Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has recently caused acute respiratory distress syndrome affecting more than 200 countries with varied mortality rate. Successive genetic variants of SARS-CoV-2 become evident across the globe immediately after its complete genome sequencing. Here, we found a decent association of SARS-CoV-2 ORF3a mutation with higher mortality rate. Extensive in silico studies revealed several amino acid changes in ORF3a protein which ultimately leads to diverse structural modifications like B cell epitope loss, gain/loss of phosphorylation site and loss of leucine zipper motif. We could further relate these changes to the enhanced antigenic diversity of SARS-CoV-2. Through protein−protein network analysis and functional annotation studies, we obtained a close federation of ORF3a protein with host immune response via divergent signal transduction pathways including JAK-STAT, chemokine and cytokine-related pathways. Our data not only unveil the fairly appreciable association of ORF3a mutation with higher mortality rate, but also suggest a potential mechanistic insight towards the immunopathogenic manifestation of SARS-CoV-2 infection.

Brome mosaic virus (BMV) genomic minus-strand RNA synthesis requires an RNA motif named stem-loop C (SLC). An NMR-derived solution structure of SLC was reported by Kim et al. (Nature Struc Biol, 2000, 7:415–423) to contain three replicase-recognition elements, the most important of which is a stable stem with a terminal trinucleotide loop, 5′AUA3′. The 5′-most adenine of the triloop is rigidly fixed to the stem helix by interactions that require the 3′-most adenine, which is called a clamped adenine motif. However, a change of the 3′ adenine to guanine (5′AUG3′) unexpectedly directed RNA synthesis at 130% of wild type (Kim et al., Nature Struc Biol, 2000, 7:415–423). To understand how RNA with the AUG mutation maintains interaction with the BMV replicase, we used NMR and other biophysical techniques to elucidate the solution conformation of a 13-nt RNA containing the AUG triloop, called S-AUG. We found that S-AUG has a drastically different loop conformation in comparison to the wild type, as evidenced by an unusual C[bull ]G loop-closing base pair. Despite the conformational change, S-AUG maintains a solution-exposed adenine similar to the clamped adenine motif found in the wild type. Biochemical studies of the 5′AUG3′ loop with various substitutions in the context of the whole SLC construct confirm that the clamped adenine motif exists in S-AUG remains a primary structural feature required for RNA synthesis by the BMV replicase.

Here we propose a new general method for directly determining RNA sequence based on the use of the RNA-dependent RNA polymerase from bacteriophage φ6 and the chain terminators (RdRP sequencing). The following properties of the polymerase render it appropriate for this application: (1) the φ6 polymerase can replicate a number of single-stranded RNA templates in vitro. (2) In contrast to the primer-dependent DNA polymerases utilized in the sequencing procedure by Sanger et al. (Proc Natl Acad Sci USA, 1977, 74:5463–5467), it initiates nascent strand synthesis without a primer, starting the polymerization on the very 3′-terminus of the template. (3) The polymerase can incorporate chain-terminating nucleotide analogs into the nascent RNA chain to produce a set of base-specific termination products. Consequently, 3′ proximal or even complete sequence of many target RNA molecules can be rapidly deduced without prior sequence information. The new technique proved useful for sequencing several synthetic ssRNA templates. Furthermore, using genomic segments of the bluetongue virus we show that RdRP sequencing can also be applied to naturally occurring dsRNA templates. This suggests possible uses of the method in the RNA virus research and diagnostics.

It has previously been observed that the only specific requirement for transcriptional initiation on viral RNA in vitro by the RNA-dependent RNA polymerase (RdRp) of turnip yellow mosaic virus is the CCA at the 3′ end of the genome. We now compare the abilities of this RdRp, turnip crinkle virus RdRp, and Qβ replicase, an enzyme capable of supporting the complete viral replication cycle in vitro, to transcribe RNA templates containing multiple CCA boxes but lacking specific viral sequences. Each enzyme is able to initiate transcription from several CCA boxes within these RNAs, and no special reaction conditions are required for these activities. The transcriptional yields produced from templates comprised of multiple CCA or CCCA repeats relative to templates derived from native viral RNA sequences vary between 2:1 and 0.1:1 for the different RdRps. Control of initiation by such redundant sequences presents a challenge to the specificity of viral transcription and replication. We identify 3′-preferential initiation and sensitivity to structural presentation as two specificity mechanisms that can limit initiation among potential CCA initiation sites. These two specificity mechanisms are used to different degrees by the three RdRps. The finding that three viral RdRps representing two of the three supergroups within the positive-strand RNA viral RdRp phylogeny support substantial transcription in the absence of unique promoters suggests that this phenomenon may be common among positive-strand viruses. A framework is presented arguing that replication of viral RNA in the absence of unique promoter elements is feasible.

20S RNA is a noninfectious viral single-stranded RNA found in most laboratory strains of the yeast Saccharomyces cerevisiae. 20S RNA encodes a protein of 91 kDa (p91) that contains the common motifs found among RNA-dependent RNA polymerases from RNA viruses. p91 and 20S RNA are noncovalently associated in vivo, forming a ribonucleoprotein complex. We detected an RNA polymerase activity in p91/20S RNA complexes isolated by high-speed centrifugation. The activity was not inhibited by actinomycin D nor α-amanitin. The majority of the in vitro products was 20S RNA and the rest was the complementary strands of 20S RNA. Because the extracts were prepared from cells accumulating 20S RNA over its complementary strands, these in vitro products reflect the corresponding activities in vivo. When the p91/20S RNA complexes were subjected to sucrose gradient centrifugation, the polymerase activity cosedimented with the complexes. Furthermore, an RNA polymerase activity was detected in the complex by an antibody-linked polymerase assay using anti-p91 antiserum, suggesting that p91 is present in the active RNA polymerase machinery. These results together indicate that p91 is the RNA-dependent RNA polymerase or a subunit thereof responsible for 20S RNA replication.