1. A novel transposable element-mediated mechanism causes antiviral resistance in Drosophila through truncating the Veneno protein
- Author
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Brosh, Osama, Fabian, Daniel K, Cogni, Rodrigo, Tolosana, Ignacio, Day, Jonathan P, Olivieri, Francesca, Merckx, Manon, Akilli, Nazli, Szkuta, Piotr, Jiggins, Francis M, Fabian, Daniel K [0000-0002-9895-2848], Tolosana, Ignacio [0000-0002-3766-8296], Merckx, Manon [0000-0002-5019-8241], Jiggins, Francis M [0000-0001-7470-8157], and Apollo - University of Cambridge Repository
- Subjects
Drosophila melanogaster ,Tudor Domain ,Gain of Function Mutation ,Host-Pathogen Interactions ,DNA Transposable Elements ,Dicistroviridae ,Animals ,Drosophila ,adaptation ,virus ,transposable element ,Sequence Deletion - Abstract
Hosts are continually selected to evolve new defenses against an ever-changing array of pathogens. To understand this process, we examined the genetic basis of resistance to the Drosophila A virus in Drosophila melanogaster. In a natural population, we identified a polymorphic transposable element (TE) insertion that was associated with an ∼19,000-fold reduction in viral titers, allowing flies to largely escape the harmful effects of infection by this virulent pathogen. The insertion occurs in the protein-coding sequence of the gene Veneno, which encodes a Tudor domain protein. By mutating Veneno with CRISPR-Cas9 in flies and expressing it in cultured cells, we show that the ancestral allele of the gene has no effect on viral replication. Instead, the TE insertion is a gain-of-function mutation that creates a gene encoding a novel resistance factor. Viral titers remained reduced when we deleted the TE sequence from the transcript, indicating that resistance results from the TE truncating the Veneno protein. This is a novel mechanism of virus resistance and a new way by which TEs can contribute to adaptation.
- Published
- 2022