UMLS:C0026986 - FACTA Search

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Query: UMLS:C0026986 (myelodysplastic syndrome)
14,926 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Low-risk myelodysplastic syndromes (MDS), including refractory anemia and sideroblastic anemia, are characterized by increased apoptotic death of erythroid progenitors. The signaling pathways that elicit this pathologic cell death in MDS have, however, remained unclear. Treatment with erythropoietin in combination with granulocyte colony-stimulating factor (G-CSF) may synergistically improve the anemia in patients with MDS, with a concomitant decrease in the number of apoptotic bone marrow precursors. Moreover, we have previously reported that G-CSF inhibits Fas-induced caspase activation in sideroblastic anemia (RARS). The present data demonstrate that almost 50% of erythroid progenitor cells derived from patients with MDS exhibit spontaneous release of cytochrome c from mitochondria with ensuing activation of caspase-9, whereas normal erythroid progenitors display neither of these features. G-CSF significantly inhibited cytochrome c release and suppressed apoptosis, most noticeably in cells from patients with sideroblastic anemia. Furthermore, inhibition of caspase-9 suppressed both spontaneous and Fas-mediated apoptosis of erythroid progenitors in all low-risk MDS cases studied. We propose that the increased sensitivity of MDS progenitor cells to death receptor stimulation is due to a constitutive activation of the mitochondrial axis of the apoptotic signaling pathway in these cells. These studies yield a mechanistic explanation for the beneficial clinical effects of growth factor administration in patients with MDS, and provide a model for the study of growth factor-mediated suppression of apoptosis in other bone marrow disorders.
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PMID:Granulocyte colony-stimulating factor inhibits spontaneous cytochrome c release and mitochondria-dependent apoptosis of myelodysplastic syndrome hematopoietic progenitors. 1239 61

Increased apoptosis of hematopoietic progenitor cells has been implicated in the pathophysiology of cytopenias associated with myelodysplastic syndromes (MDSs), and inhibition by immunosuppression may account for the success of this treatment in some patients. We examined bone marrow and peripheral blood of 25 patients with chromosomal abnormalities associated with MDS (monosomy 7, trisomy 8, and 5q-) for evidence of apoptosis. When fresh bone marrow was examined, the number of apoptotic and Fas-expressing CD34 cells was increased in patients with trisomy 8, but decreased in monosomy 7, as compared with healthy control donor marrow. Fas expression was increased in the trisomy 8 cells and decreased in the monosomy 7 cells when compared with normal cells from the same patient. Trisomy 8 cells were more likely to express activated caspase-3 than were normal cells. For bone marrow cells cultured with Fas agonist or Fas antagonist, the percentage of cells with trisomy 8 was significantly decreased in most cases after Fas receptor triggering and increased by Fas ligand (Fas-L) antagonist (P < 0.01), suggesting increased Fas susceptibility of cells with trisomy 8. No such changes were seen in cultures of cells with 5q- or monosomy 7. Fas antagonist facilitated the expansion of cells with trisomy 8 only. Cells with trisomy 8 appear to be more susceptible to Fas-mediated apoptosis. Clinical data demonstrating the responsiveness of some patients with trisomy 8 to anti-thymocyte globulin (ATG) and cyclosporine (CsA) would favor an active role of the immune system in this syndrome.
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PMID:Fas-mediated apoptosis is important in regulating cell replication and death in trisomy 8 hematopoietic cells but not in cells with other cytogenetic abnormalities. 1239 49

Bone marrow failure has been regarded as one of the triad of clinical manifestations of paroxysmal noctumal hemoglobinuria (PNH), and PNH in turn has been described as a late clonal disease evolving in patients recovering from aplastic anemia. Better understanding of the pathophysiology of both diseases and improved tests for cell surface glycosylphosphatidylinositol (GPI)-linked proteins has radically altered this view. Flow cytometry of granulocytes shows evidence of an expanded PNH clone in a large proportion of marrow failure patients at the time of presentation: in our large NIH series, about 1/3 of over 200 aplastic anemia cases and almost 20% of more than 100 myelodysplasia cases. Clonal PNH expansion (rather than bone marrow failure) is strongly linked to the histocompatability antigen HLA.-DR2 in all clinical varieties of the disease, suggesting an immune component to its pathophysiology. An extrinsic mechanism of clonal expansion is also more consistent with knock-out mouse models and culture experiments with primary cells and cell lines, which have failed to demonstrate an intrinsic proliferative advantage for PNH cells. DNA chip analysis of multiple paired normal and PIG-A mutant cell lines and lymphoblastoid cells do not show any consistent differences in levels of gene expression. In aplastic anemia/PNH there is surprisingly limited utilization of the V-beta chain of the T cell receptor, and patients' dominant T cell clones, which are functionally inhibitory of autologous hematopoiesis, use identical CDR3 regions for antigen binding. Phenotypically normal cells from PNH patients proliferate more poorly in culture than do the same patient's PNH cells, and the normal cells are damaged as a result of apoptosis and overexpress Fas. Differences in protein degradation might play a dual role in pathophysiology, as GPI-linked proteins lacking an anchor would be predicted to be processed by the proteasome machinery and displayed in a class I H.A. context, in contrast to the normal pathway of cell surface membrane recycling, lysosomal degradation, and presentation by class II HLA. The strong relationship between a chronic, organ-specific immune destructive process and the expansion of a single mutant stem cell clone remains frustratingly enigmatic but likely to be the result of interesting biologic processes, with mechanisms that potentially can be extended to the role of inflammation in producing premalignant syndromes.
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PMID:The relationship of aplastic anemia and PNH. 1243 Sep 20

In order to observe the expression of Fas, FasL and Bcl-2 and apoptosis of bone marrow CD34(+) cells in patients with myelodysplastic syndrome (MDS), and to explore the relation between the expression of these antigens and apoptosis, the expression of Fas, FasL and Bcl-2 and apoptosis of bone marrow CD34(+) cell were evaluated by flow cytometry in 26 patients with MDS including 9 cases of refactory anemia (RA), 1 case of RA with ringed sideroblasts (RAS), 9 cases of RA with excess blasts (RAEB) and 7 cases of RAEB in transformation (RAEB-t), 10 patients with acute myeloid leukemia (AML) and 6 control patients with normal bone marrow. The results showed that the expression of Fas and FasL of CD34(+) cells significantly increased in all types of MDS patients compared with control group (P < 0.01). The expression of Bcl-2 on CD34(+) cells in RAEB and RAEB-t patients was much higher as compared with that in control group (P < 0.01), but there was no significant difference between RA/RAS patients and control group (P > 0.05). The expression rates of Fas on CD34(+) cells were almost identical in all kinds of MDS, but there was significant difference on the expression of Bcl-2 (RA/RAS < RAEB < RAEB-t). Apoptosis of CD34(+) cells significantly increased in RA/RAS and RAEB patients compared with control group (P < 0.01), but there was no difference between RAEB-t and control group. Moreover, apoptosis of CD34(+) cells in control much higher than that in AML group (P < 0.01). There was no correlation between the expression of Fas or FasL and apoptosis on CD34(+) cell of MDS patients. Nevertheless, there was a negative correlation between the expression of Bcl-2 and apoptosis. It is concluded that apoptosis of CD34(+) cells was affected by a lot of factors in MDS, in which Bcl-2 is an important factor of depressing apoptosis. During the progress from MDS to AML, apoptosis changes from overgoing to deficiency in CD34(+) cell.
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PMID:[Expression of Fas, FasL and Bcl-2 and apoptosis of bone marrow CD34+ cells in patients with myelodysplastic syndrome]. 1284 12

Hematopoietic stem cell transplants (SCT) are used in the treatment of neoplastic diseases, in addition to congenital, autoimmune, and inflammatory disorders. Both autologous and allogeneic SCT are used, depending on donor availability and the type of disease being treated, resulting in different morbidity and outcomes. In both types of SCT, immune regulation via graft manipulation is being studied, although with highly different targeted outcomes. In general, autologous SCT have lower treatment-related morbidity and mortality, but a higher incidence of tumor relapse, and graft manipulation targets immune augmentation and/or the reduction of immune tolerance. In contrast, allogeneic SCT have a higher incidence of treatment-related morbidity and mortality and a significantly longer time of disease progression, and the targeted outcomes or graft manipulation focus on a reduction in graft versus host disease (GVHD). One source of the increased relapse rate and shorter overall survival (OS) following high dose chemotherapy (HDT) and autologous SCT is the immune tolerance that limits host response, both innate and antigen (Ag) specific, against the tumor. The immune tolerance that is observed is due in part to the tumor burden and prior cytotoxic therapy. Therefore, graft manipulation, as an adjuvant therapeutic approach in autologous SCT, is primarily focused on non-specific or specific immune augmentation using cytokines and vaccines. Recently, manipulation of the infused product as a form of cellular therapy has begun to also focus on approaches to reduce immune tolerance found in transplant patients, both prior to and following HDT and SCT. To this end, graft manipulation to reduce the presence of Fas Ligand (FasL)-expressing cells or interleukin (IL)10 and tumor growth factor (TGF)beta production has been proposed. In contrast to autologous transplantation, graft manipulation during allogeneic transplantation is used extensively. This includes limiting the infusion of T cells within the product or as a donor leukocyte infusion (DLI), resulting in a reduction in GVHD and the induction of long-term survivors. Indeed, allogeneic SCT provide the only curative therapy for patients with chronic myelogenous leukemia (CML), refractory acute leukemia, and myelodysplasia. The curative potential of allogeneic SCT is reduced, however, by the development of GVHD, a potentially lethal T-cell-mediated immune response targeting host tissues [Int. Arch. Allergy Immunol. 102 (1993) 309, J. Exp. Med. 183 (1996) 589]. The morbidity and mortality associated with GVHD limit this technology, resulting focus on those patients who have no alternative therapeutic options or who have advanced disease. Thus, allogeneic SCT provide one of the few statistically supported demonstrations of therapeutic efficacy by T cells (comparison of allogeneic to autologous transplantation). In contrast to autologous transplantation, control of GVHD following allogeneic SCT focuses on immune suppression and the induction of tolerance. Here too, graft manipulation is appropriate, and there are numerous studies of T-cell depletion to reduce GVHD, with or without the isolation and infusion of T cells as DLI. Additional strategies are examining the isolation and infusion of T cells with graft versus leukemia (GVL) activity to reduce GVHD and/or the infusion of genetically manipulated and/or selected cellular populations (monocytes or dendritic cells (DC)) to induce tolerance. Therefore, depending upon the type of transplant, the goals associated with graft manipulation can be radically different. In this review, we emphasize using graft manipulation to regulate immune tolerance and anergy in association with SCT. Although this paper focuses on hematopoietic SCT, it should be noted that these strategies are relevant to conditions other than neoplastic and congenital diseases, including solid organ transplants, and autoimmune and inflammatory diseases.
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PMID:Hematopoietic stem cell graft manipulation as a mechanism of immunotherapy. 1286 Jan 68

Several apoptosis-inducing systems, including Fas/Fas ligand and TNF-related apoptosis-inducing ligand (TRAIL) and its receptors, are upregulated in myelodysplastic syndrome (MDS). FLIP (FLICE (FAS-associated death-domain-like IL-1beta-converting enzyme)-inhibitory protein)) was identified as an inhibitor of FAS and TRAIL signals. Here, we characterized FLIP(Long) (FLIP(L)) and FLIP(Short) (FLIP(S)) expression in bone marrow mononuclear cells (BMMNCs) and in CD34+ cells of 29 MDS patients, and in 17 normal volunteers. The expression was correlated with apoptotic indices. In CD34+ cells, FLIP(L) levels were higher among normal individuals than in MDS patients (P=0.04). Among total BMMNC, FLIP(L) levels also tended to be higher in normal subjects than in MDS patients, although this difference was not significant (P=0.71). FLIP(L) levels in CD34+ cells were negatively correlated with apoptosis in both normal and MDS marrows (P=0.03). FLIP(Short) RNA expression was higher in MDS patients than in normal controls in both BMMNC (P=0.03) and CD34+ cells (P=0.08). In contrast to FLIP(L), FLIP(St) levels were positively correlated with apoptosis. At the protein level FLIP was most readily detectable in patients with high blast counts. The data suggest that FLIP(L) and FLIP(S) are differentially regulated, and that the relative levels of both isoforms play a role in the regulation of apoptosis in MDS.
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PMID:Expression of FLIP(Long) and FLIP(Short) in bone marrow mononuclear and CD34+ cells in patients with myelodysplastic syndrome: correlation with apoptosis. 1456 11

Purine nucleoside phosphorylase (PNP) deficiency is an autosomal recessive metabolic disorder characterized by severe combined immunodeficiency and by complex neurologic symptomatology including ataxia, developmental delay, and spasticity. Herein we report severe marrow dysplasia in a patient with PNP deficiency. Drug-related marrow dysfunction was unlikely, and marrow virological studies were negative. A preleukemic myelodysplastic syndrome was also unlikely due to normal marrow CD34+ cells, colony growth in clonogenic assay of marrow mononuclear cells, apoptosis rate, and Fas expression on marrow nucleated cells, as well as morphologic improvement of the marrow dysplasia after normal red blood cell transfusion. The patient's marrow stroma showed hypersensitivity to irradiation and undetectable PNP enzyme activity similar to peripheral lymphocytes. This is the first report of PNP deficiency associated with increased lymphocyte and marrow stromal sensitivity to irradiation. We conclude that marrows from patients with PNP deficiency might have hypersensitivity to irradiation and can develop dysplastic morphology, caused either directly or indirectly by the inherited enzymatic defect.
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PMID:Purine nucleoside phosphorylase deficiency associated with a dysplastic marrow morphology. 1471 4

Erythropoiesis is a complex multistep process encompassing the differentiation of hemopoietic stem cells to mature erythrocytes. The steps involved in this complex differentiation process are numerous and involve first the differentiation to early erythoid progenitors (burst-forming units-erythroid, BFU-E), then to late erythroid progenitors (colony-forming units-erythroid) and finally to morphologically recognizable erythroid precursors. A key event of late stages of erythropoiesis is nuclear condensation, followed by extrusion of the nucleus to produce enucleated reticulocytes and finally mature erythrocytes. During the differentiation process, the cells became progressively sensitive to erythropoietin that controls both the survival and proliferation of erythroid cells. A normal homeostasis of the erythropoietic system requires an appropriate balance between the rate of erythroid cell production and red blood cell destruction. Growing evidences outlined in the present review indicate that apoptotic mechanism play a relevant role in the control of erythropoiesis under physiologic and pathologic conditions. Withdrawal of erythropoietin or stimulation of death receptors such as Fas or TRAIL-Rs leads to activation of a subset of caspase-3, -7 and -8, which then cleave the transcription factors GATA-1 and TAL-1 and trigger apoptosis. In addition, there is evidence that a number of caspases are physiologically activated during erythroid differentiation and are functionally required for erythroid maturation. Several caspase substrates are cleaved in differentiating cells, including the protein acinus whose activation by cleavage is required for chromatin condensation. The studies on normal erythropoiesis have clearly indicated that immature erythroid precursors are sensitive to apoptotic triggering mediated by activation of the intrinsic and extrinsic apoptotic pathways. These apoptotic mechanisms are frequently exacerbated in some pathologic conditions, associated with the development of anemia (ie, thalassemias, multiple myeloma, myelodysplasia, aplastic anemia). The considerable progress in our understanding of the apoptotic mechanisms underlying normal and pathologic erythropoiesis may offer the way to improve the treatment of several pathologic conditions associated with the development of anemia.
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PMID:Apoptotic mechanisms in the control of erythropoiesis. 1520 42

To explore the difference of negative regulatory factors among T lymphocyte subsets in bone marrow (BM) of myelodysplastic syndromes (MDS) and their relations to apoptotic gene Fas, different lymphocyte subsets in BM were categorized by monoclonal antibodies with 3 color fluorescence using flow cytometry, and the intracellular cytokines such as tumor necrosis factor-alpha (TNF-alpha), interferon-gamma (IFN-gamma) were determined following marrow cells culture. Then Fas mRNA of bone marrow mononuclear cells (BMMNC) were examined by RT-PCR. The results showed that TNF-alpha, IFN-gamma levels in BM of MDS both increased, the former produced by cells CD4+CD45RO+, CD8+CD45RO+, the latter by cells CD4+CD45RO+, CD8+CD45RO+, CD8+CD45RA+, in which the cells CD8+CD45RO+ were dominant. Fas mRNA expression had relationship with IFN-gamma produced by T cells but not with TNF-alpha. It is concluded that in hematopoietic microenvironment of MDS, not only the T lymphocyte subsets are in disorder, but also negative regulatory factors secreted by T lymphocyte increase. T lymphocytes play an important role in producing IFN-gamma in patients with MDS.
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PMID:[Study on negative regulatory factors in bone marrow mononuclear cells of myelodysplastic syndromes]. 1549 20

Excessive intramedullary apoptosis is central in the pathogenesis of myelodysplastic syndromes (MDS). Growth-inhibiting cytokines, the Fas/FasLigand pathway, and autoreactive cytotoxic T-lymphocytes have been identified to be important proapoptotic factors in MDS. In normal hematopoiesis, alpha4beta1 and alpha5beta1 integrin-mediated interactions between progenitors and fibronectin are critical for progenitor cell survival. In this study, we have used flow cytometry to quantify the expression levels of members of the beta1 integrin family on CD34(+) marrow progenitors in 27 untreated patients with MDS, three with s-AML, and 25 control subjects. In MDS, we observed that nonapoptotic progenitors significantly downregulate cell surface expression levels of alpha4 and beta1 integrin chains compared with healthy controls. Downregulation of alpha4, beta1, and also alpha5 was present in MDS patients with > or =25% apoptotic progenitors, irrespective of their French, American, British subcategory. Reduced cell surface expression levels of alpha4, alpha5, and beta1 did also correlate with decreased in vitro adhesiveness to fibronectin fragments. Therefore, our observations suggest that downregulation of alpha4beta1 and alpha5beta1 integrins on CD34(+) progenitors could be a newly identified proapoptotic mechanism in MDS.
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PMID:CD34+ marrow progenitors from MDS patients with high levels of intramedullary apoptosis have reduced expression of alpha4beta1 and alpha5beta1 integrins. 1551 Feb 9

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