Zika virus dumbbell-1 structure is critical for sfRNA presence and cytopathic effect during infection

Abstract

Zika virus (ZIKV) contains multiple conserved RNA structures in the viral 3’ untranslated region (UTR), including the structure known as dumbbell-1 (DB-1). Previous research has shown that the DB-1 structure is important for flavivirus genome replication and cytopathic effect (CPE). However, the role of the DB structure and the mechanism by which it contributes to viral pathogenesis is not known. Using recently solved flavivirus DB RNA structural data, we designed two DB-1 mutant ZIKV infectious clones termed ZIKV-TL.PK, which disrupts DB-1 tertiary folding and ZIKV-p.2.5’, which alters DB-1 secondary structure formation. In cell culture, we found that viral genome replication of both mutant clones is not significantly affected compared to ZIKV-WT, but viral CPE is considerably decreased. We investigated sub-genomic flaviviral RNA (sfRNA) formation by both DB-1 mutants following A549 infection and found both mutant clones have decreased levels of all sfRNA species compared to ZIKV-WT during infection. To investigate the mechanism of decreased CPE in our DB-1 mutant clones, we assayed ZIKV DB mutant-infected A549 cells for cell viability and caspase activation. We found that cell viability is significantly increased in DB-1 mutant-infected cells compared to ZIKV-WT due to reduced caspase 3 activation. We also show that replication of the ZIKV-P.2.5’ mutant was significantly restricted by type I interferon treatment without altering interferon stimulated gene expression. Using a murine model of ZIKV infection, we show that both ZIKV-DB-1 mutants exhibit reduced morbidity and mortality compared to ZIKV-WT virus due to tissue specific attenuation in ZIKV-DB viral replication in the brain tissue. Overall, our data show that the flavivirus DB-1 RNA structure is important for maintaining sfRNA levels during infection which supports caspase-3 dependent, viral cytopathic effect, type 1 interferon resistance, and viral pathogenesis in a mouse model.