Abstract
The interplay of different virus species in a host cell after infection can affect the adaptation of each virus. Endogenous viral elements, such as endogenous pararetroviruses (PRVs), have arisen from vertical inheritance of viral sequences integrated into host germline genomes. As viral genomic fossils, these sequences can thus serve as valuable paleogenomic data to study the long-term evolutionary dynamics of virus–virus interactions, but they have rarely been applied for this purpose. All extant PRVs have been considered autonomous species in their parasitic life cycle in host cells. Here, we provide evidence for multiple non-autonomous PRV species with structural defects in viral activity that have frequently infected ancient grass hosts and adapted through interplay between viruses. Our paleogenomic analyses using endogenous PRVs in grass genomes revealed that these non-autonomous PRV species have participated in interplay with autonomous PRVs in a possible commensal partnership, or, alternatively, with one another in a possible mutualistic partnership. These partnerships, which have been established by the sharing of noncoding regulatory sequences (NRSs) in intergenic regions between two partner viruses, have been further maintained and altered by the sequence homogenization of NRSs between partners. Strikingly, we found that frequent region-specific recombination, rather than mutation selection, is the main causative mechanism of NRS homogenization. Our results, obtained from ancient DNA records of viruses, suggest that adaptation of PRVs has occurred by concerted evolution of NRSs between different virus species in the same host. Our findings further imply that evaluation of within-host NRS interactions within and between populations of viral pathogens may be important.
Highlights
Similar to virus–host interactions, virus–virus interactions, especially those occurring during mixed plant virus infections in nature, have complex outcomes ranging from antagonism to synergism [1, 2]
A BLAST search for the SFKTE domain sequence in the O. sativa genome identified 15 loci (e-value < 4.00 × 10−44) that have recently been annotated as endogenous PRVs similar to petunia vein clearing virus (PVCV) sequences; these PRVs are hereafter referred to as endogenous PVCV-like (Fig 2A; [18])
Three predicted essential domains (MP, capsid protein (CP), and PR) were confirmed by conserved motif alignment, but the reverse transcriptase with RNase H activity (RT/RH) domain indispensable for replication was not detected in endogenous RTBV-like 2 (eRTBVL2) or endogenous PVCV-like (ePVCVL) (S2 Table and S4 Fig)
Summary
Similar to virus–host interactions, virus–virus interactions, especially those occurring during mixed plant virus infections in nature, have complex outcomes ranging from antagonism to synergism [1, 2]. In addition to EVEs derived from retroviruses, EVEs originating from viruses without active reverse-transcription or integration abilities have been identified [4, 7,8,9,10] Because these elements are vertically inherited viral sequences integrated into the germline genome of a host, they are viral genomic fossils and serve as invaluable historical records [3, 11, 12]. EVEs may provide an unprecedented opportunity to advance our understanding of evolutionary-scale virus–virus interactions, these records have rarely been exploited to explore such interactions
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
