| Q31926237 | Analysis on distribution of insertion sequence IS431 in clinical isolates of staphylococci |
| Q92690126 | Biphasic regulation of RNA interference during rotavirus infection by modulation of Argonaute2 |
| Q39848740 | Close relationship between G8-serotype bovine and human rotaviruses isolated in Nigeria |
| Q40809736 | Complete nucleotide sequence of a group A avian rotavirus genome and a comparison with its counterparts of mammalian rotaviruses |
| Q30657684 | Construction of an infectious cDNA clone of Aichi virus (a new member of the family Picornaviridae) and mutational analysis of a stem-loop structure at the 5' end of the genome |
| Q36707759 | Coupling of rotavirus genome replication and capsid assembly. |
| Q34454764 | Detection of a human rotavirus with G12 and P[9] specificity in Thailand |
| Q43406052 | Determinants of rotavirus host range restriction--a heterologous bovine NSP1 gene does not affect replication kinetics in the pig. |
| Q33850456 | Effect of intragenic rearrangement and changes in the 3' consensus sequence on NSP1 expression and rotavirus replication |
| Q40352768 | Entirely plasmid-based reverse genetics system for rotaviruses |
| Q47930114 | Functional analysis of the heterologous NSP1 genes in the genetic background of simian rotavirus SA11. |
| Q36827184 | Generation of genetically stable recombinant rotaviruses containing novel genome rearrangements and heterologous sequences by reverse genetics. |
| Q54232991 | Generation of recombinant rotaviruses expressing fluorescent proteins using an optimized reverse genetics system. |
| Q96768837 | Generation of recombinant rotaviruses from just 11 cDNAs encoding a viral genome |
| Q42238618 | Genome rearrangement of a mycovirus Rosellinia necatrix megabirnavirus 1 affecting its ability to attenuate virulence of the host fungus. |
| Q113500758 | II, 4. Rotavirus genome replication: role of the RNA-binding proteins |
| Q42288582 | Identification of mutations in the genome of rotavirus SA11 temperature-sensitive mutants D, H, I and J by whole genome sequences analysis and assignment of tsI to gene 7 encoding NSP3. |
| Q47916655 | In vivo interactions among rotavirus nonstructural proteins. |
| Q39684543 | Interferon regulatory factor 3 is a cellular partner of rotavirus NSP1. |
| Q41490815 | Intragenic rearrangements of a mycoreovirus induced by the multifunctional protein p29 encoded by the prototypic hypovirus CHV1-EP713. |
| Q47222641 | MHC class I expression in intestinal cells is reduced by rotavirus infection and increased in bystander cells lacking rotavirus antigen |
| Q82226368 | Mycoreovirus 1 S4-coded protein is dispensable for viral replication but necessary for efficient vertical transmission and normal symptom induction |
| Q40920445 | Open reading frame in rotavirus mRNA specifically promotes synthesis of double-stranded RNA: template size also affects replication efficiency. |
| Q43079549 | Permissive replication of homologous murine rotavirus in the mouse intestine is primarily regulated by VP4 and NSP1. |
| Q40223856 | Post-translational regulation of rotavirus protein NSP1 expression in mammalian cells. |
| Q42628589 | Rearrangement generated in double genes, NSP1 and NSP3, of viable progenies from a human rotavirus strain |
| Q37428960 | Reassortment in segmented RNA viruses: mechanisms and outcomes |
| Q28743106 | Reconciliation of rotavirus temperature-sensitive mutant collections and assignment of reassortment groups D, J, and K to genome segments |
| Q33785214 | Reovirus growth in cell culture does not require the full complement of viral proteins: identification of a sigma1s-null mutant. |
| Q28768094 | Reverse genetics system for introduction of site-specific mutations into the double-stranded RNA genome of infectious rotavirus |
| Q41998682 | Roles of VP4 and NSP1 in determining the distinctive replication capacities of simian rotavirus RRV and bovine rotavirus UK in the mouse biliary tract |
| Q114370943 | Rotavirus Induces Epithelial-Mesenchymal Transition Markers by Transcriptional Suppression of miRNA-29b |
| Q21090517 | Rotavirus NSP1 inhibits NFkappaB activation by inducing proteasome-dependent degradation of beta-TrCP: a novel mechanism of IFN antagonism |
| Q24311932 | Rotavirus NSP1 inhibits interferon induced non-canonical NFκB activation by interacting with TNF receptor associated factor 2 |
| Q114370948 | Rotavirus NSP1 localizes in the nucleus to disrupt PML nuclear bodies during infection |
| Q35260141 | Rotavirus antagonism of the innate immune response |
| Q38834140 | Rotavirus disrupts cytoplasmic P bodies during infection |
| Q38996491 | Rotavirus inhibits IFN-induced STAT nuclear translocation by a mechanism that acts after STAT binding to importin-α. |
| Q24555785 | Rotavirus nonstructural protein 1 subverts innate immune response by inducing degradation of IFN regulatory factor 3 |
| Q24610030 | Rotavirus nonstructural protein 1 suppresses virus-induced cellular apoptosis to facilitate viral growth by activating the cell survival pathways during early stages of infection |
| Q36525406 | Rotavirus variant replicates efficiently although encoding an aberrant NSP3 that fails to induce nuclear localization of poly(A)-binding protein |
| Q24338301 | Rotavirus-encoded nonstructural protein 1 modulates cellular apoptotic machinery by targeting tumor suppressor protein p53 |
| Q42666593 | Sequence analysis demonstrates that VP6, NSP1 and NSP4 genes of Indian neonatal rotavirus strain 116E are of human origin |
| Q34958018 | Serologic and genomic characterization of a G12 human rotavirus in Thailand |
| Q37083338 | Silencing the alarms: Innate immune antagonism by rotavirus NSP1 and VP3 |
| Q41335189 | Structure and function of rotavirus NSP1. |
| Q28067379 | The Rotavirus Interferon Antagonist NSP1: Many Targets, Many Questions |
| Q40673569 | Translational regulation of rotavirus gene expression |
| Q37248029 | Variation in antagonism of the interferon response to rotavirus NSP1 results in differential infectivity in mouse embryonic fibroblasts |
| Q38377768 | Whole genomic analysis of bovine group A rotavirus strains A5-10 and A5-13 provides evidence for close evolutionary relationship with human rotaviruses |
| Q28284962 | Zinc-binding domain of rotavirus NSP1 is required for proteasome-dependent degradation of IRF3 and autoregulatory NSP1 stability |