Presence of an antigen-specific T cell subset that forms IgE-suppressive factor and IgG-suppressive factor on antigenic stimulation

B6D2F1 mice were given three i.v. injections of ovalbumin (OA), and antigen-specific T cell clones were established from their spleen cells. One of the FcR+ T cell clones formed IgE-binding factors on incubation with OA-pulsed syngeneic macrophages. Neither soluble antigen nor macrophages alone induced factor formation. T cell hybridomas were constructed by fusion of the antigen-specific T cell clone with BW 5147 cells. Among 11 T cell hybridomas established, six clones produced IgE-binding factors on incubation with OA-pulsed BDF1 macrophages. Mouse IgE also induced the same hybridoma to form IgE-binding factors. The majority of IgE-binding factors formed by two T hybridomas and by those produced by the parent T cell clone had affinity for peanut agglutinin but for neither lentil lectin nor Con A. These hybridomas and the original T cell clone spontaneously released glycosylation-inhibiting factor, which inhibits the assembly of N-linked oligosaccharide(s) on IgE-binding factors. On antigenic stimulation, the T cell hybridomas produced both IgE-binding factors and IgG-binding factors. The IgE-binding factors consisted of three species with m.w. of 60,000, 30,000, and 15,000. Both the 60K and 15K IgE-binding factors selectively suppressed the IgE response of DNP-OA-primed rat mesenteric lymph node cells, whereas IgG-binding factors selectively suppressed the IgG response. The results indicate that antigen-primed FcR+ T cells produced IgE-suppressive factors and IgG-suppressive factors on antigenic stimulation. However, the T cell hybridomas were not committed to suppressive activity. When the hybridomas were stimulated by antigen in the presence of glycosylation-enhancing factor (GEF), the 60K, 30K, and 15K IgE-binding factors formed by the cells selectively potentiated the IgE response. IgG-binding factors formed by the cells in the presence of GEF failed to suppress the IgG response. It appears that antigen-specific FcR+ T cells regulate the antibody response through the formation of Ig-binding factors, but that the function of the cells could be switched from suppression to enhancement, depending on the environment of the cells.     

Carrier-specific suppression of antibody responses by antigen-specific glycosylation-inhibiting factors

We previously established an ovalbumin (OA)-specific T cell clone from spleen cells of BDF1 mice, which had been treated by i.v. injections of OA, and constructed antigen-specific T cell hybridomas from the T cell clone. One of the hybridomas constitutively released glycosylation-inhibiting factor (GIF) which lacked affinity for OA, and was called non-specific GIF. Incubation of the same hybridoma cells with OA-pulsed syngeneic macrophages or OA-pulsed B lymphoblastoid cells of BALB/c origin resulted in the formation of GIF molecules that had affinity for OA but not for bovine serum albumin or keyhole limpet hemocyanin. Both the OA-specific GIF and nonspecific GIF bound to monoclonal anti-lipocortin and possessed I-Jb determinants. The OA-specific GIF consisted of two species of molecules, of m.w. 80,000 and 30,000 to 40,000, respectively, whereas the nonspecific GIF from unstimulated cells had an m.w. of 15,000. Intravenous injections of OA-specific GIF or nonspecific GIF into BDF1 mice suppressed both the IgE and IgG1 anti-hapten antibody responses of the animals to dinitrophenyl derivatives of OA (DNP-OA), but OA-specific GIF was much more effective than nonspecific GIF in suppressing the antibody responses. When the same preparations of GIF were injected into DNP-KHL-primed mice, OA-specific GIF and nonspecific GIF were comparable in suppressing the anti-DNP antibody response. In contrast to the 40,000 m.w. species of OA-specific GIF, the 80,000 m.w. OA-specific GIF had carrier-specific suppressive effects. The similarities of antigen-specific GIF to antigen-specific TsF suggest that the phospholipase-inhibiting activity of the molecules may be involved in the immunosuppressive effects of some antigen-specific TsF.     

Immunosuppressive effects of glycosylation inhibiting factor on the IgE and IgG antibody response

Glycosylation inhibiting factor (GIF) was purified from culture filtrates of a T cell hybridoma, 23A4, by affinity chromatography on anti-lipomodulin Sepharose. The factor exhibited phospholipase inhibitory activity upon dephosphorylation. Immunization of BDF1 mice with aluminum hydroxide gel (alum)-absorbed dinitrophenyl derivatives of ovalbumin (DNP-OA) resulted in persistent IgE and IgG antibody formation. However, repeated injections of the affinity-purified GIF into the DNP-OA-primed mice beginning on the day of priming prevented the primary anti-hapten antibody responses of both the IgE and the IgG1 isotypes. Treatment with GIF also diminished on-going IgE antibody formation in the DNP-OA-primed mice. The treatment changed the nature of IgE-binding factors formed by BDF1 spleen cells. Incubation of spleen cells from OA + alum-primed mice with OA resulted in the formation of IgE-potentiating factor, whereas spleen cells of OA-primed, GIF-treated mice formed IgE-suppressive factor upon antigenic stimulation. It was also found that Lyt-2+ T cells in the OA-primed, GIF-treated mouse spleen cells released GIF, which had affinity for OA and bore I-Jb determinant(s). Transfer of a Lyt-1+ cell-depleted fraction of the OA-primed, GIF-treated mouse spleen cells into naive syngeneic animals resulted in suppression of the primary anti-DNP IgE antibody response of the recipients to alum-absorbed DNP-OA, but failed to affect the anti-DNP antibody response to DNP-keyhole limpet hemocyanin. The results indicate that GIF treatment during the primary response to OA facilitated the generation of antigen-specific suppressor T cells.     

Effect of alpha-endorphin on the antigen-induced primary antibody response of human blood B cells in vitro

The interference of alpha-endorphin with the primary antibody response to ovalbumin (OA) of human blood lymphocytes in vitro was investigated. It was found that alpha-endorphin can block the OA-specific IgM-PFC response in a concentration of 0.05 to 0.5 microM. The decrease in the PFC response is due to an inhibitory effect of alpha-endorphin at the T cell level as well as at the B cell level. It appears that the neuropeptide is capable of blocking the production and/or secretion of antigen-specific T cell helper factor as well as of anti-OA antibodies by PFC. In addition, alpha-endorphin was shown to be capable of inhibiting the transition of B cells into PFC, which normally occurs after stimulation with antigen in the presence of adequate T cell helper activity. When alpha-endorphin, lacking the N-terminal amino acid residue tyrosine, is added to the cultures, inhibition of the PFC response is no longer observed. This indicates that alpha-endorphin influences the PFC response via opiate receptor interaction.     

Reaginic antibody formation in the mouse. VI. Suppression of IgE and IgG antibody responses to ovalbumin following the administration of high dose urea-denatured antigen.

The major antigenic determinants in ovalbumin molecules (OA) were lost following denaturation in 8 M urea. The urea-denatured antigen (UD-OA) failed to combine with anti-OA antibody, but was capable of priming mouse T cells specific for OA. BDF₁ mice primed with alum-precipitated OA were given three intravenous injections of 100 μg UD-OA at 3, 5, and 7 days after the primary immunization. The treatment with UD-OA suppressed both IgE and IgG antibody responses to OA. The same treatment of OA-primed animals with intravenous injections of OA resulted in suppression of IgE antibody response but enhanced IgG antibody response. Intravenous injections of either OA or UD-OA suppressed both IgE and IgG anti-DNP antibody responses of DNP-OA-primed animals but failed to suppress anti-hapten antibody responses to DNP-keyhole limpet hemocyanin. The effect of the treatment on helper T cells and B memory cells in OA-primed animals was studied by adoptive transfer experiments. The results showed that the OA-treatment as well as UD-OA-treatment suppressed the development of both helper function of T cells and B memory cells in the spleen, but the UD-OA treatment was more effective than OA-treatment for the suppression of B cell development. Possible mechanisms for the suppression of the development of immunocompetent cells were discussed.     

Enzyme-labeled Antigen Method: Histochemical Detection of Antigen-specific Antibody-producing Cells in Tissue Sections of Rats Immunized With Horseradish Peroxidase, Ovalbumin, or Keyhole Limpet Hemocyanin

The enzyme-labeled antigen method is a histochemical technique that visualizes antigen-specific antibody-producing cells in tissue sections, originally documented in 1968. In this study, we attempted to reemerge this hidden but potentially useful method in rat models immunized with horseradish peroxidase (HRP), ovalbumin (OA), or keyhole limpet hemocyanin (KLH). After repeated immunization in footpads, popliteal, groin, and axillary lymph nodes and spleen were sampled. Paraformaldehyde-prefixed frozen sections were incubated with HRP, biotinylated OA, or biotinylated KLH. Proteinase K pretreatment and the secondary use of HPR-labeled streptavidin were applied in the latter two situations. Plasma cells producing antigen-specific antibodies were visualized. Proportions of antigen-specific antibody-producing cells in total plasma cells shown with the immunoperoxidase method for rat immunoglobulins were evaluated. The percentage of antigen-specific plasma cells reached ∼50% of total plasma cells in the regional lymph nodes. The specificity was confirmed by (a) negativity in non-immune rat tissue, (b) negativity with indifferent antigen probes, and (c) abolishment of the reactivity with the corresponding rat serum. In buffered formalin-fixed, paraffin-embedded tissues, fewer plasma cells were labeled for HRP and KLH antibody reactivity after strong proteolysis and prolonged incubation. Expectedly, this method allows us to observe antigen-specific antibody-producing cells under varied pathological conditions. (J Histochem Cytochem 57:101–111, 2009)     

Generation of specific helper cells and suppressor cells in vitro for the IgE and IgG antibody responses.

Normal splenic lymphocytes from BDF1 mice were cultured on ovalbumin (OA)-bearing syngeneic peritoneal adherent cells for 5 days and their subsequent helper function was tested by an adoptive transfer technique. Lymphocytes harvested from the culture were mixed with DNP-KLH-primed spleen cells and transferred into irradiated syngeneic mice followed by challenge with DNP-OA. The results showed that the cultured lymphocytes has helper function for both IgE and IgG anti-DNP antibody responses. Depletion of mast cells and T cells in the peritoneal adherent cell preparations did not affect the generation of helper cells in the culture. The helper function of the cultured lymphocytes was abolished by the treatment with anti-theta antiserum and complement and was specific for ovalbumin. The OA-specific helper T cells were generated in vitro by the culture of a T cell-rich fraction of normal spleen on T cell-depleted OA-bearing peritoneal cells. If the normal splenic lymphocytes or T cell-rich fraction were cultured with 10 mug/ml of OA in the absence of macrophages, cultured lymphocytes lacked helper function. The transfer of splenic lymphocytes or splenic T cells cultured with soluble OA to normal non-irradiated mice, however, suppressed both IgG and IgE antibody responses of the recipients to subsequent immunization with DNP-OA. The suppressor cells were sensitive to anti-theta antiserum and complement and their activity was specific for OA. The cultured cells transferred into normal mice did not suppress anti-hapten antibody response to DNP-KLH. Normal lymphocytes cultured on OA-bearing macrophages and had helper function in adoptive transfer experiments failed to suppress antibody response of non-irradiated recipients to DNP-OA. The results indicate that OA-bearing macrophages primed T cells and generated helper T cells, whereas the culture of normal lymphocytes with soluble OA in the absence of macrophages generated suppressor T cells.     

Reaginic antibody formation in the mouse. X. Possible role of suppressor T cells in transient IgE antibody responses.

The kinetics of IgE antibody response to alum-absorbed dinitrophenyl derivatives of ovalbumin (DNP-OA) was dependent on the dose of immunogen. A persistent IgE antibody response was obtained when high responder BDF1 mice were immunized with a minimum (0.05 microgram) dose. An increase of the immunogen to 10 microgram depressed IgE antibody responses but enhanced IgG antibody responses of both hapten and carrier specificities. Determination of T helper cell activity and B memory cells after immunization with different doses of antigen indicated that minimum immunogen was favorable for developing helper activity, whereas 1 to 10 microgram immunogen were more favorable than a 0.05-microgram dose for developing both IgE and IgG B memory cells. Nevertheless, neither helper T cells nor B memory cells in the spleen explains a transient IgE antibody response to a high (10 microgram) dose of DNP-OA. Evidence was obtained that immunization with 10 microgram OA induced generation of antigen-specific suppressor T cells, which were not detectable after immunization with 0.05 microgram OA. Transfer of suppressor T cells to DNP-OA-primed mice depressed both anti-hapten and anti-carrier IgE antibody responses. The results suggested strongly that suppressor T cells are involved in a transient IgE antibody response to a high-dose immunogen.     

Antigen-specific suppressor cell activity in man: I. Temporal, antigenic, and proliferative requirements

The temporal, antigenic, and proliferative requirements of antigen-specific suppression of the in vitro plaque-forming cell (PFC) response of human peripheral blood mononuclear cells (PBM) were studied. Suppressor cell activity (SCA) was generated by priming PBM with high doses of the T-cell-dependent antigen ovalbumin (OA) and measured by adding washed primed cells to target PFC cultures. Priming with high doses of OA was shown to induce a population of antigen-specific T lymphocytes which interfered with the anti-OA PFC response of optimally stimulated target cultures. The generation of SCA was demonstrated following as little as 24 hr of high-dose OA priming and could be abrogated by prolonged priming (72 hr) or by pretreatment with mitomycin prior to priming. The expression of optimal SCA required the addition of primed PBM at the initiation of the target culture and could be directly correlated to both the OA concentration used for priming and the number of primed cells added. Higher priming doses of OA (up to 100 μg) generated increasing numbers of cells capable of antigen-specific SCA as measured via a cell dilution protocol. Our data suggest that an antigen-driven and dose-dependent expansion of an antigen-specific T-suppressor cell pool is an early regulative event limiting the in vitro PFC response of human lymphocytes to OA.     

IgE-binding factors from mouse T lymphocytes. III. Role of antigen-specific suppressor T cells in the formation of IgE-suppressive factor

BDF1 mice were given three i.v. injections of ovalbumin (OA) to induce antigen-specific suppressor T cells. Incubation of spleen cells of OA-treated mice with homologous antigen resulted in the formation of IgE-suppressive factor. This factor was not derived from antigen-specific suppressor T cells, but suppressor T cells were essential for determining the nature of IgE-binding factors formed. In the spleen cells of OA-treated mice, antigenic stimulation of antigen-primed Lyt-1+ (helper) T cells resulted in the formation of inducers of IgE-binding factor, whereas Lyt-2+, I-J+ T cells released glycosylation-inhibiting factor (GIF), and these two factors, in combination, induced unprimed Lyt-1+ T cells to form IgE-suppressive factor. The role of GIF is to inhibit the assembly of N-linked oligosaccharides on IgE-binding factors during their biosynthesis, and thereby provide them with a biologic activity: suppression of the IgE response. Under the experimental conditions employed, GIF was released spontaneously from antigen-specific suppressor T cells. However, antigenic stimulation of the cells enhanced the release of the factor. GIF from antigen-specific suppressor T cells has a m.w. of 25,000 to 30,000, as estimated by using gel filtration, binds to anti-I-J alloantibodies and to a monoclonal antibody specific for lipomodulin, and has affinity for specific antigen. The possible relationship between antigen-specific GIF and antigen-specific suppressor factors is discussed.     

Modulation of the biologic activities of IgE-binding factor. V. The role of glycosylation-enhancing factor and glycosylation-inhibiting factor in determining the nature of IgE-binding factors

Glycosylation-enhancing factor (GEF) and IgE-potentiating factor were detected in culture supernatants of rat mesenteric lymph nodes (MLN) cells obtained 14 days after infection with Nippostrongylus brasiliensis (Nb), but not in supernatants of MLN cells of 8-day Nb-infected rats. Both factors were also released from T cells upon antigenic stimulation of KLH + alum-primed spleen cells. The GEF from the Nb-infected rats and KLH + alum-primed spleen cells had affinity for p-aminobenzamidine agarose and were inactivated by phenylmethylsulfonylfluoride, an inhibitor of serine proteases. These results indicate that the GEF obtained in the two systems is a serine protease and is identical to that obtained by stimulation of normal T cells with lymphocytosis-promoting factor (LPF) from Bordetella pertussis. The concomitant formation of IgE-potentiating factor and GEF by Nb infection, by antigenic simulation of KLH + alum-primed spleen cells, and by treatment of rats with Bordetella pertussis vaccine suggests that the serine protease is involved in a common pathway leading to the selective formation of IgE-potentiating factor. In contrast, glycosylation-inhibiting factor (GIF) is always found during the selective formation of IgE-suppressive factor. IgE-suppressive factor and GIF were formed by MLN cells of 8-day Nb-infected rats and KLH-CFA-primed spleen cells. GIF was detected in culture supernatants of T cell hybridomas 23A4 and 23B6, which form unglycosylated IgE-binding factors upon incubation with IgE. GIF obtained from all of these sources bound to monoclonal anti-lipomodulin. These findings indicate that GIF or lipomodulin is involved in all systems, which leads to the selective formation of IgE-suppressive factor. However, the formation of GIF was not restricted to those conditions in which IgE-suppressive factor was selectively formed. The culture supernatants of MLN cells of 14-day Nb-infected rats and antigen-stimulated KLH + alum-primed spleen cells contained a small amount of GIF, which could be detected after inactivation of GEF. It appears that T cells from these sources formed GEF and GIF, but that GEF overcame the effect of GIF on glycosylation of IgE-binding factors. The results indicate that the nature and biologic activities of IgE-binding factors are decided by the balance between GEF and GIF formed by T cells.     

Definition of the pulmonary antibody response to ovalbumin following local challenge in systemically immunized rats

The in vivo pulmonary immune response of rats to local stimulation with antigen was assessed by measuring antigen-specific antibody and antibody-secreting cells utilizing enzyme-immunoassay technology. Sprague-Dawley rats were immunized subcutaneously with ovalbumin (OA) emulsified in Freund's incomplete adjuvant, challenged with OA intratracheally on Day 19 and sacrificed 1, 2, 3, or 4 days later. Specific antibody-secreting cells in the lung-associated lymph nodes were enumerated with the ELISA-SPOT assay and antibody concentration in the pulmonary lavage fluids and sera was assessed with the ELISA. The greatest response for each parameter was on Day 2. Cellular infiltration of the lung was minimal. Cellular infiltrates consisted mainly of polymorphonuclear leukocytes and were most numerous in the lavage fluid on Days 1 and 2 and in the lung parenchyma on Day 2 after challenge. Local production versus serum transudation of antibody was evaluated by comparing the levels of OA-specific antibody to albumin in the lavage fluid and serum. The data showed that antibody in the lungs was primarily produced locally.     

Distinct role of neonatal and adult monocytes in the regulation of the in vitro antigen-induced plaque-forming cell response in man

Mononuclear cells from human cord blood (CBMC) are able to mount an antigen-specific IgM plaque-forming cell (PFC) response after primary in vitro stimulation with the T cell-dependent antigen ovalbumin (OA). The antigen dose-response relationship for the induction of PFC in cultures of CBMC is represented by a bell-shaped curve comparable to that found for mononuclear cells from adult peripheral blood (adult PBMC). The dose of OA optimal for the induction of a response in cultures of CBMC consistently, however, is 100-fold lower than the antigen dose optimal for adult PBMC (0.03 microgram OA/ml vs 3.0 micrograms OA/ml). Results obtained from co-culture experiments in which semiallogeneic combinations of parental/neonatal lymphocytes and monocytes were stimulated with a variable dose of OA indicate that the adherent cell (AC) plays a pivotal role in the establishment of the optimum antigen dose. From experiments using antigen-pulsed AC, it was concluded that neonatal and adult AC differ in their antigen handling capacity. In the presence of the prostaglandin synthetase inhibitor indomethacin the antigen dose-response relationship for the induction of PFC in cultures of CBMC shifts to an "adult type" of curve. From pulsing experiments it emerges that indomethacin affects the interaction between antigen and monocytes. Indomethacin causes an enhancement of the expression of HLA-DR at the surface of neonatal as well as adult AC; this can be down regulated by the addition of prostaglandin E2 (PGE2). The addition of PGE2 to cultures of adult PBMC leads to a shift of the optimal antigen dose for induction of PFC toward lower concentrations. Although higher levels of PGE2 were measured in the supernatant of cultured neonatal AC compared with adult AC, it seems unlikely that this observation can explain the distinct antigen dose-response relationship for the induction of a PFC response in cultures of CBMC.     

Heterogeneity in the response of T cells to antigens presented by B lymphoma cells

Proliferation of antigen-specific T-cell populations was induced in cultures stimulated with antigen and a suitable source of antigen-presenting cells. Soluble (keyhole limpet hemocyanin) and particulate (horse red blood cells) antigens were presented by irradiated spleen cells and by a variety of B-lymphoma-cell lines, providing support for antigen-specific H-2-restricted T-cell responses. A marked heterogeneity was demonstrated, however, in the capacity of T-cell lines to proliferate in response to antigen presented by the B-lymphoma cells. T-cell populations were prepared from the lymph nodes of antigen-primed mice and restimulated in vitro in the presence of antigen and irradiated spleen cells. During the first six in vitro restimulations, these T-cell populations maintained the capacity to respond to antigen presented either by irradiated spleen cells or by B-lymphoma cells. Continued growth of these T-cell populations, again in the presence of antigen and irradiated spleen cells, resulted in the generation of T-cell lines which had lost the ability to respond to antigen presented by B-lymphoma cells. These lines however, fully retained the capacity to proliferate in the presence of antigen and irradiated spleen cells. T-cell clones derived from one of these lines were also unable to respond to antigen presented by B-lymphoma cells but again proliferated in the presence of antigen and irradiated spleen cells. Supernatants containing high levels of IL-1, IL-2, or IL-3 activity failed to reconstituted the antigen-specific response of T-cell lines which had lost the capacity to respond to antigen presented by B-lymphoma cells. Furthermore, titrated numbers of irradiated spleen cells, while having the capacity to support T-cell proliferation themselves, failed to synergize with B-lymphoma cells in the support of antigen-specific T-cell proliferation. Thus we have defined populations of antigen-specific, H-2-restricted T cells which do not recognize antigen presented by B-lymphoma cells and can therefore discriminate between different antigen-presenting cell types.     

Establishment of a nucleoside-specific suppressor T cell line from SLE prone (NZB/NZW)F1 mice

A long-term cultured suppressor T cell line (GTS-124) was established from an autoimmune mouse strain, (NZB X NZW)F1, by a two-part procedure: a) B/W F1 mice were made tolerant to guanosine (G) by administration of a tolerogen, the G-modified copolymer of D-glutamic acid and D-lysine (G-D-GL); and b) the spleen cells obtained from tolerant mice were repeatedly stimulated with mitomycin C-treated G-modified syngeneic spleen cells. The GTS-124 cells suppressed the secondary in vitro response to G-keyhole limpet hemocyanin (G-KLH) but did not suppress the response to unrelated antigens, sheep erythrocytes (SRBC), or trinitrophenyl-KLH (TNP-KLH). The expression of Thy-1 antigen on the cell surface of GTS-124 was demonstrated by flow cytometry. Growth of GTS-124 cells was dependent on IL 2. To determine whether GTS-124 cells could suppress the response to nucleosides other than G, KLH coupled with four nucleosides (adenosine [A], G, cytidine [C], and thymine riboside [T]) collectively (AGCT-KLH) was first used as the antigen in the assay system. The PFC response to the individual nucleosides (anti-A, -G, -C, and -T PFC) were effectively inhibited by GTS-124 cells, suggesting that the GTS-124 cells mediated cross-suppression toward all four nucleosides. A more stringent cross-suppression test was conducted by using only the T moiety bound to KLH (T-KLH) as antigen. The results showed that GTS-124 cells were capable of suppressing the T-specific response. The cross-suppression could be seen after repeated selection on a G-BSA-coated dish. These results provide direct evidence that the suppressor T cells induced by in vitro stimulation with G-modified self can indeed suppress the response to nucleosides other than G.     

Effect of Bacterial Lipopolysaccharides on Anti-Trinitrophenyl Antibody-Producing Cells

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Effect of bacterial lipopolysaccharides on anti-trinitrophenyl antibody-producing cells. Nonspecific modification of the affinity at the cellular level.

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Antigen-specific suppression of the plaque-forming cell response induced polyclonally by lipopolysaccharides

Horse erythrocytes (HRBC) were added with LPS in mouse spleen cell cultures, and the effects of HRBC on the LPS-induced polyclonal PFC response were investigated by enumerating total IgM-secreting PFC, anti-HRBC PFC, and PFC against sheep erythrocytes (SRBC). The addition of HRBC influenced the frequencies of anti-HRBC PFC in the total IgM-secreting PFC, but did not influence those of anti-SRBC PFC. The augmentation of the frequencies of anti-HRBC PFC occurred only when an appropriate dose of HRBC was added in the cultures containing T cells. Higher doses of HRBC decreased the frequencies of anti-HRBC PFC whether T cells were present or absent. The degree of reduction of the frequencies of anti-HRBC PFC was dependent on the dose of HRBC, but independent of the dose of LPS. The addition of HRBC at 1 day after LPS stimulation also decreased the frequency of anti-HRBC PFC, though the addition of 2 or 3 days hardly suppressed it. These results suggest that the antigen-specific augmentation occurs via helper T cells, and the suppression is ascribed to the direct action of antigen on the antigen-specific B cells.     

Induction of an antibody response in vitro against synthetic antigens in guinea pigs. I. Culture and assay conditions

Guinea pig spleen and lymph node cells were found to produce anti-2,4-dinitrophenyl (Dnp) oligolysine PFC in vivo against 2,4-dinitrophenyl-β-alanyl glycyl glycyl (Dagg-SRBC) but not against trinitrophenyl-SRBC target indicator cells. Furthermore, when sensitized spleen cells or their purified B-cell fractions were cocultured with primed peritoneal exudate lymphocytes (PEL) but not splenic T cells they were able to generate a secondary PFC response in vitro to the synthetic antigens, Dnp oligolysines. PFC were not induced in vitro if these same cultures were pulsed with short-chain peptides (five lysines) or the complex antigen, dinitrophenyl-bovine γ-globulin (DnpBGG). Con A was able to substitute for PEL in triggering spleen cells to mount a secondary in vitro PFC response to homologous Dnp oligolysines. More importantly, the Con A-aided spleen cell cultures were not induced above background values when challenged in vitro with heterologous Dnp oligolysines. This study suggests that spleen cells may lack a nonspecific signal for the development of a secondary in vitro PFC response.     

Selective elimination of a B cell subset having acceptor site(s) for T cell-replacing factor (TRF) with biotinylated antibody to the acceptor site(s) and avidin-ricin A-chain conjugate

A covalent conjugate of avidin with ricin subunit A-chain (avidin-RA) was prepared by using N-succinimidyl 3-(2-pyridyldithio)propionate as a coupling agent. Selective cytotoxic activity after the combined treatment of spleen cells with biotinylated antibody and avidin-RA was demonstrated by the fact that the responsiveness to LPS was selectively abrogated by pretreatment of the cells with biotinylated rabbit anti-mouse immunoglobulin (MIg) antibody, but not with biotinylated anti-Thy-1.2 antibody. Neither the biotinylated antibody alone nor avidin-RA alone was effective in decreasing the responses to mitogens. Moreover, a high anti-DNP PFC response elicited by DNP-KLH-primed BALB/c mouse spleen cells stimulated in vitro with DNP-KLH was mostly abrogated by the pretreatment of the cells with biotinylated anti-MIg antibody and avidin-RA. Again, neither the biotinylated antibody alone nor avidin-RA alone was effective in decreasing the anti-DNP PFC response. This cell-killing method with the use of biotinylated antibody and avidin-RA was applied and evaluated in experimental systems in which the helper action of T cells on B cells was mediated by T cell-replacing factor (TRF) or was performed by the direct interaction of T cells with B cells (cognate interaction). When DNP-KLH-primed splenic B cells, pretreated with biotinylated F(ab')2 fragment of DCF1 male anti-BALB/c-B IgG antibody against acceptor site(s) for TRF followed by treatment with avidin-RA, were stimulated with DNP-OVA in the presence of monoclonal TRF, the anti-DNP PFC response was significantly decreased, whereas the same treated B cells responded well to stimulation with DNP-PPD in the presence of Tbc-primed T cells (cognate interaction). These results indicate that B cells responsible for the cognate interaction and those having TRF acceptor site(s) belong to a distinct subpopulation of B cells, and that the cytocidal action of the noncovalent conjugate of the antibody and RA formed from the biotinylated antibody and avidin-RA via an avidin-biotin complex has immunologic selectivity, eliminating only the latter subset of B cells recognized by the antibody.