A unique sequence of the NZW I-E beta chain and its possible contribution to autoimmunity in the (NZB x NZW)F1 mouse

Significance of MHC class II haplotypes and IgG Fc receptors in SLE

Systemic lupus erythematosus (SLE) is a systemic antibody-mediated autoimmune disease that develops under the control of multiple susceptibility genes. Genetic studies in murine and human SLE have identified several chromosomal intervals that contain candidate susceptibility genes. However, the ultimate identification of the genes and their roles in disease process need much further investigation. Spontaneous murine SLE models provide useful tools in this respect. In this chapter, we show this line of investigation, particularly focusing on the roles of major histocompatibility complex (MHC) class II and immunoglobulin G Fc receptors (FcgammaRs). The existence of high-affinity autoantibodies is evidence that autoimmunity in SLE is antigen-driven. Thereby, MHC class II haplotypes have been implicated in SLE susceptibility; however, because of the linkage disequilibrium that exists among the class I, II and III genes within the MHC complex, it has been difficult to discriminate the relative contributions of individual loci. On the other hand, the extent of antibody synthesis upon antigen stimulation and associated inflammatory cascades are controlled in several ways by the balance of stimulatory and inhibitory signaling molecules on immune cells. Stimulatory/inhibitory FcgammaRs mediate one such mechanism, and there are reports indicating the association between polymorphic FcgammaRs and SLE. However, as stimulatory and inhibitory FcgammaRs cluster on the telomeric chromosome 1, the absolute contribution of individual genes has been difficult to dissect. In studies of genetic dissection using interval-congenic and intragenic recombinant mouse strains of SLE models, we show evidence and discuss how and to what extent MHC class II molecules and stimulatory/inhibitory FcgammaRs are involved in SLE susceptibility.

Dissection of the role of MHC class II A and E genes in autoimmune susceptibility in murine lupus models with intragenic recombination

Systemic lupus erythematosus (SLE) is a multigenic autoimmune disease, and the major histocompatibility complex (MHC) class II polymorphism serves as a key genetic element. In SLE-prone (NZB x NZW)F(1) mice, the MHC H-2(d/z) heterozygosity (H-2(d) of NZB and H-2(z) of NZW) has a strong impact on disease; thus, congenic H-2(d/d) homozygous F(1) mice do not develop severe disease. In this study, we used Ea-deficient intra-H-2 recombination to establish A(d/d)-congenic (NZB x NZW)F(1) mice, with or without E molecule expression, and dissected the role of class II A and E molecules. Here we found that A(d/d) homozygous F(1) mice lacking E molecules developed severe SLE similar to that seen in wild-type F1 mice, including lupus nephritis, autoantibody production, and spontaneously occurring T cell activation. Additional evidence revealed that E molecules prevent the disease in a dose-dependent manner; however, the effect is greatly influenced by the haplotype of A molecules, because wild-type H-2(d/z) F(1) mice develop SLE, despite E molecule expression. Studies on the potential of dendritic cells to present a self-antigen chromatin indicated that dendritic cells from wild-type F(1) mice induced a greater response of chromatin-specific T cells than did those from A(d/d) F(1) mice, irrespective of the presence or absence of E molecules, suggesting that the self-antigen presentation is mediated by A, but not by E, molecules. Our mouse models are useful for analyzing the molecular mechanisms by which MHC class II regions regulate the process of autoimmune responses.

A novel susceptibility locus on chromosome 2 in the (New Zealand Black x New Zealand White)F1 hybrid mouse model of systemic lupus erythematosus

Systemic lupus erythematosus (SLE) is inherited as a complex polygenic trait. (New Zealand Black (NZB) x New Zealand White (NZW)) F(1) hybrid mice develop symptoms that remarkably resemble human SLE, but (NZB x PL/J)F(1) hybrids do not develop lupus. Our study was conducted using (NZW x PL/J)F(1) x NZB (BWP) mice to determine the effects of the PL/J and the NZW genome on disease. Forty-five percent of BWP female mice had significant proteinuria and 25% died before 12 mo of age compared with (NZB x NZW)F(1) mice in which >90% developed severe renal disease and died before 12 mo. The analysis of BWP mice revealed a novel locus (chi(2) = 25.0; p < 1 x 10(-6); log of likelihood = 6.6 for mortality) designated Wbw1 on chromosome 2, which apparently plays an important role in the development of the disease. We also observed that both H-2 class II (the u haplotype) and TNF-alpha (TNF(z) allele) appear to contribute to the disease. A suggestive linkage to proteinuria and death was found for an NZW allele (designated Wbw2) telomeric to the H-2 locus. The NZW allele that overlaps with the previously described locus Sle1c at the telomeric part of chromosome 1 was associated with antinuclear autoantibody production in the present study. Furthermore, the previously identified Sle and Lbw susceptibility loci were associated with an increased incidence of disease. Thus, multiple NZW alleles including the Wbw1 allele discovered in this study contribute to disease induction, in conjunction with the NZB genome, and the PL/J genome appears to be protective.

Genetic susceptibility to systemic lupus erythematosus

Considerable evidence suggests that the development of systemic lupus erythematosus (SLE) has a strong genetic basis. Recent studies have emphasized that this disease, like other autoimmune diseases, is a complex genetic trait with contributions from major histocompatibility complex (MHC) genes and multiple non-MHC genes. Etiologic genes in these disorders determine susceptibility, and no particular gene is necessary or sufficient for disease expression. Studies of murine models of lupus have provided important insight into the immunopathogenesis of IgG autoantibody production and lupus nephritis, and genetic analyses of these mice overcome certain obstacles encountered when studying patients. Genome-wide linkage studies of different crosses have mapped the position of at least 12 non-MHC disease-susceptibility loci in the New Zealand hybrid model of lupus. Although the identity of the actual genes is currently unknown, recent studies have begun to characterize how these genetic contributions may function in the autoimmune process, especially in terms of their role in autoantibody production. Studies of MHC gene contributions in New Zealand mice have shown that heterozygosity for particular haplotypes greatly increases pathogenic autoantibody production and the incidence of severe nephritis. The mechanism for this effect appears to be genetically complex. Studies in human SLE have mostly focused on the association of disease with alleles of immunologically relevant genes, especially in the MHC. Associations with various complement component deficiencies and an allele of a particular Fc gamma receptor gene (FCGR2A) also have been described. In a diversion from previous association studies, a recent directed linkage analysis of sibpairs with SLE was based on mapping studies in murine lupus and may be an important step toward identifying a new disease-susceptibility gene in patients. Since the genes that predispose to autoimmunity are probably related to key events in pathogenesis, their identification in patients and murine models will almost certainly provide important insight into the breakdown of immunological self-tolerance and the cause of autoimmune disease.

Contributions of Ea z and Eb z MHC Genes to Lupus Susceptibility in New Zealand Mice

Unlike parental New Zealand Black (NZB) or New Zealand White (NZW) mice, (NZB × NZW)F1 mice exhibit a lupus-like disease characterized by IgG autoantibody production and severe immune complex-mediated nephritis. In studies of the genetic susceptibility to disease in this F1 model, the NZW MHC (H2z) has been strongly linked with the development of disease, and it was hypothesized that class II MHC genes, particularly Ez genes, may underlie this genetic contribution. In the present study, we bred transgenic B6 mice expressing I-Ez or congenic B6 mice carrying H2z with NZB mice and used a backcross analysis to test the hypothesis that Eaz and/or Ebz genes account for the effect of H2z on disease. The genetic analysis of different backcross combinations showed that unlike mice carrying H2z, mice inheriting Ez transgenes do not demonstrate increased IgG autoantibody production or increased incidence of nephritis. Surprisingly, in the same transgenic backcross mice, inheritance of the endogenous H2b from the B6 strain was strongly linked with the production of IgG autoantibodies, but not with disease. Additional experiments suggested that the level of IgG3 autoantibody production, which is controlled by H2, may be important in the pathogenesis of renal disease. Contributions to autoantibody production were also detected from an NZB locus on distal chromosome 1 (previously named Nba2). Together, these studies provide new insight into the role of MHC in lupus-like autoimmunity.

Mixed haplotypes and autoimmunity

Why do (NZB x NZW)F1 mice develop an autoimmune lupus-like syndrome? The second exons of the class II genes of NZB and NZW are identical to their counterparts of H-2d and H-2u haplotypes. Several lines of evidence suggest that this allows the production of a mixed haplotype molecule, I-E alpha dE beta z, and that this molecule plays a key role in the development of autoimmunity.

Heterozygosity of the major histocompatibility complex controls the autoimmune disease in (NZW x BXSB) F1 mice

In the F1 hybrid of phenotypically normal NZW (H-2z) and systemic lupus erythematosus (SLE)-prone BXSB mice (H-2b), features of the disease became more severe than those seen in the BXSB mice, regardless of the presence or absence of the Yaa (Y-chromosome-linked autoimmune acceleration) mutant gene. To determine whether the gene(s) linked to the major histocompatibility complex (MHC) of NZW mice is involved in this event, we developed the H-2-congenic NZW.H-2d strain and compared the severity of autoimmune disease between (NZW x BXSB) F1 (H-2z/b) and (NZW.H-2d x BXSB) F1 mice (H-2d/b). The H-2z/b, but not H-2d/b, heterozygous F1 mice of both sexes showed an accelerated, higher incidence of proteinuria and a more severe thrombocytopenia than did the BXSB mice. In NZW x (NZW x BXSB) F1 backcross mice, the H-2z/b heterozygous progeny showed more severe disease than did the H-2z/z homozygotes. Thus, disease-accelerating events in (NZW x BXSB) F1 mice are linked to the H-2z/b heterozygosity. Because H-2d/z heterozygosity plays a crucial role for SLE in (NZB x NZW) F1 mice, in which SLE features differ from those in (NZW x BXSB) F1 mice, the present observations may imply that the different but related MHC heterozygosity acts as a predisposing genetic element in these different SLE syndromes.

Genetic regulation of CD5+ B cells in autoimmune disease and in chronic lymphocytic leukemia

CD5+ B cells have attracted much attention, because of their involvement in both autoimmunity and B cell-type chronic lymphocytic leukemia (B-CLL). B-CLL is a type of leukemia most often occurring among close relatives and is partly associated with the major histocompatibility complex (MHC), a finding relevant to autoimmune disease. We established MHC (H-2)-congenic NZB x NZW (NZB/W) F1 mice (H-2d/z, H-2z/z, and H-2d/d), in that only H-2d/z heterozygotes developed severe SLE, associated with IgG anti-DNA antibodies, as the animals aged. Such age-associated changes occurred in parallel with the decrease in the splenic, but not peritoneal, CD5+ B cells. By contrast, H-2z/z homozygotes did not develop SLE but, in turn, a marked clonal proliferation of CD5+ B cells resembling B-CLL did occur. H-2d/d homozygotes also did not develop the typical SLE, and a moderate CD5+ B frequency persisted. Despite the finding that all the three H-2-congenic NZB/W F1 strains produced IgM anti-DNA antibodies, only the H-2d/z heterozygotes produced IgG antibodies. Whereas the surface phenotype of major IgM producers was CD5+ sIgM+, that of IgG producers was CD5-sIgM-. Genetic and cellular analyses supported our thesis that in the heterozygotes IgM to IgG isotype switching probably emerges in CD5+ B cells and that this event is associated with the loss of CD5 molecules. Because of the lack of genetic elements required for differentiation, only signals for proliferation would be functioning in CD5+ B cells in the H-2z/z homozygotes. These observations infer that certain different, but related, MHC haplotypes may predispose either to B-CLL or to autoimmune disease in close relatives.

Background genes mediate the development of autoimmunity in (NZB x PL/J)F1 or (NZB x BIO.PL)F1 mice

The (NZB x NZW)F1 mouse develops a lupus-like disease including anti-double-stranded DNA antibodies and renal disease. It has been demonstrated that genes linked to the H-2 locus contributed by NZW correlate with development of this disease. We investigated whether mice with identical class II molecules but different background genes could contribute to autoimmunity when crossed with NZB. We report that two strains, PL/J and BIO.PL, when crossed to NZB, do not result in F1 with autoimmunity. Therefore, background genes present in NZW but not in PL/J or BIO.PL contribute to the development of disease.

Sequence of class II major histocompatibility complex genes from MRL mice. Conserved amino acids in the I-E beta chains from autoimmune mice

Class II major histocompatibility complex molecules are critical in both normal and abnormal immune responses. Both in mice and in humans, these molecules have been implicated in the development of various diseases, including insulin-dependent diabetes mellitus and systemic lupus erythematosus. The MRL/lpr mouse strain spontaneously develops a lupus-like illness with features that include anti-DNA antibodies, glomerulonephritis, and early death. We evaluated the structure of class II molecules from these mice, to investigate for unique sequences that might contribute to autoimmunity. Utilizing the polymerase chain reaction, we sequenced the second exons from the I-A and I-E genes of MRL/lpr and MRL-+/+ mice. We found that at the nucleotide level, there are several changes between MRL class II genes and the previously sequenced "k" haplotype, but at the protein level, they are identical. Furthermore, by comparing the sequences of class II genes from several strains of autoimmune mice, we found that there are conserved amino acids in the third hypervariable region of the I-E beta chain which may be important in the development of autoimmunity.

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.

T cell receptor V beta genes expressed by IgG anti-DNA autoantibody-inducing T cells in lupus nephritis: forbidden receptors and double-negative T cells

In the (SWR x NZB)F1 (SNF1) model of lupus nephritis, pathogenic variety of IgG anti-DNA autoantibodies are induced by certain T helper (Th) cells that are either CD4+ or CD4-CD8- (double negative; DN) in phenotype. From the spleens of eight SNF1 mice with lupus nephritis, 149 T cell lines were derived and out of these only 25 lines (approximately 17%) were capable of augmenting the production of pathogenic anti-DNA autoantibodies. Herein, we analyzed the T cell receptor (TcR) V beta genes used by 16 such pathogenic autoantibody-inducing Th cell lines. Twelve of the Th lines were CD4+ and among these five lines expressed V beta 8 (8.2 or 8.3). The V beta 8 gene family is contributed by the NZB parent to the SNF1 mice, since it is absent in the SWR parental strain. Three other CD4+ Th lines expressed V beta 4, another was V beta 2+ and one line with poor autoantibody-inducing capability expressed V beta 1. Four autoantibody-inducing Th lines from the SNF1 mice had a DN phenotype and these lines were also autoreactive, proliferating in response to syngeneic spleen cells. Among these DN Th lines, two expressed V beta 6 and one expressed V beta 8.1 TcR. Both of these are forbidden TcR directed against Mls-1a (Mlsa) autoantigens expressed by the SNF1 mice and such autoreactive T cells should have been deleted during thymic ontogeny. Thus, the DN Th cells of non-lpr SNF1 mice are different from the DN cells or MRL-lpr which lack helper activity and do not express forbidden TcR. The spleens of 6 out of 19 nephritic SNF1 animals tested also showed an expansion of forbidden autoreactive TcR+ cells that were mainly DN. Two of these animals expressed high levels of V beta 6 (anti-Mlsa) and V beta 11 (anti-I-E) TcR+ cells, three others had high levels of V beta 11+ cells alone and one animal had an expanded population of V beta 17a+ (anti-I-E) cells. The I-E-reactive TcR again should have been eliminated in the SNF1 thymus, since they express I-E molecules contributed by the NZB parent. The SWR parents of SNF1, are I-E-; moreover, they lack the V beta 11 gene but they express V beta 17a in peripheral T cells. Whereas the NZB parents are I-E+, they lack a functional V beta 17a gene and they delete mature V beta 11+ T cells.(ABSTRACT TRUNCATED AT 250 WORDS)

A polymorphic microsatellite in the tumor necrosis factor alpha promoter identifies an allele unique to the NZW mouse strain

We have amplified a (CA)n:(GT)n microsatellite from the TNF promoters of a panel of mouse strains using the polymerase chain reaction. The length of the microsatellites was polymorphic, with eight alleles observed among 15 inbred strains bearing seven distinct H-2 haplotypes, and four outbred strains. In B10 congenic strains, the TNF allele detected by microsatellite polymorphism segregated with the MHC, and in recombinant haplotypes (NOD, NZW), it segregated with H-2D. The TNF allele found in the NZW strain (H-2z) was distinct from those of all other haplotypes, consistent with the hypothesis that this strain may carry a genetic defect in TNF production.

Sequence of I-E genes from autoimmune New Zealand white mice

Autoimmune New Zealand white (NZW) mice contribute to (New Zealand black x New Zealand white)F1 mice 1 or more major histocompatibility complex-linked genes that strongly correlate with susceptibility to murine lupus. The NZW class II major histocompatibility complex genes, I-E alpha and I-E beta, were cloned and sequenced and found to differ from normal B10.PL (H-2u) mice by 3 amino acids in the first domain of the I-E beta subunit. Of these differences, the arginine at position 72 of NZW mice could be an important disease determinant since it lies in a predicted antigen-binding cleft.