Selective strain distribution pattern of a germline VH gene for a pathogenic anti-DNA autoantibody family

Autoimmune NZB mice rarely develop nephritis, but the SNF1, progeny of Crosses between NZB and the normal SWR strain uniformly develop severe lupus nephritis, indicating that the normal SWR strain makes a genetic contribution to the development of nephritis. The SNF1 mice produce a select population of cationic IgG anti-DNA autoantibodies that share a recurrent cross-reactive idiotype called Id564 and these autoantibodies play a prominent role in the development of nephritis. These pathogenic autoantibodies of SNF1 possess the IgCH allotype of the SWR, indicating their origin from the normal parent. The leader-VH sequences of these Id564+ pathogenic anti-DNA autoantibodies are highly homologous and they are also related by 95% homology to a germline gene of normal C57BL/6 mice, called VH-23, that is a member of an anti-NP antibody gene family. Herein, we cloned the flanking and coding regions of the expressed VHDJH genes of the anti-DNA mAb 564, the prototype member of the pathogenic Id564 family. By restriction analysis and partial sequencing, we found that the VH564 gene is related but distinct in its 5' flanking region from all of the known anti-NP VH genes of C57BL/6 and BALB/c mice. Hybridization with four probes complementary to different segments of the flanking and coding regions of the expressed VH564 gene indicated that the germline gene for VH564 is contained in an approximately 5.2 kb EcoRI fragment of SWR genomic DNA. Moreover, high stringency hybridization with oligonucleotide probes complementary to unique CDR2 and 5' flanking sequences of the expressed VH564 gene revealed that the 'approximately 5.2 kb' germline allele for VH564 that is possessed by the normal SWR parental strain is lacking in the NZB parental strain. C57BL/6 mice also lack this allele of the anti-DNA VH564 germline gene, although this strain possesses the highly homologous, anti-NP-related VH-23 germline gene. Thus germline VH genes for certain pathogenic autoantibodies may have a selective strain distribution pattern.     

The molecular origin of anti-DNA antibodies

The in vitro observation that a single point mutation in the protective anti-phosphorylcholine anti-bacterial antibody, S107, converts it into an autoantibody that reacts with dsDNA has focused our attention on the role of somatic mutation in generating autoantibodies. It has also led us to examine the significance of an individual's prior response to environmental antigens on the subsequent production of autoantibodies. The fact that genes of the S107 heavy chain variable region family could encode autoantibodies made it possible to clone and sequence the relevant germline genes of this small family from autoimmune (NZB x NZW)F1 mice and to compare these to the comparable genes in non-autoimmune mice. The germline genes from the normal and autoimmune mice are quite homologous and the small number of polymorphisms are not likely to predispose the autoimmune mice to the production of autoantibodies. (NZB x NZW)F1 mice respond to immunization with phosphorylcholine with a response that is largely encoded by the VH1 gene of the S107 family. However, when these same mice begin to make autoantibodies, their anti-DNA antibodies which are encoded by this family are in fact derived from the VH11 gene. The VH11 encoded anti-DNA antibodies which have been sequenced are all of the IgG2a subclass, react with dsDNA, and have undergone significant somatic diversification from the germline gene. Analysis of the ratio and location of the replacement and silent mutations suggests that the regulation of the autoantibody response differs from that of the normal response to foreign antigens. Our studies suggest that the utilization of a particular VH germline gene in the immune response to foreign antigens early in life does not lead to the preferential utilization of that same gene in the subsequent production of autoantibodies.     

Somatically mutated IgG anti-DNA antibody clonally related to germ-line encoded IgM anti-DNA antibody.

Among 15 anti-DNA antibody-producing hybridomas derived from a single NZB X NZW F1 mouse, an IgM and an IgG were shown to use the same VH gene of the Q52 family. Using a combination of two primers both consisting of a mixture of oligonucleotides (one complementary to the 5' end of VH segment and one to the 3' end of VH segment of Q52 family) we determined the sequences of several members of germ-line VH genes in the Q52 family derived from NZB and NZW strains. Comparison of the sequences with those of cloned VH cDNA obtained from the hybridomas revealed that the VH sequence of the IgM anti-DNA antibody was identical to that of a cloned NZW germ-line VH gene, except for the priming sites. In contrast, the VH sequence of the IgG counterpart contained somatically mutated nucleotides. Because the IgG anti-DNA antibody showed a higher DNA binding activity than did the IgM antibody, we conclude that these changes in nucleotide sequences were induced and selected through an antigen-driven mechanism as is the case in a normal immune response. It is tempting to speculate that the germ-line encoded, low-affinity IgM autoantibody undergoes somatic mutations and isotype switching, resulting in generation of pathogenic, high-affinity autoantibodies in autoimmune diseases.     

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)     

Contribution of the gene linked to the T cell receptor beta chain gene complex of NZW mice to the autoimmunity of (NZB x NZW)F1 mice.

We have investigated the contribution to the autoimmune disease of (NZB x NZW)F1 (NZB/W) mice made by the T cell receptor beta (TcR beta) chain gene complex, or genes linked to it, that are derived from the NZW strain. For this we developed the NZW.TcR beta NZB strain, a NZW congenic line carrying the TcR beta of NZB type, and produced NZB x NZW.TcR beta NZB (NZB/W.TcR beta NZB)F1 mice. We compared the amounts of anti-DNA and anti-histone antibodies and also the severity of lupus nephritis in these mice with those in the original NZB/W F1 mice. We obtained evidence for significantly lower serum levels of autoantibodies to double-stranded and single-stranded DNA and histone, and a later onset and a lower incidence of proteinuria in the NZB/W.TcR beta NZB F1 mice than in the original NZB/W F1 mice. These findings clearly indicate that the gene(s) within or closely linked to the TcR beta chain gene complex on chromosome 6 of the NZW strain acts to intensify the feature of systemic lupus erythematosus in the NZB/W F1 strain. The significant relationship of this finding to the strict dependency of NZB/W F1 disease on the H-2d/H-2z heterozygosity is discussed.     

Variable region sequences of pathogenic anti-mouse red blood cell autoantibodies from autoimmune NZB mice

New Zealand Black (NZB) mice spontaneously develop a severe autoimmune hemolytic anemia due to the production of anti-mouse red blood cell (MRBC) autoantibodies. The contribution of variable region genes and somatic mutations in the pathogenicity of anti-MRBC autoantibodies was investigated by mRNA sequencing of eight NZB anti-MRBC monoclonal autoantibodies, among which five are capable of inducing anemia in BALB/c mice. Here we report that at least three VH gene families (J558, J606 and 3609) and five Vchi subgroups (V chi 8, 9, 19, 21 and 28), in combination with several D, JH and Jchi gene segments, encode anti-MRBC autoantibodies. Thus, the NZB anti-MRBC autoantibodies, whether pathogenic or not, are encoded by a large number of immunoglobulin gene elements and by members of known VH and Vchi gene families with preferential usage of VH gene families most distal to the D regions. The presence of several mutations in the JH gene segments of both IgM and IgG anti-MRBC autoantibodies, whether pathogenic or not, strongly suggests that their VH regions may be highly mutated and that the mechanism of somatic diversification might be important in the generation of anti-MRBC autoantibodies. Our results support the idea that anti-MRBC autoimmune responses are likely to be generated by an antigen-driven mechanism.     

Accelerated autoimmunity and lupus nephritis in NZB mice with an engineered heterozygous deficiency in tumor necrosis factor

Development of autoimmunity and lupus nephritis in New Zealand (NZB x NZW)F1 mice, a model for human systemic lupus erythematosus (SLE), involves both MHC- and non-MHC-linked contributions. A characteristic reduced responsiveness of the Tnf gene, which derives from the NZW parent, has been considered contributory since replacement therapy modifies the course of disease. It has remained unclear whether imbalances in TNF production operate early at the level of autoimmune induction, or, whether TNF interferes with the development of glomerulonephritis independent of the ensuing autoimmunity. To directly assess if reduced TNF production alone is sufficient to exacerbate the innocuous autoimmune responses present in NZB mice, we crossed NZB mice with Tnf-deficient and normal background control mice. Unlike control groups, (NZB x Tnf(0))F1 hemizygous mice develop enhanced autoimmunity and severe renal disease similar to the (NZB x NZW)F1 mice. Autoimmune responses are associated with an early spontaneous increase in serum levels of anti-nuclear autoantibodies and hyperproliferating B cells which readily express anti-dsDNA specificities in response to polyclonal and T helper stimuli. These findings demonstrate a physiological role for TNF in suppressing the emergence of autoreactive lymphocytes in the NZB model, and indicate that defective TNF function may be causative of the autoimmune and pathological phenomena in lupus.     

The genetic contribution of the NZB mouse to the renal disease of the NZB x NZW hybrid.

The occurrence of lupus nephritis in (NZB x NZW)F1 mice appears to depend on the action of at least two dominant or co-dominant genes (at least one gene from each parent) as neither of the inbred parental strains shows the disorder. Identifying affected animals by antemortem determinations of renal function, using improved methods of measuring proteinuria and renal clearance, we have studied the incidence of the renal disease in 230 (NZB x NZW)F1 x NZW backcross mice. The incidence was 49-6% which indicates that NZB strain contributes only one gene, or cluster of closely linked genes, to the renal disorder of the F1 hybrid. The gene(s) must be dominant or co-dominant, as it expresses its effect in the heterozygous state. Study of the H-2 status of the backcross mice showed a loose linkage of the NZB renal disease gene(s) to the D end of the H-2 complex, the crossover frequency being 32-6+/-3-1%.     

Evidence for an interferon-inducible gene, Ifi202, in the susceptibility to systemic lupus

The Nba2 locus is a major genetic contribution to disease susceptibility in the (NZB x NZW)F(1) mouse model of systemic lupus. We generated C57BL/6 mice congenic for this NZB locus, and these mice produced antinuclear autoantibodies characteristic of lupus. F(1) offspring of congenic and NZW mice developed high autoantibody levels and severe lupus nephritis similar to (NZB x NZW)F(1) mice. Expression profiling with oligonucleotide microarrays revealed only two differentially expressed genes, interferon-inducible genes Ifi202 and Ifi203, in congenic versus control mice, and both were within the Nba2 interval. Quantitative PCR localized increased Ifi202 expression to splenic B cells and non-T/non-B cells. These results, together with analyses of promoter region polymorphisms, strain distribution of expression, and effects on cell proliferation and apoptosis, implicate Ifi202 as a candidate gene for lupus.     

Variable region sequences of autoantibodies from mice with experimental systemic lupus erythematosus

We have sequenced nine monoclonal antibodies (mAb) derived from C3H.SW mice in which experimental systemic lupus erythematosus (SLE) was induced. The hybridomas were selected for binding to DNA or to HeLa nuclear extract (NE). Three mAb were found to bind DNA, and are shown to exhibit sequence characteristics of pathogenic anti-DNA antibodies. One, mAb 2C4C2, is shown to use a heavy chain V region gene (V_H) identical to the V_H of anti-DNA mAb isolated from other lupus-prone mice, namely (NZB × NZW)F₁. The light chain V region gene (V_L) of mAb 2C4C2 is 98 % homologous to the V_L of another anti-DNA mAb, also isolated from (NZB × NZW)F₁ mice. The other two anti-DNA mAb, 5G12-4 and 5G12-6, share 93 % of their V_H sequences with that of mAb 2C4C2. Six mAb bound proteins of HeLa NE. Four of these six antibodies were found to use the VH124 V_H and V-L7 V_L. The nine mAb use a total of five V_H and four V_L germ-line genes, demonstrating that the autoantibodies induced in mice with experimental SLE do not originate from one B cell clone. Three of these nine V_H and V_L were identical in sequence to germ-line genes, while at least three others had somatic mutations. The latter suggests that the above autoantibodies arise in mice by both usage of existing (pre-immune) B cells, and through an antigen-driven process. Furthermore, it appears that autoantibodies found in mice with experimental SLE use genetic elements similar to those used by mAb that were isolated from mouse strains which develop lupus spontaneously.     

Immunization with peptides derived from the idiotypic region of lupus-associated autoantibodies delays the development of lupus nephritis in the (SWR x NZB)F1 murine model

Systemic lupus erythematosus (SLE) is a multiorgan autoimmune disease affecting 40-50/100,000 Americans. Although most of the research on pathogenic antibodies focuses on antigenic specificity, there is increasing evidence that specific immunoglobulin idiotypes may mediate lupus nephritis independent of autoantigen specificity. In previous work, our laboratory characterized a set of nephritogenic monoclonal antibodies with substantial idiotypic cross-reactivity, produced by the spontaneous SLE model (SWR x NZB)F(1) (SNF(1)), termed Id(LN)F(1). Peptides derived from one of these antibodies, Id540, was previously shown to stimulate pathogenic T-cells from prenephritic SNF(1) mice, similar to what has been seen for pathogenic A6.1 antibody produced by the (NZB x NZW)F(1) model. In this study, we immunized pre-nephritic SNF(1) mice with p62-73, a peptide derived from the variable region of Id540 and, in separate experiments, with p58-69, a peptide derived from the variable region of A6.1. In both cases, immunization resulted in increased survival and delayed nephritis; however, while both peptides affected levels of anti-DNA antibodies, immunization with p62-73 only affected levels of Id(LN)F(1) antibodies. These findings confirm the roles of pathogenic idiotypes in the pathogenesis of lupus nephritis and suggest that therapies that target specific idiotypes might be a potential tool in the management of SLE.     

Molecular and serological diversity of anti-DNA autoantibodies from NZB and (NZB X NZW) F1 mice

We have carried out an analysis of the serological and molecular diversity of a panel of monoclonal anti-DNA autoantibodies and serum autoantibodies from NZB and (NZB X NZW) F1 mice, in an attempt to obtain insights into the mechanisms responsible for the development of systemic autoimmune disease. Our data show that the autoantibodies are quite diverse. A dominant, binding-site idiotope on one of our monoclonal autoantibodies is expressed at variable levels in anti-DNA binding antibodies in the sera of both NZB and (NZB X NZW) F1 mice, but on none of the other monoclonal autoantibodies in our panel. We have cloned and sequenced the heavy chain variable region (VH) gene of one anti-DNA hybridoma and by hybridization have determined the VH and V kappa gene segments expressed by 14 others. All of the autoantibodies express members of known V gene subfamilies. A total of four different VH and at least six V kappa subfamilies are expressed by the hybridomas. Thus, a broad spectrum of the total murine Ig repertoire is represented in the anti-DNA autoantibodies present in these strains.     

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.     

IVIG-bound IgG and IgM cloned by phage display from a healthy individual reveal the same restricted germ-line gene origin as in autoimmune thrombocytopenia

Intravenous immunoglobulin preparations (IVIG) have shown positive effects in the treatment of immune defects and autoimmune diseases. It is not clear how IVIG interacts with the components of the immune system. To investigate this, we cloned previously a large number of phage displayed IgG Fab fragments derived from three patients with autoimmune thrombocytopenia (AITP) that were specifically bound by IVIG molecules. Many of these Fabs reacted with platelets. Sequencing revealed that the most frequently used germ-line gene segments of all IVIG-bound Fabs were identical to those observed for many other autoantibodies. Particularly, the loci 3-30 or 3-30/3-30. 5, 3-23 and 3r, 3l, and 2a2 represented the most abundant genes used for the heavy (VH) and light chain V region (VL), respectively. This suggested a specific interaction of IVIG molecules with B cells that present B cell receptors derived from these germ-line genes. In the current study we determined the genetic origin of IVIG-reactive IgG and IgM cloned from a healthy person. A favoured selection of antibodies derived from the same germ-line origins as in AITP was observed. Because 3-30 and 3-23 are the most frequently rearranged VH germ-line gene segments among human B cells, our results suggest that this favoured anti-idiotypic interaction may have an important role for the development and control of the normal B cell repertoire.     

Dominant NZB contributions to lupus in the (SWR x NZB)F1 model

(SWR x NZB)F1 (or SNF1) mice succumb to lupus nephritis. Analysis of NZB x SNF1 backcross mice has recently revealed the existence of four dominant SWR loci (H2 on Chr 17, Swrl-1 on Chr 1, Swrl-2 on Chr 14 and Swrl-3 on Chr 18), and two NZB loci (Nba1 and Lbw2/Sbw2, both on Chr 4) conferring lupus susceptibility. The present study focusing on a panel of 88 SWR x SNF1 backcross mice reveals the existence of five suggestive loci for antinuclear antibody formation, consisting of three dominant NZB contributions (Nba4 on Chr 5, Lbw4 on Chr 6, and Nba5 on Chr 7), and two recessive SWR contributions (Swrl-1 on Chr 1, and Swrl-4 on Chr 10). In addition, this study reveals a dominant NZB locus for GN (Nba3 on Chr 7, peak at 31 cM), and a dominant NZB locus linked to early mortality, on Chr 10 (peak at 4 cM). Collectively, these studies suggest that lupus in the SNF1 strain is the epistatic end-product of four dominant SWR loci and four dominant NZB loci. The immunological functions and molecular identities of these loci await elucidation.     

Sequence analysis of the germ-line VH gene corresponding to a nephritogenic antibody in MRL/lpr lupus mice.

In order to investigate the genetic origin of nephritogenic antibodies in MRL/Mp-lpr/lpr (MRL/lpr) lupus mice, we isolated the germ-line heavy chain variable region (VH) gene corresponding to the nephritogenic antibody, B1, derived from an unmanipulated MRL/lpr mouse. Injection of this antibody into C.B-17/Icr-scid/scid mice resulted in the generation of wire loop-like glomerular lesions resembling those of lupus nephritis. Nucleotide sequences of this germ-line VH gene showed no replacement mutation in the VH region of the B1 antibody. Furthermore, this gene was identical to that found in the C3H/HeJ-lpr/lpr strain of mice. Our results suggest that germ-line VH genes can encode nephritogenic antibodies without somatic mutation, even in a mouse strain not prone to lupus.     

A member of a new VH gene family encodes antibromelinized mouse red blood cell autoantibodies

A cDNA clone encoding the variable region of the heavy chain of a BALB/c antibromelinized mouse red blood cell (BrMRBC) monoclonal antibody has been characterized. The nucleic acid sequence indicates that the variable region of the heavy chain is likely encoded by variable-VCP12, diversity-DSP 2 (5, 7 or 8) and joining-JH1 germ-line genes. An identical combination of V genes was observed for six other CBA/J and NZB anti-BrMRBC hybridomas. The BALB/c VCP12 nucleotide sequence is less than 80% homologous to members of the 10 known VH families. Moreover, the genomic restriction fragments detected under moderate stringency conditions with the radiolabeled cDNA probe did not correspond to those obtained with probes of the most homologous VH families (7183 and X24). The results indicate that the VCP12 gene defines a new VH family which we propose to designate VH11. The observation of 1, 2 or 3 genomic restriction fragments at the most, with mice bearing the Igh-Vd or j, Igh-Va or b or Igh-Vc haplotypes, suggests the existence of a few VCP12-related genes.     

Molecular mechanisms resulting in pathogenic anti-mouse erythrocyte antibodies in New Zealand black mice.

The New Zealand black (NZB) mouse strain is genetically predisposed to develop, at approximately 6 months of age, a spontaneous and severe autoimmune anaemia caused by production of pathogenic anti-mouse erythrocyte autoantibodies. In order to investigate the molecular mechanisms which lead to anti-mouse erythrocyte autoantibody production we have generated eight anti-mouse erythrocyte MoAbs producing hybridomas from splenocytes of 9- and 12-month-old NZB with spontaneous autoimmune anaemia. IgG2a was the predominant isotype, while IgM, IgG1 and IgG2b were each produced by one hybridoma cell line. All anti-mouse erythrocyte MoAbs were characterized for their antigen specificities. None of the MoAbs cross-reacted with ss- or dsDNA or with other species' erythrocytes, with the exception of one MoAb which cross-reacted with rat erythrocytes. None of the eight hybridomas was demonstrated to express surface or cytoplasmic CD5, suggesting that they derived from CD5- B lymphocytes. All hybridomas when implanted intraperitoneally into BALB/c mice caused anaemia. In order to define the genetic basis and investigate the molecular mechanisms resulting in pathogenic anti-mouse erythrocyte autoantibody production, the pattern of immunoglobulin variable region gene use has been studied. Five of the eight MoAbs whose IgVH genes were sequenced all have functionally rearranged genes from the VH J558 gene family. There is evidence for somatic point mutations in the complementarity-determining regions (CDR) of the IgVH genes in all of these five MoAbs when compared with the closest known germline gene. We suggest that these nucleotide sequence changes are likely to reflect selection by an antigen-driven mechanism. Furthermore, the data indicate that pathogenic anti-mouse erythrocytes are not derived from 'natural' autoantibodies.     

The VH gene sequences of anti-DNA antibodies in two different strains of lupus-prone mice are highly related

The heavy and light chain V region sequences of an IgG anti-DNA autoantibody (PME77), derived from a lupus-prone (NZB x NZW)F1 mouse have been determined by mRNA sequencing. The V kappa gene segment belongs to the V kappa 1A gene sub-group and is found in several (NZB x NZW)F1 and MRL lpr/lpr anti-DNA antibodies, as well as in other antibodies of unrelated specificities. The VH gene segment appears to represent a unique gene or a subfamily of the large J558 VH gene family of the mouse, and is highly related to a germ-line sequence of a major anti-DNA idiotype (H130, IgM) of MRL mice. This anti-DNA-related VH segment has not been found, so far, to be expressed in antibodies with specificities for external or synthetic antigens; therefore, expression of such specificities may be regulated by powerful mechanisms of self tolerance in the healthy animal. In addition, both the heavy and light chain of the PME77 IgG antibody were found to contain somatic point mutations with a high ratio of replacement to silent mutations in complementarity determining regions. This IgM to IgG sequence relationship suggests an affinity maturation process, which is driven by the autoantigen.     

Murine models of systemic lupus erythematosus: B and T cell responses to spliceosomal ribonucleoproteins in MRL/Fas(lpr) and (NZB x NZW)F(1) lupus mice

(NZB x NZW)F(1) and MRL/Fas(lpr) lupus mice present a similar phenotype with a spectrum of autoantibodies associated with very severe nephritis. It is thought, however, that in contrast to other lupus-prone mice such as MRL/Fas(lpr) mice, (NZB x NZW)F(1) mice do not generate autoantibodies to ribonucleoproteins (RNP) Sm/RNP. In this study, we demonstrate that contrary to previous reports, the autoimmune response directed against Sm/RNP antigens also occurs in NZB x NZW mice. CD4(+) T cells from unprimed 10-week-old NZB x NZW mice proliferate and secrete IL-2 in response to peptide 131-151 of the U1-70K protein, which is known to contain a T(h) epitope recognized by CD4(+) T cells from MRL/Fas(lpr) mice. Peptide 131-151, which was found to bind I-A(k) and I-E(k) class II MHC molecules, also bound both I-A(d) and I-E(d) molecules. This result led us to also re-evaluate longitudinally the anti-Sm/RNP antibody response in NZB x NZW mice. We found that 25-week-old mice do produce antibodies reacting with several small nuclear and heterogeneous nuclear (hn) RNP proteins, such as SmD1, U1-70K and hnRNP A2/B1 proteins. The fine specificity of these antibodies was studied with overlapping synthetic peptides. The same antigenically positive and negative peptides were characterized in MRL/Fas(lpr) and NZB x NZW mice in the three proteins. This new finding can help to understand the mechanisms involved in the development of the anti-Sm/RNP antibody response and, particularly, the role played by non-MHC genes in this autoimmune response.