Abstract
Rotaviruses (RVs) are nonenveloped viruses that cause gastroenteritis in infants and young children. Sialic acid is an initial receptor, especially for animal RVs, including rhesus RV. Sialic acid binds to the VP8* subunit, a part of the outer capsid protein VP4 of RV. Although interactions between virus and glycan receptors influence tissue and host tropism and viral pathogenicity, research has long been limited to biochemical and structural studies due to the unavailability of an RV reverse genetics system. Here, we examined the importance of sialic acid in RV infections using recombinant RVs harboring mutations in sialic acid-binding sites in VP4 via a simian RV strain SA11-based reverse genetics system. RV VP4 mutants that could not bind to sialic acid had replicated to decreased viral titer in MA104 cells. Wild-type virus infectivity was reduced, while that of VP4 mutants was not affected in sialic acid-deficient cells. Unexpectedly, in vivo experiments demonstrated that VP4 mutants suppressed mouse pups' weight gain and exacerbated diarrhea symptoms compared to wild-type viruses. Intestinal contents enhanced VP4 mutants' infectivity. Thus, possibly via interactions with other unknown receptors and/or intestinal contents, VP4 mutants are more likely than wild-type viruses to proliferate in the murine intestine, causing diarrhea and weight loss. These results suggest that RVs binding sialic acid notably affect viral infection in vitro and viral pathogenesis in vivo. IMPORTANCE Various studies have been conducted on the binding of VP8* and glycans, and the direct interaction between purified VP8* and glycans has been investigated by crystalline structure analyses. Here, we used a reverse genetics system to generate rotaviruses (RVs) with various VP4 mutants. The generated mutant strains clarified the importance of glycan binding in vitro and in vivo. Moreover, even when VP4 mutants could not bind to sialic acid, they were able to bind to an unknown receptor. As RVs evolve, pathogenicity can also be modified by easily altering the glycans to which VP4 binds.