Cellular basis of in vitro anti-DNA antibody production: evidence for T cell dependence of IgG-class anti-DNA antibody synthesis in the (NZB X NZW)F1 hybrid

An in vitro system was designed to measure anti-DNA antibody synthesis, and the cellular basis of this autoantibody production in NZB X NZW (B/W)F1 (B/W F1) mice was analyzed. The spleen cells from old B/W F1 mice contained a number of B cells that spontaneously produced anti-DNA antibodies of both IgM and IgG classes in the absence of stimulants, thereby demonstrating that these B cells had been activated in vivo. These activated B cells could be removed by Sephadex G-10 column (G-10) filtration. Such G-10-passed, homogeneously small B cells were activated by the stimulant lipopolysaccharide (LPS) and produced both IgM and IgG class anti-DNA antibodies. The G-10-passed cells contained both B and T cells, and the cytotoxic treatment of the cells with monoclonal antibodies to T cells, anti-Thy-1 and anti-L3T4, abolished the LPS-induced IgG class, but not IgM class, anti-DNA antibody syntheses. Thus, the LPS-induced production of IgG class anti-DNA antibodies in B/W F1 mice is regulated by T cells. Reconstitution experiments revealed the requirement of T-B cell contact but not of the proliferative response of T cells. Moreover, there was no apparent adherent cell requirement. Such IgG class anti-DNA antibodies were produced only by spleen cells from old B/W F1 mice, but not from young B/W F1, NZB, NZW, and C57BL/6 mice. Like IgM class anti-DNA antibodies, LPS-induced synthesis of polyclonal IgM was T cell-independent. Only a slight reduction in the polyclonal IgG synthesis was observed after the G-10-passed cells had been treated with anti-Thy-1 antibody plus complement. This study should facilitate investigation of cell to cell interactions in the formation of autoantibodies and their correlations to immunologic abnormalities in autoimmune disease.     

Abnormal polyclonal B cell activation in NZB/NZW F1 mice

Spleen cells from autoimmune (10-mont-old) NZB/NZW (B/W) mice failed to generate appreciable numbers of antibody-forming cells (AFC) in vitro to TNP-substituted sheep erythrocytes in response to the polyclonal B cell activators (PBA), LPS and PPD, despite normal DNA synthetic responses to these agents and normal AFC responses to TNP-Ficoll. The failure to respond to PBA in old B/W mice was not due to suppressor T cells since anti-brain-associated-theta-treated spleen cells still failed to generate AFC in response to PBA. The defect was age-related since cells from young B/W mice generated vigorous AFC responses to PBA. It is suggested that the failure of the spleen cells of old B/W mice to generate AFC is a result of in vitro polyclonal B cell activation in the course of autoantibody formation.     

Studies of the induction of anti-DNA in normal mice

Injection of PBA has previously been demonstrated to induce anti-DNA. In the present study, we found that the combination of neonatal thymectomy and chronic administration of PBA (LPS + poly rI . rC) led to significantly higher anti-DNA levels than either PBA or thymectomy separately. These results suggested that a thymic regulatory process normally serves to suppress anti-DNA after chronic PBA exposure. Indeed, antigen-nonspecific suppressor function was found to be deficient in such thymectomy + PBA-treated mice. In addition, the cells of such mice in vitro interfered with the development of normal suppressor function by control cells.     

IgG anti-DNA autoantibodies within an individual autoimmune mouse are the products of clonal selection

Although mice from almost all inbred strains produce IgM anti-DNA antibody in response to B cell mitogens, only (NZB x NZW)F1 mice and mice from other strains that are genetically predisposed to autoimmunity spontaneously produce anti-DNA antibody of the IgG isotype. Because (NZB x NZW)F1 mice display marked B cell hyperactivity, anti-DNA antibody production in these mice has been thought to result from spontaneous, polyclonal B cell activation. Although this may be true for IgM anti-DNA antibodies, our results demonstrate that IgG anti-DNA antibodies are not polyclonal. Rather, IgG anti-DNA autoantibodies within an individual autoimmune mouse are oligoclonal and somatically mutated. These results demonstrate that IgG anti-DNA autoantibodies are the products of clonally selective B cell stimulation and exhibit the same characteristics as secondary immune antibodies to conventional immunogens: they are IgG, they are clonally restricted, and they are somatically mutated.     

Suppression of murine lupus nephritis by administration of an anti-idiotypic antibody to anti-DNA

The suppression of pathogenic antibodies to DNA in NZB/NZW f1 female mice was achieved by repeated inoculation of the mice with a monoclonal anti-idiotypic antibody (anti-Id). The anti-Id, an IgG1, kappa, was directed against a major cross-reactive idiotype (Id) on NZB/NZW IgG antibodies to DNA. One hundred micrograms of the anti-Id were inoculated i.p. every 2 wk, beginning at 6 wk of age (nondiseased mice--no circulating anti-DNA or proteinuria) or 20 wk of age (diseased mice--all with circulating anti-DNA, one-third with proteinuria). As controls, littermates received an IgG, kappa non-DNA-binding myeloma or no treatment. In the young mice, nephritis and anti-DNA antibodies appeared at the same time in all groups, and their circulating antibodies to DNA did not bear the target Id. In the older (20-wk-old) mice, survival was significantly prolonged because of delay in the onset of nephritis; the total quantities of antibodies to DNA were diminished, and the target Id, initially present on circulating IgG, was deleted. These benefits were transient; the suppression of antibodies was followed by the appearance of large quantities of anti-DNA that did not bear the major Id. Therefore, although administration of anti-Id was effective in reducing an undesirable antibody response after the target Id was present on circulating antibodies, the benefits were limited, probably by Id "switch" or by increased synthesis of pathogenic antibodies bearing a minor Id.     

IgM rheumatoid factors in mice injected with bacterial lipopolysaccharides.

Bacterial lipopolysaccharides (LPS) induced the formation of IgM rheumatoid factors (RF) in several strains of mice including athymic C57BL/6 nude mice, but not in the LPS-resistant C3H/HeJ mice. The RF induced by LPS reacted not only with murine IgG but also with IgG from cows, goats, guinea pigs, and humans. The kinetics of this RF response to injection of LPS were similar to those of antibody response against DNA and a hapten, dinitrophenyl (DNP), and to those of total IgM production. In addition, the RF activity of individual serum samples correlated significantly with levels of anti-DNA and anti-DNP antibodies and of IgM. Therefore, it is concluded that the induction of RF results from polyclonal antibody synthesis by B cells stimulated with LPS. This observation suggests that LPS or LPS-like substances may help to generate RF in patients with rheumatoid arthritis or with some infectious diseases.     

Class-specific regulation of anti-DNA antibody synthesis and the age-associated changes in (NZB x NZW)F1 hybrid mice

Investigations of regulatory helper and suppressor T cells in the in vitro anti-DNA antibody synthesis in NZB x NZW (B/W) F1 hybrid mice were initiated by the development of an in vitro system in which G10-passed B cells from B/W F1 mice were cocultured with mitomycin C-treated T cells in the presence of Con A and either in the presence or in the absence of LPS. It was revealed that each IgG and IgM anti-DNA antibody synthesis was under the regulation of separate L3T4+ helper and Ly-2+ suppressor T cells. The function of these class-specific regulatory T cells was age-dependent. Although the helper effect of L3T4+ T cells on IgG antibody synthesis increased, the effect of L3T4+ T cells on IgM antibody production decreased in B/W F1 mice with aging. The IgG anti-DNA antibody production in the cocultures of L3T4+ T cells and B cells was suppressed by addition of Ly-2+ T cells from young but not aged B/W F1 mice, whereas the production of IgM anti-DNA antibodies was suppressed by Ly-2+ T cells from aged but not young B/W F1 mice. We also found that although IgM anti-DNA antibody-producing B cells were already present in 2-mo-old mice, B cells producing IgG antibodies under the influence of L3T4+ T cells appeared in mice at 7 mo of age. These data clearly indicate that separate class-specific regulatory T cells are involved in the production of IgM and IgG anti-DNA antibodies and that the total serum level of the antibodies is reflected by both their age-associated changes and the generation of antibody-forming B cells in B/W F1 mice.     

Responses of B cells with or without C3 receptors to polyclonal B cell activators

Responses of B cells with or without receptors for C3 (CR) to polyclonal B cell activators (PBA) were studied. Mouse spleen cells were incubated with sheep red blood cells (SRBC) coated with antibody and complement to form rosettes, and they were separated by Ficoll-Hypaque density sedimentation into populations depleted of and enriched with lymphocytes bearing CR (CRL). These 2 populations were cultured with lipopolysaccharide (LPS), purified protein derivative of tuberculin (PPD), or dextran sulfate (DxS) and assayed for anti-TNP PFC. The CRL-depleted population responded well to LPS, poorly to PPD, and it showed practically no response to DxS, whereas the CRL-enriched population seemed to respond poorly to LPS but well to both PPD and DxS. The low responsiveness of the cRL-depleted population to PPD and DxS could not be explained by a shift of time-kinetics, by the dose-response profile of the responding cells, or by the depletion of adherent cells. Suppressor T cells did not take part in the reduced responses, since the treatment of the population with anti-Thy 1.2 plus complement could not restore the responses. These results indicate that B cells with CR [CR(+) B cells] respond well both to PPD and DxS, whereas the cells without CR [CR(-) B cells] respond poorly to PPD and DxS. It was difficult to evaluate the low responsiveness of CR(+) B cells to LPS because of the high background PFC of the cRL-enriched population.     

Igh-C allotype-linked control of anti-DNA production and clonotype expression in mice infected with Plasmodium yoelii

The infection of nonlethal strain of Plasmodium yoelii induces the formation of IgG anti-DNA antibodies as a result of polyclonal B cell activation. By using various nonautoimmune strains of mice including H-2 or Igh congenic or recombinant mice, the levels and clonotypes of anti-DNA antibodies elicited by the malaria infection were analyzed in relation to the expression of the MHC or Igh gene. Our results showed there were little, if any, differences in serum anti-DNA levels and their clonotypes among B10 and B6 H-2 congenic mice. In contrast, malaria-induced IgG anti-DNA responses markedly differed quantitatively and clonotypically between murine strains bearing the Ighb allotype and those bearing the Igha, Ighj, Ighd, or Ighn allotype. The latter group of mice produced approximately 5 to 10 times more IgG anti-DNA antibodies than the former group of mice. Clonotypically, mice bearing the Ighb allotype developed high alkaline anti-DNA antibodies of pH 8.0 to 8.5, whereas non-Ighb mice failed to express such alkaline anti-DNA spectrotypes, and exhibited more neutral spectrotypes (pH 7.0 to 8.0). Studies on the Igh recombinant mice indicated that the observed quantitative and clonotypical differences in IgG anti-DNA production was not associated with the variable region, but with the constant region of the Igh gene complex. Our results have suggested that IgG anti-DNA responses occurring as a result of polyclonal B cell activation during the course of malaria infection markedly differs quantitatively and clonotypically among murine strains and appear to be controlled at least in part by the Igh-C gene or gene(s) closely linked to it.     

Anti-immunoglobulin autoantibodies are not preferentially induced in polyclonal activation of human and mouse lymphocytes, and more anti-DNA and anti-erythrocyte autoantibodies are induced in polyclonal activation of mouse than human lymphocytes

Using a plaque assay with immunoglobulin (Ig)-coated SRBC, we and others have previously reported that the majority of polyclonally activated mouse lymphocytes secreted antibodies that appeared to be IgM anti-IgG autoantibodies. Careful reexamination of this assay, with application of several highly purified mouse serum and myeloma IgG and IgM preparations, revealed that IgM, which was a minor contaminant of Ig preparations, rather than IgG, was responsible for the formation of these plaques. High numbers of plaques could also be detected in assays with polyclonally activated human lymphocytes, Ig-coated SRBC, and anti-Ig developing sera. Of all IgG-, IgM- or IgA-secreting cells, 40 to 100% were detected with SRBC coated with gamma-globulin or Ig of the same isotype as the isotype to which the developing serum was specific; in general, low proportions of all PFC were detected with SRBC coated with Ig of a different isotype. Studies on the sequence of events leading to the formation of plaques with Ig-sensitized SRBC (both in humans and mice) revealed that antibodies detected in these assays were not able to bind to the Ig-coated SRBC (without the presence of developing serum), and therefore were not anti-Ig autoantibodies. It is our conclusion that the plaque assays with Ig-coated SRBC represent another type of a reverse hemolytic PFC assay that detects cells secreting antibodies regardless of their specificity, and these plaques are formed due to the cross-linking by the anti-Ig developing serum of the Ig coated on SRBC and the Ig secreted by lymphocytes. Our results confirmed preferential induction of anti-DNA antibody secreting cells in mice by showing that these antibodies indeed bind to DNA coated on SRBC. In cultures of polyclonally activated human lymphocytes, anti-DNA and anti-erythrocyte autoantibody-secreting cells were over 10 to 100 times less frequent than in mice. These results, therefore, disprove the concept of preferential induction of anti-Ig autoantibodies in the polyclonal activation of mouse and human lymphocytes, and show that anti-DNA and anti-erythrocyte autoantibodies are easily induced in the polyclonal activation of mouse, but not human, lymphocytes.     

Regulation of lipopolysaccharide-induced granulopoiesis and macrophage formation by spleen cells. I. Relationship between colony-stimulating factor release and lymphocyte activation in vitro.

Addition of bacterial lipopolysaccharide (LPS), a B cell mitogen, to mouse spleen cultures strongly stimulated production of colony-stimulating factor (CSF), the humoral regulator of granulopoiesis, and macrophage formation in vitro. Secretion of CSF from LPS-stimulated spleen cells coincided with cellualr DNA synthesis and cell transformation and both activities could be attributed to the lipid A moiety of the molecule. Different experimental approaches were used to study the relationship of CSF release and lymphocyte activation in response to LPS: a) modification of LPS with polymyxin B, an antibiotic bactericidal for most Gram-negative bacteria, caused a marked reduction in mitogenic activity, although the ability to induce CSF was not significantly altered; b)spleen cells from CBA/N mice, a mutant strain with an x-linked genetic defect in immunologic and mitogenic responses to polyclonal activators including LPS, showed diminished mitogeinc responses; however, high levels of CSF were produced; c) mitotic and DNA inhibitors (colchicine and cytosine arabinoside) did not affect CSF release although they completely inhibited mitogenicity. Thus, the spleen cell population participating in the process of LPS-induced CSF generation is probably a nondividing, terminally differentiated one without need for DNA synthesis. In addition, it was also shown that active RNA and protein synthesis are needed in this process.     

Antibody affinities and relative titers in polyclonal populations: surface plasmon resonance analysis of anti-DNA antibodies

This paper presents the equations and methodology for the measurement and interpretation of apparent dissociation constants for polyclonal populations of antibodies, where antigen is kept trace relative to antibody concentration. Surface plasmon resonance is used to determine K(d)s for the binding of anti-DNA antibodies to trace amounts of DNA antigen on a chip. Since the approach taken relies on equilibrium measurements, kinetic mass transport artifacts are avoided. The apparent K(d) is a weighted average of all the K(d)s for the clonally related subpopulations within the polyclonal pool, where each weighting factor is the relative titer (fractional presence) of the subpopulation. Titration curves appear as if there is one monoclonal population with that titer-weighted-average K(d). Implications of changes in the antibody affinity distribution within the population are discussed. The equations described herein provide a better physical understanding of the apparent K(d) that is obtained when a heterogeneous population of receptors is titrated against a trace ligand.     

Mechanisms of T and B cell collaboration in the in vitro production of anti-DNA antibodies in the NZB/NZW F1 murine SLE model

B/W mice spontaneously develop IgG antibodies to DNA that cause lethal immune nephritis. T and B cell interactions in the in vitro anti-DNA antibody response of B/W mice were investigated, and two distinct families of helper T cells that drive these responses were defined. First, the anti-DNA antibody-forming cell (AFC) response was found to be increased in B/W mice with nephritis and was inhibited with the monoclonal antibody anti-L3T4, suggesting a major role for helper T cells. Purified splenic T cells from mice with nephritis were able to augment both the IgG and the IgM anti-DNA AFC response of young B/W B cells. T helper cells were cloned from spleens of NZB/W F female mice with high titer anti-DNA antibodies and nephritis. The cloned T cells augmented both IgG and IgM anti-DNA AFC responses of young B/W B cells. Four clones--27.9, 30.7, 30.8, and 30.10--were selected for further study. These cells proliferated, in the context of syngeneic (H2d/z) antigen-presenting cells (APC) but not to allogeneic APC. Analysis of the mechanism of T helper cell clone-mediated augmentation of anti-DNA AFC revealed two populations: "cognate" T helper cells, which specifically augment anti-DNA AFC (30.7 and 30.10), and non-antigen-specific T helper cells (27.9 and 30.8), which augment the response of B cells of differing specificity by a bystander mechanism, probably through increased release of B cell growth and differentiation factors.     

Identification and sequence of the VH gene elements encoding a human anti-DNA antibody

Antibodies to DNA similar to those found in patients with systemic lupus erythematosus (SLE) and autoimmune mice can be derived from the lymphocytes of normal individuals. It is not known whether these normal derived anti-DNA antibodies are made from the same VH gene elements as the anti-DNA antibodies made by SLE patients. To begin to answer this question, we examined mu chain cDNA clones from human hybrid clone C6B2 producing anti-DNA antibodies. The sequence of the 500 base pair restriction fragment containing the variable region (5' terminus) was determined and was sequenced. This antibody uses a VHII heavy chain subgroup gene, a J3 joining segment, a hitherto unknown D segment, and a previously reported leader sequence. Significant homology was found to a mouse anti-DNA antibody sequence in the use of VH subgroup in J3, and in the hypervariable regions with a shared Ser-Tyr construction in CDR1 and an identical five amino acid residue stretch in CDR2. Comparison with the limited sequence data of published SLE monoclonal anti-DNA antibodies, both human and mouse, suggests that this shared Ser-Tyr may be important in some but not all antibodies to DNA. Comparison of C6B2 antibody is made with other known antibody sequences with identification of those residues likely to be part of the antigen binding site.     

Base specificity and idiotypy of anti-DNA autoantibodies reactive with synthetic nucleic acids

Synthetic nucleic acid reactivities and the distribution of idiotypes associated with poly(dA) and poly(dT) specificities were evaluated among both monoclonal and polyclonal anti-DNA antibodies from autoimmune New Zealand mice. Ten monoclonal anti-DNA antibodies (IgG2a or IgG2b), derived from NZB/NZW mice and reactive with natural DNA (duplex and/or heat-denatured), were found to collectively exhibit a diverse binding pattern with six deoxyribohomopolymers. Several monoclonal antibodies displayed reactivity with poly(dT) comparable to that with natural DNA. Serologic studies indicated that polyclonal anti-DNA autoantibodies from NZW/NZW mice and both parental strains also cross-reacted with various homopolymers and bound preferentially with those containing pyrimidines, particularly poly(dT), relative to purines. Detailed binding analyses with two poly(dT)-reactive monoclonal antibodies demonstrated that stable DNA/anti-DNA complexes were formed with synthetic oligomers containing six to 10 nucleotides; binding to such antigens was relatively insensitive to ionic strength and inversely dependent on temperature. Both antibodies exhibited preferential binding (greater than or equal to 10-fold) with poly(dT) relative to poly(dU), suggesting the importance of the C5-methyl group and/or helical conformation in pyrimidine base recognition. Idiotypes on poly(dA)-specific and poly(dT)-specific monoclonal antibodies were found to be reciprocally distinct, localized at or near active site residues, and expressed at low levels (less than 10 to 130 ng/ml) in anti-DNA sera from all three New Zealand strains. These findings suggest that: nucleotide base determinants are significantly involved in DNA/anti-DNA interactions; poly(dT) represents a major cross-reactive synthetic antigen; and idiotype expression among lupus autoantibodies which recognize such determinants may be diverse.     

Antibody-nucleic acid complexes. Conformational and base specificities associated with spontaneously occurring poly- and monoclonal anti-DNA antibodies from autoimmune mice

An enzyme-linked immunosorbent assay (ELISA) was developed to characterize spontaneously occurring, mono-and polyclonal anti-DNA antibodies. The assay consists of adsorbing single- (ss) and double-stranded (ds) DNA and various nucleoside-bovine serum albumin conjugates (e.g., A-, G-BSA, etc.) to microtiter wells and assesses the ability of various antibodies to bind to these immobilized antigens. The conformational and base specificity of two monoclonal antibodies (designated MRss-1 BWds-3) was examined in this manner. The exclusive binding of MRss-1 to ssDNA and guanosine-BSA (G-BSA) confirms our previous findings [Munns, T.W., Liszewski, M.K., Tellam, J.T., Ebling, F. M., & Hahn, B.H. (1982) Biochemistry 21,2929-2936] that this antibody recognizes single-stranded nucleic acids by virtue of their guanine content. The extensive binding of BWds-3 to dsDNA, its limited binding to ssDNA, and complete absence of binding to nucleoside-BSA antigens implied a double-stranded conformational specificity. Further, competitive studies with naturally occurring and synthetic alternating copolymers indicated that BWds-3 preferentially recognized the native dsDNA antigens. ELISA analysis of the spontaneously occurring, polyclonal anti-DNA antibodies from MRL/lpr and NZB/NZW-F1 mice revealed that the majority of anti-ssDNA antibodies bound to nucleoside-BSA conjugates. Anti-G antibodies were most prominent in both strains of mice, yet lesser and more variable quantities of anti-A, -C, -U, and -T antibodies were also detected. Preadsorption of serum with G-BSA/Sepharose resulted in the complete removal of anti-G antibodies and a 60% reduction in anti-ssDNA antibodies.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interclonal and intraclonal diversity among anti-DNA antibodies from an (NZB x NZW)F1 mouse

The immunologic basis for the generation of autoantibodies that are characteristic of systemic autoimmunity in mice and humans remains obscure. Experiments directed toward the analysis of serum antibody and the cell populations that combine to generate antibody in autoimmune mice have led to the proposition that autoantibody production, including anti-DNA, results from the nonselective, polyclonal activation of B cells. The present results from the molecular analyses of anti-DNA autoantibodies from an individual (NZB x NZW)F1 autoimmune mouse, however, are inconsistent with a clonally nonselective model for autoantibody production and are most consistent with a clonally selective, Ag-driven model for anti-DNA autoantibody production. These results demonstrate that Ig V region structures contributed by germ-line V region genes; recombinational diversity, including unusual DH gene usage and DH-DH recombination; and somatic mutation during B cell clonal expansion are all important for generating antibody and presumably B cell Ig receptor specificity for nucleic acids including native, duplex DNA.     

The in vitro production of anti-DNA antibody by cultured peripheral blood or tonsillar lymphoid cells from normal donors and SLE patients

Anti-DNA antibody responses by cultured circulating lymphocytes from SLE patients and by the tonsillar lymphoid cells of normal donors were detected and enumerated by a sensitive specific ELISA of culture supernatants, or by a hemolytic anti-DNA PFC assay. Although spontaneous IgM and IgG anti-DNA and anti-ssDNA responses were characteristic of SLE lymphocytes and spontaneous IgM anti-ssDNA responses were characteristic of tonsillar lymphocytes, the circulating lymphocytes of normal controls never produced anti-DNA antibodies spontaneously, and rarely after PWM stimulation. The anti-DNA antibody PFC response of tonsil lymphocytes correlated directly with the total number of immunoglobulin-producing cells measured by a reverse hemolytic PFC assay. Mixing experiments in which we employed cultures of comparable numbers of separately enriched autologous circulating and tonsillar B and T cells revealed that tonsillar tissue contained an enriched population of anti-DNA antibody precursor B cells and/or helper T cells.     

A conserved anti-DNA antibody idiotype associated with nephritis in murine and human systemic lupus erythematosus

In order to identify unique structural features of pathogenic autoantibodies to DNA in SLE, a murine anti-anti-DNA (anti-Id) mAb (mAb 1C7) was produced in response to immunization of lupus mice with a syngeneic anti-DNA mAb (mAb 3E10). Immunization of lupus mice with mAb 3E10 inhibited production of native anti-DNA antibodies, suppressed development of lupus kidney disease (nephritis), and induced production of anti-anti-DNA (anti-Id) antibodies. mAb 1C7 bound F(ab')2 fragments of mAb 3E10, and it bound other murine anti-DNA mAb, but not murine mAb or polyclonal serum antibodies unreactive with DNA. Moreover, binding of mAb 1C7 anti-Id to mAb 3E10 was inhibited by DNA, suggesting anti-Id binding within or near the binding site for DNA. Furthermore, mAb 1C7 bound serum IgG immunoglobulins from 9/12 patients with lupus nephritis and serum anti-DNA antibodies compared to only 3/12 SLE patients with comparable serum levels of anti-DNA antibodies, but without nephritis (p = 0.04), and only 1/53 SLE patients without serum anti-DNA antibodies, 0/49 patients with rheumatoid arthritis, and 1/47 healthy subjects (p less than 0.001). These results provide evidence that mAb 1C7 identifies a conserved Id associated with anti-DNA antibodies in murine and human SLE and may be useful as a structural probe to characterize pathogenic anti-DNA antibodies in SLE.     

High levels of anti-mitochondrial antibodies in MRL mice. Influence of anti-DNA antibodies on anti-mitochondrial antibodies measured by an enzyme-linked immunosorbent assay

We developed an easy enzyme-linked immunosorbent assay (ELISA) for anti-mitochondrial antibodies, and detected high levels of anti-mitochondrial antibodies in MRL/Mp-lpr/lpr (MRL1/l) mice. The influence of the presence of anti-DNA antibodies in the tested sera on this assay was also evaluated. The monoclonal anti-DNA antibodies, which were made from non-immunized MRL1/l mice, did not react with the mitochondrial antigens adhering to polystyrene plates. Absorption with DNA had little effect on the levels of mitochondrial antibodies in MRL1/l sera. Our assay for mitochondria-binding antibody was very easy and sensitive, although it could not differentiate among heterogeneous anti-mitochondrial antibodies.