Differences in the reactivity of CD4+ T-cell lines generated against free versus nucleosome-bound SV40 large T antigen.

Previous results have revealed a strong correlation between polyomavirus BK reactivation and disease activity and antinuclear auto-antibody production in the human autoimmune disease systemic lupus erythematosus. BK virus establishes a latent infection in most humans, and reactivation requires the production of the DNA-binding large T antigen. Experimentally induced expression of the polyomavirus SV40 large T antigen in mice induces both an immune response to large T antigen and autoimmune response to nuclear antigens and antinuclear antibody production. Previous results have indicated that human T-antigen-specific CD4+ T-cell lines are stimulated equally by free, soluble and nucleosome-bound T antigen. This study was designed to determine how antigen processing of nucleosomes containing bound SV40 large T antigen may affect the specificity and response characteristics of experimentally induced T-antigen-specific CD4+ T cells. The results indicated that CD4+ T-cell lines generated from mice immunized with soluble, free T antigen responded very poorly in response to stimulation with T antigen bound to nucleosomes. CD4+ T-cell lines generated from mice immunized with nucleosomes that had bound T antigen in situ responded to both free and nucleosome-bound T antigen. The T-antigen-specific, CD4+ memory T cells induced by latent polyomavirus infections in humans may be uniquely suited to initiate autoimmunity to nuclear antigens upon virus reactivation.

Induction of anti-DNA antibody with DNA-peptide complexes.

Spontaneous anti-DNA antibodies in autoimmune mice have the characteristics of antibodies produced by antigen-specific, clonally selective B cell stimulation. The nature of the somatically derived antibody variable region structures recurrent among spontaneous anti-DNA antibodies suggests that DNA or DNA-protein complexes may provide the antigenic stimulus for autoimmune anti-DNA antibody. Previously we have demonstrated that native mammalian DNA in complexes with an immunogenic DNA-binding peptide Fus1 from Trypanosoma cruzi can induce anti-DNA antibody in mice not genetically prone to autoimmune disease. The induced anti-DNA has similar specificity, structure and immunopathological function as autoimmune anti-DNA. The present experiments were designed to further characterize the immune response to DNA-peptide complexes. There was considerable variation in the antibody responses of mice from different strains to DNA-Fus1 immunizations. The range was from virtually no response in C57BL/6 mice to most robust responses in NZW mice. The full-length 52 amino acid carboxy-extension protein of ubiquitin (CEP) in T. cruzi (TCEP) protein from which Fus1 was derived functions equally well as an immunogenic carrier for DNA. Anti-DNA responses were generally weak even though anti-Fus1 and anti-TCEP responses were very strong. The results are discussed with respect to the contrasting roles of T cell help and peripheral B cell tolerance in controlling immune and autoimmune antibody responses to DNA.

Analysis of the virus-specific and nonspecific B cell response to a persistent B-lymphotropic gammaherpesvirus.

Respiratory challenge of mice with murine gammaherpesvirus 68 (gammaHV68) results in acute replication in respiratory epithelial cells and persistent, latent infection of B cells and macrophages. gammaHV68 elicits virus-specific Ab, and also nonspecifically activates B cells to Ab production through a CD4+ T cell-dependent process. The current analysis characterizes virus-specific and nonspecific Ab production at the single cell level and investigates the requirements and nature of the nonspecific response. Virus-specific Ab-forming cell (AFC) numbers were dwarfed by the increase in total AFC in all sites examined, indicating substantial nonspecific Ab production. Clear increases and decreases in specific and total AFC numbers occurred in the lymph nodes draining the respiratory tract and the spleen, but AFC numbers in the bone marrow (BM) increased to a plateau and remained constant. The longevity of the BM response was reflected in a sustained increase in virus-specific and total serum Ab levels. Generally, the IgG2a and IgG2b isotypes predominated. Analysis of cytokine-deficient mice, CD40 ligand-deficient mice, and radiation BM chimeras lacking MHC class II expression specifically on B cells indicated that nonspecific Ab production is independent of IL-6 or IFN-gamma, and dependent on cognate CD4+ T cell help. Several observations were consistent with polyclonal B cell activation by gammaHV68, including the induction of durable serum levels of IgG reactive with mammalian dsDNA and murine type II collagen. Our findings indicate new directions for studies of this valuable model of gamma-herpesvirus pathogenesis.

The murine clan V(H) III related 7183, J606 and S107 and DNA4 families commonly encode for binding to a bacterial B cell superantigen.

Superantigens, by virtue of their unconventional binding interactions with Ag receptors, can simulate a large subset of mature lymphocytes in the repertoire. Recent studies have documented that in vivo exposure to the model bacterial B cell superantigen, Staphylococcal protein A (SpA), induces large scale effects on murine B-cell clonal selection by mechanism(s) that include deletion of supra-clonal sets. While the structural bases for the immunomodulatory properties of several T-cell superantigens have been well characterized, the requirements for murine Fab-binding of SpA remain incompletely defined. To investigate these structural requirements, a series of direct binding and inhibition studies were performed with a large panel of Moabs of diverse variable region gene usage. These studies confirm previous reports that superantigen binding is completely restricted to the products of clan V(H) III-related families, that include the small S107 and J606 families, and we also demonstrated that usage of the related small DNA4 family commonly correlates with weaker binding activity. Furthermore, our results document that genes from the largest clan V(H) III family, 7183, commonly encode for Fab-mediated binding of SpA, while antibodies from five other VH families, J558, Q52, Sm7, VH11 and VH12, did not display Fab-mediated SpA binding activity. By contributing to the essential foundation for understanding of the structural basis for binding interactions, these findings will aid interpretation of evolving observations regarding the clonal fates induced by in vivo B-cell superantigen exposure.

Termination of human T cell tolerance to histones by presentation of histones and polyomavirus T antigen provided that T antigen is complexed with nucleosomes.

OBJECTIVE: To investigate whether polyomavirus T antigen linked to histones through nucleosome-T antigen complexes has the potential to terminate histone-specific T cell anergy. METHODS: Blood mononuclear cells from healthy individuals were used as the source to establish T cell lines initiated and maintained by T antigen, histones, nucleosome-T antigen complexes, or nucleosomes. Proliferative responses of these lines to T antigen, histones, and nucleosomes were determined. RESULTS: Whereas T cell lines could be established using T antigen or T antigen-nucleosome complexes, histones or nucleosomes did not have this potential. However, T cell lines selected by T antigen-nucleosome complexes responded subsequently to histones and nucleosomes. Identical results were obtained with murine and human nucleosomes, provided that they were complexed with T antigen. CONCLUSION: T antigen-specific T cells possess the potential to proliferate when interacting with an antigen-presenting cell that presents T antigen. In the presence of T antigens complexed with nucleosomes, T antigen-specific T cells offer bystander help that may terminate histone-specific T cell anergy. These T cells may progress into functional, autoimmune T cells if histones are properly presented.

Mg2+ induces conformational changes in the catalytic subunit of phosphorylase kinase, whether by itself or as part of the holoenzyme complex.

Phosphorylase kinase (PhK) from skeletal muscle is a structurally complex, highly regulated, hexadecameric enzyme of subunit composition (alpha beta gamma delta)4. Previous studies have revealed that the activity of its catalytic gamma subunit is controlled by alterations in quaternary structure initiated at allosteric and covalent modification sites on PhK's three regulatory subunits; however, changes in the conformation of the holoenzyme initiated by the catalytic subunit have been more difficult to document. In this study a monoclonal antibody (mAb gamma79) has been generated against isolated gamma subunit and used as a conformational probe of that subunit. The epitope recognized by this antibody is within the catalytic core of the gamma subunit, between residues 100 and 240, and monovalent fragments of the antibody inhibit the catalytic activity of the holoenzyme, the gamma-calmodulin binary complex, and the free gamma subunit. Activation of PhK by a variety of mechanisms known or thought to act through its regulatory subunits (phosphorylation, ADP binding, or alkaline pH) increased the binding of the holoenzyme to immobilized mAb gamma79, indicating that activation by any of these distinct mechanisms involves repositioning of the portion of the catalytic domain of the gamma subunit containing the epitope for mAb gamma79. The activating ligand Mg2+ also stimulated the binding of the PhK holoenzyme to immobilized mAb gamma79, as well as the binding of mAb gamma79 to immobilized gamma subunit. Thus, Mg2+ increases the accessibility of the mAb gamma79 epitope in both the isolated gamma subunit and in the holoenzyme. Our results suggest that previously reported influences of Mg2+ on the quaternary structure of the PhK holoenzyme are directly mediated by the gamma subunit.

Effects of immunosuppression on the development of cochlear disease in the MRL-Fas(lpr) mouse.

OBJECTIVES: The MRL-Fas(lpr) mouse, an animal that spontaneously develops multisystemic autoimmune disease, has been proposed as model of immune-mediated inner ear disease. Previous studies revealed that this mouse manifested elevated auditory brainstem response thresholds, hydropic degeneration of strial cells, and antibody deposition within strial capillaries. As the etiology of the observed strial disease may be immune, genetic, or uremic, a study was designed to attempt to delineate between these possible etiologic factors. STUDY DESIGN: Prospective, controlled animal study. METHODS: Dexamethasone, which is known to suppress autoantibody production and glomerulonephritis in these animals, was administered systemically on a daily basis to experimental animals, beginning at 6 weeks of age. Control animals received no treatment. Animals were allowed to age, with control animals predictably manifesting systemic disease at 20 weeks of age, at which point all animals were sacrificed. RESULTS: Animals receiving dexamethasone treatment manifested a significant reduction in serum immunoglobulin levels, lymphoid hyperplasia, and a significant improvement in the level of renal function. However, morphologic analysis revealed a persistence of strial disease despite the elimination of strial antibody deposition. CONCLUSION: The results of this experiment support the hypothesis that genetic mechanisms may be responsible for the observed strial disease. Further studies are under way to confirm these findings.

Comparison of the frequencies of arginines in heavy chain CDR3 of antibodies expressed in the primary B-cell repertoires of autoimmune-prone and normal mice.

Because the pathogenesis of anti-DNA Ab in SLE is correlated to Ab specificity for native DNA (dsDNA), understanding how such specificity is generated is important. The VH structures of most autoimmune anti-DNA antibodies include at least one arginine in VH-CDR3; moreover, antibody specificity for dsDNA can be correlated to the relative position of arginines in VH-CDR3. The coding sequences for most VH-CDR3 arginines among the anti-DNA MoAbs we have studied to date appeared to have been encoded by sequences generated during V-D-J recombination and would have been expressed in the primary B-cell repertoire. The frequency at which arginine codons are generated during V-D-J recombination therefore could potentially influence the frequency at which DNA-specific B cells are generated in the primary B-cell repertoire. The present study was undertaken to determine whether a higher percentage of B cells in the primary, preautoimmune repertoire of autoimmune-prone (NZB x NZW)F1 mice have immunoglobulin heavy chains with at least one VH-CDR3 arginine compared to B cells in the primary, preimmune repertoire of non-autoimmune-prone BALB/c mice. The present results indicate that mature B cells in preautoimmune (NZB x NZW)F1 mice, whether specific for DNA or not, are no more likely to have heavy chains with VH-CDR3 arginines than are B cells in BALB/c mice. The high frequency of recurrence of VH-CDR3 arginines among autoimmune anti-DNA in (NZB x NZW)F1 mice would appear to derive from the selective oligoclonal expansion of selected B cells that express such structures.

Expression of an anti-DNA-associated VH gene in immunized and autoimmune mice.

The J558 family BW-16 VH gene is closely associated with the autoimmune response to DNA of lupus-prone mice. We have followed the expression of VHBW-16-encoded heavy chains in cDNA libraries prepared from unmanipulated normal (C3H, AKR) and autoimmune (New Zealand Black/New Zealand White F1) mice, and from mice immunized with a highly immunogenic peptide/DNA complex. The prevalence, clonal heterogeneity, and structural properties (somatic mutation, complementarity-determining region 3 composition) of these H chains were investigated, and the DNA affinity of VHBW-16-encoded hybridoma mAb was measured in solution. We find that H chains encoded by VHBW-16 are very rare in Igs of normal mice, but increase significantly in peptide/DNA-immunized mice, and dramatically in diseased mice. The experimentally induced VHBW-16-encoded H chains are clonally restricted, somatically mutated, partly switched from IgM to IgG, and give rise to anti-DNA Abs with low affinity. In contrast, the VHBW-16-encoded H chains from diseased New Zealand Black/New Zealand White mice are clonally heterogeneous, exclusively of the IgG isotype, and produce high affinity anti-DNA autoantibodies. We conclude that the experimentally induced and spontaneous immune responses to DNA are qualitatively similar, but quantitatively different, and may truly reflect the principles of self immunologic tolerance.

Monoclonal anti-DNA antibodies: structure, specificity, and biology.

Anti-DNA antibodies are a major contributor to the pathogenesis associated with the autoimmune disease systemic lupus erythematosus in mice and human. The accumulation of a large body of structural information on autoimmune anti-DNA antibodies over the past several years, particularly from mice, has provided considerable insight into the structure, function, and biology of this important class of autoantibodies. Even though the germline repertoire of light and heavy chain variable regions that may encode DNA-specific antibodies is very large in mice, there are individual light and heavy chain variable region genes that have been recurrent and preferentially expressed among anti-DNA hybridomas. This has been particularly true for hybridomas producing antibodies that bind duplex, B-form, mammalian DNA (dsDNA). Recurrent somatically derived variable region structures, particularly arginines in the third complementary-determining region of the heavy chain (VH-CDR3), have also been recurrent and preferentially expressed among monoclonal anti-DNA antibodies. In fact specificity for dsDNA can be correlated to the relative amino acid position at which arginines are expressed within VH-CDR3 of anti-DNA. Most important from the results of structural analyses of monoclonal anti-DNA autoantibodies has been the realization that autoimmunity to DNA results from a clonally selective, antigen-specific immune response to DNA. Autoimmune antibodies to DNA have all of the characteristics of secondary immune antibodies. In further support of this hypothesis, we have been able to induce anti-DNA antibodies in normal, nonautoimmune mice by immunization with immunogenic DNA-peptide complexes. The induced antibodies have all of the structural and functional characteristics of autoimmune anti-DNA including the pathogenetic potential to induce glomerulonephritis. This review summarizes the results of research from our laboratory that support the above conclusions.

Proximal regions of the catalytic gamma and regulatory beta subunits on the interior lobe face of phosphorylase kinase are structurally coupled to each other and with enzyme activation.

Phosphorylase kinase from skeletal muscle is a hexadecameric enzyme with the subunit composition (alphabeta gammadelta)4 and a mass of 1.3 x 10(6) Da. The catalytic gamma subunit and the remaining regulatory subunits are packed as a tetrahedral structure composed of two elongated, opposing (alphabeta gammadelta)2 octameric lobes. We show by immunoelectron microscopy with subunit-specific monoclonal antibodies that a portion of the beta subunit occurs on the interior face of the lobes at a region of inter-lobal interactions, and that at a proximal position slightly more central and distal on the interior lobe face lies the base (residues 277 to 290) of the helical domain of the catalytic core of the gamma subunit. Activation of the kinase by a variety of means caused similar increases in the binding to the holoenzyme of the monoclonal antibodies against these two regions of the beta and gamma subunits. Moreover, monovalent fragments of the antibodies against both regions stimulated the activity of the non-activated holoenzyme. Thus, the epitopes of the beta and gamma subunits recognized by the monoclonal antibodies are structurally coupled to each other and with the activation of phosphorylase kinase. Activation of the holoenzyme apparently involves the repositioning of the base of the catalytic domain of the gamma subunit and a proximal region of the beta subunit within the identified area on the interior face of the lobes of the tetrahedral phosphorylase kinase molecule.

Autoantibodies to murine type II collagen in collagen-induced arthritis: a comparison of susceptible and nonsusceptible strains.

Collagen-induced arthritis (CIA) is an experimental autoimmune disease elicited in genetically susceptible strains of mice by immunization with heterologous type II collagen. This experimental disease is mediated by the immune response of both T cells and B cells, and susceptibility is restricted by the class II molecules of the MHC. In this study we identify specific epitopes bound by autoantibodies elicited through immunization of several haplotypes of C57BL/10 mice with chick alpha1 (II)-CB11. ELISA analysis using a panel of 15-mer murine type II collagen peptides revealed a pattern of autoantibody epitope specificity that was remarkably similar among CIA-susceptible and nonsusceptible congenic strains, regardless of class II haplotype. However, one epitope was identified that was bound only by autoantibodies from CIA-susceptible strains bearing I-A(q) (B10.Q and B10.QbetaBR). In addition, this epitope was also present within affinity-purified Ab obtained from the CIA-susceptible strain DBA/1 (I-A(q)). Analyses of immune serum from B10.Q and B10.QbetaBR mice revealed that a subset of the antibodies binding this epitope were of the IgG2 subclass, and therefore efficient at fixing complement, a requirement for pathogenicity of the Abs in CIA.

Correlation between the amino acid position of arginine in VH-CDR3 and specificity for native DNA among autoimmune antibodies.

Autoimmunity to DNA in mouse models for the systemic autoimmune disease systemic lupus erythematosus (SLE) has all of the characteristics of an Ag-driven secondary immune response to DNA. Since the pathogenesis of anti-DNA Ab in SLE is correlated to Ab specificity for native DNA (dsDNA), understanding how such specificity is generated is important. As with immune A responses to most Ags, autoimmune Ab responses to DNA are dependent upon the clonal selection of B cells expressing particular H and L chain V-region structures. The VH structures of most autoimmune anti-DNA Abs include at least one arginine in VH-CDR3; moreover, previous results led us to propose that anti-DNA Ab specificity for dsDNA may be dependent upon the relative position of arginines in VH-CDR3. The present results demonstrate a strong correlation between specificity for dsDNA and arginine position in VH-CDR3, for Abs with V, encoded by VH genes from the VH7183, VHQ52, and VHS107 families but not from the VH558 family. Specificity for dsDNA was not only correlated to the presence of VH-CDR3 arginines but also to the relative position of the arginines in VH-CDR3. The majority of the VH-CDR3 arginines appeared to have been encoded by sequences generated during V-D-J recombination. These results are not only important for understanding how A specificity for dsDNA is generated but also how somatically derived structures generated during V-D-J recombination may influence clonotype selection of an immune response within an individual mouse.

Variable-region gene family usage for type II collagen autoantibodies in arthritis-susceptible DBA/1 mice.

Collagen-induced arthritis is mediated by autoantibodies to type II collagen (CII). This experimental model has proven useful in determining the molecular and cellular mechanisms responsible for autoimmune arthritis. We have shown that polyarthritis can be transferred to normal mice by administering combinations of three or four complement-fixing monoclonal antibodies (mAbs) which recognize cross-reactive epitopes on the alpha 1(II)-CB11 region of chick and mouse CII. Currently, the light- and heavy-chain variable-region structures on a panel of alpha 1 (II)-CB11-specific mAbs that cross-react with chick and mouse CII, or react solely with chick CII, have been analyzed. The results indicate biased usage of VK19 and VK21 families of light-chain variable-region genes but random VH gene usage. Interestingly, two mAbs derived from different mice recognized identical epitopes on mouse CII and had nearly identical light- and heavy-chain variable-region structure including junctionally derived sequence.

Immunoglobulin variable-region structures in immunity and autoimmunity to DNA.

Important to the immunopathology associated with the autoimmune disease systemic lupus erythematosus, is the production of autoantibody to DNA. Crucial to understanding the immunological basis for autoimmunity to DNA is knowing whether the anti-DNA autoantibody is the product of clonally-selective, antigen-specific B cell stimulation or non-selective, polyclonal B cell activation. Structural analyses of the immunoglobulin variable-regions of both early, IgM and late, IgG anti-DNA antibodies from lupus-prone (NZB x NZW) F1 mice have indicated that both IgM and IgG anti-DNA autoantibodies are generated by clonally-selective B cell stimulation. Within individual autoimmune mice the later appearing, IgG anti-DNA autoantibodies are structurally similar to the earlier appearing, IgM antibodies, and in some cases both IgM and IgG may be produced by the same B cell clones. The variable-region structural data also suggest that DNA or complexes containing DNA may be the immunogenic stimuli for autoantibody to DNA. In support of this conclusion, normal mice immunized with immunogenic peptide-DNA complexes produce anti-DNA antibodies with structural and serological characteristics similar if not identical to those of autoimmune anti-DNA antibodies. Normal mice immunized with peptide-DNA complexes eventually develop immunopathology that resembles lupus nephritis. These results suggest that autoimmunity to DNA and subsequent autoimmune disease in SLE may result from a specific immune response to DNA containing antigens.

An epitope proximal to the carboxyl terminus of the alpha-subunit is located near the lobe tips of the phosphorylase kinase hexadecamer.

An epitope of the alpha-subunit of phosphorylase kinase from fast-twitch skeletal muscle was localized to the tips of the bilobal kinase molecule by two types of immunoelectron microscopy. This is the first direct evidence identifying the location of any of the enzyme's 16 subunits within the phosphorylase kinase molecule. Negatively stained complexes of phosphorylase kinase with an immunoglobulin G monoclonal antibody specific for the alpha-subunit (mAb 157) were observed by conventional transmission electron microscopy, and complexes of the unstained enzyme with undecagold-labeled Fab' fragments derived from mAb 157 were visualized by scanning transmission electron microscopy. Images from both techniques indicate a symmetrical arrangement of the epitope, consistent with a "head-to-head" packing arrangement of the four alpha-subunits. In Western blots, mAb 157 crossreacted with comigrating fragments obtained by digesting non-denatured phosphorylase kinase with a variety of proteases, suggesting that the epitope for the anti-alpha mAb is contained within a protease-resistant domain. Partial sequencing of a 24.1 kDa immunoreactive chymotryptic fragment narrowed the epitope to somewhere within the carboxyl-terminal one-sixth of the alpha-subunit. Studies of the crossreactivity of mAb 157 with the holoenzyme in the presence of calmodulin, after phosphorylation or with different isoforms (all with known alpha-subunit sequence targets or differences), suggest that the epitope is even more proximal to the carboxyl terminus. This epitope was not implicated in any known function or activity of the enzyme, suggesting that the region proximal to the carboxyl terminus of the alpha-subunit, and thus to the lobe tips of the hexadecamer, may have a role other than catalytic or regulatory.

Two FKBP-related proteins are associated with progesterone receptor complexes.

Unactivated steroid receptors are in heterooligomeric complexes that perhaps stabilize a partially folded receptor polypeptide prior to hormone-dependent activation. Hsp90 is a common receptor component and hsp70 is a component of progesterone receptors; both appear to be important as general mediators of protein folding and assembly events. In addition to hsp90, mammalian steroid receptor complexes contain a 52-59-kDa protein that is an FK506-binding immunophilin and has peptidyl-prolyl isomerase activity. Other receptor-associated proteins have been identified but not well-characterized. In the present study, we obtained partial amino acid sequences for two avian progesterone receptor components, p50 and p54. From sequence comparisons with known proteins, they appear to be distinct members of the FKBP family of immunophilins. Six p50 peptide sequences have 80% identity with regions of rabbit FKBP52; seven p54 peptide sequences have 60% identity with rabbit FKBP52. Interaction of p54 with receptor is distinct from p50 in that its binding in vitro is highly sensitive to progesterone or N-ethylmaleimide. An anti-p54 monoclonal antibody was developed that detects a 55-kDa protein in rabbit and human tissues; in a cell-free reconstitution system, the rabbit antigen binds to chicken progesterone receptor along with rFKBP52. While p50 appears to be the chicken homolog of FKBP52, p54 is perhaps a novel member of the FKBP family that, in addition to FKBP52, interacts with progesterone receptor.