Determination of preferential binding sites for anti-dsRNA antibodies on double-stranded RNA by scanning force microscopy

• Published in: RNA (Cambridge) Vol. 6; no. 4; pp. 563 - 570
• Main Authors: BONIN, MICHAEL, OBERSTRAß, JÜRGEN, LUKACS, NOEMI, EWERT, KATJA, OESTERSCHULZE, EGBERT, KASSING, RAINER, NELLEN, WOLFGANG
• Format: Journal Article
• Language: English
• Published: United States Cambridge University Press 01.04.2000
• Subjects: Animals; Antibodies, Monoclonal - immunology; Antibody Specificity - immunology; Base Composition; Base Sequence; Binding Sites; Consensus Sequence - genetics; Dictyostelium - genetics; DNA - genetics; DNA - immunology; DNA - metabolism; Epitopes - chemistry; Epitopes - genetics; Epitopes - immunology; Genes, Protozoan - genetics; Microscopy, Atomic Force; Mutagenesis, Site-Directed - genetics; Protozoan Proteins - genetics; RNA, Double-Stranded - chemistry; RNA, Double-Stranded - genetics; RNA, Double-Stranded - immunology; RNA, Double-Stranded - metabolism; RNA-Binding Proteins - metabolism; scanning force microscopy; Substrate Specificity; AFM; RNA–protein interaction; anti-nucleic acid antibodies
• ISSN: 1355-8382; 1469-9001
• DOI: 10.1017/S1355838200992318

The monoclonal anti-dsRNA antibody J2 binds double-stranded RNAs (dsRNA) in an apparently sequence-nonspecific way. The mAb only recognizes antigens with double-stranded regions of at least 40 bp and its affinity to poly(A) poly(U) and to dsRNAs with mixed base pair composition is about tenfold higher than to poly(I) poly(C). Because no specific binding site could be determined, the number, the exact dimensions, and other distinct features of the binding sites on a given antigen are difficult to evaluate by biochemical methods. We therefore employed scanning force microscopy (SFM) as a method to analyze antibody–dsRNA interaction and protein–RNA binding in general. Several in vitro-synthesized dsRNA substrates, generated from the Dictyostelium PSV-A gene, were used. In addition to the expected sequence-nonspecific binding, imaging of the complexes indicated preferential binding of antibodies to the ends of dsRNA molecules as well as to certain internal sites. Analysis of 2,000 bound antibodies suggested that the consensus sequence of a preferential internal binding site is A2N9A3N9A2, thus presenting A residues on one face of the helix. The site was verified by site-directed mutagenesis, which abolished preferential binding to this region. The data demonstrate that SFM can be efficiently used to identify and characterize binding sites for proteins with no or incomplete sequence specificity. This is especially the case for many proteins involved in RNA metabolism.