V region sequences of anti-DNA and anti-RNA autoantibodies from NZB/NZW F1 mice

The V region sequences of two anti-DNA (A52, D42) and two anti-RNA (D44, D444) autoantibodies, derived from lupus prone NZB/NZW F1 female mice, were determined by mRNA sequencing. The sequences had the following features: 1) there was no clear sequence relationship between anti-DNA and anti-RNA antibodies; 2) there were no major similarities between any of the L chain sequences and each VL gene segment belonged to a different mouse VK subgroup; 3) the H chains of the two anti-RNA antibodies showed closely related sequences of VH gene segments and very similar third complementarity determining regions (CDR3); 4) the H chains of the two anti-DNA antibodies had VH segments belonging to different VH gene families but had a unique and similar combination of D segments and junctional sequences, suggesting a common recognition element for Ag and/or for idiotypic regulation in the H chain CDR3; and 5) the VH gene segment of one anti-DNA antibody (D42) was found to be very similar to the VH gene segment of a CBA mouse hybridoma antibody (6G6) which binds to the environmental Ag phosphocholine. The three-dimensional structure of the Fv-region of the anti-DNA antibody (D42) was modeled by computer and a stretch of poly(dT), ssDNA was docked to a cleft in the antibody combining site, formed by the three H chain CDR and by CDR1 and CDR3 of the L chain. The cleft is characterized by a preponderance of arginine and tyrosine residues, lining both the walls and base of the cleft.     

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.     

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.     

Tolerance to DNA in (NZB x NZW)F1 mice that inherit an anti-DNA V(H) as a conventional micro H chain transgene but not as a V(H) knock-in transgene

Lupus-prone (NZB x NZW)F(1) (BWF(1)) mice were made transgenic (Tg) for an anti-DNA Ab inherited either as a conventional V(H)3H9- micro H chain Tg (3H9- micro ) with or without a conventional V(kappa)8-kappa Tg, or a V(H)3H9 V(H) knock-in Tg allele (3H9R) with or without a V(kappa)4 V(kappa) knock-in Tg allele (V(kappa)4R). V(H)3H9 yields an anti-DNA Ab with most L chains including an anti-ssDNA with the V(kappa)8 Tg and an anti-dsDNA with the V(kappa)4 Tg. BWF(1) mice that inherited the conventional 3H9- micro had normal serum IgM, little to none of which was encoded by 3H9- micro, and only a small percentage of those mice had serum anti-DNA, none of which was transgene encoded. B cells expressing the conventional 3H9- micro Tg were anergic. BWF(1) mice that inherited the knock-in 3H9R Tg allele also had normal serum IgM, one-half of which was encoded by 3H9R, and produced anti-DNA encoded by the Tg allele. Most B cells expressing the knock-in 3H9R Tg also had an anergic phenotype. The results indicate that autoimmune-prone BWF(1) mice initially develop effective B cell tolerance to DNA through anergy, and anergy was sustained in 3H9- micro Tg peripheral B cells but not in 3H9R Tg B cells. B cells expressing the 3H9R knock-in Tg allele were able to achieve an activation threshold that B cells expressing the 3H9- micro conventional Tg could not. The maintenance of B cell tolerance to DNA in autoimmune-prone BWF(1) mice appears to differ from both normal mice and autoimmune-prone MRL(lpr/lpr) mice.     

Splenic phagocytes promote responses to nucleosomes in (NZB x NZW) F1 mice

Autoantigen presentation to T cells is crucial for the development of autoimmune disease. However, the mechanisms of autoantigen presentation are poorly understood. In this study, we show that splenic phagocytes play an important role in autoantigen presentation in murine lupus. Nucleosomes are major autoantigens in systemic lupus erythematosus. We found that nucleosome-specific T cells were stimulated dominantly in the spleen, compared with lymph nodes, lung, and thymus. Among splenic APCs, F4/80(+) macrophages and CD11b(+)CD11c(+) dendritic cells were strong stimulators for nucleosome-specific T cells. When splenic phagocytes were depleted in (NZB x NZW) F(1) (NZB/W F(1)) mice, nucleosome presentation in the spleen was dramatically suppressed. Moreover, depletion of splenic phagocytes significantly suppressed anti-nucleosome Ab and anti-dsDNA Ab production. Proteinuria progression was delayed and survival was prolonged in phagocyte-depleted mice. The numbers of autoantibody- secreting cells were decreased in the spleen from phagocyte-depleted mice. Multiple injections of splenic F4/80(+) macrophages, not those of splenic CD11c(+) dendritic cells, induced autoantibody production and proteinuria progression in NZB/W F(1) mice. These results indicate that autoantigen presentation by splenic phagocytes including macrophages significantly contributes to autoantibody production and disease progression in lupus-prone mice.     

Repetitive usage of immunoglobulin VH and D gene segments in CD5+ Ly-1 B clones of (NZB x NZW)F1 mice.

The usually small Ly-1 B cell population is markedly increased in older mice by expansion of certain clones. This results in a cellular picture very similar to human B chronic lymphocytic leukemia. Here we report a molecular analysis of the immunoglobulin gene rearrangements of the Ly-1 B cell populations in (NZB x NZW)F1 females. We find that (i) the number of clones found in the peritoneum (a major tissue source of Ly-1 B cells) decreases with age till mono- or biclonality is common by approximately 6 months, (ii) many clones from different mice show the same size rearrangements at both the Ig heavy and light chain loci and (iii) the IgH rearrangements found in a clone isolated from the spleen of one mouse are a subset of those found in the peritoneum of the same mouse, implying migration occurs from the peritoneum to the spleen. Molecular cloning and sequencing of the IgH rearrangements from the peritoneal clones of one B/W mouse revealed that all productive rearrangements used the identical unmutated VH and D elements joined to different JHS. Indeed, two VDJH4 rearrangements were recovered which were identical but for six junctional (N region) nucleotides. The conservation of VH and D segment usage in the rearrangements of these Ly-1 B cell clones could indicate some strong selective pressure for clonal expansion (for example antigen selection) operates via the immunoglobulin molecules of these cells. Southern analyses of other (NZB x NZW)F1 mice with this cloned VH and the usage of the same or similar VH genes among a number of Ly-1 B origin tumors in other mouse strains indicate the generality of this repetitive VH gene usage in individual mice.     

Development of the B cell anti-DNA repertoire in (NZB x NZW)F1 mice. Relationship with the natural autoimmune repertoire.

The relationship between pathologic anti-DNA and natural autoantibodies (Auto Ab) remains unclear. In particular, it has not yet been elucidated whether pathologic anti-DNA antibodies originate from and are regulated by the pool of natural Auto Ab. To address this question, a large number of Ig-secreting hybridomas were derived from the unstimulated splenocytes of B/W mice, newborn to 12 mo of age, and their binding activities against a panel of self-Ag (DNA, actin, tubulin, myosin, and myoglobin), isotype, idiotypic determinants, and VH gene utilization were analyzed. A progressive increase in the number of Ig-secreting clones was observed and associated with a constant proportion (approximately 6%) of autoreactive B cell clones. However, dramatic changes in the pool of autoreactive B cell hybridomas were observed as the disease evolved, including the selective maintenance of IgM anti-DNA polyspecific antibodies, reduction in percentage of polyspecific IgM mAb with no DNA-binding activity, and the production of IgG anti-DNA antibodies of the IgG2 class. The kinetics, immunochemical properties, and idiotypic analysis of polyspecific IgM mAb with DNA-binding activity strongly suggest that they belong to natural Auto Ab and constitute the precursors of pathologic IgG anti-DNA antibodies. In addition, and IgM polyspecific antibody was demonstrated to bind IgG anti-DNA mAb through F(ab')2 interactions suggesting a regulatory role of natural antibodies and their participation in the control of pathologic Auto Ab production.     

Morphogenetic characteristics of the mammary glands of autoimmune F1 mice (NZB x NZW)

The morphogenesis of mammary glands was studied in the normal and autoimmune F1(NZW X NZB) mice. In the lactation cycle of the autoimmune mice the normal course of structural-functional rearrangements of parenchyma and stroma in the developing and involuting mammary glands was disturbed. A conclusion has been reached that the modification of stromal elements, first of all involved in the autoimmune disease, is the leading link in the abnormal development of mammary glands.     

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.     

Two dual-specific (anti-IgG and anti-dsDNA) monoclonal autoantibodies derived from the NZB/NZW F1 recognize an epitope in the hinge region

The anti-IgG properties of two dual-specific (anti-dsDNA and anti-IgG) monoclonal NZB/NZW F1-derived autoantibodies, BV 17–45 and BV 16–13, were studied to resolve the location and possible commonality of the IgG epitope. To determine if BV 17–45 and BV 16–13 recognized the same IgG epitope, the relative temperature sensitivity of the conformational IgG epitopes were evaluated using the conformational sensitive immunoassay. Comparison of the temperature sensitivity of the conformational immunoglobulin epitopes over a temperature range of 25–100°C suggested that the epitope recognized by BV 17–45 was the same as the IgG epitope recognized by BV 16–13. Further studies with papain- and pepsin-generated F(ab′)₂, Fab, and Fc fragments of BV 17–45 and BV 16–13 revealed that the dual-specific autoantibodies BV 17–45 and BV 16–13 both bound an epitope in the hinge region of the IgG molecule. The potential correlation between these studies and the pathogenic nature of dual-specific autoantibodies is discussed.     

Lupus prone (SWR x NZB)F1 mice produce potentially nephritogenic autoantibodies inherited from the normal SWR parent

The incidence of nephritis in autoimmune NZB mice is low, but when they are crossed with normal SWR mice, almost 100% of the female F1 hybrids (SNF1) develop lethal glomerulonephritis. To define the contribution of the normal SWR strain to the development of nephritis, we analyzed 65 monoclonal anti-DNA autoantibodies derived from SNF1 mice and compared them with those obtained from the NZB parent. The majority of the SNF1-derived anti-DNA antibodies were IgG and cationic in charge. By contrast, 77% of the NZB-derived antibodies were IgM. Moreover, all three NZB-derived IgG anti-DNA antibodies were anionic. The cationic property of the SNF1-derived IgG autoantibodies was not restricted to any particular antigenic specificity pattern or IgG subclass, nor was there a preference for the allotype of either parent. However, we identified a set of highly cationic (pI at 8.2 to 8.8 pH) IgG2b anti-DNA antibodies from SNF1 hybrids that had the SWR allotype. Isoelectric focusing of intact antibodies and isolated heavy and light chains showed that the highly cationic charge of these antibodies was determined by the variable regions of their heavy chains. Because IgG anti-DNA antibodies with cationic charge are especially pathogenic, those antibodies bearing the allotype of the normal SWR parent may account for the high incidence of severe nephritis in the F1 hybrids. The results indicate that pathogenic autoantibodies, which are encoded by genes of the nonautoimmune SWR parent, are expressed in the SNF1 mice due to some cellular and genetic regulatory influence of the NZB parent.     

Two dual-specific (anti-IgG and anti-dsDNA) monoclonal autoantibodies derived from the NZB/NZW F1 recognize an epitope in the hinge region

The anti-IgG properties of two dual-specific (anti-dsDNA and anti-IgG) monoclonal NZB/NZW F1-derived autoantibodies, BV 17–45 and BV 16–13, were studied to resolve the location and possible commonality of the IgG epitope. To determine if BV 17–45 and BV 16–13 recognized the same IgG epitope, the relative temperature sensitivity of the conformational IgG epitopes were evaluated using the conformational sensitive immunoassay. Comparison of the temperature sensitivity of the conformational immunoglobulin epitopes over a temperature range of 25–100°C suggested that the epitope recognized by BV 17–45 was the same as the IgG epitope recognized by BV 16–13. Further studies with papain- and pepsin-generated F(ab′)₂, Fab, and Fc fragments of BV 17–45 and BV 16–13 revealed that the dual-specific autoantibodies BV 17–45 and BV 16–13 both bound an epitope in the hinge region of the IgG molecule. The potential correlation between these studies and the pathogenic nature of dual-specific autoantibodies is discussed.     

Establishment of a nucleoside-specific suppressor T cell line from SLE prone (NZB/NZW)F1 mice

A long-term cultured suppressor T cell line (GTS-124) was established from an autoimmune mouse strain, (NZB X NZW)F1, by a two-part procedure: a) B/W F1 mice were made tolerant to guanosine (G) by administration of a tolerogen, the G-modified copolymer of D-glutamic acid and D-lysine (G-D-GL); and b) the spleen cells obtained from tolerant mice were repeatedly stimulated with mitomycin C-treated G-modified syngeneic spleen cells. The GTS-124 cells suppressed the secondary in vitro response to G-keyhole limpet hemocyanin (G-KLH) but did not suppress the response to unrelated antigens, sheep erythrocytes (SRBC), or trinitrophenyl-KLH (TNP-KLH). The expression of Thy-1 antigen on the cell surface of GTS-124 was demonstrated by flow cytometry. Growth of GTS-124 cells was dependent on IL 2. To determine whether GTS-124 cells could suppress the response to nucleosides other than G, KLH coupled with four nucleosides (adenosine [A], G, cytidine [C], and thymine riboside [T]) collectively (AGCT-KLH) was first used as the antigen in the assay system. The PFC response to the individual nucleosides (anti-A, -G, -C, and -T PFC) were effectively inhibited by GTS-124 cells, suggesting that the GTS-124 cells mediated cross-suppression toward all four nucleosides. A more stringent cross-suppression test was conducted by using only the T moiety bound to KLH (T-KLH) as antigen. The results showed that GTS-124 cells were capable of suppressing the T-specific response. The cross-suppression could be seen after repeated selection on a G-BSA-coated dish. These results provide direct evidence that the suppressor T cells induced by in vitro stimulation with G-modified self can indeed suppress the response to nucleosides other than G.     

Dietary fat and immune function. II. Effects on immune complex nephritis in (NZB x NZW)F1 mice

(NZB x NZW)F1 mice initiated on fat restriction at weanling were significantly protected from the development of immune complex glomerulonephritis. Whereas the mice on high-fat intake demonstrated immune depositions both in capillary walls and mesangial areas in a diffuse granular pattern, those on a low-fat diet with caloric content similar to the high-fat diets exhibited mesangial confinement of the depositions of immunoglobulins, complement, and retroviral gp70. In association with these divergent patterns of immune deposition, the mice on high-fat diets had evidence of extensive diffuse cellular proliferation, wire loop lesion, and sclerosis in the glomeruli. In contrast, most of the mice on the low-fat diet showed only mesangial cell and matrix proliferations. In addition, the group of mice fed high saturated fat showed more severe glomerular pathology as compared to those fed high unsaturated fat. Paradoxically, levels of circulating immune complexes (as measured by the polyethylene glycol precipitation technique) in the high saturated fat group were low and did not correlate with the findings by light and immunofluorescence microscopy. These findings suggest that dietary fat restriction can serve as either a prophylactic or effective therapeutic approach to murine lupus nephritis.     

Dietary fat and immune function. I. Antibody responses, lymphocyte and accessory cell function in (NZB x NZW)F1 mice

The influence of dietary fat on autoimmunity in lupus-prone (NZB x NZW)F1 mice has been demonstrated. In defining further the effects of dietary lipid on the immune system of this strain, female weanling mice were placed on four diets differing in quantity and type of fat. Their immunologic response was then studied by a variety of tests at 4 and 7 mo of age. Few differences were seen among the four groups at 4 mo of age. At 7 mo of age, however, the mice receiving diets high in saturated and unsaturated fats had a reduced mitogenic response to T cell mitogens and an enhanced response to the B cell mitogen LPS. Immunoglobulin levels and delayed hypersensitivity responses did not show any consistent differences among the diet groups. At 7 mo, however, mice receiving diets high in unsaturated fat demonstrated hyperresponsiveness to injected sheep red blood cells as measured by the hemolytic plaque technique. In addition, peritoneal leukocytes from the same diet group exhibited an increased response to bromelain-treated autologous erythrocytes which was decreased after treatment with anti-Thy-1 antiserum and complement. Phagocytosis by peritoneal macrophages was significantly decreased in the animals fed high-fat diets, particular high saturated fat. Similarly, natural killer cell activity was markedly reduced in the mice with a high intake of saturated lipid, a finding which correlated with the in vitro production of interferon. These results indicate that diets high in fat influence immune responses and thus can affect the onset and severity of autoimmune disease. A low-fat diet can reduce the development of disease by maintaining normal immune responses. The data also suggest that unsaturated fat may influence T helper cell activity and therefore antibody production, whereas saturated fats may affect cellular immune responses which are dependent on membrane contact.     

Intravenous infusion of PAF affects ovulation, fertilization and preimplantation embryonic development in NZB x NZW F1 hybrid mice

Platelet Activating Factor (PAF) is a bioactive phospholipid, which exhibits a variety of biological activities and plays a significant role in all aspects of reproduction. In this work, a single intravenous injection of various concentrations of PAF shortly after Human Chorionic Gonadotropin (HCG) administration as well as 24 and 48 h before HCG administration was studied in NZB x NZW F1 hybrid mice. Optimum results were observed when PAF was injected just after the administration of HCG. In this protocol, the concentrations of PAF exhibited bell-shaped response to every stage of development. Any concentration of PAF between 5.5 x 10(-11) and 5.5 x 10(-15)g/g b.w., caused an improved ovulation rate, an increased fertilization rate, an increased rate of cell cycle and an enhanced hatching blastocyst rate (P<0.05 for all stages). Injection of lyso-PAF had no effect in any stage. Our data show that the effect of PAF on early stages of embryo development in vitro is dependent on its way of administration, on the concentrations used as well as on the time PAF is injected.     

Studies of tolerance to DNA in NZB/NZW F1 mice.

Administration of sDNA-poly-D-lysine (DNA-PDL) to newborn NZB/NZW F1 mice (B/W) was previously shown to prolonge survival and to decrease nephritis and DNA antibodies. In this study, B/W mice treated from birth with DNA-PDL were found to be tolerant to immunization with sDNA on PDL or mBSA carriers in adjuvants. Tolerance to sDNA was present and was hapten-specific carrier-dependent. IgG and IgM anti-nDNA circulating antibodies were suppressed. Continuous tolerization was necessary to maintain tolerance. Tolerance to sDNA could be transferred by spleen cells, by tolerized thymus cells, and by tolerized bone marrow cells, suggesting that both T and B cells participated in this phenomenon.