EC:3.4.24.11 - FACTA Search

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Query: EC:3.4.24.11 (CD10)
9,792 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Expression of decay-accelerating factor (DAF or CD55) and of CD59 during hematopoietic cell development in normal bone marrow and on peripheral blood leukocytes were characterized by three-color immunofluorescence experiments. With this technique cell subsets were identified by forward light scatter, orthogonal light scatter, and two cell-surface antigens. For each cell lineage, specific combinations of two monoclonal antibodies labeled with different fluorochromes were used. DAF or CD59 were then quantitated on the defined cell subsets from the fluorescence signal of the respective antibody conjugated with a third fluorochrome. Early uncommitted hematopoietic progenitor cells (CD34+, CD38-) all expressed both proteins homogeneously. Initial commitment to the erythroid (CD71+, CD45dim), myeloid (CD33+), or B lymphocyte (CD10+) lineages was not associated with changes in DAF or CD59 levels. With erythroid development, i.e., after loss of CD45 and decrease of CD71, expression of both proteins decreased. With myeloid maturation, expression of CD59 remained constant and expression of DAF varied. During neutrophil maturation, DAF decreased initially and then reemerged on maturing neutrophils concurrently with the appearance of CD16 (Fc gamma RIII), whereas during monocyte maturation, DAF increased concurrently with up-regulation of CD14. With B cell development, expression of DAF increased concurrently with down-regulation of CD10 and up-regulation of CD20, whereas expression of CD59 diminished slightly late in B cell maturation. Analysis of peripheral blood elements showed that monocytes, neutrophils, and B lymphocytes expressed both proteins homogeneously, but that in contrast to other cell subsets, which all expressed CD59, only a subset of (CD3+) T lymphocytes and (CD16+) Natural killer cells expressed DAF. The absence of DAF was not related to CD4 or CD8 expression or to the presence of activation markers (CD25+, CD38+), memory cell markers (CD58+, CD45RO+), or virgin T cell markers (CD45RA+), but was correlated with expression of CD11b (CR3) and CD11c (gp150/95). Although CD21+ (CR2) and CD35+ (CR1) cells all expressed DAF, CD11a (LFA-1) levels correlated inversely with those of DAF. Although the presence of CD55 and CD59 on early progenitor cells and throughout hematopoietic cell development is consistent with the requirements for both proteins in protection of host cells from complement-mediated injury, the physiological relevance of the unique patterns of variation for each cell lineage is unclear. Nevertheless, the availability of a detailed DAF and CD59 expression map in normal marrow will facilitate analyses of alterations during hematopoietic development that may occur in hematological disorders including paroxysmal nocturnal hemoglobinuria (PNH).
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PMID:Expression of the DAF (CD55) and CD59 antigens during normal hematopoietic cell differentiation. 128 89

We performed an immunohistochemical analysis of frozen sections from testicular biopsies from 23 children with acute lymphoblastic leukemia. Eleven cases were infiltrated by leukemia. Tumor cells were immunostained by a panel of antibodies that identified CD10, CD43, CD19, CD3, CD7, and MHC class I and II. The immunoreactivity of normal testicular components was also studied. Normal testis showed no CD10 reactivity. Wide variation in the number of stromal macrophages identified by CD11c was found. Transferrin receptor (CD71) was expressed by some stromal macrophages, by seminiferous tubules, and by Leydig cells. B lymphocytes were absent from the testicular stroma but small numbers of T lymphocytes were consistently present. MHC class I and II were expressed by most stromal cells but not by seminiferous tubules.
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PMID:An immunohistochemical study of testicular biopsies in childhood acute lymphoblastic leukemia: reactivity of normal testicular components and leukemic infiltrates. 128 64

Twenty patients were treated with chemotherapy to mobilize progenitors into the blood. Peripheral blood stem cells were quantitated in peripheral blood or leukapheresis products using colony assays and flow cytometric measurement of CD34+ cells. In four patients where complete sets of serial samples were obtained, the appearance of CD34+ cells preceded the increase in CFU-GM by 24-48 h. Peak levels of CD34+ cells ranged from 0.6-5% and coincided with the peak increase in CFU-GM. Mobilized CD34+ cells contained subsets expressing CD33, CD13, CD45RA, CD38, HLA-DR, CD61 and CD41. Subsets of CD34+ cells expressing CD33, CD13, or CD45RA represent committed myeloid progenitors. In contrast to bone marrow CD34+ cells, few mobilized CD34+ cells expressed CD71, CD7, CD19 or CD10. Prompt engraftment of granulocytes greater than 500 x 10(6)/l at a median of 13 days and platelets greater than 50 x 10(9)/l at a median of 15 days was observed in patients reconstituted with mobilized cells. These data indicate that CD34+ cells mobilized during recovery from chemotherapy are predominantly myeloid in phenotype and contain few actively proliferating cells or cells with lymphoid phenotypes.
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PMID:Characterization of chemotherapy mobilized peripheral blood progenitor cells for use in autologous stem cell transplantation. 138

HIV-related non-hodgkin lymphomas currently occur in 5 to 8% of AIDS patients. AIDS-related lymphomas are high-grade tumors with the morphologic characteristics of either small noncleaved cell lymphomas of the Burkitt type or large cell centroblastic and immunoblastic lymphomas. Mixed features may be found, making classification difficult. Useful methods for characterizing AIDS-related non-hodgkin's lymphomas include immunophenotypic studies using B-cell differentiation and activation antigens (HLA-DR, CD10, CD19, CD20, CD21, CD22, CD23, CD38), evaluation of expression of surface immunoglobulins (IgS), activation and proliferation (CD25, CD30, CD71, Ki67), and identification of T-cell markers (CD1, CD2, CD3, CD4, CD5, CD7, CD8). Cases studied were of the B-cell type. Comparison with morphologic features revealed that Burkitt's lymphomas were monoclonal and expressed B-cell markers (CD10, CD19, CD20, CD22, CD38) and surface immunoglobulins, especially IgM kappa. This immunophenotype is similar to that of large cell or centroblastic non-hodgkin's lymphomas, suggesting that Burkitt lymphomas originate from centrofollicular cells. Immunoblastic non-hodgkin's lymphomas were monotypic or polytypic and expressed CD10 and CD38 antigens but not the other B-cell antigens Furthermore, a very large number of cells stained positively with the Ki67 antibody demonstrating that most lymphoma cells were undergoing cycling.
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PMID:[Non-Hodgkin's lymphoma and AIDS: histopathologic features]. 144 58

The clinical utility of the indirect immunofluorescence (IF) and the alkaline phosphatase-anti-alkaline phosphatase (APAAP) techniques was compared in 103 newly diagnosed acute leukaemia patients immunophenotyped using a panel of 19 monoclonal antibodies (MoAb). In spite of slight variations in the percentages of cells reacting with particular MoAbs when comparing the two methods we found no discrepancies in the final classification of each case. In ANLL (n = 73) the best correlation between the two methods was found for CDw65 which is a good screening marker, and for CD15 having a prognostic significance. In ALL (n = 30) the best correlation was observed for CD19 and CD10, both of great diagnostic importance. The following antigens present both in membrane and in cytoplasm displayed higher positivity with the APAAP than in IF HLA-Dr, CD71 and CD11b in ANLL, CD22 and HLA-Dr in nonT-ALL and CD3 in T-ALL. The important advantages of the APAAP technique are: 1) its use with routinely performed bone marrow or peripheral blood films, which can be stored before staining, 2) the possibility of correlating morphology with immunological characterization and documentation of the results.
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PMID:[Comparison of clinical usefulness of immunophenotyping of leukemia using the immunofluorescence and immunoenzyme APAAP methods]. 148 65

An immunofluorescence study of the adherent layer of human long-term bone marrow cultures (HLTBMC) revealed the following surface markers on the different stromal cell populations: stromal fibroblastic cells CD10+, FIB86.3+, CD13+, CD71+; adipocytes CD10+, FIB86.3-, CD13+, CD71-/+; and macrophages CD10-/+, FIB86.3+, CD13+, CD71-/+, CD14+, CD33+, CD25+, HLA-DR+, CD4+, CD19+, CD45+. The markers of the stromal fibroblastic cells in HLTBMC were similar to those of twice-passaged fibroblasts not only from bone marrow and spleen, but also from a hemopoietic non-supportive organ such as the skin. Some of the cultured human umbilical vein endothelial cells used as controls were found to be CD25+, demonstrating for the first time the interleukin-2 receptor p55 chain on normal non-hemopoietic cells. The stromal fibroblastic cells are overrepresented compared to the small non-macrophage hemopoietic cell population in the adherent layer of HLTBMC. In addition, silver staining revealed an increased reticulin content in most of the HLTBMC. An excessive growth of stromal fibroblastic cells and an excessive deposition of their product, the reticulin fibers, are the hallmark of myelofibrosis. The finding of equivalent observations in HLTBMC suggests that the hitherto unexplained, premature quenching of hemopoiesis in HLTBMC might at least partly be due to mechanisms similar to those operating in myelofibrosis in vivo.
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PMID:Stromal populations and fibrosis in human long-term bone marrow cultures. 165 97

Recombinant interferon alpha enhanced the MHC class I antigen density on human leukaemia/lymphoma cell lines REH, U-937 and HL-60, as measured by immunocytofluorometry using specific monoclonal antibodies. A similar effect was induced (as demonstrated in REH cells), also by human leukocyte interferon-alpha. The latter, however, caused no major alterations in the expression of leukocyte common antigen (ICA; CD45) and transferrin receptor (CD71) in the cell lines examined. In REH cells, there was no interferon-induced alteration of CD10 antigen (CALLA), which in this cell line is markedly down-regulated by 12-0-tetradecanoyl-phorbol-13-acetate (TPA). A decrease of CD4 antigen density on the cell membrane was induced by interferon-alpha in monoblastoid U-937 cells. No induction of MHC class I and II antigens by interferon-alpha was found in K-562 cell subline.
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PMID:Interferon alpha-induced modulation of leukocyte cell surface antigens: immunocytofluorometric study with human leukaemia/lymphoma cell lines. 168 18

Multiparameter flow cytometry was applied on normal human bone marrow (BM) cells to study the lineage commitment of progenitor cells ie, CD34+ cells. Lineage commitment of the CD34+ cells into the erythroid lineage was assessed by the coexpression of high levels of the CD71 antigen, the myeloid lineage by coexpression of the CD33 antigen and the B-lymphoid lineage by the CD10 antigen. Three color immunofluorescence experiments showed that all CD34+ BM cells that expressed the CD71, CD33, and CD10 antigens, concurrently stained brightly with anti-CD38 monoclonal antibodies (MoAbs). In addition, the CD38 antigen was brightly expressed on early T lymphocytes in human thymus, characterized by CD34, CD5, and CD7 expression. Only 1% of the CD34+ cells, 0.01% of nucleated cells in normal BM, did not express the CD38 antigen. The CD34+, CD38- cell population lacked differentiation markers and were homogeneous primitive blast cells by morphology. In contrast the CD34+, CD38 bright cell populations were heterogeneous in morphology and contained myeloblasts and erythroblasts, as well as lymphoblasts. These features are in agreement with properties expected from putative pluripotent hematopoietic stem cells; indeed, the CD34 antigen density decreased concurrently with increasing CD38 antigen density suggesting an upregulation of the CD38 antigen on differentiation of the CD34+ cells. Further evidence for a strong enrichment of early hematopoietic precursors in the CD34+, CD38- cell fraction was obtained from culture experiments in which CD34+ cell fractions with increasing density of the CD38 antigen were sorted singularly and assayed for blast colony formation. On day 14 of incubation, interleukin-3 (IL-3), IL-6, and GM-CSF, G-CSF, and erythropoietin (Epo) were added in each well. Twenty-five percent of the single sorted cells that expressed CD34 but lacked CD38 antigen gave rise to primitive colonies 28 to 34 days after cell sorting. The ability to form primitive colonies decreased rapidly with increasing density of the CD38 antigen. During 120 days of culture, up to five sequential generations of colonies were obtained after replating of the first-generation primitive colonies. This study provides direct evidence for the existence of a single class of progenitors with extensive proliferative capacity in human BM and provides an experimental approach for their purification, manipulation, and further characterization.
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PMID:Sequential generations of hematopoietic colonies derived from single nonlineage-committed CD34+CD38- progenitor cells. 170 33

Four-color flow cytometry was used with a cocktail of antibodies to identify and isolate CD34+ hematopoietic progenitors from normal human peripheral blood (PB) and bone marrow (BM). Mature cells that did not contain colony forming cells were resolved from immature cells using antibodies for T lymphocytes (CD3), B lymphocytes (CD20), monocytes (CD14), and granulocytes (CD11b). Immature cells were subdivided based on the expression of antigens found on hematopoietic progenitors (CD34, HLA-DR, CD33, CD19, CD45, CD71, CD10, and CD7). CD34+ cells were present in the circulation in about one-tenth the concentration of BM (0.2% v 1.8%) and had a different spectrum of antigen expression. A higher proportion of PB-CD34+ cells expressed the CD33 myeloid antigen (84% v 43%) and expressed higher levels of the pan leukocyte antigen CD45 than BM-CD34+ cells. Only a small fraction of PB-CD34+ cells expressed CD71 (transferrin receptors) (17%) while 94% of BM-CD34+ expressed CD71+. The proportion of PB-CD34+ cells expressing the B-cell antigens CD19 (10%) and CD10 (3%) was not significantly different from BM-CD34+ cells (14% and 17%, respectively). Few CD34+ cells in BM (2.7%) or PB (7%) expressed the T-cell antigen CD7. CD34+ cells were found to be predominantly HLA-DR+, with a wide range of intensity. These studies show that CD34+ cells and their subsets can be identified in normal PB and that the relative frequency of these cells and their subpopulations differs in PB versus BM.
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PMID:Identification and comparison of CD34-positive cells and their subpopulations from normal peripheral blood and bone marrow using multicolor flow cytometry. 171 May 12

The majority of non-Hodgkin's lymphomas (NHLs) are of B-cell lineage, with less than 20% of cases being of T-cell lineage. The B-cell NHLs phenotypically correspond to normal cells in the mid stages of normal differentiation. More specifically, by their expression of B-cell activation antigens, these tumors are the neoplastic counterparts of normal activated B cells. The follicular lymphomas--including the small cleaved, mixed small and large cell, and large cell types, as well as the small noncleaved cell (Burkitt's) lymphomas--represent malignant expansions of normal germinal center B cells by their expression of pan-B cell antigens, B-cell activation antigens, and CD10 (CALLA). The diffuse lymphomas also correspond to normal activated B cells. The small lymphocytic lymphomas express the low-affinity IL-2 receptor and CD5, both of which are induced on normal B cells following mitogen stimulation. The other diffuse B-cell NHLs similarly express activation antigens and resemble "transformed" B cells. The T-cell NHLs generally correspond to normal activated CD4+ T cells. These tumors--which include most peripheral T-cell lymphomas, cutaneous T-cell lymphomas, and HTLV-I-associated adult T-cell leukemias/lymphomas--express antigens induced on activated T cells, including IL-2 and transferrin receptors (CD25 and CD71, respectively), as well as HLA-DR. The lymphoblastic lymphomas, which are generally of T-cell lineage, phenotypically correspond to stages of intrathymic differentiation, often by their coexpression of CD4 and CD8, as well as expression of CD1. It remains controversial whether the immunophenotype of lymphoblastic lymphoma differs significantly from T-cell acute lymphoblastic leukemia. Since immunologic heterogeneity of NHL was first observed, attempts have been made to employ the data as a prognostic variable. Early studies suggested that lineage derivation or expression of markers of proliferating cells affected outcome in NHL. However, these reports were often retrospective, included various histologies, and did not treat patients uniformly. More recent prospective studies with relatively uniformly treated patients, predominantly involving DLCL, suggest that certain immunologically defined subgroups may have significantly different clinical outcomes. However, additional clinical studies will be necessary before treatment options are based upon immunologic markers.
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PMID:Immunologic markers in non-Hodgkin's lymphoma. 193 59

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