Structure/function studies of the common acute lymphoblastic leukemia antigen (CALLA/CD10) expressed on human neutrophils

The common acute lymphoblastic leukemia antigen (CALLA/CD10) is a nonintegral membrane glycoprotein expressed on normal and neoplastic cells of hematopoietic and nonhematopoietic origin. We have undertaken a series of experiments to examine 1) the structural homology between leukemia cell and neutrophil CALLA/CD10 and 2) the putative function CALLA/CD10 subserves to human neutrophils. Biosynthetic labeling, peptide mapping, and two-dimensional gel electrophoresis indicate that neutrophils synthesize and express a CALLA/CD10 molecule that is similar, but not identical, to leukemic cell CALLA/CD10. The level of CALLA/CD10 expression is similar on the two cell populations, and neutrophil CALLA/CD10 (like its leukemic cell counterpart) undergoes antigenic modulation. Finally, we report that neutrophil cell surface-bound anti-CALLA/CD10 monoclonal antibodies inhibit the chemotactic response to both N-Formyl-methionyl-leucyl-phenylalanine (F-mlp) and zymosan-activated sera (ZAS), but had no inhibitory effect on random migration, degranulation, or aggregation. The anti-class I monoclonal antibody W6/32 exerted a similar effect on chemotaxis. We conclude that CALLA/CD10 has no clearly defined role in neutrophil function but may play a role in some distal event in chemotaxis.     

Discrepancy between flow cytometric analyses of CALLA using two monoclonal antibodies

Both the J5 and BA-3 monoclonal antibodies are considered to be specific for epitopes on the common acute lymphoblastic leukemia antigen (CALLA). Flow-cytometric analyses of three cell lines and one normal bone marrow sample using these antibodies as CALLA markers demonstrated that J5-labeled cells were always brighter than those labeled with BA-3, and that the ratio of their fluorescence intensities varied widely in the different systems. Furthermore, one of the lines, RPMI 8226, while positive for J5, appeared to be negative when labeled with BA-3, except for a slight displacement of the fluorescence distribution relative to the control. A possible explanation for the observed results is that the BA-3 binding epitope or epitopes on CALLA may vary in their number and/or accessibility to the antibody. These observations suggest that the use of a single monoclonal antibody to detect a cell surface antigen may be misleading, particularly when a negative result is obtained.     

Targeted cytotoxic effect of anti-JL1 immunotoxin against a human leukemic cell line and its clinical implications

We have previously reported the identification of a unique thymocyte-specific surface molecule, JL1, which was detected using the monoclonal antibody (mAb), anti-JL1. Interestingly, JL1 was shown to be expressed in most leukemias, irrespective of their immunophenotype, and subpopulations of normal bone marrow (BM) mononuclear cells (MNCs). Here we investigated the potential usefulness of the anti-JL1 mAb as a therapeutic tool for leukemia. We demonstrated that the proliferation of cultured human leukemia cells was dramatically inhibited in vitro by anti-JL1 mAb conjugated with the polypeptide toxin, gelonin, but not by gelonin alone. We then systematically investigated the reactivity of the anti-JL1 mAb against normal human tissues to evaluate possible side effects along with various hematopoietic and nonhematopoietic tumor cell lines. All of 33 types of normal tissues except thymus and subpopulation of BM MNCs were clearly devoid of JL1 expression. Among tumor cell lines, all the nonhematopoietic cell lines tested were negative for JL1 expression, while some hematopoietic cell lines contained JL1 antigen. Collectively, the results showed the cytotoxic effects of anti-JL1-based immunotoxin against JL1-positive leukemic cells, sparing most normal tissues other than thymocytes and some BM MNCs. Therefore, we strongly suggest that gelonin-conjugated anti-JL1 mAb immunotoxin could be developed as a potential immunotherapeutic agent in the treatment of various types of JL1-positive acute leukemias.     

Expression of the common acute lymphoblastic leukemia antigen (CALLA) on the surface of individual cells of human lymphoblastoid lines

Expression of the common acute lymphoblastic leukemia antigen (CALLA) on the surface of individual cells of the human lymphoblastoid lines CW678, Namalwa, and Nalm-6, and the distribution of the antigen epitopes within the cell populations have been determined quantitatively with the murine monoclonal anti-CALLA antibody J5. The distribution of CALLA epitopes in the cell populations was analyzed by indirect immunofluorescence measured by using flow cytometry. The average number of CALLA epitopes per cell were measured by two assays: in a direct assay by binding 125I-labeled antibody J5 to cells, and indirectly by binding 125I-labeled protein A from Staphylococcus aureus to J5-coated cells. On average, CW678, Namalwa, and Nalm-6 cells bore about 1 X 10(4), 6 X 10(4), and 8 X 10(4) CALLA epitopes per cell respectively. Histograms of the absolute number of CALLA epitopes expressed by individual cells in the populations of CW678, Namalwa, and Nalm-6 cultures were generated by a combined analysis of all the binding data. This is the first example of histograms showing quantitative distribution of antigen epitopes. Previously, the expression of antigens by individual cells as obtained by flow cytometry was only presented in terms of relative fluorescence intensity of individual cells in cell populations.     

A novel human T cell antigen preferentially expressed on mature T cells and shared by both well and poorly differentiated B cell leukemias and lymphomas

A new lymphocyte differentiation antigen shared by all normal T cells and some malignant B cells was defined by a monoclonal antibody designated 12.1. This antibody reacted with all peripheral blood T cells but not with normal B cells and B cell lines. Analysis with a fluorescence activated cell sorter showed that the expression of 12.1 antigen changes during T cell maturation. Most thymocytes, blasts of acute T cell leukemia, and cells from established leukemic T cell lines bear a small amount of 12.1 antigen. In contrast the majority of peripheral blood T cells, activated T cells, and leukemic T cells of the Sezary syndrome bear a large amount of 12.1 antigen. Unexpectedly, antibody 12.1 reacted with leukemic cells from most patients with B-type chronic lymphocytic leukemia (CLL) and some patients with lymphosarcoma cell leukemia (LSCL). Among these leukemias, expression of the 12.1 antigen was not correlated with the stage of B cell maturation, with the amount of surface immunoglobulin on the cells, or with the presence or absence of monoclonal gammapathy. In a comparative serologic analysis the antigen defined by antibody 12.1 was distinct from the p67 T cell antigen (defined by monoclonal antibody 10.2) that is also known to be expressed by B-type CLL cells.     

Inhibition of mixed lymphocyte response by a rat monoclonal antibody to a novel murine lymphocyte activation antigen (MALA-2)

A novel surface antigen expressed on activated and proliferating murine lymphocytes has been identified by a rat monoclonal antibody. The antigen, termed MALA-2, is also expressed on various lymphoid cell lines, but it is absent or present at very low densities on the majorities of unstimulated thymocytes and lymph node cells. Some cells in normal spleen and bone marrow seem to express the antigen at relatively high densities and they may represent proliferating cells in these tissues. MALA-2 has an apparent m.w. of 95,000 to 100,000 under both reducing and nonreducing conditions. The monoclonal antibody YN1/1.7 that reacts with this antigen partially inhibits Con A stimulation of spleen cells, but its inhibition of LPA stimulation is negligible. Furthermore, the antibody profoundly inhibits MLR. The inhibition of MLR by YN1/1.7 antibody is comparable to that caused by anti-transferrin receptor. The time course study suggests that the antibody may directly inhibit proliferating cell populations in MLR.     

Identification of several cell surface proteins of non-T, non-B acute lymphoblastic leukemia by using monoclonal antibodies

Monoclonal antibodies (MAb) were produced by immunization of BALB/c mice with cells from a non-T, non-B acute lymphoblastic leukemia (ALL) cell line. Nine distinct antigens (groups I to IX) were defined by these monoclonal antibodies, some of which appear to be associated with specific stages of cellular differentiation. The number of molecules of each MAb reactive with the ALL cell line, measured in a quantitative cellular radioimmunoassay, varied from 0.6 X 10(5) to 11 X 10(5) molecules/cell, indicating that the antigens identified represent major constituents of the cell surface. The biochemical nature of the antigens was examined on the ALL cell line by antibody affinity chromatography and/or immunoprecipitation and SDS-polyacrylamide gel electrophoresis. Groups I through III are composed of previously described antigens: HLA class I, HLA class II molecules, and CALLA, the common ALL antigen. The other MAb define antigens previously undescribed on non-T, non-B ALL cells. Group IV antigen is a polypeptide of apparent m.w. 95,000 distinct from CALLA. It is expressed on some ALL samples and on the vascular endothelial cells of several tissues. Group V antigen is a single polypeptide chain of m.w. 94,000, also distinct from CALLA and expressed by lymphocytes, thymocytes, acute myelogenous leukemia (AML) cells, and ALL cells. Group VI is a molecular complex composed of two noncovalently associated polypeptides of apparent m.w. 125,000 and 87,000 and appears to be restricted to ALL, AML, macrophages, and hematopoietic precursor cells. Group VII is a glycoprotein of apparent m.w. 85,000, which, within the thymus, is primarily restricted to the medullary area. It is also present on AML, bone marrow cells, and mature T and B lymphocytes. Group VIII is a disulfide-linked complex of apparent m.w. greater than 120,000 under nonreducing conditions. It is resolved into three major polypeptides of apparent m.w. 57,000, 47,000, and 41,000 under reducing conditions. This complex is found in greatest amounts on the non-T, non-B ALL cell line but is also present on AML, ALL, and on subpopulations of normal bone marrow and tonsil cells. Group IX antigen is a single polypeptide chain of apparent m.w. 51,000 on the ALL cell line. This antigen is expressed strongly on ALL and AML samples and on normal bone marrow; much lower antigenic density is found on thymus and tonsil cells. The antigens described here with a series of MAb produced in a single fusion represent a unique array of cell surface molecules of non-T, non-B ALL cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Down-regulation and inactivation of neutral endopeptidase 24.11 (enkephalinase) in human neutrophils

Neutral endopeptidase (EC 3.4.24.11, NEP) is an integral membrane protein of human neutrophils. NEP is identical with the common acute lymphoblastic leukemia antigen (CALLA) of leukemic cells. The expression of NEP on the surface of neutrophils is down-regulated by endocytosis which can be induced by phorbol 12-myristate 13-acetate (PMA) at 37 degrees C. The activity of the enzyme on the surface of intact cells decreases by 76% within 5 min. The activity can be recovered, however, if the cells are lysed within 5 min of the endocytosis. After 30 min, only 32% of the NEP activity is present in the neutrophil lysates. The loss of activity is presumably due to proteolytic inactivation. Diacylglycerol and monoclonal antibody to CALLA/NEP also induce internalization of NEP. PMA induces endocytosis even at 4 degrees C, but NEP is not inactivated at that temperature. The disappearance of NEP activity after adding PMA was inhibited by various agents. Among the most active were the phospholipase inhibitor 4-bromophenacyl bromide and a combination of the serine protease and cathepsin inhibitors, diisopropylfluorophosphate and N-ethylmaleimide. The employment of fluorescent monoclonal antibody confirmed the down-regulation and internalization of NEP antigen on the neutrophils. Since NEP inactivates chemotactic peptides and thereby affects chemotaxis of neutrophils (Painter, R. G., Dukes, R., Sullivan, J., Carter, R., Erd?s, E. G., and Johnson, A. R. (1988) J. Biol. Chem. 263, 9456-9461), the down-regulation of NEP activity on the cell membrane may modulate the function of these cells in inflammation.     

CD10 and CD44 genes of leukemic cells and malignant cell lines show no evidence of transformation-related alterations.

The expression of CD10/CALLA is associated primarily with childhood leukemia of pre-B lymphocyte phenotype. We have compared the hybridization pattern of the CALLA gene from leukemic and normal cells digested with several restriction enzymes. No alterations were noticed with Eco RI, Sac I, Pvu II, Eco RV, Hind III, and Msp I. Since CALLA is also found on other malignancies, we analyzed DNA samples prepared from cell lines derived from leukemia, lymphoma, glioblastoma, retinoblastoma, and neuroblastoma. Normal restriction patterns were observed for all the lines regardless of their CALLA phenotype. Having demonstrated previously that CALLA was structurally identical to neutral endopeptidase 3.4.24.11 (NEP), we have now established a correlation between surface expression of CALLA and NEP activity on leukemia samples and on several cell lines. Malignant cells tested expressed a functionally active enzyme and no gross alteration was present in the CALLA gene. The CD44 gene is expressed on most cells of hemopoietic origin and on greater than 95% of cases of acute lymphoblastic leukemia and acute myeloblastic leukemia studied. It is also expressed on normal astrocytes and on malignant cells of glioma/astrocytoma types. We now report that a similar pattern of hybridization was observed with Sac I, Pvu II, and Eco RI for leukemic samples, normal cells, and malignant cell lines. A polymorphism was recently detected for CD44 using Hind III; leukemic cells and malignant lines also showed this normal polymorphism. Thus no deletion or insertion could be detected in the CD44 gene of leukemic cells and malignant lines, suggesting that no gross DNA alterations were involved. The correlation between surface expression and enzymatic activity of CD10/CALLA and the expression of CD44 on a variety of malignant cells would suggest that the structure and function of these two gene products are probably not altered by the process of transformation.     

A new mouse lymphoid alloantigen (Lgp100) recognized by a monoclonal rat antibody

A new genetically polymorphic cell surface antigen recognized by a monoclonal rat anti-mouse antibody is expressed on mouse lymphoid cells. Fluorescence analysis on the fluorescence-activated cell sorter (FACS) locates the antigen on thymocytes, lymph node cells, and both T and B cells in the spleen. It also appears on approximately 40% of cells in the bone marrow.Immune precipitations from surface iodinated spleen cells followed by 2-D gel electrophoresis demonstrate that the antigen is a glycoprotein of approximately 100,000 daltons. Since it is expressed in all lymphoid tissues and on both T and B cells, we designate it lymphoid glycoprotein 100 (Lgp100).Strains with Lgp100 include A/J, AKR/J, AKR/Cu, BALB/c, 129/J, CBA/N, C3H/HeJ, CBA/2J, and SJL/J. Strains with no detectable antigen include C57BL/6J, C57BL/10J, C57BR/cdJ, C57L/J, and C58/J. Intercrosses and backcrosses establish a pair of alleles, a positive and a negative one, at a single locus. Heterozygotes display about 50% as much antigen as homozygotes by quantitative membrane immunofluorescence on the FACS. Tests for Lgp100 in 35 recombinant inbred strains from three crosses (CXB, BXB, and BXH) locate this locus on chromosome 1, closely linked to theMls locus.     

A new human T-cell differentiation antigen: Unexpected expression on chronic lymphocytic leukemia cells

Monoclonal antibody 10.2 reacts with a monomorphic antigen expressed on the surface of virtually all thymocytes, as well as thymus-dependent lymphocytes in the peripheral blood and bone marrow. In contrast, antibody 10.2 did not react with normal peripheral blood B cells, monocytes, or the non-T-cell fraction of bone marrow. This complement fixing IgG2a antibody also reacted with extablished leukemic T-cell lines, but not with cell lines of either normal or malignant B-cell origin. Similarly, when tested against acute leukemia blasts, the 10.2 antibody reacted with those from patients with T-cell acute leukemia, but not with those from patients with acute null cell or non-lymphocytic leukemia. An unexpected exception to this pattern was the reaction of 10.2 antibody with leukemic cells from patients with B-cell type chronic lymphocytic leukemia. Immune precipitates formed with 10.2 antibody and detergent lysates of radiolabeled T-cells contained three polypeptides with molecular weights of 65 000, 55 000, and 50000 daltons. It has not been determined whether all three of these polypeptides contain the 10.2 antigenic determinant, or whether these proteins represent a multimeric antigen complex.PJM is a Junior Faculty Clinical Fellow of the American Cancer Society.     

A new human T-cell differentiation antigen: unexpected expression on chronic lymphocytic leukemia cells

Monoclonal antibody 10.2 reacts with a monomorphic antigen expressed on the surface of virtually all thymocytes, as well as thymus-dependent lymphocytes in the peripheral blood and bone marrow. In contrast, antibody 10.2 did not react with normal peripheral blood B cells, monocytes, or the non-T-cell fraction of bone marrow. This complement fixing IgG2a antibody also reacted with established leukemic T-cell lines, but not with cell lines of either normal or malignant B-cell origin. Similarly, when tested against acute leukemia blasts, the 10.2 antibody reacted with those from patients with T-cell acute leukemia, but not with those from patients with acute null cell or non-lymphocytic leukemia. An unexpected exception to this pattern was the reaction of 10.2 antibody with leukemic cells from patients with B-cell type chronic lymphocytic leukemia. Immune precipitates formed with 10.2 antibody and detergent lysates of radiolabeled T-cells contained three polypeptides with molecular weights of 65 000, 55 000, and 50 000 daltons. It has not been determined whether all three of these polypeptides contain the 10.2 antigenic determinant, or whether these proteins represent a multimeric antigen complex.     

Murine cell surface glycoproteins. Purification of the polymorphic Pgp-1 antigen and analysis of its expression on macrophages and other myeloid cells

We previously reported the initial characterization of a polymorphic major cell surface glycoprotein of about 80,000 daltons from mouse embryo 3T3 cells. This glycoprotein has now been purified 1800-fold to apparent homogeneity by monoclonal antibody affinity chromatography. The purified molecule retained the total antigenic activity of the cell, as determined by antibody binding assays. The quantity of the glycoprotein, 0.06% of the total protein of the crude cell extract, confirmed its presence as a major constituent of the cell plasma membrane. The monoclonal antibody was also used to detect related antigens in cells and tissues of C57BL/6J mice. The antigen was present in high concentration in macrophages and subpopulations of bone marrow and blood polymorphonuclear cells. Much lower concentrations of antigen were detected in spleen cells, thymocytes, and extracts of solid tissues. The apparent Mr of the target antigen of myeloid cells was 92,000. This molecule was a major surface constituent of myeloid cells with 10(6) antibody binding sites per cell containing 10% of total 125I incorporated by the lactoperoxidase procedure. The macrophage glycoprotein labeled on the cell surface with 125I was highly sensitive to trypsin, yielding an antigenically active soluble glycopolypeptide of about 65,000 daltons, that contained all of the incorporated 125I. A similar 65,000-dalton glycopeptide was released from 3T3 cells by trypsin cleavage. These data indicate that a major cell surface constituent of mouse myeloid cells is a 92,000-dalton glycoprotein closely related to the 80,000-dalton glycoprotein of mouse embryo 3T3 cells.     

Biochemical characterization and cellular distribution of a polymorphic,murine cell-surface glycoprotein expressed on lymphoid tissues

A murine leukocyte surface glycoprotein (M_r = 95 000) has been defined by means of xenogeneic monoclonal antibodies. In normal hematopoietic tissues, the glycoprotein is found in highest amounts in the bone marrow. Flow cytometric analysis shows that essentially all bone-marrow cells express the glycoprotein and that it is a major component of a subpopulation of cells containing predominantly granulocytic precursors. In contrast, only about 5 percent of thymocytes express sufficient glycoprotein to be detected by flow cytometric analysis, although under stringent conditions up to 20 percent of thymocytes are susceptible to complement-mediated cytotoxicity using a monoclonal antibody against the glycoprotein. Functional assays showed that both prothymocytes and colony forming unit-spleen express the glycoprotein which is broadly distributed on murine hematopoietic tumor cell lines. However, although some Thy-I⁺ (T) cell lymphomas express large amounts of the glycoprotein, others do not express detectable quantities of the molecule. The glycoprotein is not restricted to hematopoietic cells and can be detected on lung, kidney, brain, and liver as well as cultured fibroblasts. Monoclonal antibodies against the glycoprotein cross-react with an antigen present on human cells. As described in the accompanying paper, the glycoprotein exists in two antithetical allelic forms and we show that it is identical to a polymorphic surface molecule independently characterized by Colombatti and co-workers.     

Monoclonal rat anti-mouse brain antibody detects Abelson murine leukemia virus target cells in mouse bone marrow

We report the characterization of a monoclonal antibody which detects a surface antigen expressed by the bone marrow target cell of A-MuLV. Treatment of bone marrow cells with this antibody and complement results in >95% loss of the A-MuLV-derived in vitro transformed foci. The surface antigen detected by this antibody is also expressed on A-MuLV-transformed lymphoid cell lines, thymocytes, and some peripheral lymphocytes. This antigen is not expressed, however, by the pluripotent hematopoietic stem cell defined by the spleen colony-forming assay. We present evidence that the antigen detected is neither a virally encoded product, nor exclusively associated with the BALB/c genome.     

Fibronectin-plasma membrane interaction in the adhesion of hemopoietic cells

Many hemopoietic cell lines were examined for their ability to adhere to culture dishes coated with extracellular matrix proteins. Adhesion assay was performed with murine and human leukemic cell lines representative of different stages of differentiation along both erythroid and myeloid lineages. All the hemopoietic cell lines tested adhered to fibronectin but not to laminin, types I, III, and IV collagen, serum-spreading factor, and cartilage proteoglycans. In addition to immortalized cell lines, immature erythroid and myeloid mouse bone marrow cells adhered to fibronectin. To define the fibronectin region involved in hemopoietic cell adhesion, proteolytic fragments, monoclonal antibodies, and synthetic peptides were used. Among different fibronectin fragments tested, only a 110-kD polypeptide, corresponding to the fibroblast attachment domain, was active in promoting adhesion. Moreover, a monoclonal antibody to the cell binding site located within this domain prevented hemopoietic cell adhesion. Finally, the tetrapeptide Arg-Gly-Asp-Ser, which corresponds to the fibronectin sequence recognized by fibroblastic cells, specifically and competitively inhibited attachment of hemopoietic cells to this molecule. The cell surface molecule involved in the interaction of mouse hemopoietic cells with fibronectin was identified as a 145,000-D membrane glycoprotein by adhesion-blocking antibodies. This glycoprotein was found to be antigenically and functionally related to the GP135 membrane glycoprotein involved in the adhesion of fibroblasts to fibronectin (Giancotti, F. G., P. M. Comoglio, and G. Tarone, 1986, Exp. Cell Res., 163:47-62). On the basis of these data, we conclude that interaction of hemopoietic cells with fibronectin involves a specific fibronectin sequence and a 145,000-D cell surface glycoprotein. We speculate that this property might be relevant for the interaction of hemopoietic cells with the bone marrow stroma, which represents the natural site of hemopoiesis.     

Enhancing effects of monocytes on modulation of a lymphocyte membrane antigen

Redistribution, or modulation, of some cell surface antigens occurs in the presence of specific antibody. The phenomenon of antigenic modulation may therefore affect the use of antibodies as therapeutic agents. This study was undertaken to investigate modulation of the 65,000 dalton T65 antigen, present on normal and malignant T cells and some malignant B cells, which is recognized by the monoclonal antibody T101. To induce cell surface antigenic modulation, normal or leukemic lymphoid cells were cultured in the presence of monoclonal antibody T101 for 3-hr periods. Removal of monocytes from mononuclear cell preparations resulted in significantly lower degrees of T65 antigenic modulation. The degree of antigenic modulation could be increased by adding monocytes back to monocyte-depleted lymphocyte suspensions. Furthermore, maximal modulation occurred in the presence of monocytes at T101 concentrations that were 3 logs lower than in the absence of monocytes. The enhancing effect of monocytes was dependent on the Fc portion of the T101 antibody molecule, and presumably was mediated by cross-linking of antigen-antibody complexes on the surface membrane of the modulating cell by Fc receptors present on monocytes. Further experiments performed to examine the characteristics of this enhancement of antigenic modulation by monocytes indicated that autologous as well as allogeneic monocytes were effective, indicating that the enhancing phenomenon was not dependent upon recognition of major histocompatibility antigens. Viable monocytes were required, but pretreatment of monocytes with sodium azide to inhibit energy production, or indomethacin to inhibit prostaglandin synthesis had no effect on this phenomenon. Polymorphonuclear leukocytes did not mediate similar enhancement, although monocytic and myeloid cell lines U937, THP-1, and HL-60 did. Spent culture medium from modulated cultures and preparations containing IL 1 activity did not enhance modulation of the T65 surface antigen on lymphocytes, suggesting that direct contact between lymphocytes and monocytes is required to mediate the effect. The finding that leukemic cells from patients with CLL undergo modulation of the T65 antigen to a much lower degree in vitro than observed in vivo, and that this difference can be overcome by the addition of monocytes, suggests that monocytes or the reticuloendothelial system may augment antigenic modulation in vivo.     

Two surface antigens expressed on proliferating mouse T lymphocytes defined by rat monoclonal antibodies

A hybrid cell line resulting from the fusion of a Con A-activated normal mouse spleen cell and a transformed mouse T cell (EL-4BU) has been used to prepare and select rat monoclonal antibodies reactive with molecules expressed on the surface of proliferating, as opposed to resting, mouse T cells. In this report, the characterization of two such antigens identified in this way is described. One antigen is a membrane component common to mitogen-activated T and B cells, some bone marrow cells, and various transformed cell lines but is not detectable on either normal thymocytes or the majority of spleen cells by radioimmunoassay or FACS analysis. It has a m.w. of approximately 200,000 daltons under nonreducing conditions and 100,000 daltons under reducing conditions. Antibodies to this antigen precipitate cell-bound transferrin but do not react directly with transferrin itself. It would thus appear that the antigen is the transferrin receptor molecule. The second antigen is not detectable on normal thymocytes, spleen cells, bone marrow cells, or mitogen-stimulated spleen cells but is expressed at high levels on some transformed T cell lines. It, too, appears to be a dimer, with a m.w. of 95,000 daltons under nonreducing conditions, decreasing to 50,000 daltons under reducing conditions. Although the function of the 95,000-dalton antigen is not yet known, its lack of expression on adult T cell populations both before and after activation suggests either a short-lived role at a very early stage of T cell development and/or an association with T cell transformation.     

Development and distribution of a human B cell subpopulation identified by the HB-4 monoclonal antibody

Monoclonal antibodies have been successfully used to identify B cell differentiation antigens, few of which mark discrete B cell subpopulations. We have produced a monoclonal antibody, HB-4, against a cell surface antigen on the human B cell line, BJAB, which has an unusual distribution on normal lymphoid cells. HB-4, an IgM antibody, was found to react with an antigen that is expressed by a subpopulation of B cells, approximately 50% of natural killer cells, and not by other types of cells in bone marrow, blood, and lymphoid tissues. In two-color immunofluorescence assays, the HB-4-reactive antigen was found on less than 5% of immature IgM+ B cells in fetal liver and bone marrow and on 25% of B cells in fetal spleen. The HB-4 antibody reacted with 40% of IgM+ cells in newborn blood and 60% of B cells in adult blood. In contrast, only 2 to 26% of IgM+ B cells in the peripheral lymphoid tissues of adults were HB-4+. HB-4+ B cells could be induced to proliferate by cross-linkage of their surface immunoglobulins but not by T cell-derived growth factors. The subpopulation of activated B cells that is responsive to T cell-derived differentiation factors was HB-4-, as were plasma cells. The HB-4 antibody was reactive with some but not all B cell malignancies and cell lines, and not with malignancies or cell lines of other lineages. The HB-4 antigen may therefore serve as a useful nonimmunoglobulin marker for the identification of a subpopulation of mature resting B cells that are present in the highest frequency in the circulation.     

Monoclonal antibody 53.6 recognizes a novel proliferation-associated antigen encoded on human chromosome 11

This paper describes the characterization of a novel cell surface antigen associated with proliferation. Previous work demonstrated that monoclonal antibody 53.6 reacted with every human cell line tested, as well as with subpopulations of normal bone marrow and peripheral blood lymphocytes. Mitogen stimulation of peripheral blood lymphocytes with phytohemagglutinin resulted in increased expression of the antigen recognized by 53.6. Immunoprecipitation of biosynthetically labeled KG-1A cell extracts with 53.6 revealed that the antigen is a nonglycosylated acidic protein of Mr 34,000. Analysis of mouse-human hybrid cell lines indicated that the structural gene for the antigen is encoded on chromosome 11. The antigen recognized by 53.6 is distinct from previously described cell surface antigens based on its distribution on activated cells and biochemical characteristics. These studies indicate that the 53.6 antigen is a novel proliferation-associated antigen, and may be useful in analyzing lymphocyte activation.