Regulation of vaccinia virus morphogenesis: phosphorylation of the A14L and A17L membrane proteins and C-terminal truncation of the A17L protein are dependent on the F10L kinase (original) (raw)
Related papers
Journal of Virology, 1996
The vaccinia virus (VV) A17L gene encodes a 21-to 23-kDa virion component that forms a stable complex with the 14-kDa envelope protein (A27L gene). In a previous report, we described the construction of a VV recombinant, VVindA17L, in which the expression of the A17L gene is inducibly regulated by isopropyl--Dthiogalactoside (IPTG). We demonstrated that shutoff of the A17L gene results in a blockade of virion morphogenesis at a very early stage (D. Rodríguez, M. Esteban, and J. R. Rodríguez, J. Virol. 69:4640-4648, 1995). In the present study, we show that virus growth is restored if the inducer is provided not later than 6 h postinfection. Immunofluorescence and immunoelectron microscopy analysis of VVindA17L-infected cells revealed that in the absence of the 21-to 23-kDa protein, the 14-kDa protein is distributed throughout the cytoplasm. After IPTG addition, the 14-kDa protein can be detected around viral factories and immature virions; at later times, it localizes in the external membranes of intracellular mature virions. Immunoelectron microscopy with anti-21-to 23-kDa antibodies showed that soon after induction, the protein accumulates in membranes of the rough endoplasmic reticulum and in the nuclear envelope. With time, the protein localizes in viral crescents and subsequently associates to the membranes of immature and intracellular mature virions. These results are consistent with a model in which the 21-to 23-kDa protein would be synthesized at the endoplasmic reticulum, from where the protein could be translocated to the membranes of the intermediate compartment to generate the precursors of the viral membranes. Also, these results argue that 14-kDa envelope protein becomes posttranslationally associated to viral membranes through its interaction with the 21-kDa protein.
Journal of virology, 1997
Vaccinia virus (VV) membrane biogenesis is a poorly understood process. It has been proposed that cellular membranes derived from the endoplasmic reticulum-Golgi intermediate compartment (ERGIC) are incorporated in the early stages of virion assembly. We have recently shown that the VV 21-kDa (A17L gene) envelope protein is essential for the formation of viral membranes. In the present work, we identify a 15-kDa VV membrane protein encoded by the A14L gene. This protein is phosphorylated and myristylated during infection and is incorporated into the virion envelope. Both the 21- and 15-kDa proteins are found associated with cellular tubulovesicular elements related to the ERGIC, suggesting that these proteins are transported in these membranes to the nascent viral factories. When synthesis of the 21-kDa protein is repressed, organized membranes are not formed but numerous ERGIC-derived tubulovesicular structures containing the 15-kDa protein accumulate in the boundaries of the precu...
Vaccinia Virus A6L Encodes a Virion Core Protein Required for Formation of Mature Virion
Journal of Virology, 2006
Vaccinia virus A6L is a previously uncharacterized gene that is conserved in all sequenced vertebrate poxviruses. Here, we constructed a recombinant vaccinia virus encoding A6 with an epitope tag and showed that A6 was expressed in infected cells after viral DNA replication and packaged in the core of the mature virion. Furthermore, we showed that A6 was essential for vaccinia virus replication by performing clustered charge-to-alanine mutagenesis on A6, which resulted in two vaccinia virus mutants (vA6L-mut1 and vA6L-mut2) that displayed a temperature-sensitive phenotype. At 31°C, both mutants replicated efficiently; however, at 40°C, vA6L-mut1 grew to a low titer, while vA6L-mut2 failed to replicate. The A6 protein expressed by vA6L-mut2 exhibited temperature-dependent instability. At the nonpermissive temperature, vA6L-mut2 was normal at viral gene expression and viral factory formation, but it was defective for proteolytic processing of the precursors of several major virion pro...
Expression of the Vaccinia Virus A2.5L Redox Protein Is Required for Virion Morphogenesis
Virology, 2002
In this article we report the initial biochemical, genetic, and electron microscopic analysis of a previously uncharacterized, 8.9-kDa, predicted thiol-redox protein. The name A2.5L was assigned to the corresponding vaccinia virus gene, which is conserved in all sequenced poxviruses. Multiple alignment analysis and secondary structure prediction indicated that the A2.5L gene product is an all-␣-helical protein with a conserved Cxx(x)C motif in the N-terminal ␣-helix. The DNA replication requirement and kinetics of A2.5L protein accumulation in virus-infected cells were typical of a late gene product, in agreement with the predicted promoter sequence. The A2.5L protein was a monomer under reducing conditions, but was mostly associated with the vaccinia virus E10R redox protein as a heterodimer under nonreducing conditions. The A2.5L protein was detected in virus particles at various stages of assembly, suggesting that it is an integral component of intracellular virions. An inducer-dependent A2.5L null mutant was constructed: in the absence of inducer, infectious virus formation was abolished and electron microscopy revealed an assembly block with an accumulation of crescent membranes and immature virions. This stage of assembly block was similar to that occurring when the E10R and G4L redox proteins were repressed, which is compatible with the involvement of E10R, A2.5L, and G4L in the same redox pathway.
Journal of Virology, 2006
All sequenced poxviruses encode orthologs of the vaccinia virus L1 and F9 proteins, which are structurally similar and share about 20% amino acid identity. We found that F9 further resembles L1 as both proteins are membrane components of the mature virion with similar topologies and induce neutralizing antibodies. In addition, a recombinant vaccinia virus that inducibly expresses F9, like a previously described L1 mutant, had a conditional-lethal phenotype: plaque formation and replication of infectious virus were dependent on added inducer. However, only immature virus particles are made when L1 is repressed, whereas normal-looking intracellular and extracellular virions formed in the absence of F9. Except for the lack of F9, the polypeptide components of such virions were indistinguishable from those of wild-type virus. These F9-deficient virions bound to cells, but their cores did not penetrate into the cytoplasm. Furthermore, cells infected with F9-negative virions did not fuse ...
2004
The initial characterization of the product of the vaccinia virus G5R gene, which is conserved in all poxviruses sequenced to date, is described. The G5 protein was detected in the core fraction of purified virions, and transcription and translation of the G5R open reading frame occurred early in infection, independently of DNA replication. Attempts to delete the G5R gene and isolate a replication-competent virus were unsuccessful, suggesting that G5R encodes an essential function. We engineered vaccinia virus mutants with clusters of charged amino acids changed to alanines and determined that several were unable to replicate at 40°C but grew well at 37°C. At the nonpermissive temperature, viral gene expression and DNA replication and processing were unperturbed. However, tyrosine phosphorylation and proteolytic cleavage of the A17 membrane protein and proteolytic cleavage of core proteins were inhibited at 40°C, suggesting an assembly defect. The cytoplasm of cells that had been infected at the nonpermissive temperature contained large granular areas devoid of cellular organelles or virus structures except for occasional short crescent-shaped membranes and electrondense lacy structures. The temperature-sensitive phenotype of the G5R mutants closely resembled the phenotypes of vaccinia virus mutants carrying conditionally lethal F10R protein kinase and H5R mutations. F10, although required for phosphorylation of A17 and viral membrane formation, was synthesized by the G5R mutants under nonpermissive conditions. An intriguing possibility is that G5 participates in the formation of viral membranes, a poorly understood event in poxvirus assembly.
Journal of Virology, 2010
Poxvirus virions, whose outer membrane surrounds two lateral bodies and a core, contain at least 70 different proteins. The F18 phosphoprotein is one of the most abundant core components and is essential for the assembly of mature virions. We report here the results of a structure/function analysis in which the role of conserved cysteine residues, clusters of charged amino acids and clusters of hydrophobic/aromatic amino acids have been assessed. Taking advantage of a recombinant virus in which F18 expression is IPTG (isopropyl-β- d -thiogalactopyranoside) dependent, we developed a transient complementation assay to evaluate the ability of mutant alleles of F18 to support virion morphogenesis and/or to restore the production of infectious virus. We have also examined protein-protein interactions, comparing the ability of mutant and WT F18 proteins to interact with WT F18 and to interact with the viral A30 protein, another essential core component. We show that F18 associates with an...
Journal of virology, 1998
Early stages in vaccinia virus (VV) assembly involve the recruitment of cellular membranes from the endoplasmic reticulum-Golgi intermediate compartment (ERGIC) to virus factories (or virosomes). The key viral factors involved in this process are not yet known. We have previously identified and characterized two viral proteins, of 21 kDa (A17L gene) and 15 kDa (A14L gene), that associate with tubulovesicular elements related to the ERGIC and are localized in viral membranes at all stages of virion assembly. We showed that the 21-kDa protein is not responsible for the recruitment of membranes from the ERGIC to viral factories. However, it appears to be essential for the organization of viral membranes. In this investigation we have generated a VV recombinant, VVindA14L, in which the expression of the A14L gene is inducibly regulated by the Escherichia coli lacI operator-repressor system. Repression of 15-kDa protein synthesis has a dramatic effect on virus yields and severely impairs...
Journal of Virology, 2010
Mature vaccinia virus enters cells through either fluid-phase endocytosis/macropinocytosis or plasma membrane fusion. This may explain the wide range of host cell susceptibilities to vaccinia virus entry; however, it is not known how vaccinia virus chooses between these two pathways and which viral envelope proteins determine such processes. By screening several recombinant viruses and different strains, we found that mature virions containing the vaccinia virus A25 and A26 proteins entered HeLa cells preferentially through a bafilomycin-sensitive entry pathway, whereas virions lacking these two proteins entered through a bafilomycin-resistant pathway. To investigate whether the A25 and A26 proteins contribute to entry pathway specificity, two mutant vaccinia viruses, WR⌬A25L and WR⌬A26L, were subsequently generated from the wild-type WR strain. In contrast to the WR strain, both the WR⌬A25L and WR⌬A26L viruses became resistant to bafilomycin, suggesting that the removal of the A25 and A26 proteins bypassed the low-pH endosomal requirement for mature virion entry. Indeed, WR⌬A25L and WR⌬A26L virus infections of HeLa, CHO-K1, and L cells immediately triggered cell-to-cell fusion at a neutral pH at 1 to 2 h postinfection (p.i.), providing direct evidence that viral fusion machinery is readily activated after the removal of the A25 and A26 proteins to allow virus entry through the plasma membrane. In summary, our data support a model that on vaccinia mature virions, the viral A25 and A26 proteins are low-pH-sensitive fusion suppressors whose inactivation during the endocytic route results in viral and cell membrane fusion. Our results also suggest that during virion morphogenesis, the incorporation of the A25 and A26 proteins into mature virions may help restrain viral fusion activity until the time of infections.
The E6 protein from vaccinia virus is required for the formation of immature virions
Virology, 2010
An IPTG-inducible mutant in the E6R gene of vaccinia virus was used to study the role of the E6 virion core protein in viral replication. In the absence of the inducer, the mutant exhibited a normal pattern DNA replication, concatemer resolution and late gene expression, but it showed an inhibition of virion structural protein processing it failed to produce infectious particles. Electron microscopic analysis showed that in the absence of IPTG viral morphogenesis was arrested before IV formation: crescents, aberrant or empty IV-like structures, and large aggregated virosomes were observed throughout the cytoplasm. The addition of IPTG to release a 12-h block showed that virus infectious particles could be formed in the absence of de novo DNA synthesis. Our observations show that in the absence of E6 the association of viroplasm with viral membrane crescents is impaired. Published by Elsevier Inc.