Fine specificity of the H-2 linked immune response gene for the gallinaceous lysozymes

Siglecs induce tolerance to cell surface antigens by BIM-dependent deletion of the antigen-reactive B cells

Infusion of blood cells from a donor can induce humoral tolerance in a recipient and increase the probability of successful organ transplant, a clinical method defined as donor-specific transfusion (DST). Despite the clinical success of DST, the immunological mechanisms by which blood cells displaying a foreign Ag induce tolerance remain poorly understood. Based on recent findings showing that the B cell siglecs, CD22 and Siglec-G, can promote tolerance to Ags presented on the same surface as their ligands, we speculated that the B cell siglecs are key players in tolerance induced by DST. Using a variety of chemical and genetic approaches, we show that the B cell siglecs mediate tolerance to cell surface Ags by initiating an inhibitory signal that culminates in elimination of the Ag-reactive B cell. CD22 and Siglec-G are recruited to the immunological synapse by sialic acid ligands on the Ag-bearing cells, producing a tolerogenic signal involving Lyn and the proapoptotic factor BIM that promotes deletion of the B cell and failure of mice to develop Abs to the Ag upon subsequent challenge. We speculate that this tolerogenic mechanism is a contributing factor in DST and a mechanism of peripheral B cell tolerance to cell surface autoantigens.

Hock immunization: a humane alternative to mouse footpad injections

Footpad injection is a commonly used immunization method in mice. Being relatively easy to do with well-characterized lymphatic drainage, it has become a very useful immunization protocol to study local immune responses in draining lymph nodes. However, its disadvantages include use of only hind feet as a routine site of immunization since mice use their fore feet for food handling, and exacerbation of inflammation and swelling at the injection site leading to unrelieved pain and distress since feet are weight-bearing structures. With increasingly stringent Institutional guidelines for animal manipulations, there is increasing need for more humane protocols. A novel immunization protocol involving injection into the hock, the lateral tarsal region just above the ankle, a non-weight bearing structure draining to the same lymph node as the footpad, retains the advantages of footpad immunization without its drawbacks. This study, comparing immune responses between footpad and hock immunization in six different inbred mouse strains to two different protein antigens and a heat-killed bacterium, shows that hock immunization is a better alternative to footpad immunization, inducing comparable immune responses and being considerably more humane.

The study of high-affinity TCRs reveals duality in T cell recognition of antigen: specificity and degeneracy

TCRs exhibit a high degree of Ag specificity, even though their affinity for the peptide/MHC ligand is in the micromolar range. To explore how Ag specificity is achieved, we studied murine T cells expressing high-affinity TCRs engineered by in vitro evolution for binding to hemoglobin peptide/class II complex (Hb/I-Ek). These TCRs were shown previously to maintain Ag specificity, despite having up to 800-fold higher affinity. We compared the response of the high-affinity TCRs and the low-affinity 3.L2 TCR toward a comprehensive set of peptides containing single substitutions at each TCR contact residue. This specificity analysis revealed that the increase in affinity resulted in a dramatic increase in the number of stimulatory peptides. The apparent discrepancy between observed degeneracy in the recognition of single amino acid-substituted Hb peptides and overall Ag specificity of the high-affinity TCRs was examined by generating chimeric peptides between the stimulatory Hb and nonstimulatory moth cytochrome c peptides. These experiments showed that MHC anchor residues significantly affected TCR recognition of peptide. The high-affinity TCRs allowed us to estimate the affinity, in the millimolar range, of immunologically relevant interactions of the TCR with peptide/MHC ligands that were previously unmeasurable because of their weak nature. Thus, through the study of high-affinity TCRs, we demonstrated that a TCR is more tolerant of single TCR contact residue substitutions than other peptide changes, revealing that recognition of Ag by T cells can exhibit both specificity and degeneracy.

Epitope-dependent inhibition of T cell activation by the Ea transgene: an explanation for transgene-mediated protection from murine lupus

A high level expression of the Ea(d) transgene encoding the I-E alpha-chain is highly effective in the suppression of lupus autoantibody production in mice. To explore the possible modulation of the Ag-presenting capacity of B cells as a result of the transgene expression, we assessed the ability of the transgenic B cells to activate Ag-specific T cells in vitro. By using four different model Ag-MHC class II combinations, this analysis revealed that a high transgene expression in B cells markedly inhibits the activation of T cells in an epitope-dependent manner, without modulation of the I-E expression. The transgene-mediated suppression of T cell responses is likely to be related to the relative affinity of peptides derived from transgenic I-E alpha-chains (Ealpha peptides) vs antigenic peptides to individual class II molecules. Our results support a model of autoimmunity prevention based on competition for Ag presentation, in which the generation of large amounts of Ealpha peptides with high affinity to I-A molecules decreases the use of I-A for presentation of pathogenic self-peptides by B cells, thereby preventing excessive activation of autoreactive T and B cells.

Burst-enhancing role of the IgG membrane tail as a molecular determinant of memory

The basis of immune memory leading to heightened secondary antibody responses is a longstanding unanswered issue. Here we show that a single irreversible molecular change in the B cell antigen receptor, which is brought about by immunoglobulin M (IgM) to IgG isotype switching, is sufficient to greatly increase the extrafollicular proliferative burst of antigen-specific B cells. The unique membrane-spanning regions of IgG do not alter the T cell-dependent activation and proliferation of antigen-specific B cells in vivo, but markedly increase the number of progeny cells and plasmablasts that accumulate. These results establish a key molecular determinant of immunological memory and define an unexpected cellular basis by which it enhances the magnitude of secondary antibody responses.

Principles of transcutaneous immunization using cholera toxin as an adjuvant

Transcutaneous immunization is a novel strategy for immunization employing topical application of antigen and adjuvant to the skin surface and resulting in detectable antigen/adjuvant specific IgG in plasma and mucosal secretions. In this study we show that transcutaneous immunization with cholera toxin (CT) as an adjuvant can be used in several inbred mouse strains with varying H-2 major histocompatibility complex genes (C57BL/6 (H-2(b)), BALB/c (H-2(d)), and C3H (H-2(k))). Although the primary anti-CT antibody responses reflected previously described MHC restriction patterns for this protein, the differences were overcome after two booster immunizations. Potent antibody responses against hen egg lysozyme and/or diphtheria toxoid were observed using CT as adjuvant. We also demonstrate that the unshaved dorsal or ventral surface of the ear can be effectively used for transcutaneous immunization and that gentle swabbing with alcohol increases the magnitude of the host immune response. Together these data further our understanding of the principles governing this new platform technology and support its integration into novel and existing human vaccine strategies.

Intestinal immunization of mice with antigen conjugated to anti-MHC class II antibodies

We have explored a new technique for immunization of the intestinal tract of mice, using protein antigens bound to antibodies with specificity for murine MHC class II molecules (MHC-II). Either of two protein antigens, hen avidin (AV) or hen egg lysozyme (HEL) were covalently conjugated to anti-MHC-II antibodies and the purified conjugates were given orally (p.o.) or by direct intraduodenal (i.d.) injection into the intestinal lumen of mice. A secondary immunization p.o. with the same conjugate or with the non-conjugated antigen in the presence of cholera toxin (CTX) resulted in production of both intestinal secretory IgA and serum IgA antibody by those mice. In addition, serum IgG antibodies were produced. Conjugates with appropriate MHC-II specificity targeted the antigen because they induced more IgA and IgG antibody than conjugates with irrelevant antibody specificity or antigen alone, and because they induced antibody in mice that were genetic low responders to antigen. The results indicate the feasibility of oral subunit type vaccines with antibody targeting technology.

Participation of nitric oxide in mouse anaphylactic hypotension

Mouse hen egg-white lysozyme-specific anaphylaxis was estimated by monitoring changes in blood pressure by using a tail-cuff method. Stimulation of histamine H1 receptors of the vascular endothelium was suggested to be critical for mouse anaphylactic hypotension, because pretreatment with diphenhydramine but not with cimetidine completely inhibited the hypotension. Nitric oxide (NO) was indicated to play an important role in mouse anaphylaxis, because NG-nitro-L-arginine methyl ester, a NO synthase inhibitor, significantly blocked the hypotension while a large amount of L-arginine, a precursor of NO synthesis, restored the hypotension.

High and low responsiveness to vaccines in farm animals

Low responsiveness in some farm animals is emerging as a problem in the application of newly developed vaccines which operate at skin surfaces and mucous membranes. Breeding for resistance to specific diseases seems to be associated with breeding for specific immune responsiveness in farm animals and very likely this involves selection for major histocompatibility complex (MHC) haplotype. However, other factors contribute to low responsiveness and these include poor nutrition, sire effects, antigenic competition and inadequate effector mechanisms. The future of newly developed vaccines will rest on the solution to the low responder problem, and once solved, the application of these vaccines will be fully utilized for disease control in farm animals.

The distinctive specificity of antigen-specific suppressor T cells

Although suppressor T cells have been cloned in only a few instances, the existence of a functional cadre of T cells that acts to downregulate the immune response is well documented. In this review Eli Sercarz and Urszula Krzych describe studies on suppressor T-cell (TS-cell) specificity that provide some support for the conclusion that the TS cell is a distinctive cell type with an expressed repertoire that is different from that expressed by helper T (TH) cells. They go on to explore the interaction between cells recognizing TS-cell-inducing determinants (SDs) and TH-cell-inducing determinants (HDs), and their relationship to immunogenicity and Ir gene effects.

Role of the first external domain of I-A beta chain in immune responses and diabetes in non-obese diabetic (NOD) mice

Diabetes in the non-obese diabetic (NOD) mouse is a multigenic autoimmune disease and is possibly controlled by three recessive loci, including one that is linked to the major histocompatibility complex (MHC). The first external domain of the Class II MHC I-A beta chain in these mice is unique and has been suggested as being responsible for autoimmunity. The I-A alpha chain in these mice is I-A alpha d, and they lack the expression of I-E molecules. We have investigated immune responses to various Ir gene control antigens in NOD mice to determine the influence of the NOD Ia and particularly the I-A beta chain. We find that sheep insulin is highly immunogenic while other insulins are weakly immunogenic in these mice. Hen egg lysozyme, pigeon cytochrome C and the synthetic polypeptide Poly 18, Poly EYK(EYA)5 antigen produce good antibody responses. Apart from H-2d, NOD are the only mice where Poly 18 antigen is immunogenic. In these mice Poly 18 induced good T-cell proliferative response, which was inhibited by anti-Ia antibody, and the mice were able to respond to tyrosine-containing polypeptide Poly EYA but not to the phenylalanine-containing antigen Poly EFA. We also found that synthetic peptide 48-60 of the NOD I-A beta chain is highly immunogenic in syngeneic NOD mice both for T cells and B cells. Using an I-A beta chain-specific monoclonal antibody, we are able to prevent induction of diabetes when the antibody was administrated in prediabetic, young mice. Our results suggest that the immune response to various antigens and autoimmune diabetes in NOD mice is directly influenced by the I-A beta chain.

Enhanced antigen immunogenicity induced by bispecific antibodies

The binding of protein antigens to APC with heterocrosslinked bispecific antibodies (HBAs) enhances their processing and presentation to Th cells in vitro. Here we have asked whether HBAs could also increase immune responses in vivo. We immunized mice with hen egg lysozyme (HEL) in the presence or absence of HBA, and followed antibody production after the primary challenge and after a secondary boost. We found that HBAs that bind antigen to MHC class I or II molecules, to Fc gamma R, but not to surface IgD, enhance the immunogenicity of HEL. HBAs that bound HEL to MHC class II molecules, for examples, decreased the amount of antigen required to elicit a primary anti-HEL antibody response in mice by 300-fold, and the amount required to prime for a secondary response by 10(3)- to 10(4)-fold. In fact, HBAs were as effective as IFA in generating antibody responses. Since adjuvants cannot be used in humans, HBAs could prove useful for immunizing people, especially in cases where, due to scarcity or toxicity, minute doses of antigen must be used.

T-lymphocyte specificity differences to horse cytochrome c in different lymphoid cell compartments

T-lymphocyte proliferative responses were determined with peripheral blood lymphocytes (PBL), peritoneal exudate lymphocytes (PEL) and lymph node lymphocytes (LNL) of guinea pigs immunized with horse cytochrome c (HCytc). The proliferative response of PBL activated by peptide 81-104 from animals immunized with HCytc was equal to or better than HCytc while the proliferative response activated by peptide 1-65 was small and no reactivity was seen when peptide 66-80 was tested. In contrast, the proliferative responses of PEL and LNL stimulated by peptide 1-65 approached those activated by HCytc, while peptide 81-104 was far less effective. The differences in the proliferative responses of PBL and PEL activated by peptide 81-104 and peptide 1-65 suggest that different lymphoid compartments may have T-cells directed to different T-cell epitopes displayed on the same antigen. The possible roles of different T-cell clones, antigen processing, and differential induction of suppressor cells are discussed in relation to these findings.

An adjunct trait of HEL/I-Ab-specific T helper cell is sensitivity to antigen-specific immunosuppression

The present study tests whether the specific inhibition of helper T (Th) cell (and T hybridomas) by suppressor T (Ts) cells is a phenotypic trait of Th cells correlating with their acquired specificity for antigen/major histocompatibility complex or a genotypic trait not related to selection of the T cell repertoire for antigen. To do this we took advantage of the fact that H-2d parental strains of mice commonly restrict recognition of chicken egg-white lysozyme to the L3 peptide (a.a. 105-129) and H-2b parental mice to the L2 peptide (a.a. 13-105). F1 hybrids of these strains display two subsets of lysozyme-reactive T cells, one for each parental phenotype. Using (B10 X B10.D2)F1 mice reconstituted with B10.D2 bone marrow, we were able to develop genetic H-2d T cell clones that could express an atypical specificity, that is L2/I-Ab. Clones of this type, like genetic H-2b, are also sensitive to the inhibiting effects of HEL-activated Ts cells. To overcome some of the drawbacks of using heterogeneous populations of T, B and accessory cells in our assays, we constructed T hybridomas from HEL-immune, chimeric lymph node T cell blasts which respond to a unique antigen/major histocompatibility complex with production of the lymphokine interleukin 2. Our results indicate that all HEL/I-Ab-specific T cells (helper and hybridomas) are inhibited by suppression regardless of the T cell's haplotype at the H-2 locus: H-2b (B10), H-2d (D2) or H-2b,d (BDF1). Furthermore, there is a strict correlation between the antigen and I-A specificity: I-Ab-restricted T cells recognize non-L3 determinants even though some are derived from H-2d mice.

Limiting dilution comparison of the repertoires of high and low responder MHC-restricted T cells

To approach the mechanism that determines Ir gene-controlled high or low responsiveness to whole proteins, such as sperm whale myoglobin (SWMb), we compared the repertoires of high and low responder haplotype-restricted T cells for different myoglobin epitopes by limiting dilution frequency analysis. Poisson analysis was performed using long-term limiting dilution cell lines of (B10.BR [low] X B10.D2[high])F1 T cells maintained on high or low responder APCs. The cell lines were tested with SWMb peptides and fragments for T cell repertoire fine specificities and Ia restrictions. The frequency of SWMb-specific F1 T cells responsive on B10.BR (H-2k) APCs was 2.5-3.6-fold lower than on B10.D2 (H-2d) APCs. Strikingly, all of the H-2k-restricted T cells used I-Ek as a restriction element, whereas both I-Ad- and I-Ed-restricted T cells were found among the H-2d-restricted lines. The I-Ad-restricted T cells were dominant, and the majority was specific for the synthetic peptide 102-118. T cells specific for peptide 132-146, dominant in association with I-Ed, were less frequent. However, no detectable H-2k-restricted T cells were specific for either of these peptides, but instead they were specific for fragment 1-55 or peptide 59-80. Fragment 1-55 also stimulated a similar number of H-2d-restricted T cells. Therefore, the low response of F1 T cells on H-2k-presenting cells may be due to the failure to see myoglobin plus I-Ak, in particular the immunodominant site around Glu 109, in contrast to the dominant response of high responder mice (both H-2d and H-2s) focused on the I-A molecule and the site around residue Glu 109. The I-E- low responder B10 strain also failed to respond to peptide 102-118, supporting the idea that the low responder status results from a limited repertoire lacking response to 102-118 plus I-A. In those strains that respond to the immunodominant site 102-118, the frequency of T cells in the repertoire specific for this site was always considerably greater than that for other sites. These results suggest that there is an important difference between immunodominant epitopes and minor epitopes and that Ir gene-controlled low responsiveness to a natural whole protein may be due primarily to the failure to respond to a single immunodominant site, even though a number of other epitopes can be recognized.

Suppression of the delayed-type hypersensitivity response to hen egg white lysozyme (HEL) by HEL peptides in a genetically high-responder mouse strain: evidence for requirement of the loop structure for induction of suppressor T cells

The delayed-type hypersensitivity (DTH) response of C3H/HeN mice to hen egg white lysozyme (HEL) can be blocked by a single iv injection of a solution of HEL in buffered saline 7 days before sensitization of animals with HEL in complete Freund's adjuvant (CFA). The minimal structure of HEL required for the suppression was examined by determining the abilities of various HEL-derivative peptides to inhibit HEL-DTH. Treatment of normal mice with Ploop I X II, sequence 57-107 (Cys64-Cys80, Cys76-Cys94), or P17 (sequences 1-27 and 123-129 linked by Cys6-Cys127) 7 days before immunization with HEL resulted in marked suppression of the DTH response. This inhibition of DTH involved generation of suppressor T cells (Ts). The results suggested that two suppressor pathways are involved. These data, together with another recent finding (1) that an entirely different portion of HEL is a suppressor determinant (SD) in A/J mice, indicate that different epitopes act as SDs in different strains of mice. Of the loop region peptides tested, Plc (intact loop I joined to a linear peptide, residues 84-97) was found to be the minimum structure capable of suppressing the HEL-DTH response; loop I or II alone did not cause suppression. Activation of Ts cells by the loop peptide depended on its conformational structure; completely reduced and carboxymethylated Ploop I X II did not cause suppression.

Analysis of lysozyme-specific immune responses by synthetic peptides. I. Characterization of antibody and T cell-mediated responses to the N-terminal peptide of hen egg-white lysozyme

The immunological reactivity against the N-terminal region of hen egg-white lysozyme (HEL) has been investigated by a synthetic peptide (PHEL) comprising residue 1-18 of HEL and by an analogue peptide (PREL) in which phenylalanine at position 3 is substituted by tyrosine. Both peptides are immunogenic in (C57BL/10 X DBA/2)F1 mice genetically responder to HEL. In C57BL/6 mice, genetically nonresponder to HEL, PREL induces anti-peptide antibodies that also bind to PHEL whereas PHEL is not immunogenic. Thus, a single amino acid substitution in a synthetic peptide converts a nonresponder mouse strain into a responder one. Anti-PHEL antibodies demonstrate a higher binding to HEL than anti-PREL antibodies, indicating that phenylalanine at position 3 is important for induction of anti-peptide antibodies able to recognize native HEL. At the T cell level the two peptides show very high bidirectional cross-reactivity between themselves and with HEL for interleukin 2 production, antigen-specific proliferation and delayed-type hypersensitivity response, whereas conservation of phenylalanine at position 3 is required for induction of suppressor cells cross-reactive with HEL. This indicates that the N-terminal region of HEL contains epitope(s) able to induce the same level of helper T cell activity as the native HEL molecule. However, helper T cells do not discriminate between PHEL and PREL whereas phenylalanine at position 3 is critical for HEL-specific suppressor T cell induction.

Immunoregulation of lysozyme-specific suppression. I. Induction and suppression of delayed-type hypersensitivity to hen egg-white lysozyme

Subcutaneous immunization with hen egg-white lysozyme (HEL) in complete Freund's adjuvant induces, both in antibody responder and nonresponder mice, a classical delayed-type hypersensitivity (DTH) reaction evaluated as footpad swelling. This response can be specifically transferred to naive recipients by Lyt-1+2- T cells and passive transfer is restricted by genes mapping in or to the left of the I-A region of the H-2 complex. Fine antigenic specificity analysis shows that HEL-primed T cells mediating DTH recognize ring-necked pheasant egg-white lysozyme, a lysozyme closely related to HEL, but fail to respond to human lysozyme, differing from HEL at 40% amino acid residues. Complete cross-reactivity between native and denaturated (reduced and carboxymethylated) HEL is exhibited by T cells involved in the DTH response. Subcutaneous injection of HEL coupled to spleen cells is also able to induce antigen-specific and genetically restricted DTH responses whereas the same cells administered by i.v. or i.p. route induce predominantly suppressor T cell activation. These suppressor T cells specifically inhibit the induction phase of DTH reactivity to HEL.

Differential induction of help and suppression in mice by bifunctional antigens administered via different routes

Bifunctional antigens composed of one L-tyrosine-p-azobenzenearsonate (Tyr-ABA) carrier epitope and one dinitrophenyl (DNP) haptenic epitope separated by 6-aminocaproyl or polyprolyl spacers induced weak IgM anti-DNP plaque-forming cell (PFC) responses in the spleens of mice immunized intraperitoneally, without detectable IgG PFC. However, the same antigens introduced into the footpads induced IgG PFC responses in the draining lymph nodes which rose to levels greater than 100/10(6) viable lymphocytes. Moreover, the response in the lymph nodes to booster injections of antigen was characteristic of secondary T-dependent antibody responses, whereas the splenic secondary response simply mirrored the primary. The magnitude of the IgG PFC response was influenced by the size of the spacer and by the strain of mice, although genetic control did not map to the major histocompatibility complex. Prior i.p. immunization suppressed the IgG response to subsequent immunization in the footpads. This suppression could be transferred to normal syngeneic recipient mice with spleen cells from suppressed donors. Suppressor activity was eliminated by treating the spleen cells with anti-Thy-1 antibody prior to transfer, establishing the T-cell dependency of suppression. Suppression was also induced by Tyr-ABA itself, but not by DNP-lysine, indicating the epitope specificity of the suppressor cells. Thus, bifunctional antigens induce dominant suppression in the spleen but significant help in lymph nodes.

Immunodominant protein epitopes. I. Induction of suppression to hen egg white lysozyme is obliterated by removal of the first three N-terminal amino acids

The lack of response to hen egg white lysozyme (HEL) by C57BL (H-2b) mice has been demonstrated previously to be related to the induction of suppressor T (Ts) cells which recognize the amino terminal region of HEL. In this report, the nature of the protein determinant required for Ts cell induction is more precisely detailed using des-1,2,3-HEL (AP-HEL) prepared with an aminopeptidase purified from Aeromonas proteolytica . Remarkably, the removal of just these three amino acids obliterates the ability of HEL to induce Ts cells specific for HEL. Additionally, in contrast to HEL, AP-HEL is able to prime for an in vitro T cell proliferative response to either AP-HEL or HEL. Thus, removal of a very limited region of a protein antigen can drastically alter its immunogenic properties.

Genetic regulation of the immune response to hepatitis B surface antigen (HBsAg). IV. Distinct H-2-linked Ir genes control antibody responses to different HBsAg determinants on the same molecule and map to the I-A and I-C subregions

We have previously demonstrated that the murine humoral immune responses to the group-specific a and subtype-specific d/y determinants of hepatitis B surface antigen (HBsAg) are controlled by H-2-linked immune response (Ir) genes. High responder (H-2d,q), intermediate responder (H-2a greater than b greater than k) and nonresponder (H-2f,s) haplotypes have been identified (8, 9). The kinetics and specificity of in vivo antibody production after HBsAg immunization in congeneic, H-2-recombinant strains was analyzed to further define relevant Ir genes and their influence on the immune response to distinct antigenic determinants. These studies indicate that the humoral anti-HBs response is regulated by at least two Ir genes, one in the I-A subregion (Ir-HBs-1) and one in the I-C subregion (Ir-HBs-2) of the murine H-2 complex. Ir-HBs-1 regulates the primary responses to all HBsAg determinants, whereas the influence of Ir-HBs-2 is determinant specific, affecting the responses to the d or y determinants. The anti-a response is regulated exclusively by Ir-HBs-1. Strains possessing only the Ir-HBs-2 gene [B10.S(9R) and B10.HTT] produce no anti-a response and a subtype-specific antibody response is detected only after secondary or tertiary immunization. In contrast, the influence of Ir-HBs-2 in the presence of Ir-HBs-1 is detected upon primary immunization and is additive rather than exclusive. There is also suggestive evidence that the presence of the Ek molecule, at least in the context of I-Ak, may have a suppressive influence on the anti-HBs response. Additionally, HBsAg-specific, T cell proliferative responses were H-2 restricted and the kinetics and specificity of T cell proliferative responses paralleled in vivo antibody production. These data indicate that, although the I-A subregion exerts a dominant influence, distinct Ir-HBs genes, mapping in separate I subregions, control immune responses to alternate HBsAg determinants on the same protein molecule.

The expressed lysozyme-specific B cell repertoire. I. Heterogeneity in the monoclonal anti-hen egg white lysozyme specificity repertoire, and its difference from the in situ repertoire

A panel of closely and distantly related lysozymes and lysozyme-peptide fragments were utilized in assessing the specificity repertoire of murine anti-hen egg white lysozyme hybridomas. The 44 monoclonal antibodies could be divided into a minimum of 18 fine specificity groups in tests using the lysozyme panel. Two hybridoma products were specific for epitopes containing amino acids 68 and 121, respectively; and another was specific for an epitopes containing amino acids 113-114. Several hybridomas demonstrated unique heteroclitic binding, for example, to bob-white lysozyme (BEL), but not other closely related lysozymes, suggesting lysine at position 68 in BEL as an important residue of recognition. Radioimmunoassay using lysozyme peptides bound to plastic plates specified the regional specificity of 6 additional antibodies of the 44. A comparison of the specificities of monoclonal antibodies with antibody produced in vivo showed some major differences suggesting that those cells proceeding on to antibody formation in the regulatory milieu of the whole animal are a selected subpopulation.

Selective reversal of H-2 linked genetic unresponsiveness to lysozymes. I. Non-H-2 gene(s) closely linked to the Ir-2 locus on chromosome 2 permit(s) an antilysozyme response in H-2b mice

Genes outside of the mouse major histocompatibility complex (H-2) were found to be capable of specifically reversing the previously described nonresponsiveness to hen egg-white lysozyme (HEL) owing to H-2b immune response (Ir) genes. C3H.SW, BALB.B, and C57L, all of the H-2b haplotype, showed responsiveness to HEL, but not to human lysozyme (HUL). Mapping of the reversing gene(s) was attempted by testing H-2b recombinant inbred (RI) strains of mice carrying C3H, BALB, and C57L non-H-2 genes. Analysis of the strain distribution pattern of responsiveness with both CXB and BXH RI strains was consistent with the location of the responsible site within the H-3 region on chromosome 2. The anti-HEL proliferative responsiveness in two H-3 congenic strains of mice, B10.C(28NX)SN and B10.C-H-3cH-3a, that have BALB/c genes within the H-3 region confirmed the mapping, as well as localized the reversing gene(s) near the Ir-2 gene. The data are discussed with regard to the site of expression of the reversing gene(s) and its mechanism of action.

Monoclonal suppressor T-cell factor displaying V H restriction and fine antigenic specificity

The production of stable T-cell clones is essential for the study of T-cell-derived, specific immunoregulatory products and of specific T-cell receptors. T-cell clones have been established by radiation leukaemia virus (RadLV)-induced transformation of suppressor T lymphocytes specific for hen egg white lysozyme (HEL). We report here that culture supernatant obtained from these T-cell clones can, when injected into mice, specifically suppress the anti-HEL antibody response. This monoclonal T-cell product suppresses the antibody response induced by HEL and human lysozyme, but not that induced by ring-necked pheasant egg white lysozyme (REL), thus displaying fine antigenic specificity probably restricted to an epitope involving phenylalanine at amino acid residue 3, present in the N-terminal region of HEL and shared by human lysozyme but absent in REL. The suppression induced by this monoclonal T-cell product is restricted by both H-2 and Igh-1 genes whereas anti-HEL antibodies bearing a predominant idiotype are induced in all mice strains tested, irrespective of their H-2 haplotype or Igh-1 allotype.

H-2-determined kinetic differences for the induction of nucleoside-specific suppression

The kinetic and the H-2 requirements for the induction of nucleoside-specific suppression were examined in several strains of mice; specifically, whether adenosine (A)-coupled spleen cells given intravenously suppress the primary response to adenosine-KLH. The adenosine system was chosen because C57Bl/6 mice were originally found to be resistant to immune suppression when challenged 5 days after treatment with adenosine-coupled spleen cells. (Raps et al. J. Immunol. 126, 1542, 1981.) It was determined (i) whether A-specific nonresponsiveness is inducible in strains other than C57Bl/6; (ii) whether changes in hapten density on the A-conjugated spleen cells could alter C57Bl/6s ability to become nonresponsive, and (iii) whether there are interstrain differences in the time required to induce A-specific suppressor T cells (Ts). The results show that there are H-2-associated differences in the time required to induce A-specific immune suppression. While A-spleen cells failed to suppress the A-specific response in C67Bl/10 (H-2b), they did induce unresponsiveness in B10.D2 (H-2d on C57Bl/10 background). A 2.5-fold increase in epitope density of adenosine on cells did not influence the kinetics of suppression. C67Bl/6 were resistant to suppression on Day 5, but like the CB6F1, susceptible to unresponsiveness 10 days after treatment. Nonresponsiveness was T-cell-mediated and transferable across IgH-V barriers. Suppression induced by Balb/c donor mice is transferable to Igh-incompatible CAL-20 mice. These results are discussed in the context of genetic restrictions which regulate suppressor T-cell interactions.

H-2 linked genetic control of immune responsiveness to hepatitis B surface antigen (HBsAg) in mice

Recent data suggest that genes involved in the control of (1) immune responses of humans to HBsAg and (2) the susceptibility to the development of chronic hepatitis B are linked to the major HLA histocompatibility complex. Studies on the genetic regulation of anti-HBs responses and on the possible abrogation of nonresponsiveness to HBsAg in humans are difficult. In an attempt to develop a relevant animal model system, the anti-HBs response of inbred and congenic strains of mice was investigated. A great variation in anti-HBs responses among individual mice belonging to the same strains was observed. Nevertheless, it was possible to rank the inbred mouse strains studied according to their decreasing anti-HBs responses as follows: BALB/c[d] congruent to SWR/J[q] greater than C57BL/6J[b] congruent to DBA/2J[a] greater than AKR/J[k] greater than A/J[a] greater than CBA/CaJ[k] greater than SJL/J[s]. (Letters in brackets indicate H-2 haplotype). Only a small proportion of SJL mice had an anti-HBs response. Therefore, this strain may serve as a model for human nonresponders. Studies with the congenic strains B10.D2[d] and B10.S[s] indicated that genes conferring responsiveness to HBsAg are linked to the H-2 histocompatibility complex. However, genes not linked to H-2 also probably play a role in regulating anti-Hbs responses.

Identification of an idiotypic marker of a major regulatory T cell of the immune response in B10.BR mice to ferredoxin. The relationship of idiotypic regulation to conventional hapten-carrier effects

An anti-idiotypic antiserum was raised in rabbits to a monoclonal antibody (Fd-1) with specificity for one (the N epitope) of the two antigenic epitopes found on the ferredoxin (Fd) molecule. The anti-idiotypic antiserum (anti-Fd-1) was used to demonstrate that the Fd-1 idiotype was expressed at significant levels in most anti-Fd antisera raised in B10.BR mice. Examination of antisera raised in other mouse strains demonstrated that expression of this idiotype mapped to the IgH gene complex and was found in the antisera of all mouse strains examined with the Ig-1 allotype. When splenocytes from Fd-immune B10.Br mice were treated with anti-Fd-1 and transferred to irradiated syngeneic recipients, the adoptive secondary response was significantly higher in animals receiving treated cells as opposed to control animals, which received normal rabbit serum-treated cells. This response produced a net increase in antibody to both determinants, and the relative amount of Fd-1 idiotype was not significantly altered. Further studies with separated cell populations showed that the overall increase of anti-Fd antibody produced was attributable to the effects of the anti-idiotypic serum on a population(s) of T cells. Treatment of mice with the Fd-1 monoclonal antibody (which should react with anti-idiotypic cells) had an analogous effect to that of the anti-idiotype, in that mice so treated produced higher concentrations of anti-Fd antibodies when they were immunized and these antibodies exhibited net increases to both determinants. A model is presented to explain these results.

Immunological focusing by th mouse major histocompatibility complex: mouse strains confronted with distantly related lysozymes confine their attention to very few epitopes

The gallinaceous lysozymes are a family of antigens that are distantly related to mouse lysozyme. A T cell-dependent proliferation assay was used to characterize the spectrum of reactivities to lysozyme determinants in B10-congenic mice. Cross-reactivity studies using a panel of species variant lysozymes to stimulate lymph node cells from chicken egg white lysozyme- and ring-necked pheasant egg white lysozyme-primed B10.D2 mice indicated a preferential focusing of T cell reactivity onto a single determinant containing amino acids 113-114. These data, in conjunction with results obtained by priming with cyanogen bromide cleavage fragments of lysozymes, suggested that a site commmon to the L3 region (amino acids 106-129) of all the lysozymes tested was a preferential anchorage site for I region-encoded Ia molecules on H-2d antigen-presenting cells, leading to the limited display of a determinant containing residues 113-114. Priming with L2H (amino acids 13-105), a peptide containing the major epitopes recognized by B10. A and B10 mice, failed to stimulate any T cell proliferation by B10.D2 lymph node cells. Thus, it appears the Ia molecules in any one mouse strain attach to very few sites on lysozyme to effectively display antigenic determinants for T cell activation. This result points to a model of limited determinant selection even on a very "foreign" antigen based upon a shortage of appropriate amino acid residues usable by Ia antigen-presenting structures of a strain.

The use of unideterminant fragments of ferredoxin in the genetic mapping of determinant specificity of the immune response

The ferredoxin (Fd) molecule is a small non-mammalian immunogenic protein containing 55 amino acid residues with only two major antigenic determinants located with the NH2-terminal heptapeptide and the COOH-terminal pentapeptide. Selective enzyme cleavages of Fd with either trypsin or carboxypeptidase A result in the inactivation of the antigenic determinants by the removal of a tripeptide at the NH2-terminal and two amino acid residues at the COOH-terminal, effectively leaving 52 and 53 amino acid fragments respectively, each containing a single antigenic determinant. Fd digested with both enzymes yielded a 50 amino acid peptide with both determinants inactivated. Purity of these digests was assessed using monoclonal antibodies in standard and antigen-blocking ELISAs. The doubly digested peptide had virtually no reactivity with anti-Fd sera, reconfirming that the central cysteine-rich region is serologically silent. It was found that the sum of the reactivities of the N- and C-determinant-bearing peptides as equal to that of the native Fd and that the ratio of the reactivities could be used to assess determinant selectivity in the response to Fd in congenic recombinant strains of mice. This method was used in mapping the determinant selectivity in the antibody response to the MHC of mice to the left of the I-B subregion. Use of the B10.HTT strain indicated that separate genes mapping to the same subregion code for the magnitude of the antibody response and the determinant selectivity of the response.

Immune recognition of serum albumin--XIV. Cross-reactivity by T-lymphocyte proliferation of subdomains 3, 6 and 9 of bovine serum albumin

Recently, we have shown that, with rabbit antibodies against BSA, the BSA fragments 115-184, 307-285 and 505-582 (essentially corresponding to subdomains 3, 6 and 9 of BSA) exhibit a cross-reaction which increases remarkably with the time antisera are obtained after the initial immunization. In the present report, we have examined whether this cross-reaction at the B-cell level takes place also at the T-cell level. Optimum conditions for T-cell proliferation to BSA and the three fragments were determined in terms of priming dose, challenging dose, time lymph nodes are obtained after immunization and finally duration of culture. Several strains of mice representing independent haplotypes and recombinant strains were examined for their responsiveness to BSA by T-lymphocyte proliferation, performed in the respective preimmune sera of the same mice. This afforded the identification of high- and low-responder strains to BSA. It was determined that the immune response to BSA is controlled by genes in the I-A subregion of the H-2 gene complex with some slight non-H-2 influences. In order to avoid the possibility of genetic exclusion of response to a given antigenic site and to improve the change of total site recognition, two high-responder strains (B10.M and B10.G) were crossed. Antibodies raised in (B10.M X B10.G)F1 mice recognized subdomains 3, 6 and 9 and these were found to be cross-reactive. Specific 125I-labelled antibodies isolated on a given subdomain-adsorbent were bound very well by adsorbents of the other two subdomains. T-cells from the F1 mice that had been primed with subdomain 3 responded to subdomain 3 and were also high responders to subdomain 6 and intermediate responders to subdomain 9. After priming with subdomain 6, the T-cells responded equally as well to subdomains 3 or 6 and slightly to subdomain 9. Finally, priming with subdomain 9, gave T-cells that responded to subdomain 9 and also gave high responses to subdomains 3 or 6. It was concluded that the cross-reactions originally observed at the B-cell level also take place at the T-cell level.

Production of antigen-specific suppressive T cell factor by radiation leukemia virus-transformed suppressor T cells

Hen egg-white lysozyme (HEL)-specific suppressor T cells induced in C57BL/6 mice have been selected by sequential passage over plates coated with goat anti-mouse Ig and HEL. These suppressor T cells, 80% I-J+, were infected in vitro with radiation leukemia virus (RadLV/Nu1) and injected intravenously into sublethally irradiated syngeneic recipients. After 4-6 months, 6 out of 20 injected mice developed thymic lymphomas, which were maintained by transplantation into histocompatible hosts and subsequently established as permanent cell lines. Cells of these six thymomas were screened for the presence of Thy 1.2, Lyt 1, Lyt 2, I-Jb, and Ig cell surface antigens by direct or indirect immunofluorescence. One tumor (thymoma L4) was found to express the expected phenotype of suppressor T cells (Thy 1.2+, Lyt 2+, I-J+). High-speed supernatants of extracts obtained from L4 cells were able to induce HEL-specific suppression in a T cell proliferative assay, demonstrating the presence of an antigen-specific suppressive T cell factor.

Positive selection of major histocompatibility complex-restricted suppressor T cells bearing the predominant idiotype in the immune response to lysozyme

The lysozyme system provides an excellent model for studying the role of multiple major histocompatibility complex (MHC) genes in the induction and regulation of Ir-gene controlled immune responses. Immunization of H-2b mice leads to concomitant activation of helper and suppressor activities by different epitopes on hen egg-white lysozyme (HEL) and thus phenotype unresponsiveness to native HEL. HEL-specific suppressor T cells in C57BL/10 nonresponder mice show MHC restriction, because their enrichment on antigen-pulsed macrophage monolayers requires syngeneic macrophages as well as HEL. The expression of the selected suppressor function requires interaction between the restricted suppressor precursor cell and an HEL-triggered, suppressor-inducer T cell. The MHC-restricted suppressor precursors bear the predominant idiotype found on anti-HEL antibodies, whereas MHC-restricted helpers do not.

Differential major histocompatibility complex-related activation of idiotypic suppressor T cells. Suppressor T cells cross-reactive to two distantly related lysozymes are not induced by one of them

B10 (H-2b) mice are genetic nonresponders to hen egg-white lysozyme (HEL) and the distantly related human lysozyme (HUL). However, anti-HEL or anti-HUL primary antibody responses in vivo or in vitro can be obtained in B10 mice by immunization with the appropriate lysozyme coupled to erythrocytes. T cells able to suppress either anti-lysozyme plaque-forming cells (PFC) response are induced in B10 mice after immunization with HEL-complete Freund's adjuvant (CFA) or HUL-CFA. This cross-reactivity of HEL and HUL in the induction and the expression of suppressive activity is in marked contrast to their very low cross-reactivity at the PFC level. These results suggest that either HEL or HUL can stimulate a suppressor T cell which recognizes a particular epitope present on both lysozymes. Suppressor cells induced by HEL or HUL bear the same predominant idiotype found on the majority of anti-HEL antibodies, and on the small proportion of anti-HUL antibodies cross-reactive with HEL. B10.Q (H-2q) mice are responders in vivo to HEL-CFA, but not to HUL-CFA. In contrast to B10, HEL-CFA priming in B10.Q micr induces helper cells whereas HUL-CFA priming induces suppressor cells. These suppressor cells are cross-reactive with HEL and are fully able to suppress HEL-specific helper cells. The presence of HEL-specific suppressor cell precursors in B10.Q mice which are not activated by HEL, seems to implicate differential choice by the antigen presenting system as a basis for Ir gene control, rather than the absence of a regulatory cell type from the T cell repertoire.

Ir-gene control of T cell proliferative responses: two distinct expressions of the genetically nonresponsive state

Two distinct modes of unresponsiveness to hen egg-white lysozyme (HEL) have been demonstrated in the "nonresponder" C57BL/10 Sn (B 10) mouse strain at the level of T cell proliferation. The first is an apparent inability to respond to a peptide of HEL comprising 70% of the molecule, LII (amino acids 13--105, when HEL is used as immunogen. On its own, LII is capable of eliciting a strong response from B 10 draining lymph node cells, but this capacity is concealed when the whole molecule is used for immunization (by suppressor cell activity raised against another part of HEL, as described by Adorini et al., J.Exp. Med. 1979. 150: 293). In the B 10.A mouse, LII and HEL are equally immunogenic. The second is an actual failure, presumably unrelated to suppression, to contrive a response to particular determinants on HEL, demonstrated for certain epitopes on LII and LIII (amino acids 106--129). Such a failure to respond was maintained despite an increase in the immunizing dose of peptide to a molarity at which HEL itself could overcome Ir gene control. B 10 cells responding to a high dose of HEL, or to the immunogenic lysozyme from ring-neck pheasant, were also unable to respond to these epitopes. These deficits in responsiveness appear to be characteristic manifestations of the relevant haplotype of the major histocompatibility complex. They may not only reflect the balance between competing T cell subpopulations, but also the constraints of associative recognition that may underlie the presentation of particular antigenic specificities.

Epitope specificity of the T cell proliferative response to lysozyme: proliferative T cells react predominantly to different determinants from those recognized by B cells

The fine specificity of murine B 10.A/SgSn (B 10.A) T cells reactive with hen egg-white lysozyme (HEL) has been studied through the use of reduced, carboxymethylated HEL, a set of peptides encompassing the entire molecule, and a set of variant lysozymes from other species. Cells were taken from the lymph nodes draining the site of immunization at the base of the tail, and were restimulated in vitro with immunogen or analogue to measure T cell reactivity. Unlike B cell reactivity, which we have shown to be mainly associated with an epitope preserved in the N-C peptide (residues 1--17, Cys6--Cys 127, 120--129) most T cell reactivity appears to be directed towards a limited number of determinants on cyanogen bromide cleavage fragment II of HEL (LII) (13--105). This was confirmed by a cell-dilution assay in which antigen-reactive units are measured; reactivity was highest to LII, intermediate to N-C, and low but significant to cyanogen bromide cleavage fragment III (LIII) (106--129). Furthermore, priming with LII is as effective as immunization with HEL and results in the same extensive cross-reactivities to variant lysozymes. Although LII reactivity predominates in the response to HEL, injection of LIII and N-C reveals sizeable reactivity to the homologous peptides and to HEL. By cross-stimulation studies, specific epitopes could be defined in certain regions of HEL. B 10.A is clearly responsive to the overlap between N-C and LII (residues 13--17), and to an epitope in the region 106--121, but is poorly responsive to the C-terminal portion (120--129). The response to 106--121 is characterized by an exquisite specificity in which as little as a single amino acid substitution (Asn for Gln) is recognized.

Multiple H-2 and non-H-2 genes controlling the antilysozyme response: alternative gene constellations can lead to responsiveness

Mice carrying the H-2b and H-2s haplotypes are genetically nonresponsive to hen egg-white lysozyme (HEL). Analysis of the anti-HEL response patterns of F1, F2 and backcross progeny showed that responsiveness was dominant and H-2 linked. From plaque-forming cell and serum assays in intra-H-2 recombinant mice, it was established that two I loci were implicated, the possession of either leading to responsiveness to HEL. One of the I genes maps in I-A, and the second in I-C, S or G. While the nonresponse phenotype was determined by the H-2 haplotype, there were codominant non-H-2 genes which contributed to a severe reduction in the level of antibody produced in responder strains. A model is presented attributing the outcome of an encounter with HEL to the regulatory balance of helper and suppressor T cells, which have been activated by different subregions of the major histocompatibility complex.

Basic strategies of the immune system in the regulation of antibody response

Three major regulatory mechanisms operating in the control of antibody response have been examined: 1. antibody feedback; 2. T cell regulation (I. regulatory interactions among T cell subsets, II. H-2 linked Ir gene control of T cell function, III. regulatory role of antigenic epitopes in T cell subsets induction); 3. idiotypic network. Analysis of the results of obtained in the lysozyme system together with available data in the literature have permitted the delineation of a model of antigen-triggered events involved in the regulation of antibody response. The basic feature of the proposed model is the integration of two major specific communication systems among lymphocytes engaged in the antibody response: antigen bridge and idiotypic complementarity.

Genetic control of the immune response to hen's egg-white lysozyme in mice. I. Antibody and T-lymphocyte proliferative responses to the native protein

We have initiated studies to determine whether the antibody and T-lymphocyte proliferative responses to lysozyme and its antigenic sites is genetically controlled in mice. Mice of the H-2f, H-2k and H-2p were high responders, while haplotypes H-2b, H-2d, H-2r and H-2s were low responders. Studies with recombinants indicated that the immune response is controlled by two H-2I region loci, one being in the I-A subregion and the other may be in the I-C subregions.