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.     

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.     

Antigen-specific suppressor T lymphocytes (Leu-2a+3a-) in human schistosomiasis japonica

Immunoregulatory mechanisms in human schistosomiasis japonica were investigated through in vitro T lymphocyte-macrophage co-culture experiments. High responder T lymphocytes responded to the schistosomal adult worm antigen in the presence of HLA-DR-compatible low responder macrophages, whereas low responder T lymphocytes failed to respond to this antigen even in the presence of HLA-DR-compatible high responder macrophages. This observation strongly suggested that T lymphocytes, but not macrophages, controlled the low responsiveness to the schistosomal adult worm antigen. When high responder lymphocytes were challenged with the schistosomal antigen in the presence of low responder T lymphocytes, low responder T lymphocytes caused an antigen-specific suppression, in a dose-dependent manner, of the responsiveness of high responder lymphocytes. The suppressor T lymphocytes were mitomycin C resistant and were positive for Leu-2a, but were negative for Leu-3a. When Leu-2a+ T lymphocytes were depleted from low responder T lymphocytes, a vigorous response by the Leu-2a-depleted T lymphocytes (Leu-2a-3a+) to the schistosomal adult worm antigen was observed. By adding back the Leu-2a+ T lymphocytes into autologous T lymphocyte subpopulations, the specific response to the adult worm antigen was completely suppressed. These findings clearly demonstrate the existence of Leu-2a+3a- suppressor T lymphocytes that can control low responsiveness to the schistosomal adult worm antigen in man.     

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.     

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.     

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.     

Lectin-dependent and anti-CD3 induced cytotoxicity are preferentially mediated by peripheral blood cytotoxic T lymphocytes expressing Leu-7 antigen

Monoclonal antibodies against the CD3 antigen and certain lectins can induce interleukin 2 dependent antigen-specific T cell clones to mediate non-antigen specific cytotoxicity. On the basis of this observation, we predicted that it may be possible to identify cytotoxic T lymphocytes (CTL) in peripheral blood without knowing the antigen specificity of these in vivo primed CTL. By using this strategy, peripheral blood lymphocytes were separated into low and high-density fractions on Percoll gradients and were tested for cytotoxic activity in the presence or absence of concanavalin A (Con A) or anti-Leu-4 antibody. Lectin-dependent cellular cytotoxicity (LDCC) and anti-CD3 induced cytotoxicity against both natural killer (NK)-insensitive and NK-sensitive targets were exclusively mediated by low-density CD3+ T lymphocytes. Additional studies indicated that low-density CD3+ T lymphocytes co-expressing Leu-7 antigen preferentially mediated this activity, although in some individuals, significant activity was also observed in the low-density T cells lacking Leu-7. In contrast, high-density CD3+ T lymphocytes and CD16+ (Leu-11+) NK cells (both Leu-7 and Leu-7+) did not mediate nonantigen-specific cytotoxicity under these conditions. The finding that NK cell-mediated cytotoxicity was unaffected by these lectins refutes the hypothesis that lectin-dependent cellular cytotoxicity is simply a result of effector and target agglutination. T cell-mediated cytotoxicity was both lectin and antibody specific. Phytohemagglutinin, Con A, and pokeweed mitogen induced cytolytic activity in the Leu-7+ T cells, whereas wheat germ agglutinin did not. Of the antibodies against T cell-associated differentiation antigens (anti-Leu-2,3,4, and 5), only anti-Leu-4 induced cytotoxicity. This anti-CD3-induced cytotoxicity was essentially completely inhibited by the presence of anti-LFA-1 or anti-CD2 monoclonal antibodies, implicating these molecules in the triggering process. A proportion of the CD3+, Leu-7+ CTL expressed HLA-DR antigens, indicating possible in vivo activation. Because previous clinical studies have indicated that lymphocytes with this phenotype may be elevated in clinical situations associated with immunosuppression and chronic viral infection, this unique subset of CD3+ T lymphocytes may represent a population of in vivo primed CTL possibly against viral antigens.     

Human newborn autologous mixed lymphocyte response: frequency and phenotype of responders and xenoantigen specificity

The response of human newborn lymphocytes in autologous mixed lymphocyte culture was examined for specificity (by restimulation), responder cell phenotype, and responder cell frequency. When the newborn T cells were separated from non-T cells by rosetting with sheep erythrocytes (E) in fetal calf serum (FCS), approximately 1:20,000 T cells proliferated. These responders had specificity for E + FCS, were T4+, and were self-restricted. Significant numbers of responder T cells were not found when newborn T and non-T cells were separated by nylon wool. Responses in parallel autologous cultures of adult T cells showed that 1) adults had a higher frequency than newborns of E + FCS specific responders, 2) evidence for self specificity was lacking in restimulated cultures, and 3) occasional responses to antigen on the surface of monocytes could not be excluded.     

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.     

CD4 positive Leu-8 negative helper-inducer T cells predominate in the human intestinal lamina propria

The regulatory function of peripheral blood CD4 T cells correlates with the presence or absence of the membrane glycoprotein recognized by anti-Leu-8 antibody; CD4,Leu8- T cells help Ig synthesis and CD4,Leu-8+ T cells suppress Ig synthesis. In contrast to CD4 T cells from the peripheral blood and organized gut-associated lymphoid tissues, intestinal lamina propria CD4 T cells were found to have diminished expression of the Leu-8 Ag. Therefore, studies were performed to determine whether the decreased expression of the Leu-8 Ag on lamina propria CD4 T cells correlates with a difference in the ability of peripheral blood and lamina propria CD4 T cells to regulate PWM-stimulated Ig synthesis. At high T cell to non-T cell ratios, the helper function of lamina propria CD4 T cells was significantly higher than that of peripheral blood CD4 T cells. When CD4 T cells were incubated with anti-Leu-8 antibody, the suppressor function of peripheral blood CD4 T cells was increased, but lamina propria CD4 T cells did not suppress Ig synthesis. No difference was found between the helper function of CD4,Leu-8- T cells and the suppressor function of CD4, Leu-8+ T cells isolated from either the peripheral blood or the lamina propria. Thus, the difference in the regulatory function of CD4 T cells from the peripheral blood and the lamina propria is due to the quantitative difference in CD4,Leu-8+ T cells in these sites. Consequently, the intestinal lamina propria is a site enriched in CD4,Leu-8- T cells which predominantly mediate help for Ig synthesis.     

Immunoregulatory T cell circuits in man. Identification of a distinct T cell subpopulation of the helper/inducer lineage that amplifies the development of alloantigen-specific suppressor T cells

Regulation of the immune response in man is dependent on interactions between cells of helper/inducer (Leu-3+/T4+) lineage and cells of suppressor/cytotoxic (Leu-2+/T8+) lineage. By using the mixed leukocyte reaction (MLR) as a model system, we have shown previously that alloantigen-primed Leu-3+ cells induce autologous Leu-2+ cells to differentiate into suppressor T cells that specifically inhibit the response of fresh T cells to the original allogeneic stimulator cells. The current study was undertaken to analyze the roles in this suppressor circuit of subpopulations of Leu-3+ cells distinguished from one another on the basis of their binding or lack of binding to monoclonal anti-Leu-8 antibody. Although both Leu-3+,8- and Leu-3+,8+ T cells proliferated in allogeneic MLR, alloactivated Leu-3+,8+ cells alone induced proliferation and differentiation of Leu-2+ suppressor cells. Leu-3+,8+ cells also induced Leu-3+,8- cells to proliferate, and following their activation in this manner, such autoactivated Leu-3+,8- cells augmented the differentiation of Leu-2+ suppressor cells, but only in the presence of alloactivated Leu-3+,8+ cells. Furthermore, this effect, like the suppressor effect, was specific for the inducer cells, and thus indirectly for the HLA-DR antigens of the original allogeneic stimulator cells as well. These results indicate that alloantigen-primed Leu-3+,8+ cells not only activate specific Leu-2+ suppressor cells but also activate specific Leu-3+,8- suppressor-amplifier cells, and in combination, these cells exert potent feedback inhibition of MLR.     

Enhancement of release of granulocyte- and granulocyte-macrophage colony-stimulating factors from phytohemagglutinin-stimulated sorted subsets of human T lymphocytes by recombinant human tumor necrosis factor-alpha. Synergism with recombinant human IFN-gamma

The influence of purified recombinant human TNF-alpha (rhuTNF-alpha) was assessed, alone and in combination with purified recombinant human IFN-gamma (rhuIFN-gamma), for its effects on enhancing release from human T lymphocytes of activities that stimulate colony formation by granulocyte-macrophage, erythroid, and multipotential progenitor cells. rhuTNF-alpha or rhuIFN-gamma enhanced the release of CSF, which were determined to be granulocyte-CSF and granulocyte-macrophage-CSF by human bone marrow colony assays, morphologic assessment of colony types, and neutralization studies with rabbit anti-human granulocyte-CSF and monoclonal mouse anti-human granulocyte-macrophage-CSF. The CSF were released only when PHA was used, whether or not rhuTNF-alpha and/or rhuIFN-gamma were present while the lymphocytes conditioned the medium. T lymphocytes were sorted into subsets by using three-color immunofluorescence and a dye laser flow cytometry system with cells incubated with biotin anti-Leu-4 labeled with Texas Red, FITC-conjugated anti-Leu-3a, and phycoerythrin-conjugated anti-Leu-2a. Both the Leu-4+3a+2a- and the Leu-4+2a+3a- cells released CSF in response to PHA, but the release of CSF from PHA-stimulated lymphocytes was enhanced by rhuTNF-alpha and rhuIFN-gamma only from the Leu-4+3a+2a- subset of cells. Use of the three-color cell sorting made it highly unlikely that NK cells were involved, because both sorted subsets were positive for Leu-4. rhuTNF-alpha and rhuIFN-gamma synergized to enhance release of CSF such that low concentrations of each molecule, which were inactive when used alone, were active when the two molecules were used together. These studies suggest a role, at least in vitro, for TNF-alpha and IFN-gamma in the release of CSF from subsets of T lymphocytes stimulated with PHA.     

The monoclonal antibody 41H16 detects the Leu 4 responder form of human Fc gamma RII.

Human FcR for IgG can be divided into three classes (Fc gamma RI, II, and III) based on their structure and reactivity with mAb. Fc gamma RII can be further subdivided into two categories based on functional and biochemical assays. These two Fc gamma RII subtypes were initially recognized by the failure of T cells from 40% of individuals to proliferate in response to mAb Leu 4 (mouse IgG1, anti-CD3), a response that requires the binding of the Fc region of the Leu 4 mAb to Fc gamma RII on monocyte accessory cells. Inas-much as mouse IgG1, does not bind efficiently to the nonresponder form of Fc gamma RII, mAb Leu 4 is unable to induce proliferation in these individuals. IEF data on Fc gamma RII from Leu 4 responder and nonresponder individuals suggested that the structural gene for Fc gamma RII consisted of two allelic forms R (responder) and N (nonresponder) producing the phenotypes RR, RN, and NN. Thus, exclusive expression of the nonresponder allele in monocytes of "nonresponder" individuals, appeared to be responsible for the lack of proliferation observed. In cooperation with the IVth International Conference on Human Leukocyte Differentiation Antigens, we analyzed CDw32 mAb to determine if they could distinguish the responder and nonresponder forms of Fc gamma RII. We report that mAb 41H16 binds preferentially to the responder allotypic form of Fc gamma RII expressed on human monocytes. When quantitative flow cytometry is used to measure the binding of both mAb 41H16 (responder Fc gamma RII) and mAb IV.3 (all myeloid cell Fc gamma RII), we are able to subdivide the responder population into homozygous and heterozygous responders. In addition, mAb 41H16 blocks the binding of mAb IV.3 to monocytes and inhibits proliferation when added to cells before addition of mAb Leu 4. We also show that polymorphonuclear leukocytes and platelets have the same allotypic differences in the binding of 41H16 as do monocytes. However, a subset of lymphocytes (previously shown to be B cells) expresses the 41H16 epitope with no evidence for donor to donor variability.     

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.     

Normal HBsAg presentation and T-cell defect in the immune response of nonresponders

Lymphocytes from nonresponders to HBsAg fail to proliferate in vitro in the presence of HBsAg-pulsed antigen presenting cells. We studied four pairs of major histocompatibility complex (MHC)-matched, mixed lymphocyte reaction-negative individuals discordant for HBsAg response. For each pair, responder lymphocytes proliferated in the presence of nonresponder antigen-pulsed antigen presenting cells. Respondera nd nonresponder antigen presenting cells were equally effective. There was no evidence for inhibition of responder T-cell proliferation by nonresponder lymphocytes or antigen presenting cells. The defect is thus in the helper T cells of nonresponders and not in the antigen processing or binding of processed peptides to MHC molecules on antigen presenting cells.     

Immunohistologic and immunoelectron microscopic characterization of the mucosal lymphocytes of human small intestine by the use of monoclonal antibodies

Monoclonal antibodies reactive with T cells, T cell subsets, B cells, monocytes, and natural killer cells were used to characterize the nature of mucosal lymphocytes in the human small intestine by application of the immunoperoxidase technique to tissue sections for light and electron microscopic examination. In addition, for comparison, peripheral blood mononuclear cells (PBL) were studied by immunoelectron microscopy. Most of the intraepithelial lymphocytes (IEL) were T cells (Leu-1+, T3+) and expressed the phenotype associated with cytotoxic/suppressor T cells (Leu-2a+, T8+). In contrast, a majority of T lymphocytes in the lamina propria expressed the phenotype associated with helper/inducer T cells (Leu-3a+, T4+). These observations confirm and extend the findings previously reported. In addition, a small number of cells in the lamina propria with the ultrastructural features of macrophages were found to react with anti-Leu-3a and anti-T4 antibodies. Although many IEL contained cytoplasmic granules and had ultrastructural features similar to those of circulating granular lymphocytes, none of these cells reacted with anti-Leu-7 (HNK-1), anti-T10, or anti-M1 antibodies. This suggests that IEL may not be related to circulating large granular lymphocytes, which are Leu-7+, T10+, M1+ and are associated with natural killer activity. Not only Leu-7+ PBL, but T8+, T4+, or T3+ mucosal lymphocytes or PBL also may contain cytoplasmic granules. Therefore, the cytoplasmic granules are not restricted to one cell type, in particular, to Leu-7+ cells.     

HLA-DQ-restricted CD4+ T cells specific to streptococcal antigen present in low but not in high responders.

We have found that the low immune response to streptococcal cell wall Ag (SCW) was inherited as a dominant trait and was linked to HLA, as deduced from family analysis. In the present report, HLA class II alleles of healthy donors were determined by serology and DNA typing to identify the HLA alleles controlling low or high immune responses to SCW. HLA-DR2-DQA1*0102-DQB1*0602(DQw6)-Dw2 haplotype or HLA-DR2-DQA1*0103-DQB1*0601(DQw6)-DW12 haplotype was increased in frequency in the low responders and the frequency of HLA-DR4-DRw53-DQA1*0301-DQB1*0401(DQw4)-Dw15 haplotype or HLA-DR9-DRw53-DQA1*0301-DQB1*0303(DQw3)-Dw23 haplotype was increased in the high responders to SCW. Homozygotes of either DQA1*0102 or DQA1*0103 exhibited a low responsiveness to SCW and those of DQA1*0301 were high responders. The heterozygotes of DQA1*0102 or 0103 and DQA1*0301 showed a low response to SCW, thereby confirming that the HLA-linked gene controls the low response to SCW, as a dominant trait. Using mouse L cell transfectants expressing a single class II molecule as the APC, we found that DQw6(DQA1*0103 DQB1*0601) from the low responder haplotype (DR2-DQA1*0103-DQB1*0601(DQw6)-Dw12) activated SCW-specific T cell lines whereas DQw4(DQA1*0301 DQB1*0401) from the high responder haplotype (DR4-DRw53-DQA1*0301-DQB1*0401(DQw4)-Dw15) did not activate T cell lines specific to SCW. However, DR4 and DR2 presented SCW to CD4+ T cells in both the high and low responders to SCW, hence the DR molecule even from the low responder haplotype functions as an restriction molecule in the low responders. Putative mechanisms linked to the association between the existence of DQ-restricted CD4+ T cells specific to SCW, and low responsiveness to SCW are discussed.     

Characterization of a T-cell determinant defined by a monoclonal antibody (TH5.2) which is involved in the interleukin-2-producing and proliferative capabilities of T cells

Utilizing an OKT-4-positive human T-cell lymphoma cell line as immunogen, we have produced a monoclonal antibody (MAb), designated TH5.2, which is capable of augmenting the interleukin-2 (IL-2) production and proliferation of antigen-activated T cells. TH5.2 MAb by itself is not mitogenic for T cells; the enhanced IL-2 production and proliferation requires costimulation with either antigen or mitogen. TH.2 MAb recognizes all peripheral blood T cells at varying intensities, but does not react with monocytes. Using dual-color fluorescence analysis, it was determined that TH5.2 MAb reacts at a higher intensity on Leu-3a-positive T cells compared to Leu-2a-positive cells. Sorting T cells on the basis of fluorescent intensity with TH5.2 MAb demonstrated that the T cells reacting at high TH5.2 intensity were able to respond to mitogen at a higher rate (5-10X), as well as produce higher concentrations of IL-2 in response to mitogen as compared to the low IL-2 intensity cells. Cytotoxically treating peripheral blood mononuclear cells (PBMC) with TH5.2 MAb plus complement, which resulted in an approximate 8% decrease in the total population, significantly reduced the ability of the cells to proliferate to both mitogen and antigen. Addition of recombinant IL-2 to the cultures was able to restore the proliferative capability of the cells. In further analyzing the ability of TH5.2 MAb to augment the proliferative capability of PBMC to antigen and mitogen stimulation in vitro, it was determined that TH5.2 MAb was capable of acting synergistically with antigen or mitogen in increasing the Il-2-producing capability of T cells. Taken together the data suggest that the TH5.2 determinants is involved in the proliferative capability of T cells and is functioning at the level of IL-2 synthesis and/or secretion.     

Characterization of antigen-specific T cells in multiple sclerosis twins with elevated proliferative responses to measles virus

The proliferative response to measles virus in normal individuals is low compared with the response to mumps virus. This is probably due to a low precursor frequency of OKT4+, IL 2-secreting helper cells. The presence of a measles high-responder state has previously been identified in some twin individuals with multiple sclerosis. Further characterization of the measles response in these high-responder individuals has demonstrated that the enhanced measles responses are due to a greater response by OKT4+ cells, which secrete higher levels of IL 2; this contrasting with the low levels of IL 2 secretion and OKT4+ cell proliferation seen in the unaffected twins. No evidence for suppression by either accessory or T cells, which would account for the quantitative differences between the high responders with multiple sclerosis and their unaffected low-responder twin siblings, was detected. The results indicate that a clonally expanded population of measles-specific responder cells is responsible for the high-responder state in these twins with multiple sclerosis. The mechanism producing this state may have relevance to possible immunoregulatory abnormalities producing autoimmunity in multiple sclerosis.     

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.