Ancient gene duplications in RNA viruses revealed by protein tertiary structure comparisons

Do NSm Virulence Factors in the Bunyavirales Viral Order Originate from Gn Gene Duplication?

One-third of the nine WHO shortlisted pathogens prioritized for research and development in public health emergencies belong to the Bunyavirales order. Several Bunyavirales species carry an NSm protein that acts as a virulence factor. We predicted the structures of these NSm proteins and unexpectedly found that in two families, their cytosolic domain was inferred to have a similar fold to that of the cytosolic domain of the viral envelope-forming glycoprotein N (Gncyto) encoded on the same genome fragment. We show that although the sequence identity between the NSmcyto and the Gncyto domains is low, the conservation of the two zinc finger-forming CysCysHisCys motifs explains the predicted structural conservation. Importantly, our predictions provide a first glimpse into the long-unknown structure of NSm. Also, these predictions suggest that NSm is the result of a gene duplication event in the Bunyavirales Nairoviridae and Peribunyaviridae families and that such events may be common in the recent evolutionary history of RNA viruses.

The more the merrier? Gene duplications in the coevolution of primate lentiviruses with their hosts

Gene duplications are a major source of genetic diversity and evolutionary innovation. Newly formed, duplicated genes can provide a selection advantage in constantly changing environments. One such example is the arms race of HIV and related lentiviruses with innate immune responses of their hosts. In recent years, it has become clear that both sides have benefited from multiple gene duplications. For example, amplifications of antiretroviral factors such as apolipoprotein-B mRNA-editing enzyme catalytic polypeptide-3 (APOBEC3), interferon-induced transmembrane protein (IFITM), and tripartite motif-containing (TRIM) proteins have expanded the repertoire of cell-intrinsic defense mechanisms and increased the barriers to retroviral replication and cross-species transmission. Conversely, recent studies have also shed light on how duplications of accessory lentiviral genes and Long terminal repeat (LTR) elements can provide a selection advantage in the coevolution with antiviral host proteins.

Expansion of viral genomes with viral protein genome linked copies

Virus protein-linked genome (VPg) proteins are required for replication. VPgs are duplicated in a subset of RNA viruses however their roles are not fully understood and the extent of viral genomes containing VPg copies has not been investigated in detail. Here, we generated a novel bioinformatics approach to identify VPg sequences in viral genomes using hidden Markov models (HMM) based on alignments of dicistrovirus VPg sequences. From metagenomic datasets of dicistrovirus genomes, we identified 717 dicistrovirus genomes containing VPgs ranging from a single copy to 8 tandem copies. The VPgs are classified into nine distinct types based on their sequence and length. The VPg types but not VPg numbers per viral genome followed specific virus clades, thus suggesting VPgs co-evolved with viral genomes. We also identified VPg duplications in aquamavirus and mosavirus genomes. This study greatly expands the number of viral genomes that contain VPg copies and indicates that duplicated viral sequences are more widespread than anticipated.

Discovery and Evolution of Six Positive-Sense RNA Viruses Co-infecting the Hypovirulent Strain SCH733 of Sclerotinia sclerotiorum

Sclerotinia sclerotiorum is a well-known phytopathogenic fungus with a wide host range. Identifying novel mycoviruses in phytopathogenic fungi is necessary to develop novel strategies for plant health protection and contribute to understanding the origin of viruses. Six new mycoviruses with positive single-stranded RNA genomes co-infecting the hypovirulent strain SCH733 of S. sclerotiorum were identified using a metatranscriptomic approach, and their complete genome sequences were molecularly determined. These mycoviruses belong to the following five families: Narnaviridae, Mitoviridae, Deltaflexviridae, Botourmiaviridae, and Ambiguiviridae. Three of these mycoviruses belong to existing International Committee on Taxonomy of Viruses (ICTV)-recognized species. Two of these newly identified mycoviruses have unique genomic features that are significantly different from those of all known mycoviruses. Phylogenetic analysis revealed that these six mycoviruses included close as well as distant relatives of known mycoviruses, thereby providing new insight into virus evolution and classification. Mycovirus horizontal transmission and elimination experiments revealed that Sclerotinia sclerotiorum narnavirus 5 is associated with hypovirulence of S. sclerotiorum, although we have not shown that it is independently responsible for the hypovirulence phenotype. This study broadens the diversity of known mycoviruses infecting S. sclerotiorum and provides a clue toward limiting hypovirulence in S. sclerotiorum.

Structural Analysis of Monomeric RNA-Dependent Polymerases Revisited

In the past few years, our understanding of the RNA virosphere has changed dramatically due to the growth and spurt of metagenomics, exponentially increasing the number of RNA viral sequences, and providing a better understanding of their range of potential hosts. As of today, the only conserved protein among RNA viruses appears to be the monomeric RNA-dependent RNA polymerase. This enzyme belongs to the right-hand DNA-and RNA polymerases, which also includes reverse transcriptases and eukaryotic replicative DNA polymerases. The ubiquity of this protein in RNA viruses makes it a unique evolutionary marker and an appealing broad-spectrum antiviral target. In this work pairwise structural comparisons of viral RdRps and RTs were performed, including tertiary structures that have been obtained in the last few years. The resulting phylogenetic tree shows that the RdRps from (+)ss- and dsRNA viruses might have been recruited several times throughout the evolution of mobile genetic elements. RTs also display multiple evolutionary routes. We have identified a structural core comprising the entire palm, a large moiety of the fingers and the N-terminal helices of the thumb domain, comprising over 300 conserved residues, including two regions that we have named the “knuckles” and the “hypothenar eminence”. The conservation of an helix bundle in the region preceding the polymerase domain confirms that (−)ss and dsRNA Reoviruses’ polymerases share a recent ancestor. Finally, the inclusion of DNA polymerases into our structural analyses suggests that monomeric RNA-dependent polymerases might have diverged from B-family polymerases.