Immune responses to small nuclear ribonucleoproteins: antigen-dependent distinct B cell epitope spreading patterns in mice immunized with recombinant polypeptides of small nuclear ribonucleoproteins

HLA-DR3 restricted environmental epitopes from the bacterium Clostridium tetani have T cell cross-reactivity to the SLE-related autoantigen SmD

HLA-DR3 (DR3) is one of the dominant HLA-DR alleles associated with systemic lupus erythematosus (SLE) susceptibility. Our previous studies showed multiple intramolecular DR3 restricted T cell epitopes in the Smith D (SmD) protein, from which we generated a non-homologous, bacterial epitope mimics library. From this library we identified ABC_247-261 Mimic as one new DR3 restricted bacterial T cell epitope from the ABC transporter ATP-binding protein in Clostridium tetani. It activated and induced autoreactive SmD_66-80-specific T cells and induced autoantibodies to lupus-related autoantigens in vivo. Compared to healthy donors, SLE patients have a greater percentage of cross-reactive T cells to ABC_247-261 Mimic and SmD_66-80. In addition, we analyzed the ability of single DR3 restricted Tetanus toxoid (TT) T cell epitopes to induce autoimmune T cells. We found that the immunodominant TT epitope TT_826-845 stimulated SmD_66-80 reactive T cells but failed to induce persistent anti-SmD autoantibodies compared to the ABC_247-261 Mimic. Thus, exposure to the ABC_247-261 Mimic epitope may contribute to autoimmunity in susceptible DR3 individuals.

"Ways in which the neonatal Fc-receptor is involved in autoimmunity"

Since the neonatal IgG Fc receptor (FcRn) was discovered, its role has evolved from immunoglobulin recycling and biodistribution to antigen presentation and immune complex routing, bringing it to the center of both humoral and cellular immune responses. FcRn is thus involved in the pathophysiology of immune-related diseases such as cancer, infection, and autoimmune disorders. This review focuses on the role of FcRn in autoimmunity, based on the available data from both animal models and human studies. The knowledge concerning ways in which FcRn is involved in autoimmune response has led to the development of inhibitors for the treatment of autoimmune diseases, also described here. Up to date, the literature remains scarce, shedding light on the need for further studies to fully understand the various pathophysiological roles of this unique receptor.

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FcRn is an intracellular receptor with a key role in IgG and immune complex management.

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FcRn-targeting therapies are a promising way of treatment in antibodies mediated diseases.

Haemoglobin drives inflammation and initiates antigen spread and nephritis in lupus

Haemoglobin (Hb) has well-documented inflammatory effects and is normally efficiently scavenged; clearance mechanisms can be overwhelmed during erythrocyte lysis. Whether Hb is preferentially inflammatory in lupus and triggers broad anti-self responses was assessed. Peripheral blood mononuclear cells (PBMCs) derived from SLE patients secreted higher levels of lupus-associated inflammatory cytokines when incubated with human Hb than did PBMCs derived from healthy donors, an effect negated by haptoglobin. Ferric murine Hb triggered the preferential release of lupus-associated cytokines from splenocytes, B cells, CD4 T cells, CD8 T cells and plasmacytoid dendritic cells isolated from ageing, lupus-prone NZM2410 mice, and also had mitogenic effects on B cells. Pull-downs, followed by mass spectrometry, revealed interactions of Hb with several lupus-associated autoantigens; co-incubation of ferric Hb with apoptotic blebs (structures that contain packaged autoantigens) revealed synergies-in terms of cytokine release and autoantibody production in vitro-that were also restricted to the lupus genotype. Murine ferric Hb activated multiple signalling pathways and, in combination with apoptotic blebs, preferentially triggered MAP kinase signalling specifically in splenocytes isolated from lupus-prone mice. Infusion of murine ferric Hb into lupus-prone mice led to enhanced release of lupus-associated cytokines, the generation of a spectrum of autoantibodies and enhanced-onset glomerulosclerosis. Given that the biased recognition of ferric Hb in a lupus milieu, possibly in concert with lupus-associated autoantigens, triggers inflammatory responses and the generation of lupus-associated cytokines, and also stimulates the generation of potentially pathogenic lupus-associated autoantibodies, neutralization of Hb could have beneficial effects.

Anti-complement factor H autoantibodies may be protective in lupus nephritis

BACKGROUND

This study aimed to investigate the role of anti-CFH autoantibodies in lupus nephritis based on a well-defined cohort.

METHODS

One hundred twenty patients with biopsy-proven active lupus nephritis were collected as the discovery cohort, sixty patients served as the validation cohort, thirty-four patients with SLE without renal involvement (NR-SLE) were as disease controls, and thirty healthy donors were also included. The anti-CFH autoantibodies and IgG subclasses were detected by ELISA, and epitopes were evaluated by western blot. Anti-CFH autoantibodies were purified by affinity chromatography column, and the interference on the biofunctions of CFH was further studied by the C3b binding assay and cofactor activity assay in vitro.

RESULTS

The prevalence of anti-CFH autoantibodies in lupus nephritis was significantly higher than that in healthy controls (8.3% (10/120) vs. 0% (0/30), P = 0.017), and no significant difference was found between the discovery and the validation group (8.3% (10/120) vs. 11.7% (7/60), P = 0.268) or the discovery and the NR-SLE group (8.3% (10/120) vs. 11.8% (4/34), P = 0.231). The subclass was mainly IgG2 (7/10), and major epitopes were in the middle (8/10 in SCRs 11-14) and N-terminal (7/10 in SCRs 1-4) regions of CFH. Patients with anti-CFH autoantibodies had a significantly lower prevalence of acute kidney injury (0% (0/10) vs. 40.0%(4/10), P = 0.025), lower serum creatinine levels (0.76 (0.40, 1.06) vs. 1.43 (0.46, 11.15), mg/dL, P = 0.023), and higher hemoglobin levels (113.8 ± 24.63 vs. 90.0 ± 22.53, g/L, P = 0.037) than those who were negative after further stratified analysis. A functional study showed that anti-CFH autoantibodies purified from patients with lupus nephritis could improve the binding between CFH and C3b, and also enhance the cofactor activity of CFH in vitro.

CONCLUSIONS

Anti-CFH autoantibodies were detected in patients with lupus nephritis in approximately 10% of patients with polyepitopes and IgG2 subclass predominance. Patients with anti-CFH autoantibodies presented with milder renal damage, and the purified autoantibodies could enhance the C3b binding and CFI cofactor activity of CFH in vitro, which suggested a protective role in the lupus nephritis.

Immunology of membranous nephropathy

Accounting for about 20 to 50% of cases of primary nephrotic syndrome, membranous nephropathy (MN) is the leading cause of nephrotic syndrome in adults. A rat model created nearly 60 years ago to research the primary MN disorder, Heymann nephritis, has provided us with a plethora of important information. Recently, our knowledge about MN has dramatically progressed. Heymann nephritis and human MN are now known to share a high degree of similarity in pathogenesis. This review summarizes our current understanding of MN pathogenesis while focusing particularly on the immunological aspects.

Innate and humoral recognition of the products of cell death: differential antigenicity and immunogenicity in lupus

While apoptotic debris is believed to constitute the original antigenic insult in lupus (which is characterized by a time-dependent diversification of autoreactivity), whether such debris and autoantibodies specifically recognizing its constituents mediate differential effects on innate and humoral responses in lupus-prone mice is currently unknown. Apoptotic blebs (as opposed to cellular lysate) enhanced preferentially the maturation of dendritic cells (DCs) from bone marrow precursors drawn from lupus-prone mice. Murine, somatically mutated, apoptotic cell-reactive immunoglobulin (Ig)G monoclonal antibodies demonstrated enhanced recognition of DCs and also displayed a prominent lupus strain-specific bias in mediating DC maturation. Further, immunization of such antibodies specifically in lupus-prone mice resulted in widespread humoral autoreactivity; hypergammaglobulinaemia (a hallmark of systemic autoimmunity) was observed, accompanied by enhanced antibody titres to cellular moieties. Induced antibodies recognized antigens distinct from those recognized by the antibodies employed for immunization; in particular, nephritis-associated anti-double stranded (ds) DNA antibodies and neonatal lupus-associated anti-Ro60 antibodies were elicited by a non-dsDNA, non-Ro60 reactive antibody, and Sm was a favoured target. Further, only in lupus-prone mice did such immunization enhance the kinetics of humoral anti-self responses, resulting in the advanced onset of glomerulosclerosis. These studies reveal that preferential innate and humoral recognition of the products of cell death in a lupus milieu influence the indices associated with autoimmune pathology.

B cell epitope spreading: mechanisms and contribution to autoimmune diseases

While a variety of factors act to trigger or initiate autoimmune diseases, the process of epitope spreading is an important contributor in their development. Epitope spreading is a diversification of the epitopes recognized by the immune system. This process happens to both T and B cells, with this review focusing on B cells. Such spreading can progress among multiple epitopes on a single antigen, or from one antigenic molecule to another. Systemic lupus erythematosus, multiple sclerosis, pemphigus, bullous pemphigoid and other autoimmune diseases, are all influenced by intermolecular and intramolecular B cell epitope spreading. Endocytic processing, antigen presentation, and somatic hypermutation act as molecular mechanisms that assist in driving epitope spreading and broadening the immune response in autoimmune diseases. The purpose of this review is to summarize our current understanding of B cell epitope spreading with regard to autoimmunity, how it contributes during the progression of various autoimmune diseases, and treatment options available.

Fragment of tegument protein pp65 of human cytomegalovirus induces autoantibodies in BALB/c mice

Introduction

Human cytomegalovirus (HCMV) infection has been implicated in the development of autoimmunity, including systemic lupus erythematosus (SLE). Previously we reported that HCMV phosphoprotein 65 (pp65) could induce early onset of autoantibody and glomerulonephritis on lupus-prone NZB/W mice. This study further examined whether the B cell epitope(s) in pp65 is able to drive the development of autoantibody.

Methods

Sera from SLE patients or HCMVpp65-immunized mice were analyzed for anti-nuclear antibody by immunoblotting, enzyme-linked immunosorbent assay (ELISA), immunofluorescent stain and Crithidia luciliae stain. The deposition of immunoglobulin to the kidney was also examined by immunofluorescent stain. The interactions between pp65 sub-fragment to cellular proteins were revealed by yeast two-hybrid analyses.

Results

Our results showed that most SLE patients possessed antibodies to the C-terminal half of the HCMVpp65 antigen. Of these positive sera, 73% were also positive to the pp65_336-439 sub-fragment. The immunization of pp65_336-439 induced formation of multiple anti-nuclear antibodies, including anti-chromatin, anti-centriole, anti-mitotic spindle type I/II (MSA I/II) and a significant elevation of anti-double-stranded DNA (anti-dsDNA) antibodies on BALB/c mice. Yeast two-hybrid analyses revealed the binding of pp65_336-439 sub-fragment to cellular proteins. Immunoglobulin deposition on glomeruli was also detected on pp65_336-439-immunized mice.

Conclusions

Our data suggested that HCMVpp65_336-439 sub-fragment may induce cross-reactive antibodies to several nuclear antigens, which could contribute to the development of autoimmunity in genetic-suspected individuals.

Pathogenesis of systemic lupus erythematosus revisited 2011: end organ resistance to damage, autoantibody initiation and diversification, and HLA-DR

Systemic lupus erythematosus (SLE) is a multi-system disorder resulting from interaction of susceptibility genes and environmental factors. SLE has protean clinical presentations at the initial diagnosis and relapses. SLE-related autoantibodies have unique patterns of diversification to linked proteins such as the snRNP particle and the diversification takes years before clinical diagnosis. There are both clinical and experimental evidence to indicate that separate genes contribute to autoimmunity and end organ damage and these genes are independent and interactive. Among the numerous susceptibility genes, HLA-D complex is dominant. Results from the authors' laboratories led us to postulate a unified hypothesis for SLE pathogenesis. This hypothesis states that SLE-autoantibodies are initiated by environmental T cell epitope mimics of the SLE-related autoantigens in hosts with susceptible HLA-D alleles. These autoantibodies diversify over a period of years due the accumulation of cross-reactive T cells. This process ultimately leads to the generation of organ specific autoantibodies and autoreactive effector T cells due to the polyreactive nature of T and B cell receptors from hosts with susceptibility genes to end organ damage, resulting in protean clinical presentations. This hypothesis accounts for most of the features unique to SLE and has clinical implications as to how patients should be treated.

HLA-DR3 restricted T cell epitope mimicry in induction of autoimmune response to lupus-associated antigen SmD

Although systemic lupus erythematosus (SLE) is a multigenic autoimmune disorder, HLA-D is the most dominant genetic susceptibility locus. This study was undertaken to investigate the hypothesis that microbial peptides bind HLA-DR3 and activate T cells reactive with lupus autoantigens. Using HLA-DR3 transgenic mice and lupus-associated autoantigen SmD protein, SmD(79-93) was identified to contain a dominant HLA-DR3 restricted T cell epitope. This T cell epitope was characterized by using a T-T hybridoma, C1P2, generated from SmD immunized HLA-DR3 transgenic mouse. By pattern search analysis, 20 putative mimicry peptides (P2-P21) of SmD(79-93,) from microbial and human origin were identified. C1P2 cells responded to SmD, SmD(79-93) and a peptide (P20) from Vibro cholerae. Immunization of HLA-DR3 mice with P20 induced T cell responses and IgG antibodies to SmD that were not cross-reactive with the immunogen. A T-T hybridoma, P20P1, generated from P20 immunized mice, not only responded to P20 and SmD(79-93), but also to peptides from Streptococcus agalactiae (P17) and human-La related protein (P11). These three T cell mimics (P20, P11 and P17) induced diverse and different autoantibody response profiles. Our data demonstrates for the first time molecular mimicry at T cell epitope level between lupus-associated autoantigen SmD and microbial peptides. Considering that distinct autoreactive T cell clones were activated by different microbial peptides, molecular mimicry at T cell epitope level can be an important pathway for the activation of autoreactive T cells resulting in the production of autoantibodies. In addition, the novel findings reported herein may have significant implications in the pathogenesis of SLE.

Alloantibodies prevent the induction of transplantation tolerance by enhancing alloreactive T cell priming

Circulating alloantibodies in transplant recipients are often associated with increased Ab-mediated as well as cellular rejection. We tested the hypothesis that alloantibodies facilitate cellular rejection by functioning as opsonins to enhance T cell activation using a BALB/c to C57BL/6 heart or skin transplant model. Long-term heart and skin survival induced with anti-CD154 alone or in combination with donor-specific transfusion (DST), respectively, was abrogated by the presence of anti-K(d) mAbs, and alloreactive T cell activation as well as acute rejection was observed. The prevention of graft acceptance in the skin model was dependent on anti-K(d) binding to and converting DST from tolerigenic to immunogenic. Adoptive transfer of CFSE-labeled TCR-transgenic T cells into B6 recipients treated with anti-CD154/DST revealed the ability of anti-K(d) to enhance the proliferation of anti-K(d)-specific T cells via the indirect pathway as well as of non-K(d)-reactive, recipient MHC-restricted CD4(+) and CD8(+) T cells. Thus, alloantibodies with restricted specificity are able to facilitate the indirect presentation as well as the cross-presentation of a larger repertoire of "linked" donor-derived Ags. These observations highlight the ability of alloantibodies to function not only in classical humoral rejection but also as opsonins that facilitate the CD40-CD154-independent activation of alloreactive T cells.

The U1-snRNP complex: structural properties relating to autoimmune pathogenesis in rheumatic diseases

The U1 small nuclear ribonucleoprotein particle (snRNP) is a target of autoreactive B cells and T cells in several rheumatic diseases including systemic lupus erythematosus (SLE) and mixed connective tissue disease (MCTD). We propose that inherent structural properties of this autoantigen complex, including common RNA-binding motifs, B and T-cell epitopes, and a unique stimulatory RNA molecule, underlie its susceptibility as a target of the autoimmune response. Immune mechanisms that may contribute to overall U1-snRNP immunogenicity include epitope spreading through B and T-cell interactions, apoptosis-induced modifications, and toll-like receptor (TLR) activation through stimulation by U1-snRNA. We conclude that understanding the interactions between U1-snRNP and the immune system will provide insights into why certain patients develop anti-U1-snRNP autoimmunity, and more importantly how to effectively target therapies against this autoimmune response.

Differential responses to Smith D autoantigen by mice with HLA-DR and HLA-DQ transgenes: dominant responses by HLA-DR3 transgenic mice with diversification of autoantibodies to small nuclear ribonucleoprotein, double-stranded DNA, and nuclear antigens

Anti-Smith (Sm) D autoantibodies are specific for systemic lupus erythematosus. In this investigation, the influence of HLA-D genes on immune responses to SmD was investigated. Mice with HLA-DR3, HLA-DR4, HLA-DQ0601, HLA-DQ0604, or HLA-DQ8 transgenes were immunized with recombinant SmD1, and their Ab responses were analyzed. Analysis by ELISA showed that all strains responded well to SmD. However, when synthetic SmD peptides were used as substrate, DR3 mice had the highest Ab response followed by DQ8, DQ0604, DQ0601, and DR4. A similar trend was observed in Western blot analysis using WEHI 7.1 cell lysate as the substrate, with the exception that DR4 mice did not generate detectable amounts of Abs. Only sera from DR3 and DQ0604 mice immunoprecipitated A-ribonucleoprotein (RNP), SmB, and SmD. Intermolecular epitope spreading to A-RNP and SmB was evident in DR3 and DQ0604 mice, as sera depleted of anti-SmD Abs were reactive with these proteins. DR3 mice also generated an immune response to C-RNP. Anti-nuclear Abs were detected in the majority of the DR3 mice, whereas moderate reactivities were seen in DQ0604 and DQ8 mice. Interestingly, only DR3 mice mounted an anti-dsDNA Ab response. Approximately half of the anti-dsDNA Abs were cross-reactive with SmD. Ab responses correlated with the strength of the T cell responses. Thus, HLA-DR3 appears to be the dominant HLA-D gene that determines the magnitude and quality of the anti-SmD immune response. In addition, our findings provide insights into the origin of the anti-dsDNA Abs often detected in patients with systemic lupus erythematosus.

Germinal center reutilization by newly activated B cells

Germinal centers (GCs) are specialized structures in which B lymphocytes undergo clonal expansion, class switch recombination, somatic hypermutation, and affinity maturation. Although these structures were previously thought to contain a limited number of isolated B cell clones, recent in vivo imaging studies revealed that they are in fact dynamic and appear to be open to their environment. We demonstrate that B cells can colonize heterologous GCs. Invasion of primary GCs after subsequent immunization is most efficient when T cell help is shared by the two immune responses; however, it also occurs when the immune responses are entirely unrelated. We conclude that GCs are dynamic anatomical structures that can be reutilized by newly activated B cells during immune responses.

Early targets of nuclear RNP humoral autoimmunity in human systemic lupus erythematosus

OBJECTIVE

The U1 small nuclear RNPs are common targets of autoantibodies in lupus and other autoimmune diseases. However, the etiology and progression of autoimmune responses directed against these antigens are not well understood. The aim of this study was to use a unique collection of serial samples obtained from patients before and after the development of nuclear RNP (nRNP) antibodies to investigate early humoral events in the development of anti-nRNP autoimmunity.

METHODS

Lupus patients with sera available from both before and after the development of nRNP antibody precipitin were identified from the Oklahoma Clinical Immunology Serum Repository. Antibodies in the serial samples were analyzed by enzyme-linked immunosorbent assay, Western blotting, solid-phase epitope mapping, and competition assays.

RESULTS

The first-detected nRNP antibodies targeted 6 common initial epitopes in nRNP A, 2 in nRNP C, and 9 in nRNP 70K. The initial epitopes of nRNP A and nRNP C were significantly enriched for proline and shared up to 95% sequence homology. The initial nRNP 70K humoral epitopes differed from those of nRNP A and nRNP C. The initial antibodies to nRNP A and nRNP C were cross-reactive with the SmB'-derived peptide PPPGMRPP. Antibody binding against all 3 nRNP subunits diversified significantly over time.

CONCLUSION

Autoantibodies to nRNP A and nRNP C initially targeted restricted, proline-rich motifs. Antibody binding subsequently spread to other epitopes. The similarity and cross-reactivity between the initial targets of nRNP and Sm autoantibodies identifies a likely commonality in cause and a focal point for intermolecular epitope spreading.

Lupus-like autoantibody development in rabbits and mice after immunization with EBNA-1 fragments

Epstein-Barr virus has been implicated in the etiology of systemic lupus erythematosus (SLE) through serologic and immunologic studies. A potential mechanism for this influence is through molecular mimicry. The EBV nuclear antigen EBNA-1 contains a region, PPPGRRP, with considerable homology to the initial sequence targeted by antibodies in Sm B' autoimmunity, PPPGMRPP. This study examined whether immunization of rabbits and mice with peptides containing the PPPGRRP sequence from EBNA-1 constructed on a poly-lysine backbone was able to drive the development of autoantibodies against the Smith antigen (Sm) and the related antigenic complex, the U1 nuclear ribonucleoproteins (nRNPs). PPPGRRP immunization, and immunization with an EBNA-1 fragment containing PPPGRRP, led to autoantibodies in both rabbits and mice at high frequency (83% of rabbits and 43% of mice). Five out of six immunized rabbits developed either leucopenia or lymphopenia or both. The fine specificity of antibody binding against the lupus-associated autoantigens Sm B', nRNP A, and nRNP C after immunization with the EBNA-1-derived peptides was very similar to the early antibody binding patterns against these proteins in human SLE. This similarity, as well as the prevalence of autoimmunity after immunization with these peptides, identifies PPPGRRP as a strong candidate for molecular mimicry in SLE etiology.

Intramolecular epitope spreading in Heymann nephritis

Immunization with megalin induces active Heymann nephritis, which reproduces features of human idiopathic membranous glomerulonephritis. Megalin is a complex immunological target with four discrete ligand-binding domains (LBDs) that may contain epitopes to which pathogenic autoantibodies are directed. Recently, a 236-residue N-terminal fragment, termed "L6," that spans the first LBD was shown to induce autoantibodies and severe disease. We used this model to examine epitope-specific contributions to pathogenesis. Sera obtained from rats 4 weeks after immunization with L6 demonstrated reactivity only with the L6 fragment on Western blot, whereas sera obtained after 8 weeks demonstrated reactivity with all four recombinant fragments of interest (L6 and LBDs II, III, and IV). We demonstrated that the L6 immunogen does not contain the epitopes responsible for the reactivity to the LBD fragments. Therefore, the appearance of antibodies directed at LBD fragments several weeks after the primary immune response suggests intramolecular epitope spreading. In vivo, we observed a temporal association between increased proteinuria and the appearance of antibodies to LBD fragments. These data implicate B cell epitope spreading in antibody-mediated pathogenesis of active Heymann nephritis, a model that should prove valuable for further study of autoimmune dysregulation.

A SmD Peptide Induces Better Antibody Responses to Other Proteins within the Small Nuclear Ribonucleoprotein Complex than to SmD Protein via Intermolecular Epitope Spreading

Autoantibody response against the small nuclear ribonucleoprotein (snRNP) complex is a characteristic feature of systemic lupus erythematosus. The current investigation was undertaken to determine whether activation of SmD-reactive T cells by synthetic peptides harboring T cell epitopes can initiate a B cell epitope spreading cascade within the snRNP complex. T cell epitopes on SmD were mapped in A/J mice and were localized to three regions on SmD, within aa 26-55, 52-69, and 86-115. Immunization with synthetic peptides SmD(31-45), SmD(52-66), and SmD(91-110) induced T and B cell responses to the peptides, with SmD(31-45) inducing the strongest response. However, only SmD(52-66) immunization induced T cells capable of reacting with SmD. Analysis of sera by immunoprecipitation assays showed that intermolecular B cell epitope spreading to U1RNA-associated A ribonucleoprotein and SmB was consistently observed only in the SmD(52-66)-immunized mice. Surprisingly, in these mice, Ab responses to SmD were at low levels and transient. In addition, the sera did not react with other regions on SmD, indicating a lack of intramolecular B cell epitope spreading within SmD. Our study demonstrates that T cell responses to dominant epitope on a protein within a multiantigenic complex are capable of inducing B cell responses to other proteins within the complex. This effect can happen without generating a good Ab response to the protein from which the T epitope was derived. Thus caution must be taken in the identification of Ags responsible for initiating autoimmune responses based solely on serological analysis of patients and animals with systemic autoimmune disorders.

Antibody responses to mycobacterial and self heat shock protein 65 in autoimmune arthritis: epitope specificity and implication in pathogenesis

Many autoimmune diseases are believed to involve primarily T cell-mediated effector mechanisms. There is increasing realization, however, that Abs may also play a vital role in the propagation of T cell-driven disorders. In this study, on the rat adjuvant-induced arthritis (AA) model of human rheumatoid arthritis, we examined the characteristics of serum Ab response to mycobacterial heat shock protein (hsp) 65 (Bhsp65), self (rat) hsp65 (Rhsp65), and linear peptides spanning these two molecules. The AA-resistant WKY (RT.1(l)) rat responded to the heat-killed Mycobacterium tuberculosis immunization with a rapid burst of Abs to both Bhsp65 and Rhsp65. These Abs reacted with numerous peptide epitopes; however, this response was reduced to a few epitopes with time. On the contrary, the susceptible Lewis (RT.1(l)) rat developed a relatively lower Ab response to Bhsp65, and Abs to Rhsp65 did not appear until the recovery from the disease. The Ab response in Lewis rats diversified with progression of AA, and there was an intriguing overlap between the repertoire of Bhsp65-reactive B and T cells during the recovery phase of AA. Nonetheless, subsets of the repertoire of the late Abs in both rat strains became focused on the same epitope regions of Bhsp65 and Rhsp65. The functional relevance of these Abs was evident from the results showing that sera from recovery phase Lewis or WKY rats, but not that of naive rats, afforded protection against subsequent AA. These results are of significance in further understanding of the role of humoral immunity in the pathogenesis of autoimmune arthritis.

Autoimmunity: basic mechanisms and implications in endocrine diseases. Part I

Autoimmunity implies disturbances at several levels of the immune control. Self-tolerance and discrimination between self and non-self synergize to avoid the development of autoimmunity. Negative selection in the thymus, the transcription factor AIRE, CD4+CD25+ regulatory T cells, and dendritic cells cooperate to produce and maintain tolerance. Cytokines modulate deriving immune processes and influence the local micro-environment. Multiple mechanisms are involved in tolerance breakdown: genetic factors (major histocompatibility complex haplotypes, polymorphisms in the cytotoxic T lymphocyte antigen gene and epigenetic alterations), environmental factors (mainly infections), impaired apoptosis, and the emergence of autoreactive naive lymphocytes. These events may be involved in the pathogenesis of endocrine diseases at several levels.

Heterogeneous nuclear ribonucleoprotein P2 is an autoantibody target in mice deficient for Mer, Axl, and Tyro3 receptor tyrosine kinases

Deficiencies in clearance of apoptotic cells predispose to the development of autoimmune disease. This is evident in mice lacking the receptor tyrosine kinases Tyro3, Axl, and Mer. Deficient mice exhibit an increased abundance of apoptotic cells in tissues and manifest diverse autoimmune conditions. To test these mice for the presence of autoantibodies to apoptotic cells, we generated spontaneous splenic B cell hybridomas and used a novel microscopy screen to detect Ab binding to apoptotic Jurkat cells. From hybridomas secreting IgG Abs reactive with apoptotic cells, we selected one that recreated the major serum specificity for apoptotic cells. The Ab LHC7.15 bound to an Ag that is differentially distributed between the nucleus and the cytoplasm in live and apoptotic cells. In late apoptotic cells, the Ag coalesces into aggregates that bleb from the cell surface. Immunopurification of the Ag, followed by mass spectrometry, identified a protein of 69 kDa whose partial sequence matched heterogeneous nuclear ribonucleoprotein P2. This multifunctional protein binds DNA, RNA, and several known ribonucleoprotein autoantigens. Our observations indicate that a ribonucleoprotein complex, formed and translocated to the cell surface in apoptosis, represents a potent stimulus for breaking tolerance and inducing systemic autoimmunity in mice with defective clearance of cell remnants.

Evidence for multiple shared antigenic determinants within Ro60 and other lupus-related ribonucleoprotein autoantigens in human autoimmune responses

Ab responses directed against several ribonucleoprotein (RNP) Ags are a characteristic feature of systemic lupus erythematosus (SLE). Previous work in our laboratory using mouse model systems had revealed that both epitope spreading and inherent cross-reactivity between ribonucleoproteins contributes to the observed multiple specificities in autoimmune sera. We have now extended these studies to human autoimmune responses. Using purified polyclonal and mAbs derived from SLE patients, cross-reactivity between Ro60 and SmD was demonstrated. The cross-reactive epitope was mapped to nonhomologous regions on Ro60(481-505) and SmD(88-102). Five mAbs specifically recognized apoptotic cells, demonstrated variable levels of cross-reactivity toward other nonhomologous ribonucleoprotein targets and bound multiple, nonoverlapping and nonhomologous epitopes on Ro60. Our study demonstrates that cross-reactivity between frequently targeted autoantigens is an important aspect of human systemic autoimmune responses. The presence of multiple cross-reactive epitopes on Ro60 might be important for the generation of anti-Ro60 Ab in SLE patients and in normal individuals displaying no evidence of clinical disease.

Role of anti-DNA antibodies in the pathogenesis of lupus nephritis

Despite a good association between anti-DNA autoantibodies and lupus nephritis, it is difficult to determine the pathogenic potential of an anti-DNA autoantibody response. It is proposed that anti-DNA antibodies can exert their pathogenic effects through deposition as immune complexes in the kidney or through the recognition of cross-reactive antigens in the kidneys. Several studies in literature demonstrate that cross-reactivity of anti-DNA antibodies with kidney antigens is critical for their pathogenic potential. This raises the question whether DNA is responsible for the activation and selection of B cells generating cross-reactive anti-DNA antibodies. Recent studies suggest that antigens other than DNA can initiate an antibody response that is cross-reactive with dsDNA. Moreover, we and other have demonstrated that lupus nephritis can occur in the absence of anti-DNA antibodies. Thus, reactivity to dsDNA should be considered as one of the characteristic of polyreactive autoantibodies and not a primary requisite for the pathogenesis of lupus nephritis.

New insights from murine lupus: disassociation of autoimmunity and end organ damage and the role of T cells

PURPOSE OF REVIEW

This review summarizes current literature on genetic regulation of different phenotypes in systemic lupus erythematosus in context of end-organ disease. Recent findings conflicting with the current paradigm that loss of tolerance to chromatin is the critical step for end-organ injury are discussed.

RECENT FINDINGS

Systemic lupus erythematosus is a prototype immune complex disease with circulating autoantibodies to chromatin, histone proteins, Sm/La, and other nuclear and cytoplasmic proteins. Extensive studies have been carried out on the regulation of B-cell and autoantibody production in lupus mice. However, the hypothesis that autoantibodies are primary mediators of organ damage fails to explain the heterogenous presentation in patients. Studies in murine models of systemic lupus erythematosus clearly dissociate genetic control of autoantibody responses to classic lupus antigens and kidney disease. There is increasing evidence to support the role of autoreactive T cells and genetic control of end organ susceptibility. These studies suggest complex interactions between innate and adaptive immunity resulting in end-organ damage. This review focuses on autoimmune responses and renal involvement in spontaneous systemic lupus erythematosus using murine models of lupus nephritis.

SUMMARY

Studies in murine models demonstrate complex genetic interactions regulating spontaneous systemic lupus erythematosus. Although detection of serum autoantibodies is considered a hallmark for clinical diagnosis of systemic lupus erythematosus, recent evidence shows that autoantibodies to classic lupus antigens are neither required nor sufficient for end-organ damage. Thus, murine models provide new insights into the pathogenesis of systemic lupus erythematosus.

Epitope spreading within lupus-associated ribonucleoprotein antigens

Autoantibodies reactive with several cellular antigens are present in the sera of patients with systemic lupus erythematosus. Polypeptides within the Ro-RNP complex and the snRNP complex are often targeted by these autoantibodies. One of the mechanisms responsible for their evolution is that of epitope spreading. Experimental animal model systems provide evidence for this. This review discusses the animal model systems of epitope spreading within these ribonucleoprotein antigens, the mechanisms of epitope spreading, and its relevance for disease pathogenesis.

Intramolecular T cell spreading in unprimed MRL/lpr mice: importance of the U1-70k protein sequence 131-151

OBJECTIVE

To analyze spontaneous T cell spreading against determinants of the U1-70K protein in young autoimmune MRL/lpr lupus mice, in comparison with the T cell spreading occurring in normal BALB/c mice immunized with peptide 131-151 of this protein.

METHODS

Peripheral blood lymphocytes (PBLs) from both unprimed MRL/lpr mice and immunized BALB/c mice were tested for their ability to proliferate ex vivo in response to 18 overlapping peptides of the U1-70K spliceosomal protein, using assays for lymphocyte proliferation and secretion of interleukin-2.

RESULTS

The proliferative response to peptides of the U1-70K protein evolved rapidly in MRL/lpr mice tested at different ages. At least 5 peptides were recognized by PBLs from 8-week-old autoimmune mice, whereas a different peptide was recognized by PBLs from MRL/lpr mice at 12 weeks of age. At 15 weeks, the proliferative response was weak or negative when assessed with any of the test peptides. At least 2 major peptides recognized by MRL/lpr PBLs were also recognized by PBLs generated in the BALB/c mice primed with peptide 131-151. We further demonstrated that, in preautoimmune MRL/lpr mice, repeated administration of phosphorylated peptide 131-151 (called P140), which was shown previously to be protective, transiently abolished T cell intramolecular spreading to other regions of the 70K protein.

CONCLUSION

This is the first study to demonstrate that intramolecular T cell spreading effectively occurs in MRL/lpr mice with lupus, and that region 131-151 is important in the cascade of events observed in the murine lupus response. This sequence might originate a mechanism of tolerance spreading that leads to the beneficial effect observed in MRL/lpr mice after treatment with the phosphorylated peptide 131-151.

Novel Negative Regulator of Expression in Fas Ligand (CD178) Cytoplasmic Tail: Evidence for Translational Regulation and against Fas Ligand Retention in Secretory Lysosomes

Fas ligand ((FasL) CD178), a type II transmembrane protein, induces apoptosis of cells expressing the Fas receptor. It possesses a unique cytoplasmic tail (FasLCyt) of 80 aa. As a type II transmembrane protein, the early synthesis of FasLCyt could affect FasL translation by impacting FasL endoplasmic reticulum translocation and/or endoplasmic reticulum retention. Previous studies suggest that the proline-rich domain (aa 43-70) in FasLCyt (FasLPRD) inhibits FasL membrane expression by retaining FasL in the secretory lysosomes. This report shows that deletion of aa 2-33 of FasLCyt dramatically increased total FasL levels and FasL cell surface expression. This negative regulator of FasL expression is dominant despite the presence of FasLPRD. In addition, retention of proline-rich domain-containing FasL in the cytoplasm was not observed. Moreover, we demonstrated that FasLCyt regulates FasL expression by controlling the rate of de novo synthesis of FasL. Our study demonstrated a novel negative regulator of FasL expression in the FasLCyt region and its mechanism of action.

Human T cell clones specific for heterogeneous nuclear ribonucleoprotein A2 autoantigen from connective tissue disease patients assist in autoantibody production

OBJECTIVE

To identify and characterize human T cells reactive with heterogeneous nuclear RNP A2 (hnRNP A2) antigen, and to determine the ability of hnRNP-reactive T cells to assist in the production of human autoantibodies.

METHODS

T cells from patients with high serum levels of anti-hnRNP IgG autoantibody were stimulated with an hnRNP recombinant fusion protein, and the cells were cloned by limiting dilution. The surface phenotype and cytokine profiles of the T cells were examined by flow cytometry and enzyme-linked immunosorbent assay (ELISA), respectively. T cell clones were cultured with highly purified autologous B cells, and the ability of T cells to enhance autoantibody production under a variety of conditions was measured by ELISA.

RESULTS

Human T cells reactive with hnRNP antigen were cloned from 2 patients with systemic lupus erythematosus (SLE) and 1 patient with mixed connective tissue disease (MCTD). The T cells were CD4+ and had a Th1-like functional phenotype. In coculture in vitro with autologous B cells, T cell clones augmented anti-hnRNP autoantibody production and did so without the need for direct T cell-B cell contact.

CONCLUSION

This study provides direct evidence for a role of anti-hnRNP-reactive T cells in autoantibody production in SLE and MCTD. These findings support the notion that hnRNP-reactive T cells play a role in the pathogenesis of these diseases.

Lupus Glomerulonephritis Revisited 2004: Autoimmunity and End-Organ Damage

Histopathology of the kidney and clinical presentation are critical factors in the diagnosis of immune-mediated glomerulonephritis (GN). The histological manifestations of glomerular injury are shared by multiple underlying mechanisms. Work from our laboratory and from other investigators shows that antinuclear, antihistone or anti-dsDNA antibodies are neither required nor sufficient for development of lupus GN. In addition, antibody to dsDNA can be generated by mechanisms other than loss of tolerance to chromatin. Genetic analyses demonstrate that although there is some interaction between autoantibody production and renal disease, the phenotypes are regulated by distinct genetic intervals. Furthermore, renal failure is not an essential outcome of the immune-complex deposition and proliferative lupus GN. These data are also supported by published studies from systemic lupus erythematosus (SLE) patients. The immune regulation of lupus GN is distinct from other organ-specific diseases and not influenced by CD25(+) or NK1.1(+) regulatory T cells. Thus, fatal GN may depend upon a kidney-reactive T-cell response that, in turn, may be regulated by gender and intrinsic end-organ factors. The data discussed in this review call for a re-evaluation of the current paradigms for pathogenesis of SLE. An interactive model separating autoimmunity from end-organ susceptibility for the pathogenesis of SLE is proposed.

Cloned human TCR from patients with autoimmune disease can respond to two structurally distinct autoantigens

There is increasing evidence that the TCR can have significant plasticity in the range of Ags that a single receptor can recognize. Although it has been proposed that such TCR plasticity might contribute to autoimmunity, there have been few studies examining this possibility in either animal models or human disease. In the present study, we examined human T cell clones that were generated against two structurally dissimilar proteins, U1-70 kDa and Smith-B, that are physically associated in the U1-small nuclear ribonucleoprotein complex and that are frequent targets of autoantibodies and T cells in the same lupus patient. We found that the TCR from all clones isolated had substantial sequence homology within their complementarity-determining region 3. We molecularly cloned and expressed individual TCR/A and TCR/B genes in a TCR-negative human cell line J.RT3-T3.5. We then examined the interaction between the TCR and U1-70 kDa and Smith-B antigenic peptides. We found that there was plasticity or degeneracy of the TCR reactive with these lupus autoantigens in that two structurally dissimilar lupus autoantigenic peptides could stimulate a single TCR. These studies support an important role of plasticity of the TCR in the development of human autoimmunity.

A Self T Cell Epitope Induces Autoantibody Response: Mechanism for Production of Antibodies to Diverse Glomerular Basement Membrane Antigens

The anti-glomerular basement membrane (GBM) Ab has been regarded as a prototypical example of pathogenic autoantibodies. However, the mechanism for elicitation of this Ab remains unknown. In the present paper, we report that the Ab to diverse GBM Ags was induced by a single nephritogenic T cell epitope in a rat model. The T cell epitope pCol(28-40) of noncollagen domain 1 of collagen type IV alpha3 chain not only uniformly induced severe glomerulonephritis but also elicited anti-GBM Ab in 76% of the immunized rats after prominent glomerular injury. Furthermore, we demonstrated that the anti-GBM Ab was not related to the peptidic B cell epitope nested in pCol(28-40); that is, 1) elimination of the B cell epitope, either by substitution of the critical residues of the B cell epitope or by truncation, failed to abrogate anti-GBM Ab production, and 2) the anti-GBM Ab, eluted from the diseased kidneys, reacted only with native GBM, but not with pCol(28-40). Confocal microscopy and immunoprecipitation further demonstrated that the eluted anti-GBM Ab recognized conformational B cell epitope(s) of multiple native GBM proteins. We conclude that autoantibody response to diverse native GBM Ags was induced by a single nephritogenic T cell epitope. Thus, anti-GBM Ab may actually be a consequence of T cell-mediated glomerulonephritis.

Autoantibodies and glomerulonephritis in systemic lupus erythematosus

Autoantibody diversification to a variety of autoantigens is a hallmark for systemic autoimmunity. SLE represents a prototype. In this article the roots of the important questions probed by the Kunkel laboratory in SLE research are traced. Data from the recent animal work by the laboratory of Shu Man Fu are summarized to emphasize the importance of further exploration of autoantibody specificities in lupus with a special emphasis on nephritis and to suggest a broader perspective regarding lupus autoantibody reactivities in addition to those against nuclear components.

Mechanisms of autoantibody diversification to SLE-related autoantigens

Systemic lupus erythematosus is a prototype of systemic autoimmunity with autoantibodies (autoAbs) to ribonucleoproteins such as Ro/La, snRNP, dsDNA, and other cellular constituents. A/J mice were used to explore the mechanism of autoAb diversification with recombinant proteins and synthetic peptides. Previous studies showed that Ro60(316-335) induced Abs to Ro60, La, and snRNP proteins. Specific Abs to determinants outside Ro60(316-335) were detected. Absorption experiments showed that Abs to La and snRNP proteins were due to the induction of anti-Ro60 Abs cross-reactive with these peptides. With snRNP proteins, SmD, SmB, and A-RNP as immunogens, specific patterns of intermolecular spreading were obtained in addition to Abs to the immunogens. With SmD-immunized mice, specific Abs to A-RNP and SmB were detected. With SmB as the immunogen, specific Abs to A-RNP were detected in the majority of the mice. Only in a rare incident, specific Abs to SmD were induced. In A-RNP-immunized mice, only Abs to the 70-kD U1-RNP were seen. In all cases, Abs capable of precipitating snRNP particles were detected. Thus, the intermolecular epitope spreading is immunogen-dependent. Evidence for the presence of cross-reactive T cells to more than one autoAg was obtained. The Ag-dependent unique patterns of Ab diversification will facilitate analyses of patients' sera. These results have implications regarding the nature of the Ag-driven autoimmune process.