Differential Inhibition of Intra- and Inter-molecular Protease Cleavages by Antiviral Compounds

Abstract

ABSTRACTEnteroviruses encode two protease active sites, in the 2A and 3C coding regions. While they target many host proteins, they first need to be excised from the viral polyprotein in which they are embedded. Polyprotein cleavage can occur either intra-molecularly (incis) or inter-molecularly (intrans). Previous work suggested that antivirals targeting intra-molecular cleavages could generate inhibitory precursors that suppress the outgrowth of drug-resistant variants. Therefore, we wanted to evaluate enteroviral cleavage patterns to identify such obligate intra-molecular cleavages for drug target selection. Using translation extracts, we show thatciscleavage of the 2A protease N-terminal junction is conserved across three enteroviruses, while the mechanism for the N-terminal junction of 3C varies, with EV-D68 3C cleavage occurring incisand poliovirus 3C cleavage occurring intrans.Antiviral agents targeting proteases are often identified via their ability to block the cleavage of artificial peptide substrates. Here, we show that antivirals identified for their abilities to block inter-molecular cleavage can sometimes block intra-molecular cleavage of the protease from its polyprotein as well, but with widely varying efficacy. Additionally, we demonstrate that, for three enteroviral species, genomes defective in 2A protease activity suppress the growth of wild-type virus in mixed populations, supporting the hypothesis that preventing intra-molecular cleavage at the VP1·2A junction can create dominantly inhibitory precursors. These data argue that, to reduce the likelihood of drug resistance, protease-targeted antivirals should be evaluated for their ability to block intra-molecular polyprotein cleavages in addition to inter-molecular cleavage of other substrates.IMPORTANCEMost protease-targeted antiviral development evaluates the ability of small molecules to inhibit cleavage of model substrates. However, before they can cleave any other substrates, viral proteases need to cleave themselves from the viral polyprotein in which they have been translated. This can occur either intra- or inter-molecularly. Here, we show that, for poliovirus, Enterovirus D68 and Enterovirus A71, many of these cleavages are required to occur intra-molecularly. Further, we show that antivirals identified for their ability to block cleavage of artificial substrates can also block intra-molecular self-cleavage, but that their efficacy in doing so varies widely. We argue that evaluating candidate antivirals for their ability to block these cleavages is vital to drug development, because the buildup of uncleaved precursors can be inhibitory to the virus and potentially suppress the selection of drug-resistant variants.