Showing papers on "NSP1 published in 2019"

Generation of Recombinant Rotavirus Expressing NSP3-UnaG Fusion Protein by a Simplified Reverse Genetics System.

Abstract: Rotavirus is a segmented double-stranded RNA (dsRNA) virus that causes severe gastroenteritis in young children. We have established an efficient simplified rotavirus reverse genetics (RG) system that uses 11 T7 plasmids, each expressing a unique simian SA11 (+)RNA, and a cytomegalovirus support plasmid for the African swine fever virus NP868R capping enzyme. With the NP868R-based system, we generated recombinant rotavirus (rSA11/NSP3-FL-UnaG) with a genetically modified 1.5-kb segment 7 dsRNA encoding full-length nonstructural protein 3 (NSP3) fused to UnaG, a 139-amino-acid green fluorescent protein (FP). Analysis of rSA11/NSP3-FL-UnaG showed that the virus replicated efficiently and was genetically stable over 10 rounds of serial passaging. The NSP3-UnaG fusion product was well expressed in rSA11/NSP3-FL-UnaG-infected cells, reaching levels similar to NSP3 levels in wild-type recombinant SA11-infected cells. Moreover, the NSP3-UnaG protein, like functional wild-type NSP3, formed dimers in vivo Notably, the NSP3-UnaG protein was readily detected in infected cells via live-cell imaging, with intensity levels ∼3-fold greater than those of the NSP1-UnaG fusion product of rSA11/NSP1-FL-UnaG. Our results indicate that FP-expressing recombinant rotaviruses can be made through manipulation of the segment 7 dsRNA without deletion or interruption of any of the 12 open reading frames (ORFs) of the virus. Because NSP3 is expressed at higher levels than NSP1 in infected cells, rotaviruses expressing NSP3-based FPs may be more sensitive tools for studying rotavirus biology than rotaviruses expressing NSP1-based FPs. This is the first report of a recombinant rotavirus containing a genetically engineered segment 7 dsRNA.IMPORTANCE Previous studies generated recombinant rotaviruses that express FPs by inserting reporter genes into the NSP1 ORF of genome segment 5. Unfortunately, NSP1 is expressed at low levels in infected cells, making viruses expressing FP-fused NSP1 less than ideal probes of rotavirus biology. Moreover, FPs were inserted into segment 5 in such a way as to compromise NSP1, an interferon antagonist affecting viral growth and pathogenesis. We have identified an alternative approach for generating rotaviruses expressing FPs, one relying on fusing the reporter gene to the NSP3 ORF of genome segment 7. This was accomplished without interrupting any of the viral ORFs, yielding recombinant viruses that likely express the complete set of functional viral proteins. Given that NSP3 is made at moderate levels in infected cells, rotaviruses encoding NSP3-based FPs should be more sensitive probes of viral infection than rotaviruses encoding NSP1-based FPs.

Rotavirus Species B Encodes a Functional Fusion-Associated Small Transmembrane Protein.

Abstract: Rotavirus is an important cause of diarrheal disease in young mammals. Rotavirus species A (RVA) causes most human rotavirus diarrheal disease and primarily affects infants and young children. Rotavirus species B (RVB) has been associated with sporadic outbreaks of human adult diarrheal disease. RVA and RVB are predicted to encode mostly homologous proteins but differ significantly in the proteins encoded by the NSP1 gene. In the case of RVB, the NSP1 gene encodes two putative protein products of unknown function, NSP1-1 and NSP1-2. We demonstrate that human RVB NSP1-1 mediates syncytium formation in cultured human cells. Based on sequence alignment, NSP1-1 proteins from species B, G, and I contain features consistent with fusion-associated small transmembrane (FAST) proteins, which have previously been identified in other genera of the Reoviridae family. Like some other FAST proteins, RVB NSP1-1 is predicted to have an N-terminal myristoyl modification. Addition of an N-terminal FLAG peptide disrupts NSP1-1-mediated fusion. NSP1-1 from a human RVB mediates fusion of human cells but not hamster cells and, thus, may serve as a species tropism determinant. NSP1-1 also can enhance RVA replication in human cells, both in single-cycle infection studies and during a multicycle time course in the presence of fetal bovine serum, which inhibits rotavirus spread. These findings suggest potential yet untested roles for NSP1-1 in RVB species tropism, immune evasion, and pathogenesis.IMPORTANCE While species A rotavirus is commonly associated with diarrheal disease in young children, species B rotavirus has caused sporadic outbreaks of adult diarrheal disease. A major genetic difference between species A and B rotaviruses is the NSP1 gene, which encodes two proteins for species B rotavirus. We demonstrate that the smaller of these proteins, NSP1-1, can mediate fusion of cultured human cells. Comparison with viral proteins of similar function provides insight into NSP1-1 domain organization and fusion mechanism. These comparisons suggest that there is a fatty acid modification at the amino terminus of the protein, and our results show that an intact amino terminus is required for NSP1-1-mediated fusion. NSP1-1 from a human virus mediates fusion of human cells, but not hamster cells, and enhances species A rotavirus replication in culture. These findings suggest potential, but currently untested, roles for NSP1-1 in RVB host species tropism, immune evasion, and pathogenesis.

Porcine Reproductive and Respiratory Syndrome Virus Nonstructural Protein 1 Beta Interacts with Nucleoporin 62 To Promote Viral Replication and Immune Evasion.

Abstract: Porcine reproductive and respiratory syndrome virus (PRRSV) blocks host mRNA nuclear export to the cytoplasm, and nonstructural protein 1 beta (nsp1β) of PRRSV has been identified as the protein that disintegrates the nuclear pore complex. In the present study, the molecular basis for the inhibition of host mRNA nuclear export was investigated. Nucleoporin 62 (Nup62) was found to bind to nsp1β, and the region representing the C-terminal residues 328 to 522 of Nup62 was determined to be the binding domain for nsp1β. The nsp1β L126A mutant in the SAP domain did not bind to Nup62, and in L126A-expressing cells, host mRNA nuclear export occurred normally. The vL126A mutant PRRSV generated by reverse genetics replicated at a lower rate, and the titer was lower than for wild-type virus. In nsp1β-overexpressing cells or small interfering RNA (siRNA)-mediated Nup62 knockdown cells, viral protein synthesis increased. Notably, the production of type I interferons (IFN-α/β), IFN-stimulated genes (PKR, OAS, Mx1, and ISG15 genes), IFN-induced proteins with tetratricopeptide repeats (IFITs) 1 and 2, and IFN regulatory factor 3 decreased in these cells. As a consequence, the growth of vL126A mutant PRRSV was rescued to the level of wild-type PRRSV. These findings are attributed to nuclear pore complex (NPC) disintegration by nsp1β, resulting in increased viral protein production and decreased host protein production, including antiviral proteins in the cytoplasm. Our study reveals a new strategy of PRRSV for immune evasion and enhanced replication during infection.IMPORTANCE Porcine reproductive and respiratory syndrome virus (PRRSV) causes PRRS and is known to effectively suppress host innate immunity. The PRRSV nsp1β protein blocks host mRNA nuclear export, which has been shown to be one of the viral mechanisms for inhibition of antiviral protein production. nsp1β binds to the cellular protein nucleoporin 62 (Nup62), and as a consequence, the nuclear pore complex (NPC) is disintegrated and the nucleocytoplasmic trafficking of host mRNAs and host proteins is blocked. We show the dual benefits of Nup62 and nsp1β binding for PRRSV replication: the inhibition of host antiviral protein expression and the exclusive use of host translation machinery by the virus. Our study unveils a novel strategy of PRRSV for immune evasion and enhanced replication during infection.

Generation of Recombinant Rotavirus Expressing NSP3-UnaG Fusion Protein by a Simplified Reverse Genetics System

Abstract: Rotavirus is a segmented double-stranded (ds)RNA virus that causes severe gastroenteritis in young children. We have established an efficient simplified rotavirus reverse genetics (RG) system that uses eleven T7 plasmids, each expressing a unique simian SA11 (+)RNA, and a CMV support plasmid for the African swine fever virus NP868R capping enzyme. With the NP868R-based system, we generated recombinant rotavirus (rSA11/NSP3-FL-UnaG) with a genetically modified 1.5-kB segment 7 dsRNA that encodes full-length NSP3 fused to UnaG, a 139-aa green fluorescent protein (FP). Analysis of rSA11/NSP3-FL-UnaG showed that the virus replicated efficiently and was genetically stable over 10 rounds of serial passage. The NSP3-UnaG fusion product was well expressed in rSA11/NSP3-FL-UnaG-infected cells, reaching levels similar to NSP3 in wildtype rSA11-infected cells. Moreover, the NSP3-UnaG protein, like functional wildtype NSP3, formed dimers in vivo. Notably, NSP3-UnaG protein was readily detected in infected cells via live cell imaging, with intensity levels ~3-fold greater than that of the NSP1-UnaG fusion product of rSA11/NSP1-FL-UnaG. Our results indicate that FP-expressing recombinant rotaviruses can be made through manipulation of the segment 7 dsRNA without deleting or interrupting any of the twelve open reading frames of the virus. Because NSP3 is expressed at levels higher than NSP1 in infected cells, rotaviruses expressing NSP3-based FPs may be a more sensitive tool for studying rotavirus biology than rotaviruses expressing NSP1-based FPs. This is the first report of a recombinant rotavirus containing a genetically engineered segment 7 dsRNA. Importance Previous studies have generated recombinant rotaviruses that express fluorescent proteins (FPs) by inserting reporter genes into the NSP1 open reading frame (ORF) of genome segment 5. Unfortunately, NSP1 is expressed at low levels in infected cells, making viruses expressing FP-fused NSP1 less than ideal probes of rotavirus biology. Moreover, FPs were inserted into segment 5 in such a way as to compromise NSP1, an interferon antagonist affecting viral growth and pathogenesis. We have identified an alternative approach for generating rotaviruses expressing FPs, one relying on fusing the reporter gene to the NSP3 ORF of genome segment 7. This was accomplished without interrupting any of the viral ORFs, yielding recombinant viruses likely expressing the complete set of functional viral proteins. Given that NSP3 is made at moderate levels in infected cells, rotavirus encoding NSP3-based FPs should be more sensitive probes of viral infection than rotaviruses encoding NSP1-based FPs.

Rotavirus NSP1 localizes in the nucleus to disrupt PML nuclear bodies during infection

Abstract: The rotavirus nonstructural protein 1 (NSP1) antagonizes interferon (IFN) induction in infected host cells. The primary function of NSP1 is thought to be degradation of interferon regulatory factors (IRFs) and beta-transducin repeat-containing protein (β-TrCP) in the cytoplasm to inhibit IFN induction. Here, we report that NSP1 localizes to the cytoplasm and nucleus and disrupts promyelocytic (PML) nuclear bodies (NB) in the nucleus during infection. Nuclear localization of NSP1 did not require an intact C terminus, suggesting NSP1 has a novel function in the nucleus independent of degradation of IRFs or β-TrCP. NSP1 expression either led to a reduction in PML NB number or a change in PML NB morphology from sphere-shaped foci to oblong-shaped structures, depending on the virus strain. Additionally, infection was not affected when cells lack PML NB, suggesting that rotavirus does not require PML for replication in highly permissive cell types. PML was not essential for nuclear localization of NSP1, but PML was required for NSP1 nuclear focus formation. PML NBs play an important role in many cellular functions that include IFN induction and host stress responses. This is the first report that rotavirus, a cytoplasmically replicating virus, encodes a viral protein that localizes to the nucleus during infection, and may suggest a new function of NSP1 in the nucleus. IMPORTANCE Rotavirus causes severe gastroenteritis in young children and leads to over 200,000 deaths per year. Rotavirus is a cytoplasmically replicating virus, and must find ways to avoid or actively inhibit host antiviral responses to efficiently replicate. The nonstructural protein NSP1 is known to inhibit IFN induction by promoting degradation of host proteins in the cytoplasm of infected cells. Here, we demonstrate that NSP1 also localizes to the nucleus of infected cells, specifically to PML NB. NSP1 causes a disruption of PML NB, which may serve as an additional mechanism of IFN inhibition or interfere with other nuclear processes to promote viral replication. A detailed exploration of the manipulation of nuclear processes in cells infected with cytoplasmically replicating viruses will lead to new insights into viral evasion of host responses.

Group B rotavirus encodes a functional fusion-associated small transmembrane (FAST) protein

Abstract: Rotavirus is an important cause of diarrheal disease in young mammals. Group A rotavirus (RVA) causes most human rotavirus diarrheal disease and primarily affects infants and young children. Group B rotavirus (RVB) has been associated with sporadic outbreaks of human adult diarrheal disease. RVA and RVB are predicted to encode mostly homologous proteins but differ significantly in the proteins encoded by the NSP1 gene. In the case of RVB, the NSP1 gene encodes two putative protein products of unknown function, NSP1-1 and NSP1-2. We demonstrate that human RVB NSP1-1 mediates syncytia formation in cultured human cells. Based on sequence alignment, NSP1-1 from groups B, G, and I contain features consistent with fusion-associated small transmembrane (FAST) proteins, which have previously been identified in other Reoviridae viruses. Like some other FAST proteins, RVB NSP1-1 is predicted to have an N-terminal myristoyl modification. Addition of an N-terminal FLAG peptide disrupts NSP1-1-mediated fusion, consistent with a role for this fatty-acid modification in NSP1-1 function. NSP1-1 from a human RVB mediates fusion of human cells but not hamster cells and, thus, may serve as a species tropism determinant. NSP1-1 also can enhance RVA replication in human cells, both in single-cycle infection studies and during a multi-cycle time course in the presence of fetal bovine serum, which inhibits rotavirus spread. These findings suggest potential yet untested roles for NSP1-1 in RVB species tropism, immune evasion, and pathogenesis. IMPORTANCE While group A rotavirus is commonly associated with diarrheal disease in young children, group B rotavirus has caused sporadic outbreaks of adult diarrheal disease. A major genetic difference between group A and B rotaviruses is the NSP1 gene, which encodes two proteins for group B rotavirus. We demonstrate that the smaller of these proteins, NSP1-1, can mediate fusion of cultured human cells. Comparison with viral proteins of similar function provides insight into NSP1-1 domain organization and fusion mechanism. Our findings are consistent with an important role for a fatty acid modification at the amino terminus of the protein in mediating its function. NSP1-1 from a human virus mediates fusion of human cells, but not hamster cells, and enhances rotavirus replication in culture. These findings suggest potential, but currently untested, roles for NSP1-1 in RVB species tropism, immune evasion, and pathogenesis.

Samrna vaccine and preparation method therefor

Abstract: The invention discloses a SamRNA vaccine. The vaccine comprises a recombinant virus vector. The recombinant virus vector consists of a virogene replication complex and a nucleotide sequence encoding at least one type of antigen, and the virogene replication complex consists of nucleotide sequences encoding virogene replication-related proteins nsP1, nsP2, nsP3 and nsP4. The SamRNA vaccine disclosed by the invention can modify the promoter of the adenovirus vector to transcribe antigen gene to form mRNA, moreover, with RNA as a template, the virogene replication-related proteins nsP1-4 can synthesize a large amount of mRNA, and thereby the immune effect of the target antigen is greatly increased.