T-helper 1 dominated responses to erythrocyte Band 3 in NZB mice.

Band 3, the red blood cell (RBC) anion channel protein, is the target autoantigen for the pathogenic RBC autoantibodies and T-helper (Th) cells in New Zealand Black (NZB) mice with autoimmune haemolytic anaemia (AIHA). To determine the subpopulation of these Th cells, they were stimulated with Band 3 and the profile of the cytokines elaborated by the responding cells was measured. NZB T cells stimulated with Band 3 produced high levels of the Th1 cytokine, interferon-gamma (IFN-gamma), but little or no interleukin-4 (IL-4), IL-5 or IL-10. Similar patterns were produced by NZB T cells responding to a spectrin preparation from the RBC membrane skeleton, or to mycobacterial heat-shock protein (hsp) 65 following immunization of mice with hsp 65 in incomplete adjuvant. By contrast, T cells from CBA mice similarly immunized with hsp 65 produced high levels of IL-4 and IL-5 in response to hsp 65. Examination of the isotype of the RBC-bound immunoglobulins in NZB mice revealed that immunoglobulin G2a (IgG2a) autoantibodies were the first to be detected in most mice and that later in the disease, IgG3 autoantibodies were often prominent. It is concluded that, contrary to expectation, the development of RBC autoantibodies in NZB mice is associated with Th1 cytokine-dominated responses.     

Pathogenic autoantibodies in the NZB mouse are specific for erythrocyte Band 3 protein

NZB mice spontaneously develop autoimmune hemolytic anemia (AIHA). The red blood cell (RBC) autoantigen bound by pathogenic IgG autoantibodies, previously designated “X”, was identified by immunoprecipitation. Autoantibody eluted from the RBC of AIHA-positive NZB mice precipitated a 105-kDa antigen that was identical in apparent molecular mass to Band 3, the RBC anion channel protein. Furthermore, the immunoblotted antigen also reacted specifically with BRIC 132, a monoclonal antibody against Band 3. The results, therefore, demonstrate that Band 3 bears autoantigenic epitopes that are important in the pathogenesis of AIHA in the NZB mouse.     

T-cell specificity in murine autoimmune haemolytic anaemia induced by rat red blood cells

Autoimmune haemolytic anaemia (AIHA) can be induced in mice by repeated injections with rat red blood cells (RBC). Here we describe the identification of rat and murine RBC antigens recognized by T-cells from mice with this disease. Splenic T-cells from mice with AIHA proliferated in response to multiple murine RBC membrane components, each of which is recognized by rat RBC induced autoantibodies. Thus, there were responses to murine autoantigen fractions that correspond in apparent molecular mass with the anion channel Band 3, with spectrin from the membrane skeleton and with the high and low molecular mass glycophorins, and the equivalent fractions from rat RBC also stimulated proliferation by T-cells. It was confirmed that purified Band 3 from murine and rat RBC also elicited responses. In contrast with the results in AIHA, T-cells from healthy control mice failed to respond to the antigens from either species, with the exception of proliferation induced by murine spectrin in one experiment and weak responses elicited by rat Band 3. It is suggested that T-cells activated by multiple cross-reactions between rat and murine RBC proteins, and by epitope spreading, are necessary to drive autoantibody production in this model of AIHA.     

The anti-erythrocyte autoimmune response of NZB mice. Identification of two distinct autoantigens.

With age, New Zealand black (NZB) mice spontaneously develop anti-mouse red blood cell (RBC) autoantibodies resulting in the development of autoimmune haemolytic anemia (AIHA). Previously, we characterized a panel of monoclonal autoantibodies derived from unimmunized, adult NZB mice. One of these antibodies (G8) was shown to be pathogenic, inducing AIHA in a non-autoimmune-prone mouse strain (BALB/c). Using G8, and two other antibodies from our panel, we have characterized two distinct autoantigens on the surface of mouse RBCs. The autoantigen, historically referred to as antigen X (AgX), was found to be partially hidden on the surface of the mouse RBC because glycosidase treatment or mild digestion with proteinase K resulted in increased reactivity with autoantibodies. One of the monoclonal antibodies (3H5G1) was found to immunoprecipitate a 110,000 MW protein identified as the erythrocyte anion transporter (band 3) whereas the pathogenic antibody (G8) as well as a third monoclonal antibody (2E6m) were shown to immunoprecipitate a 60,000 MW protein that was not reactive with the anti-band 3 serum. Finally, we show that the autoantigen recognized by G8 is expressed on differentiated mouse erythroleukaemia (MEL) cells. The results suggest that a protein distinct from band 3 can serve as a target for AIHA in NZB mice.     

Characterization of the dominant autoreactive T-cell epitope in spontaneous autoimmune haemolytic anaemia of the NZB mouse

NZB mice spontaneously develop autoimmune haemolytic anaemia (AIHA) due to a T helper-dependent autoantibody response against the erythrocyte anion channel protein, Band 3. Here, we characterize the recognition of the Band 3 sequence 861-874, which carries the dominant, I-E(d)-restricted T cell epitope. The ability of N and C-terminal truncated versions of peptide 861-874 to elicit NZB splenic T-cell proliferation indicated that the core epitope spans residues 862-870. Next, a set of alanine substitution analogues was tested to determine which residues functioned either as MHC anchor or TCR contact residues. A combination of proliferation and MHC:peptide binding assays identified residues 862(L), 864(V), 865(L), and 869(K) as I-E(d) anchor residues, and 868(V) as the only TCR contact residue. The ability of the wild-type sequence 861-874 to compete with a high affinity reference peptide for binding to I-E(d) indicates that the escape of pathogenic NZB T cells from purging of the autoreactive repertoire cannot be attributed to ineffective presentation of peptide 861-874 by its restricting element. It will now be possible to design altered peptide ligands of Band 3 861-874, in order to further dissect the mechanisms responsible for the maintenance and loss of T cell tolerance to RBC autoantigens, and to modulate the immune response in AIHA.     

Diseases caused by reactions of T lymphocytes to in compatible structures of the major histocompatibility complex. I. Autoimmune hemolytic anemia

The capacities of various lymphoid cells from C57BL/10 donors to induce antibodies against red blood cells (RBC) in (C57BL/10 × DBA/2)F₁ recipients were compared: cortisone-resistant thymocytes were more potent inducers than spleen cells, and bone marrow cells were ineffective. This established a need for parental T lymphocytes in the induction of Coombs-positive hemolytic anemia by the graft-versus-host reaction (GVHR). Since some of the anti-RBC antibodies carried the Ig^c allotype specific for the F₁ host, they were autoantibodies. When antibodies were eluted from the erythrocytes of F₁ mice undergoing the GVHR (GVH F₁ mice) and subsequently tested against normal RBC in the indirect Coombs' test, the Ig^c allotype was demonstrable even on those antibodies found to react with RBC of the donor strain (C57BL/10). In addition, reactions with normal intact RBC of other strains and species were noted. Anti-RBC antibodies belonged to all Ig classes and subclasses that were tested (IgG₁, IgG_2a, IgG_2b, IgA, and IgM). By means of histocompatibility typing it was shown that the overwhelming majority of lymphoid cells from GVH animals were host cells; most of these host cells were Thy-1.2-negative. In several GVH F₁ mice Coombs-positive erythrocytes were demonstrated for periods of more than 5 months; Ig^c-positive anti-RBC antibodies were detected for periods up to 3 months. When an additional injection of parental T cells was administered to GVH F₁ mice, which had become Coombs-negative in the course of the GVHR, new anti-RBC antibodies appeared. In contrast to F₁ B cells, T cells of the F₁ host were not needed for autoimmunization as shown by the induction of anti-RBC auto-antibodies in F₁ recipients that were depleted of autologous T cells prior to the administration of parental T cells. When (C57BL/10 × DBA/2)F₁ mice were back-crossed into strain C57BL/10 and the offsprings injected with C57BL/10 (H-2^bb) lymphoid cells, most of the H-2 heterozygous (H-2^bd) back-crosses developed Coombs'-positive hemolytic anemia, whereas none of the H-2 homozygous (H-2^bb) ones did. The most likely explanation of these results is that anti-RBC autoantibodies were induced by a persistent reaction of parental T helper cells to incompatible H-2 structures on normally present autoreactive F₁ B cells. The hypothesis is proposed that reactions of T lymphocytes against virally or chemically altered structures of the major histocompatibility complex may lead to autoimmunization also in nonchimeric individuals.     

Splenic but not thymic autoreactive T cells from New Zealand Black mice respond to a dominant erythrocyte Band 3 peptide

Previous work from our laboratory suggested that erythrocyte Band 3 peptide 861-874 is the dominant epitope recognized by splenic T cells from adult New Zealand Black (NZB) mice that are developing autoimmune haemolytic anaemia (AIHA). Here, it is shown that splenic T cells from 6-week-old NZB mice mount a vigorous in vitro proliferative response to peptide 861-874 and some other selected Band 3 peptides. As the donors grow older, splenic T cells respond to an increasing number of Band 3 peptides and the magnitude of their response also becomes greater. Splenic T cells from 3-week-old NZB mice still responded vigorously to peptide 861-874 and Band 3. By contrast, neither thymocytes nor single-positive CD4-enriched thymus cells from NZB mice responded to peptide 861-874 or Band 3, although they responded to concanavalin A (Con A). However, thymocytes from mice expressing a transgenic T-cell receptor (TCR)-specific for myelin basic protein (MBP) peptide Ac 1-9 responded vigorously to Ac 1-9. It is considered that the T-cell response of NZB mice to Band 3 is initially focused on peptide 861-874 and later spreads to other Band 3 peptides as the disease progresses and that peptide 861-874-reactive T cells are primed in the periphery rather than the thymus.     

Mechanisms of immunological tolerance loss versus erythrocyte self-antigens and autoimmune hemolytic anemia

Recent studies on animal and human autoimmune hemolytic anemia (AIHA) suggest that immunological tolerance loss toward red blood cells (RBC) self-antigens may be originate by different, non-mutually exclusive, mechanisms. According to now available data the identified mechanisms may be: ignorance against RBC self-antigens; molecular mimicry; polyclonal T and/or B cells activation; errors in central or peripheral tolerance; immunoregulatory disorders including cytokine network alteration. In some patients with AIHA, stimulation of PMBC by synthetic Rh peptides indicate that ignorant T and/or B cell clones may recognize cryptic RBC self-antigens. AIHA associated with bacterial or viral infections seems to be produced by polyclonal T and/or B cells activation against foreign antigens which mimic protein or carbohydrate epitopes on RBC. Polyclonal activation of host B cell clones by donor alloreactive T cells causes the AIHA in chronic GVHD. As the tolerance loss is concerned, experiments on mouse lines expressing a transgene with autoantibody activity against murine RBC have shown that non-deleted peripheral B cell clones may produce RBC autoantibodies. In humans a genetic defect of Fas/FasL autoreactive lymphocytes apoptosis may be associated to AIHA. Immunoregulatory disorders due to depletion of CD4+ CD25+ T cells or Th1/Th2 cytokines imbalance may induce autoimmune diseases. In mice AIHA may be induced or improved by cytokines or anticytokine antibodies administration. In NZB/W mice and human AIHA there is an increased production of Th2 cytokines as IL4 and IL10 but INF-gamma reduced production. In addition in human AIHA has been shown a downregulation of IL12 and therefore, an IL10/IL12 immunoregulatory circuit imbalance which might facilitate the RBC autoantibodies production.     

ReviewMechanisms of Immunological Tolerance Loss Versus Erythrocyte Self-antigens and Autoimmune Hemolytic Anemia

Recent studies on animal and human autoimmune hemolytic anemia (AIHA) suggest that immunological tolerance loss toward red blood cells (RBC) self-antigens may be originate by different, non-mutually exclusive, mechanisms. According to now available data the identified mechanisms may be: ignorance against RBC self-antigens; molecular mimicry; polyclonal T and/or B cells activation; errors in central or peripheral tolerance; immunoregulatory disorders including cytokine network alteration.

In some patients with AIHA, stimulation of PMBC by synthetic Rh peptides indicate that ignorant T and/or B cell clones may recognize cryptic RBC self-antigens. AIHA associated with bacterial or viral infections seems to be produced by polyclonal T and/or B cells activation against foreign antigens which mimic protein or carbohydrate epitopes on RBC. Polyclonal activation of host B cell clones by donor alloreactive T cells causes the AIHA in chronic GVHD. As the tolerance loss is concerned, experiments on mouse lines expressing a transgene with autoantibody activity against murine RBC have shown that non-deleted peripheral B cell clones may produce RBC autoantibodies. In humans a genetic defect of Fas/FasL autoreactive lymphocytes apoptosis may be associated to AIHA. Immunoregulatory disorders due to depletion of CD4+ CD25+ T cells or Th1/Th2 cytokines imbalance may induce autoimmune diseases. In mice AIHA may be induced or improved by cytokines or anticytokine antibodies administration. In NZB/W mice and human AIHA there is an increased production of Th2 cytokines as IL4 and IL10 but INF-γ reduced production. In addition in human AIHA has been shown a downregulation of IL12 and therefore, an IL10/IL12 immunoregulatory circuit imbalance which might facilitate the RBC autoantibodies production.     

Genetic association between natural autoantibody responses to histones and DNA in murine lupus.

Genetic regulation of the spontaneous anti-histone antibody production in systemic lupus erythematosus (SLE) was studied using the H-2-congenic and T cell receptor beta chain gene complex (TCR beta)-congenic NZB and NZW strains and their crosses. We found that the original, parental H-2d/d NZB mice produced significantly higher titers of serum IgM class anti-histone antibodies than did the congenic H-2d/z or H-2z/z NZB mice. However, none of these three NZB strains produced IgG antibodies. The NZW strain of any H-2 haplotype did not produce IgM and IgG anti-histone antibodies. The IgG anti-histone antibodies were produced only by H-2d/z heterozygous NZB x NZW F1, but not by homozygous H-2z/z or H-2d/d NZB x NZW F1 mice. In studies using (NZB x NZW) F1 x NZB backcross mice, only the progeny having both H-2d/z and NZW-type TCR beta genotypes produced high amounts of IgG antibodies. There was a tight linkage between the NZW-type TCR beta and the production of IgG anti-histone antibodies in TCR beta-congenic NZB x NZW F1 mice. All these findings were in keeping with our preceding observations on the genetic regulation of anti-DNA antibodies in these mice and suggest that certain common mechanisms such as super-antigen-mediated or common idiotope-mediated regulations may underlie the production of these two distinct autoantibodies in NZB x NZW F1 mice.     

Galactosylation of serum IgG and autoantibodies in murine models of autoimmune haemolytic anaemia.

A number of systemic autoimmune diseases are associated with increased levels of the agalactosyl (G0) IgG isoforms that lack a terminal galactose from the CH2 domain oligosaccharide. The current aim was to determine whether the galactosylation of serum IgG is also reduced in a classic antibody-mediated, organ-specific autoimmune condition, and whether the pathogenic autoantibodies are preferentially G0. In two murine forms of autoimmune haemolytic anaemia (AIHA), sera and autoantibodies eluted from erythrocytes were obtained, and the levels of G0 measured using a lectin-binding assay. Serum IgG galactosylation was unaffected following the induction of AIHA in CBA/Igb mice by immunization with rat erythrocytes, but in all animals with the disease the IgG autoantibodies generated were more G0 than the sera. The anti-rat erythrocyte antibodies were similar to the autoantibodies in being preferentially G0, and when CBA/Igb mice were immunized with canine erythrocytes as a control foreign antigen, there was again a bias towards the production of G0 IgG antibodies. In NZB mice with chronic, spontaneous AIHA, the concentration and galactosylation of both serum IgG and autoantibodies were lower than in the induced model, and the ratio of G0 IgG in the serum and erythrocyte eluates varied markedly between different individuals. Our interpretation of these results is that changes in serum IgG or autoantibody galactosylation are not consistent in different models of AIHA, and that production of low galactosyl antibodies can be a feature of a normal immune response.     

Infection of C3HeB/FeJ mice with the docile strain of lymphocytic choriomeningitis virus induces autoantibodies specific for erythrocyte Band 3.

C3HeB/FeJ mice infected with the docile strain of lymphocytic choriomeningitis virus (LCMV-d) develop a persistent infection with a transient haemolytic anaemia. Immunoglobulin can be eluted from the red blood cells (RBC) of these mice but it cannot be detected on the RBC by a conventional antiglobulin test. The present study demonstrates that RBC from such mice bear erythrocyte autoantibodies which are predominantly of the IgG2a subclass, with lower levels of autoantibodies of the IgG1, IgG2b and IgG3 subclasses. To identify the target antigen the autoantibodies were eluted from the RBC of LCMV-infected mice. The eluted autoantibody bound to intact normal RBC and precipitated a 105000 MW component that corresponds to murine Band 3 protein. A monoclonal antibody derived from mice infected with LCMV-d also precipitated mouse Band 3, and reacted specifically by enzyme-linked immunosorbent assay against a purified preparation of Band 3. This study has shown that in C3H mice infected with LCMV-d which develop autoimmune haemolytic anaemia, the target autoantigen is erythrocyte membrane Band 3.     

Effects of major histocompatibility complex on autoimmune disease of H-2-congenic New Zealand mice

Autoimmune-prone NZB mice mainly produce IgM-class anti-DNA antibodies and mild SLE develops later in life. The F1 hybrid of NZB and non-autoimmune NZW mice (NZB/W F1 mice) develop a more fulminant SLE, associated with decreases in IgM class, and, in turn, increases in IgG class anti-DNA antibodies. To elucidate the role of the H-2 complex in this mode of anti-DNA antibody production, we established and studied H-2-congenic New Zealand mice, i.e. NZB, NZW, and NZB/W F1 mice with either the homozygous H-2z/H-2z or H-2d/H-2d haplotype or the heterozygous H-2d/H-2z haplotype. The data showed that: (i) although the non-H-2-linked NZB gene(s) seems to determine the IgM anti-DNA antibody production in NZB mice, the effect of this gene is fully expressed only in the case of the H-2d/H-2d homozygous state. (ii) The production of IgG anti-DNA antibodies observed in NZB/W F1 hybrid mice is restricted to the H-2d/H-2z heterozygosity. (iii) Because both NZB and NZW mice with the H-2d/H-2z haplotype produce a lower titer of IgG anti-DNA antibodies than do the NZB/W F1 mice, other complementary non-H-2-linked genetic elements from both NZB and NZW parents are required. The development of lupus nephritis correlated well with that of anti-DNA antibodies. Thus, H-2d/H-2z heterozygosity is a necessary but not sufficient condition for the development of autoimmunity in NZB/W F1 mice.(ABSTRACT TRUNCATED AT 250 WORDS)     

Indoleamine 2,3 dioxygenase contributes to transferable tolerance in rat red blood cell inducible model of experimental autoimmune haemolytic anaemia

Autoimmune haemolytic anaemia (AIHA) is caused by autoantibodies against red blood cell (RBC) surface antigens that render RBC susceptible to Fc‐mediated phagocytosis and complement‐mediated lysis. Experimental AIHA can be induced by injection of rat RBC to naive mice, but a lymphocyte‐mediated regulatory mechanism eventually suppresses the production of autoantibodies specific for mouse RBC. Critically, this tolerogenic response can be transferred to naive mice by splenocytes from the rat RBC‐immunized mouse. Here we investigate whether indoleamine 2,3 dioxygenase (IDO) or the initiators of IDO cascade, including the cytotoxic T lymphocyte antigen (CTLA)‐4 receptor and its soluble isoform, contribute to this tolerogenic mechanism. Splenocytes from experimental AIHA mice were transferred adoptively to naive mice under the cover of anti‐CTLA‐4, anti‐soluble CTLA‐4 antibodies or IDO inhibitor 1‐methyl tryptophan (1‐MT). Recipient mice were immunized with rat RBC and levels of antibody against self‐RBC and rat‐RBC were monitored. Our results indicate that transfer of tolerance to naive recipients is dependent upon IDO‐mediated immunosuppression, as mice receiving previously tolerized splenocytes under the cover of 1‐MT were refractory to tolerance and developed haemolytic disease upon further challenge with rat RBC. Initiators of IDO activity, CTLA‐4 or soluble CTLA‐4 did not mediate this tolerogenic process but, on their blockade, boosted antigen‐specific effector immune responses.     

The contribution of I-Abm12 to the production of autoantibodies to dsDNA.

The development of IgG autoantibodies to dsDNA in NZBxNZW F1 (NZB/W) and NZBxSWR F1 (SNF1) mice have been linked to specific alleles of MHC class II genes contributed by the NZW and SWR parents respectively. Recently, our laboratory has shown that the introduction of the bm12 mutation into NZB mice (NZB.H-2bm12) results in mice which are phenotypically similar to NZB/W F1 mice and, in particular, develop IgG anti-dsDNA antibodies. A variety of immune abnormalities have been described in autoimmune NZB (H-2d) mice. It is, however, unclear at present, whether all these abnormalities are due to the influence or effect of a single set of linked genes or due to multiple genes. It was reasoned that NZB.H-2bm12 mice provide a unique opportunity to examine this issue. Specifically, we bred a series of five different F1 colonies of mice: (a) NZB.H-2bm12/b F1; (b) NZB.H-2bm12/d F1; (c) NZB-H-2b/d F1; (d) NZB-H-2bm12 x B6.C-2bm12 F1 (NZB/B6.H-2bm12 F1); and (e) NZB x B6.C-H-2bm12 F1 (NZB/B6.H-2d/bm12 F1) mice. All groups of mice were serially followed for the appearance of IgM and IgG anti-ssDNA and anti-dsDNA antibodies, splenic CFU-B, spontaneous secretion of IgM, FMF analysis, proteinuria and survival. We report herein that H-2bm12 genes have a dominant influence on the appearance of IgG anti-dsDNA antibodies. In contrast, antibodies to ssDNA, IgM secreting cells, CFU-B and Ly-1 B cells are linked to genes from the NZB background. Finally, we particularly note an absence of IgG antibodies to dsDNA in NZB-H-2b/d F1 mice.     

Ionic binding characteristics of monoclonal autoantibodies to DNA from NZB.H-2bm12 mice

NZB (H-2d) mice are well known for the production of IgM autoantibodies to ssDNA. However, an F1 cross between NZB and either NZW or SWR mice is required to produce IgG nephritogenic antibodies to dsDNA and glomerulonephritis. The contribution of parental class II loci in the hybrid mice is clearly important to the development of anti-dsDNA antibodies. In contrast, NZB mice congenic with the Iabm12 mutation develop IgG autoantibodies to dsDNA despite being homozygous for Ia. As a part of our effort to examine the mechanisms of disease development in NZB.H-2bm12 mice, we have generated a panel of monoclonal antibodies against nucleic acids. A subgroup of these antibodies exhibited strong electrostatic interaction with nucleic acids as evidenced by inhibition of their binding by a moderate increase in ionic strength. Interestingly, the effect of salt was either all or none; e.g., antibodies were either markedly inhibited or virtually unaffected. The importance of this ionic interaction was highlighted by analysis of DNA binding of antibodies from serum and nephritic kidneys of NZB.H-2bm12 mice. Antibodies specific for ssDNA, which are common in NZB mice and not associated with nephritic lupus, are largely unaffected by salt. However, serum and kidney eluted IgG antibodies specific for dsDNA were markedly inhibited by salt. We postulate that B cell clones whose antibodies exhibit electrostatic interaction with DNA are preferentially expanded during the course of lupus in NZB.H-2bm12 mice and that such antibodies contribute significantly to glomerulonephritis.     

An Ig mu-heavy chain transgene inhibits systemic lupus erythematosus immunopathology in autoimmune (NZB x NZW)F1 mice.

Intrinsic defects in the B lymphoid lineage are involved in predisposition for systemic lupus erythematosus in (NZB x NZW)F(1) (NZB/W) mice. In addition, a contribution of CD4(+) T cells has been shown to be crucial for the development of fatal glomerulonephritis. To further dissect the role of B and T cells in lupus immunopathology we used Ig mu-heavy chain (muHC) transgenic (Tg) NZB/W mice that we recently established to study mechanisms of B cell tolerance. The Tg NZB/W mice have a very restricted B cell repertoire and only a very minor population of B cells having endogenously rearranged muHC Ig loci are able to undergo isotype switch. Here we analyzed the influence of the restricted B cell repertoire on the development of IgG anti-DNA antibodies and glomerulonephritis as well as the hyperactivation of T(h) cells. IgG anti-DNA antibodies developed delayed but consistently in the Tg NZB/W mice, suggesting that a strong selective mechanism for the development of these autoantibodies is operative. Despite significant autoantibody titers in Tg NZB/W mice, very little immune deposits in the glomeruli and no evidence for renal inflammation were found. The Tg mice have a significantly prolonged survival time and most of the Tg mice lived much longer than 1 year. Interestingly, the generalized T cell activation that normally correlates and coincides with the progression of the disease in NZB/W mice is strongly reduced in older Tg animals. The absence of IgG3 anti-DNA antibodies and the strong reduction of IgG2a anti-DNA antibodies in the Tg mice suggests that particularly the activation of T(h)1 cells is inhibited. This result shows that a significant restriction in the B cell repertoire prevents hyperactivation of T(h) cells and supports the model that T cell hyperactivation in NZB/W mice is secondary to specific interactions with a subpopulation of presumably autoreactive B lymphocytes.     

Systemic Lupus Erythematosus and Related Diseases

NZB (H-2^d) mice are well known for the production of IgM autoantibodies to ssDNA. However, an FI cross between NZB and either NZW or SWR mice is required to produce IgG nephritogenic antibodies to dsDNA and glomerulonephritis. The contribution of parental class II loci in the hybrid mice is clearly important to the development of anti-dsDNA antibodies, In contrast, NZB mice congenic with the la^bm12 mutation develop IgG autoantibodies to dsDNA despite being homozygous for Ia. As a part of our effort to examine the mechanisms of disease development in NZB.H-2^bm12 mice, we have generated a panel of monoclonal antibodies against nucleic acids. A subgroup of these antibodies exhibited strong electrostatic interaction with nucleic acids as evidenced by inhibition of their binding by a moderate increase in ionic strength. Interestingly, the effect of salt was either all or none; e.g., antibodies were either markedly inhibited or virtually unaffected. The importance of this ionic interaction was highlighted by analysis of DNA binding of antibodies from serum and nephritic kidneys of NZB.H-2^bm12 mice. Antibodies specific for ssDNA, which are common in NZB mice and not associated with nephritic lupus, are largely unaffected by salt. However, serum and kidney eluted IgG antibodies specific for dsDNA were markedly inhibited by salt. We postulate that B cell clones whose antibodies exhibit electrostatic interaction with DNA are preferentially expanded during the course of lupus in NZB.H-2^bm12 mice and that such antibodies contribute significantly to glomerulonephritis.     

Evidence for antigen presentation to sensitized T cells by thyroid peroxidase (TPO)-specific B cells in mice injected with fibroblasts co-expressing TPO and MHC class II

Injection of AKR/N mice with fibroblasts co-expressing MHC class II and TPO in the absence of adjuvant induces IgG-class TPO antibodies that resemble spontaneously arising human thyroid autoantibodies. We have used this model to examine the effect of iodide on TPO antibody induction as well as to analyse the interaction between T and B cells. Despite its importance as a major environmental factor in thyroid autoimmunity, variable iodide intake had no detectable effects on TPO antibody levels, lymphocytic infiltration of the thyroid or thyroid hormone levels. In terms of T cell responsiveness, splenocytes from TPO fibroblast-injected mice, but not from control mice, proliferated in response to TPO. Intriguingly, B cell-depleted splenocytes (mainly T cells without reduction of macrophages) proliferated in response to TPO only when co-cultured with irradiated autologous splenocytes from TPO fibroblast-injected mice but not from control mice. These data suggest that TPO-specific B cells are involved in antigen presentation to sensitized T cells and are supported by the ability of spleen cells from TPO cell-injected (but not control) mice to secrete TPO antibodies spontaneously in culture. In conclusion, we provide the first evidence for the presence of thyroid autoantigen-specific B cells and their ability to present their autoantigen to sensitized T cells in mice induced to develop TPO antibodies resembling autoantibodies in humans.     

Anti-mouse red blood cell monoclonal antibodies use functionally rearranged genes from the VH J558 family and are derived from the CD5- B-lymphocyte subpopulation.

Autoimmune haemolytic anaemia (AIHA) can be induced in mice by repeated injections with rat red blood cells (RBC). Here we describe the identification of murine RBC autoantigens and cross-reactive rat antigens. Sera and RBC eluates from the AIHA-positive mice immunoprecipitated a murine RBC autoantigen of 42,000 MW that comigrates with a zone of glycophorin in PAS-stained polyacrylamide gels. In addition, the eluates immunoprecipitated a 105,000 MW protein corresponding to band 3, the erythrocyte anion channel, and two further components of 34,000 and 29,000 MW within the glycophorin zone. The 42,000 MW band was not detected by immunoblotting, indicating that it bears autoantigenic epitope(s) that are denatured during electrophoresis. Cross-reactive autoantibody in the eluates immunoprecipitated a rat RBC protein that comigrated with band 3, together with two bands of 36,000 MW and 34,000 MW that may represent minor rat glycophorins. In contrast, rat-specific serum IgG from mice with AIHA reacted predominantly with major rat glycophorins of 75,000 MW and 38,000 MW. Immunoblotting revealed that normal murine sera contain IgG that binds autologous spectrin from the RBC membrane skeleton, and that this activity is increased in mice with AIHA. Sera from AIHA-positive mice also reacted with other internal murine RBC components that are not exposed on the surface of intact cells. It is evident from the data that immunization of mice with rat RBC results in the generation of multiple autoantibodies with a complex range of specificities.