Heterogeneity of human T4+ inducer T cells defined by a monoclonal antibody that delineates two functional subpopulations

A monoclonal antibody termed anti-T4 that detected approximately 60% of peripheral blood T lymphocytes was shown to define the human inducer population. In the present study, we characterized three additional monoclonal antibodies, anti-T4A, anti-T4B, and anti-TQ1, that were reactive with a similar percentage of T lymphocytes. Anti-T4A, anti-T4B, and anti-T4 delineated identical cell populations, while those defined by anti-TQ1 differed in several respects: 1) Anti-TQ1 stained a minority (less than 7%) of thymocytes, whereas the other antibodies stained a majority (80%); 2) Anti-TQ1 reacted with 70 to 85% of T4+ lymphocytes, but also stained 50% of T cells within the T4- (T8+) cytotoxic/suppressor subset; 3) The antigen defined by anti-TQ1 was not restricted in its expression to T cells; it defined a fraction of normal B and null lymphocytes as well as non-T cell lines. In vitro studies indicated that the subpopulations of T4+ T lymphocytes delineated by anti-TQ1 were functionally distinct. Although T4+TQ1+ and T4+TQ1- T cells proliferated in an equal fashion to soluble antigen and alloantigen, only the T4+TQ1+ subset was responsible for maximal proliferation in autologous MLR. This T4+TQ1+ subset contained a population of lymphocytes reactive with the previously defined JRA autoantibody. In contrast, the T4+TQ1-, but not the T4+TQ1+, subset provided the majority of T cell help for B cell immunoglobulin production in a pokeweed-driven system. We conclude that the subpopulation of T4+ inducer cells responsible for maximal helper activity in T-B interactions is restricted to a minor subpopulation of T4+ lymphocytes.     

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.     

Phenotypic and functional distinctions between the TH2+ and JRA+ T cell subsets in man.

Prior work has demonstrated the existence of distinct human peripheral blood T cell subsets by utilizing heterologous as well as autoimmune antisera. In the present study, the relationship between the TH2+ and JRA+ T cell subsets was examined. T cells were purified with Sephadex G-200 anti-F(ab)2' affinity chromatography and E-rosetting technique, and subsequently fractionated into TH2+ and TH2- subsets by utilizing indirect immunofluorescence on FACS. Approximately 40 to 45% of the TH2- subset was shown to be JRA+, whereas less than 5% of the TH2+ subset was JRA+. In reciprocal studies, T cells were fractionated into JRA+ and JRA- subsets and reacted with heterologous antisera with anti-TH2+ specificity and indirect immunofluorescence. FACS analysis demonstrated that the JRA+ population contained no TH2+ T cells. In contrast, the JRA- population contained TH2+ T cells and accounted for the entire TH2+ subset found in the unfractionated T cell population. Functional studies showed that the TH2+ subset, and not the JRA+ subset, contain the effector population for cell-mediated lympholysis. It is concluded that the TH2+ and JRA+ T cell subsets define distinct and different T cell populations in man.     

The isolation and characterization of the human suppressor inducer T cell subset

Immunization of mice with lower primate lymphoid cells has provided a useful strategy for raising monoclonal antibodies against functionally important surface determinants on human T lymphocytes. We have developed a monoclonal antibody, anti-2H4, which defines functionally unique human T cell subsets. This anti-2H4 antibody was reactive with approximately 42% of unfractionated T cells, 41% of T4+ inducer cells, and was reactive with approximately 54% of T8+ cytotoxic/suppressor population. Anti-2H4 was not reactive with human thymocytes, but reacted with subsets of peripheral blood B cells and null cells. This antibody subdivided peripheral blood T4+ cells into two functionally distinct populations. The T4+2H4+ subset proliferate well to concanavalin A (Con A) stimulation, but poorly to soluble antigen stimulation, and provides poor help to B cells for PWM-induced Ig synthesis. The T4+2H4- subset, in contrast, proliferates poorly upon stimulation with Con A, but well on exposure to soluble antigen, and provides a good helper signal for PWM-induced Ig synthesis. What is, perhaps, most important, the T4+2H4+ subset functions as the inducer of the T8+ suppressor cells. Previous attempts to define the latter subset of cells has relied heavily on the use of specific autoantibodies present in the sera of patients with juvenile rheumatoid arthritis (JRA) and systemic lupus erythematosus (SLE). The present results suggest that anti-2H4 antibody defines the human suppressor induced subset of lymphocyte previously described as T4+JRA+. Last, the results reemphasize the previously documented remarkable structural conservation of certain T cell-specific determinants on lymphocytes of phylogenetically distant primates.     

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.     

The isolation and characterization of the human helper inducer T cell subset

Monoclonal antibody anti-4B4 was produced by fusing NS1 myeloma with spleen cells of a mouse immunized with Saguinus oedipus lymphocyte. This anti-4B4 antibody defines a 135-KD cell surface protein that is widely distributed throughout the hematopoietic system. More importantly, anti-4B4 is reactive with functionally unique human T cell subsets. Anti-4B4 antibody was reactive with approximately 41% of unfractionated T cells, 41% of T4+ inducer cells, and approximately 43% of T8+ cytotoxic/suppressor population. This antibody subdivided peripheral blood T4+ cells into two functionally distinct populations. The T4+4B4+ subset proliferates relatively poorly upon stimulation with Con A and autologous cell antigens (AMLR) but well on exposure to soluble antigens, and it provides a good helper signal for PWM-induced Ig synthesis. The T4+4B4- subset, in contrast, proliferates well to Con A stimulation and autologous cell antigen (AMLR) but relatively poorly to soluble antigen stimulation, and provides little help to B cells for PWM-induced Ig synthesis. The T4+4B4- subset is largely 2H4+ and functions as the inducer of the T8+ suppressor cells. Thus, the present results suggest that one can divide the human T4 population into two major subsets that are phenotypically and functionally distinct, the human helper inducer subset (T4+4B4+/H.I.) and its reciprocal population defined by anti-2H4, the suppressor inducer subset (T4+2H4+/S.I.).     

A defect in the suppressor circuits among OKT4+ cell populations in patients with systemic lupus erythematosus occurs independently of a defect in the OKT8+ suppressor T cell function

The autologous mixed lymphocyte reaction (MLR) is thought to be part of a regulatory role of T cells on B cell function. OKT4+, but not OKT8+, cells can proliferate in response to autologous non-T cells. Moreover, the OKT4+ cell population activated early in the course of autologous MLR functioned as inducer cells for the differentiation of B cells, whereas later in the response, the activated OKT4+ cells were particularly enriched in suppressor cells. A part of the autologous MLR appears to be an important pathway for the activation of feedback suppression mechanisms among cells contained within the OKT4+ populations. Patients with systemic lupus erythematosus (SLE) were studied with regard to the following OKT4+ cell functions in vitro after activation in the autologous MLR: a) proliferative response, and b) helper and suppressor activities for differentiation of B cells. A marked reduction in the proliferative response of OKT4+ cells was observed in SLE patients. SLE OKT4+ cells activated in the autologous MLR could function as helper cells but could not exert any suppressor activity. This OKT4+ cell abnormality was present regardless of the disease activity, and occurred in the absence of autoantibodies including anti-T cell antibodies. Instead, SLE anti-T cell antibodies could preferentially eliminate cells bearing the OKT8+ phenotype characteristic of suppressor cells in populations of normal T cells. These results suggest that the defect in the suppressor circuits among OKT4+ cell populations is intrinsic to SLE lymphocytes and that the OKT8+ suppressor T cell defect is caused by antibodies produced by the B cells of SLE patients.     

The functional heterogeneity of CD8+ cells defined by anti-CD45RA (2H4) and anti-CD29 (4B4) antibodies.

The monoclonal antibodies, anti-2H4(CD45RA), and anti-4B4(CD29), along with UCHL1-(CD45RO), identify reciprocal populations of CD4 cells with distinct suppressor inducer (CD45RA+CD29-CD45RO-) and helper inducer (CD45RA-CD29+CD45RO+) functions. Although the CD8+ population is known to contain precytotoxic, cytotoxic, suppressor, and some natural killer cells, the exact phenotypic identities of these functional CD8 subsets has not been established. In this study, we tried to determine whether these monoclonal antibodies could distinguish functionally distinct subsets of cells within the CD8+ population. For this purpose, whole T cells or fractionated T cells were sensitized with irradiated allogeneic non-T cells for 6 days, following which, CD8+ or CD8+CD11b- cells were isolated and cellular functions such as suppressor, killer precursor, and killer effector activity were assessed. The results showed that both class I-restricted alloantigen-specific killer effector and killer precursor cells belonged to the CD8+CD11b-CD45RA-CD29+ population. Moreover, these killer effector cells expressed the CTL-associated S6F1 molecule, an epitope of the LFA-1 antigen. In contrast, suppressor effector cells belonged to the CD8+CD11b-CD45RA+CD29- cell population. Although the UCHL1 antigen has been reported to define the CD4+CD29+ helper inducer cell, over 90% of allo-activated CD8+ cells expressed this antigen, whereas only 40-60% of these cells expressed either CD45RA or CD29 antigens. These results suggest that anti-CD45RA and anti-CD29 antibodies may provide useful tools for distinguishing between suppressor effector versus killer effector and killer precursor cells within the CD8+CD11b- population.     

The murine IL 2 receptor. III. Cellular requirements for the induction of IL 2 receptor expression on T cell subpopulations

The accessory cell requirements for the induction of the IL 2 receptor by the lectin Con A on murine T cell subsets were directly assayed with anti-IL 2 receptor monoclonal antibodies. Substantial levels of IL 2 receptor expression were induced on T lymphocytes of the MHC class I-restricted, suppressor/cytotoxic phenotype (L3T4-, Ly-2+) in the presence and absence of accessory cells. In contrast, high levels of IL 2 receptor expression could only be induced on T cells of the MHC class II-restricted, helper/inducer phenotype (L3T4+, LY-2-) in the presence, but not in the absence, of accessory cells. Ia- cells such as the P388D1 macrophage line or cultured fibroblasts (DAP X 3) were as efficient as the Ia+ B cell hybridoma LB in providing accessory cell function for the L3T4+, Ly-2- subset. PMA, but not purified human IL 1, could substitute for accessory cells for both IL 2 receptor expression and IL 2 secretion by the L3T4+, Ly-2- subset. These data suggest that IL 2 receptor induction on the L3T4+, Ly-2- subset is complex, possibly requiring a T cell-accessory cell interaction, whereas the lectin may directly trigger IL 2 receptor expression on L3T4-, Ly-2+ T 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.     

Differential effects of leukotriene B4 on T4+ and T8+ lymphocyte phenotype and immunoregulatory functions

Leukotriene B4 (LTB4) can regulate several lymphocyte functions, including the augmentation of cytotoxic activity and the induction of suppressor cells. When T lymphocytes were preincubated with picomolar concentrations of LTB4, they would suppress the proliferative response of unfractionated peripheral blood mononuclear leukocytes to concanavalin A in a subsequent co-culture system. Such a suppression did not occur when the responding population was depleted of monocytes. Furthermore, the effect was reversed to an enhancement when the responding unfractionated population was treated with indomethacin, suggesting a role for monocytes and cyclooxygenase products in the effector phase of LTB4-induced suppressor activity. When sorted into T4+ and T8+ cells before preincubation with LTB4, both T cell subsets could be induced by LTB4 to exert suppression. T4+ cells, however, required the presence of monocytes in the responder population in order to manifest suppressor activity, whereas T8+ cells were active even in the absence of monocytes. When LTB4-preincubated T cells or T4+ cells were sorted into T4+ and T8+ subsets after preincubation, suppressor cell activity was found only in the T8+ subset. Furthermore, T8+ cell-depleted T lymphocyte cultures, incubated for 24 hr with LTB4, showed a significant increase in the proportion of T8+ cells. Together, these data suggest that LTB4 induces suppressor T cells which can derive from either T4+ or T8+ subpopulations but which are phenotypically T8+ when exerting their suppressive activity. Thus, by interacting with both T4+ and T8+ lymphocytes, LTB4 can modulate immune responses with the cooperation of functionally competent accessory monocytes.     

Identification of the T cell subset that produces human gamma interferon

Positive and negative selection procedures combined with cytofluorographic analysis and lysis with monoclonal antibodies were utilized to identify the T lymphocyte subset that produces human gamma interferon (gamma-IFN) (formerly referred to as "immune" or "type II" interferon) in response to mitogen stimulation. Lymphocytes were separated on the basis of their Fc receptors for IgG or IgM, their nonreactivity with IgM or IgG antibodies, and their reactivity with the monoclonal antibodies OKT4, OKT8, OKT11a, and OKM1. Isolated T cell subsets were incubated with the gamma-IFN inducer, phytohemagglutinin. Three days after induction, the cell supernatants were harvested and assayed for interferon. The T cell subset that produces gamma-IFN was identified as E rosette positive with the phenotype: T gamma, T non-micro, OKM1+, OKT4-, OKT8- and OKT11a+. gamma-IFN production by cells was resistant to doses of x-irradiation that abrogate mitogen-induced T suppressor function but was highly sensitive to low doses of 4-hydroperoxycyclophosphamide. These data demonstrate that gamma-IFN is produced by the T gamma, OKM1+ lymphocyte subset, but these cells may also require the presence of accessory monocytes for elaboration of gamma-IFN. The anti-proliferative activity of gamma-IFN may be responsible for the previously described suppressor function of this subset, and gamma-IFN production by T gamma cells may distinguish this subset from the suppressor/cytotoxic functions of the OKT8+ subset or the mitogen-induced OKT4+ suppressor.     

The 2H4 molecule but not the T3-receptor complex is involved in suppressor inducer signals in the AMLR system

It is suggested that autologous mixed lymphocyte reaction (AMLR) may play an important role in generating suppressor inducer signals and in down-regulating the immune response following self-major histocompatibility recognition. In the present study, monoclonal antibodies directed at cell surface structures on T4+ cells activated in AMLR were used to define the molecules important in the generation of the suppressor inducer signal. The density of a 200/220-kDa structure, termed 2H4, increased on T4 cells during activation in AMLR and furthermore a strong correlation was observed between the generated suppressor inducer activity of such cells and the density of the 2H4 antigen. More importantly, we showed that treatment of AMLR activated T4 cells with anti-2H4 but not anti-T3 or T4 antibody abolished the suppressor inducer function of these cells. These results suggest that the 2H4 molecule but not the T3-receptor complex plays an important role in generating suppressor inducer signals in the AMLR system.     

CD11 molecule defines two types of suppressor cells within the T8+ population

It has been shown that T8+ cells are comprised of functionally heterogeneous subpopulations such as suppressor, cytotoxic, and NK cells. In this report, we attempted to delineate the functional heterogeneity of T8 cells defined by anti-CD11 antibody (anti-Mol). Although allospecific cytotoxic activity was restricted to the T8+Mol- subset, suppression of PWM IgG synthesis could be elicited in both the T8+Mol+ and the T8+Mol- subset of cells. However, the mechanism of suppression was different in these two subsets. Suppression by the T8+Mol- subset of cells required the interaction with the T4+2H4+ suppressor inducer cells, whereas the T8+Mol+ subset of cells could suppress in the absence of the suppressor inducer cells. Moreover, recombinant interleukin-2 alone could augment this suppression by the T8+Mol+ subset, but did not induce suppression by the T8+Mol- subset. In contrast, NK and LAK activity was exclusively found in the T8+Mol+ subset of cells but not in the T8+Mol- subset of cells. These results suggest that the CD11 molecule is useful for distinguishing novel subsets of T8 cells.     

Two-dimensional flow cytometric analysis of T cell subsets maintained in IL-2 medium after autologous mixed leukocyte reaction activation

Human T cells are stimulated with an autologous mixed leukocyte reaction (AMLR) and can be propagated in interleukin-2. Staining of the cultured cells with the combination of two monoclonal antibodies was evaluated by two-dimensional flow cytometry at weekly intervals. AMLR activation resulted in an initial preservation of the CD4+ (helper/inducer T) subset predominance over the CD8+ (suppressor/cytotoxic T) cells, noted on normal circulating blood lymphocytes. However, during culture in interleukin-2, there was a progressive increase in the percentages of CD8+ Leu 15- cytotoxic T, CD4+ Leu 8- helper T, and CD3+ HLA-DR+ activated T cells, and a concomitant decrease in those of CD4+ Leu 8+ suppressor inducer T and CD8+ Leu 15+ suppressor T cells if the responder sheep red blood cell (SRBC)-rosetting T cells were made up by tris ammonium chloride, but not by hypotonic shock treatment to lyse SRBC. The significant difference between hypotonic shock-T cells and ammonium chloride-T cells in the phenotypic changes of T cell subsets after long-term culture in an interleukin-2 medium may suggest a regulatory role of the ammonium chloride-sensitive T cells in the AMLR.     

Impaired immunoregulation in systemic lupus erythematosus: defective adenosine-induced suppressor T lymphocyte generation

It is currently unclear whether the suppressor cell dysfunction observed during active systemic lupus erythematosus (SLE) reflects a primary T cell disorder or one that results from immunologic modulation of suppressor T cell activity by autoantibodies. To determine whether the suppressor T cell dysfunction of active SLE is the result of a primary T cell disorder, the model of adenosine-induced immunosuppression was utilized to study the suppressor T cell functions of 12 patients with SLE (seven active SLE, five inactive SLE) and 12 matched healthy controls. T lymphocyte phenotyping was performed by utilizing monoclonal antibodies directed against T cell-specific determinants. Suppressor T cell functions were assessed by two assays in parallel. The first technique tested the capacity of two suppressor T cell subsets (spontaneous suppressors, Ts; adenosine-inducible suppressors, TRA) to inhibit pokeweed mitogen- (PWM) induced B cell differentiation. In the second technique, the ability of enriched T cell preparations to suppress mitogen- and alloantigen-induced proliferation was assayed. It was demonstrated that brief treatment of the control theophylline-resistant T lymphocyte (TR) subset possessing inducer/helper activity with adenosine (10(-5) M, 30 min, 37 degrees C) triggered a rapid shift in phenotype (RFC gamma -, T-4+ leads to RFC gamma +, T-8+) in a proportion of the subset, and the development of radioresistant suppressor function. By contrast, exposure of active SLE TR to adenosine failed to induce either the switch of phenotype or suppressor activity. When compared to controls, both the TS and TRA suppressors failed to inhibit B cell differentiation (TS, p less than 0.001; TRA, p less than 0.001). Moreover, enriched T cell preparations incompletely suppressed the proliferative responses to phytohemagglutinin (p less than 0.003), PWM (p less than 0.0003), or alloantigens (p less than 0.01). During inactive SLE, the T cell responses were usually restored. Treatment of the TR subsets with adenosine induced a switch of phenotype in four of five patients and the subsequent expression of effective suppressor function. We conclude that a) during active SLE, there is impaired suppression of proliferation and B cell differentiation; b) the impaired suppression of B cell differentiation results from abnormal spontaneous (TS) and adenosine-inducible (TRA) suppressor functions; c) the defective generation of suppressor T cell function during active disease results, in part, from a block in the transition from inducer/helper to suppressor cell; and, d) the suppressor T cell dysfunction is reversible with disease remission. The investigation of immunopharmacologic events by using the adenosine-induced immuno-suppression model in T cells from normal donors and SLE patients may provide insights into the molecular basis of disordered immunoregulation in SLE.     

The role of the 2H4 molecule in the generation of suppressor function in Con A-activated T cells

The molecular basis for the suppression generated in a concanavalin A (Con A)-activated T cell culture remains unknown. In this study, we have attempted to determine whether the 2H4 and 4B4 molecules on Con A-activated T cells play some role in the generation of suppression by such cells. We have shown that Con A-activated suppressor cells belong to the 2H4+ subset of T cells but not the 4B4+ (2H4-) subset. Con A-activated T cells exerted their optimal suppressor function on day 2 in culture, a time at which the expression of 2H4 on such cells was maximal and 4B4 was minimal. Furthermore, the stimulation of T cells with the higher concentration of Con A generated the stronger suppressor function. At the same time, both 2H4 expression and density were increased and 4B4 expression and density were decreased on such Con A-activated T cells. More importantly, the treatment of Con A-activated T cells with anti-2H4 antibody but not with anti-4B4, anti-TQ1, or anti-T4 antibodies can block the suppressor function of such cells. Taken together, the above results strongly suggest that the 2H4 molecule itself may be involved in the generation of suppressor function in Con A-activated T cells. The 2H4 antigen on such cells was shown to be comprised of 220,000 and 200,000 m.w. glycoproteins. Thus this study indicates that the 220,000 and 200,000 m.w. structure of the 2H4 molecule may itself play a crucial role in the generation of suppressor signals of Con A-activated cells.     

Interaction of reovirus with cell surface receptors. IV. The reovirus type 3 receptor is expressed predominantly on murine Lyt-2,3+ and human T8+ cells

Reovirus type 3 binds to approximately 20% of murine and human T cells via the viral hemagglutinin, a small outer capsid polypeptide. By using purified viral particles as a ligand in a standard plate separation technique, we have been able to enrich human peripheral blood and murine splenic T cells for reovirus receptor-positive cells (reovirus 3+) to levels of 88 to 92%. Analysis of reovirus 3+ T cells with monoclonal antibodies that identify inducer and suppressor/cytotoxic cells demonstrated that in the mouse, 68% of reovirus 3+ cells were Lyt-2+, and in the human, 60% were T8+. In reciprocal experiments, when subpopulations of murine and human T cells were prepared with the use of monoclonal anti-T cell reagents, 16% of Lyt-1+ and 81% of Lyt-2+ cells bound reovirus, whereas 30% of T4+ and 65% of T8+ cells bound reovirus. To determine whether reovirus type 3 identified a functional as well as a phenotypic category of cells, an antigen-specific cytotoxic T cell assay was employed. There was complete loss of cytotoxic activity in the reovirus 3+ cell population and slight enhancement of cytotoxic activity in the cell population from which reovirus 3+ cells were removed. This suggested that reovirus was binding to functionally active suppressor cells. Furthermore, adoptive transfer of antigen-specific T cells that were enriched for reovirus 3+ cells demonstrated suppression of cytoxic T cell activity. These results suggest that reovirus type 3 may identify a structure common to a subclass of murine and human T cells and that by using the virus as a natural biologic probe for cell surface receptors, one may be able to functionally segregate murine cytotoxic from suppressor T cells.     

Binding of human lymphocyte-specific monoclonal antibodies to common marmoset lymphoid cells

Commercially available monoclonal antibodies which bind to human lymphocyte subsets were screened for their ability to bind to lymphoid cells from the common marmoset Callithrix jacchus. Anti-Leu-5 and T11 were the only pan T-cell antibodies which reacted strongly. None of the antibodies which bind human lymphocytes of the helper/inducer subpopulation reacted with C. jacchus cells and only one antibody, T8, specific for the cytotoxic/suppressor subset, bound to the marmoset cells. The two antibodies tested which bind human B cells, B1 and anti-HLA-DR, were also reactive with marmoset cells. The cellular specificity of the T11, T8, and B1 antibodies was determined by dual binding studies on the fluorescence-activated cell sorter. The B1 antibody bound only Ig+ cells and all Ig+ cells were B1+. The T11 and T8 antibodies bound only to Ig- marmoset lymphoid cells and, as in the human, all T8+ marmoset cells were also T11+. Thus, using these monoclonal antibodies in the common marmoset one can identify three populations of lymphoid cells: (1) T11+, T8+ cells; (2) T11+, T8- cells; (3) B1+ cells.     

Characterization of anti-idiotypic suppressor T cells (Tsid) induced after antigen priming

The induction and fine specificity of idiotype-specific suppressor T cells (Tsid) were studied. Spleen cells from C57BL/6 mice, immunized 4 wk previously with NP-KLH, failed to express NPb3 idiotype-bearing PFC when challenged in vitro with NP-Ficoll or NP-Brucella abortus. After treatment of NP-primed responder cultures with anti-Thy-1.2 anti-serum + C, NPb idiotype-bearing B cells could be detected. This B cell subset was preferentially suppressed by the addition of T cells from NP-primed mice. With this reconstitution protocol, it was determined that suppression of the NPb idiotype-bearing portion of the B cell response was mediated by a specifically induced T cell population (Tsid) that directly suppressed NPb-bearing B cells. As with a previously described suppressor population induced with hapten-modified syngeneic spleen cells (Ts2), the Tsid population bound and was lysed by NPb idiotype-bearing serum antibodies. However, the Tsid could be distinguished from the Ts2 population because it lacked I-J determinants and functioned as an effector T cell, not an intermediary suppressor cell. Furthermore, fine specificity studies with monoclonal NP-specific antibodies expressing various levels of serologically detectable NPb idiotypic determinants indicated that unlike the Ts2, the Tsid population reacts with conventional, serologically detected members of the NPb family. The combined idiotype binding studies for the Tsid and Ts2 populations demonstrate that the fine specificity of suppressor T cell populations reflects their independent mechanisms of regulation.