Production of Noncapped Genomic RNAs is Critical to Sindbis Virus Disease and Pathogenicity

Alphaviruses are positive-sense RNA viruses that utilize a 5’ cap structure to facilitate translation of viral proteins and to protect the viral RNA genome. Nonetheless, significant quantities of viral genomic RNAs that lack a canonical 5’ cap structure are produced during alphaviral replication and packaged into viral particles. However, the role/impact of the noncapped genomic RNA (ncgRNA) during alphaviral infection in vivo has yet to be characterized. To determine the importance of the ncgRNA in vivo, the previously described D355A and N376A nsP1 mutations, which increase or decrease nsP1 capping activity respectively, were incorporated into the neurovirulent AR86 strain of Sindbis virus to enable characterization of the impact of altered capping efficiency in a murine model of infection. Mice infected with the N376A nsP1 mutant exhibited slightly decreased rates of mortality and delayed weight loss and neurological symptoms, although levels of inflammation in the brain were similar to wild type infection. The mice infected with the D355A nsP1 mutant showed significantly reduced mortality and morbidity compared to mice infected with wild type virus. Interestingly, both capping mutants had roughly equivalent viral titer in the brain compared to wild type virus, illustrating that the changes in mortality were not due to deficits in viral replication or dissemination. Examination of the brain tissue revealed that mice infected with the D355A capping mutant had significantly reduced cell death and immune cell infiltration compared to the N376A mutant and wild type virus. Finally, expression of proinflammatory cytokines was found to be significantly decreased in mice infected with the D355A mutant, suggesting that capping efficiency and the production of ncgRNA are vital to eliciting pathogenic levels of inflammation. Collectively, these data indicate that the ncgRNA have important roles during alphaviral infection and suggest a novel mechanism by which noncapped viral RNA aid in viral pathogenesis.