Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.4.24.11 (CD10)
 9,792 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

For 60 cases of acute lymphoblastic leukemia (ALL) immunological typing was done concurrently by the avidin-biotin-peroxidase method using cytocentrifuged smears and by flow cytofluorometry for the study of surface antigens. The use of a large panel of antibodies detecting differentiation antigens allowed us to sub-classify 57/60 cases as 43 B-lineage ALLs and 14 T-lineage ALLs. The two types of ALL can be accurately distinguished by the expression of the antigens recognized by the antibodies of the clusters of differentiation CD19 (B4) and CD7 (Leu 9). Almost perfect agreement was obtained between the results of the two methods for antigens DR, CD10 (cALLA;J5) and CD7. A number of discordances were observed with other antigens [CD19 (B4), CD20 (B1), CD22 (To15), CD1 (T6), CD2 (T11), CD4 (T4), CD8 (T8), CD3 (T3), T9, T10]. In spite of these discordances, the avidin-biotin-peroxidase method can predict the lineage involved in most ALLs with a high degree of reliability. Nevertheless, for weakly expressed surface antigens (such as B4 and B1) the immunocytological method is less sensitive than flow cytofluorometry and can only approximately determine the stage of differentiation of neoplastic cells. Furthermore, the existence of cases which are at the same time negative with flow cytofluorometry and positive with immunocytology is consistent with the intracytoplasmic expression of certain differentiation antigens. Thus in the course of lymphoid differentiation, intra-cytoplasmic expression of T3, To15 and possibly J5 precedes their expression at the cell surface.
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PMID:Immunological typing of acute lymphoblastic leukemia: concurrent analysis by flow cytofluorometry and immunocytology. 354 Apr 62

In the present study, the expression of two NK-associated antigens (CD56 and CD16) together with six 'classically' considered lymphoid-related markers (TDT,CD19,CD10,CD7,CD2,CD4) has been analyzed by appropriate dual combinations in 265 acute myelogenous leukemia (AML) patients. Among the lymphoid markers, CD4 and CD7 were those most frequently expressed by AML blast cells (58% and 21.6%, respectively) while the incidence of positivity for the other markers was lower: CD19 (7.8%), CD10 (10.9%), CD2 (11.4%), and TDT (11.3%). Regarding NK-associated antigens, CD56 was present in 41% of AML cases analyzed whereas CD16 was detected in only 23%. All but one of the CD16+ cases coexpressed the CD56 antigen. The expression of these antigens was not associated with the degree of cell differentiation assessed either by morphological or immunophenotypical criteria, with the exception of the correlation observed between monocytic leukaemias and the expression of the CD4, CD56, and CD16 antigens. Regarding the prognostic value of the markers investigated, CD56 expression was associated with a tendency for a better outcome whereas CD7 was the only antigen that had an adverse influence on the survival of AML patients.
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PMID:Expression of NK and lymphoid-associated antigens in blast cells of acute myeloblastic leukemia. 750 72

A 75-year-old man developed a cluster of differentiation (CD)4-positive but human T-cell lymphotropic virus type I (HTLV-I)-negative T lymphoid neoplasm with overwhelming cutaneous involvement and mild thrombocytosis. Twelve courses tetrahydropyranyl adriamycin, cyclophosphamide, vincristine and prednisone (THP-COP) combination chemotherapy led him to complete remission. After four months of complete remission, however, atypical immature cells (blasts) appeared in peripheral blood and bone marrow. Surface marker analysis revealed the blasts to be CD2-, CD3-, CD4-, CD5-, CD7+, CD8-, CD10, CD13 +/-, CD19-, CD20-, CD25-, CD33+ and human leukocyte antigen-DR (HLA-DR+). Staining for myeloperoxidase, esterases, PAS and platelet peroxidase were all negative. The patient was diagnosed as having both CD7 and CD33 positive acute myeloid leukemia (AML). The relation between the T cell lymphoid neoplasm and AML was not clear. Thrombocytosis became more marked after acute leukemia occurred and the platelet count varied in parallel with the blast cell count in peripheral blood. When the leukemic cell count was high, thrombopoietic activity could be detected in the serum. In addition, conditioned medium obtained from primarily-cultured blasts had detectable thrombopoietic activity, which implied the blasts directly to produce a thrombopoietic factor(s). Analysis of the serum concentration for cytokines with associated thrombopoietic activity indicated that the blasts possibly produced a thrombopoietic factor(s) distinct from interleukin (IL)6, IL3, leukemia inhibitory factor (LIF), erythropoietin and granulocyte macrophage-colony stimulating factor. To our knowledge, this is the first reported case of an acute myeloid leukemia with marked thrombopoiesis (more than 2000 x 10(3)/microliter of maximum platelet count in peripheral blood.
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PMID:Acute myeloid leukemia possibly producing thrombopoietic factor(s). 750 2

A method for automatic lineage assignment of acute leukemias was developed. Input are eight list mode data files acquired with a FACScan flow cytometer. For each cell, four parameters are measured: forward light scatter, orthogonal light scatter, fluorescein fluorescence, and phycoerythrin fluorescence. Eight data files are acquired in the following sequence: unstained, isotype controls, CD10/CD19, CD20/CD5, CD3/CD22, CD7/CD33, HLADR/CD13, and CD34/CD38. First, each of the data files 3 to 8 are clustered independently employing an algorithm based on nearest neighbors. Next, the clusters are associated across the data files to form cell populations, using the assumption of light scatter invariance across tubes for each population. The mean positions of each cell population are fed into a decision tree. The decision tree first identifies normal cell populations, i.e., monocytes, neutrophils, eosinophils, basophils, NK cells, T-lymphocytes, and B-lymphocytes. After elimination of the normal cell populations from the data space, the residual cell populations are classified as B-lineage ALL, T-lineage ALL, AML, AUL, B-CLL, or unknown. The effectiveness of this novel approach is shown with case studies of B-lymphoid, T-lymphoid, and Myeloid acute leukemias.
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PMID:Automatic lineage assignment of acute leukemias by flow cytometry. 750 22

A strategy to phenotype rare populations of hematopoietic cells expressing the cell-surface marker CD34 was studied. The antigenic phenotype of umbilical core blood (CB) CD34+ cells was investigated using flow cytometry and compared with the mRNA-phenotype determined by cDNA-polymerase chain reaction (cDNA-PCR) analysis. The cDNA-PCR method allowed an mRNA evaluation of small numbers of cells. Monoclonal antibodies and oligonucleotide primers that recognize myeloid, lymphoid, erythroid and platelet/megakaryocytic cell membrane antigens or corresponding mRNA transcripts were used. Evaluation by flow cytometry showed that the vast majority of CD34+ CB cells coexpressed CD38, CD18, HLA-DR, and CD33. Rare subpopulations of CD34+CD38-, CD34+CD18-, CD34+HLA-DR-, and CD34+CD33- were also identified. A large proportion of CD34+ CB cells expressed CD13, CD45R, and to a lesser extent CD71. The CD36, CD51, and CD61 antigens were identified on a small number of CD34+ cells. The three-color flow cytometry analysis showed that CD34+ cells stained with antibodies to CD61 and CD36 or CD51 can be divided into subsets that may represent progenitor cells committed to the erythroid and/or megakaryocytic lineage. A variety of other lineage-specific cell-surface antigens including pre-T-cell marker CD7 and markers of early B cells, ie, CD10 and CD19, were not coexpressed with CD34+. Using the cDNA-PCR it was seen that the mRNA phenotype of a small number of sorted CD34+ cells (purity > 98%) was negative for the markers CD2, CD14, CD16, CD20, CD21, CD22, CD41b, and glycophorin A that are expressed on differentiated cells but positive for CD34, CD7, CD19, CD36, and CD61. The results suggest that circulating CD34+CD7+ and CD34+CD19+ CB cells cannot be distinguished by flow cytometry but can be detected by cDNA-PCR. This indicates that CB either contains very low numbers of these progenitors or that the antigen density of CD7 and CD19 on CD34+ cells is below the detection limit of the flow cytometer. In contrast to flow cytometry, cDNA-PCR allows the phenotypic analysis of cells even if their number is small. Thus, the cDNA-PCR method can be useful in linking phenotype analyses, ie, markers of differentiation, to studies on gene expression within rare populations of hematopoietic stem cells.
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PMID:Phenotype analysis of hematopoietic CD34+ cell populations derived from human umbilical cord blood using flow cytometry and cDNA-polymerase chain reaction. 751 40

Using two-color flow cytometry, we analyzed the subpopulations of CD34+ stem and progenitor cells in the blood and bone marrow from 10 patients with hematological malignancies. Peripheral blood mononuclear cells (PBMNC) harvested after chemotherapy (high-dose Ara C and VP-16) and rhG-CSF, and BM mononuclear cells, which were obtained before chemotherapy (BMMNCbefore) and after the stem cell collection (BMMNCafter) were isolated by Ficoll-Hypaque centrifugation. The purified cells were stained with FITC-conjugated anti-CD34 antibody and one of the following PE-conjugated antibodies: anti-CD7, CD10, CD11b, CD11c, CD13, CD19, CD33, CD38, CD45RO, CD56, and HLA-DR. CD34+ PBMNC harvested and the CD34+ BMMNCafter expressed CD13 and CD33 more frequently than CD34+ BMMNCbefore but expressed CD10 and CD19 less frequently than CD34+ BMMNCbefore. These data suggested that harvested PBMNC contain more myeloid lineage committed progenitors than BMMNCbefore, which might contribute to the rapid recovery of neutrophils after peripheral blood stem cell transplantation. No significant phenotypic differences of CD34+ cells between harvested PBMNC and BMMNCafter were observed except for the expression of CD11c. CD34+ PBMNC harvested coexpressed CD11c more frequently than both CD34+ BMMNCbefore and CD34+ BMMNCafter, which expression might be associated with commitment to the monocyte lineage.
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PMID:Phenotypic differences of CD34-positive stem cells harvested from peripheral blood and bone marrow obtained before and after peripheral blood stem cell collection. 751 35

Severe combined immunodeficiencies (SCID), a heterogeneous group of disorders of infancy, are fatal without treatment directed at immunologic reconstitution. Allogeneic bone marrow transplantation (BMT), which is such a treatment presents some unique features in SCID, especially when T-lymphocyte-depleted HLA haploidentical allografts are used. Donor-type T lymphopoiesis, less often B lymphopoiesis, develops, whereas myelopoiesis remains the recipient-type. Little is known about the engrafting cells in this peculiar lymphohematopoietic chimerism and the pathophysiology of the frequent failure of B-lymphocyte reconstitution. To address these issues, we purified CD34+ BM cells from a patient with selective T-lymphocyte reconstitution after HLA haploidentical BMT for B-SCID. Phenotypic analysis of CD34+ cells was performed by flow cytometry, and functional studies of donor- and recipient-type CD34+ cells were performed in vitro. Donor-type CD34+ cells, constituting approximately 2% of the CD34+ cells, were detected; both CD34+ HLA-DR- cells and CD34+ cells coexpressing B-(CD10 and CD19) and T-(CD2 and CD7) lymphocyte-associated cell surface molecules. Donor-type CD34+ cells coexpressing myeloid-associated molecules (CD13, CD14, CD15, and CD33) were undetectable. However, donor-type CD34+ myeloid progenitors could be shown in functional assays. Recipient-type CD34+ cells coexpressing B- and T-lymphocyte- as well as myeloid-associated molecules were detected, but recipient-type CD34+ cells could not be driven into T-lymphocyte differentiation in vitro. These findings provide evidence for engraftment of multipotent stem cells in our patient with B-SCID. Furthermore, the failure of B-lymphocyte reconstitution cannot be explained by lack of donor-type B-lymphocyte progenitors. Donor-type B lymphopoiesis and myelopoiesis are prevented by an unidentified mechanism.
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PMID:Evidence for engraftment of donor-type multipotent CD34+ cells in a patient with selective T-lymphocyte reconstitution after bone marrow transplantation for B-SCID. 752 43

A 66-year-old male patient was admitted with dyspnea; physical examination revealed petechiae and systemic lymphadenopathy. Laboratory findings showed leukemia. The blasts in the peripheral blood were negative for cytochemical myeloperoxidase, and had condensed nuclear chromatin with a nucleolus. The histological diagnosis of the biopsied neck lymph node was lymphoblastic lymphoma. The leukemia cells expressed CD2, CD6, CD7, CD13low, CD56, beta chain of IL-2 receptorlow (IL-2R beta), and HLA-DR antigens, but not other pan-T (CD5, CD3, CD4, and CD8); pan-B (CD10, CD19, CD20, and CD24); natural killer (NK) (CD16, CD57); or myeloid (CD33) antigens. Electronmicroscopy revealed convoluted nuclei with conspicuous nucleoli and peripherally condensed heterochromatin. Membrane-bound granules containing an electron dense matrix were observed in the cytoplasm, indicating the NK cell nature of the neoplastic cells. While terminal deoxynucleotidyl transferase (TdT) and cytoplasmic CD3 were not detected by immunofluorescence on fixed smears, Northern blot analysis revealed the gene expression of CD3 epsilon, CD3 zeta, and TdT. Gene rearrangement analysis revealed that the beta, gamma, and delta chains of T-cell receptor (TCR) and immunoglobulin heavy chain (IgH) were of germline genotype. While the overall interpretation of the phenotype and genotype was difficult, the derivation of an immature stage of NK lineage was strongly suggested, based predominantly on the electronmicroscopic features. Despite initially successful chemotherapy, the patient died 14 months after initial presentation.
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PMID:Novel leukemic lymphoma with probable derivation from immature stage of natural killer (NK) lineage in an aged patient. 753 82

Human umbilical cord blood (CB) is a rich source of hematopoietic stem cells for both research and stem cell transplantation. In clinical studies, it appears that recovery from myeloablative therapy using CB requires significantly fewer cells than a typical allogeneic marrow transplant. This suggests that CB may be enriched for early hematopoietic progenitors. The present studies were undertaken to determine the presence of CD34+ cells in CB with the phenotypic characteristics of multipotential stem cells. In 22 CB harvests, the average percentage of CD34+ cells was 1.33 +/- 0.21% (SE), a value similar to that in adult normal bone marrows (BM). However, the distribution of CD34+ cells was distinctly different from either BM or granulocyte colony-stimulating factor (G-CSF) mobilized peripheral blood stem cell harvests. CB contained a defined population of brightly staining CD34+ cells with low side scatter. These CD34 (bright) cells comprised a mean of 14.5 +/- 2.5% of the CB CD34+ cells, whereas < 1% of BM CD34+ cells has been shown to be CD34- bright. Eighty-five to ninety percent were negative for three antigens expressed at an early stage of stem cell maturation: CD38, HLA-DR and LFA-1. Fifty-five percent of these CD34 (bright) cells did not express the CD45RA isoform, an additional marker of immaturity. The antigen-bright cells also lacked lineage-specific antigens including CD33, CD56, CD19, CD10 and CD7 as well as CD71. Approximately 46% were Thy-1+, and 40% expressed c-kit receptors. These data suggest that, by phenotypic criteria, CB may be a particularly enriched source of primitive hematopoietic precursors.
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PMID:A unique population of CD34+ cells in cord blood. 754 Apr 69

The immunophenotype of 110 adult patients with diagnosis of acute myeloblastic leukemia (AML) was analyzed using a wide panel of monoclonal antibodies (mAbs). Leukemic blasts were tested by applying direct immunofluorescence analysis and dual-fluorescence staining, and two groups of patients were identified: 56/110 (51%) expressing only myeloid antigens (My/AML) and 54/110 (49%) expressing both myeloid and lymphoid antigens (Ly/AML). CD13 and CD33 were expressed in almost all FAB subtypes, whereas CD14, frequently expressed in M4 and M5 subtypes (70%), was rarely expressed in M0 + M1 cases (9%). On the contrary, CD34, expressed in 77% of M0 + M1 cases, was practically absent in M3 and M5 subtypes (6% and 7%, respectively). CD2 and CD7 antigens were found in 34% and 42% of patients respectively, whereas B cell-associated antigens, such as CD10 and CD19, were found in 31% and 18% of patients. Cytogenetic abnormalities characteristically present in AML patients were also analyzed and, except for t(8;21) which was found in both groups of patients, the other abnormalities were frequently found in cases coexpressing lymphoid-associated antigens. Finally, the complete remission (CR) rate, survival and event-free survival were analyzed according to the presence of lymphoid markers and also of some specific antigens such as CD7 and CD34. The only prognostic difference was represented by CD34+ patients who showed a reduction in the CR rate compared with CD34- patients (65% versus 82%) (p = 0.05) which became more evident when the mean intensity of fluorescence was considered.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The presence of lymphoid-associated antigens in adult acute myeloid leukemia is devoid of prognostic relevance. 754 2


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