Immunization with peptides from 60 kDa Ro in diverse mouse strains

Antibodies binding the Ro (or SSA) and La (or SBB) proteins are commonly found in a high proportion of sera from patients with systemic lupus erythematosus or Sjögren's syndrome. The mechanism by which these autoantibodies arise is not known. Others and we have shown that immunization of nonautoimmune‐prone mice with short peptides from the Ro ribonucleoprotein particle can induce autoimmunity to 60 kDa Ro and 52 kDa Ro as well as to the 48 kDa La protein after epitope spreading. We have explored the differences in the epitope spreading after 60 kDa Ro peptide immunization in several strains of mice. There is intra‐ and intermolecular diversification of the immune response after immunization of DBA/2J animals with a monomer peptide representing the residues 480–494 of the 60 kDa Ro protein, but this peptide does not induce epitope spreading when used as the immunogen in either C57Bl/6J or PL/J mice. Similar to previously studied BALB/c mice, DBA/2J mice have antibodies binding many epitopes of 60 kDa Ro, and some sera bind 52 kDa Ro as well as La. These mice have antinuclear antibody in their sera. These data demonstrate that Ro peptide immunization results in different outcomes depending upon the strain of mouse used. Furthermore, these data suggest that genetic variation is important with regard to responding towards short peptide immunization by epitope spreading.     

Autoantibodies to the Ro/SSA autoantigen are conformation dependent. II: Antibodies to the denatured form of 52 kD Ro/SSA are a cross reacting subset of antibodies to the native 60 kD Ro/SSA molecule.

The immune response to the Ro/SSA particles is conformation dependent. In sera with only anti-Ro/SSA precipitins, the autoantibodies to the 60 kD Ro/SSA are largely to the native 60 kD Ro/SSA while autoantibodies to the 52 kD Ro/SSA particle when present are exclusively to the denatured 52 kD Ro/SSA particle. Antibodies eluted from a recombinant 52 kD Ro/SSA fusion protein reacted in a sandwich ELISA which only measures antibody to native 60 kD Ro/SSA antigens and this reaction is largely inhibited by native homogeneous 60 kD Ro/SSA. In addition, antibody binding to the 52 kD Ro/SSA antigen in Western blot is also strongly inhibited by native 60 kD Ro/SSA. These experiment strongly suggest that reactivity of denatured 52 kD Ro/SSA antigen represents a cross reaction with autoantibodies directed to the native 60 kD Ro/SSA antigen. As a corollary of these experiments, data are presented that suggest the hY-RNAs are not associated with the 52 kD Ro/SSA protein but only with the 60 kD Ro/SSA protein. These data are consistent with the hypothesis that the autoanti-Ro/SSA response is driven by native 60 kD Ro/SSA and the immune response to denatured 52 kD Ro/SSA is largely a cross-reactive subset of the immune response to native 60 kD Ro/SSA.     

Autoantibodies to the Ro/SSA antigen are conformation dependent. I: Anti-60 kD antibodies are mainly directed to the native protein; anti-52 kD antibodies are mainly directed to the denatured protein.

Recent studies have shown that Ro/SSA autoantigen is heterogeneous and the autoanti-Ro/SSA response is correspondingly heterogeneous. There are two isoform families; the 60 kD forms and the 52 kD forms. We studied the antigenic difference between the native and denatured Ro/SSA isoforms and found that the autoanti-Ro/SSA response to the native 60 kD antigen is quite homogeneous. All anti-Ro/SSA sera recognize the native kD antigen regardless of the reactivities to the 60 kD band on the Western blot. Surprisingly, no anti-Ro/SSA sera without anti-La/SSB reacts with the native 52 kD Ro/SSA, although sera with both precipitating anti-Ro/SSA and anti-La/SSB can immunoprecipitate the native 52 kD antigen. Anti-Ro/SSA sera exist which react exclusively with the native 60 kD Ro/SSA protein (10/43, 23%) while no anti-Ro/SSA sera have been found which react exclusively with the denatured 52 kD Ro/SSA antigen. In sera with anti-Ro/SSA precipitins alone, only antibody to the denatured 52 kD Ro/SSA molecule is found! In sera with anti-Ro/SSA and anti-U1 RNP precipitins, no antibody to either native or denatured 52 kD Ro/SSA is found, while in sera with both anti-Ro/SSA and anti-La/SSB precipitins, antibodies to both the native and denatured forms of 52 kD Ro/SSA are present. These data suggest that the anti-Ro/SSA response to the 60 kD molecule is driven by the native 60 kD Ro/SSA molecule while the molecular identification of the antigen drive in the anti-52 kD Ro/SSA response is unknown.     

Interaction of calcium and Ro60: increase of antigenicity

The structural and functional integrity of the cell is largely maintained by protein-protein interactions. Recently, we demonstrated that multiple antigenic peptides (MAPs) constructed from 60 kDa Ro sequence could be used to show intramolecular and intermolecular protein-protein interaction within the 60 kDa Ro ribonucleoprotein particle. We were interested in understanding the mechanism of this binding and hypothesized that this interaction might be mediated through divalent metal ions. The 60 kDa Ro-MAPs failed to interact with purified 60 kDa Ro in the presence of EDTA or EGTA when analyzed by Ouchterlony or surface plasmon resonance (SPR) analysis. When purified 60 kDa Ro was incubated with various metal ions such as Cu2+, Mg2+, Zn2+ and Ca2+, and analyzed by Ouchterlony or SPR for binding to specific 60 kDa Ro-MAPs only Ca2+ ions significantly increased the binding. It was interesting to note that recombinant 60 kDa Ro formed precipitin lines with Ro-MAPs only in the presence of Ca2+ ions. Anti-Ro60 containing SLE sera bound to recombinant Ro60 strongly when incubated in the presence of Ca2+ ions but not in the absence of Ca2+ ions. Using SPR analysis we also found that native Ro60 binds to La only in the presence of Ca2+. These data imply that Ca2+ induces a more native tertiary structure to recombinant 60 kDa Ro and makes it more antigenic. Thus, the observed intramolecular and intermolecular interactions and antigen-antibody interactions could be Ca2+ ion mediated conformational interactions, and we propose that 60 kDa Ro is a calcium binding protein.     

Post-translational modifications of the major linear epitope 169-190aa of Ro60 kDa autoantigen alter the autoantibody binding

Ro60 kDa is a member of the Ro/LaRNP ribonucleoprotein complex and its major linear B cell epitope, corresponding to the region 169–190aa, has been found to be the initial target of the autoimmune response in patients with systemic lupus erythematosus. This sequence contains one serine and two arginine amino acid residues, which can potentially be modified post‐translationally by phosphorylation or citrullination, respectively. The aim of this study was to develop an immunoassay for anti‐Ro60 kDa epitope antibody detection and to investigate the changes in the antigenicity of the Ro60 kDa epitope when it is post‐translationally modified, by either citrullination or phosphorylation. Peptide analogues corresponding to the unmodified form of the epitope, its phosphorylated form, and a form with both arginine residues citrullinated were synthesized. The peptide coating conditions were investigated and it was found that the use of highly hydrophilic surfaces increase the efficiency of the coating, as well as the sensitivity of the method for anti‐peptide antibody detection. All peptides were tested by the optimized enzyme‐linked immunosorbent assay (ELISA) against 119 sera from patients with primary Sjögren's syndrome, systemic lupus erythematosus and rheumatoid arthritis with anti‐Ro/SSA reactivity, 20 sera from patients with systemic diseases without anti‐Ro/SSA immune reactivity, as well as against 65 sera from normal individuals. A large proportion of the tested sera reacted against all three peptide analogues, although with a preference for the unmodified form of the epitope. In conclusion, post‐translational modifications of the major Ro60 kDa B cell epitope can alter the autoantibody binding.     

Epitope mapping of the 52-kD Ro/SSA autoantigen.

Autoantibodies to Ro/SSA are commonly found in sera of patients with systemic lupus erythematosus (SLE) and primary Sjögren's syndrome. The presence of these antibodies is related to lymphopenia, photosensitive dermatitis, and pulmonary and renal disease, suggesting that they have an immunopathologic role [1-6]. We previously isolated a cDNA clone which encodes the 52-kD human Ro/SSA protein. In this study we have determined the number and location of epitopes recognized by SLE sera using recombinant proteins encoded by the full-length or overlapping subclones of this cDNA. An immunodominant epitope was detected using Western blots and ELISA on the NH2-terminal side of this protein's putative leucine zipper. The data suggest that 11 amino acids are critical for the recognition of this molecule by these autoantibodies. Although the titres of anti-52-kD Ro/SSA antibodies vary between different patient sera, no heterogeneity in the location of antigenic epitopes to which their autoantibodies bound was detected. This homogeneous pattern of reactivity to a single rather than multiple regions of this protein is unusual for lupus autoantigens which have been identified, and suggests that these antibodies may have arisen as by a cross-reaction to an epitope on another molecule.     

Specific testing for "isolated" anti-52 kDa SSA/Ro antibodies during standard anti-extractable nuclear antigen testing is of limited clinical value

AIM: To ascertain whether specific testing for "isolated" anti-52 kDa SSA/Ro antibodies (a-SSA/Ro52) during standard anti-extractable nuclear antigen (ENA) testing is clinically useful. METHODS: 1438 consecutive sera submitted for anti-ENA testing over 1 year were evaluated for a-SSA/Ro52 using various assays. RESULTS: 7 of 1438 (0.48%) patients were found to have a-SSA/Ro52 without SSA/Ro60 antibodies. Subsequent testing detected a further five patients. Clinical follow-up was possible in 10/12 patients. 2 of these 10 patients had evidence of primary Sj?gren's syndrome (SS) and one had systemic lupus erythematosus (SLE), with sicca symptoms and abnormal Schirmer's tests. Five other patients had sicca symptoms, of which four had abnormal Schirmer's tests. CONCLUSIONS: "Isolated" anti-52 kDa SSA/Ro antibodies were detected in approximately 0.5% of standard anti-ENA requests, in which their presence was generally not associated with underlying SS or SLE. In view of the increased testing complexity and costs in detecting and confirming these antibodies, specific testing for isolated a-SSA Ro52 antibodies during standard anti-ENA testing seems to be of limited clinical value in a non-obstetric population.     

Human Anti-Ro Autoantibodies Bind Peptides Accessible to the Surface of the Native Ro Autoantigen

The relationship between fine specificity of linear epitopes and conformational determinants has been explored in a naturally arising human autoimmune response. In particular, the hypothesis tested is that the linear epitopes of the human Ro autoantigen are components of its conformational epitopes. Twenty groups among the 531 overlapping octapeptides 60kDa Ro are variably bound by anti-Ro precipitin positive lupus sera whose reactivity was easily distinguished from sera of normal controls and of anti-Ro precipitin negative lupus patients. The specific activities of anti-peptide antibodies and of anti-native Ro autoantibodies are similarly increased after affinity enrichment using native human Ro as ligand. Moreover, affinity-enriched anti-native Ro autoantibodies bind virtually the same 20 groups of epitopes recognized by whole anti-Ro positive sera. Two peptides (residues 274–290 and 480–494) from the defined 60 kDa Ro octapeptide epitopes have been prepared and used as ligands for affinity purification of peptide specific autoantibodies. The binding of both whole IgG and affinity-enriched peptide specific autoantibodies is inhibited by native Ro autoantigen. Thus, none of the available data can be construed to support the existence of cryptic linear epitopes in this system. Indeed, the data are only consistent with the conclusion that all of the anti-Ro octapeptide autoantibodies are part of the population of anti-native Ro autoantibodies in this naturally arising autoimmune response.     

Effective separation of the 52 kDa SSA/Ro polypeptide from the 48 kDa SSB/La polypeptide by altering conditions of polyacrylamide gel electrophoresis

A method is described for the separation of the 52 kDa SSA/Ro polypeptide from the 48 kDa SSB/La polypeptide. These two proteins anomalously co-migrate with the same relative mass under conditions of conventional sodium dodecyl sulfate polyacrylamide gel electrophoresis according to Laemmli using a stock solution of acrylamide: bisacrylamide 30:0.8, ratio = 37.5. A higher ratio of monomer to cross-linker, ratio = 172.4 used in a 15% acrylamide solution, readily separates the two peptide chains. This method facilitates the detection of the 52 kDa SSA/Ro component which otherwise might have been incorrectly assigned as a 48 kDa SSB/La polypeptide.     

The Ro 60 kDa autoantigen comes into focus: interpreting epitope mapping experiments on the basis of structure

A conserved RNA-binding protein, the Ro 60 kDa (Ro60) autoantigen, is a major target of autoantibodies in patients suffering from the rheumatic diseases Sjogren's syndrome, systemic lupus erythematosus, subacute cutaneous lupus erythematosus and neonatal lupus erythematosus. In both mice and certain bacteria, Ro60 is important for cell survival following ultraviolet irradiation. Although the function of Ro60 was mysterious for many years, recent experiments have demonstrated that this protein binds misfolded noncoding RNAs in vertebrate cells and likely functions in a pathway by which defective RNAs are recognized and targeted for degradation. Recent structural studies have revealed that Ro60 is shaped like a doughnut with an inner hole. Noncoding RNAs called Y RNAs bind on the outer surface of the ring, while the single-stranded ends of misfolded RNAs likely bind within the hole. Comparison of the Ro60 structure with the results of epitope-mapping studies reveals that many of the currently identified epitopes recognized by patient sera overlap regions of Ro60 that function in RNA binding. Moreover, in some patients with anti-Ro60 antibodies, the initial antigenic epitope corresponds to a loop involved in binding single-stranded RNA in the central cavity.     

Cloning and characterization of two human Ro52-specific monoclonal autoantibodies directed towards a domain associated with congenital heart block

Autoantibodies against amino acid 200-239 (p200) in the predicted leucine zipper region of the Ro52 protein are associated with congenital heart block, a potentially fatal condition that may affect fetuses of women with Ro52 autoantibodies. To allow detailed studies of the antibodies associated with congenital heart block, B-cell derived combinatorial antibody libraries from patients were screened for Ro52 and p200 specific antibody clones. Two human monoclonal anti-p200 antibody fragments, S3A8 and M4H1, were isolated and analysed with regard to VHand VL gene utilization, somatic mutations and binding properties. Both identified clones recognized recombinant and native intact Ro52, and reacted only with p200 in a set of related Ro52 peptides. The specificity and affinity was confirmed by biosensor measurements. Structural analysis of overlapping peptides revealed increased helicity in the p200 peptide compared to non-recognized peptides, indicating epitope conformation as essential for antibody binding. Both monoclonals produced punctate nuclear and diffuse cytoplasmic staining in human and mouse cell lines. The identified antibodies, which react specifically with the leucine zipper structure of Ro52, will be valuable in further exploration of the mechanisms operating during development of Ro52 antibody-associated congenital heart block.     

Detection and occurrence of the 60- and 52-kD Ro (SS-A) antigens and of autoantibodies against these proteins.

The simultaneous detection of anti-La, anti-60-kD Ro and anti-52-kD Ro antibodies by immunoblotting is greatly improved by changing the crosslinking level in the gel to an acrylamide/bisacrylamide ratio of 19:1. Using this method for the analysis of a number of systemic lupus erythematosus (SLE) and Sjögren''s syndrome patient sera it was observed that antibody to the 52-kD Ro protein without anti-60-kD Ro antibody was restricted to Sjögren''s syndrome patients (9/26), whereas antibody to the 60-kD Ro protein without contaminating anti-52-kD Ro antibody was only found in SLE patients (8/38). Moreover, in Sjögren''s syndrome patient sera anti-Ro antibody was found only in combination with anti-La antibody (20/26), whereas in SLE patient sera anti-Ro antibody could be found without detectable anti-La specificity (4/38). Double immunofluorescence microscopy revealed that the 52-kD Ro and the 60-kD Ro proteins co-localize in the cytoplasm as well as in the nucleus, whereas immunoprecipitation of [32P]-labelled HeLa cell extract with monospecific anti-52-kD Ro and anti-60-kD Ro sera showed that both proteins are associated with the Ro RNAs. These data suggest the presence of both the 52-kD and the 60-kD Ro proteins in the same ribonucleoprotein complexes. To study the evolutionary conservation of the 52-kD Ro, the 60-kD Ro and the La proteins, extracts of cell lines derived from various mammalian species were analysed on Western blots using monospecific human antibodies. In contrast to the 60-kD Ro and the La antigens which are well conserved in evolution, the 52-kD Ro antigen could be detected in primate cells only by this immunological approach.     

IgM and IgG Subclass Distribution of Human Anti-Ro/SSA 60 kDa Autoantibodies

The Ro/SSA and La/SSB antigens are common targets for autoantibodies found in the sera of patients with Sjögren's syndrome and SLE. The anti-Ro/SSA and anti-La/SSB antibodies often appear together but are not cross-reactive. This paper describes the humoral autoimmune response to the Ro/SSA 60 kDa protein moiety with respect to the presence of IgM and IgG1-4 antibodies. IgM antibodies to the Ro 60 kDa protein coexisted with IgG anti-Ro 60 kDa antibodies in nearly half of the sera. A similar fraction also contained IgM anti-La/SSB antibodies. The frequency of sera with IgM antibodies of both specificities was that expected from random overlap.
A predominating igGl anti-Ro 60 kDa response was found in all patients, but anti-Ro 60 kDa antibodies of the other IgG subclasses were present also in a high number of sera. This is in contrast to the reported IgG subclass distribution of anti-La/SSB antibodies.
Mapping of IgM and IgG 1–4 antibody recognition of different parts of the Ro 60 kDa protein was also performed. IgM and IgGl-4 antibodies of all sera reacted with the central part of the Ro 60 kDa protein, encompassing amino acid residues 181–320.     

Identification of antigenic regions of the human Ro 60 kDa protein using recombinant antigen and synthetic peptides.

Autoantibodies reacting with the human Ro 60 kDa protein are present in anti-Ro/SS-A positive sera from patients with several different connective tissue diseases including Sj?gren's syndrome and systemic lupus erythematosus. To investigate the humoral immune response to this protein, the pattern of antibody recognition of recombinant Ro 60 kDa proteins encoded by both full-length and deletion clones was analysed by immunoblotting. An antigenic region recognized by nearly all anti-Ro 60 kDa positive sera was found to reside in the middle part of the protein. In addition, some sera reacted with two other antigenic regions located in the amino-terminal and carboxyl-terminal part of the protein. For further mapping, overlapping peptides covering the most frequently recognized region of the protein were synthesized by solid-phase methods and used as antigens in ELISA. Three major patterns of reactivity to Ro 60 kDa peptides were found. These results not only indicate the presence of an immunodominant region but also heterogeneity in the autoimmune human response to the Ro 60 kDa antigen.     

Calreticulin binds preferentially with B cell linear epitopes of Ro60 kD autoantigen,enhancing recognition by anti-Ro60 kD autoantibodies

Calreticulin is a molecular chaperone to newly synthesized polypeptides. Previous studies suggested that calreticulin is probably a protein member of the Ro/La RNP complex. The aims of this study were (a) to investigate whether linear B cell epitopes of the Ro/La RNP complex are bound to calreticulin and (b) if the complex peptide–calreticulin is recognized specifically by anti‐Ro autoantibodies. Calreticulin was isolated from either human or pig spleen using a multi‐step purification method and found to interact preferentially with biotinylated peptides derived from the sequence of the Ro60 kD 175–184aa(10p) and 216–232aa(17p). The interaction of the peptide–calreticulin complex was favoured by the combination of heat treatment, divalent cations and ATP. La/SSB epitopes did not react with calreticulin. Peptides corresponding to La/SSB epitopes as well as the common epitope of Sm did not interact with calreticulin. Thirty‐eight anti‐Ro60 KD positive and 23 anti‐Ro60 kD negative sera of patients with systemic lupus erythematosus (SLE) and primary Sjögren's syndrome (pSS) were tested. All anti‐Ro60 kD positive sera bound the complex calreticulin‐17p, while 95% of the same sera had activity against the complex calreticulin ? 10p. Tested individually, calreticulin, pep10p and pep17p presented very low reactivity (8%, 11% and 29%, respectively) against anti‐Ro60 kD positive sera. Anti‐Ro60 KD negative sera did not exhibit significant reactivity either with calreticulin, 10ρ and 17ρ or with the complexes calreticulin ? 10p and calreticulin‐17p (<5%). These results suggest that calreticulin can induce conformation‐dependent recognition of the Ro60 kD epitopes, leading eventually to their recognition by autoantibodies. This is the first time that such a relationship is shown between a chaperone protein and fragments of an intracellular autoantigen. This work also provides insights into the understanding of mechanisms for autoantibody production. Furthermore, this association can be proved useful for the development of new sensitive assays for autoantibody detection.     

Putative sequences on Ro60 three-dimensional structure accessible for 4-hydroxy-2-nonenal (HNE) modification compared to in vitro HNE modification of Ro60 sequences

We have previously reported accelerated acquisition of new autoreactivity upon immunization with 4-hydroxy-2-nonenal (HNE)-modified Ro60, as well as differential induction of lupus or Sj?gren's syndrome by immunization with Ro60 containing varying amounts of HNE. Since the number of HNE molecules on Ro60 appears to be important, we hypothesized that specific sequences on Ro60 are targets for HNE-modification. Using surface plasmon resonance (SPR) we have also shown intramolecular protein-protein interaction between Ro60 and Ro multiple antigenic peptides (MAPs). We also hypothesized that intramolecular protein-protein interaction would be abolished by HNE-modification. To test this hypotheses we investigated (a) the epitopes of Ro60, using 19 Ro MAPs in an in vitro assay (involving HNE-modification of MAPs following immobilization on ELISA plates) to identify targets of HNE modification on Ro60 and (b) the protein-protein interaction between unmodified Ro60 MAPs, immobilized on the sensor surface of BIAcore, and unmodified Ro60 or HNE-modified Ro60 using SPR. New data obtained with SPR strengthens our earlier observation that immunization with HNE-Ro60 induces a stronger response. Unmodified Ro60 bound to several Ro60 MAPs through protein-protein interaction analyzed using SPR. This interaction was totally abrogated using HNE-modified Ro60 suggesting that sequences on Ro had become modified with HNE. When 19 Ro60 MAPs were modified in vitro with HNE, it was found that 10/19 MAPs significantly bound HNE covalently (p<0.001 compared to MAPs binding HNE poorly). The amino acid sequences 126-137, 166-272 and 401-495 on Ro60 were strongly HNE modified. Using computational model system based on the recently published crystal structure for Ro60 enabled us to identify regions on the Ro60 molecule represented by the HNE-modified Ro MAPs, which are part of the exposed tertiary structure of the Ro60 protein.     

Structural, Molecular and Immunological Properties of Linear B-Cell Epitopes of Ro60KD Autoantigen

Antibodies to Ro60KD protein are found with high frequency in sera from patients with systemic lupus erythematosus (SLE) and primary Sjögren's syndrome (pSS). Two major epitopes of the Ro60KD antigen, the TKYKQRNGWSHKDLLRSHLKP (169–190) and the ELYKEKALSVETEKLLKYLEAV (211–232), were synthesized and their antigenic and structural properties were studied. Using a large panel of SLE and pSS patients' sera, it was found that the anti-Ro60KD reactivity of both Ro60KD epitopes is rather limited (≈45%), although they retain their original disease specificity. The epitope p.169–190 possessed sequence similarity with the peptide RPDAEYWNSQKDLLEQKRGR, shared in the β-chain of different HLA-DR molecules, among them the HLA-DR3 (which is associated with anti-Ro/Sjögren's syndrome A (SSA) response in patients with SLE). The antigenicity of the HLA-DR3 RPDAEYWNSQKDLLEQKRGR peptide was found to be similar to the 169–190 homologous Ro60KD epitope, recognized mainly by SLE sera. Structural studies showed that the 211–232 Ro60KD epitope exhibits pronounced helical characteristics, while the 169–190 epitope and the HLA-DR3 homologous peptide possess a somewhat lower percentage of α-helix. A β-folded structure was identified in the latter two peptides. Although the diagnostic value of the reported Ro60KD epitopes seems to be rather limited, correlations with other ribonucleoprotein epitopes (La/Sjögren's syndrome B, Ro52KD) may prove complementary to each other and valuable in clinical use. The ordered structure of the HLA-DR3 homologous peptide, exposed to the autoantibody binding, may offer an initiative in further investigation of the role of the HLA haplotypes, associated with the anti-Ro/SSA response, in the autoimmune stimulus.     

Different temporal expression of immunodominant Ro60/60 kDa-SSA and La/SSB apotopes

Opsonization of apoptotic cardiocytes by maternal anti-Ro/SSA and anti-La/SSB antibodies contributes to tissue injury in the neonatal lupus syndrome. The objective of the current study was to quantify the surface membrane expression of Ro/La components during different phases of apoptosis and map the Ro/La apotopes (epitopes expressed on apoptotic cells) bound by cognate antibodies. Multi-parameter flow cytometry was used to define early and late apoptotic populations and their respective binding by monospecific anti-Ro and anti-La IgGs. Anti-Ro60 bound specifically to early apoptotic Jurkat cells and remained accessible on the cell surface throughout early and late apoptosis. In contrast, anti-La bound exclusively to late apoptotic cells in experiments controlled for non-specific membrane leakage of IgG. Ro52 was not accessible for antibody binding on either apoptotic population. The immunodominant NH₂-terminal and RNA recognition motif (RRM) epitopes of La were expressed as apotopes on late apoptotic cells, confirming recent in vivo findings. An immunodominant internal epitope of Ro60 that contains the RRM, and is recognized by a majority of sera from mothers of children with congenital heart block (CHB) and patients with primary Sjögren's syndrome, was also accessible as an apotope on early apoptotic cells. The distinct temporal expression of the immunodominant Ro60 and La apotopes indicates that these intracellular autoantigens translocate independently to the cell surface, and supports a model in which maternal antibody populations against both Ro60 and La apotopes act in an additive fashion to increase the risk of tissue damage in CHB.     

Epitope mapping with synthetic peptides of 52-kD SSA/Ro protein reveals heterogeneous antibody profiles in human autoimmune sera.

The reactivity of autoantibodies present in the sera of 489 patients with Sjögren's syndrome (SS), systemic lupus erythematosus (SLE) and other autoimmune diseases was investigated by ELISA using recombinant 52-kD SSA/Ro protein (rRo52) and 39 overlapping synthetic peptides representing the entire sequence of Ro52. We report that IgG antibodies reacting with rRo52 were present in the sera of a large number of patients with SS (67% of patients with primary SS and 46% of patients with SS associated with SLE), whereas they were less frequent (10-25%) in SLE, rheumatoid arthritis (RA), juvenile chronic arthritis (JCA) and mixed connective tissue disease (MCTD), and absent in scleroderma. Among the 39 peptides tested, five were recognized by sera from 30-65% of patients with SS, namely peptides representing residues 2-11, 107-122, 107-126, 277-292 and 365-382. Patients with JCA had raised levels of IgG antibodies reacting with peptides 2-11 and 365-382, and 51% of patients with MCTD had raised levels of IgG antibodies reacting with peptide 365-382. None of the five peptides was recognized by more than 20% of sera from patients with SLE and RA. Interestingly, and of importance in the field of diagnostic tests based on peptides, the reactivity of antibodies to the Ro52 synthetic peptides varied greatly according to the origin of sera. Inhibition experiments using either patients' sera or antibodies induced in rabbits against Ro52 peptides showed that the four domains 2-11, 107-122, 277-292 and 365-382 are accessible on the surface of the Ro52 protein. These regions may thus be involved in the induction of specific antibodies in autoimmune patients.