Structural characteristics of the variable regions of immunoglobulin genes encoding a pathogenic autoantibody in murine lupus

Differences in V kappa gene utilization and VH CDR3 sequence among anti-DNA from C3H-lpr mice and lupus mice with nephritis

To investigate the molecular properties of anti-DNA from lpr mice that express high levels of anti-DNA without immune-mediated nephritis, the sequences of VH and V kappa genes encoding 11 monoclonal anti-DNA antibodies derived from C3H-lpr/lpr (C3H-lpr) mice were studied. All of the C3H-lpr monoclonal anti-DNA bound single-stranded DNA while five also bound double-stranded DNA. Two of the hybridomas were clonally related as determined by Southern analysis and sequencing. Sequence analysis of C3H-lpr anti-DNA revealed the use of VH genes that encode anti-DNA from the MRL-lpr/lpr and (NZB X NZW) F1 mouse models of lupus, although differences occurred in the VH CDR3 amino acid content. In contrast, the V kappa genes from C3H-lpr mice lacked significant identity with previously reported V kappa genes for anti-DNA from lupus models. These results indicate that anti-DNA from C3H-lpr mice differ from anti-DNA from lupus mice with nephritis in patterns of V gene expression and suggest a molecular basis for the lack of pathogenicity of anti-DNA in these mice.

Structural properties and mutation patterns of anti-nucleosome monoclonal antibodies are similar to those of anti-DNA antibodies

Four monoclonal antibodies (mAb) derived from an (NZB x NZW)F1 mouse bound to nucleosomes, total histones and to the H2A-H2B dimers but not to individual histones or DNA. Sequencing of their heavy (H)- and light (L)-chain variable region genes showed that they derived by somatic mutations from the same B cell precursor. The distribution of negatively and positively charged amino acids in the H-chain complementarity-determining regions was very similar to that observed not only in anti-H2A-H2B mAb derived from different lupus-prone mouse strains but also in anti-DNA mAb. Combined analysis of the mAb structures and their interactions with immobilized H2A-H2B dimer or total histones by plasmon resonance allowed us to assign the H-chain mutations a major role in the binding profiles of these anti-nucleosome mAb. Interestingly, four of the five H-chain mutations that distinguished mAb 3F6 from 2E1 generated negatively or positively charged amino acid residues, and two of them occurred at positions 56 and 76, which are frequently involved in the maturation process of anti-DNA antibodies. A modeling study of the 3F6 variable fragment (Fv) predicted that acidic residues occupy the cleft of the Ab combining site and have the potential to participate in electrostatic interactions. Thus, the demonstration that (NZB x NZW)F1-derived anti-H2A-H2B antibodies share certain structural features and mutation patterns with anti-DNA mAb suggest that common selection and maturation processes account for the production of these lupus-related autoantibodies.

Lupus autoantibodies interact directly with distinct glomerular and vascular cell surface antigens

We have identified monoclonal anti-DNA antibodies derived from lupus prone MRL-lpr/lpr mice that produce glomerular immune deposits and nephritis after passive transfer to normal mice. Particularly noteworthy is that the location of immune deposition varied among nephritogenic Ig, and this was associated with distinctive histologies and clinical disease profiles. Although their autoantigen binding properties differed, they were highly cross-reactive, in a manner similar to Ig deposited in glomeruli of lupus mice. This antigen binding profile was also typical of other previously described nephritogenic autoantibodies that bound directly to glomerular antigens to initiate immune deposit formation. In this study, we questioned whether ligation of different glomerular antigens by individual autoantibodies could contribute to the observed differences in the location of immune deposits. To examine this possibility, monoclonal anti-DNA antibodies (IgG2a) that produced glomerular immune deposits in different locations were evaluated. H221 produced mesangial, intracapillary (that is, intraluminal or within the capillary lumen) and subendothelial deposits associated with heavy proteinuria, whereas H147 produced mesangial, subendothelial and linear basement membrane deposits associated with proliferative glomerulonephritis. Initially, the capacity of H221 and H147 to bind directly to glomerular and vascular cell surfaces was evaluated. As demonstrated by FACS, H221 bound preferentially to mesangial cells whereas H147 bound preferentially to endothelial cells. To identify possible target cell surface antigens, Western blots, immunoprecipitation of surface labeled cells, and 2D gel electrophoresis were employed. H221 reacted with a 108 kDa protein on mesangial cells not identified by H147, whereas H147 reacted with a 45 kDa protein on endothelial cells not identified by H221. These results support the hypothesis that some nephritogenic lupus autoantibodies initiate immune deposit formation through direct interaction with glomerular antigens. Furthermore, they suggest that the site of immune deposition is determined by both antigen binding properties of the relevant antibody and the location of its target ligand within the glomerulus. In a given individual, therefore, the predominant autoantibody-glomerular antigen interaction may influence the morphologic and clinical phenotype expressed. Variation in the predominant interaction may also contribute to variations in disease expression among individuals with lupus nephritis.

Ligand recognition by murine anti-DNA autoantibodies. II. Genetic analysis and pathogenicity

Although anti-DNA autoantibodies are an important hallmark of lupus, the relationships among anti-DNA structure, reactivity, and pathogenicity have not been fully elucidated. To further investigate these relationships, we compare the variable genes and primary structure of eight anti-DNA mAbs previously obtained from an MRL/MpJ-lpr/lpr mouse along with the ability of three representative mAbs to induce nephritis in nonautoimmune mice using established adoptive transfer protocols. One monospecific anti-single-stranded (ss) DNA (11F8) induces severe diffuse proliferative glomerulonephritis in nonautoimmune mice whereas another anti-ssDNA with apparently similar in vitro binding properties (9F11) and an anti-double-stranded DNA (4B2) are essentially benign. These results establish a murine model of anti-DNA-induced glomerular injury resembling the severe nephritis seen in lupus patients and provide direct evidence that anti-ssDNA can be more pathogenic than anti-double-stranded DNA. In vitro binding experiments using both protein-DNA complexes and naive kidney tissue indicate that glomerular localization of 11F8 may occur by recognition of a planted antigen in vivo. Binding to this antigen is DNase sensitive which suggests that DNA or a DNA-containing molecule is being recognized.

Functional and modelling studies of the binding of human monoclonal anti-DNA antibodies to DNA

The relationships between the antigen-binding specificities of four human monoclonal anti-DNA antibodies and the structural aspects of the combining sites of two of these were examined. Competition ELISAs were used to examine the reactivities of two IgM MAbs (WRI-176 and RT-79) and two IgG mAbs (D5 and B3) to a wide range of polynucleotides. The mAbs WRI-176 and RT-79 were found to bind predominantly ssDNA, with a preference for poly (dT), whilst D5 and B3 bound components of both ss- and dsDNA, and Z-DNA. The mAb B3 also exhibited a preference for A(T) rich nucleotides. Computer models were generated for the Fv regions of WRI-176 and B3. Models for RT-79 and D5 were not generated as the structure of the long CDR-H3 loops in these mAbs could not be predicted. The B3 combining site contains a groove flanked by three arginines at positions CDR-L1-27A, CDR-L2-54 and CDR-H2-53. Using interactive molecular graphics, B-DNA was docked into the B3 antigen combining site along the plane of the VH/VL interface, whilst Z-DNA was best-fitted at approximately 90 degrees to this direction. The models provide a hypothesis to explain the ability of a single autoantibody to bind two different antigens. In addition, aspects of the base specificity of B3 may be explained. The model of the WRI-176 Fv region revealed a relatively flat surface, on which a large number of hydrophobic and aromatic residues were present. Trp-H52, in particular, is prominent on the surface. This may participate in ssDNA binding through base stacking interactions. The models allow identification of potential targets for site-directed mutagenesis.

Ligand recognition by anti-DNA autoantibodies. Affinity, specificity, and mode of binding

Understanding the molecular basis of DNA recognition by anti-DNA autoantibodies is a key element in defining the role of antibody.DNA complexes in the pathogenesis of the autoimmune disorder systemic lupus erythematosus. As part of our efforts to relate anti-DNA affinity and specificity to antibody structure, and ultimately to disease pathogenesis, we have generated a panel of eight anti-DNA mAbs from an autoimmune MRL MpJ-lpr/lpr mouse and have assessed the binding properties of these antibodies. We find that none of our anti-DNA mAbs bind to RNA and only one low-affinity mAb cross-reacts with non-DNA antigens, albeit weakly. None of the mAbs in our panel bind double-stranded DNA exclusively. Antibodies that recognize single-stranded DNA can be categorized into two groups based on their affinity and apparent mode of binding. One group possesses relatively high affinity for oligo(dT) and may recognize single-stranded DNA ligands by accommodating thymine bases in hydrophobic pockets on the antigen binding site. The second group binds more weakly, apparently recognizes single-stranded DNA nonspecifically, and in some cases also binds double-stranded DNA. Although different mechanisms are used for binding single- and double-stranded ligands, the mode of DNA recognition appears conserved within groups of antibodies.

Heavy chain dominance in the binding of DNA by a lupus mouse monoclonal autoantibody

Antibodies H241 and 2C10 are lupus mouse IgG autoantibodies that bind native DNA. In previous experiments, oligonucleotide antigens affinity-labeled both H and L chains of H241 but only the H chain of antibody 2C10. Primary structures of the V regions of the 2C10 H and L chains and the H241 L chain, determined from cDNA, help to explain the previous affinity-labeling experiments. The 2C10 L chain CDRs had several Asp residues and a net negative charge of five, whereas the 2C10 H chain CDRs had four Arg residues and a net positive charge of five. The L chain CDRs of H241 had a net positive charge of one. [The H241 H chain cDNA sequence was published previously by Gangemi et al. (1993) J. Immun. 151, 4660-4671]. Plasmid vectors were used for bacterial expression of H and L chains of 2C10 alone and in combinations in single chain Fv (scFv) molecules. The H chain alone bound native DNA as well as or better than the H-plus-L chain scFv. The H chain alone also bound Z-DNA. Combination of the 2C10 H chain with the L chain of an anti-Z-DNA antibody maintained the selectivity for Z-DNA, whereas its combination with the 2C10 L chain (in the 2C10 Fab) yielded selective B-DNA binding. The results with 2C10 match other examples in which the H chain is sufficient for DNA binding but selectivity is modulated by the L chain. The H chain binding to autoantigen may reflect selective events in early stages of B cell development.

Immune tolerance to autoantibody-derived peptides delays development of autoimmunity in murine lupus

Mechanisms that initiate and maintain autoantibody (autoAb) production in individuals with autoimmune diseases like SLE are poorly understood. Inadequate suppression of autoreactive T cells and/or unusual activation of T and B cells may underlie the persistence of pathogenic autoAbs in lupus. Here, we examine the possibility that in mice with lupus, autoAb molecules may be upregulating their own production by activating self-reactive T cells via their own processed peptides; downregulation of this circuit may decrease autoAb production and delay the development of lupus. We found that before the onset of clinical disease, lupus-prone (NZB/NZW) F1 [BWF1] (but not MHC-matched nonautoimmune mice) developed spontaneous T cell autoimmunity to peptides from variable regions of heavy chains (VH) of syngeneic anti-DNA mAbs but not to peptides from the VH region of an mAb to an exogenous antigen. Tolerizing young BWF1 mice with intravenous injections of autoAb-derived determinants substantially delayed development of anti-DNA antibodies and nephritis and prolonged survival. Thus, in such an autoAb-mediated disease, the presence of autoreactive T cells against VH region determinants of autoAbs may represent an important mechanism involved in the regulation of autoimmunity. Our findings show that tolerizing such autoreactive T cells can postpone the development of an autoimmune disease like SLE.

Anti-nuclear antibody production and immune-complex glomerulonephritis in BALB/c mice treated with pristane

The pathogenesis of systemic lupus erythematosus is thought to be primarily under genetic control, with environmental factors playing a secondary role. However, it has been shown recently that intraperitoneal injection of pristane (2,6,10,14-tetramethylpentadecane) induces autoantibodies typical of lupus in BALB/c mice, a strain not usually considered to be genetically susceptible to the disease. In this study, the induction of autoimmune disease by pristane was investigated. BALB/c mice receiving pristane were tested for autoantibody production and histopathological evidence of glomerulonephritis. Six of 11 mice developed IgM anti-single-stranded DNA antibodies shortly after receiving pristane and 4 developed IgM anti-histone antibodies, but anti-double-stranded DNA antibodies were absent. IgG anti-DNA and anti-histone antibodies were absent. In contrast, the lupus-associated anti-nuclear ribonucleoprotein/Sm and anti-Su autoantibodies produced by these mice were predominantly IgG. In addition to autoantibodies, most of the mice developed significant proteinuria. Light microscopy of the kidney showed segmental or diffuse proliferative glomerulonephritis. Electron microscopy showed subepithelial and mesangial immune-complex deposits and epithelial foot process effacement. Immunofluorescence revealed striking glomerular deposition of IgM, IgG, and C3 with a mesangial or mesangiocapillary distribution. Thus, pristane induces immune-complex glomerulonephritis in association with autoantibodies typical of lupus in BALB/c mice. These data support the idea that lupus is produced by an interplay of genetic and environmental factors and that unlike the MRL or (NZB x W)F1 mouse models, in which genetic susceptibility factors are of primary importance, environmental factors are of considerable importance in the autoimmune disease of pristane-treated BALB/c mice.

Normal human cord blood B cells can produce high affinity IgG antibodies to dsDNA that are recognized by cord blood-derived anti-idiotypic antibodies

It is possible to identify, in Epstein-Barr virus-transformed normal human cord blood B cell populations, cells present at a low frequency that produce IgG antibodies specific for dsDNA. By cloning out these B cells as immortalized monoclonal cell lines, it could be shown that the antibodies were the products of CD5 positive B cells. Two monoclonal anti-dsDNA antibodies were derived from cell lines T52 and A7 and these were further characterized as anionic (pI approximately 6.4) IgG4 kappa antibodies that bound with affinities of 7.18 x 10(9) l/mol and 3.28 x 10(9) l/mol, respectively, to dsDNA but did not bind to ssDNA. These affinities were similar to those of polyclonal IgG anti-dsDNA antibodies from lupus patients, which ranged from 1 x 10(9) -8.9 x 10(10) l/mol. Both T52 and A7 monoclonal anti-dsDNA antibodies were recognized by cord blood-derived IgM antibodies. These IgM antibodies were not rheumatoid factors but bound to the F(ab')2 of A7 and T52 while failing to recognize T50, which is an autologous IgG4 kappa monoclonal antibody without specificity for dsDNA. A cloned B cell line A24 generated from the same cord blood sample as A7 produced an IgM monoclonal antibody that bound to the heavy chains of T52 and A7, but not T50 on Western blot and inhibited the binding of these antibodies to dsDNA. A7 and T52 competitively inhibited each other in their binding to the anti-idiotype A24, and A24 inhibited the binding to dsDNA of some polyclonal IgG anti-dsDNA antibodies purified from sera of lupus patients. The level of inhibition of binding of these antibodies to dsDNA was directly proportional to the levels of expression of the idiotype recognized by A24 on these antibodies. The normal human cord blood, therefore, may contain cells that form an idiotype/anti-idiotype network in which the idiotype is expressed on IgG antibodies with specificity for dsDNA and the anti-idiotype is an IgM antibody that binds to a heavy chain idiotope in such a way as to interfere with its interaction with dsDNA. The presence of a similar idiotype on some polyclonal anti-dsDNA antibodies in lupus that are similarly inhibitable by the cord blood-derived anti-idiotype raises the possibility that this network may persist in later life and perhaps become dysfunctional in systemic lupus erythematosus.

Mechanisms of the pathogenic autoimmune response in lupus: prospects for specific immunotherapy

A major step towards understanding the basic mechanism of systemic lupus erythematosus (SLE), the prototypic autoimmune disease that develops spontaneously, has been the identification of nucleosomes as a primary immunogen in this disease. The production of pathogenic autoantibodies in SLE results from an MHC class-II-restricted, cognate interaction between select populations of T helper cells and B cells that are specific for nucleosomal components. These observations pave the way for specific immunotherapy that blocks this pathogenic T and B cell interaction.

An idiotype D23-bearing polyspecific, murine anti-DNA monoclonal antibody forms glomerular immune deposits. Pathogenic role of natural autoantibodies?

Identification of the immunochemical and structural properties of pathogenic anti-DNA antibodies is a major goal for understanding their origins and the mechanisms whereby they induce tissue lesions. Herein, we report on the production of an IgG2a,k anti-DNA monoclonal antibody (4B1), derived from a 12-month-old (NZB x NZW)F1 lupus mouse, able to form glomerular immune deposits. mAb 4B1 is a polyspecific antibody able to bind to ssDNA, actin, tubulin, cardiolipin and to laminin as shown by solid phase ELISAs. Indirect immunofluorescence labeling of HEp-2 cells gave a cytoplasmic staining pattern similar to that obtained with anti-cytoskeleton antibodies. Western blot analysis demonstrated that mAb 4B1 bore idiotype D23, previously shown to be characteristic of natural antibodies derived from normal mice. After injecting the 4B1-secreting hybridoma intraperitoneally into normal (NZW x BALB/c)F1 mice, glomerular immune deposits were observed along the capillary wall. These deposits contained mainly IgM, IgG2a and mAb 4B1, as demonstrated by direct immunofluorescence using a biotinylated-rat anti-4B1 idiotype mAb and kidney eluate analysis. Nucleotide sequence analysis of the VH and VL genes showed that mAb 4B1 is encoded by VH Q52, DSP2.9 and JH2 genes with minimal mutations and by VK8 very similar to the canonic D23 light chain, and JK1 germline genes. No arginine residues were observed in the VH CDR and both chains lacked N-segment addition. Thus, no structural characteristics deduced from the primary structure of mAb 4B1 could explain its pathogenic potential. However, the immunochemical and structural properties suggest that autoantibodies closely related to natural autoantibodies may be pathogenic.

Cerebrovascular disease with antiphospholipid antibodies: immune mechanisms, significance, and therapeutic options

There has been a recent, dramatic surge in interest in antiphospholipid antibodies and associated clinical disorders, especially focal ischemic cerebrovascular disease. Antiphospholipid antibodies are a heterogeneous group of antibodies with varying specificities. Coagulation assays will detect lupus anticoagulants while enzyme-linked immunosorbent assays detect anticardiolipin antibodies. There are numerous potential links between antiphospholipid antibodies and coagulation disorders, including interaction of antiphospholipid antibodies and a cofactor, beta 2-glycoprotein I, which itself is involved in coagulation mechanisms. While the specific mechanism of antiphospholipid antibody-related coagulopathy is unknown, it is clear that antiphospholipid antibodies are associated with an immune-mediated prothrombotic state. Patients with the highest titers of IgG antiphospholipid antibodies have a relatively high risk of recurrent thrombotic events, especially stroke, deep venous thrombosis, and spontaneous abortion. Because of limited controlled, prospective data, current therapy remains empiric and directed at coagulation mechanisms, immune mechanisms, or both.

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.

The role of the immunoglobulin heavy chain in human anti-DNA antibody binding specificity

OBJECTIVE

To investigate the structural basis for DNA binding of the natural human IgM lambda monoclonal antibody KIM4.6.

METHODS

An IgM lambda, non-DNA-reactive variant hybridoma was derived during in vitro subcloning of the anti-DNA antibody KIM4.6. The variable (V)-region heavy (H) and light (L) chain genes expressed by the variant hybridoma were amplified by polymerase chain reaction, cloned, sequenced, and compared with those of the KIM4.6 parent and other DNA-binding and non-DNA-binding antibodies.

RESULTS

The VL chain of the variant was identical to that of KIM4.6. In contrast, the VH chain was completely different from the VH chain of the parent but was similar or identical, except in the diversity (D) and joining regions, to the VH chain of the systemic lupus erythematosus (SLE) IgG anti-DNA antibody T14 and SLE IgM nephritogenic anti-DNA antibodies NE-1 and NE-13.

CONCLUSION

The expression of the KIM4.6 VL chain is not sufficient for DNA specificity. The VH chain and its D region play a key role in conferring DNA binding of the KIM4.6 anti-DNA antibody.

Isolated VH4 heavy chain variable regions bind DNA characterization of a recombinant antibody heavy chain library derived from patient(s) with active SLE

In many autoimmune diseases autoantibodies are intimately involved in disease manifestations. Molecular characterization of these autoantibodies should provide insights into the pathogenesis of these diseases, as well as suggest novel avenues for development of therapeutics. While some prior studies suggest that DNA binding may be a characteristic of individual heavy chain variable regions, the ability of these V regions to bind DNA in isolation has not been investigated. We have utilized a bacterial vector for cloning and expressing isolated antibody heavy chain variable regions. RNA was extracted from peripheral blood mononuclear cells of patients with active SLE, cDNA synthesized and heavy chain V regions amplified with VH specific oligonucleotide primers. The VH fragments were cloned into a bacterial expression plasmid including the pelB leader peptide to direct appropriate expression. Recombinant antibodies were screened for binding to 32P-labeled double-stranded plasmid DNA and later also characterized for binding to single-stranded DNA. Binding was confirmed by standard ELISA methodology. Sequence analysis of seven DNA binding VH fragments revealed that they utilized the VH gene family previously described to be associated with autoimmune responses, with a JH6 segment. On VH sequence analysis only one residue substitution in the consensus sequence is needed to form a VH4 germline gene. Potential contact residues with DNA were delineated by three-dimensional structure analysis. We concluded that the DNA binding characteristics of VH regions can be examined in the absence of light chain. DNA binding specificity appears to be a property of the germline VH4 gene. Analysis of such V regions can aid in the identification of hypervariable region contact residues important for DNA binding.

Structural properties of a subset of nephritogenic anti-DNA antibodies

Structural analysis of lupus autoantibodies is beginning to provide clues to the molecular basis for antigenic specificity and pathogenicity. The present analysis indicates that multiple light and heavy chains contain residues which can facilitate DNA binding, reaffirming the notion that there are multiple ways that different amino acids combine to form an antigen-binding pocket with affinity for dsDNA and ssDNA. Furthermore, this analysis suggests that these conformations and contact residues are intrinsic to germline sequences, although amino acid changes at critical locations (somatically introduced) modulate antigen binding, and appear to influence the capacity of individual immunoglobulin to form immune deposits. Analysis of additional individual immunoglobulins with closely related V-region sequences and differing pathogenic properties will be required to resolve the contribution of specific motifs to pathogenecity.

Germline-encoded IgG antibodies bind mouse cartilage in vivo: epitope- and idiotype-specific binding and inhibition

Autoantibodies specific for type-II collagen (CII) occur in mice and rats with collagen-induced arthritis (CIA). The binding in vitro and in vivo of mouse monoclonal antibodies (MoAbs) specific for separate epitopes in CII have been investigated. Two-day-old mice were injected intraperitoneally (i.p.) with the anti-CII antibody CIID3 in both unlabelled and biotinylated form. It was found that antibodies binding to the same epitope in CII in vivo can inhibit others from binding in an epitope-specific fashion. The binding in vivo and in vitro of anti-CII antibodies could be inhibited also by an anti-idiotypic rat antiserum produced against the D3 antibody. The anti-idiotypic antiserum inhibited the binding of the antibody D3 and the idiotypically related antibody C2. The cDNA's of anti-CII antibodies D3, C2, and F4 were sequenced and found to contain germline encoded V-genes, apparently without somatic mutations. The variable heavy chain of D3 and C2 both expressed the same VH rearrangement, confirming that they share idiotypes. This report demonstrates that CII-specific germline-encoded IgG autoantibodies bind specifically to normal cartilage in vivo via their combining site.

Beneficial effect of polyclonal immunoglobulins from malaria-infected BALB/c mice on the lupus-like syndrome of (NZB x NZW)F1 mice

We previously reported that infection of BALB/c mice with the parasite Plasmodium chabaudi induces high production of natural autoantibodies. Here we demonstrate that such an infection of lupus-prone (NZB x NZW)F1 (B/W) mice retards the development of their autoimmune disease. Survival and disease hallmarks (high-grade proteinuria and IgG anti-DNA antibodies) were delayed for 6 months when parasite inoculation was given at either 3 or 7 months of age, i.e. before or after the onset of the clinical symptoms. Similar beneficial effects, although less pronounced, were obtained when mice were treated with a total of 800 micrograms of IgG (P-IgG) or IgM (P-IgM) or 300 micrograms of cryoglobulin preparations isolated from P. chabaudi-infected BALB/c mice while similarly prepared fractions from uninfected mice had little effect. Compared to these fractions, P-IgG and P-IgM contained higher levels of natural antibodies bearing the D23 idiotype characteristic of polyreactive natural autoantibodies with enhanced activity against Fab and Fc fragments of IgG. In surviving mice, the level of anti-DNA antibodies, particularly those of IgG1 isotype, were significantly decreased. Flow cytometric analysis of various T cell subsets showed that the number of cells expressing gamma delta T cell receptor (TcR) antigens which did not vary with age was not modified after P-IgG or P-IgM treatment. In contrast, the number of T cells expressing V beta 8.1,2,V beta 10 and V beta 14 TcR antigens, which increased with age, were significantly reduced. Taken together, these results indicate that parasite infection of mice induces the synthesis of populations of IgM and IgG natural autoantibodies with immunoregulatory properties and that these antibodies attempt, at least transitorily, to rescue a natural autoantibody network that is deficient in B/W mice.

Lupus autoantibodies to native DNA cross-react with the A and D SnRNP polypeptides

Antibodies to native DNA (nDNA) in sera from patients with systemic lupus erythematosus have been found to frequently correlate with antibodies to the A and D SnRNP proteins measured in Western blot assays. 40 of 54 SLE (74.1%) sera with anti-nDNA bound to A and D proteins, while 9 of 113 sera (8%) without anti-nDNA bound the A and D proteins, P < 10(-8) by Fisher's exact test. Antibodies to nDNA correlated closely with anti-A and anti-D in seven of eight patients followed sequentially, r = 0.7865. Nine human polyclonal anti-nDNA populations were isolated from DNA cellulose columns. Seven reacted equally with A and D, and two reacted predominantly with D. Two of three murine monoclonal anti-DNA antibodies isolated from NZB/NZW F1 hybrid mice bound A and D equally in Western blot with a titer > 1/40,000. These reactions were directed to the unfolded A and D proteins measurable in Western blot since these monoclonals (and several of the human anti-nDNA populations) failed to react with native U1RNP in ELISA or in RNA immunoprecipitation experiments. These newly recognized cross reactions of anti-nDNA may amplify the immune response to DNA and be part of the original immunogenic drive.

The role of VL gene structural determinants in the fine specificity of anti-DNA antibodies

To investigate the structural contribution of the light chain of anti-DNA antibodies to fine specificity, the VKappa genes of two monoclonal anti-DNA antibodies, termed H241 and H102, were cloned and sequenced. H102 and H241 are independently derived from MRL-lpr/lpr mice and differ in their fine specificity: H241 binds dsDNA and normal glomeruli in vitro and deposits in the kidney in vivo, whereas H102 binds only ssDNA and does not deposit in the kidney. Both are encoded by nearly identical VH genes but different N and D regions. Our previous results have demonstrated that the VH gene for H102 and H241 encodes eight other anti-DNA antibodies that also differed in fine specificity. This suggested that the gene product encoded by the VH 102/241 gene, may have intrinsic affinity for DNA, but is unlikely to determine fine specificity or nephritogenicity. In the present study we examined whether the VKappa gene might account for the difference in nephritogenicity. The complete nucleotide and deduced amino acid sequence of VK 102 and VK241 revealed that they are very dissimilar to each other (< 60% homology). VK 241 defined a new member of the VKappa gene family and was moderately homologous to two other VK genes encoding anti-DNA antibodies and to one VK gene encoding an anti-histone antibody all from lupus strains of mice. In addition, sequence diversity in the VK CDR1 region and position 96 of the CDR3 region was observed that may be of significance in determining fine specificity. VK 102 was highly homologous to two other VKappa genes, VKs17.2 and VK C8.5, both encoding anti-DNA antibodies and members of the VK20 gene family. It was striking that all three members of the VK 20 gene family code for DNA reactivity. This suggests that certain VKappa genes may also be used to repeatedly code for anti-DNA reactivity.

B cells are anergic in transgenic mice that express IgM anti-DNA antibodies

B lymphocytes in individuals with systemic lupus erythematosus (SLE) secrete pathogenic autoantibodies to DNA which cause clinical nephritis. (NZB X NZW) F1 (BW) female mice also secrete pathogenic anti-DNA autoantibodies, and therefore are considered to be an animal model of SLE. The rearranged immunoglobulin (Ig) genes that encode an anti-DNA antibody from a diseased BW mouse have been cloned, and transgenic (Tg) mice have been created by microinjection of these constructs into fertilized eggs from normal mice. As we reported previously, when the construct contains the C gamma 2a heavy chain constant (CH) region, the mice spontaneously secrete anti-DNA IgG and they develop mild nephritis. This demonstrated that the Ig encoded by the transgene is pathogenic. In contrast, here we report that when the construct contains the same anti-DNA Ig variable (V) regions used previously, along with the C mu region, the autoreactive B cells are rendered tolerant. Most B cells in the Tg mice express the mu transgene product on their surface, and rearrangement of endogenous light chain genes is partially suppressed. Furthermore, most hybridomas made from Tg B cells secrete IgM anti-DNA. Despite this, the Tg mice have reduced levels of total serum Ig and they do not secrete anti-DNA IgM either spontaneously or following immunization with DNA. We conclude that most B cells in the Tg mice have been rendered anergic. Anergy is however reversible in vitro; lipopolysaccharide stimulation of Tg B cells leads to the production of a significant amount of IgM anti-DNA antibody. The studies demonstrate that in this line of Tg mice on a normal mouse genetic background potentially pathogenic B cells that express a high-affinity Ig specific for a natural autoantigen are subject to tolerance by induction of anergy.

Nucleosome: a major immunogen for pathogenic autoantibody-inducing T cells of lupus

Only a fraction (12%) of 268 "autoreactive" T cell clones derived from lupus-prone mice can selectively induce the production of pathogenic anti-DNA autoantibodies in vitro and accelerate the development of lupus nephritis when transferred in vivo. The CDR3 loops of T cell receptor beta chains expressed by these pathogenic T helper (Th) clones contain a recurrent motif of anionic residues suggesting that they are selected by autoantigens with cationic residues. Herein, we found that approximately 50% of these pathogenic Th clones were specific for nucleosomal antigens, but none of them responded to cationic idiopeptides shared by variable regions of pathogenic anti-DNA autoantibodies. Nucleosomes did not stimulate the T cells as a nonspecific mitogen or superantigen. Only the pathogenic Th cells of lupus responded to nucleosomal antigens that were processed and presented via the major histocompatibility class II pathway. Although the presentation of purified mononucleosomes to the Th clones could be blocked by inhibitors of endosomal proteases, neither of the two components of the nucleosomes--free DNA or histones by themselves--could stimulate the Th clones. Thus critical peptide epitopes for the Th cells were probably protected during uptake and processing of the nucleosome particle as a whole. The nucleosome-specific Th clones preferentially augmented the production of IgG autoantibodies to histone-DNA complex in vitro. In vivo, nucleosome-specific, CD4+ T cells were not detectable in normal mice, but they were found in the spleens of lupus-prone mice as early as 1 mo of age, long before other autoimmune manifestations. Immunization of young, preautoimmune lupus mice with nucleosomes augmented the production of autoantibodies and markedly accelerated the development of severe glomerulonephritis. Previously, crude preparations containing nucleosomes were shown by others to have polyclonal mitogenic activity for B cells from normal as well as lupus mice. Identification here of pure mononucleosome as a lupus-specific immunogen for the Th cells that selectively help the pathogenic anti-DNA autoantibody producing B cells of lupus could lead to the design of specific therapy against this pathogenic autoimmune response.

A peptide derived from an autoantibody can stimulate T cells in the (NZB x NZW)F1 mouse model of systemic lupus erythematosus

OBJECTIVE

To assess the ability of peptides derived from anti-DNA to stimulate syngeneic T lymphocytes and influence lupus in (NZB x NZW)F1 (NZB/W) mice.

METHODS

We synthesized (by Geysen pin method) overlapping 12-mer peptides recapitulating the amino acid sequence of the VH region of a nephritogenic monoclonal IgG2a anti-DNA antibody (A6.1) from an NZB/W mouse. Splenic T cells were cultured with the peptides; multiple experiments assayed 12-mer and 16-mer peptides which contained a triple-base motif (KFKGK). We immunized 20-week-old NZB/W mice with the 12-mer and evaluated them for evidence of nephritis and for quantities of antibodies in plasma and glomeruli.

RESULTS

Three clusters of peptides caused proliferation of spleen cells from young, nonimmunized mice. Both the 12-mer FYNQKFKGKATL and the 16-mer GDTFYNQKFKGKATLT peptides stimulated purified T cells. The KXKXK motif occurs in 15% of murine Ig VH (NBRF protein database), compared with 100% (6 of 6) of NZB/W anti-DNA monoclonal antibody. Immunization with the 12-mer peptide increased plasma levels of IgG, anti-DNA, and immune complexes, and levels of anti-DNA in glomeruli; nephritis was accelerated.

CONCLUSION

NZB/W anti-DNA contain peptide sequences in their VH regions that stimulate self-T cells. At least one motif is frequent in NZB/W anti-DNA. If some activated T cells provide help, this mechanism may contribute to sustained up-regulation of autoantibodies in murine lupus.

Independently derived murine glomerular immune deposit-forming anti-DNA antibodies are encoded by near-identical VH gene sequences

To examine the influence of variable region sequences on the capacity of individual lupus autoantibodies (autoAb) to form glomerular immune deposits, the complete VH and VL region sequences of three anti-DNA mAb that produced morphologically similar immune deposits after administration to normal mice were determined. The Ig were independently derived from 1-mo-old (H238, IgM), 3-mo-old (H8, IgG2a), and 6-mo-old (H161, IgG3) MRL-lpr/lpr mice, and they all produced subendothelial and mesangial immune deposits after passive transfer to normal mice. In addition, H238 and H161 produced granular deposits in small extraglomerular vessels. The mAb had nearly identical VH gene sequences; H8 differed from H238 and H161 by a single nucleotide in FR1 that resulted in a histidine for glutamine substitution. This VH gene sequence was also > 99% homologous to another anti-DNA Ab (termed H241), that we previously reported to produce glomerular immune deposits in a similar morphologic pattern. H161 and H238 were encoded by DFL16 and JH2 genes, whereas H8 was encoded by a JH4 gene. Different Vk family genes were used to encode the three mAb, however H161 and H238 both used a Jk5 gene. The results indicate that an identical or highly related VH gene is used to encode a subgroup of murine lupus autoAb that share immune deposit forming properties. Furthermore, they raise the possibility that amino acid residues independent from those encoded by VH genes may be influential in immune deposit formation at extraglomerular sites.

Cloning and cDNA sequence analysis of nephritogenic monoclonal antibodies derived from an MRL/lpr lupus mouse

Production of IgG3 in MRL/Mp-lpr/lpr (MRL/lpr) lupus mice is one of the major factors to develop glomerulonephritis (GN) in these mice. To examine molecular characteristics of IgG3 responsible for GN in these mice, hybridoma clones producing IgG3 antibodies were prepared from one unmanipulated MRL/lpr mouse. Two clones, 2B11.3 and 7B6.8, were nephritogenic; that is, they caused severe glomerular lesions when injected to normal mice, moreover with a different histopathological manifestation. The 2B11.3 clone generated diffuse cell-proliferative lesions, while those induced by the 7B6.8 clone resembled wire loop lesions in human lupus nephritis. The cDNA sequence analysis of 7B6.8 antibody and the other IgG3 antibody, 1G3, non-nephritogenic, revealed that the C regions of the heavy and light kappa chains were completely the same between them. Furthermore, they were identical in deduced amino acid sequences to those from non-autoimmune BALB/c mice, indicating no allelic difference of Igh-8 between these two strains. The V regions of 2B11.3 and 7B6.8 antibodies were composed of different sets of VH, D, JH, Vk and Jk. Although both of the VH belonged to the J558 family, they seemed to use a different VH germline gene. These findings suggest that GN in MRL/lpr mice is generated by the expansion of clonally different B cells producing particular antibodies possibly with a different pathogenetic potency.

Both IgM and IgG anti-DNA antibodies are the products of clonally selective B cell stimulation in (NZB x NZW)F1 mice

Disease activity in systemic lupus erythematosus is closely associated with the appearance of immunoglobulin (Ig)G antibody to native DNA in both humans and mice. Like normal antibody responses, the anti-DNA autoantibody first appears as IgM and then switches to IgG. Structural studies of IgG anti-DNA suggest that these antibodies are the products of clonally selected, specifically stimulated B cells. The origins of the IgM anti-DNA have been less clear. To determine whether the earlier appearing IgM anti-DNA antibody in autoimmune mice also derives from clonally selected, specifically stimulated B cells or B cells activated by nonselective, polyclonal stimuli, we have analyzed the molecular and serological characteristics of a large number of monoclonal IgM anti-DNA antibodies from autoimmune (NZB x NZW)F1 mice. We have also analyzed IgM and IgG anti-DNA hybridomas obtained from the same individual mice to determine how the later-appearing IgG autoantibody may be related to the earlier-appearing IgM autoantibody within an individual mouse. The results demonstrate that: (a) IgM anti-DNA, like IgG, has the characteristics of a specifically stimulated antibody; (b) IgM and IgG anti-DNA antibodies have similar variable region structures and within individual mice may be produced by B cells derived from the same clonal precursors; (c) recurrent germline and somatically derived VH and VL structures may influence the specificity of anti-DNA monoclonal antibody for denatured vs. native DNA; and (d) the results provide a structural explanation for the selective development of IgG antibody to native DNA as autoimmunity to DNA progresses in (NZB x NZW)F1 mice.

Selection of immunoglobulin variable regions in autoimmunity to DNA

Results from our analyses of variable region gene usage among spontaneous anti-DNA antibodies in autoimmune mice have indicated that both the early IgM and later-appearing IgG autoantibodies to DNA are generated by clonally selected B cells. The recurrent usage of particular variable region genes among all the anti-DNA hybridomas analyzed and reported to date supports this hypothesis. The preferential expression of particular light and heavy chain variable region genes among selected populations of both IgM and IgG anti-DNA hybridomas likewise supports the hypothesis. Both IgM and IgG antibody-producing B cells are derived from the same clonal precursor population and may be derived from the same B cell clonal precursor within an individual mouse. The selective and recurrent expression of germline and somatically-derived structures that would be expected to promote protein binding to DNA within anti-DNA antibody variable regions, particularly arginines in both light and heavy chain complementarity-determining regions, indicates that DNA or DNA-containing complexes may be the antigen that stimulates anti-DNA antibody in autoimmune mice. The progressive increase in the specificity of spontaneous anti-DNA antibodies for native DNA as the autoimmune response matures from IgM to IgG likewise suggests that DNA may be the antigenic stimulus for spontaneous anti-DNA in autoimmune mice. A hypothetical, computer-generated model of anti-DNA antibody binding to DNA provides an interesting paradigm for the molecular basis of antibody specificity for DNA.

VH-gene representation in autoantibodies reflects the normal human B-cell repertoire

The recurrence in the V-gene repertoire of individual germline VH genes can now be extended from the restricted B-cell populations of the fetus, autoantibodies and B-cell malignancies to the expressed V-gene repertoire of normal adults. Why the human B cell preferentially utilizes these individual VH genes remains speculative. However, it is apparent that the population of VH genes used to encode autoantibodies reflects the normal expressed repertoire (Fig. 7). Even so, the overrepresentation of other V genes such as Dxp'1 in anti-DNA antibodies and the presence of somatic mutation in the pathogenic autoantibodies of autoimmune disease continues to suggest an antigenic influence on V-gene selection. We postulate that only a fraction of available germline V genes are utilized in the expressed repertoire, and that polyspecificity of naturally occurring antibodies and somatic mutation of CDR3 compensate for the loss of diversity entailed by the limited use of the potential repertoire. The mechanisms by which germline genes become pathogenic remains unclear but they presumably relate to mutation, loss of regulatory control or perhaps environmental factors (Isenberg et al. 1992). What then are the mechanisms which lead to escape of these VH genes from normal control? What antigenic drive if any produces anti-DNA specificity in SLE? Why indeed is the expressed repertoire using only a fraction of the available germline? To answer these questions, further study of the V-gene repertoire of selected populations of antigen-binding cells and of pathogenic IgG autoantibodies is necessary and is ongoing. The contribution of individual V genes to antigen binding and idiotype is also being dissected and promises to yield important information about the relative contribution of VH genes to autoimmunity.

Shift of private and not of cross-reactive anti-DNA idiotypes in systemic lupus erythematosus

The shift of private idiotype (Id) and cross-reactive Id (CRI) on anti-DNA antibodies in a lupus patient KE was investigated during a 7-year period. Anti-private Id and anti-CRI activities were separated by affinity chromatography from rabbit (R)-anti-Ids raised against KE anti-DNA antibodies during active (1/84) and inactive (4/90) stages of the disease. Anti-CRI isolated from the 84 R-anti-Id appeared to recognize binding site-related Ids that are shared with KE non-anti-DNA antibodies, unrelated lupus patients' sera, and certain normal sera. Id expression on serial serum samples of KE using these fractionated R-anti-Ids as probes showed that the 1/84 private Id expression declined while the 4/90 private Id expression gradually increased. Expression of the CRI showed a relatively stable pattern. These results suggest that anti-DNA populations detected by anti-private Id can shift, while populations expressing CRI may stay stable.

Structural aspects of recognition motifs contributing to autoimmune responses

Sequence analysis of autoimmune-associated antibodies has suggested a structural relatedness between genes used to encode autoantibodies and those encoding unrelated antibodies without autoreactive specificities. Subsequently, the basis for cross-reactive idiotypes across germ-line lineages, as well as conserved interspecies cross-reactivities of autoantigens among serologically similar antibodies, may result from evolutionary duplication of particular types of recognition motifs. As a first step toward elucidating structural recognition principles underlying possible cross-reactive epitopes involved in autoimmune pathologies, structural features of selected motifs associated with native ligand binding are examined for their inherent occurrence in antibody and T-cell receptor repertoires. This analysis considers the putative recognition features representative of common motif subsets shared with loop structures in CDR2 and FR3 regions of antibodies such as charge-2x-charge-x-charge or hydrogen bond donor (acceptor)-2x-charge-x-hydrogen bond donor (acceptor) type motifs, where x is any residue that can participate in maintaining a loop conformation. Such tracts encoded in the CRD2 and FR3 regions of heavy chains of antibodies and T-cell receptors (TCRs) associated with autoimmune dysfunction, with non-autoreactive antibodies, and with native host proteins. Such evolutionarily conserved motifs may be targets for complementary interactions involving autoantibodies and receptors.

Variable region sequence analysis of anti-DNA antibodies: evidence for a family of closely related germ-line VH genes encoding lupus autoantibodies

Cloning and sequencing of the V regions of the anti-DNA monoclonal antibodies (mAbs), H438 and H130, indicate that H438 is encoded by a J558 VH gene, a single D region nucleotide, and unmutated JH1, V kappa-1C and J kappa 1 genes, and the H130 L chain is encoded by a V kappa-21 subgroup gene J kappa 1 gene. Identification of VH438, which shared VH hybridization pattern with 6% of a panel of 352 MRL/lpr hybridomas, suggests that the frequency of J558 use among spontaneously activated B cells in MRL/lpr mice is greater than previously reported. The VHH438 J558 family gene is identical to VHPAR, which encodes the independently derived MRL/lpr autoantibody, MRP-2, and is highly homologous to the previously reported VHH130, which is identical to a BALB/c germ-line VH gene. Comparison of consensus sequences of homologous autoantibodies and previously reported restriction mapping suggest that a minimum of three highly related J558 germ-line genes encode lupus autoantibodies.

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.

Molecular characteristics of antibodies bearing an anti-DNA-associated idiotype

Anti-double-stranded DNA antibodies are the hallmark of the disease systemic lupus erythematosus and are believed to contribute to pathogenesis. While a large number of anti-DNA antibodies from mice with lupus-like syndromes have been characterized and their variable region genes sequenced, few human anti-DNA antibodies have been reported. We describe here the variable region gene sequences of eight antibodies produced by Epstein-Barr virus (EBV)-transformed B cells that bear the 3I idiotype, an idiotype expressed on anti-DNA antibodies and present in high titer in patients with systemic lupus. The comparison of these antibodies to the light chains of 3I+ myeloma proteins and serum antibodies reveals that EBV transformation yields B cells producing antibodies representative of the expressed antibody repertoire. The analysis of nucleotide and amino acid sequences of these antibodies suggests the first complementarity determining region of the light chain may be important in DNA binding and that paradigms previously generated to account for DNA binding require modification. The understanding of the molecular genetics of the anti-DNA response requires a more complete description of the immunoglobulin germ line repertoire, but data reported here suggest that somatic diversification is a characteristic of the anti-DNA response.

The recognition of self-antigens and autoimmune disease

Recent studies have increased our understanding of the nature of autoimmune recognition and of the identity of autoantigens, at least in model systems. Knowledge of the autoantigens and the process of recognition is suggesting new therapies for autoimmune disease.

Idiotypic characteristics of immunoglobulins associated with human systemic lupus erythematosus. Association of high serum levels of IdGN2 with nephritis but not with HLA class II genes predisposing to nephritis

Serum levels of IdGN2 (an idiotype enriched in nephritogenic antibodies), IdX (an idiotype not enriched in nephritogenic antibodies), IgG, and anti-DNA were measured in 23 Caucasian patients with lupus nephritis, in age- and sex-matched lupus patients without nephritis, and in similarly matched healthy individuals. Serum levels of IdGN2 were significantly higher in the patients with lupus nephritis than in those without, and they were higher in all lupus patients compared with the healthy control subjects. However, the same observations were true for serum levels of IdX. There were significant positive correlations between the serum levels of IgG, IdGN2, IdX, and anti-DNA. HLA typing at the DR and DQ loci was performed in 105 lupus patients of different races (Caucasian, black, and Asian/Polynesian/Filipino). Serum levels of IdGN2 in 83 of these individuals did not correlate with any of the HLA class II haplotypes currently known to predispose to lupus nephritis. We conclude that the high serum levels of IdGN2, which are characteristic of some patients with lupus nephritis, may often result from polyclonal B cell activation rather than from idiotype-specific upregulation associated with one or more of the class II genes that predispose to nephritis in this disease.