Comparative analysis of Panicum streak virus and Maize streak virus diversity, recombination patterns and phylogeography

Background: Panicum streak virus (PanSV; Family Geminiviridae; Genus Mastrevirus) is a close relative of Maize streak virus (MSV), the most serious viral threat to maize production in Africa. PanSV and MSV have the same leafhopper vector species, largely overlapping natural host ranges and similar geographical distributions across Africa and its associated Indian Ocean Islands. Unlike MSV, however, PanSV has no known economic relevance. Results: Here we report on 16 new PanSV full genome sequences sampled throughout Africa and use these together with others in public databases to reveal that PanSV and MSV populations in general share very similar patterns of genetic exchange and geographically structured diversity. A potentially important difference between the species, however, is that the movement of MSV strains throughout Africa is apparently less constrained than that of PanSV strains. Interestingly the MSV-A strain which causes maize streak disease is apparently the most mobile of all the PanSV and MSV strains investigated. Conclusion: We therefore hypothesize that the generally increased mobility of MSV relative to other closely related species such as PanSV, may have been an important evolutionary step in the eventual emergence of MSV-A as a serious agricultural pathogen. The GenBank accession numbers for the sequences reported in this paper are GQ415386-GQ415401. © 2009 Varsani et al; licensee BioMed Central Ltd

The phylogenetics of the global population of potato virus Y and its necrogenic recombinants

Potato virus Y (PVY) is a major pathogen of potatoes and other solanaceous crops worldwide. It is most closely related to potyviruses first or only found in the Americas, and it almost certainly originated in the Andes, where its hosts were domesticated. We have inferred the phylogeny of the published genomic sequences of 240 PVY isolates collected since 1938 worldwide, but not the Andes. All fall into five groupings, which mostly, but not exclusively, correspond with groupings already devised using biological and taxonomic data. Only 42 percent of the sequences are not recombinant, and all these fall into one or other of three phylogroups; the previously named C (common), O (ordinary), and N (necrotic) groups. There are also two other distinct groups of isolates all of which are recombinant; the R-1 isolates have N (5' terminal minor) and O (major) parents, and the R-2 isolates have R-1 (major) and N (3' terminal minor) parents. Many isolates also have additional minor intra- and inter-group recombinant genomic regions. The complex interrelationships between the genomes were resolved by progressively identifying and removing recombinants using partitioned sequences of synonymous codons. Least squared dating and BEAST analyses of two datasets of gene sequences from non-recombinant heterochronously-sampled isolates (seventy-three non-recombinant major ORFs and 166 partial ORFs) found the 95% confidence intervals of the TMRCA estimates overlap around 1,000 CE (Common Era; AD). We attempted to identify the most accurate datings by comparing the estimated phylogenetic dates with historical events in the worldwide adoption of potato and other PVY hosts as crops, but found that more evidence from gene sequences of non-potato isolates, especially from South America, was required

Phylodynamic Reconstruction Reveals Norovirus GII.4 Epidemic Expansions and their Molecular Determinants

Noroviruses are the most common cause of viral gastroenteritis. An increase in the number of globally reported norovirus outbreaks was seen the past decade, especially for outbreaks caused by successive genogroup II genotype 4 (GII.4) variants. Whether this observed increase was due to an upswing in the number of infections, or to a surveillance artifact caused by heightened awareness and concomitant improved reporting, remained unclear. Therefore, we set out to study the population structure and changes thereof of GII.4 strains detected through systematic outbreak surveillance since the early 1990s. We collected 1383 partial polymerase and 194 full capsid GII.4 sequences. A Bayesian MCMC coalescent analysis revealed an increase in the number of GII.4 infections during the last decade. The GII.4 strains included in our analyses evolved at a rate of 4.3–9.0×10−3 mutations per site per year, and share a most recent common ancestor in the early 1980s. Determinants of adaptation in the capsid protein were studied using different maximum likelihood approaches to identify sites subject to diversifying or directional selection and sites that co-evolved. While a number of the computationally determined adaptively evolving sites were on the surface of the capsid and possible subject to immune selection, we also detected sites that were subject to constrained or compensatory evolution due to secondary RNA structures, relevant in virus-replication. We highlight codons that may prove useful in identifying emerging novel variants, and, using these, indicate that the novel 2008 variant is more likely to cause a future epidemic than the 2007 variant. While norovirus infections are generally mild and self-limiting, more severe outcomes of infection frequently occur in elderly and immunocompromized people, and no treatment is available. The observed pattern of continually emerging novel variants of GII.4, causing elevated numbers of infections, is therefore a cause for concern

Molecular signals of arms race evolution between RNA viruses and their hosts

Viruses are intracellular parasites that hijack their hosts’ cellular machinery to replicate themselves. This creates an evolutionary “arms race” between hosts and viruses, where the former develop mechanisms to restrict viral infection and the latter evolve ways to circumvent these molecular barriers. In this thesis, I explore examples of this virus-host molecular interplay, focusing on events in the evolutionary histories of both viruses and hosts. The thesis begins by examining how recombination, the exchange of genetic material between related viruses, expands the genomic diversity of the Sarbecovirus subgenus, which includes SARS-CoV responsible for the 2002 SARS epidemic and SARS-CoV-2 responsible for the COVID-19 pandemic. On the host side, I examine the evolutionary interaction between RNA viruses and two interferon-stimulated genes expressed in hosts. First, I show how the 2′-5′-oligoadenylate synthetase 1 (OAS1) gene of horseshoe bats (Rhinolophoidea), the reservoir host of sarbecoviruses, lost its anti-coronaviral activity at the base of this bat superfamily. By reconstructing the Rhinolophoidea common ancestor OAS1 protein, I first validate the loss of antiviral function and highlight the implications of this event in the virus-host association between sarbecoviruses and horseshoe bat hosts. Second, I focus on the evolution of the human butyrophilin subfamily 3 member A3 (BTN3A3) gene which restricts infection by avian influenza A viruses (IAV). The evolutionary analysis reveals that BTN3A3’s anti-IAV function was gained within the primates and that specific amino acid substitutions need to be acquired in IAVs’ NP protein to evade the human BTN3A3 activity. Gain of BTN3A3-evasion-conferring substitutions correlate with all major human IAV pandemics and epidemics, making these NP residues key markers for IAV transmissibility potential to humans. In the final part of the thesis, I present a novel approach for evaluating dinucleotide compositional biases in virus genomes. An application of my metric on the Flaviviridae virus family uncovers how ancestral host shifts of these viruses correlate with adaptive shifts in their genomes’ dinucleotide representation. Collectively, the contents of this thesis extend our understanding of how viruses interact with their hosts along their intertangled evolution and provide insights into virus host switching and pandemic preparedness