Conserved methionine 165 of matrix protein contributes to the nuclear import and is essential for influenza A virus replication (original) (raw)
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Nuclear trafficking of influenza virus ribonuleoproteins in heterokaryons
Journal of Virology, 1996
The influenza virus nucleoprotein (NP), matrix protein (M1), and ribonucleoproteins (vRNPs) undergo regulated nuclear import and export during infection. Their trafficking was analyzed by using interspecies heterokaryons containing nuclei from infected and uninfected cells. Under normal conditions, it was demonstrated that the vRNPs which were assembled in the nucleus and transported to the cytosol were prevented from reimport into the nucleus. To be import competent, they must first assemble into virions and enter by the endosomal entry pathway. In influenza virus mutant ts51, in which M1 is defective, direct reimport took place but was inhibited by heterologous expression of wild-type M1. These data confirm M1's role as the inhibitor of premature nuclear import and as the main regulator of nuclear transport of vRNPs. In addition to this vRNP shuttling, M1 also shuttled between the nucleus and the cytoplasm in ts51-infected cells. When NP was expressed in the absence of virus i...
Journal of Virology, 1995
The matrix (M1) protein of influenza virus is a major structural component, involved in regulation of viral ribonucleoprotein transport into and out of the nucleus. Early in infection, M1 is distributed in the nucleus, whereas later, it is localized predominantly in the cytoplasm. Using immunofluorescence microscopy and the influenza virus mutant ts51, we found that at the nonpermissive temperature M1 was retained in the nucleus, even at late times after infection. In contrast, the viral nucleoprotein (NP), after a temporary retention in the nucleus, was distributed in the cytoplasm. Therefore, mutant M1 supported the release of the viral ribonucleoproteins from the nucleus, but not the formation of infectious virions. The point mutation in the ts51 M1 gene was predicted to encode an additional phosphorylation site. We observed a substantial increase in the incorporation of 32Pi into M1 at the nonpermissive temperature. The critical role of this phosphorylation site was demonstrated...
The Journal of general virology, 2000
A systematic analysis was carried out to identify the amino acid signals that regulate the nucleo-cytoplasmic transport of the influenza A virus nucleoprotein (NP). The analysis involved determining the intracellular localization of eight deleted recombinant NP proteins and 14 chimeric proteins containing the green fluorescent protein fused to different NP fragments. In addition, the subcellular distribution of NP derivatives that contained specific substitutions at serine-3, which is the major phosphorylation site of the A/Victoria/3/75 NP, were analysed. From the results obtained, it is concluded that the NP contains three signals involved in nuclear accumulation and two regions that cause cytoplasmic accumulation of the fusion proteins. One of the karyophilic signals was located at the N terminus of the protein, and the data obtained suggest that the functionality of this signal can be modified by phosphorylation at serine-3. These findings are discussed in the context of the tra...
Virus research, 2017
Nuclear exportation of influenza ribonucleoprotein is a vital step in viral replication cycle. In this study a particular H7N1 (A/ostrich/Zimbabwe/222-E3/1996) virus showed exclusively nuclear localization of the viral nucleoprotein (NP) only in human cell lines but not in cell lines of other species suggesting a human-specific nuclear exportation defect. After 10 passages in human lung cells, an adapted strain (H7N1:P10) could efficiently replicate and export viral NP in human cells. Mutations in the NP and matrix M1 gene at position 297 and 227, respectively, were found to rescue the defect. While the NP mutant showed a comparable ratio of total to NP-associated negative-sense RNA in the cytoplasm as compared to the wild type, the M1 mutant showed an increase in free negative-sense RNA in the cytoplasm. These indicated that the NP mutation might cause a nuclear export defect, whereas the M1 mutation might cause a defect in ribonucleoprotein assembly step.
A Classical Bipartite Nuclear Localization Signal on Thogoto and Influenza A Virus Nucleoproteins
We have previously shown that the nucleoprotein (NP) of Thogoto virus (THOV), a tick-borne member of the Orthomyxoviridae family, accumulates in the cell nucleus. Here we demonstrate that THOV NP contains a motif (KRxxxxxxxxxKTKK) at amino acid positions 179±193 that represents a classical bipartite nuclear localization signal (NLS). This sequence motif (named cNLS) was able to translocate a cytoplasmic 80-kDa reporter protein into the nucleus. Targeted mutations substituting lysines for alanines in the downstream cluster of the bipartite motif abolished the capacity of cNLS to mediate nuclear import. In contrast, identical mutations had no effect on nuclear localization when introduced into THOV NP, indicating that additional transport signals are present in NP. Amino-acid sequence comparisons revealed that THOV NP lacks the N-terminal nonconvential NLS (named here nNLS), which has been implicated in nuclear import of influenza A virus NP. Accordingly, THOV NP failed to interact in coprecipitation assays with the cellular NPI-1/3 transport factors of the karyopherin ␣ family. A highly conserved motif identified in THOV NP was the so-called nuclear accumulation sequence (NAS). Mutating NAS alone, or in combination with cNLS, had no gross effect on the intracellular distribution of the protein, indicating that a functional NAS is not required for nuclear accumulation of THOV NP in mammalian cells. We also studied nuclear transport of influenza A/PR/8/34 virus NP. Interestingly, we found a cNLS motif at amino acid positions 198±216 in addition to the previously described nonconventional nNLS. To further assess the functional role of cNLS, nNLS, and NAS, we analyzed single, double, and triple mutants of influenza A virus NP. When nNLS was destroyed, the protein stayed in the cytoplasm as expected. When NAS was disrupted in addition to nNLS, the double mutant accumulated in the nucleus, suggesting that cNLS was active. Indeed, when cNLS was also inactivated, the triple mutant protein localized again predominantly to the cytoplasm. These findings suggest that NP of orthomyxoviruses have two independent NLSs, namely cNLS and nNLS. They further suggest that NAS and NLSs may assume opposing roles in nucleocytoplasmic transport of NP.
Role of the Influenza Virus M1 Protein in Nuclear Export of Viral Ribonucleoproteins
Journal of Virology, 2000
The protein kinase inhibitor H7 blocks influenza virus replication, inhibits production of the matrix protein (M1), and leads to a retention of the viral ribonucleoproteins (vRNPs) in the nucleus at late times of infection (K. Martin and A. Helenius, Cell 67:117–130, 1991). We show here that production of assembled vRNPs occurs normally in H7-treated cells, and we have used H7 as a biochemical tool to trap vRNPs in the nucleus. When H7 was removed from the cells, vRNP export was specifically induced in a CHO cell line stably expressing recombinant M1. Similarly, fusion of cells expressing recombinant M1 from a Semliki Forest virus vector allowed nuclear export of vRNPs. However, export was not rescued when H7 was present in the cells, implying an additional role for phosphorylation in this process. The viral NS2 protein was undetectable in these systems. We conclude that influenza virus M1 is required to induce vRNP nuclear export but that cellular phosphorylation is an additional f...
Journal of Virology, 2006
The influenza A virus RNA-dependent RNA polymerase is a heterotrimeric complex of polymerase basic protein 1 (PB1), PB2, and polymerase acidic protein (PA) subunits. It performs transcription and replication of the viral RNA genome in the nucleus of infected cells. We have identified a nuclear import factor, Ran binding protein 5 (RanBP5), also known as karyopherin 3, importin 3, or importin 5, as an interactor of the PB1 subunit. RanBP5 interacted with either PB1 alone or with a PB1-PA dimer but not with a PB1-PB2 dimer or the trimeric complex. The interaction between RanBP5 and PB1-PA was disrupted by RanGTP in vitro, allowing PB2 to bind to the PB1-PA dimer to form a functional trimeric RNA polymerase complex. We propose a model in which RanBP5 acts as an import factor for the newly synthesized polymerase by targeting the PB1-PA dimer to the nucleus. In agreement with this model, small interfering RNA (siRNA)-mediated knock-down of RanBP5 inhibited the nuclear accumulation of the PB1-PA dimer. Moreover, siRNA knock-down of RanBP5 resulted in the delayed accumulation of viral RNAs in infected cells, confirming that RanBP5 plays a biological role during the influenza virus life cycle.
The role of nuclear import and export in influenza virus infection
Trends in Cell Biology, 1996
Many enveloped viruses, including influenza virus, herpes viruses, hepatitis B virus and RNA tumour viruses, replicate their genomes in the nucleus, but the virus particles themselves mature at the plasma membrane or at cytoplasmic membranes. Because of the spatial separation between genome replication and viral maturation, these viruses must not only get their genomes into the nucleus to initiate infection, but must also ensure that, after replication, the genome is transported to cytosolic budding sites. Each of these virus families use different strategies to solve the nuclear trafficking problem.
PloS one, 2016
The influenza A(H1N1)pdm09 virus caused the first influenza pandemic of the 21st century. In this study, we wanted to decipher the role of conserved basic residues of the viral M1 matrix protein in virus assembly and release. M1 plays many roles in the influenza virus replication cycle. Specifically, it participates in viral particle assembly, can associate with the viral ribonucleoprotein complexes and can bind to the cell plasma membrane and/or the cytoplasmic tail of viral transmembrane proteins. M1 contains an N-terminal domain of 164 amino acids with two basic domains: the nuclear localization signal on helix 6 and an arginine triplet (R76/77/78) on helix 5. To investigate the role of these two M1 basic domains in influenza A(H1N1)pdm09 virus molecular assembly, we analyzed M1 attachment to membranes, virus-like particle (VLP) production and virus infectivity. In vitro, M1 binding to large unilamellar vesicles (LUVs), which contain negatively charged lipids, decreased significa...