scholarly journals Rubella virus-like replicon particles: analysis of encapsidation determinants and non-structural roles of capsid protein in early post-entry replication

2012 ◽  
Vol 93 (3) ◽  
pp. 516-525 ◽  
Author(s):  
Claudia Claus ◽  
Wen-Pin Tzeng ◽  
U. G Liebert ◽  
Teryl K. Frey
Keyword(s):  
Capsid Protein ◽  
Rubella Virus ◽  
Sindbis Virus ◽  
Packaging Signal ◽  
Initiation Of Replication ◽  
Replicase Proteins ◽  
Infected Cells ◽  
In Trans ◽  
Post Entry

Rubella virus (RUBV) contains a plus-strand RNA genome with two ORFs, one encoding the non-structural replicase proteins (NS-ORF) and the second encoding the virion structural proteins (SP-ORF). This study describes development and use of a trans-encapsidation system for the assembly of infectious RUBV-like replicon particles (VRPs) containing RUBV replicons (self replicating genomes with the SP-ORF replaced with a reporter gene). First, this system was used to map signals within the RUBV genome that mediate packaging of viral RNA. Mutations within a proposed packaging signal did not significantly affect relative packaging efficiency. The insertion of various fragments derived from the RUBV genome into Sindbis virus replicons revealed that there are several regions within the RUBV genome capable of enhancing encapsidation of heterologous replicon RNAs. Secondly, the trans-encapsidation system was used to analyse the effect of alterations within the capsid protein (CP) on release of VRPs and subsequent initiation of replication in newly infected cells. Deletion of the N-terminal eight amino acids of the CP reduced VRP titre significantly, which could be partially complemented by native CP provided in trans, indicating that this mutation affected an entry or post-entry event in the replication cycle. To test this hypothesis, the trans-encapsidation system was used to demonstrate the rescue of a lethal deletion within P150, one of the virus replicase proteins, by CP contained within the virus particle. This novel finding substantiated the functional role of CP in early post-entry replication.

scholarly journals Role of Sindbis Virus Capsid Protein Region II in Nucleocapsid Core Assembly and Encapsidation of Genomic RNA

2008 ◽  
Vol 82 (9) ◽  
pp. 4461-4470 ◽  
Author(s):  
Ranjit Warrier ◽  
Benjamin R. Linger ◽  
Barbara L. Golden ◽  
Richard J. Kuhn
Keyword(s):  
Amino Acids ◽  
Capsid Protein ◽  
Sindbis Virus ◽  
Rna Virus ◽  
Genomic Rna ◽  
Viral Glycoproteins ◽  
Infected Cells ◽  
Viral Genomic Rna ◽  
Region Ii

ABSTRACT Sindbis virus is an enveloped positive-sense RNA virus in the alphavirus genus. The nucleocapsid core contains the genomic RNA surrounded by 240 copies of a single capsid protein. The capsid protein is multifunctional, and its roles include acting as a protease, controlling the specificity of RNA that is encapsidated into nucleocapsid cores, and interacting with viral glycoproteins to promote the budding of mature virus and the release of the genomic RNA into the newly infected cell. The region comprising amino acids 81 to 113 was previously implicated in two processes, the encapsidation of the viral genomic RNA and the stable accumulation of nucleocapsid cores in the cytoplasm of infected cells. In the present study, specific amino acids within this region responsible for the encapsidation of the genomic RNA have been identified. The region that is responsible for nucleocapsid core accumulation has considerable overlap with the region that controls encapsidation specificity.

scholarly journals Multiple capsid protein binding sites mediate selective packaging of the alphavirus genomic RNA

2020 ◽  
Vol 11 (1) ◽  
Author(s):  
Rebecca S. Brown ◽  
Dimitrios G. Anastasakis ◽  
Markus Hafner ◽  
Margaret Kielian
Keyword(s):  
Capsid Protein ◽  
Binding Sites ◽  
Semliki Forest Virus ◽  
Virus Assembly ◽  
Genomic Rna ◽  
Packaging Signal ◽  
Genome Packaging ◽  
Genome Recognition ◽  
Infected Cells

Abstract The alphavirus capsid protein (Cp) selectively packages genomic RNA (gRNA) into the viral nucleocapsid to produce infectious virus. Using photoactivatable ribonucleoside crosslinking and an innovative biotinylated Cp retrieval method, here we comprehensively define binding sites for Semliki Forest virus (SFV) Cp on the gRNA. While data in infected cells demonstrate Cp binding to the proposed genome packaging signal (PS), mutagenesis experiments show that PS is not required for production of infectious SFV or Chikungunya virus. Instead, we identify multiple Cp binding sites that are enriched on gRNA-specific regions and promote infectious SFV production and gRNA packaging. Comparisons of binding sites in cytoplasmic vs. viral nucleocapsids demonstrate that budding causes discrete changes in Cp-gRNA interactions. Notably, Cp’s top binding site is maintained throughout virus assembly, and specifically binds and assembles with Cp into core-like particles in vitro. Together our data suggest a model for selective alphavirus genome recognition and assembly.

scholarly journals Binding of cellular p32 protein to the rubella virus P150 replicase protein via PxxPxR motifs

2012 ◽  
Vol 93 (4) ◽  
pp. 807-816 ◽  
Author(s):  
Suganthi Suppiah ◽  
Heather A. Mousa ◽  
Wen-Pin Tzeng ◽  
Jason D. Matthews ◽  
Teryl K. Frey
Keyword(s):  
Rubella Virus ◽  
Rna Synthesis ◽  
Specific Binding ◽  
Infectious Clone ◽  
Binding Motifs ◽  
Replicase Protein ◽  
Virus Rna ◽  
Infected Cells ◽  
Proline Rich Region

A proline-rich region (PRR) within the rubella virus (RUBV) P150 replicase protein that contains three SH3 domain-binding motifs (PxxPxR) was investigated for its ability to bind cell proteins. Pull-down experiments using a glutathione S-transferase–PRR fusion revealed PxxPxR motif-specific binding with human p32 protein (gC1qR), which could be mediated by either of the first two motifs. This finding was of interest because p32 protein also binds to the RUBV capsid protein. Binding of p32 to P150 was confirmed and was abolished by mutation of the first two motifs. When mutations in the first two motifs were introduced into a RUBV cDNA infectious clone, virus replication was significantly impaired. However, virus RNA synthesis was found to be unaffected, and subsequent immunofluorescence analysis of RUBV-infected cells revealed co-localization of p32 and P150 but little overlap of p32 with RNA replication complexes, indicating that p32 does not participate directly in virus RNA synthesis. Thus, the role of p32 in RUBV replication remains unresolved.

scholarly journals HIV-1 Virus Interactions With Host Proteins: Interaction of the N-terminal Domain of the HIV-1 Capsid Protein With Human Calmodulin

2019 ◽  
Vol 14 (5) ◽  
pp. 1934578X1984919
Author(s):  
Ywh-Min Tzou ◽  
Ronald Shin ◽  
N. Rama Krishna
Keyword(s):  
Capsid Protein ◽  
Host Factors ◽  
Host Proteins ◽  
Terminal Domain ◽  
Immunodeficiency Virus ◽  
Infected Cells ◽  
Virus Interactions ◽  
Precise Role ◽  
Hiv 1

The human immunodeficiency virus (HIV-1 virus) exploits several host factors for assembly, infection, and replication within the infected cells. In this work, we describe the evidence for an interaction of the N-terminal domain of the HIV-1 capsid protein with human calmodulin. The precise role of this interaction within the life cycle of the HIV-1 virus is yet to be defined. Potential roles for this interaction in the viral capsid uncoating are discussed.

scholarly journals Multiple Capsid Protein Binding Sites Mediate Selective Packaging of the Alphavirus Genomic RNA

2020 ◽  
Author(s):  
Rebecca S. Brown ◽  
Dimitrios G. Anastasakis ◽  
Markus Hafner ◽  
Margaret Kielian
Keyword(s):  
Capsid Protein ◽  
Binding Sites ◽  
Semliki Forest Virus ◽  
Virus Assembly ◽  
Genomic Rna ◽  
Packaging Signal ◽  
Genome Packaging ◽  
Genome Recognition ◽  
Infected Cells

ABSTRACTThe alphavirus capsid protein (Cp) selectively packages genomic RNA (gRNA) into the viral nucleocapsid to produce infectious virus. Using photoactivatable ribonucleoside crosslinking and an innovative biotinylated Cp retrieval method, we comprehensively defined binding sites for Semliki Forest virus (SFV) Cp on the gRNA. While data in infected cells demonstrated Cp binding to the proposed genome packaging signal (PS), mutagenesis experiments showed that PS was not required for production of infectious SFV or Chikungunya virus. Instead, we identified multiple novel Cp binding sites that were enriched on gRNA-specific regions and promoted infectious SFV production and gRNA packaging. Comparisons of binding sites in cytoplasmic vs. viral nucleocapsids demonstrated that budding caused discrete changes in Cp-gRNA interactions. Notably, Cp’s top binding site was maintained throughout virus assembly, and specifically bound and assembled with Cp into core-like particles in vitro. Together our data suggest a new model for selective alphavirus genome recognition and assembly.

scholarly journals Potential Dual Role of West Nile Virus NS2B in Orchestrating NS3 Enzymatic Activity in Viral Replication

Viruses ◽  
2021 ◽  
Vol 13 (2) ◽  
pp. 216
Author(s):  
Alanna C. Tseng ◽  
Vivek R. Nerurkar ◽  
Kabi R. Neupane ◽  
Helmut Kae ◽  
Pakieli H. Kaufusi
Keyword(s):  
West Nile Virus ◽  
Enzymatic Activity ◽  
Nonstructural Protein ◽  
Antiviral Drug ◽  
West Nile ◽  
Biochemical Assays ◽  
In Trans ◽  
Viral Polyprotein ◽  
Ns3 Protease

West Nile virus (WNV) nonstructural protein 3 (NS3) harbors the viral triphosphatase and helicase for viral RNA synthesis and, together with NS2B, constitutes the protease responsible for polyprotein processing. NS3 is a soluble protein, but it is localized to specialized compartments at the rough endoplasmic reticulum (RER), where its enzymatic functions are essential for virus replication. However, the mechanistic details behind the recruitment of NS3 from the cytoplasm to the RER have not yet been fully elucidated. In this study, we employed immunofluorescence and biochemical assays to demonstrate that NS3, when expressed individually and when cleaved from the viral polyprotein, is localized exclusively to the cytoplasm. Furthermore, NS3 appeared to be peripherally recruited to the RER and proteolytically active when NS2B was provided in trans. Thus, we provide evidence for a potential additional role for NS2B in not only serving as the cofactor for the NS3 protease, but also in recruiting NS3 from the cytoplasm to the RER for proper enzymatic activity. Results from our study suggest that targeting the interaction between NS2B and NS3 in disrupting the NS3 ER localization may be an attractive avenue for antiviral drug discovery.

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