Characterization of the two heavy chains of the T3 complex on the surface of human T lymphocytes

The T3 complex has been defined by a group of monoclonal antibodies which react with all human peripheral blood T lymphocytes and a subpopulation of thymocytes. This membrane structure includes glycoproteins of 44 (alpha), 37 (beta), 25 (gamma), and 20 kDa (delta) as well as a nonglycosylated polypeptide of 20 kDa (epsilon). The characterization of the alpha and beta chains has been of particular interest because they may constitute the T cell receptor for antigen. Here we show that the T3 complex prepared by immunoprecipitation from T lymphocytes of a leukemic patient (Sezary syndrome) displays an unusually strong association of the alpha and beta chains with the 20/25-kDa T3 proteins. The alpha and beta chains (48 and 44 kDa) were co-precipitated by anti-20-kDa T3 monoclonal antibodies as a disulfide-linked 90-kDa heterodimer. A minor 220-kDa multimer composed of proteins similar to the alpha and beta chains was also present in these immunoprecipitates. This multimer could be independently precipitated with a new monoclonal antibody WT-31, which detects the larger polypeptide chains of the T3 complex on all human T lymphocytes. After removal of N-linked oligosaccharides, both the alpha and beta chain were found to have 33-kDa peptide backbones with distinct isoelectric points. Using a monoclonal reagent T40/25, a 90-kDa heterodimer, consisting of 40- and 49-kDa chains with peptide backbones of 34 kDa was found to be T3-associated on the T leukemic cell line HPB-ALL. When the alpha and beta chains from the Sezary patient were compared with the corresponding chains from HPB-ALL by peptide mapping, large differences were observed. Taken together, the data presented here provide strong evidence that the T cell receptor for antigen is part of the T3 complex on the surface of human T lymphocytes.     

T3-p28 is a protein associated with the delta and epsilon chains of the T cell receptor-T3 antigen complex during biosynthesis

The human T cell receptor-T3 antigen complex is composed of at least five polypeptide chains. In addition to the 45-kDa/50-kDa heterodimer (alpha and beta chains) of the T cell receptor, the complex includes 25-kDa (T3-gamma) and 20-kDa (T3-delta) glycoproteins and a nonglycosylated 20-kDa (T3-epsilon) protein. Here we report that in pulse-chase biosynthetic labeling experiments we detect a new polypeptide chain (T3-p28) which is associated with the T3-delta and T3-epsilon chains during biosynthesis but not on the cell surface. T3-p28, which is not recognized by anti-T3 antibodies, can be chemically distinguished from the previously described T3-gamma chain. The carboxylic ionophore monensin blocks the apparent dissociation of T3-p28 from the T3-delta and T3-epsilon chains. Peripheral blood lymphocytes as well as all T cell leukemic lines tested contain T3-p28, except one HPB-ALL subline. Since the T3-p28 protein is only observed early in biosynthesis of T3-delta and T3-epsilon, it may function in intracellular transport or assembly of the T cell receptor-T3 complex.     

Biochemical studies of the human thymocyte cell-surface antigens T6, T9 and T10

Three human thymic cell-surface antigens T6, T9 and T10, previously defined by monoclonal antibodies, were analyzed using immunoprecipitation techniques. The antigen T6 was found to be a 49,000 dalton glycoprotein, which is associated with β2-microglobulin, the small subunit (12,000 daltons) of the HLA-A, -B, and -C antigens. The target antigen for the monoclonal reagent anti-T9 was found to be a glycoprotein of 94,000 daltons, which appears as a disulfide-linked dimer of 190,000 daltons on the cell surface. The antigen precipitated by the anti-T10 antibody is a 45,000 dalton glycoprotein. We present preliminary evidence that all three cell-surface proteins may be integral membrane proteins. These findings, in addition to the distribution patterns, suggest that the T6 antigen is the human homolog of the murine thymus leukemia (TL) antigen.     

Human helper-T-cell function does not require T4 antigen expression

The relationship between immunoregulatory T-cell function and the expression of T-cell subset-specific differentiation antigens was examined using a phenotypically anomalous human T-cell line (TCL), termed H-1. H-1 cells were found to express T11, extremely high levels of T3, but no T4 nor T8 antigen. Despite their lack of T4 antigen expression, H-1 cells could be activated by coculture with pokeweed mitogen (PWM), anti-T3 antibody, or autologous B cells to provide potent help for B-cell differentiation into plaque-forming cells (PFC). In contrast, H-1 cells did not suppress the PFC response triggered by PWM-activated T4+ cells. These results demonstrate that the expression of the T-cell subclass-specific differentiation antigen, T4, is not required for a T cell to become activated and to implement the program for helper function. In addition, enhanced expression of T3 on the T4-, T8-, H-1 cell surface may reflect a compensatory upregulation of the T3/Ti receptor complex on T cells which are deficient in these nonpolymorphic associative recognition structures.     

The T3/T cell receptor complex: antigenic distinction between the two 20-kd T3 (T3-delta and T3-epsilon) subunits.

Clonally distributed (clonotypic) antigen receptors on human T lymphocytes (alpha and beta chains) are associated with three invariable T3 polypeptide chains (T3 gamma, delta and epsilon), together forming the T3/T cell receptor complex. Monoclonal antibodies prepared against the two 20-kd T3 polypeptide chains demonstrated that T3-delta and T3-epsilon are distinct polypeptide chains. Only one monoclonal antibody (anti-T3-delta chain) reacted with the T cell surface as judged by indirect immunofluorescence, and by its mitogenicity for quiescent peripheral blood lymphocytes. Immunohistological staining and immunoprecipitation experiments showed that both the T3-delta and T3-epsilon chains are T cell-specific. As seen with the anti-alpha/beta chain reagent WT-31, anti-T3-delta chain monoclonal antibodies stained medullary thymocytes more intensely than cortical thymocytes, whereas the difference between the staining of cortical and medullary thymocytes was generally not apparent with anti-T3-epsilon chain antibodies. Because of this specificity and their ability to react with both the denatured and the native forms of each polypeptide chain, these new monoclonal reagents will be useful tools in studies of the biosynthesis and cell surface expression of the T3/T cell receptor complex during normal and malignant thymic differentiation.     

IGM and IGG response to 29-35-kDa Toxoplasma gondii protein fractions in experimentally infected goats

The evolution of the humoral responses of IgG and IgM against 29-35-kDa Toxoplasma gondii fractions from experimentally infected goats were studied and compared by ELISA with the use of whole T. gondii soluble extracts and 29-35-kDa electroeluted proteins as antigens. The IgM response to electroeluted proteins was detected from wk 1 to wk 3 postinfection, showing a similar evolution to that observed when T. gondii crude extracts were used as antigens. These results suggest that this group of proteins could be used for a more specific detection of anti-T. gondii IgM. In the same way, the IgG response was equivalent in both cases, although when 29-35-kDa T. gondii fractions were used as antigens, the level of specific IgGs reached a peak 2 wk before than when T. gondii crude extract was used. The detection by ELISA of anti-T. gondii IgM in goats does not seem to be affected by the presence of specific IgG in serum samples when 29-35-kDa protein fractions were used as antigens.     

Protein disulfide crosslinking stabilizes a polyoma large T antigen-host protein complex on the nuclear matrix

We have investigated the effects of intermolecular disulfide crosslinking and temperature-dependent insolubilization of nuclear proteins in vitro on the association of the polyoma large T antigen with the nuclear matrix in polyomavirus-infected mouse 3T6 cells. Nuclear matrices, prepared from polyomavirus-infected 3T6 cells by sequential extraction of isolated nuclei with 1% Triton X-100 (Triton wash), DNase I, and 2 M NaCl (high salt extract) at 4 degrees C, represented 18% of total nuclear protein. Incubation of nuclei with 1 mM sodium tetrathionate (NaTT) to induce disulfide crosslinks or at 37 degrees C to induce temperature-dependent insolubilization prior to extraction, transferred an additional 9-18% of the nuclear protein from the high salt extract to the nuclear matrix. This additional protein represented primarily an increased recovery of the same nuclear protein subset present in nuclear matrices prepared from untreated nuclei. Major constituents of chromatin including histones, hnRNP core proteins, and 98% of nuclear DNA were removed in the high salt extract following either incubation. Polyoma large T antigen was quantified in subcellular fractions by immunoblotting with rat anti-T ascites. Approximately 60-70% of the T antigen was retained in nuclei isolated in isotonic sucrose buffer at pH 7.2. Most (greater than 95%) of the T antigen retained in untreated nuclei was extracted by DNase-high salt treatment. Incubation at 37 degrees C or with NaTT transferred most (greater than 95%) of the T antigen to the nuclear matrix. T antigen solubilized from NaTT-treated matrices with 1% SDS sedimented on sucrose gradients as a large (50-S) complex. These complexes, isolated by immunoprecipitation with anti-T sera, were dissociated by reduction with 2-mercaptoethanol, and SDS-PAGE analysis revealed that T antigen was crosslinked in stoichiometric amounts to several host proteins: 150, 129, 72, and 70 kDa. These host proteins were not present in anti-T immunoprecipitates of solubilized nuclear matrices prepared from iodoacetamide-treated cells. Our results suggest that the majority of polyomavirus large T antigen in infected cells is localized to a specific subnuclear domain which is distinct from the bulk chromatin and is closely associated with the nuclear matrix.     

The T11 (CD2) molecule is functionally linked to the T3/Ti T cell receptor in the majority of T cells

Most mature human T lymphocytes express both the multichain T3 (CD3)/Ti T cell receptor for antigen (TCR), and the biochemically distinct 55-kDa T11 (CD2) glycoprotein. Stimulating the T11 molecule causes profound T cell proliferation and functional activation in vitro, but the relationship of T11-mediated activation to antigenic stimulation of T lymphocytes in vivo remains unknown. We now present evidence that T11 function is directly linked to TCR components in T3/Ti+ T11+ human T cells. First, we found that stimulating peripheral blood T cells with the mitogenic combination of anti-T11(2) cells with the mitogenic combination of anti-T11(2) plus anti-T11(3) monoclonal antibodies caused the phosphorylation of TCR T3 chains. The predominance of T3-gamma-phosphorylation that occurred in anti-T11(2) plus anti-T11(3)-treated T cells is similar to the pattern previously observed in antigen-stimulated T cell clones. Second, T11 function depended upon concurrent cell-surface expression of the TCR. Thus, when peripheral blood T cells were deprived of cell surface T3/Ti by anti-T3 modulation, anti-T11(2) plus anti-T11(3)-induced mitogenesis and transmembrane signal generation in the form of calcium mobilization were inhibited. The mechanism of TCR-T11 interdependence was investigated in a series of TCR-deficient variants of a T cell lymphoblastoid cell line. T3/Ti negative variants expressed cell surface T11, but anti-T11(2) plus anti-T11(3) failed to cause detectable calcium mobilization. The TCR-deficient variants also failed to express T11(3) activation epitopes after incubation with anti-T11(2) antibodies, suggesting that T11(3) expression is an essential and TCR-dependent intermediate in the T11 activation mechanism in these cells. Taken together, our results suggest that T11 function depends upon cell-surface expression of TCR in many T3/Ti+ T11+ T lymphocytes, and T11-mediated activation is intimately interconnected with TCR activation mechanisms. A model in which stimulating signals delivered via T11 may be a part of antigenic activation of T lymphocytes is presented.     

Analysis of the monocyte Fc receptors and antibody-mediated cellular interactions required for the induction of T cell proliferation by anti-T3 antibodies

The induction of human T cell proliferation by antibodies that cross-link T3 antigens is dependent on functional interactions of anti-T3 antibodies with monocyte Fc receptors. In this report, we used a panel of anti-T3 antibodies of differing heavy chain isotype and a variety of other monoclonal antibodies to analyze several features of the antibody-mediated interactions between T cells and monocytes that are required for mitogenesis. Whereas three IgG2a anti-T3 antibodies were mitogenic for cells from all individuals, IgM and IgG2b anti-T3 antibodies did not induce T cell proliferation in any donor and could block the proliferative responses induced by other mitogenic anti-T3 antibodies. Dose-response analyses with four IgG1 anti-T3 antibodies demonstrated donor heterogeneity as reported by other investigators. However, in contrast to these previous reports, high concentrations of IgG1 anti-T3 antibodies were found to be mitogenic for all donors, indicating that this heterogeneity is based on relative rather than absolute defects in low responder monocytes. Cell mixing experiments in which monocytes from two different low responder donors were co-cultured with T cells and IgG1 anti-T3 antibodies did not identify any complementary defects, suggesting that the low responder phenotype results from a relatively restricted polymorphism. To assess the nature of the signals required for inducing T cell proliferation, nonmitogenic anti-T3 antibodies were co-cultured with other pan-T cell antibodies having the IgG2a isotype. The combination of signals from T3 antigen cross-linkage and those independently generated by other IgG2a antibodies bound to monocyte Fc receptors did not induce T cell proliferation. Hence, it appears that the T3 antigen or closely associated structures must be clustered at the monocyte membrane for mitogenesis. Finally, in competitive inhibition experiments, the isotype specificity of monocyte Fc receptors involved in the induction of T cell proliferation was examined. Two distinct Fc receptor sites, one that binds murine IgG2a and IgG3 antibodies and a second that binds murine IgG1 antibodies, were identified. Murine IgM or IgG2b did not appear to bind either of these receptor sites. Taken together, these data indicate that human monocytes have two distinct Fc receptor sites, which must specifically and directly interact with T cell-bound anti-T3 antibodies for mitogenesis.     

Characteristics of a monoclonal antibody (WT-31) that recognizes a common epitope on the human T cell receptor for antigen

We describe a monoclonal antibody, WT-31, that reacted with all human T lymphocytes. Electrophoretic analysis of the material reacting with WT-31 revealed that it precipitated predominantly an 80-kD disulfide-linked heterodimer from the cell surface-labeled T leukemic cell line HPB-ALL. This heterodimer was identical to the one precipitated with a recently described monoclonal reagent, T40/25, which recognizes a clonotypic structure on HPB-ALL. The target antigen of WT-31 comodulated with T3 after incubation of T cells with excess anti-T3 antibody, indicating that the WT-31 target antigen is associated with T3. We also found that anti-T3 reagents, but not the clonotypic reagent T40/25, blocked binding of FITC-labeled WT-31 to HPB-ALL cells. This indicates that the T cell receptor epitope recognized by WT-31 is located close to the epitopes recognized by the anti-T3 reagents anti-Leu-4 and SPV-T3b but distal from the clonotypic T40/25 epitope. Functional studies showed that WT-31 reacts similar to anti-T3 antibodies. It is mitogenic for resting T cells, blocks cytolysis mediated by alloantigen-specific CTL clones, and induces antigen-nonspecific cytolysis by CTL clones against Daudi target cells. WT-31 did not inhibit the formation of conjugates, but it blocked cytolysis just before or during the Ca2++-dependent programming for lysis. We conclude that WT-31 is an antibody that recognizes a common determinant on the T cell receptor for antigen. The present results support the notion that the two chains of the T cell receptor (alpha and beta) form a functional protein ensemble with the three invariable T3 polypeptide chains (T3-gamma-, delta-, epsilon).     

Characterization of the interaction of polyomavirus middle T antigen with type 2A protein phosphatase.

Two cellular proteins of 36 and 63 kDa which bind the small T and middle T antigens of polyomavirus recently have been identified as the catalytic and regulatory subunits of the phosphoserine/threonine-specific type 2A protein phosphatase (PP2A). We report here the presence of phosphoseryl phosphatase activity associated with polyomavirus small T and middle T antigens in immunoprecipitates prepared from virus-infected and transformed cells. Phosphatase activity was also found associated with middle T-antigen mutants, some of which had been defined previously to associate with 36- and 63-kDa cellular proteins. Middle T-antigen-associated phosphatase activity was sensitive to okadaic acid and microcystin-LR, inhibitors of PP2A, and insensitive to inhibitor 1 or 2, orthovanadate, or EDTA. Using antiserum specific for the catalytic subunit of PP2A, we found that unlike the majority of PP2A, middle T-antigen-bound PP2A was membrane associated. However, no gross change in the amount, activity, or localization of PP2A could be attributed to middle T-antigen expression in transformed cells. Anti-PP2A antibodies coprecipitated a 63-kDa protein from normal cells and in addition coprecipitated middle T antigen, 60- and 61-kDa proteins (identified as src family members), and an 81-kDa protein from middle T-antigen-transformed cells. Furthermore, we detected protein kinase activity in PP2A immunoprecipitates and protein phosphatase activity in src immune complexes from extracts of middle T-antigen-transformed, but not normal, cells. These results reinforce the notion that at least a portion of middle T antigen bridges a protein kinase with a protein phosphatase.     

Antigen recognition by human T lymphocytes is linked to surface expression of the T3 molecular complex

Four distinct surface molecules on human T cells are defined by the monoclonal antibodies anti-T1, anti-T3 (anti-T3_A), anti-T11 and anti-T12. Following cell binding, anti-T3 (anti-T3_A) and anti-T1 induce independent modulation of their respective ligands, whereas anti-T11 and anti-T12 do not. To explore the biological consequences of this modulation, we used cloned populations of T4 and T8 cytotoxic T lymphocytes. Anti-T3 (anti-T3_A), but not anti-T1, inhibits cytotoxic T lymphocyte effector function by T4 and T8 clones as well as antigen-specific T cell recognition. The latter is not secondary to a generalized inhibitory effect since responsiveness to interleukin 2 is maintained. Moreover, after modulation, cytotoxic T lymphocytes recover cytolytic function in parallel with reexpression of surface T3 molecules. We provide evidence for a direct linkage between antigen recognition by T lymphocytes and surface expression of the T3 molecular complex.     

Growth inhibition of human T cells by antibodies recognizing the T cell antigen receptor complex

Monoclonal antibodies that bind to the T cell MHC-antigen recognition complex (anti-T3 or anti-Ti) are known to either mimic ligand binding and activate T cells or block ligand binding, leading to an inhibition of T cell activation. In the present experiments, we demonstrate a direct inhibitory effect on the growth of human T cells by anti-T3 or anti-Ti antibodies. The proliferation of human peripheral blood T cells preactivated by exposure to PHA was inhibited in a specific manner by anti-T3. Colony formation in soft agar by REX cells, a leukemic cell line of early T cell phenotype, was completely inhibited by anti-T3 or anti-Ti antibodies, whereas isotype-matched antibodies to a variety of other T cell markers had no effect. Growth of REX cells in suspension culture was not affected by anti-T3 or anti-Ti. A cell line, T3.N1, was established from an agar colony of anti-T3-resistant REX cells. T3.N1 was phenotypically identical to REX except for failure to express any detectable T3 or Ti surface antigen. T3.N1 colony formation in soft agar was not inhibited by anti-T3 or anti-Ti. There was no rise in [Ca2+]i of T3.N1 cells after anti-T3 or anti-Ti exposure. These results indicate that in addition to the well-known positive regulatory effects of ligand binding to the T3/Ti complex, T3/Ti binding can also result in a down-regulatory signal for human T cell growth.     

An induced fit hypothesis for antigen recognition by T lymphocytes: a role for specific antigen retention structures on antigen-presenting cells

The nature of T lymphocyte recognition of foreign antigens is not known, despite recent advances in elucidating the cellular structures that may be involved in the specific interactions. The central difficulty in this process is that T cells respond to foreign antigen only in the context of major histocompatibility complex (MHC) antigens expressed by another antigen-presenting cell. In addition, T cells that interact with class II MHC antigens do not bind foreign protein antigens in their native form, but seem to recognize only proteolytic peptide fragments as the relevant antigen. The simplest explanation for these observations is that the class II MHC antigens themselves bind antigenic peptides to form the appropriate determinant that interacts with the antigen-specific T cell receptor. However, to date no such antigenic complex has been found with MHC antigens despite rigorous attempts at their demonstration. One alternative explanation described here is that there is no preexisting foreign antigen-MHC antigen complex prior to interaction with T cells, and it is the T cells that cause the two moieties to become associated for recognition by a single antigen-specific T cell receptor. Central to this mechanism is that foreign antigenic peptides must be associated with specific antigen retention structures (SARS) expressed by antigen-presenting cells which retain and protect the peptide on the cell surface. These SARS, upon interaction with T cell membrane moieties, would subsequently associate with MHC antigens. A hypothesis to describe this mechanism is developed to account for published observations of antigen processing by antigen-presenting cells and T cell antigen recognition, and makes several predictions that are experimentally testable. This mechanism is also generally applicable to other cellular interactions in which soluble peptide mediators may become associated with surface components of one cell type, and this newly formed complex is in turn recognized by a receptor on a second cell type to deliver functional signals.     

Cellular proteins that associate with the middle and small T antigens of polyomavirus.

We have used two-dimensional gel electrophoresis to analyze in more detail the cellular proteins which associate with the middle and small tumor antigens (MT and ST, respectively) of polyomavirus. Proteins with molecular masses of 27, 29, 36, 51, 61, 63, and 85 kilodaltons (kDa) that specifically coimmunoprecipitated with MT were identified on these gels. The 36-, 51-, 61-, 63-, and 85-kDa proteins are probably the same as the proteins of similar sizes previously reported by a number of groups, whereas the 27- and 29-kDa proteins represent proteins that are heretofore undescribed. The 27- and 29-kDa proteins were abundant cellular proteins, whereas the others were minor cellular constituents. The association of each of these proteins with MT was sensitive to one or more mutations in MT that rendered it transformation defective. The association of the 85-kDa protein was the most sensitive indicator of the transformation competence of MT mutants. In addition, the 85-kDa protein was the only associated protein whose association with MT changed consistently in parallel with MT-associated phosphatidylinositol kinase activity. Furthermore, the fraction of the 85-kDa protein which was found associated with the MT complex contained 15 to 20% of its phosphate content on tyrosine. The 36- and 63-kDa proteins complexed with both polyomavirus MT and ST and comigrated on two-dimensional gels with two simian virus 40 ST-associated proteins originally described by Rundell and coworkers (K. Rundell, E. O. Major, and M. Lampert, J. Virol. 37:1090-1093, 1981). None of the other MT-associated proteins associated significantly with ST.     

Stoichiometry of large T antigen and pp53 in complexes isolated from simian virus 40-transformed rat cells.

Simian virus 40-transformed cells synthesize high-molecular-weight protein complexes (22 to 30S) that consist of the virus-coded large T antigen (81,500 daltons) and the cellular antigen pp53. These complexes were partially purified from lysates of transformed rat cells by sucrose velocity sedimentation. The stoichiometry of the two proteins in the complex was studied by direct enzyme-linked immunosorbent assays, using alkaline phosphatase-conjugated anti-T and anti-pp53 monoclonal antibodies. The results from these experiments indicate that the T antigen-to-pp53 ratio in the complex is 0.87 +/- 0.27. No statistically significant differences were found in this ratio for faster- and slower-sedimenting complexes. These results from enzyme-linked immunosorbent assays and previous molecular weight estimates of the complex suggest that this complex is composed, on the average, of four molecules of T antigen and four or five molecules of pp53.     

Amplification of suppressor inducer pathway with monoclonal antibody, anti-2H4, identifying a novel epitope of the common leukocyte antigen/T200 antigen

The 2H4 antigen, comprised of a 200/220-kDa glycoprotein of the leukocyte common antigen (LCA) family, is expressed on a suppressor inducer, but not a helper inducer subset of T4 cells. Earlier studies have demonstrated that the T4+2H4+ subset of cells maximally responded to the AMLR and this molecule has an important role in generated suppressor signals in AMLR/Con A-activated T cell systems. In the present study, we examined the effect of a series of monoclonal antibodies including anti-2H4 antibody on the initial activation of T4 cells in response to self-Ia antigens. We found that the addition of anti-2H4 antibody resulted in an augmentation of the proliferative response of T4 cells in AMLR, whereas other antibodies reactive with LCA/T200 antigens lacked this ability. Furthermore, anti-2H4 antibody enhanced both IL-2 production and IL-2R expression in this AMLR system. This enhancing effect was inhibited by anti-T3 antibody. Moreover, the suppressor inducer function of AMLR T4 cells was enhanced with anti-2H4 antibody by increasing the number of 2H4+ cells with high antigen density. Taken together, these results suggest that the 2H4 antigen may serve as an accessory structure for enhancing the activation of the T4+2H4+ suppressor inducer subset at initiation of cell triggering.     

Biochemical analysis of two cell surface glycoprotein complexes, very common antigen 1 and very common antigen 2. Relationship to very late activation T cell antigens

Two mouse monoclonal antibodies (mAb), AJ2 and J143, define two related human cell surface protein complexes, very common antigen 1 (VCA-1) and very common antigen 2 (VCA-2). In the present report, these complexes have been defined with respect to: (i) subunit arrangement; (ii) monoclonal antibody binding sites; (iii) carbohydrate content; (iv) homology to other cell surface protein complexes; and (v) possible functional roles. Analysis of the antigens from a human melanoma cell line, MeWo, reveals that VCA-1 is a noncovalently linked heterodimer of 170- and 140 (designated 1401)-kDa polypeptides. mAb AJ2 reacts with an epitope on the 1401-kDa polypeptide. VCA-2 is composed of the same 1401-kDa polypeptide as VCA-1 and another 170-kDa species; this 170-kDa species consists of a second distinct 140-kDa (designated 140(2)) and a 30-kDa polypeptide which are disulfide-bonded. Indirect evidence indicates that mAb J143 reacts with an epitope on this 170-kDa complex. Peptide mapping has shown that the complexes are members of a family of cell surface proteins that include antigens present on activated T cells (designated very late activation antigens). Since VCA-2 is found predominantly on the basal membrane of adherent cells and its expression increases 12-fold when HUT-102 lymphoblastoid cells are grown as an adherent cell culture, we suggest that VCA-2 plays a role in cellular adherence.     

Cross-linking of T3 (CD3) with T4 (CD4) enhances the proliferation of resting T lymphocytes

Monoclonal antibodies reactive with defined T lymphocyte surface antigens were covalently coupled to protein A-Sepharose beads using the bifunctional imidoester, dimethyl pimelimidate. Sepharose-immobilized antibody reactive with T3 induced the proliferation of resting T lymphocytes in the presence of either recombinant interleukin 2 or phorbol myristate acetate. When monoclonal antibodies reactive with T3 and T4 were coupled to the same Sepharose bead (hereafter designated Sepharose (T3:T4)), proliferation was enhanced an average of three-fold. Similarly prepared Sepharose beads coupled to anti-T3 and anti-T8 also enhanced proliferation over that observed with anti-T3 alone. Sepharose (T3:T4) similarly increased the proliferation of T4+ lymphocytes and a T4+ clone but failed to enhance the proliferation of T8+ lymphocytes. The increased proliferation of T4+ lymphocytes resulted from a preferential activation of the T4+2H4- helper population over the T4+2H4+ suppressor-inducer population. The enhanced proliferation induced by Sepharose (T3:T4) could be completely inhibited by soluble anti-T4. These results suggest that perturbation of T3 may be a minimal signal for T cell activation and that the assembly of a multimeric complex including T3 and T4 may be required for optimal T cell activation.     

The T4 molecule differentially regulating the activation of subpopulations of T4+ cells

It has been demonstrated that the T4+2H4+ subset functioned as a suppressor inducer cell, whereas the reciprocal T4+2H4- subset provided help for B cell Ig production. In the present studies, a series of monoclonal antibodies to cell surface structures expressed on these subsets of cells were examined for their effects on the proliferative and immunoregulatory functions generated in AMLR. We demonstrated that anti-T4 antibody preferentially inhibited the proliferative response of the T4+2H4+ but not T4+2H4- cells against self-MHC antigens. In contrast, anti-T3 and anti-Ia antibodies inhibited the response of both subsets of cells. This subset preference of anti-T4 antibody was not attributable to either the isolation procedures used or a shift in the kinetics of proliferation to autologous self-MHC antigens. Moreover, both IL 2 production and the immunoregulatory function of the T4+2H4+ subset was profoundly inhibited by anti-T4 antibody, whereas the T4+2H4- subset was minimally influenced. In the absence of Ia molecules, T4+2H4+ but not T4+2H4- cell proliferation was inhibited with anti-T4 antibody. Together, these results suggest that the T4 molecule plays a distinct functional role in the differential triggering of subsets of T4+ cells.