Antibody conjugates mimic specific B cell presentation of antigen: relationship between T and B cell specificity

We developed antibody conjugates by covalently coupling antibodies against mouse mu-chain and monoclonal antibodies against nominal antigen, myoglobin, as a tool for antigen presentation and as a model of specific presentation of antigen by antigen-specific B cells and T-B interaction. In the presence of the antibody conjugates, myoglobin-specific Iad-restricted cloned T cells proliferated at 1000-fold lower concentration of myoglobin than the stimulatory concentration without the conjugates. This enhanced presentation was observed only when Iad spleen cells were 1000 R-irradiated but not 3300 R-irradiated, consistent with B cell presentation. The simple mixture of each component of the conjugates had no enhancement effects. The conjugates per se had no mitogenic effects on either splenic B cells or the cloned T cells at concentrations employed for antigen presentation. The conjugates reduced the number of antigen-presenting cells required for the maximal response but did not change the kinetics of response. The enhanced presentation by the conjugates required a genetically restricted interaction with B cells. Antigen specificity of the enhanced presentation was confirmed by using various T cell clones or lines with different antigen specificities and different conjugates constructed with monoclonal antibodies of known epitope specificity. The enhanced presentation was significantly inhibited by competition with exogenous mouse IgM or anti-mouse mu-chain but was not significantly inhibited by monoclonal antibodies against Fc receptor. Thus, conjugate-coated B cells serve as models for myoglobin-specific B cells in that they can take up specific antigens at extremely low concentration and can present the antigen to specific T cells. This model system can be applied to any antigen and any species without the need to develop antigen-specific B cell clones, which is not yet possible for most antigens and species of experimental animals. This system allowed us to investigate the relationship between T cell epitope and B cell epitope when these cells interact with each other in an antigen-specific and Ia-restricted manner. Experiments using antibody conjugates of different monoclonal antibodies against myoglobin and various myoglobin-specific cloned T cells of known antigen specificity revealed that there are some particular combinations in which much more limited enhancement of antigen presentation is observed.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction of anti-hapten antibody response by hapten-isologous carrier conjugate. II. Specificity of hapten-reactive helper T cells.

Anti-hapten antibody production was elicited by the immunization of hapten-isologous carrier conjugate (PAB-MGG) in mice. Spleen and lymph node cells taken from these primed mice could demonstrate their helper activity for anti-DNP antibody production when transferred intravenously into 600R X-irradiated recipient mice along with DNP-primed B cells and the double hapten conjugated carrier, DNP-MGG-PAB. Isologous carrier (MGG)-primed cells could not demonstrate this helper activity. Accordingly, helper cells reactive for a haptenic group are considered to develop by the immunization of hapten-isologous carrier conjugate. Hapten-reactive helper activity was also induced by the immunization of other hapten-isologous carrier conjugates, e.g., MAB-MGG, PABS-MGG or PAB-MSA. These hapten-reactive helper cells were T lymphocytes, as the helper activity of PAB-MGG-primed cells was completely abolished by in vivo ATS-treatment. Helper activity of PAB-MGG-primed cells for DNP-primed B cells was also demonstrated through the double hapten conjugated heterologous carrier DNP-HGG-PAB to be the same as with DNP-MGG-PAB, but weakly through DNP-KLH-PAB. As HGG but not KLH resembles MGG in composition, almost all hapten-reactive helper T cells can be considered to recognize not only haptenic groups but also physicochemical properties of the hapten-conjugated carrier site. However, these helper T cells could discriminate structural differences among related haptenic groups, because PAB-MGG-primed cells clearly responded to DNP-MGG-PAB to demonstrate their helper activity for DNP-primed B cells, but responded only weakly to DNP-MGG-PABS or DNP-MGG-MAB. When the specificity restrictions of T and B cells to the same haptenic group were compared by responsiveness measured after the antigenic stimulation (B cell function by anti-hapten antibody production and T cell function by helper activity), differences were noted, as PAB-MGG-primed T cells could respond not only to DNP-MGG-PAB but also fairly well to DNP-MGG-MAB to demonstrate their helper activity, but PAB-MGG-primed B cells responded to only PAB-MGG. Thus, hapten specificity appears to be much more restricted for B cells than T cells. The difference of this responsivity between B cells and helper T cells was thought to derive from the specificity difference of B cell and helper T cell receptors rather than from any sensitivity differences of the experimental procedure. The differences in the specificity restrictions of receptors of B and helper T cells were discussed in the light of hapten-specificity.     

Induction of anti-hapten antibody response by hapten-isologous carrier conjugate. I. Development of hapten-reactive helper cells by hapten-isologous carrier

Anti-hapten antibody production was elicited by the immunization of hapten-isologous carrier conjugate (DNP-MγG) in mice. The spleen and lymph node cells taken from those primed mice were effectively stimulated with hapten-heterologous carrier conjugates (DNP-KLH and DNP-BαA) as well as hapten-homologous carrier conjugate (DNP-MγG) when transferred into X-irradiated recipient mice. The reactivity of DNP-MγG-primed cells to DNP-heterologous carrier conjugates was not due to the mutual crossreactivity of the carrier with MγG on cellular level, since the spleen and lymph node cells primed with DNP-KLH or DNP-BαA could only be stimulated with corresponding hapten-homologous carrier conjugate. The responsiveness of DNP-MγG-primed cells to hapten-heterologous carrier conjugates was due to the result that hapten-reactive helper cells were developed by the immunization of hapten-isologous carrier and these cells cooperated with hapten-specific B cells.The helper activity of the hapten-isologous carrier-primed cells was resistant to 600-R X-irradiation in vitro and sensitive to in vivo ATS treatment. This suggests that the helper activity induced by hapten-isologous carrier is of T cell origin. The helper activity of hapten-isologous carrier-primed cells was also developed by the immunization of PAB-MγG, and clear cooperative interaction between PAB-MγG-primed cells and DNP-specific B cells was demonstrated through DNP-MγG-PAB.The possible mechanism of helper cell development induced by the immunization of hapten-isologous carrier conjugate was discussed in light of the hapten specificity of helper activity.     

ABA-specific helper T cells in A/J mice bear the major cross-reactive idiotype

Attempts were made to induce azobenzenearsonate (ABA)-specific helper cell responses in A/J mice. These were measured by an increase in TNP plaque-forming cells following administration of the double hapten conjugate ABA-bovine serum albumin-TNP. Immunization with ABA coupled homologous immunoglobulin or spleen cells produced ABA-specific help only when the same carrier was used to boost. Hapten-specific help was achieved by two injections of ABA-N-acetyltyrosine in complete Freund's adjuvant 5 weeks apart. This help was passively transferable by T cells as shown by its elimination with anti-Thy 1.2 serum and complement treatment. The presence of the major ABA cross-reactive idiotype (CRI) on these T helper cells could be similarly shown by the elimination of help when the cells were treated with rabbit anti-CRI antibody and complement prior to passive transfer. The same treatment did not effect ABA-specific helper activity of CBA/J mice.     

Enhancement of antigenic potency in vitro and immunogenicity in vivo by coupling the antigen to anti-immunoglobulin

We have examined the effect of targeting an antigen to the immune system, by covalently coupling it to anti-immunoglobulin (Ig), on its efficacy for T cell stimulation in vitro and its immunogenicity for antibody production in vivo. In vitro, we compared the potency (for stimulation of a ferritin-specific T cell line) of free ferritin, ferritin coupled to goat antimouse IgM (heavy (H) chain specific), ferritin coupled to anti-IgG (H and light (L) chain specific), or ferritin coupled to anti-IgA (H chain specific), as well as a mixture of free ferritin plus goat anti-IgG. The ferritin coupled to anti-IgM or to anti-IgG (H + L), which could bind to surface Ig of B cells, stimulated T cell proliferation at concentrations of ferritin at least 10-fold lower than those required for the other forms of the antigen over the entire time course of the response, with 1000 rad-irradiated spleen cells as presenting cells. Because the goat antibodies were all of the same IgG isotype and coupling ratio, the failure of goat anti-IgA to enhance potency served as a control to exclude Fc receptor binding as the mechanism. The effect was not due to the nonspecific activation of B cells to become more efficient antigen-presenting cells, because mixtures of ferritin plus anti-IgG (H + L) had no effect, and the anti-IgG coupled to ferritin did not enhance presentation of myoglobin to a myoglobin-specific T cell line. The enhanced presentation of ferritin conjugated to goat anti-IgG (H + L) or to anti-IgM was sensitive to radiation doses greater than 2000 R, and was effective at less than one-tenth the number of spleen cells, consistent with the predominance of B cells as antigen-presenting cells for this form of the antigen rather than macrophages and dendritic cells only. When B cells and accessory cells were purified from T-depleted spleen cells, only the B cell preparation but not the accessory cell population manifested enhanced presentation of ferritin coupled to anti-IgG compared with free ferritin, and it was radiosensitive. Finally, allogeneic B cells could not mediate the enhancement in the presence of syngeneic splenic accessory cells (SAC); therefore, the enhancement was not due to shedding of immune complexes from B cells and subsequent presentation by SAC. We conclude that targeting the antigen to B cells as presenting cells greatly enhances its efficacy in vitro.(ABSTRACT TRUNCATED AT 400 WORDS)     

IgG-specific helper activity of t lymphocytes from mice lacking theIr-IgG gene

Cooperative interactions between T and B cells from the congenic inbred mouse strains B10.A(2R) and B10.A(4R) in antibody responses controlled byIr genes have been studied. Within theI region of the MHC, these strains share only theI-A subregion. TheIr gene controlling responsiveness to IgA maps in theI-A subregion, both strains being responders to IgA. T cells from 2R mice collaborate effectively with B cells from 2R or 4R mice for antihapten antibody responses to DNP-IgA. TheIr gene controlling responses to IgG maps in theI-B subregion, and 2R mice are nonresponders for this antigen. Nevertheless, 2R T cells primed with IgG can help responder (4R) B cells -but not syngeneic nonresponder (2R) B cells -in responding to DNP-IgG. These results indicate that mice lacking theIr-IgG gene nonetheless may develop helper T lymphocytes specific for myeloma proteins. In addition, they indicate that cells from congenic mice sharing only theA subregion of theI region can collaborate efficiently.     

Antigen-specific helper factor production by immortalized clone of OVA-specific T cells. I. In vitro activity

Immortalized clones of virally transformed OVA-specific T cells produce antigen-specific helper factor upon stimulation in vitro. The helper factor activate DNP-primed B cells to multiply and synthesize IgG anti-DNP antibodies. The trigger of the helper clone is antigen specific and the B cell-stimulating hapten must be coupled to the specific T cell carrier in order to transfer the help signal from the activated T clone to the B lymphocytes. Activation of the helper clone is performed by antigen-pulsed macrophages and cannot be achieved by the free soluble antigen. However, cell-free supernatant of the antigen-pulsed macrophages can stimulate the helper cells. Thus the antigenic determinant must be presented to the helper cell in the form of macrophage-processed antigen. These requirements for antigenic stimulation and the activity of the secreted helper factor demonstrate that the immortalized helper clone preserved the cellular components which control the antigen-specific immune function of the normal T lymphocyte.     

Regulation of T15 idiotype dominance. I. Mice expressing the xid immune defect provide normal help to T15+ B cell precursors

The immune response to phosphocholine (PC) in many strains of mice is dominated by the T15 idiotype family of anti-PC antibodies. By introducing the CBA/N X-linked immune defect (xid gene) into these mice, one profoundly alters their ability to make a T15-predominant, IgM anti-PC response. This loss of T15 dominance in mice expressing the xid gene is not due to the presence of suppressor T cells or the lack of T15 idiotype-specific helper cells in these mice. Thus, one can reconstitute a T15 idiotype-dominant response in immune defective mice with B cells from normal mice, and in adoptive transfer assays the primed T helper cells from immune-defective mice provide qualitatively the same help to normal B cells as the T helper cells from normal mice. T15 idiotype dominance appears to be controlled by the expression and activation of Lyb-5+ PC-specific B cells. Thus, the majority of T15+ B cell precursors are restricted to this B cell subset, whereas the Lyb-5- B cell subset contains predominantly T15-, anti-PC B cell precursors, which produce mainly IgG antibodies after activation by PC-containing antigens.     

Adaptive differentiation of murine lymphocytes. III. T and B lymphocytes display reciprocal preference for one another to develop optimal interacting partner cell sets.

Responses to the synthetic terpolymer L-glutanmic acid, L-lysine, L-phenylalanine (GLphi) and hapten derivatives thereof are controlled by two complementing H-2 linked Ir genes in the mouse. F1 hybrids derived from two different nonresponder strains (one of which possesses the alpha and the other beta Ir-GLphi gene) are phenotypic responders to GLphi and 2,4-dinitrophenyl (DNP)-GLphi. Moreover, spleen cells from DNP-GLphi-primed F1 mice can adoptively transfer secondary anti-DNP antibody responses to irradiate been challenged with DNP-GLphi. When, however, GLphi-primed F1 helper T cells are transfered together with the DNP-specific F1 B cells that had been primed in separate mice altogether by DNP coupled to an unrelated protein carrier, such mixtures failed to develop adequate adoptive secondary anti-DNP responses to DNP-GLphi. This contrasted with the ability of the same GLphi-primed F1 T cells to provide helper activity for DNP-primed B cells from responder recombinant B10.A (5R) mice. More important, the apparent defect of GLphi-primed F1 T cells in providing help for DNP-primed F1 B cells (primed to a DNP-protein conjugate) could be readily overcome by using DNP-primed B cells from donor F1 mice primed with DNP-GLphi. As discussed herein, these results suggest that interacting T and B lymphocytes pair off into partner cell sets, any pair of which interact optimally when a "best fit" reciprocal self-recognition occurs between them.     

Isotype specificity of antigen-specific helper clone in vivo

Inoculation of an immortalized clone of radiation leukemia virus (RadLV)-transformed antigen (ovalbumin, OVA)-specific T cells together with the relevant carrier (OVA) into unprimed syngeneic mice results in a preferential increase in the expression of anti-OVA antibodies of the immunoglobulin (Ig)G2b and IgG2a isotypes. Identical boosting of the clone-primed mice further augments the preferential production of anti-OVA antibodies of these two isotypes. The class-related helper activity is not due to nonspecific shift of class expression produced by the injected tumor cells, as a non-helper clone of RadLV-transformed T cells does not change the isotypic pattern of anti-OVA antibodies in the inoculated mice. A carrier-specific activation of the B cells is responsible for the class-restricted function of the helper clone. The isotypic profile of anti-hapten antibodies in mice injected with 2,4-dinitrophenyl (DNP)-bovine serum albumin and OVA-specific helper clone is not altered. On the other hand, mice inoculated with the OVA-specific helper clone and DNP-OVA respond with a preferential elevation of anti-DNP antibodies of the IgG2a and IgG2b isotypes. The preferential class augmentation may result from carrier-specific signals delivered by the helper clone which activate B cells in vivo toward certain CH expression. Alternatively, the observed class pattern may be induced by an isotype noncommited helper clone which triggers selected population of B lymphocytes of defined differentiation status toward secretion of a restricted array of isotypes. Regardless of the mechanism of the clone-dependent class expression, the isotypic profile in most of the experiments clearly demonstrates that an antigen-specific helper clone may be one of the elements which regulates the class of antibodies to be produced in vivo under normal physiologic conditions.     

Oligocellular mechanism in the production of antibodies: in vitro response to a haptenic determinant

Spleen explants from mice tolerant to rabbit serum albumin (RSA) failed to react in vitro to dinitrophenyl (DNP)-RSA; antibodies to DNP were, however, produced by such spleens, when stimulated with α-DNP-poly(Lys). To study the function of T and B cells in recognition of carrier determinants, spleen explants from X-irradiated mice, which had been inoculated with combinations of thymus and bone marrow cells from normal and from RSA tolerant donors, were tested for their reactivity in vitro to the DNP-RSA conjugate. A significant response was obtained only by spleens of mice containing bone marrow and thymus from normal donors. Spleens of mice treated with thymus from tolerant and bone marrow from normal or with thymus from normal and bone marrow from tolerant donors did not respond to DNP-RSA. The absence of the response to DNP-RSA by tolerant B cells combined with normal T cells was unexpected. It could not be attributed to binding of the tolerogen to B cells which would have prevented the interaction with T-cells. Neither could the result be attributed to an inhibition of normal cells by RSA-tolerant B-cells. θ-positive cells in the bone marrow are not the cells controlling the recognition of carrier determinants in the B population, since elimination of θ-positive cells did not affect the reactivity of spleens repopulated with B and T cells. Nor are bone marrow macrophages responsible for the lack of reactivity in spleens containing tolerant B cells, since normal macrophages did not restore reactivity. Hence, the production of antibodies to DNP is based on the recognition of carrier determinants not only by T cells, as previously established, but also by B cells. Whether this indicates a B-B in addition to the T-B cell cooperation is an inviting possibility.     

The role of hapten-reactive T lymphocytes in the induction of autoimmunity in mice. I. Establishment of the experimental conditions for the termination of immunological tolerance to human gamma globulin.

In order to study the role of hapten-reactive helper T cells in the induction of autoimmunity in mice, an attempt was made to establish an experimental model for the development of hapten-reactive helper T cells and the termination of immunological tolerance against heterologous proteins. Spleen cells taken from mice which were immunized with hapten-isologous protein conjugates (PAB-MGG) demonstrated helper activity for the anti-DNP antibody response of DNP-primed B cells responding to DNP and PAB-conjugated protein, but spleen cells from hapten-heterologous protein conjugate (PAB-HGG)-primed mice could not respond to PAB-determinant. Thus, hapten-reactive helper T cells can develop in mice by the immunization with hapten-isologous protein conjugate, but not with hapten-heterologous protein conjugate. However, spleen cells from mice which had been rendered tolerant by treatment with 2.5 or 0.2 mg of DHGG and then immunized with PAB-HGG could demonstrate helper activity responding to PAB-determinant. This helper activity was PAB-specific, because these spleen cells did not demonstrate helper activity if PAB-determinant was omitted in the primary and the secondary antigen. This helper activity was abrogated by the treatment of spleen cells with anti-θ serum and complement. Thus, hapten-reactive helper T cells were successfully induced by the challenge with hapten-heterologous protein conjugate in carrier-protein tolerant mice. When mice were treated with 2.5 or 0.2 mg of DHGG, no anti-HGG antibody response was induced by the challenge with HGG or PAB-HGG. However, the termination of HGG-tolerance was demonstrated only when the mice were preimmunized with PAB-MGG to raise PAB-rcactive helper T cells, treated with 0.2 mg of DHGG, and then challenged with PAB-HGG. This termination of immunological tolerance was not observed when the mice were preimmunized with PAB-BαA to raise PAB-specific B cells and anti-PAB antibody, or when the mice were treated with 2.5 mg of DHGG. Thus, if HGG-specific B cells remain intact in mice such as treated with low dose of DHGG, these B cells can be activated by some bypass mechanisms in the presence of PAB-reactive helper T cells through the PAB-determinant even in the absence of HGG-reactive helper T cells. These data clearly showed the role of hapten-reactive helper T cells in the termination of immunological tolerance and provide experimental supports to the hypothesis on the termination mechanism proposed by Weigle. The cellular mechanism for the development of hapten-reactive helper T cells in tolerant animals and the cellular mechanism of autoantibody production were discussed on the basis of T-B cell collaboration.     

Tolerance defects in New Zealand Black and New Zealand Black X New Zealand White F1 mice

The susceptibility of autoimmune NZB and (NZB X NZW)F1 mice to the induction of tolerance by monomeric BSA was compared with several normal mouse strains. Unresponsiveness in T and B lymphocyte compartments was probed by challenging with DNP8BSA and measuring anti-DNP and anti-BSA antibodies separately. Tolerance induced by monomeric BSA was carrier specific, and there was no evidence of epitope-specific suppression. Normal NZW, NFS, and B10.D2 mice were easily rendered tolerant with monomeric BSA and did not produce anti-DNP or anti-BSA antibodies after challenge with DNP8BSA. By contrast, the lack of anti-DNP antibody response in similarly treated NZB mice was dependent on the dose of monomeric BSA, indicating that the helper T cells were partially resistant to tolerance induction. NZB mice treated with a high dose of monomeric BSA produced anti-BSA, but not anti-DNP, antibodies after immunization. Thus, the anti-carrier B cells in NZB mice may have been primed by monomeric BSA. The presence of the xid gene on the NZB background rendered the mice susceptible to induction of tolerance, suggesting that the tolerance defect in NZB mice involves the B cell compartment. This abnormal antibody response was a dominant trait: (NZB X NFS)F1 and (NZB X B10.D2)F1 mice had the same characteristics as NZB mice. These F1 hybrids do not develop autoimmune disease, indicating that resistance to experimental tolerance induction expressed at a B cell level may not be sufficient for disease development. In contrast to NZB and other NZB F1 hybrids, (NZB X NZW)F1 hybrids treated with monomeric BSA and challenged with DNP8BSA responded to both DNP and BSA. The contribution of a B cell defect to the tolerance abnormality of (NZB X NZW)F1 mice was examined by analyzing the effect of the xid gene on the progeny of (NZB.xid X NZW)F1 mice. Unlike the effect of the xid gene on NZB mice, both phenotypically normal heterozygous female and phenotypically xid hemizygous male mice produced anti-DNP and anti-BSA antibodies after tolerance induction and immunization, demonstrating that a major helper T cell abnormality was present in (NZB X NZW)F1 mice. The (NZW X B10.D2)F1 hybrid was rendered tolerant by this procedure, indicating that the helper T cell defect (NZB X NZW)F1 mice may have resulted from gene complementation with the NZB mice contributing partial resistance of T helper cells to tolerance induction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Helper T cell interactions.

Studies of the relationship between carrier-primed helper T cell dose and the antibody response to a hapten on that carrier reveal evidence for two synergistic T helper cells. One of these two T cells is absent in agammaglobulinemic mice. This finding is not due to suppression; instead, T helper cells from these mice interact synergistically with T helper cells from normal mice, as would be predicted if two populations of cells are present in normal mice, while only one is present in the agammaglobulinemic mice. These findings, taken together with studies in similar systems, suggest that one of the two T helper cells recognizes immunoglobulin on B cells, while the other is specific for carrier. It remains to be determined whether both cells show the phenomenon of major histocompatibility complex restriction, or whether this a property of one of the cells only. It is also not clear whether the Ig-recognizing T cell is also carrier specific, or whether its apparent carrier specificity in this system reflects an ability of the carrier to bring together Ig and an I region gene product into a unique configuration on the B cell surface.     

Induction of human immunoglobulin secretion. II. T lymphocyte dependency and radiosensitivity of T-cell help for induction of B-cell differentiation by Staphylococcus aureus strain Cowan I

The induction of peripheral blood B lymphocytes to mature to immunoglobulin-secreting cells (ISC) when stimulated by Staphylococcus aureus strain Cowan I was found to be T helper cell-dependent (J. Immunol.127, 1044, 1981). The nature of T help was studied in B- and T-cell separation and reconstitution experiments. T helper cells for Cowan I were very radiosensitive (D₃₇ < 500 rad) in comparison to helpers for pokeweed mitogen (PWM) (D₃₇ > 2000 rad). PWM synergized with Cowan I in induction of ISC, and helper T cells for dual stimulation were also radioresistant. The ratio of T to B cells was found to be critical in judging reactivity of donors for both PWM and Cowan I. T cells stimulated with PWM, but not Cowan I, produced T cell-replacing factors essential for Cowan I-induced maturation of B cells. Irradiation of T cells prior to PWM stimulation increased the level of such helper factors. Poor responders to Cowan I, as judged by mononuclear cell cultures, had apparently few helpers for the bacterial stimulant, compared to high responders. Cowan I helper T-cell activity did not appear to be due to protein A leaking from the bacteria and stimulating T cells. In all these experiments, induction of ISC by Cowan I was completely dependent on T cells or factor, providing a good model for investigation of B-cell differentiation regulated by a unique subset of radiosensitive T helper cells.     

Idiotope antigens (Ab2 alpha and Ab2 beta) can induce in vitro B cell proliferation and antibody production

We previously showed that immunization of various strains of mice with three types of antigen--PC-Hy (nominal antigen), F6-Hy (Ab2 alpha-Hy, and 4C11-Hy (Ab2 beta-Hy)--induces a differential PC-specific, T15-Id+ antibody response. In this report, the in vitro phosphorylcholine (PC)-specific B cell responses induced by these three antigens were studied. A hemocyanin-specific long-term T helper cell line was used to provide help for primary and secondary in vitro T cell-dependent B cell responses. At low doses (0.005 to 0.5 micrograms/ml) of antigen, a significant increase in the proliferation of PC-OVA-primed BALB/c B cells was observed with Ab2-Hy or PC-Hy conjugate, but not unconjugate, antigens. Similar low doses of antigen could stimulate naive B cells to secrete IgM and stimulate PC-OVA- or 4C11-Hy-primed B cells to secret IgM and IgG1 anti-PC antibodies. The percentage of T15-Id of the PC-specific antibodies produced in the in vitro T-B culture was found to be less dominant than that produced by in vivo immunization, suggesting that certain regulatory mechanisms occur in the in vivo environment that may help to maintain the T15-Id dominance. Taken together, our in vivo and in vitro results indicate that idiotope antigens can function like nominal antigens to induce antigen-specific B cell responses. The mechanisms of thymic-dependent B cell activation induced by idiotope and nominal antigen are similar in that the T-B interaction is MHC-restricted and requires cognate recognition.     

Memory CD4 T cells that express CXCR5 provide accelerated help to B cells

CD4 T cell help for B cells is critical for effective Ab responses. Although many of the molecules involved in helper functions of naive CD4 T cells have been characterized, much less is known about the helper capabilities of memory CD4 T cells, an important consideration for the design of vaccines that aim to prime protective memory CD4 T cells. In this study, we demonstrate that memory CD4 T cells enable B cells to expand more rapidly and class switch earlier than do primary responding CD4 T cells. This accelerated response does not require large numbers of memory cells, and similar numbers of primary responding cells provide less effective help than do memory cells. However, only memory CD4 T cells that express the B cell follicle homing molecule, CXCR5, are able to accelerate the response, suggesting that the rapidity of the Ab response depends on the ability of CD4 memory T cells to migrate quickly toward B cells.     

Effect of histidine residues in antigenic sites on pH dependence of immuno-adsorption equilibrium

Summary Polyclonal anti-myoglobin antibodies were fractionated into five subpopulations directed against five specific antigenic sites, respectively. The equilibrium characteristics of each subpopulation and orginal anti-myoglobin immobilized to CNBr-activated Sepharose 4B were compared. The four subpopulations of antibodies lost their binding abilities at around pH 4.5 because of the conformational changes of myoglobin. However, the subpopulation directed against the region containing three histidine residues dissociated with the antigenic site at higher pH, and such equilibrium characteristics were considered to be caused by the dissociation characteristics of histidine residues. Therefore, the effects of histidine modification in BSA on the adsorption capacities of original anti-BSA antibody and a pH sensitive fraction of it were compared. The adsorption capacity of the pH sensitive fraction showed greater decrease than that of original antibody by histidine modification in BSA. These results imply that the antigenic sites in which histidine residues play an important role for the binding to antibodies show equilibrium characteristics sensitive to pH.     

In vivo activity of affinity-purified helper factor from antigen-specific helper clone

Supernatant from culture of a virally transformed OVA-specific helper T clone (C-41) was examined for the presence of soluble helper factor. Inoculation of helper clone supernatant into DNP-KLH-primed mice enhanced the IgG anti-DNP response when given with DNP-OVA. The C-41 supernatant did not trigger the DNP-primed B cells in mice when injected with hapten (DNP) coupled to an unrelated carrier (BSA). The carrier-dependent helper activity of C-41 supernatant in vivo demonstrates the presence of an antigen-specific T helper factor in the media of the cultured helper clone. Extensive immunization of F1(C57BL X BALB/c) mice with the helper clone resulted in the production of anti C-41 antibodies. Monoclonal antibodies prepared from the immunized mice were screened for specificity of binding to other transformed T lines and clones, some specific to OVA. Monoclonal antibodies that stained the C-41 cells exclusively were considered clone-specific. Supernatants of the helper clone were passed over columns of anti-clone-specific antibodies. The eluates from three antibodies were active as antigen-specific helper factor, i.e., they elevated the IgG anti-DNP response in vivo in a linked recognition fashion in the presence of DNP-OVA. The affinity-purified factor was inactive when injected with DNP-BSA or DNP-BSA + OVA. Thus, we describe the antigen-specific immune function of a clone-produced helper factor in normal mice.     

Mapping the idiotopes of a monoclonal anti-myoglobin antibody with syngeneic monoclonal anti-idiotypic antibodies: detection of a common idiotope

A panel of syngeneic monoclonal anti-idiotypic antibodies was prepared by immunizing A.SW mice with keyhole limpet hemocyanin-coupled A.SW monoclonal anti-myoglobin (HAL 19, IgG1) and screening the cloned hybridomas for production of IgG2 binding to idiotype but not to certain other anti-myoglobin antibodies of the same subclass in an ELISA. With these antibodies, we identified three nonoverlapping idiotopes, based on three clusters of monoclonal anti-idiotopes that mutually inhibit within each cluster, but not between clusters (Cluster I: S2, S6, S8; Cluster II: S5, S7; Cluster III: S9). Only Cluster II antibodies block the binding of myoglobin to HAL 19 and so identify a binding site-related idiotope(s). Binding of both Cluster II monoclonals (S5 and S7) to Hal 19 is inhibited by a rabbit anti-idiotype that we previously reported detects a common cross-reactive anti-myoglobin idiotope in immune sera. However, only one of these, S7, and not S5, identifies an idiotope that is present on 20 to 30% of A.SW anti-myoglobin antibodies in immune sera and ascites. The panel of syngeneic monoclonal anti-idiotype antibodies also detects new idiotopes not detected by the rabbit anti-idiotype. The development of a panel of syngeneic monoclonal anti-idiotypic antibodies to different clusters of idiotopes on the same antibody molecule, including one that identifies a major common idiotope in immune sera, should allow the analysis of possible idiotype network regulation in vivo and in vitro in a completely syngeneic system.