NSP1

About: NSP1 is a research topic. Over the lifetime, 248 publications have been published within this topic receiving 12044 citations.

Structural basis for translational shutdown and immune evasion by the Nsp1 protein of SARS-CoV-2

Abstract: SARS-CoV-2 is the causative agent of the current COVID-19 pandemic. A major virulence factor of SARS-CoVs is the nonstructural protein 1 (Nsp1) which suppresses host gene expression by ribosome association via an unknown mechanism. Here, we show that Nsp1 from SARS-CoV-2 binds to 40S and 80S ribosomes, resulting in shutdown of capped mRNA translation both in vitro and in cells. Structural analysis by cryo-electron microscopy (cryo-EM) of in vitro reconstituted Nsp1-40S and of native human Nsp1-ribosome complexes revealed that the Nsp1 C-terminus binds to and obstructs the mRNA entry tunnel. Thereby, Nsp1 effectively blocks RIG-I-dependent innate immune responses that would otherwise facilitate clearance of the infection. Thus, the structural characterization of the inhibitory mechanism of Nsp1 may aid structure-based drug design against SARS-CoV-2.

Rotavirus nonstructural protein 1 subverts innate immune response by inducing degradation of IFN regulatory factor 3.

Abstract: IFN regulatory factor 3 (IRF3), a constitutively expressed protein localizing largely to the cytoplasm, is a primary effector of the innate immune response. Infection can trigger the phosphorylation, dimerization, and nuclear translocation of IRF3, where the factor stimulates the expression and release of IFN. In this study, we determined that the rotavirus gene 5 product, nonstructural protein 1 (NSP1), interacts with IRF3 in the infected cell. To understand the importance of the interaction, we compared IRF3 activation by rotaviruses expressing wild-type and C-truncated forms of NSP1. The analysis showed that IRF3 underwent dimerization and nuclear translocation and stimulated IFN promoter activity in infected cells expressing truncated NSP1. In contrast, infected cells expressing wild-type NSP1 were characterized by the rapid degradation of IRF3 during the replication cycle, severe decreases in IRF3 dimerization and nuclear translocation, and lack of IFN promoter activity. The implication of these results, that wild-type NSP1 is an antagonist of the IFN-signaling pathway, was confirmed in transient expression assays, which showed that wild-type NSP1, but not the C-truncated protein, induced the degradation of IRF3 fusion proteins. Related experiments indicated that NSP1 mediates IRF3 degradation through a proteasome-dependent pathway. The critical role of NSP1 in promoting cell-to-cell spread of rotavirus was demonstrated by using gene 5-specific short interfering RNAs in plaque assays. Although several viruses have been described that subvert the innate immune response by preventing IRF3 activation, rotavirus is identified as one that accomplishes this task by inducing the degradation of IRF3.

Processing the nonstructural polyproteins of Sindbis virus: nonstructural proteinase is in the C-terminal half of nsP2 and functions both in cis and in trans

Abstract: The processing of the Sindbis virus nonstructural polyprotein translated in vitro has been studied. When Sindbis virus genomic RNA was translated in a reticulocyte lysate, polyprotein P123 was cleaved efficiently to produce nsP1, nsP2, and nsP3. Inhibition of this processing by anti-nsP2 antibodies, but not by antibodies specific for nsP1, nsP3, or nsP4, suggested that the viral proteinase was present in nsP2. To localize the proteolytic activity more precisely, deletions were made in a full-length cDNA clone of Sindbis virus, and RNA was transcribed from these constructs with SP6 RNA polymerase and translated in vitro. Although virtually all of the nsP1, nsP3, and nsP4 sequences could be deleted without affecting processing, deletions in the N-terminal half of nsP2 led to aberrant processing, and deletions in the C-terminal half abolished proteolysis. However, inactive polyproteins containing the nsP2 deletions could be processed by exogenously supplied proteins translated from virion RNA, demonstrating that cleavage was virus specific and not due to a protease present in the reticulocyte lysate and that the deleted polyproteins still served as substrates for the enzyme. From these results and from experiments in which processing was studied at increasingly higher dilution, we have concluded the following: (i) the viral nonstructural proteinase is located in the C-terminal half of nsP2; (ii) in the P123 precursor the cleavage between nsP2 and nsP3 occurs efficiently as a bimolecular reaction (in trans) to remove nsP3, while the bond between nsP1 and nsP2 is cleaved inefficiently, but detectably, in trans, but no autoproteolysis of P123 was detected; (iii) once nsP3 has been removed, the bond between nsP1 and nsP2 in the P12 precursor is cleaved efficiently by autoproteolysis (in cis). This mode of processing leads to a slow rate of cleavage, particularly early in infection, suggesting that the polyproteins might play roles in virus RNA replication distinct from those of the cleaved products. A hypothesis is presented that the proteinase is a thiol protease related to papain.

Rotavirus Replication: Plus-Sense Templates for Double-Stranded RNA Synthesis Are Made in Viroplasms

Abstract: Rotavirus plus-strand RNAs not only direct protein synthesis but also serve as templates for the synthesis of the segmented double-stranded RNA (dsRNA) genome. In this study, we identified short-interfering RNAs (siRNAs) for viral genes 5, 8, and 9 that suppressed the expression of NSP1, a nonessential protein; NSP2, a component of viral replication factories (viroplasms); and VP7, an outer capsid protein, respectively. The loss of NSP2 expression inhibited viroplasm formation, genome replication, virion assembly, and synthesis of the other viral proteins. In contrast, the loss of VP7 expression had no effect on genome replication; instead, it inhibited only outer-capsid morphogenesis. Similarly, neither genome replication nor any other event of the viral life cycle was affected by the loss of NSP1. The data indicate that plus-strand RNAs templating dsRNA synthesis within viroplasms are not susceptible to siRNA-induced RNase degradation. In contrast, plus-strand RNAs templating protein synthesis in the cytosol are susceptible to degradation and thus are not the likely source of plus-strand RNAs for dsRNA synthesis in viroplasms. Indeed, immunofluorescence analysis of bromouridine (BrU)-labeled RNA made in infected cells provided evidence that plus-strand RNAs are synthesized within viroplasms. Furthermore, transfection of BrU-labeled viral plus-strand RNA into infected cells suggested that plus-strand RNAs introduced into the cytosol do not localize to viroplasms. From these results, we propose that plus-strand RNAs synthesized within viroplasms are the primary source of templates for genome replication and that trafficking pathways do not exist within the cytosol that transport plus-strand RNAs to viroplasms. The lack of such pathways confounds the development of reverse genetics systems for rotavirus.

Full Genomic Analysis of Human Rotavirus Strain B4106 and Lapine Rotavirus Strain 30/96 Provides Evidence for Interspecies Transmission

Abstract: The Belgian rotavirus strain B4106, isolated from a child with gastroenteritis, was previously found to have VP7 (G3), VP4 (P[14]), and NSP4 (A genotype) genes closely related to those of lapine rotaviruses, suggesting a possible lapine origin or natural reassortment of strain B4106 To investigate the origin of this unusual strain, the gene sequences encoding VP1, VP2, VP3, VP6, NSP1, NSP2, NSP3, and NSP5/6 were also determined To allow comparison to a lapine strain, the 11 double-stranded RNA segments of a European G3P[14] rabbit rotavirus strain 30/96 were also determined The complete genome similarity between strains B4106 and 30/96 was 934% at the nucleotide level and 969% at the amino acid level All 11 genome segments of strain B4106 were closely related to those of lapine rotaviruses and clustered with the lapine strains in phylogenetic analyses In addition, sequence analyses of the NSP5 gene of strain B4106 revealed that the altered electrophoretic mobility of NSP5, resulting in a super-short pattern, was due to a gene rearrangement (head-to-tail partial duplication, combined with two short insertions and a deletion) Altogether, these findings confirm that a rotavirus strain with an entirely lapine genome complement was able to infect and cause severe disease in a human child