Lack of HLA class I and class II antigens on human preimplantation embryos

The expression of HLA Ag on polyploid early human embryonic stages, obtained in an in vitro fertilization and embryo transfer program, was investigated by indirect immunofluorescence tests using a panel of mAb. Neither HLA class I Ag, beta 2-microglobulin, nor HLA class II molecules could be detected on blastomers. The zona pellucida also lacked these Ag, but granulosa cells expressed HLA class I Ag, beta 2-microglobulin, and HLA class II Ag. These results make it likely that the absence of HLA Ag is one of the mechanisms involved in protecting the implanting embryo from rejection by the immunocompetent mother.     

Recognition of nonclassical HLA class I antigens by gamma delta T cells during pregnancy

The healthy trophoblast does not express classical HLA-A and HLA-B products; therefore, an MHC-restricted recognition of trophoblast-presented Ags is unlikely. In the decidua and also in peripheral blood of healthy pregnant women, gammadelta T cells significantly increase in number. We investigated the possible role of gammadelta T cells in recognition of trophoblast-presented Ags. PBL and isolated gammadelta T cells from healthy pregnant women as well as from those at risk for premature pregnancy termination were conjugated to choriocarcinoma cells (JAR) transfected with nonclassical HLA Ags (HLA-E, HLA-G). To investigate the involvement of killer-inhibitory/killer-activatory receptors in trophoblast recognition, we tested the effect of CD94 block on cytotoxic activity of Vdelta2(+) enriched gammadelta T cells to HLA-E- and/or HLA-G-transfected targets. Lymphocytes from healthy pregnant women preferentially recognized HLA(-) choriocarcinoma cells, whereas those from pathologically pregnant patients did not discriminate between HLA(+) and HLA(-) cells. Normal pregnancy Vdelta2(+) T cells conjugated at a significantly increased rate to HLA-E transfectants, whereas Vdelta2(+) lymphocytes from pathologically pregnant women did not show a difference between those and HLA(-) cells. Blocking of the CD94 molecule of Vdelta2(+) lymphocytes from healthy pregnant women resulted in an increased cytotoxic activity to HLA-E-transfected target cells. These data indicate that Vdelta2(+) lymphocytes of healthy pregnant women recognize HLA-E on the trophoblast, whereas Vdelta1 cells react with other than HLA Ags. In contrast to Vdelta2(+) lymphocytes from healthy pregnant women, those from women with pathological pregnancies do not recognize HLA-E via their killer-inhibitory receptors and this might account for their high cytotoxic activity.     

Expression of class II antigens by subsets of activated T cells

Gene products coded for within the HLA complex play an important role in the control of immune responses. Class I antigens, coded for by the HLA-A, B, and C loci, are expressed by virtually all mononuclear blood cells. Class II antigens, coded for by the DR, DQ, and DP loci, have a more limited tissue distribution. They are expressed by B cells, monocytes, and by activated, but not by resting, T cells. The class II molecules of B cells and antigen-presenting cells have long been of interest to immunologists, since they are involved in the presentation of antigen, in communication between T cells and B cells and between T cells and adherent cells, and in susceptibility to certain diseases. The class II antigens expressed by activated T cells, however, remain largely uncharacterized in terms of their specificity, functional significance, and molecular nature. We have studied the expression of DR and DQ antigens by activated T cells and then examined the expression of DR versus DQ antigens by Leu 2a and Leu 3a subsets of mitogen-activated populations. Our results demonstrated that, as for class II-positive macrophages, the intensity of staining with monoclonal antibodies directed against DR antigens was much greater than that obtained with those directed against DQ antigens. Interestingly, the percentages of Leu 2a- and Leu 3a-positive cells which expressed DR antigens were quite similar, as were the percentages of Leu 2a and Leu 3a cells which expressed DQ. Thus, there does not seem to be preferential expression of DR versus DQ antigens by mitogen-activated T-cell subsets. Finally, though both DR-positive-DQ-positive and DR-positive-DQ-negative populations were detected, few or no DR-negative-DQ-positive cells were observed in these populations.     

HLA class II-restricted presentation of cytoplasmic measles virus antigens to cytotoxic T cells

To analyze the nature of the HLA class II-restricted cytotoxic T-lymphocyte (CTL) response to measles virus, murine fibroblasts were transfected with expressible cDNA clones for human HLA-DR antigen and for measles virus matrix or nucleocapsid proteins. DR-positive murine fibroblasts transfected with measles virus matrix or nucleocapsid genes were lysed by class II-restricted measles virus-specific CTL lines. Lysis was as efficient as with infected autologous B-cell lines, even though the measles virus cytoplasmic proteins were undetectable by antibodies in the transfected target cells. These results demonstrate that cytoplasmic viral antigens can be presented to CTL in the context of HLA class II antigens and that measles virus matrix and nucleocapsid proteins contribute to class II-restricted measles virus-specific CTL responses. These results also show that endogenously synthesized measles virus proteins can be efficiently presented by class II antigens. The implications of these findings for measles virus pathogenesis and for antigen processing are discussed.     

Induction of HLA class II molecules on human T cells: relationship to immunoregulation and the pathogenesis of AIDS.

Human T cells express HLA class II molecules upon activation. The factors that regulate the induction of expression of these molecules are for the most part unknown. Here we report preliminary results indicating that tumor necrosis factor-alpha (TNF-alpha) regulates the induction of cell-surface HLA-DR, DO, and DP molecules in human T cells stimulated with PHA. In contrast, recombinant interferon-gamma (rIFN-gamma), recombinant interleukin-1 alpha (rIL-1 alpha), or rIL-4 appear to have no effect on class II expression. The role of class II molecules on activated T cells is discussed in relationship to immunoregulation and the progression of HIV infection. Three non-mutually exclusive hypotheses are discussed. In the first hypothesis, we consider the role of these class II molecules in antigen presentation of endogenously synthesized HIV envelope by CD4+ cells. The second is a clonal inactivation of virus-specific helper T cells that might occur as a consequence of a direct T cell to T cell interaction and a bypass of the "accessory signal" normally delivered by antigen-presenting cells such as macrophages. The third is a molecular mimicry between HIV envelope proteins and HLA class II molecules, which may lead to the development of autoimmunity against CD4+ T-cell-expressing class II molecules.     

Cancerous HLA class I expression and regulatory T cell infiltration in gastric cancer

Background

Since antitumor immune reactions between tumors and intratumoral immunocytes have been verified in several human tumors, immunological therapeutic strategies must be considered to obtain the proper efficacy of tumor shrinkage under these conditions. Human leukocyte antigen (HLA) class I expression in cancer cells and degree of infiltration of regulatory T cells (Tregs) in the stroma have been regarded as important markers of antitumor immune reactions in the context of independent immunological mechanisms. In the current study, we investigated HLA class I expression and Treg cells infiltration in gastric cancer and discussed the clinical implications of this combinatory analysis in gastric cancer.

Patients and methods

A total of 141 gastric cancer patients who received R0 gastrectomy at Kagoshima University Hospital were studied. Immunohistochemically, in 141 gastric cancer patients, HLA class I expression and Treg cell infiltration in cancerous tissue were evaluated using HLA class I (EMR8-5) and forkhead box p3 (FOXP3) monoclonal antibodies. The correlation between clinical factors and tumor-infiltrating Treg cells was analyzed.

Results

HLA class I expression was positively associated with depth of tumor invasion (P?r?=?0.04). A better postoperative outcome was associated with fewer numbers of Treg infiltration (P?=?0.034). A combination of HLA and Treg analysis may lead to a more accurate prediction of postoperative outcome (P?=?0.02).

Conclusions

Two different antitumor immunological markers, Treg infiltration and HLA class I expression, affected clinicopathological factors in gastric cancer by different mechanisms. Thus, an immunological combination of HLA class I expression and Treg cell infiltration may more accurately predict postoperative outcome. Immunological balance needs to be restored after evaluation of each immunological deficit in gastric cancer.     

Separation and comparison of human TL-like antigens and HLA(A,B, C) antigens expressed on Cultured T cells

Beta₂-microglobulin-bound T-cell membrane components containing both human TL-like antigens and HLA(A, B, C) antigens were partially purified from Renex 30-solubilized membrane material of cells of a human T-cell-type leukemia cell line, HPB-ALL. The radioiodinated preparation was subjected to limited papain digestion; the HLA(A, B, C) antigens split, whereas a large portion of the human TL-like antigens remained intact. The antigen molecules were recovered by lentil-lectin affinity chromatography and separated by gel filtration on the basis of the induced difference in molecular size. The human TL-like-antigen preparation thus obtained was essentially free of HLA(A, B, C) antigens. The human TL-like antigens were immunospecifically precipitated and the component polypeptide, heavy and light, chains were separated by acid dissociation followed by gel filtration. The component chains were compared with the corresponding chains of HLA(A, B, C) antigens obtained similarly from the same HPB-ALL cells with respect to their fragmentation patterns on chemical or enzymatic cleavage. The results provided convincing evidence for the identity of the light chains of human TL-like antigens and HLA(A, B, C) antigens, and also evidence suggesting the presence of substantial differences in the fundamental structure of the heavy chains of human TL-like antigens and HLA(A, B, C) antigens.A unit of the New York State Department of Health.     

Role of HLA class I and class II antigens in activation and differentiation of B cells

The monoclonal antibodies (MoAb) CR10-214, CR11-115, and Q1/28 to distinct monomorphic determinants of HLA class I antigens, the MoAb CL413 and PTF29.12 recognizing monomorphic determinants of HLA-DR antigens, the anti-HLA-DQw1 MoAb KS11, the anti-HLA-DPw1 MoAb B7/21, and the anti-HLA-DR,DP MoAb CR11-462 were tested for their ability to modulate human B-lymphocyte proliferation and maturation to IgM-forming cells. Purified tonsillar B cells were stimulated with Staphylococcus aureus bacteria of the Cowan first strain (SAC) or anti-human mu-chain xenoantibodies, as well as in growth factor- or T-cell-dependent activation cultures. The B-cell proliferative responses induced by SAC or by mitogenic concentrations of anti-mu-chain xenoantibodies were inhibited by some of the anti-HLA class I and anti-HLA class II monoclonal antibodies tested. The same antibodies were effective inhibitors of the proliferation of B cells stimulated with interferon-gamma (IFN-gamma) or interleukin-2 (IL-2) and with submitogenic concentrations of anti-mu-chain xenoantibodies. The proliferation induced by IL-2 of SAC-preactivated B cells was inhibited by some of the anti-HLA class II monoclonal antibodies, but not by the anti-HLA class I monoclonal antibodies tested. This inhibition appeared to reflect at least in part a direct effect on later events of the B-cell activation cascade, since some anti-HLA class II monoclonal antibodies still exerted considerable inhibitory activity when added together with IL-2 to SAC-preactivated B cells after the third day of culture. Anti HLA-DR, DQ, and DP monoclonal antibodies consistently inhibited the IgM production induced in B cells by T cells alone, T cells plus pokeweed mitogen (PWM), SAC plus IL-2, or IL-2 alone. In contrast, two of the three anti-HLA class I monoclonal antibodies tested inhibited the IgM production in cultures stimulated with SAC plus IL-2 and one the IgM production induced by IL-2 alone, but none of them had inhibitory effects on T-cell dependent IgM production. The results reported herein indicate that HLA class II molecules directly participate in different phases of the B-cell activation cascade. In addition, our data also suggest that HLA class I molecules can be involved in the events leading to B-cell proliferation and differentiation into immunoglobulin-secreting cells.     

Analysis of mRNA for class I HLA on human gametogenic cells

We have studied mRNA expression for Class I HLA (human leukocyte antigen) on male germ cells by amplification of gene fragments in PCR techique and by Northern hybridization. RNA was extracted from fractionated gametogenic cells (isolated from testis) and reversely transcribed. Then, cDNA was amplified for specific HLA sequence (1151 bp) representing whole-length coding sequence (HLA, -A, -B, -C). The specificity of this product was confirmed in “nested” PCR of 400 bp gene fragment coding for alpha 2 domain, alpha 3 domain, and the transmembrane portion of Class I HLA. The results indicate minimal expression of classical Class I HLA on gametogenic cells. Northern hybridization with 669 bp cDNA fragment (spanning for alpha 3 domain, transmembrane, cytoplasmic, and 3′ untraslated region) resulted in a low intensity signal from gametogenic cell fractions and confirmed our findings obtained by PCR. The minimal expression of classical HLA antigens may create a neutral cover for the male reproductive system, thereby preventing an immunological response during germ cell differentiation. © 1994 Wiley-Liss, Inc.     

Missing HLA class I expression on Daudi cells unveils cytotoxic and proliferative responses of human gammadelta T lymphocytes

The major subset of human blood gammadelta T lymphocytes expresses the variable-region genes Vgamma9 and Vdelta2. These cells recognize non-peptidic phosphoantigens that are present in some microbial extracts, as well as the beta(2)-microglobulin-deficient Burkitt's lymphoma Daudi. Most cytotoxic human Vgamma9/Vdelta2 T cells express inhibitory natural killer cell receptors for HLA class I that downmodulate the responses of the gammadelta T lymphocytes against HLA class I expressing cells. In this study we show that transfection of the human beta(2)-microglobulin cDNA into Daudi cells markedly inhibits the cytotoxic and proliferative responses of human Vgamma9/Vdelta2 T cells. This provides direct evidence that the "innate" specificity of human Vgamma9/Vdelta2 T-lymphocytes for Daudi cells is uncovered by the loss of beta(2)m by Daudi. However, Daudi cells that express HLA class I in association with mouse beta(2)m at the cell surface are recognized by human Vgamma9/Vdelta2 T cells close to the same degree as the parental HLA class I deficient Daudi cell line. Thus, proper conformation of the HLA class I molecules is required for binding to natural killer cell receptors. Cloning of the HLA class I A, B, and C molecules of Daudi cells and transfer of the individual HLA class I molecules of Daudi cells into the HLA class I deficient recipient cell lines.221 and C1R demonstrate that for some human gammadelta T-cell clones cytolysis can be entirely inhibited by single HLA class I alleles while for other clones single HLA class I alleles only partially inhibit cytotoxicity. Thus, most human Vgamma9/Vdelta2 T cells represent a population of killer cells that evolved like NK cells to destroy target cells that have lost expression of individual HLA class I molecules but with a specificity that is determined by the Vgamma9/Vdelta2 TCR.     

Soluble HLA class I and HLA class II antigens in the blood of HIV infected patients

The levels of HLA, class I, antigen and HLA-DR antigen in the blood sera of HIV-infected persons were determined by the enzyme immunoassay. The levels of soluble antigens HLR-DR and of HLA, class I, in serum samples containing only antibodies to HIV were elevated, respectively, 1.8- and 1.3-fold in comparison with the norm. The level of soluble HLA-DR antigen in samples containing the markers of other infections (HBsAg, antibodies to hepatitis C virus, anti-IgM antibodies to cytomegalovirus) was significantly higher in comparison with samples containing only antibodies to HIV and serum samples from healthy donors (p < 0.05). The concentration of soluble HLA antigen, class I, in the samples containing antibodies to HIV and markers of other infections was also elevated, but the statistically authentic increase in comparison with the normal level was observed only in the presence of the markers of HIV infection, hepatitis C and cytomegalovirus infection.     

Activation of human T4 cells by cross-linking class I MHC molecules

These studies examined whether cross-linking class I MHC molecules results in functional or biochemical responses in human T4 cells. The initial studies demonstrated that cross-linking class I MHC molecules either by culturing highly purified T4 cells with immobilized mAb to class I MHC Ag or reacting the T4 cells with mAb to class I MHC Ag and then cross-linking the mAb with goat antimouse Ig (GaMIg) enhanced T4 cell proliferation induced by an immobilized mAb to CD3, OKT3. More-over, immobilized but not soluble mAb to class I MHC Ag enhanced T4 cell proliferation induced by the combination of two mAb to CD2, OKT11, and D66.2. Finally, T4 cells reacted with mAb to CD3 and class I MHC Ag proliferated in the presence of IL-2 when cross-linked with GaMIg more vigorously than T4 cells reacted with either mAb alone. Cross-linking class I MHC molecules was also found to stimulate T4 cells directly. T4 cells reacted with mAb to class I MHC Ag or beta 2 microglobulin and cross-linked with GaMIg proliferated vigorously in the presence of IL-2 or PMA. In addition, it was demonstrated that cross-linking class I MHC molecules by culturing T4 cells with immobilized mAb to class I MHC Ag induced T4 cell proliferation in the presence of IL-2. T4 cell proliferation in the presence of IL-2 and PMA could also be induced by reacting the cells with specific mAb to polymorphic determinants on class I MHC molecules and cross-linking with GaMIg. Cross-linking mAb to CD4 or CD11a did not have a similar functional effect on T4 cells. Finally it was demonstrated that adding GaMIg to T4 cells reacted with mAb to class I MHC Ag but not CD11a resulted in an increase in intracellular calcium concentration. The data demonstrate that cross-linking class I MHC molecules results in the generation of at least one activation signal, a rise in intracellular calcium concentration, and, thereby, stimulates human T4 cells.     

Effect of monoclonal antibodies (MoAb) to class I and class II HLA antigens on lectin- and MoAb OKT3-induced lymphocyte proliferation

We have examined the effect of several monoclonal antibodies (MoAb) to monomorphic determinants of class II HLA antigens, and MoAb to monomorphic determinants of class I HLA antigens and to beta-2-microglobulin (beta 2-mu) on lectin- and MoAb OKT3-induced proliferation of human peripheral blood mononuclear cells (PBMNC) and cultured T cells (CTC). Some, but not all, anti-class II HLA MoAb inhibited the proliferative response of PBMNC to MoAb OKT3 and pokeweed mitogen (PWM). The degree of inhibitory effect varied considerably. This effect was not limited to anti-class II HLA MoAb since anti-class I HLA MoAb and anti-beta 2-mu MoAb also inhibited MoAb OKT3- or PWM-induced proliferative responses. In contrast, the response of PBMNC to phytohemagglutinin (PHA) and concanavalin A (Con A) was not blocked by any anti-class II HLA MoAb. However, some anti-class II HLA MoAb also inhibited the proliferative response of CTC plus allogeneic peripheral blood adherent accessory cells (AC) to PHA or Con A as well as to MoAb OKT3 or PWM. This may be attributable to the substantially greater class II HLA antigen expression by CTC than by fresh lymphocytes. Pretreatment of either CTC or AC with anti-class II HLA MoAb inhibited OKT3-induced proliferation. In contrast, pretreatment of CTC, but not AC, with anti-class I HLA MoAb inhibited the proliferative response of CTC to OKT3. Pretreatment of CTC with anti-class I HLA MoAb inhibited PHA-, Con A and PWM-induced proliferation, to a greater degree than the anti-class II HLA MoAb. It appears as if lymphocyte activation by different mitogens exhibits variable requirements for the presence of cells expressing major histocompatibility determinants. Binding of Ab to membrane markers may interfere with lymphocyte-AC cooperation, perhaps by inhibiting binding of mitogens to their receptors or by interfering with lymphocyte and AC function. We also have examined the role of class II HLA antigens on CTC by depleting class II HLA-positive cells. As expected, elimination of class II HLA-positive AC with anti-class II HLA MoAb plus complement caused a decrease in proliferation of CTC in response to all the mitogens tested. In contrast, elimination of class II HLA-positive CTC was shown to clearly increase proliferation of CTC, perhaps because this may deplete class II HLA-positive suppressor cells.     

Modulation of class I and class II histocompatibility antigens on human T cell lines by IFN-gamma

IFN-gamma is an immunomodulatory agent which is known to induce or enhance the expression of class II histocompatibility Ag (Ia Ag) on many lymphoid cells and cell lines of diverse origin. However, we have observed that IFN-gamma did not induce the expression of Ia Ag on Ia- human T cell lines. Neither did IFN-gamma enhance the expression of Ia Ag on Ia+ T cells. However, IFN-gamma was able to enhance the expression of class I histocompatibility Ag (HLA-A,B,C Ag) on a number of the T cell lines tested. Experiments with 125I-labeled IFN-gamma showed a relatively small degree of specific binding to these T cell lines. More extensive studies on two of the T cell lines demonstrated 1000 and 2600 IFN-gamma binding receptor sites/cell and binding affinities of 4.0 X 10(-10) M and 7.3 X 10(-10) M. Thus, although IFN-gamma can bind to human T cell lines and enhance class I histocompatibility Ag on these cells, IFN-gamma alone does not appear to regulate expression of class II histocompatibility Ag on T cell lines.     

Lymphocyte subsets differentially induce class II human leukocyte antigens on allogeneic microvascular endothelial cells

Increased expression of major histocompatibility complex class II (Ia) antigens on vascular endothelium is a common observation in allografts undergoing acute rejection. This phenomenon is generally ascribed to the host immune response directed against graft alloantigens, but its cellular and molecular basis are incompletely understood. In the present study we show that constitutively Ia-negative human microvascular endothelial cells (EC) can be induced to express surface class II human leukocyte antigens shortly after exposure to allogeneic lymphocytes in vitro. CD16+ (natural killer) and CD8+ (cytotoxic/suppressor) lymphocytes were efficient in triggering Ia antigen expression by EC, whereas CD4+ (helper/inducer) lymphocytes induced EC Ia expression only if cultured in the presence of autologous monocytes. Binding of lymphocytes to EC was shown to be essential for the subsequent induction of EC Ia, and anti-CD18 (LFA-1) antibody, which blocks lymphocyte-EC adhesion, was the only antibody of a panel of antilymphocyte antibodies that completely blocked the induction of EC Ia. Antibodies to interferon-gamma, which is a potent inducer of EC Ia, and to the CD3 T cell-surface antigen partly inhibited the induction of EC Ia by T cells, but neither antibody had any effect on Ia induction mediated by CD16+ cells, suggesting that T cells and natural killer cells utilize different mechanisms to induce Ia on EC. When combined with data from other laboratories indicating that Ia+ but not Ia- EC stimulate allogeneic T cell proliferation and cytotoxicity, our results suggest that the binding of EC by lymphocyte subpopulations followed by the induction of Ia antigen may represent the initial stage of incompatible allograft rejection.     

Possible association between IL-2 receptors and class I HLA molecules on T cells

In the process of evaluating murine hybridomas for an antibody to the beta-subunit of the IL-2R (p70) we identified an antibody that immunoprecipitated a 55- to 57-kDa complex from cross-linked lysates. We demonstrate that this complex is composed of IL-2 (15.5 kDa) cross-linked to the H chain of HLA class I (40 to 42 kDa), suggesting a molecular interaction between HLA class I molecules and IL-2R. Although the exact role of this association remains to be determined, the specific cross-linking of IL-2 to HLA class I Ag is intriguing in view of published claims for a role of HLA class I in OKT3-induced lymphocyte proliferation and in NK cell lytic activity.     

The role of HLA class I antigens in recognition of melanoma cells by tumor-specific cytotoxic T lymphocytes. Evidence for shared tumor antigens

CTL lines were established in vitro by stimulating patient lymphocytes with autologous melanoma cells in the presence of IL-2. Resulting CTL lines lysed autologous melanoma and failed to lyse several allogeneic melanomas or K562. The mechanism of target cell recognition by autologous tumor-specific CTL was evaluated in this system, using several CTL lines: DT6, DT105, DT141, DT166, DT169, and DT179. Autologous melanoma lysis was inhibited by W6/32, mAb directed against HLA class I Ag, but not by L243, mAb directed against HLA class II Ag. CTL from DT6, DT141, DT166, DT169, and DT179 lysed fresh and cultured allogeneic melanomas, which shared the HLA-A2 Ag, but failed to lyse allogeneic melanomas, which shared B-region or C-region Ag, or shared no HLA class I Ag. CTL from DM141 lysed DM93, which shared A2 and Bw6, but failed to lyse DM105, which shared only Bw6. DM105 CTL failed to lyse allogeneic melanomas that shared HLA-A1, or that shared B or C region Ag, but they did lyse allogeneic melanoma DM49, which expressed an A region Ag that either was A10 or was serologically cross-reactive with A10. A T cell leukemia line, three EBV transformed B cell lines, and a pancreatic cancer line, all of which expressed HLA-A2, were not lysed by DM6 or DM179 CTL. Furthermore, HLA-matched nonmelanomas failed to inhibit autologous tumor lysis in cold target inhibition assays, whereas an HLA-A2+ allogeneic melanoma, DM93, inhibited autologous tumor lysis as effectively as the autologous tumor itself. HLA-A2, and possibly other HLA-A-region Ag, appear to function in HLA-restricted recognition of shared melanoma associated Ag by CTL.     

Possible involvement of the T4 molecule in T cell recognition of class II HLA antigens: evidence from studies of proliferative responses to SB antigens

The T4 molecule has been identified as a marker of human T cell differentiation, but the function of this molecule remains to be defined. We have investigated its possible functional involvement in T cell proliferative responses to class II HLA antigens encoded by the recently described SB locus. The responses of SB-primed cells (specific for each of four different SB antigens) were studied with the use of two proliferation-inducing stimuli, SB antigen or TCGF. The proliferative responses to both stimuli were found to be mediated by T4+, T8- cells. Monoclonal antibodies against some epitopes on the T4 molecule (OKT4A and OKT4B) substantially blocked antigen-stimulated proliferative responses; antibodies against other epitopes of the T4 molecule (OKT4, T4C, T4D) blocked less well. Inhibition of SB-specific proliferation by antibodies to the T4 molecule was maximal only when the antibodies were incubated with the responder cells before the addition of stimulator cells. Proliferative responses of SB-primed cells stimulated with TCGF alone were not inhibited by any of the OKT4-related antibodies, but were completely inhibited by the anti-Tac monoclonal antibody, which reacts with the TCGF receptor. These results lend further support for the hypothesis that the T4 molecule is involved in T cell recognition of and/or activation by class II HLA antigens. We suggest that 1) the T4 molecule binds a nonpolymorphic epitope on class II HLA molecules, and 2) this interaction may facilitate, but not be an obligate requirement for, T cell activation by class II antigens.