ABSTRACT
The rotavirus (RV) VP4 spike protrudes as a trimeric structure from the five-fold axes of the virion triple-layer. Infectious RV particles need to be proteolytically cleaved in VP4 into two subunits, VP8* and VP5*, constituting both the distal part and central body of the virus spike. Modification of VP4 has been challenging as it is involved in biological process including the interaction with sialic acid and integrins, cell tropism and hemagglutinin activity. Here, we engineered a loop at position K145-G150 in the lectin domain of the VP8* subunit to harbor a small biotin acceptor peptide (BAP) tag and rescued viable viral particles using RV reverse genetics system. This rRV/VP4-BAP internalizes, replicates, and generates virus progeny, demonstrating that the VP4 spike of RV particles can be genetically manipulated by the incorporation of at least 15 exogenous amino acids. Although, VP4-BAP had a similar distribution as VP4 in infected cells by localizing in the cytoskeleton and surrounding viroplasms. However, compared to wild-type RV, rRV/VP4-BAP featured a reduced replication fitness and impaired viroplasm stability. Upon treatment of viroplasms with 1,6-hexanediol, a drug disrupting liquid-liquid phase-separated condensates, the kinetic of rRV/VP4-BAP viroplasm recovery was delayed, and their size and numbers reduced when compared to viroplasms of wild type RV. Moreover, siRNA silencing of VP4 expression in RV strain SA11 showed similar recovery patterns as rRV/VP4-BAP, revealing a novel function of VP4 in viroplasm stability.
IMPORTANCE The rotavirus (RV) spike protein, VP4, has a relevant role in several steps involving virion internalization. The strategic position of VP4 in the virion resulted in a challenge for the addition of an exogenous peptide producing infectious particles. The identification of a specific loop in position K145-G150 in the VP8* subunit of VP4 allowed the rescue by RV reverse genetics of a recombinant RV harboring VP4 containing a 15 amino acids tag. This study demonstrates this recombinant virus has similar replication properties as a wild-type virus. Moreover, we also discovered that VP4 is necessary for the assembly and stabilization of the cytosolic replication compartments, the viroplasms, demonstrating a novel role of this protein in the RV life cycle.
Footnotes
↵1 Author Contributions: GP and JV contributed equally to this work.