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.     

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.     

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.     

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.     

Induction of autoimmune phenomena in normal mice treated with natural thymocytotoxic autoantibody

Natural thymocytotoxic autoantibody (NTA) developed spontaneously in New Zealand Black (NZB) mice consists of two autoantibodies in terms of target cell specificity. One of the autoantibodies, NTA-2, is strongly cytotoxic only against desialized lymphocytes, whereas the other one, NTA-1, is cytotoxic against both intact thymocytes and asialolymphocytes. To study the pathogenic role of NTA in murine autoimmunity, DBA/2 mice were injected every other day with affinity-purified NTA (NTA-1, NTA-2). Control mice received normal mice sera (NMS) or saline. After 20 days of treatment, spleen cells from DBA/2 mice treated with NTA-1 or NTA-2 showed a significant increase in the number of anti-ssDNA plaque-forming cells and IgM-producing cells. Sera from NTA-treated mice showed greater DNA binding than sera from control mice did. The levels of proteinuria were moderately increased in NTA-2-treated mice. Con A responsiveness of thymocytes was markedly reduced in NTA-2-treated mice. On the other hand, Con A-activated spleen cells from both control and NTA-treated mice equally suppressed anti-SRBC antibody production in vitro, suggesting that NTA treatment didn't affect the direct precursors of suppressor T cells. Finally, prior absorption of NTA-1 by thymocytes prevented its ability to induce anti-DNA antibodies; however, prior absorption of NTA-2 by thymocytes didn't affect its activity.     

Autoimmune alterations induced by the New Zealand Black Lbw2 locus in BWF1 mice

The New Zealand Black (NZB) Lbw2 locus (lupus NZB x New Zealand White (NZW) 2 locus) was previously linked to mortality and glomerulonephritis, but not to IgG autoantibodies, suggesting that it played a role in a later disease stage. To define its contribution, (NZB x NZW)F1 hybrids (BWF1) containing two, one, or no copies of this locus were generated. Lack of the NZB Lbw2 indeed reduced mortality and glomerulonephritis, but not serum levels of total and anti-DNA IgG Abs. There were, however, significant reductions in the B cell response to LPS, total and anti-DNA IgM and IgG Ab-forming cells, IgM Ab levels, and glomerular Ig deposits. Furthermore, although serum IgG autoantibody levels correlated poorly with kidney IgG deposits, the number of spontaneous IgG Ab-forming cells had a significant correlation. Genome-wide mapping of IgM anti-chromatin levels identified only Lbw2, and analysis of subinterval congenics tentatively reduced Lbw2 to approximately 5 Mb. Because no known genes associated with B cell activation and lupus are in this interval, Lbw2 probably represents a novel B cell activation gene. These findings establish the importance of Lbw2 in the BWF1 hybrid and indicate that Lbw2, by enhancing B cell hyperactivity, promotes the early polyclonal activation of B cells and subsequent production of autoantibodies.     

The nonobese diabetic mouse model. Independent expression of humoral and cell-mediated autoimmune features

Nonobese diabetic (NOD) mice present concomitant signs of cell-mediated and humoral autoimmunity. Whereas the involvement of the cell-mediated manifestations in the pathogenesis of diabetes has been clearly demonstrated, the origin and the relevance of the humoral manifestations is still unclear. In the present study, we have tried to determine whether the humoral manifestations observed in NOD mice were secondary to the cell-mediated antiislet reaction, or whether they resulted from an autonomous polyclonal activation of B cells, a possibility suggested by the notorious presence of antilymphocyte antibodies with thymocytotoxic properties, in the serum of old NOD females. To discriminate between the two alternatives, we have followed the titers of thymocytotoxic autoantibodies in aging males and females, as well as in F1 hybrids where the organ-specific disease is recessive, and in back-crossed mice where the susceptibility genes responsible for insulitis and diabetes have segregated. In addition to thymocytotoxic antibodies, we have also screened the sera of these animals for hyperglobulinemia, antiinsulin, and anti-DNA autoantibodies that are classically associated with polyclonal B cell activation in autoimmune strains of mice. The results indicate that these humoral anomalies are clearly disconnected from the occurrence of diabetes and even of insulitis. Lymphocytotoxic antibodies appear several weeks after the onset of insulitis in NOD mice, are not correlated with disease occurrence and have no predictive value for its onset. The humoral manifestations that include, beside thymocytotoxic antibodies, antiinsulin antibodies, hyperglobulinemia, but no anti-DNA antibodies, are found at the same frequency in F1 mice as in parental mice in spite of the fact that the former are practically free of insulitis lesions. These anomalies are also randomly distributed among back-crossed mice independently of the presence and the severity of the organ-specific lesions. Altogether, these results suggest that NOD mice, like other autoimmune strains, suffer from a genetically inherited defect of B cell regulation resulting in the hyperproduction of natural autoantibodies.     

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.     

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.     

Anti-Sm autoantibodies in MRL mice: analysis of precursor frequency

Individual MRL-lpr mice vary in their capacity to generate anti-Sm autoantibodies spontaneously. We have compared the frequency of B-cell precursors for this autoantibody in serologically negative and serologically positive MRL-lpr mice, and in normals. Anti-Sm precursors were present in a frequency of approximately 1 per 10-30,000 in spleen cell cultures from anti-Sm positive mice, but were undetectable when spleen cells from serologically negative MRL-lpr mice or from normal mice were examined. Despite LPS stimulation, neither IgM nor IgG precursors could be detected. In parallel cultures, in contrast, anti-DNA autoantibody precursors were readily detected. The results thus indicate that, for the lupus-specific autoantibodies, the absence of antibody in autoimmune mice reflects a deficit in precursor B lymphocytes rather than an active regulatory mechanism. It is suggested that the generation of anti-Sm may reflect a low-probability random event in the generation of B-cell diversity.     

The relationship between circulating CD5+ B lymphocytes and in vitro autoantibody synthesis in normal individuals.

Recent observations suggest that a subpopulation of B lymphocytes bearing the phenotype CD5+ may be enriched for cells committed to the synthesis and secretion of autoantibodies. We had previously shown that a subset of normal individuals has an expanded subpopulation of B lymphocytes committed to the synthesis of IgM and IgM-rheumatoid factor (RF), and that this condition was associated with HLA-DR4 (4). In these studies, we performed simultaneous quantitation of the size of the circulating CD5+ B lymphocyte subpopulation in a group of 20 normal donors, and of the pokeweed mitogen-induced in vitro synthesis of a panel of autoantibodies by the same peripheral blood cells depleted of CD8+ suppressor lymphocytes in 18 of the 20 individuals. The culture supernatants were assayed for total IgM and IgG, RF, IgM, and IgG anti-single-stranded DNA, anti-human thyroglobulin, and anti-tetanus toxoid. The mean percentage CD5+ B cells was 13.5 +/- 2.5%. There was no significant correlation between total B lymphocytes and CD5+ B cells (R = 0.25, P greater than 0.20. Positive correlations were found between the proportion of circulating CD5+ B lymphocytes and synthesis of RF (R = 0.73, P less than 0.001), and IgM anti-DNA (R = 0.58, P less than 0.03). Significant correlations were not found between CD5+ B cells and secreted IgM or IgG antibodies against the exogenous antigen tetanus toxoid, measured in the same supernatants. The antibodies produced in vitro by T cell-dependent B cell activation appear to have limited or no polyspecificity. These results indicate that the size of the circulating CD5+ B cell subpopulation in any given individual contributes importantly to the magnitude of autoantibody synthesis in cultures where T cell-mediated B lymphocyte activation takes place in the absence of suppressor signals.     

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.     

Treatment of NZB/NZW mice with total lymphoid irradiation: long-lasting suppression of disease without generalized immune suppression

We used total lymphoid irradiation (TLI; total dose = 3400 rad) to treat the lupus-like renal disease of 6-mo-old female NZB/NZW mice. Similar to our past studies, this treatment resulted in a marked prolongation of survival, decrease in proteinuria, and decrease in serum anti-DNA antibodies compared with untreated littermate controls. Although there was no evidence of disease recurrence in TLI-treated mice until after 12 mo of age, the in vitro proliferative response to phytohemagglutinin by NZB/NZW spleen cells recovered within 6 wk such that responses were greater than control NZB/NZW animals. A similar recovery and overshoot after TLI were evident in the primary antibody response to the T cell-dependent antigen sheep red blood cells (SRBC). Both the total and IgG anti-SRBC antibody responses after TLI were greater than those of untreated NZB/NZW controls, and were comparable with those of untreated non-autoimmune mice. Despite this increased response to mitogens and antigens after TLI, we noted a decrease in spontaneous splenic IgG-secreting cells and a decrease in IgG but not IgM antinuclear antibody production. Nonspecific suppressor cells of the mixed leukocyte response were detectable in the spleens of NZB/NZW mice early after TLI. However, the disappearance of suppressor cells was not associated with recrudescence of disease activity. Furthermore, transfer of large numbers of spleen cells from TLI-treated NZB/NZW mice did not result in disease suppression in untreated age-matched recipients. In summary, treatment of NZB/NZW mice with TLI results in a prolonged remission in autoimmune disease, which is achieved in the absence of generalized immunosuppression.     

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.     

IgG autoantibody activity in normal mouse serum is controlled by IgM

In the serum of normal BALB/c mice, IgG antibody reactivity to mouse actin and tubulin, DNA, and TNP groups was very low compared to that of the IgM. This activity was considerably increased when IgG was separated, by affinity chromatography on protein A-Sepharose, whereas no difference in the IgM activity was observed. Addition of IgM to IgG isolated from the same serum resulted in the inhibition of IgG binding to these Ag. Isolation of IgG antibodies on actin, TNP, and tubulin immunoadsorbents has indicated that at least part of the IgG antibodies is polyreactive. In order to understand this inhibition better, experiments with F(ab')2 fragments of IgG were performed. IgM inhibited the binding of F(ab')2 to the antigens in a dose-dependent manner and reacted with immobilized F(ab')2. IgM isolated on F(ab')2 immunoadsorbent, as compared to the initial IgM preparation, were less active toward the Ag but more inhibitory for IgG binding to the Ag. In some pathologic situations, IgM failed to inhibit some IgG antibody activities. The anti-DNA IgG activity from (NZB x NZW)F1 mice was not affected by autologous IgM. Similarly the anti-tubulin IgG from mice infected with Trypanosoma cruzi were less inhibited by IgM from autologous serum than antitubulin IgG from normal mice. These results are compatible with the existence in normal mice of an idiotypic-like network, regulating via an IgM population in the serum, the binding of IgG autoantibodies to self Ag. Modifications of this idiotype-anti-idiotype system might lead to the expression and/or expansion of autoreactive IgG-producing clones.     

Failed self-tolerance and autoimmunity in IgG anti-DNA transgenic mice.

Transgenic mice were generated that express both the H and L chain genes derived from a hybridoma secreting an IgG2a mAb specific for ds- and ssDNA. This hybridoma is derived from a lupus mouse and can accelerate nephritis in young NZB x NZW F1 female mice and induce clinical nephritis in BALB/c mice. Some transgenic B cells did not exhibit allelic exclusion; they expressed both transgene-derived IgG and endogenous IgM intracellularly. Most of the B cells in transgenic mice expressed endogenous IgM, some of them expressed low levels of IgG on cell membranes. The transgenic mice, created in a strain not prone to SLE, expressed elevated serum IgG anti-DNA, and some developed clinical nephritis. The affinity of the spontaneously secreted IgG antibodies for dsDNA were similar in nephritic NZB x NZW F1 and transgenic mice. In contrast to the nontransgenic littermates, immunization of transgenic mice with murine DNA further enhanced serum levels of IgG anti-DNA in transgenic mice. Therefore, expression of transgene-encoded IgG anti-DNA mainly in the secreted form does not provide the signals necessary for allelic exclusion or self-tolerance. Expression of this Ig is sufficient to induce a mild form of autoimmune disease.     

Modulation of SLE induction in naive mice by specific T cells with suppressor activity to pathogenic anti-DNA idiotype.

T cells (CD8+) with specific suppressor activity against anti-dsDNA antibody (16/6 Id+) were generated in vitro. The cells were established from BALB/c-enriched T cells exposed in vitro to silica beads coated with the pathogenic anti-DNA idiotype, 16/6. The idiotype specificity of the suppressor cells was demonstrated by (a) specific induction of a decrease in proliferative response of T helper cell lines specific for the pathogenic idiotype (16/6 Id), when exposed to the idiotype, with no effect on T cell lines with other specificities, e.g., against human IgM or synthetic polypeptide. (b) Effectively suppressing in vitro antibody production of anti-16/6 antibody, employing 16/6-primed B cells and specific helper T cell line. The 16/6 Id-specific Ts cells were found to be MHC restricted. Weekly intravenous injections of 10(7) 16/6 Id-specific Ts cells given to BALB/c mice at different stages of experimental SLE disease prevented the clinical, serological, and pathological manifestations. This effect was characterized by decreased titers of autoantibodies (e.g., anti-DNA, anti-Sm antibodies) in the sera, by abolishment of the proteinuria, leukopenia, and the increased ESR, followed by decreased immunoglobulin deposition in the kidneys. Treating the mice with control IgM-specific T cells did not affect the above parameters. These studies demonstrate the ability to generate Ts cells specific for pathogenic idiotypes. The method might be employed therapeutically to modulate the course of autoimmune conditions.     

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.     

The effects of pepsin on the natural progression of autoimmunity in glomerulonephritis in the NZB/W F1 mouse

The effects of pepsin on autoimmune glomerulonephritis of New Zealand Black and White F1 hybrid (NZB/W F1) mice were investigated. Intravenous pepsin significantly improved survival rate and suppressed progressive increase in urinary protein and histopathological changes in kidney. Increased serum levels of immune complexes, anti-DNA antibody and natural thymocytotoxic autoantibody were decreased and abnormalities in lymphocyte subsets were ameliorated by pepsin. Pepsin suppressed autoantibody production and enhanced antibody production against xenogeneic substance in these mice. The fact that pepsin ameliorates abnormalities in immune function may contribute to the preventive effects of pepsin against pathogenesis and progression of immune complex nephritis.     

Specific and shared idiotypes found on hybridoma anti-DNA autoantibodies derived from rheumatoid arthritis and systemic lupus erythematosus patients

The idiotype determinants found on hybridoma anti-DNA autoantibodies produced from the fusion of peripheral blood lymphocytes from 13 systemic lupus erythematosus (SLE) and five rheumatoid arthritis (RA) patients with the GM 4672 human lymphoblastoid line were analyzed. A total of 47 SLE and 21 RA hybridomas were studied, of which 26 SLE and 10 RA produced anti-DNA autoantibodies. Rabbit antisera, raised to six of the SLE hybridoma anti-DNA IgM antibodies, were rendered idiotype specific by multiple absorptions on human IgM and IgG immunoabsorbent columns. In direct binding radioimmunoassays, all six anti-idiotype antisera reacted specifically with the anti-DNA antibody used as immunogen. In competition studies, five anti-idiotype antisera were able to inhibit the binding of their homologous idiotype to DNA-coated tubes. In addition, DNA and polynucleotides inhibited the binding of the five idiotypes to anti-idiotype-coated tubes, suggesting that these anti-idiotypes react with idiotype determinants located within the antigen-combining sites of the anti-DNA antibody molecules. Shared idiotypes were detected among the 68 hybridoma antibodies by direct binding studies on anti-idiotype-coated tubes. Our results revealed that 58% (21/36) of the anti-DNA antibodies and 16% (5/32) of the non-DNA-binding antibodies reacted with at least one anti-idiotype serum. Five anti-idiotype antisera reacted only with hybridoma anti-DNA antibodies from SLE patients. The other anti-idiotype antiserum reacted with both SLE- and RA-derived hybridoma anti-DNA and non-DNA-binding antibodies. These studies indicate that some anti-idiotype antisera may detect specific idiotypes found only on SLE-derived anti-DNA auto-antibodies, whereas other antisera detect shared idiotypes found on both RA and SLE DNA-binding and non-DNA-binding antibodies.