Hematopoietic precursor cells in radiation chimeras restored by bone marrow from thymectomized mice]

Radioprotective capacity of bone marrow CFUs of adult thymectomized mice was studied. Lethally irradiated mice were inoculated with bone marrow of mice thymectomized 8-11 months before. The colony forming capacity and proliferative rate of CFUs were studied 1-7.5 months after obtaining the radiation chimeras. It has been shown that proliferative capacity of bone marrow of adult thymectomized mice was reduced in comparison with that of normal animals. It is related to the decrease (4-fold) of the proliferative rate of bone marrow of thymectomized mice which was inoculated into lethally irradiated recipients 1 month before. We also found that the content of CFUs in bone of those chimeras was reduced later--after 7.5 months. In this period (1-7.5 months) the cellularity of bone marrow did not change.     

1 alpha, 25-Dihydroxyvitamin D3 augments clonal growth of macrophages from rat bone marrow progenitor cells and modulates their function

1 alpha, 25-Dihydroxyvitamin D3 (1,25(OH)2D3) was shown to enhance (approximately 2 fold) the colony-stimulating factor-dependent clonal growth of macrophage colonies and clusters from rat bone marrow progenitor cells. The proliferative capacity of macrophage progenitors in liquid cultures was likewise augmented (2-3 fold). Mononuclear phagocytes (macrophages, for simplicity) developing in the presence of 1,25(OH)2D3 showed a reduced capacity of migration. 1,25(OH)2D3 administered at bone marrow culture initiation led to augmentation of the phagocytic capability of macrophages in four-day cultures and to its suppression in macrophages in seven-day cultures. The observed patterns of modulation of differentiation and function by 1,25(OH)2D3 differ from the patterns we found for mouse bone marrow cells. The results suggest that the differential response to hormones observed in different species may include responses to 1,25(OH)2D3.     

Cultivation of frozen mouse bone marrow cells in agar.

The authors attempted to cultivate frozen mouse bone marrow cells in a semisolid medium. They demonstrated that the stem haematopoietic cells of frozen mouse bone marrow were capable of proliferation and of colony formation on agar. The much smaller number of colonies from frozen mouse bone marrow (about 80% fewer) compared with fresh marrow is evidence that part of the stem haematopoietic cell population retains proliferative capacity even after freezing.     

Cultivation of fresh and frozen mouse bone marrow. - Application of methyl cellulose.

The culture of cells of both fresh and frozen mouse bone marrow on methyl cellulose (MC) was approached. We used 1.5%-concentration of MC and proved the stem cells of fresh and frozen mouse bone marrow to proliferate and form haemopoietic colonies on MC. We established that the freezing process did not significantly decrease the proliferative capacity of CFU-C stem cells.     

Radiobiological properties of human hematopoietic and stromal marrow cells

Effective hematopoiesis requires the presence of normal hematopoietic progenitors and a supporting microenvironment. Impairment of one of these marrow compartments will result in marrow failure. Total body irradiation (TBI) followed by bone marrow transplantation (BMT) is becoming an established modality in the treatment of malignant hematopoietic disorders. The objectives of irradiation are to ablate host marrow and immunocompetent cells as well as to eradicate neoplastic cells. Although leukemic cells are thought to have the same radiobiological characteristics as their normal counterparts, it has been proposed recently that some leukemic cells may possess a substantial capacity to repair sublethal radiation damage. Thus, radiation administered at different dose rates or fractions might differ in its ability to ablate malignant cells and consequently affect the relapse rate in the post-transplant period. Different modes of irradiation can also affect the proliferative capacity and the hematopoietic supportive function of the marrow microenvironment. Bone marrow ablation must be accomplished with the least possible damage to other tissues. Impairment of the proliferative capacity of the marrow microenvironment or its hematopoietic supportive function can result in graft failure in the post-transplant period. In this review, we discuss the radiobiological characteristics of normal hematopoietic, leukemic and stromal cells and their relevance to bone marrow transplantation.     

Variable in vitro erythropoiesis in patients with transient erythroblastopenia of childhood

Transient erythroblastopenia of childhood (TEC) is a pure red cell aplasia which primarily affects children in the infant and toddler age group. The clinical syndrome of TEC is well defined and is characterized by moderate to severe anemia with reticulocytopenia, selective aplasia of the erythroid bone marrow elements, and spontaneous recovery, usually within a month of presentation. We utilized the plasma clot tissue culture technique to explore the defect of erythropoiesis in seven patients with TEC. Culture of bone marrow at diagnosis in four patients revealed an increased erythroid proliferative capacity in one and a decreased capacity in three. The former patient plus three additional patients were found to have a transient serum inhibitor of erythroid colony formation in autologous and allogeneic systems. The three patients with diminished erythroid proliferative capacity had no demonstrable serum inhibitor, and in one patient studied the erythroid proliferative capacity became supernormal after recovery. We conclude that although TEC has a characteristic clinical picture, in vitro studies reveal a variable expression of the erythropoietic defect and support the hypothesis of a heterogeneous pathogenesis of this disorder.     

Granulocytopoiesis in children with acute lymphoblastic leukaemia.

Numbers, proliferative potential, and differentiative capacity of bone marrow granulocyte-macrophage precursor cells were studied in 130 children with acute lymphoblastic leukaemia (ALL), including 77 children in an acute phase of the disease and 53 in remission. Bone marrow samples from 65 children without haematopoietic abnormalities were used as controls. The numbers of clonogenic precursors were found to be below normal in all phases of ALL, particularly during the acute period when the bone marrow was heavily infiltrated with leukaemic cells. It is shown that the decreases in the numbers and proliferative potential of the precursor cells during the acute phases was associated with the effects of leukaemic blast cells, but that in remission the observed reduction in the precursor cell pool was due to the cytostatic effect of therapy. The differentiative capacity of clonogenic granulocyte and macrophage precursors was not altered in children with ALL.     

Age-related changes in the capacity of bone marrow cells to differentiate in thymic organ cultures

The capacity of the bone marrow to give rise to T cells in advanced age was studied in vitro by reconstituting fetal thymic lobes from 14-day C57BL/Ka (Thy-1.1) mice with bone marrow cells from old (24-month) or young (3-month) C57BL/6 (Thy-1.2) mice. The use of these congenic strains enabled distinguishing between donor and host contribution to the developing T cells. We found that bone marrow cells from aged mice maintained their capacity to reconstitute fetal thymic explants and to differentiate into various T-cell subsets as assessed by distinct T-cell-specific surface markers (Thy-1, Lyt-1, Lyt-2, and L3T4) and functions (concanavalin A-induced proliferative and cytotoxic responses). However, when mixtures of old and young bone marrow cells reconstituted fetal thymic explants, the cells of old mice were less efficient than those of young in their capacity to give rise to T cells. These results indicate that bone marrow cells from aged mice can reconstitute the thymus and differentiate into T cells; however, their reconstituting capacity is inferior to that of bone marrow cells from young mice.     

The Effects of Radiation and Hindlimb Unloading on Rat Bone Marrow Progenitor Cells

Bone marrow cells of mesenchymal origin play an important role in adaptation of physiological systems to space flight. Hematopoiesis, immunity, and homeostasis of bone tissue depend on their functional activity. An investigation that was carried out in the framework of the Bion and Bion-M programs showed a decrease of the number of rat bone marrow hematopoietic progenitors and the inhibition of lympho- and erythropoiesis when the granulocyte-macrophage linage was activated. A negative influence on nonhematopoietic bone marrow cells was also revealed. The pathogenetic influence of radiation and microgravity on the bone marrow progenitor cells has remained unclear so far. The goal of this research was to study the effect of a 30-day unloading and 6 days of γ-irradiation on rat bone marrow progenitor cells. The study was conducted on male rats of four groups: vivarium control (VC), hindlimb unloading (HU), irradiation (IR), and combined action (HU + IR). The following parameters have been examined: the number of bone marrow mononuclear cells, proliferative activity of marrow mononuclear cells, immunophenotype, number of hematopoietic CFU and CFU-f, and differentiation potency of hematopoietic and stromal bone marrow precursors. It was found that the cellularity and proliferation activity of rat bone marrow cells did not change under simulation of space flight. The number of CFU-f was decreased. Irradiation was accompanied by an increase in the hematopoietic cell share among total bone marrow mononuclear cells, while their activity was attenuated. The osteopotential of the stromal precursors was unchanged. Adipogenic differentiation was stimulated with irradiation. The functional activity of bone marrow progenitor cells was restored after 2 weeks of recovery. Thus, 30-day simulation of space flight factors negatively affected the morphofunctional properties of rat bone marrow progenitor cells. These effects were reversible upon 2 weeks of recovery.     

The proliferative capacity of pure red cell aplasia bone marrow cells.

Pure red cell aplasia (PRCA) is a heterogeneous disorder. Immunologic abnormalities have recently been uncovered suggesting that both cell-mediated and humoral immune mechanisms may be of etiological importance in PRCA. Utilizing a technique for the cloning of bone marrow erythroid precursors, we determined the in vitro proliferative capacity of erythroid cells obtained from 21 patients with PRCA. Bone marrow cells from one group of patients produced normal or increased numbers of erythroid colonies while the in vitro proliferative capacity of bone marrow cells from a second group was characterized by subnormal erythroid colony formation. Sera obtained from the former group was frequently associated with demonstrable serum inhibitors of erythropoiesis, while PRCA in the latter group was probably the consequence of intrinsic erythroid stem cell defects or pathologic cellular interactions with nonerythroid regulatory cells. This survey of a relatively large population of patients with PRCA provides evidence for the multiple causative mechanisms that can be operative in the production of PRCA.     

ADAPTATION OF HEMOPOIETIC TISSUE RESULTING FROM ESTRONE-INDUCED OSTEOSCLEROSIS IN MICE

The redistribution of hemopoietic tissue resulting from estrone-induced osteosclerosis in the mouse was studied. As the marrow was gradually replaced by bone, extramedullary hematopoiesis in the spleen increased at a rate sufficient to maintain hemopoietic homeostasis. The total numbers of colony forming units (CFU) in the tibia and spleen as well as the proportion of CFU in cycle was assessed. After five injections of estrone, tibial CFUs decreased to 2% of control values whereas splenic CFUs increased approximately nine-fold. The proliferative capacity of the splenic CFU was also increased in the estrone-treated animals. The increased numbers of splenic CFUs as well as the increased proliferative capacity of this compartment are probably related to the ability of extramedullary hematopoiesis in the spleen to compensate for a marrow that has been replaced by bone.     

Competitive in vivo proliferation of foetal and adult haematopoietic cells in lethally irradiated mice

The relative proliferative capacity of haematopoietic cell populations derived from 22-week-old adult bone marrow and 14–18 day foetal liver has been studied in lethally irradiated syngeneic recipients by means of chromosome markers. Although starting at a disadvantage in terms of the number of colony-forming units (stem cells) injected, the foetal liver-derived populations steadily increased their relative numbers in the myeloid and lymphoid tissues over a period of several weeks until a plateau was reached. It is suggested that stem cells in foetal liver have, on average, a higher intrinsic capacity for self-renewal than do those in bone marrow, and that this capacity falls to the adult level within about ten weeks of transfer.     

Microfluorimetric research on the erythroblastic islands and macrophages of the bone marrow]

A microfluorimetric system was used to study rat bone marrow erythroblastic islands (EI) and macrophages. Measurement of fluorescence from acridine-orange-treated cells was performed on the microscope LUMAM-E3 (LOMO, Leningrad) at 530-550 and 630-650 nm. The intensity of fluorescence in 530-550 nm range depended on the intensity of proliferative processes in EI, that at 630-650 nm was associated with activity of lysosomal apparatus of EI macrophages. Erythroblast amplification in EI is parallel both to enhancement of fluorescence intensity at 530-550 nm and 630-650 nm. Intensity of fluorescence of different bone marrow macrophages was evaluated. It is suggested that a part of bone marrow macrophages has high affinity to erythroid tissue.     

An in vitro clonal assay of adherent stem cells (ASC) in mouse marrow

Hematopoietic stem cells with high proliferative capacity can be assayed when stromal bone marrow cultures are overlaid with limiting dilutions of marrow samples. This leads to hematopoietic growth after 4 weeks in a fraction of cultures, consistent with expectations based on Poisson statistics. It will be shown that monoclonal cultures are obtained that last from 2 to 15 weeks and that can generate up to several million mature granulocytes. The originating clone-forming cell is named adherent stem cell (ASC) because of its adherence to plastic or stromal surfaces. The ASC is comparable to the CFU-S in frequency, proliferative capacity and in its ability to give rise to CFU-S. As an unexpected additional finding we report that a mode of "clonal succession" was apparent in cultures which expressed more than one clone.     

Oct-4, Rex-1, and Gata-4 expression in human MSC increase the differentiation efficiency but not hTERT expression

Micro-environment seems to exert an important influence on human mesenchymal stem cell (MSC) differentiation and proliferative capacity in bone marrow as well as in culture ex vivo. Oct-4, Rex-1, and TERT genes are well-known for the maintenance of pluripotentiality differentiation and the proliferative capacity of embryonic stem cells. Some previous data report expression of these embryonic factors in selected clones from bone marrow adult stem cells. Our goal was to study expression of Oct-4, Rex-1, and TERT in primary cultured human MSC according to the serum concentration. In addition, we have studied the expression of Gata-4 since this factor plays a key role in organogenesis. We hypothesized that low serum concentration with appropriate growth factors may induce an undifferentiated status with a re-expression of embryonic factors and extend differentiation capacity. Thus, using a defined culture medium, we report on the increased expression of Oct-4, Rex-1, and Gata-4 in human MSC. We have correlated this expression to an increase in differentiation efficiency towards osteogenic and adipogenic phenotypes. Our data suggest that the culture medium used permits the emergence of adult stem cells with a high differentiation capacity and expression of embryonic factors. These cells may have important implications for cell therapy.     

Leucyl-leucine methyl ester treatment of donor cells permits establishment of immunocompetent parent----F1 chimeras that are selectively tolerant of host alloantigens

Treatment of murine lymphocytes with L-leucyl-L-leucine methyl ester (Leu-Leu-OMe) selectively removes natural killer cells, cytotoxic T lymphocyte precursors, and the capacity to cause lethal graft-vs-host disease, whereas bone marrow stem cell function and alloantigen-induced L3T4+ T helper function remains intact. The present studies assess the immunocompetence of allogeneic bone marrow chimeras established by reconstituting irradiated (C57BL/6 X DBA/2)F1 (B6D2F1) mice with Leu-Leu-OMe-treated C57BL/6 (B6) bone marrow and spleen cells. Spleen cells from such chimeras were found to have normal B and T cell mitogenic responses. Furthermore, levels of natural-killer cell function were comparable to those observed in B6----B6 syngeneic radiation chimeras established without Leu-Leu-OMe treatment of donor cells. Spleen cells from B6----B6D2F1 mice were identical with B6----B6 or B6 mice in allostimulatory capacity and thus contained no discernible cells of non-H-2b phenotype. Whereas B6----B6D2F1 spleen cells demonstrated alloproliferative and allocytotoxic responses toward H-2k bearing spleen cells, no H-2d specific proliferative or cytotoxic responses could be elicited. B6----B6D2F1 spleen cells did not suppress the generation of anti-H-2d or anti-H-2k proliferative or cytotoxic responses from control B6 spleen cells. Furthermore, addition of rat concanavalin A supernatants did not reconstitute anti-H-2d responses of B6----B6D2F1 chimeric spleen cells. Thus, Leu-Leu-OMe treatment of B6 donor cells not only prevents lethal graft-vs-host disease, but also permits establishment of long-lived parent----F1 chimeras that are selectively tolerant of host H-2 disparate alloantigens, but fully immunocompetent with respect to natural killer cell function, B and T cell mitogenesis, and anti-third party alloresponsiveness.     

Mitotic activity of rat bone marrow cells during injury

The mitotic regimen analysis in rat bone marrow cells was conducted 1, 3, 7, 14, 21 and 35 days after shock trauma. A sharp impairment of myelocyte reproductive function was registered against an increase in the mitotic index. It confirms a universal character of normal mitosis impairment in strong stresses, which was earlier established for epithelial tissues. Cell division disturbances in the bone marrow may be considered an pathogenic factor of a number of pathological processes occurring in the blood system in traumatic disease (anemia, immunodepression). A complex of drugs (sodium oxybutyrate, sodium oxiferriscarbon, Laevamizolum) is offered for the correction of proliferative processes in the bone marrow. This complex has no significant influence on mitotic index and causes relative reduction of pathological mitosis level, ensuring its earlier normalization.     

小鼠巨核系祖细胞增殖,分化特性的研究

小鼠骨髓细胞经7d培养后进行细胞形态学观察,可见不同发育阶段的巨核细胞及不同大小的巨核细胞集落。通过计数每个集落中的细胞数,可确定相应祖细胞的有丝分裂能力。结果表明,具有不同有丝分裂能力的祖细胞的体外增殖动力学有所不同。祖细胞的数量与其有丝分裂次数呈负相关(r=-0.986)。进行0、1、2和3次有丝分裂的祖细胞的阿糖胞苷自杀率分别为48.9,58.7,48.0和41.2％;放射敏感性的D_O值(Gy)分别为1.71,1.24,1.03和0.77,D_O值的大小与有丝分裂次数呈负相关(r=-0.958)。经3Gy全身照射后CFU-Meg与CFU-GM的恢复动态过程具有不同特点。     

Nuclear reprogramming: a key to stem cell function in regenerative medicine

The goal of regenerative medicine is to restore form and function to damaged tissues. One potential therapeutic approach involves the use of autologous cells derived from the bone marrow (bone marrow-derived cells, BMDCs). Advances in nuclear transplantation, experimental heterokaryon formation and the observed plasticity of gene expression and phenotype reported in multiple phyla provide evidence for nuclear plasticity. Recent observations have extended these findings to show that endogenous cells within the bone marrow have the capacity to incorporate into defective tissues and be reprogrammed. Irrespective of the mechanism, the potential for new gene expression patterns by BMDCs in recipient tissues holds promise for developing cellular therapies for both proliferative and post-mitotic tissues.     

Capacity of hematopoietic colony-forming cells to maintain their own population in the late periods after prolonged radiation exposure

The content of multipotent CFUs in bone marrow and their self-maintenance capacity were studied for 15 months following protracted external radiation of CBA mice at the total dose 10 Gy (0.5 Gy per day). The mean life shortening was 16% in the irradiated mice. The proliferating, maturating and functional pools returned to normal within 1-3 months after exposure. The stem cell pool did not return to the values seen in the same age controls till the end of the life of experimental animals and averaged 55% of normal. The self-maintenance capacity of bone marrow CFUs was 2.5-4.5-fold as decreased in the irradiated mice. The failure of this unique property of multipotent CFUs was principally due to the foregoing increase in their proliferative activity.