-fucogangliotetraosylceramide (IV3 alpha GalIV2 alpha Fuc-Gg4Cer, blood group B lipid) were used. The cells sorted out by each anti-glycolipid antiserum were stained with May-Grünwald-Giemsa reagent and identified by microscopy. In the erythropoietic group, only polychromatic erythroblasts had these four glycolipids on their cell surfaces; none appeared on differentiated erythrocytes. These glycolipids were expressed during the early stages of immature granulocytes, especially in the promyelocyte and myelocyte stages of eosinophilic and neutrophilic granulocytes. Very limited populations of lymphocytes were sorted out as asialoganglioside-expressing cells. We concluded that asialogangliosides are useful differentiation markers for the erythropoietic and granulopoietic cells of rat bone marrow, and that anti-asialoganglioside antibody-flow cytometry is a very useful technique with which to isolate immature granulocytes and erythropoietic cells from rat bone marrow cells.     

Comparative kinetic behaviour and regulation by fructose-1,6-bisphosphate and ATP of pyruvate kinase from erythrocytes, reticulocytes and bone marrow cells

1. Kinetic and regulatory properties of pyruvate kinase have been studied in haemolysates of erythrocytic populations from blood and bone marrow of rats. 2. Pyruvate kinase from normal rat erythrocytes showed sigmoidal kinetics vs phosphoenolpyruvate. In contrast, the enzyme from reticulocytes and erythroid-rich bone marrow cells behaved as hyperbolic. 3. The enzyme activities were always inhibited by ATP. Activation by fructose-1,6-bisphosphate was only observed in erythrocytes. 4. These kinetic differences suggest changes in pyruvate kinase isozymes in cells of the erythrocytic line of rats.     

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.     

Development of a method to increase the proportion of polychromatic erythrocytes from mouse bone marrow for more rapid evaluation of the micronucleus assay. Comparison with the conventional method with respect to micronucleus frequency and time required for preparation and evaluation

By treatment of bone marrow suspension in hypotonic (0.51%) saline, followed by purification on a cellulose column, the proportion of polychromatic erythrocytes in bone marrow smears can be increased 2.6-fold. Furthermore, practically all nucleated cells of erythropoietic or leukopoietic origin are removed. This kind of bone marrow preparation can lead to a considerable reduction in the time required for microscopical evaluation of the micronucleus assay without altering the rate of micronucleated polychromatic erythrocytes in a negative (isotonic saline) and a positive (mitomycin C) control group.     

E-cadherin is functionally involved in the maturation of the erythroid lineage

Differentiation and proliferation of hematopoietic progenitors take place in the bone marrow and is a tightly controlled process. Cell adhesion molecules of the integrin and immunoglobulin families have been shown to be involved in these processes, but almost nothing was known about the involvement of the cadherin family in the hematopoietic system. A PCR screening of RNA of human bone marrow mononuclear cells with specific primers for classical cadherins revealed that E-cadherin, which is mainly expressed by cells of epithelial origin, is also expressed by bone marrow cells. Western blot analysis and immunofluorescence staining of bone marrow sections confirmed this unexpected finding. A more detailed analysis using immunoaffinity columns and dual color flow cytometry showed that the expression of E- cadherin is restricted to defined maturation stages of the erythropoietic lineage. Erythroblasts and normoblasts express E- cadherin, mature erythrocytes do not. A functional role of E-cadherin in the differentiation process of the erythroid lineage was indicated by antibody-inhibition studies. The addition of anti-E-cadherin antibody to bone marrow mononuclear cultures containing exogeneous erythropoietin drastically diminished the formation of erythropoietic cells. These data suggest a non-anticipated expression and function of E-cadherin in one defined hematopoietic cell lineage.     

Development of a method to increase the proportion of polychromatic erythrocytes from mouse bone marrow for more rapid evaluation of the micronucleus assay: Comparison with the conventional method with respect to micronucleus frequency and time required for preparation and evaluation

By treatment of bone marrow suspension in hypotonic (0.51%) saline, followed by purification on a cellulose column, the proportion of polychromatic erythrocytes in bone marrow smears can be increased 2.6-fold. Furthermore, practically all nucleated cells of erythropoietic or leukopoietic origin are removed. This kind of bone marrow preparation can lead to a considerable reduction in the time required for microscopical evaluation of the micronucleus assay without altering the rate of micronucleated polychromatic erythrocytes in a negative (isotonic saline) and a positive (mitomycin C) control group.     

Hexokinase in developing rabbit erythroid cells

The activity and isozyme distribution of hexokinase were studied in bone marrow cells from normal and anemic rabbits seperated by density centrifugation or by unit-gravity sedimentation. The specific activity of the enzyme was found to be about 150-fold higher in the basophilic erythroblasts as compared with the mature circulating erythrocytes. Mos of the falls in hexokinase activity take place whent the cell completes its final division and matures from the polychromatic stage to the orthochromatic stage. Concomitant with this strong decrease in enzyme activity, qualitative as well as quantitative changes in the hexokinase isozymic pattern become apparent. While in the basophilic and polychromatic erythroblasts the only hexokinase isozyme present is hexokinase type I, the orthochromatic cells also contain hexokinase Ib. This last isozymic form, which increases further at the reticulocyte stage, is also present in the circulating reticulocytes but not in mature red blood cells.     

Hemopoietic progenitor cells with limited potential for differentiation: erythropoietic function of mouse marrow "lymphocytes"

Filtration of mouse marrow cell suspensions over columns of glass wool increased the frequency of small and medium-sized lymphocytes (SML) and of erythropoietic progenitor units (EPU) by about the same factor. Identical results were obtained when erythropoiesis was assayed by isotope uptake (⁵⁹FeCl₃ and ¹²⁵IUdR) or by the spleen-colony techniques. Transfusion of prospective donor mice with erythrocytes virtually eliminated morphologically recognizable erythroid cells from marrow without affecting the frequency of EPU. Injection of prospective donors with cortisol decreased the frequency of SML in marrow but not that of EPU or erythropoietin-sensitive cells. However, glass wool filtration of lymphocyte-poor marrow taken from mice pretreated with cortisol resulted in a similar increase in frequency of residual SML and of EPU. Therefore, it appears that a subpopulation of marrow SML are EPU. Whereas glass wool filtration increased the frequency of erythropoietic progenitor and colony-forming units, the filtration failed to change the frequency of leukopoietic progenitor or colony-forming units (assayed in mice hypertransfused with erythrocytes to suppress erythropoiesis). It follows that separate progenitor cells for erythropoiesis and leukopoiesis are present in bone marrow of adult mice, in addition to pluripotent stem cells.     

Microenvironment created by stromal cells is essential for a rapid expansion of erythroid cells in mouse fetal liver

Mouse stromal cell lines (FLS lines), established from the livers of 13-day gestation mouse fetus, supported the proliferation and differentiation of the erythroid progenitor cells from mouse fetal livers and bone marrow in a semisolid medium in the presence of erythropoietin. A large erythroid colony of over 1000 benzidine-positive erythroid cells was developed from a single erythroid progenitor cell on the FLS cell layer after 4 days of culture. When in close contact with the layer, the erythroid progenitor cells divided rapidly with an average generation time of 9.6 h and mature erythroid cells, including enucleated erythrocytes, were produced. The present studies demonstrate that the microenvironment created by the stromal cells can support the rapid expansion of erythropoietic cell population in the fetal liver of mice.     

Splenic hematopoiesis in an experimental model of hemolytic anemia

The splenic hemopoiesis of rabbits, made anemic with acetylphenylhydrazine, and of control animals was investigated. Pieces of spleen of both groups were fixed in formalin and embedded in paraffin. Paraffin sections, cut 5-7 microns in thickness, were stained with hematoxylin-eosin, Giemsa, Perls' method for tissue iron (hemosiderin), and Perls-Chayen's method for iron stored in the hemoglobin. The erythroid line in the anemic rabbits, showed a marked increase of proerythroblasts and basophilic erythroblasts, while the poli and orthochromatic erythroblasts were less than their precursors. In contrast these cells were more than their precursors in control animals. There was no notable quantitative difference in the mature elements of this line in the anemic animals and in the controls. Megaloblasts and macroblasts were frequently observed in anemic spleens but they were practically absent in the controls. Regarding to other cell lineages, we noted in the anemic spleens many macrophages containing Perls and Perls-Chayen positive material and some megakaryocytes. Our results indicate that the APH-induced anemia stimulate the erythropoietic activity of the spleen in the rabbit, but the reversion of the amplification phase of the differentiation steps reveals that the erythropoietic process is ineffective. The presence of megalo- and macroblasts provide morphological evidence of dyserythropoiesis and the megakaryocytes suggest that under the anemia condition also the platelet regenerating process is stimulated.     

Cell transfer studies in cyclophosphamide-induced tolerance

Thymectomized, irradiated adult CBA mice were restored with various combinations of bone marrow and thymus cells from nontolerant animals and from animals made tolerant to sheep erythrocytes or to hemocyanin with the drug cyclophosphamide. Mice reconstituted with tolerant marrow and thymus responded as well as those that received nontolerant cells. Thus it is concluded that the tolerant state of the transferred marrow and thymus cells is not a significant factor in the tolerant state of the recipient, and that antigenic diversity is restored in the interaction and proliferation of bone marrow and thymus cells that follow transfer.Thymectomized irradiated mice restored with thymocytes, in contrast to unoperated animals, require multiple antigen injections to demonstrate comparable immune response, but develop tolerance normally when treated with cyclophosphamide and antigen. Reconstitution with tolerant marrow and thymus cells resembles the recovery of immune responsiveness seen after lethal irradiation of tolerant mice; in both instances a complete breakdown of immunological tolerance is observed.     

Role of T-lymphocytes in the mechanisms of hemopoiesis-inducing microenvironment activation in inflammation]

On the model of acute infectious peritonitis in mice, the inflammation was shown to accompany pronounced activation of bone marrow haemopoiesis. The increased number of committed precursor cells of erythro- and granulomonocytopoiesis, morphologically differentiated elements and enhancing colony-stimulating and erythropoietic activities of GIM cells origin were shown as well. Thy 1.2+ cells, migrating to bone marrow, were shown to play an important role in hemopoiesis stimulation inflammation. These stimulate the processes of myeloid precursor proliferation directly (by means of lymphokines) and in cooperation with monocytes-macrophages of GIM.     

A kinetic study of the genetic control of hemopoietic progenitor cells assayed in culture and in vivo

The kinetics of growth of bone marrow cells from normal or genetically anemic mice (Sl/Sl^d and W/W^v) were studied in irradiated normal and genetically anemic hosts. The parameters followed included total cellularity, the number of peroxidase positive cells, and the number of cells capable of forming colonies in vivo (CFU-S) or in culture (CFU-C). The results of these experiments demonstrate that W and Sl defects alter the growth of CFU-C and peroxidase-positive cells to a modest degree; that the defects are more obvious when studied in spleen rather than in bone marrow; and that there is no additivity of W and Sl defects. Nineteen irradiated recipients of marrow from W/W^v mice were studied after three to six months. Of these, 18 showed host-type erythrocytes, while in one mouse the erythrocytes had the size distribution of W/W^v cells. This finding indicated that occasionally genetically defective stem cells may repopulate irradiated hosts.     

Analysis of the tetrahydrobiopterin synthesizing system during maturation of murine reticulocytes

The enzymes of tetrahydrobiopterin synthesis have been studied in murine bone marrow, in spleen, in erythrocytes, and in reticulocytes. Mice with chemically induced and with genetically conditioned reticulocytosis as found in the lactate dehydrogenase deficient strain (Ldh-1c/Ldh-1c) were used for analysis of reticulocytic enzyme activities. The activity of the biopterin synthesizing system is highest in bone marrow even though it amounts to only about 10% as compared with liver. The first enzyme of the biosynthetic pathway, GTP-cyclohydrolase, virtually disappears during the final maturation step of reticulocytes. In contrast, the activities of 6-pyruvoyltetrahydropterin synthase and of sepiapterin reductase of erythrocytes are only reduced to about one half of the reticulocyte level. The absence of biopterin in erythrocytes is therefore caused by the loss of the enzyme that initiates the pterin biosynthetic pathway.     

An experimental study on the pathway of iron transfer from macrophages to erythrocytes in rat liver

In order to reveal the pathway of iron release from macrophages, a 59Fe-labelled ferric hydroxide-potassium polyvinyl sulfate complex (Fe-PVS) was injected intravenously into anemic rats and the level of radioactivity in the liver, spleen, bone marrow, blood plasma and red blood cells (RBC) was estimated at various time intervals after the injection. Histochemical observation of ferric iron and ferritin in the liver was also made on anemic rats treated using unlabelled Fe-PVS. Fe-PVS injection promoted the recovery of anemia causing a rapid increase in the RBC number, with activated erythropoiesis occurring in the spleen and bone marrow. Soon after the injection, most of the radio iron was found in the liver with a small amount in the circulating erythrocytes, bone marrow and spleen. The iron level in the liver decreased gradually with a rapid increase in the iron level of the erythrocytes which reached a very high level 6 days after the 59Fe-PVS injection. Histochemical observations showed a heavy deposition of ferritin in the Kupffer cells 3 days after Fe-PVS injection. This deposition was minimized after 6 days with an increase in the level of ferritin in the parenchymal cells in the central area of acini. The level of radioferritin estimated biochemically in the nonparenchymal cell fractions of the liver revealed that the level dropped by about one third approximately 3.5 days after the Fe-PVS injection, showing the stimulated ferritin release at this stage. Results indicate that Kupffer cells in the liver play an important role in ferritin synthesis from the phagocytized iron compounds and that the iron is supplied for erythroid cell proliferation.     

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.     

Murine adult hematopoietic cells produce adult erythrocytes in fetal recipients

Bone marrow cells from normal adult mice were introduced by microinjection via the placenta into W/W^v genetically anemic fetuses of 11 days' gestation. After birth, erythrocytes were fractionated by fluorescence-activated cell sorting on the basis of antibody binding to a fetal-specific antigen (Ft). Lysates of Ft-positive, i.e., fetal, erythrocytes did not detectably contain hemoglobin of the donor type, as judged from electrophoresis of strain-specific hemoglobin variants. Thus, adult hematopoietic bone marrow cells did not resume fetal differentiation despite their post-transplant maturation in a fetal environment.     

DISSECTING THE HEMATOPOIETIC MICROENVIRONMENT. I. STEM CELL LODGMENT AND COMMITMENT, AND THE PROLIFERATION AND DIFFERENTIATION OF ERYTHROPOIETIC DESCENDANTS IN THE Sl/Sld MOUSE

The anemic Sl/Sl^d mouse and its normal (+/+) congenic control were used to explore the possibility of stromal control over four phases of erythropoiesis: CFU lodgment, commitment of multipotent stem cells to the erythropoietic line, proliferation of stem cells and their descendants, and the differentiation of those descendants into successively more mature forms. Lodgment was found to be the same in the Sl/Sl^d as in the normal mouse, but commitment, although characteristically different for spleen compared to the bone marrow, was subnormal. The stimulus to proliferate, as measured by spleen colony size and cell type content, was even more reduced. It is suggested that the direct control of differentiation into more mature cells may not be under stromal control.     

The micronucleus test with mouse spleen cells

The results of this study show that the micronucleus test can be carried out with mouse spleen cells as well as with cells from bone marrow. Polychromatic erythrocytes occurred in the spleen at a frequency of about 9% of the whole spleen cells compared with about 13% in the bone marrow. 3 test compounds were used to compare the frequency of micronuclei in cells from the 2 tissues. Mitomycin C and cyclophosphamide induced micronucleated polychromatic erythrocytes in both spleen and bone marrow. Fosfomycin, an antibiotic having a broad spectrum of antimicrobial activities, did not induce micronucleated erythrocytes in either organ.     

Suppression by bone marrow cells of the level of specific IgE antibodies in the blood of mice and decrease in the production of IGE by bone marrow cells

Changes in the level of the specific IgE-antibodies to ovalbumin under the influence of syngeneic cells of a bone marrow were studied. The IgE-response was induced by ovalbumin in mice (CBA X C57Bl/6)F1. The bone marrow cells suspensions (20-30 X 10(6) cells per mouse) from syngeneic donors was inoculated simultaneously with the immunization. It was found that bone marrow cells suppressed both the level of IgE-antibodies in experimental mice serum and the production of IgE by the bone marrow cells of the recipient. The ability to suppress IgE-response remained when erythrocytes, monocytes and T-lymphocytes were removed from inoculated suspensions. The bone marrow cells taken from the mice immunized with ovalbumin, at the stage of a decreasing IgE-response, provided more pronounced suppression, than bone marrow cells taken from intact animals.