Diverse humoral autoimmunity to the ribosomal P proteins in systemic lupus erythematosus and hepatitis C virus infection.

Autoantibodies to the three ribosomal P proteins (Rib-P) are specifically found in 10% to 40% of systemic lupus erythematosus (SLE) patients. Most anti-Rib-P autoantibodies bind to a C-terminal epitope shared by all three Rib-P proteins P0, P1 and P2. In the present study, we shed more light on the humoral autoimmune response to the Rib-P antigen as it occurs in autoimmunity and infectious disease. In a mutational analysis of the major C-terminal epitope, we verified the key role of phenylalanine residues Phe ( 111 ) and Phe ( 114 ) for binding of most anti-Rib-P serum autoantibodies present in SLE sera (n = 28). By nuclear magnetic resonance (NMR) investigation of a peptide comprising the C-terminal 22 amino acids, we observed hallmarks for alpha-helical secondary structure of the Rib-P epitope core (GFGLFD). Based on NMR data and on SPOT epitope analysis, we propose a structural model of the Rib-P major epitope, which displays Phe ( 111 ) and Phe ( 114 ) on one side of the helix. Apart from that, two sera from the hepatitis C virus (HCV) control group (n = 68) were found to contain antibodies specific for P2, but not for the other Rib-P proteins. Using a SPOT peptide array scanning the P2 amino acid sequence, we identified reactivity with two distinct epitopes (residues 21-35 and 41-55 of Rib-P2) shared by both HCV sera. We conclude that anti-Rib-P autoreactivity occurs in SLE, Chagas' disease (CD) and-as firstly described here-during HCV infection. Anti-Rib-P reactivity in SLE sera primarily depends on Phe ( 111 ) and Phe ( 114 ) of the alpha-helical C-terminal epitope. In contrast, anti-Rib-P autoantibodies in HCV infection mainly recognize epitopes within the N-terminal half of ribosomal P2.

Technical and clinical evaluation of anti-ribosomal P protein immunoassays.

Autoantibodies to the three ribosomal phospho (-P) proteins P0, P1, P2, referred to as Rib-P, are specifically found in 10-40% of patients with systemic lupus erythematosus. The variations in the observed frequency of these autoantibodies is related to a number of factors such as the test system used to detect the antibodies. Several immunoassays that were designed for research and diagnostic laboratory use have been developed. The autoantigens employed in these tests include native proteins, recombinant polypeptides, and synthetic peptides. In this study, we compared the technical and clinical accuracy of anti-Rib-P antibody assays from different commercial suppliers including ELISA systems and a novel addressable laser bead assay (from Euroimmun, MBL, Pharmacia Diagnostics, INOVA). Although the assays from all suppliers used in this study performed well in the technical part of the study, relatively poor correlations and significant differences in the clinical accuracy were found. Based on the results, we conclude that the detection of anti-Rib-P antibodies strongly depends on both the nature of the antigen and the detection system. We recommend that anti-Rib-P assays should be standardized on an international level. The Varelisa Rib-P profile and the addressable laser bead Rib-P assays represent promising tools and platforms for the detection of anti-Rib-P antibodies in the future.

Characterization of the human autoimmune response to the major C-terminal epitope of the ribosomal P proteins.

Autoantibodies to the ribosomal phospho (-P) proteins P0, P1, and P2, collectively referred to as Rib-P, are specifically found in 10-40% of patients with systemic lupus erythematosus (SLE). These antibodies are believed to be correlated with lupus nephritis, hepatitis, and central nervous system involvement. The major immunoreactive epitope of these ribosomal antigens has been localized to the carboxy terminus, which is a highly conserved domain of all three proteins and contains two phosphorylated serine residues. The phosphorylated amino acids of the P proteins are known not to be critical epitope determinants. Furthermore, epitope-mapping studies have shown that the major epitope is located within the last 11 C-terminal amino acids. Using peptide arrays we identified more precisely this shared epitope as the six C-terminal amino acids GFGLFD and elucidated the molecular recognition events of anti-Rib-P antibodies at the amino acid level. We identified Phe(111) and Phe(114) of Rib-P2 as the key residues for the interaction, with further contributions of Gly-112 and Asp-115. This amino acid stretch is also present in proteins of several pathogenic micro-organisms such as Trypanosoma cruzi, Brugia malayi, Pseudomonas aeruginosa, Candida albicans, several Leishmania species, and Bartonella henselae. Using newly developed ELISA systems with a C-terminal peptide (C22) and the recombinant proteins (P0, P1, and P2) as antigens we found a high specificity of anti-Rib-P antibodies for SLE and demonstrated positive correlations with anti-U1-C, anti-Sm-B/B' and anti-D and anti-dsDNA antibodies. The sensitivity and specificity in the peptide (C22) based assay varied between 12.8%/100% and 23.4%/96.7% for SLE, depending on the assigned cutoff. In contrast to other studies, we found no significant correlation of anti-Rib-P reactivity with central nervous system manifestations or renal involvement in SLE patients. We conclude that the epitope motif GFGLFD in the C-termini of the ribosomal P proteins is the key determinant of anti-Rib-P antibodies, and that the C22 peptide and the recombinant proteins can be used equally well for the detection of anti-Rib-P antibodies. The role of the major Rib-P epitope in the development of anti-ribosomal P antibodies and in the pathogenesis of SLE remains a subject of further investigation.