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)

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

By using monoclonal antibodies, two-color immunofluorescence techniques and flow cytometry, we evaluated the surface marker phenotypes of lymphocyte subsets in cord blood samples from fetuses in the second trimester of pregnancy. The results indicate that cells of the T-, B- and NK-cell lineages as well as precursor cells can be detected in fetal blood at 18-20 weeks of gestation. At this stage of development, variable proportions of T and B lymphocytes express surface molecules, such as the CD1, CD10, CD38, CD45RA, indicative of a precursor or 'naive' state; on the other hand, the CD57 molecule is not detectable on the membrane of NK and T cells, and the RO isoform of the CD45 leukocyte antigen is synthesized by a low percentage of T cells. We suggest that the observed phenotypic peculiarities of the lymphoid cells might be related to the easy induction of tolerance that occurs in the early ontogenetic stages of the immune system.
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PMID:Ontogeny of human lymphocytes. Two-color fluorescence analysis of circulating lymphocyte subsets in fetuses in the second trimester of pregnancy. 178 14

Neutrophil research relies largely on studies with highly purified cells. Yet the isolation procedures induce changes in surface expression of several proteins. We used a large panel of monoclonal antibodies (MoAbs) to characterize in detail the phenotypic changes during isolation and stimulation of human neutrophils. Centrifugation on density gradients appears to be the crucial step that causes an increase in expression of antigens not detectable on neutrophils in whole blood samples (cytochrome b558 recognized by MoAb 7D5; and CD10) or expressed at significantly lower levels (CD11a, CD11b, CD11c, CD13, CD16, CD45, and CD67). Other antigens were unaffected by the density gradient centrifugation step (CD32, CD54, CD58, Leu-8, HLA class I). Upregulation of antigens was also determined by stimulation of purified neutrophils. Upregulation of CD63 was an excellent marker for release from azurophil granules. We subsequently related the surface antigen expression to functional activities of purified neutrophils. From these experiments, we concluded that 7D5-as "early activation" marker--does not necessarily discriminate between primed or resting neutrophils with respect to NADPH oxidase activity.
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PMID:Membrane surface antigen expression on neutrophils: a reappraisal of the use of surface markers for neutrophil activation. 190 73

Phenotypes of cells from 12 patients with ATL were analysed by means of a fluorescence-activated cell sorter by utilizing a panel of monoclonal antibodies. A majority of the cells from peripheral blood coexpressed the antigens against MAbs CD2, CD3, CD4, CD5, Ti (WT31), CD25, CD38, CD45, and CD29, but did not express the antigens against CD1, CD13, CD14, CD33, CD36, CD10, CD19, CD20, CD21, CD24, CD41, CD42, CD45RA, CD56, and CD57. The expression of antigen for TQ-1 or Leu8 was variable. Surface immunoglobulins were not detected. Phenotypes of cultured cells established by utilizing recombinant interleukin II were similar to those of the uncultured peripheral blood lymphoid cells except for the lack of expression of CD8. By means of two-color fluorescence, the ATL cells possessing CD4 in peripheral blood and culture coexpressed CD29, but did not express CD45RA. The suppression of PWM-induced B-cell immunoglobulin synthesis by normal T and B cells was found in five cases in the presence of ATL cells. The ATL cells demonstrated helper T-cell phenotypes (CD4+, CD29+) with suppressor function, paradoxically. We conclude that the phenotype of the ATL cells was CD4+, CD29+, and CD45RA- but that the function of these cells was of suppressor T-cells. Our results inevitably suggest the possible existence of suppressor T-cells with CD4+, CD29+ phenotype in persons without evidence of any underlying hematologic disorder.
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PMID:Discordance between phenotype and function of Japanese adult T cell leukemia cells. 214 86

The low frequency of plasma cells and the lack of specific cell surface markers has been a major obstacle for a detailed characterization of plasma cells in normal human bone marrow. Multiparameter flow cytometry enabled the identification of plasma cells in normal bone marrow aspirates. The plasma cells were located in a unique position in the correlation of forward light scattering, orthogonal light scattering, and immunofluorescent-labeled CD38. The identity of the sorted cell populations was confirmed by microscopic examination of Wright's stained slides and slides stained for cytoplasmic immunoglobulin using polyclonal antibodies reactive with light chains; ie, anti-kappa fluorescein isothiocyanate and anti lambda phycoerythrin (PE). The purity of the sorted plasma cells was greater than 97% (n = 4). The average frequency of plasma cells in normal bone marrow aspirates was low--0.25% of the nucleated cells (n = 7)--but surprisingly consistent between individuals (SD = .05; range 0.14% to 0.30%). A detailed analysis showed two distinct populations of plasma cells: (1) A population relatively smaller by forward light scattering expressed CD22, CD35, and sigE and was identified as early plasma cells (ie, lymphoplasmacytoid), and (2) a population larger by forward light scattering lacked these markers and was identified as mature plasma cells. The antigenic profile of the normal plasma cells was determined in two-color immunofluorescence studies. The expression of cell surface immunoglobulin G (IgG), IgA, IgE, IgD, IgM, and the cell surface antigens CD10, CD11b, CD13, CD11c, CD14, CD15, CD16, CD19, CD22, CD20, CD33, CD35, CD45, and HLA-DR was determined on the plasma cells. A significant heterogeneity in cell surface antigen expression was observed within the plasma cell population. Unexpectedly, myeloid-specific cell surface antigens such as CD33 and CD13 and the early B-cell antigen identified by CD10 were expressed on a proportion of plasma cells. These observations imply that the association of myeloid and early B-cell markers described in multiple myeloma may not be associated with the neoplasia but is a normal phenomenon.
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PMID:Identification and characterization of plasma cells in normal human bone marrow by high-resolution flow cytometry. 222 23

Immunophenotypic analyses of immature stage (day 19-23), intermediate stage (day 28-32), mature stage (day 34-37), and older stage (day 42-44) human hemopoietic mast cells from colonies grown in semi-solid agar cultures were performed to study the ontogeny and identity of this cell type and its relationship to other leukocytes. Intermediate to mature stage mast cells were positive with the YB5.B8 mouse monoclonal antibody, (McAb) specific for human mast cells, whereas the reactivity of immature mast cells with this McAb was inconsistent and older cells were generally negative. Mast cells at all stages of maturation were strongly positive for IgE receptor sites and negative with the Bsp-1 McAb, specific for human basophils. Mast cells at all stages of maturation were also strongly positive with the monocyte McAbs RPA-M1 (CD11), positive with the monocyte McAb OKM5 and the monocyte/granulocyte McAbs BMA-210 and MY7 (CD13), strongly positive with the B-cell markers J5 (CD10) and anti-IgM, and positive with the plasma cell marker PCA-1 and to a lesser extent with the activated B-cell marker CD23. The mast cells were also strongly positive with anti-CD45 to the common leukocyte antigen and positive with an antibody to HLA-DR and an antibody to FVIIIC. They were negative for specific T-cell markers. The diversity of this phenotype supports the current concept that mast cells originate from the pluripotential progenitor cells in the bone marrow.
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PMID:Immunophenotypic analyses of cultured hemopoietic mast cells. 239 49

Recently, great interest has been shown in the histological identification of small cell tumours of childhood--nephroblastoma (Wilms' tumour), neuroblastoma, rhabdomyosarcoma and Ewing's sarcoma--using immunohistochemical methods. However, several antigens operationally specific for leucocyte typing in blood and marrow are also expressed on cells of epithelial and neural origin. We undertook phenotypic characterization of 17 non-haemopoietic small cell tumours of childhood using a panel of 30 monoclonal antibodies to leucocyte, epithelial and cytoskeletal antigens using a sensitive alkaline phosphatase-anti-alkaline phosphatase technique on cryostat sections of fresh tumour. Our results demonstrated frequent expression of the leucocyte-associated antigens CD10 (CALLA), CD9 (p24) and CDw32 (FcRII) in these small cell tumours and occasional expression of MHC class II (HLA-DR) and HNK-1 antigens. However, the leucocyte-associated antigens CD45 (leucocyte common), CD22 (pan B-cell), CD11b (C3bi receptor), CD15 (Lewisx) or CDw42 (platelet gp Ib) were not detected on any tumour. Aberrant expression of desmin, neurofilament and UJ13A antigen was found in nephroblastoma and of epithelial-associated markers (CIBr17 and 43-9F) in neuroblastoma. Our results also demonstrated broad reactivity in frozen section with two monoclonal antibodies specific for melanoma (NKI/C-3) or epithelial cells (OM-1) in paraffin sections. Hence, it is necessary to include monoclonal antibodies to CD45 and pan-epithelial antigens, e.g. LP34 (cytokeratin) or HEA125 for the precise immunohistochemical identification of small round cell malignancies of childhood.
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PMID:Phenotypic characterization of non-haemopoietic small cell tumours of childhood with monoclonal antibodies to leucocytes, epithelial cells and cytoskeletal proteins. 254

During 1987, striking advances were made in defining the receptors and ligands for cell-to-cell adhesion interactions involving leukocytes. In 1988, two major leukocyte differentiation antigens, CD10 (cALLA) and CD45 (LCA, T200), were shown to be enzymes while two other markers, CD4 and CD8, were found to be associated with an enzyme. In this article, Ed Clark and Jeff Ledbetter discuss recent findings in the emerging area of leukocyte cell surface enzymology with emphasis on CD45, a membrane-associated protein tyrosine phosphatase (PTPase)2,3.
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PMID:Leukocyte cell surface enzymology: CD45 (LCA, T200) is a protein tyrosine phosphatase. 255 46

The expression of TCR-associated molecules was examined in human fetal and postnatal tissues. From gestational wk 7 onward in the fetal liver, putative prothymocytes have been identified with cytoplasmic CD3 positivity (cCD3+). These immature cells are TdT- and do not express membrane CD3 (mCD3-) or TCR beta identified by beta F1, but show CD7 and CD45 positivity without CD1, CD2, CD5, CD4, CD8, CD10, and class II Ag. Their high proliferative activity is indicated by greater than 85% Ki67 positivity. After the 10th wk, beta F1+, mCD3+ cells also appear in the liver and these are mostly Ki67- but no TCR gamma delta-bearing cells can be identified at such an early stage of extrathymic development. In the mCD3- TdT-fetal thymus (10 1/2 to 18th wk) cCD3+, mCD3- CD1-blasts proliferate (Ki67+) and lack TCR-beta or TCR-gamma delta. The TdT-, CD1+ cortical thymocytes develop into TCR-beta + and WT31-positive (TCR-alpha beta +) cells. Subsequently TdT-positive thymocytes become detectable around 19 to 20 wk, and in such glands the peak of proliferative activity is seen among TdT+, cCD3+ cells which appear to acquire, in a regular sequence, cytoplasmic beta F1 (TCR-beta), mCD3, and TCR-alpha beta (WT31 positivity) together with the loss of TdT and Ki67 positivity. A newly described transitional population of cells is TdT-, beta F1+ but exhibits no detectable WT31 positivity. These cells correspond to the CD1+, mCD3+ thymocytes and are probably the targets of thymic selection. The cells of the TCR-gamma delta lineage, detected by mAb TCR-delta-1 and delta TCS1, are rare (0.02 to 0.5%) among thymocytes from gestational wk 10 1/2 onward through the whole span of thymic development, but these cells include a proportion (18 to 59%) of cells expressing CD1 Ag, suggesting that these TCR-gamma delta cells differentiate in the thymus. Among the CD1+, TCR-gamma delta + thymocytes, no TdT positivity can be detected.
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PMID:The expression of T cell receptor-associated proteins during T cell ontogeny in man. 278 27

We have correlated the intensity of expression of CD45 Ag (T200 common leukocyte Ag) with mAb reactive with various lineages of hemopoietic cells in normal human bone marrow by using two-color immunofluorescence on a flow cytometer. Mature T lymphocytes (CD3+) and NK cells (CD16+ or CD11b+) expressed CD45 at the highest intensity. B lymphoid cells (CD19+) had three distinct levels of CD45 Ag expression. The bright CD45(3+) cells were mature B cells (CD19+, CD20+), whereas the less intense CD45(2+) cells were less mature B lymphoid cells (CD19+, CD10+). The dim CD45+ cells were very early, B lymphoid precursor cells (CD19+, CD10(2+), CD34+). The intensity of CD45 expression increased as cells matured in the monocytic lineage (CD14+, CD11b+). Among marrow granulocytic cells, CD45 intensity did not change on cells during maturation. Within the erythroid lineage, the most immature cells were CD45+ dim, and CD45 expression decreased during erythroid maturation to become undetectable on mature E. Hemopoietic progenitor cells (CD34+) expressed low levels of CD45 Ag. Expression of CD45R on marrow cells also showed intensity differences on different lineages. All NK cells (CD16+) were positive for CD45R, whereas only about one-half of the T lymphocytes (CD3+) were positive for CD45R. Almost all the cells in the erythroid and myelomonocytic lineages were CD45R-. Quantitative differences in expression of CD45R were observed on marrow B lymphoid cells which were correlated with the expression of CD45. The results show that quantitative changes in CD45 Ag expression accompany the differentiation and maturation of cells in the bone marrow. Comparisons with CD45R showed that this Ag was not always correlated with CD45. Since these Ag are the products of the same gene, these data indicate that the regulation of expression of the T200 molecules during normal hemopoietic development must be both quantitative and qualitative.
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PMID:Flow cytometric analysis of human bone marrow. IV. Differential quantitative expression of T-200 common leukocyte antigen during normal hemopoiesis. 296 86

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