Self-tolerance to HLA focuses the response of immunized HLA-transgenic mice on production of antibody to precise polymorphic HLA alloantigens

Deletion of IgG-switched autoreactive B cells and defects in Fas(lpr) lupus mice

During a T cell-dependent Ab response, B cells undergo Ab class switching and V region hypermutation, with the latter process potentially rendering previously innocuous B cells autoreactive. Class switching and hypermutation are temporally and anatomically linked with both processes dependent on the enzyme, activation-induced deaminase, and occurring principally, but not exclusively, in germinal centers. To understand tolerance regulation at this stage, we generated a new transgenic mouse model expressing a membrane-tethered gamma2a-reactive superantigen (gamma2a-macroself Ag) and assessed the fate of emerging IgG2a-expressing B cells that have, following class switch, acquired self-reactivity of the Ag receptor to the macroself-Ag. In normal mice, self-reactive IgG2a-switched B cells were deleted, leading to the selective absence of IgG2a memory responses. These findings identify a novel negative selection mechanism for deleting mature B cells that acquire reactivity to self-Ag. This process was only partly dependent on the Bcl-2 pathway, but markedly inefficient in MRL-Fas(lpr) lupus mice, suggesting that defective apoptosis of isotype-switched autoreactive B cells is central to Fas mutation-associated systemic autoimmunity.

Specificity-Based Negative Selection of Autoreactive B Cells during Memory Formation

Autoreactive B cells are not completely purged from the primary B cell repertoire, and whether they can be prevented from maturation into memory B cells has been uncertain. We show here that a population of B cells that dominates primary immune responses of BALB/c mice to influenza virus A/PR/8/34 hemagglutinin (HA) are negatively selected in transgenic mice expressing PR8 HA as an abundant membrane-bound Ag (HACII mice). However, a separate population of B cells that contains precursors of memory B cells is activated by PR8 virus immunization and is subsequently negatively selected during the formation of the memory response. Negative selection of PR8 HA-specific B cells altered the specificity of the memory B cell response to a mutant virus containing a single amino acid substitution in a B cell epitope. Strikingly, this skewed reactivity resulted from an increase in the formation of memory B cells directed to non-self-epitopes on the mutant virus, which increased 8-fold in HACII mice relative to nontransgenic mice and precisely compensated for the absence of autoreactive PR8 HA-specific memory B cells. Negative selection of PR8 HA-specific B cells was a dominant process, since B cells from HACII mice could induce negative selection of PR8 HA-specific B cells from BALB/c mice. Lastly, HA-specific memory responses were unaffected by self-tolerance in another lineage of HA-transgenic mice (HA104 mice), indicating that the amount and/or cell type in which self-Ags are expressed can determine their ability to prevent autoreactive memory B cell formation.

Virus-induced maturation and activation of autoreactive memory B cells

We have examined B cell populations that participate in distinct phases of the immune response to the influenza virus A/PR/8/34 hemagglutinin (HA) for their susceptibility to negative selection in mice that express the HA as a neo-self-antigen (HA104 mice). We demonstrated previously that specificity for the neo-self-HA causes a population of immunoglobulin G antibody-secreting cells, which dominate the primary response to virus immunization in BALB/c mice, to be negatively selected in HA104 mice. We find here that in contrast to these primary response B cells, HA-specific memory response B cells developed equivalently in HA104 and nontransgenic (BALB/c) mice. Indeed, there was no indication that HA-specific B cells were negatively selected during memory formation in influenza virus-immunized HA104 mice, even though the neo-self-HA can be recognized by memory B cells. Furthermore, HA-specific autoantibodies were induced in the absence of virus immunization by mating HA104 mice with mice transgenic for a CD4(+) HA-specific T cell receptor. These findings indicate that specificity for a self-antigen does not prevent the maturation of autoreactive B cells in the germinal center pathway. Rather, the availability of CD4(+) T cell help may play a crucial role in regulating autoantibody responses to the HA in HA104 mice.

CD8+ T cells are necessary for recognition of allelic, but not locus-mismatched or xeno-, HLA class I transplantation antigens

Although HLA transgenic mice (HLA TgM) could provide a powerful approach to investigate human MHC-specific T cell responsiveness, the extent to which these molecules are recognized by the mouse immune system remains unclear. We established TgM expressing HLA class I alleles A2, B7, or B27 in their fully native form (HLAnat) or as hybrid molecules (HLAhyb) of the HLA alpha1/alpha2 domains linked to the H-2Kb alpha3, transmembrane, and cytoplasmic domains (i.e., to maintain possible species-specific interactions). Comparison of each as xeno- (i.e., by non-TgM) vs allo- (i.e., by TgM carrying an alternate HLA allele) transplantation Ags revealed the following: 1) Although HLAhyb molecules induced stronger xeno-CD8+ T cell responses in vitro, additional effector mechanisms must be active in vivo because HLAnat skin grafts were rejected faster by non-TgM; 2) gene knockout recipients showed that xenorejection of HLAnat and, unexpectedly, HLAhyb grafts doesn't depend on CD8+ or CD4+ T cells or B cells; 3) each HLAhyb strain developed tolerance to "self" but rejected allele- (-B27 vs -B7) and locus- (-B vs -A) mismatched grafts, the former requiring CD8+ T cells, the latter by CD8+ T cell-independent mechanisms. The finding that recognition of xeno-HLAhyb does not require CD8+ T cells while recognition of the identical molecule in a strictly allo context does, demonstrates an alpha1/alpha2 domain-dependent difference in effector mechanism(s). Furthermore, the CD8+ T cell-independence of locus-mismatched rejection suggests the degree of similarity between self and non-self alpha1/alpha2 determines the effector mechanism(s) activated. The HLA Tg model provides a unique approach to characterize these mechanisms and develop tolerance protocols in the context of human transplantation Ags.

Cell-mediated graft rejection observed in two lines of human histocompatibility leukocyte antigen class I transgenic mice

BACKGROUND

Human histocompatibility leukocyte antigen (HLA) class I molecules are essential for graft rejection. However, to determine the specific role of these molecules in clinical situations is difficult. We investigated the applicability of HLA class I transgenic mice (C3H.B35 and C3H.B51) for elucidation of the role of HLA class I molecules.

METHODS

Skin or heart grafts were transplanted. Cytotoxic T cells (CTL) of C3H.B51 against C3H.B35 were generated and their cytotoxicity against various transfectant cell lines was determined.

RESULTS

C3H.B35 skin and heart grafted to C3H.B51 were rejected within 17 and 28 days, respectively. Cytotoxic T cells generated from C3H.B51 showed cytotoxicity against a HLA-B*3501-transfectant cell line that did not express H-2 molecule, which indicates that these cytotoxic T cells recognize HLA-B35 molecules directly without H-2 restriction.

CONCLUSION

Our results suggest that C3H.B51 recognize C3H.B35 grafts as allo-MHC class I-incompatible grafts, and these mice are valuable to elucidate the role of HLA class I molecules in transplantation.

Trypanosoma cruzi: immune response and functional heart damage induced in mice by the main linear B-cell epitope of parasite ribosomal P proteins

We report herein on the specific and autoimmune humoral response generated by the immunization of mice with the R13 synthetic peptide coupled to a carrier protein, OVA. This peptide corresponds to the C-terminal region of Trypanosoma cruzi ribosomal P1 and P2 proteins (EEEDDDMGFGLFD), a sequence that differs from the other eukariotic P consensus sequence (EESDDDMGFGLFD) only in a nonconservative amino acid substitution. The antibody response studied by ELISA revealed that all R13-immunized mice had antibodies against R13, consisting mainly of IgG1 and IgG2 isotypes, even though IgG3 and IgE isotypes were also observed. The self-reactivity of anti-R13 sera assayed by immunoblot, revealed that all sera contained IgG antibodies binding to mouse and human 38-kDa heart antigen. This antigenic band binds several immunoglobulin isotypes (IgG2 > IgG3 > IgE > IgG1). The specificity of anti-R13 antibodies analyzed by competitive inhibition of R13 ELISA using R13 and R7 (MGFGLFD) peptides revealed that the reactivity of the induced anti-P antibodies was not absorbed by R7. Therefore, the main immunogenic region of R13 for mouse would be EEEDDD, which contains the amino acid substitution. In parallel with this humoral response, both partial protection and heart damage were observed in R13-immunized mice. In fact, the R13-immunized mice showed significantly lower parasitemia and longer survival than the control animals. In addition, all R13-immunized mice showed electrocardiographic changes (bradycardia, prolonged PQ segment, and intraventricular conduction disturbances), which are typical findings in Chagas disease patients. This study represents the first definitive report in which one defined B-cell epitope, the single peptide R13 from T. cruzi, coupled to a carrier protein was able to induce specific and autoreactive antibodies as well as to generate heart functional alterations.

Evaluation of trophoblast HLA-G antigen with a specific monoclonal antibody

A monoclonal antibody to HLA-G has been generated by immunizing HLA-A2.1/human beta 2-microglobulin (beta 2 m) double transgenic mice with murine L cells transfected with both human beta 2 m and HLA-G. This monoclonal antibody, designated as G233, has been found not to cross-react with other HLA class I antigens when tested on numerous cell lines by flow cytometry. With immunohistology, all populations of extravillous trophoblast (cell columns, interstitial trophoblast, endovascular trophoblast, placental bed giant cells) were stained. An extensive range of adult and fetal tissues was also tested but none reacted with monoclonal antibody G233, including those previously reported to express HLA-G mRNA, indicating that the protein has a highly restricted distribution. Failure to detect HLA-G in the fetal thymus raises the question as to how T-cell tolerance to this antigen is induced. Immunoprecipitation of trophoblast surface proteins with monoclonal antibody G233 revealed a heavy chain of 39 kDa and a light chain of 12 kDa, indicating that HLA-G expressed on the surface of trophoblast is complexed with beta 2 m. However, sequential immunoprecipitation with monoclonal antibody W6/32 followed by monoclonal antibody G233 continued to detect a residual band of 39 kDa, suggesting that trophoblast surface HLA-G may also occur as free heavy chains not associated with beta 2 m. Immunoprecipitation followed by two dimensional gel electrophoresis showed that monoclonal antibody G233 recognizes several isoforms of HLA-G from trophoblast similar to the characteristic spot array previously described for HLA-G. This monoclonal antibody G233 will be highly useful in future experiments to elucidate the function of HLA-G.

Activation and negative selection of functionally distinct subsets of antibody-secreting cells by influenza hemagglutinin as a viral and a neo-self antigen

We have compared transgenic mice that express the influenza virus PR8 hemagglutinin (PR8 HA) as a membrane-bound neo-self antigen (HA104 mice) with nontransgenic (non-Tg) mice for their ability to generate HA-specific B cell responses after primary immunization with PR8 virus. HA-specific, IgM-secreting B cells were induced with similar frequencies in HA104 and non-Tg mice. In addition, a B cell clonotype (C4) that is characteristic of anti-HA immune responses of BALB/c mice was identified among HA-specific IgM hybridomas from HA104 mice. A subset of HA-specific, IgG-secreting B cells that arises rapidly after primary virus immunization in non-Tg mice, however, was substantially reduced in HA104 mice. Likewise, a B cell clonotype (C12) that dominates HA-specific IgG hybridomas generated after primary immunization of non-Tg mice was present at greatly reduced frequencies among hybridomas from HA104 mice. Because HA-specific, IgG-secreting B cells were generated by HA104 mice in response to a mutant HA containing an amino acid interchange in a B cell antigenic site, we conclude that these PR8 HA-specific, IgG-secreting B cells are negatively selected in HA104 mice as a result of their specificity for the neo-self PR8 HA. The findings demonstrate that HA-specific B cells that display distinct phenotypic potentials in non-Tg mice also differ in their susceptibility to negative selection from the primary B cell repertoire of HA104 mice: a subset of B cells that undergo rapid differentiation to become HA-specific IgG antibody-secreting cells (ASC) after activation in non-Tg mice is negatively selected in HA104 mice. By contrast, a subset that gives rise to HA-specific, IgM-secreting ASC persists in the primary repertoire of HA104 mice and can be activated by virus immunization.

Antibodies directed against monomorphic and evolutionary conserved self epitopes may be generated in 'knock-out' mice. Development of monoclonal antibodies directed against monomorphic MHC class I determinants

Beta-2 microglobulin (beta 2m) gene 'knock-out' mice (C1D) were primed with purified H-2Kb and H-2Db molecules and spleen cells from immunized mice were used to generate monoclonal antibody secreting B-cell hybridomas. Approximately 0.2% of the Ig-secreting primary microcultures contained H-2b binding antibodies. Three stable anti-MHC class I (MHC-I) antibody secreting hybridoma clones were established and subcloned. All three MoAbs precipitated radiolabelled H-2 molecules as analysed by SDS PAGE, and all three MoAbs stained H-2b, H-2d, as well as H-2k cells by FACS analysis. The MoAbs stained to two beta 2m loss mutant cell lines, C4.4-25- and R1E, suggesting that some MHC-I heavy chain is exported to the cell surface even in the absence of endogenous beta 2m. Staining of murine cell lines kept under serum-free culture conditions was strongly influenced by the addition of bovine or human serum as a source of exogenous beta 2m suggesting that xenogeneic beta 2m affects the conformation of class I molecules. Furthermore, all three MoAbs strongly stained the peptide transporter deficient cell line, RMA-S, when cultured at 26 degrees C, however, staining was reduced five-fold when RMA-S cells were cultured at 37 degrees C. In total, these observations suggest that the MoAbs recognize conformational, presumably beta 2m and peptide dependent, self epitopes on MHC-class I. One of the three MoAbs stained rat blood mononuclear blood cells (BMC), all three MoAbs stained hamster BMC, whereas two of the MoAbs stained human cells. These data suggest that the MoAbs recognize determinants which are conserved between species. All three antibodies strongly inhibited the development of CTLs generated in an allogeneic one-way MLC, provided that the MoAbs were present during the first 24 h of culture. It is concluded that MoAbs reacting with monomorphic self epitopes may be generated using animals deleted of the gene of interest. The implications may be far reaching since such MoAbs potentially identify evolutionary conserved and physiologically important epitopes.

HLA antibody responses in HLA class I transgenic mice

In a previous report we described how cross-immunizations of pairs of transgenic mice expressing different HLA class I antigens led to the production of antibodies directed exclusively at polymorphic epitopes. This was ascribed to self-tolerance of HLA that prevents immune responses to monomorphic epitopes and focuses responses on polymorphic ones. In the present report we extend our findings and demonstrate that immunizations of class I transgenic mice with HLA transfected mouse fibrosarcoma as well as with human lymphoblastoid cells also preferentially yield antibodies to polymorphic epitopes. This was the case whether or not immunizations were carried out across locus barriers [e.g., Tg(HLA-A *0201) or Tg(HLA-Cw*0301) transgenic mice immunized with HLA-B27 transfectants] or within the same locus [e.g., Tg(HLA-B*1302) transgenic mice immunized with HLA-B27 transfectants or B27-expressing lymphoblastoid cells]. Use of an extended immunization protocol with four or more booster injections favored antibodies of IgG isotype with affinities high enough to lyse normal peripheral blood lymphocytes (PBLs) in complement-dependent cytotoxicity assays and to immunoprecipitate HLA antigens. The specificities covered by the monoclonal antibodies (mAbs) could be either broad or narrow, depending on the genetic distance of the HLA antigens or alleles involved. For instance, a Tg(HLA-B*1302) transgenic mouse immunized with B27 produced both broad B7/B27-specific antibodies, Bw4-specific antibodies, and one antibody reacting with all B alleles except B13 and with some C alleles. On the other hand, a Tg(HLA-B*1302) transgenic mouse immunized with Bw47 transfectants responded narrowly with an antibody to Bw60 and Bw47. Thus it appears that by choosing appropriate recipient mice and closely related or more distant HLA antigens, antibodies of a programmed specificity can be generated.