Abstract
BACKGROUND: The mechanism by which coronavirus-defective viral genomes (DVGs) affect coronavirus and host cells during infection remains unclear. A variety of DVGs with different RNA structures can be synthesized from coronavirus-infected cells, and these DVGs can also encode proteins. Consequently, in the present study, we first dissected the effects of individual DVGs on the synthesis of IFNβ and ISG15 mRNAs at the RNA, protein and combined levels, and then examined whether different coronavirus-DVGs have different effects on the synthesis of IFNβ and ISG15 mRNAs and coronavirus replication both individually and collectively under different infection conditions. METHODS: To dissect the effects of individual DVGs on the synthesis of IFNβ and ISG15 mRNAs at the RNA, protein and combined levels, DVG 2.2 and DVG 5.1, which were previously identified in coronavirus-infected cells, and their mutants were constructed followed by transfection. Western blot and RT‒qPCR were used to detect the synthesis of protein and to quantify the synthesis of IFNβ and ISG15 mRNAs, respectively. To examined whether different coronavirus-DVGs have different effects on the synthesis of IFNβ and ISG15 mRNAs and coronavirus replication both individually and collectively under different infection conditions, different naturally occurring DVGs were selected and constructed followed by transfection after or before coronavirus infection and by RT‒qPCR and hemagglutination assay. RESULTS: These results suggested that (i) coronavirus-DVGs at the RNA, protein and combined levels have different effects on the synthesis of IFNβ and ISG15 mRNAs, (ii) coronavirus-DVGs can inhibit coronavirus replication at least partly through interferon signaling and (iii) different DVGs have different effects on the synthesis of IFNβ and ISG15 mRNAs and coronavirus replication both individually and collectively under different infection conditions. CONCLUSIONS: Coronavirus replication can be regulated by diverse coronavirus-derived DVGs at least partly through innate immunity. Such regulation may contribute to the pathogenesis of coronavirus. The DVG populations in coronavirus-infected cells with the ability to inhibit coronavirus replication are expected to be potential resources for the identification of antivirals at the level of RNA, protein or in combination, and the methods used in the current study can be used as a platform for this purpose.