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

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

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

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

Intrastrain recurrent idiotypes among anti-DNA antibodies of (NZB X NZW)F1 hybrid mice

Immunization of NZB and A/J mice against an anti-DNA hybridoma antibody (F227) derived from (NZB x NZW)F₁ (B/W) mice allowed the preparation of two anti-idiotype antisera. These two reagents were shown to recognize different idiotopes of the F227 monoclonal antibody. NZB anti-idiotypic antibodies recognized non-ligand-modifiable idiotypic determinants. These idiotopes were private or present at undetectable level in BW mouse sera since it was found that only two of the 24 B/W mouse sera tested were recognized by these antibodies. Conversely, A/J anti-idiotypic antibodies recognized partially ligand-modifiable idiotopes which were found in all B/W mouse sera tested. These results demonstrate that anti-DNA antibodies share similar idiotypic specificities and suggest that these autoantibodies occur as families of structurally related proteins.     

Natural antibodies that react with V-region peptide epitopes of DNA-binding antibodies are made by mice with systemic lupus erythematosus as disease develops.

Cross-reactive idiotypes (CRI) have been detected on anti-DNA autoantibodies associated with lesions typical of systemic lupus erythematosus. In order to analyse the antigenic make up of idiotypes on anti-DNA monoclonal antibodies (mAb) V-88 (IgG1 kappa) and F-423 (IgG3 kappa), derived respectively from an adult (NZB x NZW)F1 and a fetal MRL/Mp-lpr/lpr mouse, a set of overlapping hexapeptides representing the VH and VL regions of mAb V-88 and F-423 were synthesized and reacted with a range of sera in pepscan enzyme-linked immunosorbent assays (ELISA) taken from normal and lupus mouse strains. Serum pools were collected both from normal BALB/c and lupus MRL/Mp-lpr/lpr and (NZB x NZW)F1 mice at 10, 20 and 30 weeks of age and analysed for the presence of spontaneously produced anti-V-region peptide IgM and IgG antibodies. IgM antibodies from both the lupus mice reacted with the same V-region epitopes, and although some epitopes mapped to similar locations in the two mAb, the maps for V-88 and F-423 were not identical. In MRL/Mp-lpr/lpr mice, as lupus disease progressed there was a switch from IgM antibodies to IgG anti-peptide antibodies whose specificity for the peptide antigens coincided with but was better defined than that of the IgM antibodies. The identified idiotopes were located in both complementary determining regions (CDR) and framework region (FR) regions, indicating that some contribute to CRI shared by other related antibodies, while others were unique to either mAb V-88 or F-423. In conclusion, we have dissected and identified a mosaic of antibody V-region idiotopes that contribute to the idiotype of an anti-DNA autoantibody and against which autoantibodies are made naturally in lupus disease.     

Genetic,structural and functional properties of an IgG DNA-binding monoclonal antibody from a lupus patient with nephritis

Antibodies binding to double-stranded (ds) DNA are strongly associated with renal involvement in patients with systemic lupus erythematosus (SLE). We have generated two new IgG DNA-binding monoclonal antibodies (mAb), RH-14 and DIL-6, from the peripheral blood lymphocytes of two SLE patients with glomerulonephritis using the heteromyeloma cell line CB-F7. RH-14 is an IgG1 λ antibody which also bound to single-stranded (ss)DNA, histones and nucleosomes. DIL-6 is an IgG3 λ antibody with restricted antigen binding specificity. cDNA encoding the variable regions of the heavy (V_H) and light (V_L) chains of RH-14 was sequenced and the antigen binding site of this mAb was computer modelled. Sequence analysis of V_H and V_L regions of RH-14 showed that V_H is derived from germ-line gene V3-7, a member of the V_H3 family, and V_L is derived from DPL 11, a member of the V_λ2 family. Somatic mutations and basic amino acid residues are identified in the complementarity- determining regions of both V_H and V_L regions. The nephritogenic properties of these mAb were analyzed by implanting and growing the hybridoma cells secreting the mAb in the peri toneum of SCID mice. The animals that received the RH-14 hybridoma produced higher levels of proteinuria (3 to ≥ 4) (p < 0.001) compared to the groups that received DIL-6 (trace to ≥ 1) or CB-F7 (trace). Electron microscopy of kidney sections from all the RH-14- implanted animals showed granular immunoglobulin deposition in the renal glomerular capil laries and mesangium. In this study we have shown for the first time using electron micros copy that a human IgG anti-dsDNA mAb, RH-14, is nephritogenic and that deposition of such an antibody alone is sufficient to induce renal damage.     

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.     

Tolerance induced by anti-DNA Ig peptide in (NZB×NZW)F1 lupus mice impinges on the resistance of effector T cells to suppression by regulatory T cells

We have previously shown that immune tolerance induced by the anti-DNA Ig peptide pCons in (NZB×NZW)F(1) (NZB/W) lupus mice prolonged survival of treated animals and delayed the appearance of autoantibodies and glomerulonephritis. Part of the protection conferred by pCons could be ascribed to the induction of regulatory T cells (T(Reg)) that suppressed the production of anti-DNA antibodies in a p38 MAPK-dependent fashion. Here we show that another effect of pCons in the induction of immune tolerance in NZB/W lupus mice is the facilitation of effector T cell suppression by T(Reg). These new findings indicate that pCons exerts protective effects in NZB/W lupus mice by differentially modulating the activity of different T cell subsets, implying new considerations in the design of T(Reg)-based approaches to modulate T cell autoreactivity in SLE.     

Enhanced response of autoantibody-secreting B cells from young NZB/NZW mice to T-cell-derived differentiation signals

Spleen cells from young NZB/NZW mice spontaneously produce IgM antihistone and anti-DNA antibodies in culture, and this in vitro autoantibody production is T-cell dependent. In the present studies, we investigated the response of young autoantibody-producing NZB/NZW B cells to various T-cell-derived signals. Stimulation with unprimed allogeneic T cells resulted in a 10- to 20-fold increase in IgM antihistone and anti-DNA antibody production compared with cultures of B cells alone. The responding cells were found in the large B-cell fraction after separation on Percoll gradients. Allo-stimulated B cells from nonautoimmune mice produced much lower absolute amounts of IgM autoantibodies as well as total IgM compared with NZB/NZW cells. Marked IgM antinuclear antibody and total IgM production was also observed when NZB/NZW B cells were cultured with supernatants from TH2 but not TH1 T-helper clones. Although B cells from nonautoimmune mice produced high levels of autoantibodies after stimulation with lipopolysaccharide, only minimal levels were secreted in response to the active supernatants. These results suggest that young NZB/NZW mice have IgM autoantibody-producing B cells that are more sensitive to certain T-cell-derived signals compared with B cells from normal mice. Although these hyperresponsive NZB/NZW cells appear to be in an advanced stage of activation, they require additional T-cell signals to express this abnormality.     

Thymic microenvironment and NZB mice: the abnormal thymic microenvironment of New Zealand mice correlates with immunopathology

There are distinct microenvironmental abnormalities of thymic architecture in several murine models of SLE defined using immunohistochemistry and a panel of mAb dissected at thymic epithelial markers. To address the issue of the relationship between the thymic microenvironment and autoimmunity, we studied backcross (NZB x NZW) F1 x NZW mice in which 50% of offspring develop nephritis associated with proteinuria and anti-DNA antibodies. We reasoned that if thymic abnormalities are associated with development of disease, the correlation of abnormalities with lupus-like disease in individual backcross mice will form the foundation for identification of the mechanisms involved. In parallel, we directed a genetic linkage analysis, using markers previously shown to be linked to nephritis and IgG autoantibody production, to determine if such loci were similarly associated with microenvironmental changes. Our data demonstrate that all (NZB x NZW) F1 x NZW backcross mice with disease have microenvironmental defects. Although the microenvironmental defects are not sufficient for development of autoimmune disease, the severity of thymic abnormalities correlates with titers of IgG autoantibodies to DNA and with proteinuria. Consistent with past studies of (NZB x NZW) F1 x NZW mice, genetic markers on proximal chromosome 17 (near MHC) and distal chromosome 4 showed trends for linkage with nephritis. Although the markers chosen only covered about 10-15% of the genome, the results demonstrated trends for linkage with thymic medullary abnormalities for loci on distal chromosome 4 and distal chromosome 1. We believe it will be important to define the biochemical nature of the molecules recognized by these mAbs to understand the relationships between thymic architecture and immunopathology.     

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

B lymphocytes in individuals with systemic lupus erythematosus (SLE) secrete pathogenic auto antibodies to DNA which cause clinical nephritis. (NZB x NZW) Fl (BW) female mice also secrete pathogenic anti-DNA auto antibodies, 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 Cγ2a heavy chain constant (C_H) 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 Cμ region, the auto reactive B cells are rendered tolerant. Most B cells in the Tg mice express the μ 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.     

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.     

The pathogenic human monoclonal anti-DNA that induces experimental systemic lupus erythematosus in mice is encoded by a VH4 gene segment

Systemic lupus erythematosus (SLE) can be induced in mice byimmunization with a human anti-DNA IgM mAb that was derivedfrom a patient with cold agglutinln disease. The latter antl-DNAmAb expresses the common Idiotype (Id) designated 16/6 Id. Theoriginal human hybridoma 16/6 that secreted an IgM antibodythat bound ssDNA and carried the 16/6 Id had switched in cultureto secrete an IgG molecule. Herein we show that the IgG 16/6antibody contains the previously reported characteristics ofthe original IgM 16/6 mAb: It expresses the 16/6 Id and is capableof inducing experimental SLE in susceptible mouse strains. Theidentity of the IgG 16/6 anti-DNA mAb to the orginal IgM mAbwas shown both by serological techniques and at the T cell level.The human IgG 16/6 mAb was found to be encoded by a germlinegene from the human V_H4 gene family, with high similarity tothe germline gene V_H4.21 that was previously shown to code foranti-DNA antibodies isolated from SLE patients. The V_H4.21 germlinegene was found to also code for most antibodies with cold agglutininactivity that were isolated from patients with cold agglutinindisease.     

Properties of Whole Human IgG Molecules Produced by the Expression of Cloned Anti-DNA Antibody cDNA in Mammalian Cells

Antibodies to DNA are believed to play an important role in systemic lupus erythematosus (SLE). High affinity IgG antibodies which show marked specificity for double stranded DNA (dsDNA) are particularly closely linked to the occurrence and severity of tissue damage. Sequence analysis of mouse and human monoclonal antibodies has previously suggested that mutations in the complementarity determining regions (CDRs) play a major role in determining these binding properties. In many cases such mutations increase the overall number of basic residues in the CDRs. To further elucidate the role played by such mutations it is important to develop methods of expressing cloned autoantibody cDNA in the form of functional whole immunoglobulin molecules. We describe a system in which autoantibody V_Hand V_LcDNA from monoclonal human anti-DNA antibodies, B3 and WRI176 were cloned into separate vectors which allowed their expression as whole heavy and whole light chains respectively. By cotransfecting mammalian cells with pairs of heavy and light chain vectors it was possible to produce whole IgG molecules from each of the four possible V_H/V_Lcombinations. Only antibody produced by homologous V_Hand V_Lpairs bound DNA, suggesting that in these autoantibodies both chains are important in conferring this property.     

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.     

Requirement of H-2 heterozygosity for autoimmunity in (NZB X NZW)F1 hybrid mice

In the F1 hybrid of autoimmune New Zealand Black (NZB) and phenotypically normal New Zealand White (NZW) mice, there occurs a severe systemic lupus erythematosus (SLE)-like autoimmune disease more fulminant than that found in the parental NZB mice. To determine the role of the H-2 complex in the pathogenesis of autoimmune disease of the (NZB X NZW)F1 hybrid, we developed H-2-congenic NZB (NZB.H-2z) and NZW (NZW.H-2d) strains, and compared the degree of autoimmune features between congenic H-2d/H-2d and H-2z/H-2z homozygous F1 hybrids and the original H-2d/H-2z heterozygous (NZB X NZW)F1 hybrid. We found that autoimmune features such as productions of IgG class anti-DNA antibodies and retroviral gp70 immune complexes and the development of renal disease were to a great extent reduced in both H-2 homozygous F1 hybrids, as compared with the H-2 heterozygous (NZB X NZW)F1 hybrid. It would thus appear that the heterozygosity of H-2d haplotype derived from NZB and H-2z from NZW is essential for the autoimmune disease characteristic of the (NZB X NZW)F1 hybrid.     

Autoantibodies to anti-DNA with anti-allotypic and anti-idiotypic specificities in (NZB X NZW)F1 mice

The monoclonal A52 (IgG2b, kappa) anti-DNA autoantibody represents a major cross-reactive idiotype in the murine and human autoimmune response to DNA. Examination of sera and purified IgG derived from (NZB X NZW)F1 mice showed that these mice develop an age-dependent binding reactivity with the pure anti-DNA IgG. Three monoclonal antibodies possessing this reactivity were prepared from unprimed female (NZB X NZW)F1 mice. One of these monoclonal antibodies appeared to be directed against allotypic determinants present in the NZB IgG2b; the other two antibodies exhibited a marked preference for idiotypic determinants of the A52 IgG. The IgG anti-allotype and anti-idiotype activities in (NZB X NZW)F1 mice may, therefore, represent the products of a deregulated immune system and/or constitute the normal elements of a functional immune regulation system.     

CD40-mediated stimulation of B1 and B2 cells: implication in autoantibody production in murine lupus

B1 cells usually show preferential responses to T cell-independent antigens. To ask whether B1 cells could respond to CD40-mediated stimulation for proliferation and differentiation, and whether CD40-mediated signals are involved in the production of autoantibodies by B1 cells, we compared responses to our newly established agonistic anti-mouse CD40 monoclonal antibody (mAb) between B1 and B2 cells from autoimmune-prone (NZB X NZW) F1 mice. Stimulation with this mAb induced a similar level of proliferative responses of both B1 and B2 cells, as well as an increase in expression of cell surface molecules I-A, CD54, CD23, CD80, and CD86. While co-stimulation with interleukin (IL)-4 markedly augmented proliferative as well as IgG1 and IgE antibody responses of both B1 and B2 cells, co-stimulation with IL-5 augmented proliferative and IgM antibody responses of only B1 cells. Splenic B1, but not B2 cells from young (NZB X NZW) F1 mice spontaneously produced substantial amounts of IgM including IgM anti-DNA antibodies, and the levels increased in case of stimulation with anti-CD40 mAb alone, or to a greater extent with the mAb plus IL-4 and IL-5. Collectively, these results indicate that splenic B1 cells from autoimmune (NZB X NZW) F1 mice have a comparable responsiveness to the CD40-mediated stimulation to that of B2 cells, which would be a potent regulatory mechanism involved in the spontaneous production of autoantibodies by B1 cells.     

Induction of anti-DNA autoanti-idiotypic antibodies in (NZB X NZW)F1 mice: possible role for specific immune suppression

(NZB X NZW)F1 (B/W) mice spontaneously produce anti-deoxyribonucleic (DNA) acid antibodies. PME77 anti-DNA monoclonal antibody (MoAb) is a syngeneic antibody bearing idiotype present in most B/W sera. In the present investigation the effect of immunization of B/W mice with the PME77 MoAb on the production of PME77 idiotypes and anti-DNA antibodies in B/W mouse sera was investigated. PME77 MoAb immunization regimen induced the production of autoanti-idiotypic antibodies and abrogated the expression of PME77 idiotype in B/W treated mice. In contrast, untreated mice and control B/W mice, receiving NZB polyclonal IgG2b which lacked detectable DNA binding capacity, expressed PME77 idiotopes. These results demonstrate that the expression of idiotype borne by autoantibodies may be modified through the induction of autoanti-idiotypic antibodies.     

Somatic diversification and affinity maturation of IgM and IgG anti-DNA antibodies in murine lupus

Molecular events occurring during the process of generation of pathogenic immunoglobulin (Ig)G anti-DNA antibodies in systemic lupus erythematosus (SLE) were studied using a newly established method. We analyzed the Ig variable (V) region gene sequence and DNA-binding activity of IgM and IgG anti-DNA monoclonal antibodies (mAb) from individual SLE-prone (NZB × NZW) F₁ mice. The first event appeared to be clonal selection and expansion of IgM anti-DNA clones, in which several clones had intraclonal V gene mutations. Although the number of mutations was small, the mutated IgM clones were associated with an increase in DNA-binding activity. The somatic mutations located in complementarity-determining regions (CDR) and in framework regions (FR) of V genes were apparently related to changes in DNA-binding activity. IgG anti-DNA clones that progressively increased in number with aging had numerous somatic mutations in the V region genes and there was a pair of clones which showed an intraclonal accumulation of mutations, in association with increase in the DNA-binding activity. All these findings show that somatic mutations associated with affinity maturation of the V region begin immediately before isotype-switching from IgM to IgG of the clones that have been selected and expanded, in an antigen-driven manner and/or by other forces. We propose that further accumulations of intraclonal somatic hypermutation, in association with selection and expansion of high affinity IgG clones, may lead to formation of highly pathogenic anti-DNA antibodies.     

A central anti-DNA idiotype in human and murine systemic lupus erythematosus

The monoclonal anti-DNA autoantibody A52 (IgG2b) was obtained from a (NZB X NZW)F1 (B/W) hybridoma. Two rabbits were immunized with the pure monoclonal antibody and produced anti-idiotypic (Id) antibodies. The purified anti-Id reacted with three different B/W monoclonal anti-DNA antibodies at or close to their DNA binding sites. Moreover, the rabbit antibodies had a profound inhibitory effect on the polyclonal anti-DNA activity in the majority of sera derived from B/W mice and human systemic lupus erythematosus (SLE) patients. The A52 IgG must, therefore, represent a major cross-reactive Id of anti-DNA immunoglobulins. In addition, the rabbit anti-Id antibodies may act as the "internal image" of antigen and should prove useful in modulation of the autoimmune response to DNA in SLE.