A key survival strategy of RNA viruses is their ability to populate a diverse sequence space that creates a 'cloud' of potentially beneficial mutations at the population level affording the viral quasispecies a greater probability of evolving and adapting to new environments and challenges during infection. One established mechanism relies on high mutation rates of viral RNA replication. It is becoming increasingly clear that an additional mechanism to expand and retain genetic diversity relies on RNA recombination that enables exchange of genetic material between RNA viruses. Furthermore, these recombination mechanisms may provide viruses with two advantages: (i) purge their genomes of accumulated deleterious changes and (ii) create or spread beneficial combinations of mutations in an efficient manner. Despite its importance, the mechanism of viral recombination is poorly understood. Genetic experiments have suggested that homologous RNA recombination occurs by dissociation of the RNA-dependent RNA polymerase and nascent RNA strand before replication completes, and the re-association of that nascent strand-polymerase complex with another template. However, this mechanism remains largely untested. We propose to combine genetics, biochemistry and ultra-deep sequencing approaches with classical virology experiments in cell culture and animal models to define the mechanism of viral recombination and determine its role in virus evolution and pathogenesis. A central hypothesis in this application is that RNA recombination plays a critical role in the generation of virus diversity and evolution and is critial for viral fitness and pathogenesis.
We have developed a platform that combines genetics, biochemical and computational approaches to examine the role of recombination on the evolution of RNA virus. The integration of recombination defective variants, experimental and computational tools will allow liking recombination rates on the ability of a virus population to evolve and adapt to various selective pressures, including in infected animals. This may allow better mechanistic understanding of the recombination process, as well as the role of recombination in evolution and adaptation.
Dolan, Patrick T; Whitfield, Zachary J; Andino, Raul (2018) Mapping the Evolutionary Potential of RNA Viruses. Cell Host Microbe 23:435-446 |
Lidsky, Peter V; Lukyanov, Konstantin A; Misra, Tvisha et al. (2018) A genetically encoded fluorescent probe for imaging of oxygenation gradients in living Drosophila. Development 145: |
Geller, Ron; Pechmann, Sebastian; Acevedo, Ashley et al. (2018) Hsp90 shapes protein and RNA evolution to balance trade-offs between protein stability and aggregation. Nat Commun 9:1781 |
Xiao, Yinghong; Dolan, Patrick Timothy; Goldstein, Elizabeth Faul et al. (2017) Poliovirus intrahost evolution is required to overcome tissue-specific innate immune responses. Nat Commun 8:375 |
Lidsky, Peter V; Andino, Raul; Rouzine, Igor M (2017) Variability in viral pathogenesis: modeling the dynamic of acute and persistent infections. Curr Opin Virol 23:120-124 |
Menéndez-Arias, Luis; Andino, Raul (2017) Viral polymerases. Virus Res 234:1-3 |
Whitfield, Zachary J; Dolan, Patrick T; Kunitomi, Mark et al. (2017) The Diversity, Structure, and Function of Heritable Adaptive Immunity Sequences in the Aedes aegypti Genome. Curr Biol 27:3511-3519.e7 |
Stern, Adi; Yeh, Ming Te; Zinger, Tal et al. (2017) The Evolutionary Pathway to Virulence of an RNA Virus. Cell 169:35-46.e19 |
Andino, Raul; Diamond, Michael (2017) Editorial overview: Viral pathogenesis: Strategies for virus survival - Acute versus persistent infections. Curr Opin Virol 23:v |
Xiao, Yinghong; Rouzine, Igor M; Bianco, Simone et al. (2017) RNA Recombination Enhances Adaptability and Is Required for Virus Spread and Virulence. Cell Host Microbe 22:420 |
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