Hepatitis delta antigen requires a flexible quasi-double-stranded RNA structure to bind and condense hepatitis delta virus RNA in a ribonucleoprotein complex.

UNLABELLED: The circular genome and antigenome RNAs of hepatitis delta virus (HDV) form characteristic unbranched, quasi-double-stranded RNA secondary structures in which short double-stranded helical segments are interspersed with internal loops and bulges. The ribonucleoprotein complexes (RNPs) formed by these RNAs with the virus-encoded protein hepatitis delta antigen (HDAg) perform essential roles in the viral life cycle, including viral replication and virion formation. Little is understood about the formation and structure of these complexes and how they function in these key processes. Here, the specific RNA features required for HDAg binding and the topology of the complexes formed were investigated. Selective 2'OH acylation analyzed by primer extension (SHAPE) applied to free and HDAg-bound HDV RNAs indicated that the characteristic secondary structure of the RNA is preserved when bound to HDAg. Notably, the analysis indicated that predicted unpaired positions in the RNA remained dynamic in the RNP. Analysis of the in vitro binding activity of RNAs in which internal loops and bulges were mutated and of synthetically designed RNAs demonstrated that the distinctive secondary structure, not the primary RNA sequence, is the major determinant of HDAg RNA binding specificity. Atomic force microscopy analysis of RNPs formed in vitro revealed complexes in which the HDV RNA is substantially condensed by bending or wrapping. Our results support a model in which the internal loops and bulges in HDV RNA contribute flexibility to the quasi-double-stranded structure that allows RNA bending and condensing by HDAg. IMPORTANCE: RNA-protein complexes (RNPs) formed by the hepatitis delta virus RNAs and protein, HDAg, perform critical roles in virus replication. Neither the structures of these RNPs nor the RNA features required to form them have been characterized. HDV RNA is unusual in that it forms an unbranched quasi-double-stranded structure in which short base-paired segments are interspersed with internal loops and bulges. We analyzed the role of the HDV RNA sequence and secondary structure in the formation of a minimal RNP and visualized the structure of this RNP using atomic force microscopy. Our results indicate that HDAg does not recognize the primary sequence of the RNA; rather, the principle contribution of unpaired bases in HDV RNA to HDAg binding is to allow flexibility in the unbranched quasi-double-stranded RNA structure. Visualization of RNPs by atomic force microscopy indicated that the RNA is significantly bent or condensed in the complex.

Arginine-rich motifs are not required for hepatitis delta virus RNA binding activity of the hepatitis delta antigen.

Hepatitis delta virus (HDV) replication and packaging require interactions between the unbranched rodlike structure of HDV RNA and hepatitis delta antigen (HDAg), a basic, disordered, oligomeric protein. The tendency of the protein to bind nonspecifically to nucleic acids has impeded analysis of HDV RNA protein complexes and conclusive determination of the regions of HDAg involved in RNA binding. The most widely cited model suggests that RNA binding involves two proposed arginine-rich motifs (ARMs I and II) in the middle of HDAg. However, other studies have questioned the roles of the ARMs. Here, binding activity was analyzed in vitro using HDAg-160, a C-terminal truncation that binds with high affinity and specificity to HDV RNA segments in vitro. Mutation of the core arginines of ARM I or ARM II in HDAg-160 did not diminish binding to HDV unbranched rodlike RNA. These same mutations did not abolish the ability of full-length HDAg to inhibit HDV RNA editing in cells, an activity that involves RNA binding. Moreover, only the N-terminal region of the protein, which does not contain the ARMs, was cross-linked to a bound HDV RNA segment in vitro. These results indicate that the amino-terminal region of HDAg is in close contact with the RNA and that the proposed ARMs are not required for binding HDV RNA. Binding was not reduced by mutation of additional clusters of basic amino acids. This result is consistent with an RNA-protein complex that is formed via numerous contacts between the RNA and each HDAg monomer.