The CD19/CD21 signal transducing complex of human B lymphocytes includes the target of antiproliferative antibody-1 and Leu-13 molecules.

CD19 is a member of the Ig superfamily expressed on the surface of B lymphocytes that may be involved in the regulation of B cell function. Immunoprecipitation studies with B cell lines solubilized by digitonin have shown CD19 to be part of a multimolecular complex that includes CD21 (CR2) and other unidentified proteins. In this study, two of the CD19-associated proteins were identified as TAPA-1, which is expressed on most cell types, and Leu-13, which is expressed on subsets of lymphoid cells. TAPA-1 and Leu-13 are physically associated in many cell lineages. CD19 and CD21 mAb each specifically coprecipitated proteins of the same size as those precipitated by TAPA-1 and Leu-13 mAb from B cell lines and cDNA-transfected K562 cell lines. Western blot analysis with a TAPA-1 mAb verified the identity of TAPA-1 in CD19 and CD21 immunoprecipitated materials. In addition, when TAPA-1 or Leu-13 were crosslinked and patched on the cell surface, all of the CD19 comigrated with TAPA-1 and some of the CD19 comigrated with Leu-13. Furthermore, mAb binding to CD19, CD21, TAPA-1, and Leu-13 on B cell lines induced similar biologic responses, including the induction of homotypic adhesion, inhibition of proliferation, and an augmentation of the increase in intracellular [Ca2+] induced by suboptimal cross-linking of surface Ig on B cell lines. Together, these data suggest that TAPA-1 and Leu-13 are broadly expressed members of a signal transduction complex in which lineage-specific proteins, such as CD19 and CD21, provide cell-specific functions.     

Blocking of human T lymphocyte functions by anti-Leu-2 and anti-Leu-3 antibodies: differential inhibition of proliferation and suppression

We have shown previously that monoclonal antibodies to the Leu-2 and Leu-3 T cell antigens block the response of their respective subsets in allogeneic MLR. The present study was an effort to explore the mechanism of inhibition and to determine if anti-Leu-2 and anti-Leu-3 antibodies affect the responses to stimuli in addition to alloantigens. Our results indicate that antibodies to Leu-2 and Leu-3 have profound inhibitory effects on proliferation by their respective T cell subsets responding to a variety of stimuli, including specific soluble antigens and alloantigen. This effect was characterized by the following features: a) For optimal inhibition of proliferation, antibody must be present at the onset of antigenic stimulation. b) Inhibition is augmented by increasing the concentration of antibody or decreasing the concentration of antigen. c) Fab fragments of both anti-Leu-2a and anti-Leu-3a antibodies also block proliferation. In addition to their effects on T cell proliferation, anti-Leu-3 antibody blocked T cell-dependent lg synthesis induced in MLR, and anti-Leu-2 antibody prevented the induction, in vitro, of Leu-2+3- suppressor cells of lg synthesis. Taken together, these results suggest that antibodies to antigenic determinants on the Leu-2 and Leu-3 molecules competitively block segments of these structures that bind to alloantigen or nominal antigen. On the other hand, anti-Leu-2a antibody failed to block suppression of the MLR by in vivo activated, antigen-specific Leu-2+3- suppressor cells, which suggests that the Leu-2a epitope does not transmit antigen-specific signals from these differentiated suppressor T cells.     

Differential modulation of the CD-2 and CD-3 T cell activation pathways by a monoclonal antibody to Leu-13.

MAb anti-Leu-13 reacts with a 16-kDa-interferon-responsive lymphocyte-endothelial cell surface antigen and has been demonstrated to induce lymphocyte aggregation by an undefined adhesion pathway. While anti-Leu-13 inhibits proliferation triggered by CD3 antibodies it was found to consistently augment proliferation induced by a pair of CD2 antibodies at suboptimally mitogenic concentrations. The latter mechanism of T cell activation may represent an antigen-nonspecific activation pathway requiring extensive cell-cell interaction. Proliferation induced via the CD2 pathway was very sensitive to the presence of monocytes whose inhibitory effect was reversed by indomethacin. While the potent inhibitory effect of PGE2 on proliferation induced via the CD2 pathway was weakly antagonized by anti-Leu-13, the combined effects of anti-Leu-13 and PGE2 on the CD3 pathway were additive and very inhibitory. The possibility that the Leu-13 signal reflects a mechanism by which a monocyte/macrophage-sensitive T cell activation pathway might be selectively amplified in vivo is discussed.     

Genomic organization and chromosomal localization of the TAPA-1 gene.

TAPA-1 is a 26-kDa integral membrane protein expressed on many human cell types. Antibodies against TAPA-1 induce homotypic aggregation of cells and can inhibit their growth. The murine homologue of TAPA-1 was cloned from both cDNA and genomic DNA libraries. A very high level of homology was found between human and mouse TAPA-1. The 5' untranslated region of the TAPA-1 gene resembles housekeeping gene promoters with respect to G + C content and the presence of potential Sp1 binding sites. The chromosomal localization of human and murine TAPA-1 genes was determined by Southern blot experiments using DNA from somatic cell hybrids. The genes were found to be part of a conserved syntenic group in mouse chromosome 7 and the short arm of human chromosome 11. The organization of the TAPA-1 gene and the projection of the exon boundaries on the proposed protein structure are presented.     

Human lymphocyte subpopulations identified by using three-color immunofluorescence and flow cytometry analysis: correlation of Leu-2, Leu-3, Leu-7, Leu-8, and Leu-11 cell surface antigen expression

Three-color immunofluorescence has been used to determine the co-expression of cell surface antigens on human peripheral blood lymphocytes. Monoclonal antibodies or avidin were coupled to either FITC (green), phycoerythrin (orange), or Texas Red (red) fluorochromes. These three fluorochromes could be independently measured by using a dual laser FACS IV system equipped with an argon ion laser (488 nm) and a dye laser (600 nm). Human peripheral blood lymphocytes were stained with the following combinations of reagents: (1) FITC anti-Leu-11a + PE anti-Leu-2a + TR avidin/biotin anti-Leu-7; (2) FITC anti-Leu-11a + PE anti-Leu-3a + TR avidin/biotin anti-Leu-7; (3) FITC anti-Leu-8 + PE anti-Leu-2a + TR avidin/biotin anti-Leu-7; and (4) FITC anti-Leu-11a + PE anti-Leu-2 + TR avidin/biotin anti-Leu-8. The light scatter, green fluorescence, orange fluorescence, and red fluorescence signals for each sample were stored by a Consort 40 PDP/11 computer in list mode files. Sequential reanalysis of the data directly demonstrated the existence of several unrecognized subpopulations of lymphocytes. Previously, we reported that the anti-Leu-7 and anti-Leu-11 antibodies can be used to identify discrete subsets of human NK cells with distinct functional capacities. In this report, we show that these subsets can be further subdivided on the basis of Leu-8 and Leu-2 expression. Thus, these studies illustrate how multicolor and multiparameter flow cytometry can further our understanding of cellular heterogeneity within this group of lymphocytes.     

Activation of antigen-specific suppressor T lymphocytes in man involves dual recognition of self class I MHC molecules and Leu-4/T3-associated structures on the surface of inducer T lymphocytes

We showed previously that fresh Leu-2+ T cells respond to autologous antigen-primed Leu-3+ T cells by proliferation and differentiation into suppressor T cells (Ts) that specifically inhibit the response of fresh Leu-3+ cells to the original priming antigen. This study was undertaken to characterize the role of various cell surface molecules expressed by antigen-primed Leu-3+ cells in their activation of Leu-2+ Ts cells. Alloactivated Leu-3+ blasts were treated in the absence of complement with a variety of monoclonal antibodies recognizing distinct antigens on human lymphoid cells, and then were examined for their functional effects on fresh autologous T cells. Prior treatment of Leu-3+ blasts with anti-Leu-4 or anti-HLA-A,B,C framework antibodies, but not with anti-Leu-1, anti-Leu-3, anti-Leu-5, or anti-HLA-DR framework-specific antibodies, not only blocked proliferation of fresh Leu-2+ cells, it also prevented their differentiation into Ts cells. Furthermore, after their activation by Leu-3+ blasts, Leu-2+ Ts cells inhibited the response of fresh Leu-3+ cells from only those individuals who shared HLA-A,B phenotypes with suppressor-effector cells. These results suggest that both the inductive and effector phases of suppression involve dual recognition of autologous class I MHC molecules and structures associated with the Leu-4 (T3) molecule on the surface of antigen-reactive Leu-3+ cells.     

Gold probe choice in simultaneous detection of human lymphocyte surface antigens at the ultrastructural level

A double immunogold-labeling method in immunoelectron microscopy was used for simultaneous detection of two antigens by monoclonal antibodies [OKT 8 (CD 8), anti-Leu-7, anti-Leu-11b (CD 16)] on lymphocytes in suspension. The combination of gold probe size (5 nm and 15 nm) and monoclonal antibody was found to be decisive for detecting double-labeled cells with the OKT 8+, Leu-11b+ phenotype. The combinations of OKT 8 labeled with the 5-nm gold probe (OKT 8(5] and anti-Leu-11b with the 15-nm gold probe (Leu-11b15) gave double-labeled cells; the reverse situation, using OKT 8 with a 15-nm gold probe (OKT 8(15] and anti-Leu-11b with a 5-nm gold probe (Leu-11b5), did not. Double-labeled OKT 8+, Leu-7+ cells were detected irrespective of which gold probe combination was applied. Our findings indicate that although the double immunogold-labeling method is well suited for study of lymphocyte subsets, it is important to determine suitable combinations of gold probe sizes and monoclonal antibodies for the lymphocyte subset under study, taking into account surface antigen density, so that double labeling ensues.     

Ultrastructural characterization of human large granular lymphocyte subsets defined by the expression of HNK-1 (Leu-7), Leu-11, or both HNK-1 and Leu-11 antigens

A peroxidase-colloidal gold double labeling system in immunoelectron microscopy was used to investigate the ultrastructural features of human large granular lymphocytes (LGL) subpopulations. Three subsets of LGL, Leu-7+-Leu-11-, Leu-7+-Leu-11+, Leu-7- -Leu-11+, were characterized using combinations of the monoclonal antibodies anti-Leu-7 and anti-Leu-11. They showed different ultrastructural patterns. In fact, Leu-7+-Leu-11- cells showed a high nuclear/cytoplasmic ratio (N/C), a round nucleus, a cytoplasm with few organelles, and a rather even surface. Moreover, most of them lacked electron-dense granules. On the other hand, Leu-11+ cells displayed a low N/C, an irregular-shaped nucleus, and a cytoplasm containing a well-developed Golgi apparatus, many mitochondria, vacuoles, vesicles, and numerous electron-dense granules. Moreover, they exhibited an irregular cell surface. Thus, Leu-7+-Leu-11- cells seemed to represent an immature form of LGL, while cells expressing the Leu-11 antigen showed a fine structure specific for functional NK cells. Our findings suggest that the expression of HNK-1 (Leu-7) and Leu-11 antigens respectively represents subsequent stages in NK cell differentiation.     

Monoclonal antibodies, L-35 and L-36, define novel T cell activation antigens

Two novel T cell specific activation antigens were characterized and were defined by monoclonal antibodies developed against mitogen-stimulated human T cells. These antigens, designated as L-35 and L-36 were expressed on both the CD 4(Leu-3) and the CD 8(Leu-2) subsets of activated but not resting T cells. Moreover these antigens were not expressed on a number of T, B, and myeloid tumor cell lines. L-35 and L-36 were expressed on interleukin 2 (IL 2)-dependent cloned T cell lines, and were weakly expressed on the T cell tumor line, HSB-2. L-35 was expressed on granulocytes and a small subset of thymocytes. SDS-PAGE analysis of 125I-labeled lysates from phytohemagglutinin (PHA)-activated T cells demonstrated that L-35 existed as a complex of 32,000 and 97,000 dalton polypeptides under reducing and nonreducing conditions. Anti-L-36 immunoprecipitated a 90,000 dalton structure from PHA-activated cell lysates prepared with CHAPS detergent. When immunoprecipitates were analyzed from [35S]methionine labeled lysates, anti-L-35 precipitated only the 97,000 dalton component, suggesting that the 32,000 dalton subunit of L-35 complex was not synthesized by the activated cell population. Furthermore anti-L-35 did not immunoprecipitate a 32,000 dalton component from 125I-labeled lysates of anti-Leu-4 or Con A-activated cells, suggesting that the 32,000 dalton component of the L-35 complex may represent a subunit of PHA. The 32,000 dalton protein could not, however, be precipitated from cells incubated with PHA for less than 1 day. These results suggested that anti-L-35 recognizes a 97,000 dalton structure expressed on activated T cells, and that upon activation by PHA, becomes associated with a subunit of this mitogen.     

Functional characterization of human T lymphocyte subsets distinguished by monoclonal anti-leu-8

Previous studies have shown that monoclonal anti-Leu-8 antibody identifies functionally distinct subpopulations within both the Leu-2 (T8+) and Leu-3 (T4+) lineages of human T lymphocytes. We now report in detail on the tissue distribution of the Leu-8 antigen and on extensive functional studies of T cells subsets distinguished by their expression or lack of expression of this marker. Leu-8 is present on a wide variety of hematologic cells, including granulocytes, T and B lymphocytes, monocytes, and null or NK cells. Within lymph nodes and tonsils, Leu-8 is absent from both B and T cells within germinal centers but is present on nearly all paracortical lymphocytes. Leu-8 is present on most but not all EBV-transformed B cell lines, reflecting its presence on a subset of normal peripheral blood B cells. None of six malignant T cell lines tested were Leu-8+, whereas most circulating T cells are Leu-8+. Although standard immunoprecipitation techniques failed to demonstrate any specific bands on SDS polyacrylamide gels, the antigenic determinant recognized by anti-Leu-8 is protein or protein-associated, because brief treatment of target cells with pronase abrogated binding of anti-Leu-8. Both Leu-3+8+ and Leu-3+8- cells proliferated in response to several soluble antigens and to autologous and allogeneic non-T cells. Nonetheless, nearly all of the helper T cells for PWM- and AMLR-induced PFC were contained within the Leu3+8- subset. Optimal suppression of the PWM-induced PFC response required both Leu-2+8+ and Leu-2+8- cells, and irradiation of either subset with 3000 R abrogated the capacity of the recombined subsets to effect suppression. In contrast to help for B cell differentiation, both Leu-3+8+ and Leu-3+8- cells were capable of amplifying the development of allospecific T killer cells; precursor and effector T killer cells could be found within both Leu-2+8+ and Leu-2+8- subpopulations. The correlation between Leu-8 phenotype and selected immune functions of T cells (and B cells; see companion paper) indicates that anti-Leu-8 distinguishes important immunoregulatory T and B lymphocyte subsets in man.     

Colony formation by subpopulations of human T lymphocytes. III. Antigenic phenotype and function of colony-forming cells, colony cells, and their expanded progeny

The antigenic phenotype of individual PHA-induced T lymphocyte colonies was studied with a direct immunofluorescence technique using fluorescein-labeled anti-Leu-2a and anti-Leu-3a antibodies. Of the colonies grown from mononuclear peripheral blood cells 85% were Leu-3a+ (inducer/helper phenotype), 12% were Leu-2a+ (suppressor/cytotoxic phenotype), and 3% contained equal numbers of Leu-2a+ and Leu-3a+ cells. Fluorescence-activated cell sorter (FACS) separated T-cell subsets showed that Leu-2a+ cells and Leu-3a+ cells form exclusively Leu-2a+ and Leu-3a+ colonies, respectively. Leu-3a+ cells formed colonies in both the absence and presence of conditioned medium (PHA-CM), whereas colony formation by Leu-2a+ cells was absolutely dependent on PHA-CM. Mixing experiments with FACS-separated T-cell subsets showed that Leu-2a+ cells inhibit colony formation by Leu-3a+ cells in a cell dose-dependent manner both in the presence and absence of PHA-CM. Phenotype analysis of individual colonies from mixing experiments strongly suggested monoclonal proliferation in the present colony assay system. The majority of expanded T-cell colonies showed helper activity in a reverse hemolytic plaque-forming B-cell assay, although to a lesser degree as compared to that of freshly isolated T lymphocytes.     

Morphometric characterization of NK cell subset expressing the Leu-11 antigen in comparison to Leu-7 positive, 11 negative cells

Three subpopulations of human natural killer (NK) cells were identified by immunoelectron microscopy, using combinations of anti-Leu-7 and anti-Leu-11 monoclonal antibodies. For each subpopulation the nuclear area/cellular area ratio (An/Ac) and the perimeter/equivalent circumference ratio were evaluated employing an interactive image analyzer. Leu-11+ cells showed a larger area, a smaller An/Ac and a higher "villousity degree" in comparison to Leu-7+, 11- cells. These differences were proved to be significant using the Kolmogorov-Smirnov two sample test. Previous studies described the existence of distinct cytotoxic capability, recombinant interleukin 2-mediated activation, and ultrastructural features of Leu-11+ in comparison to Leu-7+, 11- cells. This is the first report in which morphometric differences within NK cell subsets are exactly determined.     

TAPA-1, the target of an antiproliferative antibody, defines a new family of transmembrane proteins.

A murine monoclonal antibody was identified by its ability to induce a reversible antiproliferative effect on a human lymphoma cell line. Immunoprecipitation studies revealed that the antibody reacted with a 26-kilodalton cell surface protein (TAPA-1). A diverse group of human cell lines, including hematolymphoid, neuroectodermal, and mesenchymal cells, expressed the TAPA-1 protein. Many of the lymphoid cell lines, in particular those derived from large cell lymphomas, were susceptible to the antiproliferative effects of the antibody. TAPA-1 may therefore play an important role in the regulation of lymphoma cell growth. A cDNA clone coding for TAPA-1 was isolated by using the monoclonal antibody to screen an expression library in COS cells. Analysis of the deduced amino acid sequence indicated that the protein is highly hydrophobic and that it contains four putative transmembrane domains and a potential N-myristoylation site. TAPA-1 showed strong homology with the CD37 leukocyte antigen and with the ME491 melanoma-associated antigen, both of which have been implicated in the regulation of cell growth.     

Anti-Leu-3/T4 antibodies react with cells of monocyte/macrophage and Langerhans lineage

Anti-Leu-3a, anti-Leu-3b, OKT4, and anti-T4 murine monoclonal antibodies react with a membrane component expressed by mature peripheral blood helper T cells and certain thymocyte subsets. Using a variety of immunologic staining techniques, we have demonstrated the reactivity of these antibodies with other cell types. Normal and neoplastic cells of monocyte/macrophage lineage bear the Ia+/Leu-6-/Leu-3+ phenotype, whereas histiocytosis X cells bear the Ia+/Leu-6+/Leu-3+ phenotype. The Ia+/Leu-6- cells of malignant histiocytosis and the Ia+/Leu-6+ epidermal Langerhans cells were variably Leu-3+. Normal monocyte/macrophage reactivity with anti-Leu-3/T4 appears to be primarily intracytoplasmic, whereas on U937 monocyte tumor cells, marked membrane reactivity is also observed. These results strongly suggest that certain cells other than helper T cells and thymocytes can express and, at least in some cases, synthesize a component previously regarded as T-lineage specific.     

Induction of CD4 suppressor T cells with anti-Leu-8 antibody

To characterize the conditions under which CD4 T cells suppress polyclonal immunoglobulin synthesis, we investigated the capacity of CD4 T cells that coexpress the surface antigen recognized by the monoclonal antibody anti-Leu-8 to mediate suppression. In an in vitro system devoid of CD8 T cells, CD4, Leu-8+ T cells suppressed pokeweed mitogen-induced immunoglobulin synthesis. Similarly, suppressor function was induced in unfractionated CD4 T cell populations after incubation with anti-Leu-8 antibody under cross-linking conditions. This induction of suppressor function by anti-Leu-8 antibody was not due to expansion of the CD4, Leu-8+ T cell population because CD4 T cells did not proliferate in response to anti-Leu-8 antibody. However, CD4, Leu-8+ T cell-mediated suppression was radiosensitive. Finally, CD4, Leu-8+ T cells do not inhibit immunoglobulin synthesis when T cell lymphokines were used in place of helper CD4 T cells (CD4, Leu-8- T cells), suggesting that CD4 T cell-mediated suppression occurs at the T cell level. We conclude that CD4 T cells can be induced to suppress immunoglobulin synthesis by modulation of the membrane antigen recognized by anti-Leu-8 antibody.     

Morphologic and phenotypic features of the subpopulation of Leu-2+ cells that suppresses B cell differentiation

The Leu-2 antigen is expressed on a subpopulation of human T cells that perform suppressor and cytotoxic functions. In addition, this antigen is also present on a portion of cells with morphologic characteristics of granular lymphocytes. Although both Leu-2+ cells and granular lymphocytes have been shown to suppress B cell differentiation, the interrelationship of these two suppressor populations has not previously been fully characterized. We recently produced a monoclonal antibody, termed D12 (anti-Leu-15), which reacts with a variety of cell types, including a subpopulation of Leu-2+ cells. Previous studies have indicated that the Leu-2+ cells that suppress T cell proliferative responses express the Leu-2+15+ phenotype, whereas the precursor and effector cytotoxic T cells that recognize class I major histocompatibility antigens are Leu-2+15- lymphocytes. For this report, we used the anti-Leu-2 and anti-Leu-15 monoclonal antibodies and fluorescence-activated cell sorter techniques to characterize the E+ cells that suppress PWM-induced B cell differentiation. These studies indicate that the vast majority of Leu-2+ cells that suppress this T cell-dependent B cell response have the Leu-2+15+ phenotype. Furthermore, when the morphologic and cytochemical characteristics of these Leu-2+15+ cells were studied, virtually all of these cells were granular lymphocytes. Most of the Leu-2+15+ suppressor cells co-expressed the HNK-1 (Leu-7) antigen, which is detected only on granular lymphocytes. In contrast, virtually none of the Leu-2+15+ granular lymphocytes expressed Fc receptors for IgG molecules. These data indicate that the Leu-2+ cells that suppress PWM-induced B cell differentiation are Leu-2+15+ (and predominantly Leu-7+) granular lymphocytes that do not express Fc receptors. The implications of these observations concerning the relationship of human Leu-2+ suppressor cells to murine Ly-2+ cells and the lineage of granular lymphocytes are discussed.     

Antigen-specific suppressor T lymphocytes in man make use of the same set of surface molecules as do cytolytic T lymphocytes: roles of Leu-2/T8, Leu-4/T3, Leu-5/T11, LFA-1 molecules

When cultured with autologous antigen-primed Leu-3+ lymphoblasts, Leu-2+ cells differentiate into suppressor T cells (Ts) that specifically inhibit the responses of fresh autologous Leu-3+ cells to the priming antigen. We have shown previously that the Leu-4/T3 (CD-3) molecular complex and HLA-A,B molecules on the surface of Leu-3+ inducer blasts are recognized by Leu-2+ Ts during their differentiation. This study examines the role of various cell surface molecules expressed by Leu-2+ Ts during the inductive and effector phases of suppression. Leu-2+ cells were treated in the absence of complement with a variety of monoclonal antibodies recognizing distinct human lymphoid antigens either before or after their activation with alloantigen-primed Leu-3+ blasts. Antibodies to Leu-2/T8 (CD-8) and lymphocyte function-associated antigen-1 (LFA-1) (CDw-18) molecules inhibited not only the generation but also the effector function of Leu-2+ Ts. Although antibodies to Leu-4/T3 (CD-3) and Leu-5/T11 (CD-2) molecules caused profound inhibition of the activation of Ts, these antibodies failed to inhibit the effector function of Ts. On the contrary, anti-Leu-4 antibody consistently augmented the suppressor effect of Ts. Antibodies directed against Leu-1/T1 (CD-5), Leu-3/T4 (CD-4), LFA-3, and class I (HLA-A,B,C) and class II (HLA-DR,DQ) major histocompatibility complex molecules had no effect on either the generation or the effector function of Ts. These results suggest the involvement of Leu-2/T8 (CD-8), Leu-4/T3 (CD-3), Leu-5/T11 (CD-2), and LFA-1 (CDw-18) molecules on the surfaces of Leu-2+ cells in the activation and effector functions of Ts.     

Two distinct cytotoxic T lymphocyte subpopulations in patients with Vogt-Koyanagi-Harada disease that recognize human melanoma cells

The functional properties of cytotoxic lymphocytes from patients with Vogt-Koyanagi-Harada disease ( VKH ) specific for human melanoma cells (P-36 melanoma cell line established from a patient with malignant melanoma) were investigated by using monoclonal antibodies specific for human T cell subsets. Peripheral blood lymphocytes (PBL) from patients with VKH showed significant cytotoxic activity against the P-36 (SK-MEL-28) human melanoma cell line, but not against a human cervical carcinoma of the uterus cell line (HeLa-S3 cell line) or against a mouse melanoma cell line (B-16 cell line) originating from a C57BL/6 strain mouse or against the EL-4 mouse lymphoma cell line from a C57BL/6 mouse. The cytotoxic activity of the patients' PBL against the P-36 melanoma cell line was markedly reduced by pretreatment of the PBL with monoclonal anti-human Leu-1 antibody plus rabbit complement, but it was reduced to much less extent by pretreatment with either monoclonal anti-human Leu-2a or Leu-3a antibody plus rabbit complement. The specific cytotoxic activity of the patients' PBL against the P-36 human melanoma cell line is, therefore, mediated by T cells bearing Leu-1+ Leu-2a+ or Leu-1+ Leu-3a+ antigens. Furthermore, the cytotoxic activity was shown to be blocked not only by anti-Leu-2a antibody specific to human cytotoxic/suppressor T cells but also unexpectedly by anti-Leu-3a antibody which has previously been considered to be specific to human inducer/helper T cells. The results of this study suggest that at least two distinct subpopulations of cytotoxic T cells specific for P-36 human melanoma cells are present in the peripheral blood of VKH patients. These cytotoxic T cells have different surface antigens, Leu-2a and Leu-3a.     

Human T lymphocytes and monocytes bear the same Leu-3(T4) antigen

An analysis of the cellular distribution, biosynthesis, and structure of the human T lymphocyte antigen Leu-3(T4) was performed. By using a sensitive ELISA as well as FACS analysis, relative quantities of the Leu-3(T4) antigen from whole cell lysates and from cell surfaces of six cell lines were determined. The T-T hybrid cell line 255.88, and the monocyte/macrophage cell line U937, proved to be high producers of the antigen and were chosen for additional investigation. The Leu-3(T4) antigens from the T lymphocyte cell line and the monocyte/macrophage cell were shown to be identical by SDS-PAGE. Leu-3(T4) was a polypeptide of 55,000 AMW under reducing conditions, and 63,000 AMW under nonreducing conditions. In the 255.88 cell line, a second band of 41,000 AMW was associated with the true Leu-3(T4) molecule. The 55,000 AMW Leu-3(T4) molecule was shown to possess a high mannose sugar side chain, and to contain few accessible tyrosine residues. These studies demonstrate that human T lymphocytes and monocytes produce and process similar molecules that react with the anti-Leu-3(T4) monoclonal antibody. They also characterize this important associative antigen recognition structure and suggest that cells other than the T lymphocyte may be targets for the retrovirus HTLV-III.     

Murine monoclonal antibodies to the myelin-associated glycoprotein (MAG) recognize Leu-7-reactive molecules on human mononuclear cells

It is known that the antibody to human myelin-associated glycoprotein (MAG) reacts with a subset of human mononuclear cells (MNC) mediating a natural killer (NK) activity. The properties of the target molecule of the anti-MAG antibody, however, have not yet been elucidated. Three (GC-J4, MC-P2, and MC-P4) of five murine monoclonal antibodies (mAb) to MAG bound to human MNC. Moreover, MC-P2 and MC-P4 inhibited the binding of 125I-labeled anti-Leu-7 to MNC in a dose-dependent fashion. Conversely, anti-Leu-7 inhibited the binding of MC-P2 and MC-P4 to MNC, but did not inhibit the binding of GC-J4. Therefore, it is possible that MC-P2 and MC-P4 bind directly to or close to the Leu-7 epitope, and that GC-J4 binds to the epitope which is distinct from the Leu-7 epitope. The electrophoretic patterns of immunoprecipitates with GC-J4, MC-P2 and anti-Leu-7 from detergent lysates of surface-labeled human MNC were very similar. The target molecules of anti-Leu-7 and anti-MAG mAb have apparent m.w. of 205, 170, 150, 135, 110, 85, 65, and 55 kDa. All of the molecules precipitated by these mAb are monomeric or noncovalently associated proteins, because the electrophoretic mobilities of the proteins remained unchanged whether the samples were reduced or not. MC-P4 may have a higher affinity for the 65 kDa molecule than the other mAb, and precipitates the 58 kDa molecule as well. Therefore, the fine antigenic specificity of MC-P4 is slightly different from those of anti-Leu-7 or MC-P2. The implication of these results is that mAb, whose specificity is directed to the carbohydrate part of human MAG, reacts with the Leu-7 reactive molecules on human MNC, and that at least two epitopes detected by anti-MAG mAb coexist on the surface molecules with various apparent m.w.