Synergy among rat T cells in the proliferative response to alloantigen.

A synergistic interaction in the proliferative response to alloantigen is described for mixtures of rat thymus and lymph node cells. The optimal conditions for synergy are quantitatively defined. Regression analysis of the slope of the dose-response curve has been utilized to estimate the degree of interaction in thymus-lymph node cell mixtures. The slope of the response of cell mixtures was noted to be significantly greater than the slope for the response of lymph node cells alone. Irradiation was shown to have a differential effect on the response of thymus and lymph node cells in mixtures. Irradiated thymus cells retained the capacity for synergy in mixtures, whereas irradiated lymph node cells did not. Additional studies have demonstrated that both de novo protein synthesis and specific antigen recognition by both responding cell populations in mixtures was required for maximal synergy. These studies demonstrate that synergy cannot be explained as an artifact of altered cell density in vitro. They establish that thymus cells and lymph node cells represent distinct subsets which manifest qualitatively different functions in the proliferative response to alloantigen. Thymus cells can respond directly to alloantigen by proliferation but also have the capacity to amplify the proliferative response of lymph node cells—a capacity which is resistant to X irradiation but requires recognition of alloantigen and de novo protein synthesis. Lymph node cells may similarly respond by proliferation to alloantigen but lack the amplifier activity of thymus cells. Synergy for rat lymphoid cells, like mouse lymphoid cells, has been shown to involve an interaction of thymus-derived lymphocytes.     

B cell response to T helper cell subsets. II. Both the stage of T cell differentiation and the cytokines secreted determine the extent and nature of helper activity.

Helper activity of several murine CD4+ T cell subsets was examined. Effector Th, derived from naive cells after 4 days of in vitro stimulation with alloantigen, when generated in the presence of IL-4, secreted high levels of IL-4, IL-5, and IL-6, and low levels of IL-2 and IFN-gamma, and induced the secretion of all Ig isotypes particularly IgM, IgG1, IgA, and IgE from resting allogeneic B cells. Effectors generated with IL-6 secreted IL-2, IL-4, IL-5, IL-6, and IFN-gamma, and induced similar levels of total Ig, 25 to 35 micrograms/ml, but with IgM, IgG3, IgG1, and IgG2a isotypes predominating. Helper activity of these Th was significantly greater than that of effectors generated with IL-2 (10-15 micrograms/ml Ig) and of 24-h-activated naive and memory cells (2-4 micrograms/ml), both of which induced mainly IgM. Unlike other isotypes, IgE was induced only by effector Th generated with IL-4. Blocking studies showed that secretion of all isotypes in response to IL-6-primed effectors was dependent on IL-2, IL-5, and IL-6. IL-4 was required for optimal IgM, IgG1, and IgA secretion, but limited secretion of IgG2a, whereas IFN-gamma was required for optimal IgG2a secretion, and limited IgM, IgG1, and IgA. In contrast, secretion of all isotypes in response to IL-4-primed effectors was dependent on IL-5, although IL-4 and IFN-gamma were also essential for IgE and IgG2a, respectively. Addition of exogenous IL-5 to B cell cultures driven by IL-6-primed effectors did not obviate the requirement for IL-2, IL-4, and IL-6, suggesting that interaction of IL-4-primed effectors with B cells was qualitatively different from that of IL-6-primed effectors, driving B cells to a stage requiring only IL-5 for differentiation. Addition of exogenous factors to IL-2-primed effector Th, particularly IL-4 in the presence of anti-IFN-gamma, resulted in levels of Ig, including IgE, comparable to those induced with other effectors. These results show that functionally distinct Th cell subsets can be generated rapidly in vitro, under the influence of distinct cytokines, which vary dramatically in their levels of help for resting B cells. The cytokines involved in responses to distinct Th cells differ depending on the quality of interaction with the B cell, and the extent of help is strongly determined by the quantity and nature of cytokines secreted by the T cells.     

Synergy of helper factors in the differentiation of in vivo-preactivated antigen-specific human B cells

After in vivo immunization with antigen, B cells appear in the peripheral blood which can be induced in vitro by nonspecific factors found in mixed lymphocyte culture supernatants (MLC-SN) to differentiate and secrete antibody specific for the immunizing antigen. In order to further delineate the nature of the factors involved in the differentiation of these in vivo-activated B cells, various helper factors, including interleukin 1 and interleukin 2 (IL-1 and IL-2), B-cell growth factor (BCGF), and B-cell differentiation factor (BCDF) were added separately and in combination to cultures of these preactivated B cells. T-cell-depleted fractions of peripheral blood mononuclear cells were obtained from normal individuals immunized in vivo with keyhole limpet hemocyanin. MLC-SN alone, without the addition of antigen, selectively triggered an antibody response specific for the antigen used to immunize in vivo in the absence of a polyclonal B-cell response. In order to obtain responses equal to those seen with MLC-SN, a combination of BCGF, IL-2, and BCDF was required, although any two factors partially reconstituted the response. Exogenous IL-1 had the least effect but was suppressive in the presence of optimal concentrations of monocytes. Thus, for maximal in vitro differentiation of in vivo-preactivated B cells, a combination of at least three helper factors is required and acts in a synergistic manner to induce antigen-specific antibody responses.     

Cognate interactions between helper T cells and B cells. III. Contact-dependent, lymphokine-independent induction of B cell cycle entry by activated helper T cells

An Ag-specific, IL-2-dependent Th clone induced the growth of B cells in a class II-restricted, Ag-specific, IL-2-dependent manner. The formation of stable Th-3.1-B cell conjugates was restricted by Ag and class II MHC. After activation of Th-3.1 by insolubilized anti-T3 (Th-3.1T3), Th-3.1T3 induced the growth of B cells in a class II unrestricted, Ag nonspecific manner. The formation of stable conjugates between Th-3.1T3 and B cells was also class II unrestricted and Ag nonspecific. Although the interaction of Th-3.1T3 and B cells was class II unrestricted, the interaction was inhibited by the combination of anti-IA and anti-IE mAb. This suggested that monomorphic domains of class II MHC molecules were involved in Th-3.1T3-B cell interaction. Fixed Th-3.1T3 but not fixed resting Th-3.1 induced B cell cycle entry, as measured by an increase in B cell RNA synthesis. Trypsin-treatment of Th-3.1T3 before fixation reduced their ability to activate B cells, indicating that cell surface proteins on Th-3.1T3 were required for enhanced B cell RNA synthesis. Anti-IL-4, anti-IL-2R, or anti-IFN-gamma did not affect the ability of Th-3.1T3 to induce heightened B cell RNA synthesis. Progression into S phase by B cells activated with fixed Th-3.1T3 was supported by the addition of soluble factors. When stimulated with fixed Th-3.1T3, EL4 supernatant (SN) enhanced B cell DNA synthesis. Depletion of IL-4, but not IL-2, from EL4 SN ablated its supportive capabilities. IL-4 alone was completely ineffective in supporting entry into S phase. Therefore, IL-4 and another activity(ies) in EL4 SN were necessary for B cell cycle progression into S phase. Taken together, these data suggest that after Th activation, Th cell surface proteins are expressed that mediate the binding of Th to B cells via recognition of nonpolymorphic domains of class II MHC molecules. Contact of Th-3.1T3 with B cells, not lymphokines, results in the entry of B cells into the cell cycle and heightened B cell lymphokine responsiveness. The addition of exogenous lymphokines supports the progression of Th-3.1T3-activated B cells into S phase.     

T helper cell-dependent B cell activation.

Small, resting B lymphocytes are driven into the cell cycle as a consequence of receiving multiple signals from elements found within their local environment. The first of these signals results from the binding of specific antigen to membrane immunoglobulin (mIg) receptors on the B cells. Pursuant to antigen binding, signals are transduced and the B cell commences to endocytose and degrade the antigen. Fragments of the antigen are expressed on the B cell surface in noncovalent association with class II major histocompatibility complex (MHC) molecules. The antigen-class II MHC complex serves as a recognition complex for CD4+ helper T cells (Th). As a consequence of recognition, Th form stable physical conjugates with the B cells. Over an extended period of time the Th and B cells bilaterally signal one another. This interchange of signals results in the growth and differentiation of both cells. This review will discuss the sequence of events that culminate in the growth and differentiation of B lymphocytes to antibody-producing cells.     

Antigen-specific and nonspecific mediatiors of T cell/B cell cooperation. II. Two helper T cells distinguished by their antigen sensitivities.

Further evidence is presented for two types of helper T cells in the mouse specific for the protein antigen, keyhole limpet hemocyanin (KLH). The first cell helps B cells respond to the trinitrophenyl hapten (TNP) coupled to KLH, is primed by relatively high doses of antigen in vivo, and yet the effector cell is stimulated by very low doses of antigen in vitro. The second cell helps B cells respond to a non-cross-reacting antigen, sheep red blood cells, presumably via production of a nonspecific factor. This cell is primed by relatively low doses of antigen in vivo, but the effector cell requires relatively high doses of antigen in vitro. Thus, the two T cell types are differently sensitive to antigen dose, both in priming and challenge. The properties of T cells responding to KLH by proliferation in vitro were also studied. These cells showed the same antigen-sensitivity in vitro, as cells producing nonspecific B cell-stimulating factors.     

Cognate interactions between helper T cells and B cells. V. Reconstitution of T helper cell function using purified plasma membranes from activated Th1 and Th2 T helper cells and lymphokines.

Th physically interact with B cells and produce lymphokines that influence B cell growth and differentiation. The respective contribution of cell contact and lymphokines to induction of B cell growth and differentiation was addressed using purified plasma membranes (PM) from resting Th (PMrest) and anti-CD3-activated Th (PMCD3) together with lymphokines. Results show that PMCD3, but not PMrest, induce 10% of resting B cells to enter the G1 phase of the cell cycle, with few B cells entering G1b and S/G2. The inclusion of IL-4, but not IL-2, IL-5, or IFN-gamma, amplifies the B cell response to PMCD3 by increasing the total percentage of activatable B cells to greater than 40% and inducing B cell progression into G1b, S, and G2. Direct comparison between PMrest and PMCD3 purified from Th1 and Th2 indicate that both Th1 and Th2 induce similar levels of B cell proliferation in the presence of IL-4. Further, the lymphokine requirements for B cell proliferation induced by PMCD3 from Th1 and Th2 is indistinguishable. B cell differentiation to IgM, IgG1, and IgG2a synthesis by PMCD3 required IL-4 and IL-5. Using lymphokine conditions that supported B cell differentiation, PMCD3 purified from Th1 and Th2 induced similar levels of IgM, and IgG1. Given the functional data on PMCD3 from Th1 and Th2, the data indicate that there are no substantive differences between Th1- and Th2-derived PMCD3, and that the major differences in the ability of viable Th1 and Th2 to activate B cells is the lymphokines produced by the cells.     

Triggering of affinity-enriched B cells. II. Composition and B cell triggering properties of affinity-purified, antigen-specific, T cell-derived helper factor

Antigen-specific, T cell-derived helper factor (ASHF), recognizing alloantigens on chicken red blood cells (CRBC), had previously been shown to trigger an IgM anti-CRBC response in vitro by 2 X 10(3) affinity-enriched B cells. Triggering signals for B cell proliferation were shown to be substituted by ASHF or lipopolysaccharide, and signals for differentiation to IgM production by Thy-1+ cells. In an effort to demonstrate unequivocally antigen specificity of helper factor, secretory products and cell extracts from helper T cells that had been primed by either the B2 or the B13 chicken alloantigens, were purified by antigen affinity and ion exchange chromatography. With each step of purification, antigen-specific biologic activity of ASHF-containing material increased such that ASHF from B2, but not B13, primed helper T cells would help trigger a B2, but not a B13, -specific response and vice versa. Gel filtration of ASHF suggests it to have a m.w. of at least 50,000. Absorption studies showed that ASHF binds to B cells in the absence of antigen. Delivery of the triggering signal requires ASHF to bind simultaneously to both, the cell surface and the antigen. ASHF consists of at least two subunits that may be separated from each other by chelating agents. This yields two biologically inactive fractions, only one of which binds to the nominal antigen. Upon recombining them in the presence of Ca++, full biologic activity is restored.     

Cognate interactions between helper T cells and B cells. II. Dissection of cognate help by using a class II-restricted, antigen-specific, IL-2-dependent helper T cell clone

In order to determine the involvement of T-B cell contact vs lymphokine production in mediating B cell cycle entry and progression, Th cell clones "defective" in lymphokine production were cloned. Th-3.1 is one such clone that required IL-2 to produce significant levels of IL-4 and IFN-gamma. Unlike conventional Th clones, Th-3.1 induced B cell proliferation only in the presence of Ag and IL-2. In contrast to the absolute requirement of IL-2 for Th-3.1-induced B cell proliferation, IL-2 was not required for the formation of stable Th-3.1-B cell conjugates or Th-3.1-induced B cell entry into the G1 phase of the cell cycle. In the absence of IL-2 and under conditions that promoted Th-B cell interactions, Th-3.1 induced 10 to 20% of resting B cells to enter G1. B cell entry into the cell cycle was not inhibited by anti-lymphokine mAb or promoted by exogenous lymphokines, suggesting that endogenous lymphokine activity was not required for Th-3.1-induced G0 to G1 transition. The data suggested that the IL-2-independent induction of B cells into G1 by Th-3.1 was a cell contact-dependent event. Direct proof that Th-3.1-B cell contact was necessary for B cell cycle entry was provided by comparative in situ analysis of the RNA synthetic activity and the RNA content of B cells that were in physical contact with Th-3.1 or not in contact with Th-3.1. In situ autoradiography of RNA synthesis illustrated that a high frequency of B cells in contact with Th-3.1 expressed heightened RNA synthetic activity, whereas "bystander" B cells were less frequently induced into cycle. In situ laser cytometry of B cell size and total RNA content showed that B cells in physical contact with Th-3.1 had a higher RNA content and were larger than "bystander" B cells present in the same microcultures. This model system has allowed the dissection of T cell help into IL-2-dependent and IL-2-independent phases. Early cell contact-dependent events and B cell cycle progression into G1 were IL-2 independent, whereas the production of lymphokines (IL-4, IFN-gamma) by Th-3.1 and Th-3.1-induced B cell proliferation was IL-2 dependent.     

Antigen-specific, MHC-restricted B cell activation by cell-free Th2 cell products. Synergy between antigen-specific helper factors and IL-4

Ag-specific and MHC-restricted Th clones of different Ag specificities and MHC haplotypes were tested for their ability to produce soluble factors capable of providing the signals required for B cell activation and IgG antibody production. Each of five Th clones tested generated significant helper activity in supernatants derived from coculture of the T cell clone with specific Ag and syngeneic APC. The same helper activity was detected in supernatants of clones stimulated with immobilized anti-CD3 antibody in the absence of Ag or APC. The secreted helper activity resembled the activity of the intact Th cells in that it was Ag-specific, carrier-hapten-linked and MHC-restricted. These T cell products functioned to activate only those B cells expressing MHC products which corresponded to the specificity of each Th clone. Thus, the specificity of the cell-free T cell product mimicked precisely that expressed by the intact Th cell and presumably mediated by the cell surface TcR. In addition to the apparent presence of specific helper factor in Th clone supernatants, a role for nonspecific lymphokines was also identified in these preparations. Although recombinant or purified IL-4 alone was not sufficient to stimulate hapten-primed B cells to secrete hapten-specific IgG antibodies, mAb specific for IL-4 blocked the induction of antibody secretion by Th cell supernatant. These results indicate that stimulation of B cells to produce hapten-specific IgG antibody requires at least two distinct signals: an Ag-specific T cell signal which is restricted by MHC products expressed on the B cells, and a nonspecific signal mediated at least in part by the lymphokine IL-4.     

Analysis of two distinct B cell activation pathways mediated by a monoclonal T helper cell. II. T helper cell secretion of interleukin 4 selectively inhibits antigen-specific B cell activation by cognate, but not noncognate, interactions with T cells

A single monoclonal T helper (Th) clone can activate B cells in two distinct pathways; a cognate pathway requiring a major histocompatibility complex (MHC)-restricted T-B cell interaction, and a noncognate pathway not requiring an MHC-restricted T-B cell interaction. The present study was undertaken to investigate whether Th cells mediating a given immune response provide further regulatory function to B cells other than helper function. It was demonstrated that conditions of high antigen concentration which activate a noncognate B cell activation pathway simultaneously inhibit IgG responses. The inhibition is shown to be mediated by the T cell factor interleukin 4, produced by activated cloned Th cells. The inhibitory effect of this factor is directed to B cells and is MHC-unrestricted, antigen-nonspecific, and IgG class-specific. In addition to being susceptible to the effects of augmenting cells and suppressor cells, cloned Th cell populations can therefore themselves function as regulatory cells to inhibit IgG responses when stimulated with high dose of specific antigen. These results indicate that Th cells function to regulate B cells both positively and negatively, depending upon the activation conditions.     

Cognate interactions between helper T cells and B cells. IV. Requirements for the expression of effector phase activity by helper T cells.

After activation with anti-CD3, activated Th (THCD3), but not resting Th, fixed with paraformaldehyde induce B cell RNA synthesis when co-cultured with resting B cells. This activity is expressed by Th of both Th1 and Th2 subtypes, as well as a third Th clone that is not classified into either subtype. It is proposed that anti-CD3 activation of Th results in the expression of Th membrane proteins that trigger B cell cycle entry. Kinetic studies reveal that 4 to 8 h of activation with anti-CD3 is sufficient for ThCD3 to express B cell-activating function. However, activation of Th with anti-CD3 for extended periods of time results in reduced Th effector activity. Inhibition of Th RNA synthesis during the anti-CD3 activation period ablates the ability of ThCD3 to induce B cell cycle entry. This indicates that de novo synthesis of proteins is required for ThCD3 to express effector function. The ability of fixed ThCD3 to induce entry of B cell into cycle is not due to an increase in expression of CD3, CD4, LFA-1, ICAM-1, class I MHC or Thy-1. Other forms of Th activation (PMA and A23187, Con A) also induced Th effector function. Furthermore, purified plasma membranes from anti-CD3 activated, but not resting Th, induced resting B cells to enter cycle. The addition of IL-4, but not IL-2, IL-5, or IFN-gamma amplified the DNA synthetic response of B cells stimulated with PM from activated Th. Taken together these data indicate that de novo expression of Th surface proteins on activated Th is required for Th to induce B cell cycle entry into G1 and the addition of IL-4 is required for the heightened progression into S phase.     

Cloned allospecific human helper T cell lines induce an MHC-restricted proliferative response by resting B cells

To analyze helper T (Th) cell-induced B cell proliferation in man, we have cloned allospecific Th cells, grown them as long-term IL 2-dependent T cell lines (TCL), and analyzed their phenotypic and functional properties. The two TCL described in this report, A-7 and A-57, are both composed exclusively of T3+, T4+, T8- T cells blasts. In proliferative assays, with a panel of x-irradiated allogeneic stimulator cells, A-7 was found to proliferate in response to DR3-bearing cells, whereas A-57 responds to DR2-positive stimulators. Both TCL are capable of providing MHC-restricted polyclonal help for allogeneic B cells, as measured in the reverse hemolytic plaque assay. Of greater interest, x-irradiated A-7 and A-57 cells are capable of inducing a proliferative response by allogeneic B cells that is absolutely MHC restricted at the inductive (Th-APC) level. Thus, x-irradiated A-7 cells only trigger proliferation by DR3+ B cells, whereas A-57 cells selectively activate DR2+ B cells. In contrast, after antigen-specific activation, x-irradiated A-7 and A-57 cells can recruit a significant proliferative response by allogeneic B cells bearing "irrelevant" DR antigens. The possibility that Th-induced B cell proliferation may be restricted at the effector (Th-B cell) level was addressed by fractionating B cell populations into "activated" and "resting" subsets by discontinuous Percoll density gradient centrifugation and further purification by employing a monoclonal antibody directed against an antigen expressed on activated B cells (4F2). These studies demonstrate that activated B cells are readily and nonspecifically recruited to proliferate by activated Th cells, whereas optimal proliferative responses by resting B cells require MHC restricted Th-B cell interaction.     

In vivo priming of helper T cells in the absence of B cell activation

This paper describes an adjuvant-free immunization regimen that results in the priming of T cells but not B cells. B10.A mice were primed s.c. with syngeneic spleen cells that had been pulsed with the peptide 81-104 derived from pigeon cytochrome c. The T cell response was measured by using a sensitive limiting dilution assay that measures lymphokine production. The precursor frequency of Ag-specific cells found in these mice was indistinguishable from the frequency found in mice primed in the footpads with 81-104 in CFA. A striking difference in antibody induction was found, however, when these two immunization regimens were compared. Mice primed with 81-104 in CFA developed significant serum antibody responses against the peptide, whereas mice primed with Ag-pulsed spleen cells produced no detectable anti-peptide antibodies. This lack of antibody did not result from detectable differences in the T cells that were primed: no differences were seen in IL-2 and IL-4 production or in the ability to provide help to B cells in vitro. In vitro stimulation with LPS suggested that the B cells were not primed by the Ag-pulsed spleen cells. The B cells were not tolerized, however, because boosting the mice with Ag in CFA resulted in the induction of an antibody response. The failure to induce an antibody response by priming with Ag-pulsed spleen cells was not caused by the site of immunization or the total amount of Ag used for priming. The critical variable may be the introduction of the Ag on the surface of an APC; in this form, B cell Ag recognition was apparently inefficient, whereas T cell Ag recognition was optimal.     

T cell induction of precursor B cells: Temporal separation of helper T cell functional activities

Summary The temporal relationships involved in T cell induction of immunoglobulin-secreting B cells have been studied by employing a pulse label technique, in vitro. It was shown that addition of rabbit thymocytes or splenic T cells to B cell-enriched splenocyte populations at the time of initiation of cultures resulted in a marked enhancement in induction of immunoglobulin-secreting cells. However, even a two-hour delay in the addition of thymus cells was sufficient to reduce substantially the extent of induction when measured 70 hours later. Besides this early requirement for thymocytes, a late requirement was also detectable. Thus, thymus cells and splenocyte populations upon being mixed, subsequent to being cultured separately for 72 hours, yielded a several-fold enhancement in [³H]-immunoglobulin secreted during the course of a 90-minute labeling period with [³H]-leucine. Moreover, both the early and late thymocyte effects were lost after treatment with anti-thymocyte serum and complement.The thymocyte-mediated enhancement of immunoglobulin secretion by splenocytes that occurs late in the induction process was detected with spleen cells cultured for two or three days but not with freshly-isolated splenocytes. Although the rate of appearance of extracellular immunoglobulins was markedly enhanced by fresh thymus cells, the rate of appearance of intracellular immunoglobulins in such spleen cells was unchanged. The secretion-stimulating (secretagogue) activity of thymocytes appeared to be specific in that thymus cells were without effect on the rate of secretion of serum albumin by liver cells.In regard to the induction of immunoglobulin-secreting cells, both B and T cell-enriched population's were sensitive to mitomycin C treatment performed before initiation of cell culture, indicating that not only B cells but also T cells undergo some form of differentiation or maturation prior to functioning in the induction of immunoglobulin-producing cells. It should be noted in this context that the late T cell requirement was unaffected by prior mitomycin C treatment of thymocytes. On the other hand, thymocytes heated at 60°C for 5 minutes did not enhance immunoglobulin secretion when added at any time and the late thymocyte requirement could not be replaced with medium in which thymocytes had been previously cultured.     

Antigen-specific human T cell factors. I. T cell helper factor: biololgic properties

The in vitro induction and assay of an ovalbumin-specific human T cell helper factor are described. Peripheral blood T cells, cultured with ovalbumin in a Marbrook-Diener system, produce an antigen-specific factor(ThF120-OA), which can be purified by affinity chromatography. The in vitro studies with ThF120-OA pointed out that in the production of the factor as well as in the factor-B cell interaction the adherent cell determines the genetic restriction. The results of kinetic studies on T helper activities demonstrated that Thf120-OA provides an auxiliary activity at various moments during the differentiation of the human peripheral B cell into an antibody-secreting cell. The observed differences in the mode of action of Th cells and Th factor are discussed.     

In vitro antibody response to influenza virus. II. Specificity of helper T cell recognizing hemagglutinin

Intraperitoneal immunization of mice with liver influenza virus was shown to induce helper T (TH) cells with specificity for the hemagglutinin (HA). The interaction of virus-primed TH cells with purified HA was studied independently of B cell reactivity to the same antigen by using the generation of nonspecific help as an index of activation of HA-specific TH cells. TH cells from mice primed with any of the H3 viruses A/Aichi/68 X A/Bel/42 (H3N1), A/Memphis/102/72 X A/Bel/42 (H3N1) or A/Port Chalmers/73 (H3N2) were strongly cross-reactive towards HA of other strains within the H3 subtype. In addition, several examples of cross-reactivity towards HA of a different subtype were observed, usually of a lower magnitude. TH cells from mice primed to any of the H3 viruses above or to A/Bel/42 (H1N1) virus cross-reacted with the HA of A/Japan/305/57 (H2); furthermore, priming with A/Bel/42 or with A/Jap/305/57 X A/Bel/42 (h2N1) virus yielded TH cells that cross-reacted with certain of the H3 HA preparations. The cross-reactivity observed between subtypes was not due to the common chicken host carbohydrate component of HA, since no response to the purified type A HA preparations was obtained with T cells from mice primed with egg-grown influenza B/Hong-Kong/8/73 virus. The results indicate that HA of different subtypes may share cross-reactive antigenic determinants recognized by TH cells. Within a subtype, HA are highly cross-reactive with respect to tH cell recognition.     

Human lymphocyte differentiation antigens HB-10 and HB-11. II. Differential production of B cell growth and differentiation factors by distinct helper T cell subpopulations

Two monoclonal antibodies (HB-10 and HB-11), which react with human T, B, and NK cells, identify approximately 50% of the Leu-3+ T helper (TH) cells in adult blood. In the present studies, the functional capabilities of the HB-11+ and HB-11-TH cell subpopulations were examined after purification by fluorescence-activated cell sorting. Both subpopulations proliferated in response to PHA, Con A, PWM, and OKT-3 antibodies. The HB-11+ TH cells gave a minimal proliferative response to soluble tetanus toxoid antigen, whereas HB-11-TH cells responded well. After mitogen activation, both HB-11+ and HB-11-TH cells and to produce soluble factors which induce large B cells to proliferate. However, PWM-stimulated HB-11+TH cells were incapable of inducing B cells to differentiate into antibody-secreting plasma cells, whereas HB-11-TH cells were efficient in this regard. The results suggest that the HB-11 antigen is expressed on a subpopulation of virgin TH cells that can produce B cell growth factors but are deficient in the ability to produce B cell differentiation factors.     

Regulation of hapten-specific T-cell response. II. Functional analysis of helper T cells and cytotoxic T cells in animals suppressed by azobenzenearsonate (ABA)-specific suppressor T cells

The administration of azobenzenearsonate-modified syngeneic spleen cells (ABA-SC) intravenously induces a population of first order hapten-specific inducer suppressor T cells (Ts1), which downregulate various aspects of T-cell-mediated immune responses via a well defined suppressor-T-cell pathway. In this study, we investigated the effects of these suppressor cells on the generation of ABA-specific cytolytic T lymphocytes (CTL) and helper T cells (Th) in vivo. We found evidence for functional impairment of ABA-activated Th and ABA-specific CTL precursors (CTLp) in the suppressed animals by a number of different in vitro criteria. Functional analysis of ABA-specific CTLp and ABA-activated Th in suppressed animals revealed that ABA-specific Ts inhibit the generation of CTL by impairing the antigen-specific activation of Th, which may in turn, prevent the clonal expansion of antigen-specific CTLp. The significance of these findings in relationship to our understanding of the cellular interactions necessary for the generation of CTL and the mode of action and mechanisms of suppressor T cells is discussed.