Abstract
To characterize RNA–capsid binding sites genome-wide within mature RNA virus particles, we have developed a Next-Generation Sequencing (NGS) platform: viral Photo-Activatable Ribonucleoside CrossLinking (vPAR-CL). In vPAR-CL, 4-thiouridine is incorporated into the encapsidated genomes of virus particles and subsequently UV-crosslinked to adjacent capsid proteins. We demonstrate that vPAR-CL can readily and reliably identify capsid binding sites in genomic viral RNA by detecting crosslink-specific uridine to cytidine transitions in NGS data. Using Flock House virus (FHV) as a model system, we identified highly consistent and significant vPAR-CL signals across virus RNA genome, indicating a clear tropism of the encapsidated RNA genome. Certain interaction sites coincide with previously identified functional RNA motifs. We additionally performed dimethyl sulfate mutational profiling with sequencing (DMS-MaPseq) to generate a high-resolution profile of single-stranded genomic RNA inside viral particles. Combining vPAR-CL and DMS-MaPseq reveals that the predominant RNA–capsid interaction sites favored double-stranded RNA regions. We disrupted secondary structures associated with vPAR-CL sites using synonymous mutations, resulting in varied effects to virus replication, propagation and packaging. Certain mutations showed substantial deficiency in virus replication, suggesting these RNA–capsid sites are multifunctional. These provide further evidence to support that FHV packaging and replication are highly coordinated and inter-dependent events.
Highlights
Flock House virus (FHV) is a non-enveloped, single-stranded positive-sense RNA (+ssRNA) virus from the family Nodaviridae
Purified virus particles were subjected to UV 365 nm irradiation, yielding crosslinks between the thio-group of 4SU in the viral genomic RNA and amino acid residues in the protein capsid shell only if they are in close proximity [32, 33]
We demonstrated that Photo-Activatable Ribonucleoside Cross-Linking (PAR-CL) can be used as a reliable and convenient method to screen for capsid-interacting sites on viral RNA genomes
Summary
Flock House virus (FHV) is a non-enveloped, single-stranded positive-sense RNA (+ssRNA) virus from the family Nodaviridae. The small bipartite genome comprising RNA 1 (3.1kb) and RNA 2. Two non-structural proteins are produced by FHV: the RNA-dependent RNA polymerase (RdRp) and sub-genomic. The B2 protein was discovered as the virus’s approach to evade the invertebrate anti-viral RNA silencing machinery [1, 2], which thereafter led to the discovery of similar mechanisms in plant cells [3]. FHV is perhaps the best studied alphanodavirus and provides a powerful model system by virtue of its small genome size (4.5kb), genetic tractability and ability to infect Drosophila and mosquito cells in culture and whole flies (reviewed in [4, 5]). FHV-related vaccine developments utilized either the viral particle as antibody-display system [6], or the viral RNA as transencapsidated chimeric viral vaccine platform [7,8,9]
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