Interplay between the Poly(A) Tail, Poly(A)-Binding Protein, and Coronavirus Nucleocapsid Protein Regulates Gene Expression of Coronavirus and the Host Cell

In the present study, we investigated the roles of interactions among the poly(A) tail, coronavirus nucleocapsid (N) protein, and poly(A)-binding protein (PABP) in the regulation of coronavirus gene expression. Through dissociation constant (k(d)) comparison, we found that the coronavirus N protein can bind to the poly(A) tail with high affinity, establishing N protein as a PABP. A subsequent analysis with UV cross-linking and immunoprecipitation revealed that the N protein is able to bind to the poly(A) tail in infected cells. Further examination demonstrated that poly(A) tail binding by the N protein negatively regulates translation of coronaviral RNA and host mRNA both in vitro and in cells. Although the N protein can interact with PABP and eukaryotic initiation factor 4G (eIF4G), the poor interaction efficiency between the poly(A)-bound N protein and elF4E may explain the observed decreased translation efficiency. In addition to interaction with translation factor elF4G, the N protein is able to interact with coronavirus nonstructural protein 9 (nsp9), a replicase protein required for replication. The study demonstrates interactions among the poly(A) tail, N protein, and PABP both in vitro and in infected cells. Of the interactions, binding of the poly(A) tail to N protein decreases the interaction efficiency between the poly(A) tail and elF4E, leading to translation inhibition. The poly(A)-dependent translation inhibition by N protein has not been previously demonstrated and thus extends our understanding of coronavirus gene expression. IMPORTANCE Gene expression in coronavirus is a complicated and dynamic process. In this study, we demonstrated that coronavirus N protein is able to bind to the poly(A) tail with high affinity, establishing N protein as a PABP. We also show how the interplay between coronavirus 3' poly(A) tail, PABP, and N protein regulates gene expression of the coronavirus and host cell. Of the interactions, poly(A) tail binding by the N protein negatively regulates translation, and to our knowledge, this inhibition of translation by binding of the N protein to poly(A) tail has not been previously studied. Accordingly, the study provides fundamental molecular details regarding coronavirus infection and expands our knowledge of coronavirus gene expression.