Flavivirus genome recoding by codon optimisation confers genetically stable in vivo attenuation in both mice and mosquitoes.

Virus genome recoding is an attenuation method that confers genetically stable attenuation by rewriting a virus genome with numerous silent mutations. Prior flavivirus genome recoding attempts utilised codon deoptimisation approaches. However, these codon deoptimisation approaches act in a species dependent manner and were unable to confer flavivirus attenuation in mosquito cells or in mosquito animal models. To overcome these limitations, we performed flavivirus genome recoding using the contrary approach of codon optimisation. The genomes of flaviviruses such as dengue virus type 2 (DENV2) and Zika virus (ZIKV) contain functional RNA elements that regulate viral replication. We hypothesised that flavivirus genome recoding by codon optimisation would introduce silent mutations that disrupt these RNA elements, leading to decreased replication efficiency and attenuation. We chose DENV2 and ZIKV as representative flaviviruses and recoded them by codon optimising their genomes for human expression. Our study confirms that this recoding approach of codon optimisation does translate into reduced replication efficiency in mammalian, human, and mosquito cells as well as in vivo attenuation in both mice and mosquitoes. In silico modelling and RNA SHAPE analysis confirmed that DENV2 recoding resulted in the extensive disruption of genomic structural elements. Serial passaging of recoded DENV2 resulted in the emergence of rescue or adaptation mutations, but no reversion mutations. These rescue mutations were unable to rescue the delayed replication kinetics and in vivo attenuation of recoded DENV2, demonstrating that recoding confers genetically stable attenuation. Therefore, our recoding approach is a reliable attenuation method with potential applications for developing flavivirus vaccines.

Betulinic acid exhibits antiviral effects against dengue virus infection.

Dengue virus (DENV) is an arthropod-borne virus that has developed into a prominent global health threat in recent decades. The main causative agent of dengue fever, the virus infects an estimated 390 million individuals across the globe each year. Despite the sharply increasing social and economic burden on global society caused by the disease, there is still a glaring lack of effective therapeutics against DENV. In this study, betulinic acid, a naturally occurring pentacyclic triterpenoid was established as an inhibitor of DENV infection in vitro. Time-course studies revealed that betulinic acid inhibits a post-entry stage of the DENV replication cycle and subsequent analyses also showed that the compound is able to inhibit viral RNA synthesis and protein production. Betulinic acid also demonstrated antiviral efficacy against other serotypes of DENV, as well as against other mosquito-borne RNA viruses such as Zika virus and Chikungunya virus, which are commonly found co-circulating together with DENV. As such, betulinic acid may serve as a valuable starting point for the development of antivirals to combat potential DENV outbreaks, particularly in tropical and subtropical regions which make up a large majority of documented infections.