Fas-induced in vivo apoptosis in bone marrow: anti-Fas mAb-induced elimination and successive proliferation of Fas-expressing cells especially those of myeloid lineage.

A single administration of agonistic anti-Fas mAb RK8 into mice decreased the number of bone marrow cells especially Mac1+ and Gr1+ cells of myeloid lineage. These cells, which were shown to be Fas-positive in normal bone marrow, were directly eliminated in vivo by Fas-mediated apoptosis. After the elimination of Fas-positive bone marrow cells, bone marrow was reconstituted by successive increase of numbers of Gr1(low) and Mac1(low) myeloid precursor cells expressing high levels of Fas, which are minor constituents in normal bone marrow. The increased cells consisted at least two components, Gr1(dull) Mac1+ cKit+ cells and Gr1(intermediate) Mac1+ cKit- cells, both of which were shown to be sensitive to Fas-induced apoptosis in vivo. Thus, Fas is functional in normal bone marrow and Fas-induced apoptosis in bone marrow enhances marked proliferation of Fas-expressing myeloid precursor cells in vivo.     

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.     

Chronic inflammation,the tumor microenvironment and carcinogenesis

Chronic inflammation often precedes or accompanies a substantial number of cancers. Indeed, anti-inflammatory therapies have shown efficacy in cancer prevention and treatment. The exact mechanisms that turn a wound healing process into a cancer precursor are topics of intense research. A pathogenic link has been identified between inflammatory mediators, inflammation related gene polymorphisms and carcinogenesis. Animal models of cancer have been instrumental in demonstrating the diversity of mechanisms through which every tumor compartment and tumor stage may be affected by the underlying inflammatory process. In this review, we focus on the interaction between chronic inflammation, tumor stem cells and the tumor microenvironment. We summarize the proposed mechanisms that lead to the recruitment of bone marrow derived cells and explore the genetic and epigenetic alterations that may occur in inflammation associated cancers.     

Immunofluorescent study of the origin of connective tissue cells in xenogenic radiation chimeras under normal conditions and in aseptic inflammation]

The origin of elements of the focus of aseptic inflammation and the normal subcutaneous connective tissue in the xenogenic (mouse-rat) radiation chimaeras was investigated by means of indirect Coons method with antiserum to the rat bone marrow cells. The cells of the imflammation focus (leucocytes, macrophages, fibroblasts or fibroblast-like cells, polynuclear giant cells of foreign bodies), as well as leucocytes, macrophages and some fibroblasts of the normal subcutaneous connective tissue, were shown to take their origin from the transplanted bone marrow cells of the donor.     

Regulatory effects of opioid peptides on bone marrow hematopoiesis in stress

It was shown that inhibition of bone marrow hyperplasia disappear due to injection of leu-enkephalin and dalargin as well as the increase of plasma leu-enkephalin by means of D-phenylalanine on the immobilized mice. The effect of enkephalin on hematopoietic precursor cells may be realized by inhibition of T-lymphocytes migration to bone marrow. Besides, direct specific influence of dalargin on myelokaryocytes is observed.     

The primary role of murine bone marrow in the production of natural killer cells. A cytokinetic study

The normal steady state production of natural killer (NK) cells in the bone marrow and spleen was characterized with cytokinetic technics. We developed a protocol to enrich for NK cells in bone marrow and demonstrate that target binding can be used as a criterion for marrow NK cells if nonspecifically "sticky" cells are eliminated. The selected population of B cell-depleted bone marrow lymphoid cells was comprised mainly of lymphocytes, of which 80% were NK-1.1+. B cell-depleted bone marrow lymphocytes that bound to YAC-1 could be characterized as two populations on the basis of morphology and proliferative status: large, proliferating target-binding cells (TBC), of which 25% were in S phase of the mitotic cycle, and small postmitotic TBC. Pulse and chase studies indicated that the small TBC in bone marrow were derived from an immediate proliferating precursor, presumably the large TBC, which were, in turn, derived from a precursor population that was more rapidly proliferating. In contrast, few if any splenic TBC were labeled after a 30-min pulse with [3H]TdR and significant numbers of labeled TBC did not appear in the spleen until 2 or more days after the pulse label. Surprisingly, some of the splenic TBC were relatively long lived and survived 2 mo or longer. These studies are the first to directly characterize the production of NK cells in situ in normal marrow. We demonstrate that the marrow is the primary site of production of NK cells and that little, if any, proliferation of NK cells occurs in the periphery of unstimulated mice. The data suggest the existence in the bone marrow of at least three compartments in the NK lineage: a rapidly proliferating NK precursor population, a less rapidly proliferating population of large TBC, and a population of small postmitotic TBC.     

Effect of cytotoxic lymphocytes obtained by in vitro immunization with syngeneic lymphoma cells on pluripotent hemopoietic cells

The possibility of the presence of leukemia-associated antigens on pluripotent hemopoietic cells was studied with the aid of immune lymphocytes, cytotoxic against mouse syngeneic lymphoma cells. Cytotoxic lymphocytes were obtained during immunization in vitro of C57BL/6 mouse splenocytes by syngeneic T lymphoma EL-4 cells in the presence of interleukin-2. Specific cytotoxic activity of immune lymphocytes as regards EL-4 cells was not blocked by addition of normal bone marrow cells. Incubation of the bone marrow with immune killers did not lead to a decrease in the number of colony-forming units in the spleen. It was shown that using cytotoxic lymphocytes the total killing of lymphoma cells might be achieved in a mixture of bone marrow and lymphoma cells, whereas pluripotent precursor cells might be retained.     

Heterologous antiserum to rat lymphohemopoietic precursor cells.

Lymphohemopoietic precursor cells in rat bone marrow are members of a subset of lymphocyte-like cells that bears the bone marrow lymphocyte antigen (BMLA) and that lacks antigens present on peripheral B and T cells. This was demonstrated by two experimental approaches. In the first, bone marrow cells with the potential to form hemopoietic colonies in spleen (CFU-S), to repopulate lumphoid tissues and blood, and to rescue lethally irradiated recipients were enriched approximately 10-fold by a fractionation procedure designed to isolate a "null" population of bone marro lymphocytes. In the second approach, the lymphohemopoietic precursor cell activity in bone marrow was completely abrogated by opsonization with rabbit antiserum (ALSBM) raised against this "null" population of bone marrow cells. Precursor cell activity was not affected by treatment with antiserum to T and B cells. Quantitative cross-absorption studies showed that the antigen detected by ALSBM on lymphohemopoietic precursor cells had the same cellular distribution as did the previously described bone marrow lymphocyte antigen. It is likely that this antigen is present both on pluripotent stem cells and on committed progenitors of the myelocytic, erythrocytic and lymphocytic series.     

Effects of polysaccharide from Thuja occidentale L. on stromal precursor cells of hematopoietic microenvironment in mice]

The effect of high molecular polysaccharide subfraction from Thuja occidentale L. (TPS) on stromal precursor cells of hematopoietic microenvironment under the "steady-state" conditions and after sublethal irradiation was investigated. The stromal precursor cells of different stages of differentiation were detected by the implantation of mouse bone marrow under the renal capsule of syngeneic intact recipients and chimeras. It was shown that TPS did not occur the toxic influence on the stromal precursor cells and provided the defense effect on them under the strong (6 Gy) radiation damages.     

Immunotoxin-mediated elimination of clonogenic tumor cells in the presence of human bone marrow

An immunotoxin was synthesized with pokeweed antiviral protein and an IgG1 monoclonal antibody directed against human B and pre-B cells. The B43 murine monoclonal antibody does not react with normal human bone marrow precursor cells. The immunotoxin bound to all Burkitt's lymphoma cell lines that were tested but not to human peripheral blood T cells. The ability of antibody-toxin conjugate to inhibit human lymphoblast cell lines was checked in a clonogenic assay system. The immunotoxin in the presence of chloroquine elicited 5.8 logs of killing of Burkitt's lymphoma cells (B-ALL). The efficient inhibition of clonogenic growth of B-ALL cells was not affected by the presence of normal bone marrow cells. The immunotoxin was not very toxic to pluripotent stem cells; less than 50% of the stem cells were lost under conditions where 5.6 logs of clonogenic lymphoma cells were eliminated from a 100-fold excess of normal marrow cells. Further, when assayed by long-term human bone marrow cultures, immunotoxin treatment did not result in a significant loss of pluripotent precursor cells.     

Isolation and enrichment of skeletal muscle progenitor cells from mouse bone marrow

There is great interest in the therapeutic potential of non-hematopoietic stem cells obtained from bone marrow called mesenchymal stem cells (MSCs). Rare myogenic progenitor cells in MSC cultures have been shown to convert into skeletal muscle cells in vitro and also in vivo after transplantation of bone marrow into mice. To be clinically useful, however, isolation and expansion of myogenic progenitor cells is important to improve the efficacy of cell transplantation in generating normal skeletal muscle cells. We introduced into MSCs obtained from mouse bone marrow, a plasmid vector in which an antibiotic (Zeocin) resistance gene is driven by MyoD and Myf5 enhancer elements, which are selectively active in skeletal muscle progenitor cells. Myogenic precursor cells were then isolated by antibiotic selection, expanded in culture, and shown to differentiate appropriately into multinucleate myotubes in vitro. Our results show that using a genetic selection strategy, an enriched population of myogenic progenitor cells, which will be useful for cell transplantation therapies, can be isolated from MSCs.     

Analyzing the cellular contribution of bone marrow to fracture healing using bone marrow transplantation in mice

The bone marrow is believed to play important roles during fracture healing such as providing progenitor cells for inflammation, matrix remodeling, and cartilage and bone formation. Given the complex nature of bone repair, it remains difficult to distinguish the contributions of various cell types. Here we describe a mouse model based on bone marrow transplantation and genetic labeling to track cells originating from bone marrow during fracture healing. Following lethal irradiation and engraftment of bone marrow expressing the LacZ transgene constitutively, wild type mice underwent tibial fracture. Donor bone marrow-derived cells, which originated from the hematopoietic compartment, did not participate in the chondrogenic and osteogenic lineages during fracture healing. Instead, the donor bone marrow contributed to inflammatory and bone resorbing cells. This model can be exploited in the future to investigate the role of inflammation and matrix remodeling during bone repair, independent from osteogenesis and chondrogenesis.     

In vitro differentiation of reprogrammed murine somatic cells into hepatic precursor cells

Recently, a new approach to reprogram somatic cells into pluripotent stem cells was shown by fusion of somatic cells with embryonic stem (ES) cells, which results in a tetraploid karyotype. Normal hepatocytes are often polyploid, so we decided to investigate the differentiation potential of fusion hybrids into hepatic cells. We chose toxic milk mice (a model of Wilson's disease) and performed initial transplantation experiments using this potential cell therapy approach. Mononuclear bone marrow cells from Rosa26 mice were fused with OG2 (Oct4-GFP transgenic) ES cells. Unfused ES cells were eliminated by selection with G418 for OG2-Rosa26 hybrids and fusion-derived colonies could be subcloned. Using an endodermal differentiation protocol, hepatic precursor cells could be generated. After FACS depletion of contaminating Oct4-GFP-positive cells, the hepatic precursor cells were transplanted into immunosuppressed toxic milk mice by intrasplenic injection. However, five out of eight mice showed teratoma formation within 3-6 weeks after transplantation in the spleen and liver. In conclusion, a hepatic precursor cell type was achieved from mononuclear bone marrow cell-ES cell hybrids and preliminary transplantation experiments confirmed engraftment, but also showed teratoma formation, which needs to be excluded by using more stringent purification strategies.     

Skeletal muscle precursors do not arise from bone marrow cells

Cell and Tissue Research - This paper tests the hypothesis that bone marrow stem cells can give rise to circulating muscle precursor cells. Irradiated host mice were reconstituted with bone marrow...     

Evidence for the presence of precursor B cells in normal and in hormonally bursectomized chick embryos

Embryonic bone marrow of normal and hormonally bursectomized chicks was examined for the presence of hematopoietic precursor cells capable of migrating to the thymus and bursa and of differentiating into functional T and B cells, respectively. Following transfer of chromosomally marked bone marrow of normal and in ovo bursectomized 14-day-old embryos to 14-day-old γ-irradiated embryonic recipients, donor cells proliferated in the marrow, thymus, and bursa of recipients, and differentiated to PHA- and Con A-responsive T cells as well as to dextran sulfate- and anti-immunoglobulin-responsive B cells. In contrast, when marrow of 2-day-old hatched normal and in ovo-bursectomized donors was transferred to 14-day-old embryonic recipients, donor cells repopulated only the marrow and thymus of recipients which was followed by differentiation to Con A- or PHA-responsive T cells, but the same donor cells failed to proliferate in the bursa and there was no differentiation to functional B cells of donor type. The data were fitted to a model of T- and B-cell differentiation from the stem cell level and they suggest the presence of separate populations of committed precursor T (PT) and precursor B (PB) cells in the marrow of normal and in ovo bursectomized embryos with a bursa-independent selective disappearance of PB cells from the marrow during the late embryonic period.     

A granulocytosis-inducing tumor inhibits the production of B lymphocytes in murine bone marrow

Mice bearing a transplantable CE mammary carcinoma have been shown to have greatly augmented rates of neutrophil production coupled with a marked diminution of bone marrow lymphocytes. The objective of the present study was to test whether the loss of lymphocytes, and especially of B cells, from the bone marrow and spleen of tumor-bearing animals was due to a reduced rate of cell production and if so, at what level this response was regulated. A modified 3H-TdR pulse and chase analysis was used to assess the rates of production of small lymphocytes and B cells (stained for c mu and s mu) at weekly intervals after CE tumor transplantation. 3H-TdR was infused continuously for 24 hr, and radioautographs were prepared of bone marrow and spleen cells 0, 24, and 48 hr after termination of the infusion. Pre-B cells (c mu+s mu-) essentially disappeared from the femoral bone marrow by the end of 1 wk of tumor growth, followed by a great reduction in the number of c mu+s mu+ cells in the marrow and s mu + cells in the spleen. Although pre-B cells appeared in the peripheral marrow (caudal vertebrae, metatarsal bones) and spleen of tumor-bearing mice, these cells could not compensate for the continued decrease in the numbers of more mature B cells. In normal mice, during the 48-hr chase period, newly formed, 3H-TdR-labeled, small lymphocytes and s mu+ cells continued to emerge from the prelabeled precursor compartment at a steady rate, but after 1 wk of tumor growth, the number of small lymphocytes and s mu+ cells emerging from the precursor compartment fell steadily during the 48-hr chase period. During the second and third weeks of tumor growth, a steady state appears to have been reached in B cell production, which was at a level approximately 10 times below that of normal. Because pre-B cells are normally maintained by a less mature precursor population (2), the initial disappearance of c mu+s mu- cells suggests that the CE mammary carcinoma exerts its modulatory influence on primary B cell production by inhibiting or eliminating the cells that eventually feed into the pre-B compartment. The nature of the regulatory factors apparently secreted by the tumor and the more precise identity of the target cells are under investigation.     

Eosinophilopoiesis in a murine model of allergic airway eosinophilia: involvement of bone marrow IL-5 and IL-5 receptor alpha

The airway inflammation in asthma is dominated by eosinophils. The aim of this study was to elucidate the contribution of newly produced eosinophils in airway allergic inflammation and to determine mechanisms of any enhanced eosinophilopoiesis. OVA-sensitized BALB/c mice were repeatedly exposed to allergen via airway route. Newly produced cells were identified using a thymidine analog, 5-bromo-2'-deoxyuridine, which is incorporated into DNA during mitosis. Identification of IL-5-producing cells in the bone marrow was performed using FACS. Bone marrow CD3+ cells were enriched to evaluate IL-5-protein release in vitro. Anti-IL-5-treatment (TRFK-5) was given either systemically or directly to the airways. IL-5R-bearing cells were localized by immunocytochemistry. Repeated airway allergen exposure caused prominent airway eosinophilia after three to five exposures, and increased the number of immature eosinophils in the bone marrow. Up to 78% of bronchoalveolar lavage (BAL) granulocytes were 5-bromo-2'-deoxyuridine positive. After three allergen exposures, both CD3+ and non-CD3 cells acquired from the bone marrow expressed and released IL-5-protein. Anti-IL-5 given i.p. inhibited both bone marrow and airway eosinophilia. Intranasal administration of anti-IL-5 also reduced BAL eosinophilia, partly via local effects in the airways. Bone marrow cells, but not BAL eosinophils, displayed stainable amounts of the IL-5R alpha-chain. We conclude that the bone marrow is activated by airway allergen exposure, and that newly produced eosinophils contribute to a substantial degree to the airway eosinophilia induced by allergen. Airway allergen exposure increases the number of cells expressing IL-5-protein in the bone marrow. The bone marrow, as well as the lung, are possible targets for anti-IL-5-treatment.     

Generation of megakaryocytes and platelets from human subcutaneous adipose tissues

Recent advances in regenerative medicine have created a broad spectrum of stem cell research. Among them, tissue stem cell regulations are important issues to clarify the molecular mechanism of differentiation. Adipose tissues have been shown to contain abundant preadipocytes, which are multipotent to differentiate into cells including adipocytes, chondrocytes, and osteoblasts. In this study, we have first shown that megakaryocytes and platelets can be generated from adipocyte precursor cells. Human adipocyte precursor cells were cultured in conditioned media for 12 days to differentiate adipocytes, followed by 12 days of culture in media containing thrombopoietin. The ultrastructures of adipocyte precursor cell- and bone marrow CD34-positive cell-derived megakaryocytes and platelets were similar. In addition, adipocyte precursor cell-derived platelets exhibited surface expression of P-selectin and bound fibrinogen upon stimulation with platelet agonists, suggesting that these platelets were functional. This is the first demonstration that human subcutaneous adipocyte precursor cells can generate megakaryocyte and functional platelets in an in vitro culture system.     

Population Dynamics of Clonogenic Stromal Precursor Cells in Hemopoietic and Lymphoid Organs during Bone Marrow Regeneration

This paper describes our study on the regeneration of hemopoietic and stromal components of bone marrow after mechanically emptying the medullar cavity of the guinea pig tibia. The intensity of hemopoiesis was determined from the number of hemopoietic cells, while the concentration and total number of stromal precursor cells were used to estimate the ability of the bone marrow to produce stromal structures, including its ability to restore a specific microenvironment. We found that there was no direct correlation between the recovery characteristics of hemopoietic and stromal cells. An increase in the population size of stromal precursor cells takes place early after curettage, and stromal fibroblasts become phosphatase-positive according to Gomori, which is characteristic of osteogenic tissue. We have also demonstrated that curettage of 3–5 tubular bones results in the growth of this cell population in the bone marrow of nonoperated bones and even in the spleen, which in guinea pigs participates only in lymphopoiesis.