Your search keyword '"Baines JD"' showing total 59 results

1. Aberrant RNA polymerase initiation and processivity on the genome of a herpes simplex virus 1 mutant lacking ICP27.

Author

Birkenheuer CH and Baines JD

Subjects

Animals, Humans, Cell Line, Chlorocebus aethiops, Gene Expression Regulation, Viral drug effects, Genes, Viral genetics, Herpes Simplex virology, Herpes Simplex genetics, Poly A genetics, Poly A metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, RNA, Viral genetics, RNA, Viral metabolism, Vero Cells, Virus Replication genetics, Genome, Viral genetics, Herpesvirus 1, Human genetics, Herpesvirus 1, Human physiology, Immediate-Early Proteins deficiency, Immediate-Early Proteins genetics, Mutation, RNA Polymerase II metabolism, Viral Transcription drug effects, Viral Transcription genetics

Abstract

Within the first 15 minutes of infection, herpes simplex virus 1 immediate early proteins repurpose cellular RNA polymerase (Pol II) for viral transcription. An important role of the viral-infected cell protein 27 (ICP27) is to facilitate viral pre-mRNA processing and export viral mRNA to the cytoplasm. Here, we use precision nuclear run-on followed by deep sequencing (PRO-seq) to characterize transcription of a viral ICP27 null mutant. At 1.5 and 3 hours post infection (hpi), we observed increased total levels of Pol II on the mutant viral genome and accumulation of Pol II downstream of poly A sites indicating increased levels of initiation and processivity. By 6 hpi, Pol II accumulation on specific mutant viral genes was higher than that on wild-type virus either at or upstream of poly A signals, depending on the gene. The PRO-seq profile of the ICP27 mutant on late genes at 6 hpi was similar but not identical to that caused by treatment with flavopiridol, a known inhibitor of RNA processivity. This pattern was different from PRO-seq profiles of other α gene mutants and upon inhibition of viral DNA replication with PAA. Together, these results indicate that ICP27 contributes to the repression of aberrant viral transcription at 1.5 and 3 hpi by inhibiting initiation and decreasing RNA processivity. However, ICP27 is needed to enhance processivity on most late genes by 6 hpi in a mechanism distinguishable from its role in viral DNA replication.IMPORTANCEWe developed and validated the use of a processivity index for precision nuclear run-on followed by deep sequencing data. The processivity index calculations confirm infected cell protein 27 (ICP27) induces downstream of transcription termination on certain host genes. The processivity indices and whole gene probe data implicate ICP27 in transient immediate early gene-mediated repression, a process that also requires ICP4, ICP22, and ICP0. The data indicate that ICP27 directly or indirectly regulates RNA polymerase (Pol II) initiation and processivity on specific genes at specific times post infection. These observations support specific and varied roles for ICP27 in regulating Pol II activity on viral genes in addition to its known roles in post transcriptional mRNA processing and export., Competing Interests: The authors declare no conflict of interest.

Published

2024

2. Herpes simplex virus 1 immediate early transcription initiation, pause-release, elongation, and termination in the presence and absence of ICP4.

Author

Dunn LEM and Baines JD

Subjects

Humans, Genes, Viral genetics, Herpes Simplex virology, Transcription Initiation, Genetic, Transcription Elongation, Genetic, Transcription Termination, Genetic, Gene Expression Regulation, Viral, Herpesvirus 1, Human genetics, Immediate-Early Proteins deficiency, Immediate-Early Proteins metabolism, Transcription, Genetic

Abstract

Importance: Infection with herpes simplex virus 1 (HSV-1) leads to lifelong infection due to the virus's remarkable ability to control transcription of its own genome, resulting in two transcriptional programs: lytic (highly active) and latent (restricted). The lytic program requires immediate early (IE) proteins to first repress transcription of late viral genes, which then undergo sequential de-repression, leading to a specific sequence of gene expression. Here, we show that the IE ICP4 functions to regulate the cascade by limiting RNA polymerase initiation at immediate early times. However, late viral genes that initiate too early in the absence of ICP4 do not yield mRNA as transcription stalls within gene bodies. It follows that other regulatory steps intercede to prevent elongation of genes at the incorrect time, demonstrating the precise control HSV-1 exerts over its own transcription., Competing Interests: The authors declare no conflict of interest.

Published

2023

3. Immediate Early Proteins of Herpes Simplex Virus Transiently Repress Viral Transcription before Subsequent Activation.

Author

Dunn LEM, Birkenheuer CH, Dufour R, and Baines JD

Subjects

Animals, Humans, Chlorocebus aethiops, Gene Expression Regulation, Viral, Herpes Simplex virology, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Vero Cells, Virus Replication, Herpesvirus 1, Human physiology, Immediate-Early Proteins metabolism, Viral Transcription

Abstract

Herpes simplex virus 1 (HSV-1) utilizes cellular RNA polymerase II (Pol) to transcribe its genes in one of two phases. In the latent phase, viral transcription is highly restricted, but during the productive lytic phase, more than 80 genes are expressed in a temporally coordinated cascade. In this study, we used Precision nuclear Run On followed by deep Sequencing (PRO-Seq) to characterize early viral transcriptional events using HSV-1 immediate early (IE) gene mutants, corresponding genetically repaired viruses, and wild-type virus. Unexpectedly, in the absence of the IE genes ICP4, ICP22, and ICP0 at 1.5 hours postinfection (hpi), we observed high levels of aberrant transcriptional activity across the mutant viral genomes but substantially less on either wild-type or the congenic repaired virus genomes. This feature was particularly prominent in the absence of ICP4 expression. Cycloheximide treatment during infection with both the ICP4 and ICP22 mutants and their respective genetic repairs did not alter the relative distribution of Pol activity, but it increased overall activity across both viral genomes, indicating that both virion components and at least some de novo protein synthesis were required for full repression. Overall, these data reveal that prior to their role in transcriptional activation, IE gene products and virion components first repress transcription and that the HSV-1 lytic transcriptional cascade is mediated through subsequent derepression steps. IMPORTANCE HSV-1 transcription during productive replication is believed to comprise a series of activation steps leading to a specific sequence of gene expression. Here, we show that virion components and IE gene products ICP0, ICP4, and ICP22 first repress viral gene transcription to various degrees before subsequently activating specific gene subsets. It follows that the entire HSV transcriptional program involves a series of steps to sequentially reverse this repression. This previously uncharacterized repressive activity of IE genes very early in infection may represent an important checkpoint allowing HSV-1 to orchestrate either the robust lytic transcriptional cascade or the more restricted transcriptional program during latency.

Published

2022

4. ICP22 of Herpes Simplex Virus 1 Decreases RNA Polymerase Processivity.

Author

Birkenheuer CH, Dunn L, Dufour R, and Baines JD

Subjects

DNA Replication genetics, DNA, Viral, Humans, RNA Polymerase II metabolism, Virus Replication, Herpes Simplex, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Immediate-Early Proteins genetics, Immediate-Early Proteins metabolism

Abstract

To determine the role of ICP22 in transcription, we performed precise nuclear run-on followed by deep sequencing (PRO-seq) and global nuclear run-on with sequencing (GRO-seq) in cells infected with a viral mutant lacking the entire ICP22-encoding α22 (US1/US1.5) gene and a virus derived from this mutant bearing a restored α22 gene. At 3 h postinfection (hpi), the lack of ICP22 reduced RNA polymerase (Pol) promoter proximal pausing (PPP) on the immediate early α4, α0, and α27 genes. Diminished PPP at these sites accompanied increased Pol processivity across the entire herpes simplex virus 1 (HSV-1) genome in GRO-seq assays, resulting in substantial increases in antisense and intergenic transcription. The diminished PPP on α gene promoters at 3 hpi was distinguishable from effects caused by treatment with a viral DNA polymerase inhibitor at this time. The ICP22 mutant had multiple defects at 6 hpi, including lower viral DNA replication, reduced Pol activity on viral genes, and increased Pol activity on cellular genes. The lack of ICP22 also increased PPP release from most cellular genes, while a minority of cellular genes exhibited decreased PPP release. Taken together, these data indicate that ICP22 acts to negatively regulate transcriptional elongation on viral genes in part to limit antisense and intergenic transcription on the highly compact viral genome. This regulatory function directly or indirectly helps to retain Pol activity on the viral genome later in infection. IMPORTANCE The longstanding observation that ICP22 reduces RNA polymerase II (Pol II) serine 2 phosphorylation, which initiates transcriptional elongation, is puzzling because this phosphorylation is essential for viral replication. The current study helps explain this apparent paradox because it demonstrates significant advantages in negatively regulating transcriptional elongation, including the reduction of antisense and intergenic transcription. Delays in elongation would be expected to facilitate the ordered assembly and functions of transcriptional initiation, elongation, and termination complexes. Such limiting functions are likely to be important in herpesvirus genomes that are otherwise highly transcriptionally active and compact, comprising mostly short, intronless genes near neighboring genes of opposite sense and containing numerous 3'-nested sets of genes that share transcriptional termination signals but differ at transcriptional start sites on the same template strand.

Published

2022

5. RNA Polymerase II Promoter-Proximal Pausing and Release to Elongation Are Key Steps Regulating Herpes Simplex Virus 1 Transcription.

Author

Birkenheuer CH and Baines JD

Subjects

Animals, Cell Line, Cyclin-Dependent Kinase 9, DNA Replication, DNA, Viral, Genes, Viral genetics, Genome, Viral, Humans, RNA Polymerase II metabolism, RNA, Messenger metabolism, Transcription Initiation Site, Virus Replication, Herpesvirus 1, Human genetics, Herpesvirus 1, Human physiology, Promoter Regions, Genetic genetics, RNA Polymerase II genetics, Transcription, Genetic physiology

Abstract

Herpes simplex virus 1 (HSV-1) genes are transcribed by cellular RNA polymerase II (Pol II). Expression of viral immediate early (α) genes is followed sequentially by early (β), late (γ 1 ), and true late (γ 2 ) genes. We used precision nuclear run-on with deep sequencing to map and to quantify Pol II on the HSV-1(F) genome with single-nucleotide resolution. Approximately 30% of total Pol II relocated to viral genomes within 3 h postinfection (hpi), when it occupied genes of all temporal classes. At that time, Pol II on α genes accumulated most heavily at promoter-proximal pause (PPP) sites located ∼60 nucleotides downstream of the transcriptional start site, while β genes bore Pol II more evenly across gene bodies. At 6 hpi, Pol II increased on γ 1 and γ 2 genes while Pol II pausing remained prominent on α genes. At that time, average cytoplasmic mRNA expression from α and β genes decreased, relative to levels at 3 hpi, while γ 1 relative expression increased slightly and γ 2 expression increased more substantially. Cycloheximide treatment during the first 3 h reduced the amount of Pol II associated with the viral genome and confined most of the remaining Pol II to α gene PPP sites. Inhibition of both cyclin-dependent kinase 9 activity and viral DNA replication reduced Pol II on the viral genome and restricted much of the remaining Pol II to PPP sites. IMPORTANCE These data suggest that viral transcription is regulated not only by Pol II recruitment to viral genes but also by control of elongation into viral gene bodies. We provide a detailed map of Pol II occupancy on the HSV-1 genome that clarifies features of the viral transcriptome, including the first identification of Pol II PPP sites. The data indicate that Pol II is recruited to late genes early in infection. Comparing α and β gene occupancy at PPP sites and gene bodies suggests that Pol II is released more efficiently into the bodies of β genes than α genes at 3 hpi and that repression of α gene expression late in infection is mediated by prolonged promoter-proximal pausing. In addition, DNA replication is required to maintain full Pol II occupancy on viral DNA and to promote elongation on late genes later in infection., (Copyright © 2020 American Society for Microbiology.)

Published

2020

6. Herpes Simplex Virus 1 Dramatically Alters Loading and Positioning of RNA Polymerase II on Host Genes Early in Infection.

Author

Birkenheuer CH, Danko CG, and Baines JD

Subjects

Carcinoma, Squamous Cell genetics, Carcinoma, Squamous Cell metabolism, Carcinoma, Squamous Cell virology, Chromatin Immunoprecipitation, High-Throughput Nucleotide Sequencing, Humans, Laryngeal Neoplasms genetics, Laryngeal Neoplasms metabolism, Laryngeal Neoplasms virology, Promoter Regions, Genetic, RNA, Messenger genetics, Transcriptional Activation, Tumor Cells, Cultured, Herpes Simplex virology, Herpesvirus 1, Human physiology, Host-Pathogen Interactions, RNA Polymerase II metabolism, RNA, Messenger metabolism, Transcription, Genetic, Virus Replication

Abstract

Herpes simplex virus 1 (HSV-1) transcription is mediated by cellular RNA polymerase II (Pol II). Recent studies investigating how Pol II transcription of host genes is altered after HSV-1 are conflicting. Chromatin immunoprecipitation sequencing (ChIP-seq) studies suggest that Pol II is almost completely removed from host genes at 4 h postinfection (hpi), while 4-thiouridine (4SU) labeling experiments show that host transcription termination is extended at 7 hpi, implying that a significant amount of Pol II remains associated with host genes in infected cells. To address this discrepancy, we used precision nuclear run-on analysis (PRO-seq) to determine the location of Pol II to single-base-pair resolution in combination with quantitative reverse transcription-PCR (qRT-PCR) analysis at 3 hpi. HSV-1 decreased Pol II on approximately two-thirds of cellular genes but increased Pol II on others. For more than 85% of genes for which transcriptional termination could be statistically assessed, Pol II was displaced to positions downstream of the normal termination zone, suggesting extensive termination defects. Pol II amounts at the promoter, promoter-proximal pause site, and gene body were also modulated in a gene-specific manner. qRT-PCR of selected RNAs showed that HSV-1-induced extension of the termination zone strongly correlated with decreased RNA and mRNA accumulation. However, HSV-1-induced increases of Pol II occupancy on genes without termination zone extension correlated with increased cytoplasmic mRNA. Functional grouping of genes with increased Pol II occupancy suggested an upregulation of exosome secretion and downregulation of apoptosis, both of which are potentially beneficial to virus production. IMPORTANCE This study provides a map of RNA polymerase II location on host genes after infection with HSV-1 with greater detail than previous ChIP-seq studies and rectifies discrepancies between ChIP-seq data and 4SU labeling experiments with HSV-1. The data show the effects that a given change in RNA Pol II location on host genes has on the abundance of different RNA types, including nuclear, polyadenylated mRNA and cytoplasmic, polyadenylated mRNA. It gives a clearer understanding of how HSV-1 augments host transcription of some genes to provide an environment favorable to HSV-1 replication., (Copyright © 2018 American Society for Microbiology.)

Published

2018

7. A Domain of Herpes Simplex Virus pU L 33 Required To Release Monomeric Viral Genomes from Cleaved Concatemeric DNA.

Author

Yang K, Dang X, and Baines JD

Subjects

Animals, Cell Line, Chlorocebus aethiops, Chromosomes, Artificial, Bacterial, DNA Packaging, DNA, Viral genetics, Electrophoresis, Gel, Pulsed-Field, Herpesvirus 1, Human enzymology, Humans, Vero Cells, Viral Proteins genetics, Virus Replication, DNA, Concatenated metabolism, DNA, Viral metabolism, Genome, Viral, Herpesvirus 1, Human genetics, Herpesvirus 1, Human physiology, Viral Proteins metabolism, Virus Assembly

Abstract

Monomeric herpesvirus DNA is cleaved from concatemers and inserted into preformed capsids through the actions of the viral terminase. The terminase of herpes simplex virus (HSV) is composed of three subunits encoded by U L 15, U L 28, and U L 33. The U L 33-encoded protein (pU L 33) interacts with pU L 28, but its precise role in the DNA cleavage and packaging reaction is unclear. To investigate the function of pU L 33, we generated a panel of recombinant viruses with either deletions or substitutions in the most conserved regions of U L 33 using a bacterial artificial chromosome system. Deletion of 11 amino acids (residues 50 to 60 or residues 110 to 120) precluded viral replication, whereas the truncation of the last 10 amino acids from the pU L 33 C terminus did not affect viral replication or the interaction of pU L 33 with pU L 28. Mutations that replaced the lysine at codon 110 and the arginine at codon 111 with alanine codons failed to replicate, and the pU L 33 mutant interacted with pU L 28 less efficiently. Interestingly, genomic termini of the large (L) and small (S) components were detected readily in cells infected with these mutants, indicating that concatemeric DNA was cleaved efficiently. However, the release of monomeric genomes as assessed by pulsed-field gel electrophoresis was greatly diminished, and DNA-containing capsids were not observed. These results suggest that pU L 33 is necessary for one of the two viral DNA cleavage events required to release individual genomes from concatemeric viral DNA. IMPORTANCE This paper shows a role for pU L 33 in one of the two DNA cleavage events required to release monomeric genomes from concatemeric viral DNA. This is the first time that such a phenotype has been observed and is the first identification of a function of this protein relevant to DNA packaging other than its interaction with other terminase components., (Copyright © 2017 Yang et al.)

Published

2017

8. A mutation in the DNA polymerase accessory factor of herpes simplex virus 1 restores viral DNA replication in the presence of raltegravir.

Author

Zhou B, Yang K, Wills E, Tang L, and Baines JD

Subjects

Animals, Cell Line, Chlorocebus aethiops, Cytomegalovirus drug effects, Cytomegalovirus genetics, DNA, Viral genetics, Drug Resistance, Viral genetics, Gene Expression Regulation, Viral drug effects, Herpesvirus 1, Human genetics, Herpesvirus 2, Human drug effects, Herpesvirus 2, Human genetics, Humans, Mice, Models, Molecular, Muromegalovirus drug effects, Muromegalovirus genetics, Raltegravir Potassium, Transcription, Genetic drug effects, Antiviral Agents pharmacology, DNA Replication drug effects, DNA-Directed DNA Polymerase genetics, Exodeoxyribonucleases genetics, Herpesvirus 1, Human drug effects, Mutation, Pyrrolidinones pharmacology, Viral Proteins genetics

Abstract

Unlabelled: Previous reports showed that raltegravir, a recently approved antiviral compound that targets HIV integrase, can inhibit the nuclease function of human cytomegalovirus (HCMV terminase) in vitro. In this study, subtoxic levels of raltegravir were shown to inhibit the replication of four different herpesviruses, herpes simplex virus 1 (HSV-1), HSV-2, HCMV, and mouse cytomegalovirus, by 30- to 700-fold, depending on the dose and the virus tested. Southern blotting and quantitative PCR revealed that raltegravir inhibits DNA replication of HSV-1 rather than cleavage of viral DNA. A raltegravir-resistant HSV-1 mutant was generated by repeated passage in the presence of 200 μM raltegravir. The genomic sequence of the resistant virus, designated clone 7, contained mutations in 16 open reading frames. Of these, the mutations F198S in unique long region 15 (UL15; encoding the large terminase subunit), A374V in UL32 (required for DNA cleavage and packaging), V296I in UL42 (encoding the DNA polymerase accessory factor), and A224S in UL54 (encoding ICP27, an important transcriptional regulator) were introduced independently into the wild-type HSV-1(F) genome, and the recombinant viruses were tested for raltegravir resistance. Viruses bearing both the UL15 and UL32 mutations inserted within the genome of the UL42 mutant were also tested. While the UL15, UL32, and UL54 mutant viruses were fully susceptible to raltegravir, any virus bearing the UL42 mutation was as resistant to raltegravir as clone 7. Overall, these results suggest that raltegravir may be a valuable therapeutic agent against herpesviruses and the antiviral activity targets the DNA polymerase accessory factor rather than the nuclease activity of the terminase., Importance: This paper shows that raltegravir, the antiretrovirus drug targeting integrase, is effective against various herpesviruses. Drug resistance mapped to the herpesvirus DNA polymerase accessory factor, which was an unexpected finding., (Copyright © 2014, American Society for Microbiology. All Rights Reserved.)

Published

2014

9. The herpes simplex virus 1 UL51 gene product has cell type-specific functions in cell-to-cell spread.

Author

Roller RJ, Haugo AC, Yang K, and Baines JD

Subjects

Amino Acid Sequence, Animals, Chlorocebus aethiops, Herpesvirus 1, Human chemistry, Herpesvirus 1, Human genetics, Humans, Molecular Sequence Data, Phosphoproteins chemistry, Phosphoproteins genetics, Sequence Alignment, Vero Cells, Viral Proteins chemistry, Viral Proteins genetics, Virus Release, Virus Replication, Herpes Simplex virology, Herpesvirus 1, Human physiology, Phosphoproteins metabolism, Viral Proteins metabolism

Abstract

Unlabelled: The herpes simplex virus 1 (HSV-1) UL51 gene encodes a 244-amino-acid (aa) palmitoylated protein that is conserved in all herpesviruses. The alphaherpesvirus UL51 (pUL51) protein has been reported to function in nuclear egress and cytoplasmic envelopment. No complete deletion has been generated because of the overlap of the UL51 coding sequence 5' end with the UL52 promoter sequences, but partial deletions generated in HSV and pseudorabies virus (PrV) suggest an additional function in epithelial cell-to-cell spread. Here we show partial uncoupling of the replication, release, and cell-to-cell spread functions of HSV-1 pUL51 in two ways. Viruses in which aa 73 to 244 were deleted from pUL51 or in which a conserved YXXΦ motif near the N terminus was altered showed cell-specific defects in spread that cannot be accounted for by defects in replication and virus release. Also, a cell line that expresses C-terminally enhanced green fluorescent protein (EGFP)-tagged pUL51 supported normal virus replication and release into the medium but the formation of only small plaques. This cell line also failed to support normal localization of gE to cell junctions. gE and pUL51 partially colocalized in infected cells, and these two proteins could be coimmunoprecipitated from infected cells, suggesting that they can form a complex during infection. The cell-to-cell spread defect associated with the pUL51 mutation was more severe than that associated with gE-null virus, suggesting that pUL51 has gE-independent functions in epithelial cell spread., Importance: Herpesviruses establish and reactivate from lifelong latency in their hosts. When they reactivate, they are able to spread within their hosts despite the presence of a potent immune response that includes neutralizing antibody. This ability is derived in part from a specialized mechanism for virus spread between cells. Cell-to-cell spread is a conserved property of herpesviruses that likely relies on conserved viral genes. An understanding of their function may aid in the design of vaccines and therapeutics. Here we show that one of the conserved viral genes, UL51, has an important role in cell-to-cell spread in addition to its previously demonstrated role in virus assembly. We find that its function depends on the type of cell that is infected, and we show that it interacts with and modulates the function of another viral spread factor, gE.

Published

2014

10. The structure of the herpes simplex virus DNA-packaging terminase pUL15 nuclease domain suggests an evolutionary lineage among eukaryotic and prokaryotic viruses.

Author

Selvarajan Sigamani S, Zhao H, Kamau YN, Baines JD, and Tang L

Subjects

Animals, Crystallization, Crystallography, X-Ray, DNA, Viral genetics, Endodeoxyribonucleases genetics, Endodeoxyribonucleases metabolism, Endonucleases genetics, Endonucleases metabolism, Eukaryota virology, Herpesvirus 1, Human genetics, Humans, Models, Molecular, Molecular Sequence Data, Virus Assembly, Bacteriophages genetics, DNA Packaging, DNA, Viral metabolism, Endodeoxyribonucleases chemistry, Endonucleases chemistry, Evolution, Molecular, Herpesviridae genetics, Herpesvirus 1, Human enzymology

Abstract

Herpes simplex virus 1 (HSV-1), the prototypic member of herpesviruses, employs a virally encoded molecular machine called terminase to package the viral double-stranded DNA (dsDNA) genome into a preformed protein shell. The terminase contains a large subunit that is thought to cleave concatemeric viral DNA during the packaging initiation and completion of each packaging cycle and supply energy to the packaging process via ATP hydrolysis. We have determined the X-ray structure of the C-terminal domain of the terminase large-subunit pUL15 (pUL15C) from HSV-1. The structure shows a fold resembling those of bacteriophage terminases, RNase H, integrases, DNA polymerases, and topoisomerases, with an active site clustered with acidic residues. Docking analysis reveals a DNA-binding surface surrounded by flexible loops, indicating considerable conformational changes upon DNA binding. In vitro assay shows that pUL15C possesses non-sequence-specific, Mg(2+)-dependent nuclease activity. These results suggest that pUL15 uses an RNase H-like, metal ion-mediated catalysis mechanism for cleavage of viral concatemeric DNA. The structure reveals extra structural elements in addition to the RNase H-like fold core and variations in local architecture of the nuclease active site, which are conserved in herpesvirus terminases and bear great similarity to the phage T4 gp17 but are distinct from podovirus and siphovirus orthologs and cellular RNase H, delineating a new evolutionary lineage among a large family of eukaryotic viruses and simple and complex prokaryotic viruses.

Published

2013

11. A herpes simplex virus scaffold peptide that binds the portal vertex inhibits early steps in viral replication.

Author

Yang K, Wills E, and Baines JD

Subjects

Amino Acid Sequence, Animals, Antiviral Agents chemical synthesis, Antiviral Agents metabolism, Antiviral Agents pharmacology, Capsid chemistry, Capsid metabolism, Capsid Proteins genetics, Cell Line, DNA Replication, Drosophila metabolism, Herpesvirus 1, Human drug effects, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Humans, Insect Proteins genetics, Insect Proteins metabolism, Insect Proteins pharmacology, Microscopy, Electron, Microscopy, Fluorescence, Molecular Sequence Data, Mutation, Peptides chemical synthesis, Peptides genetics, Capsid Proteins metabolism, Capsid Proteins pharmacology, Herpesvirus 1, Human physiology, Peptides metabolism, Peptides pharmacology, Virus Replication drug effects

Abstract

Previous experiments identified a 12-amino-acid (aa) peptide that was sufficient to interact with the herpes simplex virus 1 (HSV-1) portal protein and was necessary to incorporate the portal into capsids. In the present study, cells were treated at various times postinfection with peptides consisting of a portion of the Drosophila antennapedia protein, previously shown to enter cells efficiently, fused to either wild-type HSV-1 scaffold peptide (YPYYPGEARGAP) or a control peptide that contained changes at positions 4 and 5. These 4-tyrosine and 5-proline residues are highly conserved in herpesvirus scaffold proteins and were previously shown to be critical for the portal interaction. Treatment early in infection with subtoxic levels of wild-type peptide reduced viral infectivity by over 1,000-fold, while the mutant peptide had little effect on viral yields. In cells infected for 3 h in the presence of wild-type peptide, capsids were observed to transit to the nuclear rim normally, as viewed by fluorescence microscopy. However, observation by electron microscopy in thin sections revealed an aberrant and significant increase of DNA-containing capsids compared to infected cells treated with the mutant peptide. Early treatment with peptide also prevented formation of viral DNA replication compartments. These data suggest that the antiviral peptide stabilizes capsids early in infection, causing retention of DNA within them, and that this activity correlates with peptide binding to the portal protein. The data are consistent with the hypothesis that the portal vertex is the conduit through which DNA is ejected to initiate infection.

Published

2013

12. Release of the herpes simplex virus 1 protease by self cleavage is required for proper conformation of the portal vertex.

Author

Yang K, Wills EG, and Baines JD

Subjects

Animals, Capsid Proteins chemistry, Capsid Proteins genetics, Cell Line, Herpesvirus 1, Human chemistry, Herpesvirus 1, Human genetics, Humans, Proteolysis, Viral Proteins chemistry, Viral Proteins genetics, Virus Assembly, Capsid Proteins metabolism, Herpes Simplex virology, Herpesvirus 1, Human enzymology, Herpesvirus 1, Human physiology, Viral Proteins metabolism

Abstract

We identify an NLS within herpes simplex virus scaffold proteins that is required for optimal nuclear import of these proteins into infected or uninfected nuclei, and is sufficient to mediate nuclear import of GFP. A virus lacking this NLS replicated to titers reduced by 1000-fold, but was able to make capsids containing both scaffold and portal proteins suggesting that other functions can complement the NLS in infected cells. We also show that Vp22a, the major scaffold protein, is sufficient to mediate the incorporation of portal protein into capsids, whereas proper portal immunoreactivity in the capsid requires the larger scaffold protein pU(L)26. Finally, capsid angularization in infected cells did not require the HSV-1 protease unless full length pU(L)26 was expressed. These data suggest that the HSV-1 portal undergoes conformational changes during capsid maturation, and reveal that full length pU(L)26 is required for this conformational change., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

13. Deletion of UL21 causes a delay in the early stages of the herpes simplex virus 1 replication cycle.

Author

Mbong EF, Woodley L, Frost E, Baines JD, and Duffy C

Subjects

Cell Line, Herpesvirus 1, Human genetics, Humans, Viral Proteins metabolism, Down-Regulation, Gene Deletion, Herpes Simplex virology, Herpesvirus 1, Human physiology, Viral Proteins genetics, Virus Replication

Abstract

The herpes simplex virus 1 (HSV-1) U(L)21 gene encodes a 62-kDa tegument protein with homologs in the alpha-, beta-, and gammaherpesvirus subfamilies. In the present study, we characterized a novel U(L)21-null virus and its genetic repair to determine whether this protein plays a role in early stages of the HSV-1 replication cycle. Single-step growth analyses, protein synthesis time courses, and mRNA quantifications indicated that the absence of U(L)21 results in a delay early in the HSV-1 replication cycle.

Published

2012

14. A mutation in UL15 of herpes simplex virus 1 that reduces packaging of cleaved genomes.

Author

Yang K, Wills EG, and Baines JD

Subjects

Animals, Capsid metabolism, Cell Line, Genetic Complementation Test, Herpesvirus 1, Human genetics, Mutant Proteins genetics, Mutant Proteins metabolism, Viral Proteins genetics, DNA, Viral metabolism, Herpesvirus 1, Human physiology, Sequence Deletion, Viral Proteins metabolism, Virus Assembly

Abstract

Herpesvirus genomic DNA is cleaved from concatemers that accumulate in infected cell nuclei. Genomic DNA is inserted into preassembled capsids through a unique portal vertex. Extensive analyses of viral mutants have indicated that intact capsids, the portal vertex, and all components of a tripartite terminase enzyme are required to both cleave and package viral DNA, suggesting that DNA cleavage and packaging are inextricably linked. Because the processes have not been functionally separable, it has been difficult to parse the roles of individual proteins in the DNA cleavage/packaging reaction. In the present study, a virus bearing the deletion of codons 400 to 420 of U(L)15, encoding a terminase component, was analyzed. This virus, designated vJB27, failed to replicate on noncomplementing cells but cleaved concatemeric DNA to ca. 35 to 98% of wild-type levels. No DNA cleavage was detected in cells infected with a U(L)15-null virus or a virus lacking U(L)15 codons 383 to 385, comprising a motif proposed to couple ATP hydrolysis to DNA translocation. The amount of vJB27 DNA protected from DNase I digestion was reduced compared to the wild-type virus by 6.5- to 200-fold, depending on the DNA fragment analyzed, thus indicating a profound defect in DNA packaging. Capsids containing viral DNA were not detected in vJB27-infected cells, as determined by electron microscopy. These data suggest that pU(L)15 plays an essential role in DNA translocation into the capsid and indicate that this function is separable from its role in DNA cleavage.

Published

2011

15. Selection of HSV capsids for envelopment involves interaction between capsid surface components pUL31, pUL17, and pUL25.

Author

Yang K and Baines JD

Subjects

Animals, Cell Line, Centrifugation, Density Gradient, Immunoblotting, Immunoprecipitation, Models, Biological, Nuclear Proteins metabolism, Protein Binding, Capsid metabolism, Herpesvirus 1, Human metabolism, Viral Proteins metabolism

Abstract

During egress from the nucleus, HSV capsids that contain DNA (termed C capsids) are preferentially enveloped at the inner nuclear membrane over capsid types lacking DNA. Using coimmunoprecipitation and biochemical analyses of wild-type and mutant capsids, we identify an interaction between a complex of pU(L)17/pU(L)25, termed the C capsid-specific complex (CCSC), and pU(L)31, a component of the nuclear egress complex (NEC). We also show that the interactions between these components are dependent on expression of all three proteins but occur independently of the pU(L)31 interacting protein and NEC component pU(L)34, as well as a kinase encoded by U(S)3 that phosphorylates both pU(L)31 and pU(L)34. The interaction between the CCSC and pU(L)31 in the NEC suggests a mechanism to conserve viral resources by promoting assembly of only those viral particles with the potential to become infectious.

Published

2011

16. UL31 of herpes simplex virus 1 is necessary for optimal NF-kappaB activation and expression of viral gene products.

Author

Roberts KL and Baines JD

Subjects

Animals, Cell Line, Gene Deletion, Herpesvirus 1, Human growth & development, Humans, Nuclear Proteins genetics, Viral Proteins genetics, Viral Proteins metabolism, Gene Expression, Herpesvirus 1, Human pathogenicity, Host-Pathogen Interactions, NF-kappa B metabolism, Nuclear Proteins metabolism, Viral Proteins biosynthesis

Abstract

Previous results suggested that the U(L)31 gene of herpes simplex virus 1 (HSV-1) is required for envelopment of nucleocapsids at the inner nuclear membrane and optimal viral DNA synthesis and DNA packaging. In the current study, viral gene expression and NF-κB and c-Jun N-terminal kinase (JNK) activation of a herpes simplex virus mutant lacking the U(L)31 gene, designated ΔU(L)31, and its genetic repair construct, designated ΔU(L)31-R, were studied in various cell lines. In Hep2 and Vero cells infected with ΔU(L)31, expression of the immediate-early protein ICP4, early protein ICP8, and late protein glycoprotein C (gC) were delayed significantly. In Hep2 cells, expression of these proteins failed to reach levels seen in cells infected with ΔU(L)31-R or wild-type HSV-1(F) even after 18 h. The defect in protein accumulation correlated with poor or no activation of NF-κB and JNK upon infection with ΔU(L)31 compared to wild-type virus infection. The protein expression defects of the U(L)31 deletion mutant were not explainable by a failure to enter nonpermissive cells and were not complemented in an ICP27-expressing cell line. These data suggest that pU(L)31 facilitates initiation of infection and/or accelerates the onset of viral gene expression in a manner that correlates with NF-κB activation and is independent of the transactivator ICP27. The effects on very early events in expression are surprising in light of the fact that U(L)31 is designated a late gene and pU(L)31 is not a virion component. We show herein that while most pUL31 is expressed late in infection, low levels of pU(L)31 are detectable as early as 2 h postinfection, consistent with an early role in HSV-1 infection.

Published

2011

17. Myosin Va enhances secretion of herpes simplex virus 1 virions and cell surface expression of viral glycoproteins.

Author

Roberts KL and Baines JD

Subjects

Base Sequence, Biological Transport, Active, Cell Membrane virology, Cytoplasm virology, DNA Primers genetics, Epitopes metabolism, HeLa Cells, Herpesvirus 1, Human pathogenicity, Host-Pathogen Interactions physiology, Humans, Membrane Fusion physiology, Mutant Proteins genetics, Mutant Proteins metabolism, Myosin Heavy Chains genetics, Myosin Heavy Chains immunology, Myosin Type V genetics, Myosin Type V immunology, Recombinant Proteins genetics, Recombinant Proteins immunology, Recombinant Proteins metabolism, Virion physiology, trans-Golgi Network virology, Herpesvirus 1, Human physiology, Myosin Heavy Chains physiology, Myosin Type V physiology, Viral Structural Proteins physiology, Virus Release physiology

Abstract

The final step in the egress of herpes simplex virus (HSV) virions requires virion-laden vesicles to bypass cortical actin and fuse with the plasma membrane, releasing virions into the extracellular space. Little is known about the host or viral proteins involved. In the current study, we noted that the conformation of myosin Va (myoVa), a protein known to be involved in melanosome and secretory granule trafficking to the plasma membrane in melanocytes and neuroendocrine cells, respectively, was altered by 4 h after infection with HSV-1 such that an N-terminal epitope expected to be masked in its inactive state was rendered immunoreactive. Wild-type myoVa localized throughout the cytoplasm and to a limited extent in the nuclei of HSV-infected cells. Two different dominant negative myoVa molecules containing cargo-binding domains but lacking the lever arms and actin-binding domains colocalized with markers of the trans-Golgi network (TGN). Expression of dominant negative myoVa isoforms reduced secretion of HSV-1 infectivity into the medium by 50 to 75%, reduced surface expression of glycoproteins B, M, and D, and increased intracellular virus infectivity to levels consistent with increased retention of virions in the cytoplasm. These data suggest that myoVa is activated during HSV-1 infection to help transport virion- and glycoprotein-laden vesicles from the TGN, through the cortical actin, to the plasma membrane. We cannot exclude a role for myoVa in promoting fusion of these vesicles with the inner surface of the plasma membrane. These data also indicate that myoVa is involved in exocytosis in human epithelial cells as well as other cell types.

Published

2010

18. The capsid protein encoded by U(L)17 of herpes simplex virus 1 interacts with tegument protein VP13/14.

Author

Scholtes LD, Yang K, Li LX, and Baines JD

Subjects

Animals, Cell Line, Cell Membrane chemistry, Chromatography, Affinity, Cytoplasm chemistry, Humans, Immunoprecipitation, Mass Spectrometry, Protein Binding, Herpesvirus 1, Human physiology, Protein Interaction Mapping, Viral Fusion Proteins metabolism, Viral Proteins metabolism

Abstract

The U(L)17 protein (pU(L)17) of herpes simplex virus 1 (HSV-1) likely associates with the surfaces of DNA-containing capsids in a heterodimer with pU(L)25. pU(L)17 is also associated with viral light particles that lack capsid proteins, suggesting its presence in the tegument of the HSV-1 virion. To help determine how pU(L)17 becomes incorporated into virions and its functions therein, we identified pU(L)17-interacting proteins by immunoprecipitation with pU(L)17-specific IgY at 16 h postinfection, followed by mass spectrometry. Coimmunoprecipitated proteins included cellular histone proteins H2A, H3, and H4; the intermediate filament protein vimentin; the major HSV-1 capsid protein VP5; and the HSV tegument proteins VP11/12 (pU(L)46) and VP13/14 (pU(L)47). The pU(L)17-VP13/14 interaction was confirmed by coimmunoprecipitation in the presence and absence of intact capsids and by affinity copurification of pU(L)17 and VP13/14 from lysates of cells infected with a recombinant virus encoding His-tagged pU(L)17. pU(L)17 and VP13/14-HA colocalized in the nuclear replication compartment, in the cytoplasm, and at the plasma membrane between 9 and 18 h postinfection. One possible explanation of these data is that pU(L)17 links the external face of the capsid to VP13/14 and associated tegument components.

Published

2010

19. Tryptophan residues in the portal protein of herpes simplex virus 1 critical to the interaction with scaffold proteins and incorporation of the portal into capsids.

Author

Yang K and Baines JD

Subjects

Animals, Capsid Proteins genetics, Capsid Proteins physiology, Cell Line, Herpesvirus 1, Human genetics, Mutagenesis, Site-Directed, Rabbits, Sequence Alignment, Tryptophan, Viral Proteins genetics, Viral Structural Proteins genetics, Virus Assembly genetics, Herpesvirus 1, Human physiology, Viral Proteins physiology, Viral Structural Proteins physiology, Virus Assembly physiology

Abstract

Incorporation of the herpes simplex virus 1 (HSV-1) portal vertex into the capsid requires interaction with a 12-amino-acid hydrophobic domain within capsid scaffold proteins. The goal of this work was to identify domains and residues in the UL6-encoded portal protein pUL6 critical to the interaction with scaffold proteins. We show that whereas the wild-type portal and scaffold proteins readily coimmunoprecipitated with one another in the absence of other viral proteins, truncation beyond the first 18 or last 36 amino acids of the portal protein precluded this coimmunoprecipitation. The coimmunoprecipitation was also precluded by mutation of conserved tryptophan (W) residues to alanine (A) at positions 27, 90, 127, 163, 241, 262, 532, and 596 of UL6. All of these W-to-A mutations precluded the rescue of a viral deletion mutant lacking UL6, except W163A, which supported replication poorly, and W596A, which fully rescued replication. A recombinant virus bearing the W596A mutation replicated and packaged DNA normally, and scaffold proteins readily coimmunoprecipitated with portal protein from lysates of infected cells. Thus, viral functions compensated for the W596A mutation's detrimental effects on the portal-scaffold interaction seen during transient expression of portal and scaffold proteins. In contrast, the W27A mutation precluded portal-scaffold interactions in infected cell lysates, reduced the solubility of pUL6, decreased incorporation of the portal into capsids, and abrogated viral-DNA cleavage and packaging.

Published

2009

20. Proline and tyrosine residues in scaffold proteins of herpes simplex virus 1 critical to the interaction with portal protein and its incorporation into capsids.

Author

Yang K and Baines JD

Subjects

Amino Acid Sequence, Animals, Capsid chemistry, Capsid Proteins chemistry, Capsid Proteins genetics, Cell Line, Chlorocebus aethiops, Herpesvirus 1, Human chemistry, Herpesvirus 1, Human genetics, Molecular Sequence Data, Nuclear Matrix-Associated Proteins genetics, Proline genetics, Proline metabolism, Protein Binding, Rabbits, Tyrosine genetics, Tyrosine metabolism, Virus Assembly, Virus Replication, Capsid metabolism, Capsid Proteins metabolism, Herpesvirus 1, Human physiology, Nuclear Matrix-Associated Proteins chemistry, Nuclear Matrix-Associated Proteins metabolism

Abstract

Previous results showed that amino acids 449 to 457 of pU(L)26, a component of the scaffold of herpes simplex virus 1 capsids, were critical for interaction with the portal protein encoded by U(L)6 and for incorporation of the portal into capsids. To identify residues in this scaffold domain critical for the interaction with pU(L)6, the two proteins were coexpressed in the absence of other viral proteins and subjected to immunoprecipitation with scaffold-specific antibody. Coimmunoprecipitation of pU(L)6 was precluded by pU(L)26 mutations Y451A, P452A, and E454A but not by P449A, R456A, or Y450A. In infected cells, Y451A and P452A diminished solubilization of pU(L)6, reduced incorporation of the portal into the capsid, and precluded viral replication and DNA packaging. In contrast, E454A did not affect these parameters despite the fact that E454 is invariant in a number of different alphaherpesvirus scaffold proteins. These data suggest that the interaction between the scaffold E454A mutant and portal protein is rescued by other viral functions. Finally, we show that amino acids 448 to 459 of pU(L)26 are sufficient to interact with pU(L)6 in a glutathione S-transferase pulldown assay in the absence of other viral proteins and that this interaction is inhibited with excess peptide containing pU(L)26 amino acids 443 to 462. Together, these observations suggest that a direct interaction between this scaffold domain and portal protein mediates incorporation of the portal into the capsid.

Published

2009

21. Phosphorylation of the U(L)31 protein of herpes simplex virus 1 by the U(S)3-encoded kinase regulates localization of the nuclear envelopment complex and egress of nucleocapsids.

Author

Mou F, Wills E, and Baines JD

Subjects

Animals, Chlorocebus aethiops, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Humans, Nuclear Envelope virology, Phosphorylation, Rabbits, Vero Cells, Virus Assembly, Herpesvirus 1, Human physiology, Nuclear Proteins metabolism, Nucleocapsid metabolism, Protein Serine-Threonine Kinases metabolism, Viral Proteins metabolism

Abstract

Herpes simplex virus 1 nucleocapsids bud through the inner nuclear membrane (INM) into the perinuclear space to obtain a primary viral envelope. This process requires a protein complex at the INM composed of the U(L)31 and U(L)34 gene products. While it is clear that the viral kinase encoded by the U(S)3 gene regulates the localization of pU(L)31/pU(L)34 within the INM, the molecular mechanism by which this is accomplished remains enigmatic. Here, we have determined the following. (i) The N terminus of pU(L)31 is indispensable for the protein's normal function and contains up to six serines that are phosphorylated by the U(S)3 kinase during infection. (ii) Phosphorylation at these six serines was not essential for a productive infection but was required for optimal viral growth kinetics. (iii) In the presence of active U(S)3 kinase, changing the serines to alanine caused the pU(L)31/pU(L)34 complex to aggregate at the nuclear rim and caused some virions to accumulate aberrantly in herniations of the nuclear membrane, much as in cells infected with a U(S)3 kinase-dead mutant. (iv) The replacement of the six serines of pU(L)31 with glutamic acid largely restored the smooth distribution of pU(L)34/pU(L)31 at the nuclear membrane and precluded the accumulation of virions in herniations whether or not U(S)3 kinase was active but also precluded the optimal primary envelopment of nucleocapsids. These observations indicate that the phosphorylation of pU(L)31 by pU(S)3 represents an important regulatory event in the virion egress pathway that can account for much of pU(S)3's role in nuclear egress. The data also suggest that the dynamics of pU(L)31 phosphorylation modulate both the primary envelopment and the subsequent fusion of the nascent virion envelope with the outer nuclear membrane.

Published

2009

22. The putative leucine zipper of the UL6-encoded portal protein of herpes simplex virus 1 is necessary for interaction with pUL15 and pUL28 and their association with capsids.

Author

Yang K, Wills E, and Baines JD

Subjects

Animals, Cell Line, Chlorocebus aethiops, Epitopes immunology, Gene Deletion, Herpesvirus 1, Human chemistry, Herpesvirus 1, Human genetics, Herpesvirus 1, Human immunology, Rabbits, Viral Proteins chemistry, Viral Proteins genetics, Viral Proteins immunology, Virus Replication, Capsid metabolism, Herpesvirus 1, Human metabolism, Leucine Zippers, Viral Proteins metabolism

Abstract

Herpes simplex virus (HSV) type 1 capsids contain a single portal vertex that is composed of 12 copies of the U(L)6 gene product (pU(L)6), which forms a pore through which DNA is inserted during packaging. This unique vertex is also believed to comprise the site with which a molecular motor, termed the terminase, associates during the DNA packaging reaction. In HSV, the terminase likely comprises the U(L)15, U(L)28, and U(L)33 proteins (pU(L)15, pU(L)28, and pU(L)33, respectively). The current study was undertaken to identify portal domains required for interaction with the terminase. Both the amino and carboxyl termini, as well as amino acids 422 to 443 of pU(L)6 forming a putative leucine zipper motif, were critical for coimmunoprecipitation with pU(L)15 in the absence of other viral proteins. Amino acids 422 to 443 were also necessary for interaction with pU(L)28 in the absence of other viral proteins. By using an engineered recombinant virus, it was further determined that although amino acids 422 to 443 were dispensable for interaction with scaffold protein and incorporation of portal protein into capsids, they were necessary for coimmunoprecipitation of pU(L)6 and pU(L)15 from infected cell lysates, association of optimal levels of pU(L)15, pU(L)28, and pU(L)33 with capsids, and DNA cleavage and packaging. These data identify a portal protein domain critical for terminase association with the capsid and suggest that both the pU(L)15- and pU(L)28-bearing terminase subunits mediate docking of the terminase with the portal vertex.

Published

2009

23. The U(L)31 and U(L)34 gene products of herpes simplex virus 1 are required for optimal localization of viral glycoproteins D and M to the inner nuclear membranes of infected cells.

Author

Wills E, Mou F, and Baines JD

Subjects

Animals, Cell Line, Herpesvirus 1, Human metabolism, Humans, Microscopy, Electron, Rabbits, Virus Replication, Herpesvirus 1, Human physiology, Nuclear Envelope virology, Nuclear Proteins metabolism, Viral Envelope Proteins metabolism, Viral Proteins metabolism

Abstract

U(L)31 and U(L)34 of herpes simplex virus type 1 form a complex necessary for nucleocapsid budding at the inner nuclear membrane (INM). Previous examination by immunogold electron microscopy and electron tomography showed that pU(L)31, pU(L)34, and glycoproteins D and M are recruited to perinuclear virions and densely staining regions of the INM where nucleocapsids bud into the perinuclear space. We now show by quantitative immunogold electron microscopy coupled with analysis of variance that gD-specific immunoreactivity is significantly reduced at both the INM and outer nuclear membrane (ONM) of cells infected with a U(L)34 null virus. While the amount of gM associated with the nuclear membrane (NM) was only slightly (P = 0.027) reduced in cells infected with the U(L)34 null virus, enrichment of gM in the INM at the expense of that in the ONM was greatly dependent on U(L)34 (P < 0.0001). pU(L)34 also interacted directly or indirectly with immature forms of gD (species expected to reside in the endoplasmic reticulum or nuclear membrane) in lysates of infected cells and with the cytosolic tail of gD fused to glutathione S-transferase in rabbit reticulocyte lysates, suggesting a role for the pU(L)34/gD interaction in recruiting gD to the NM. The effects of U(L)34 on gD and gM localization were not a consequence of decreased total expression of gD and gM, as determined by flow cytometry. Separately, pU(L)31 was dispensable for targeting gD and gM to the two leaflets of the NM but was required for (i) the proper INM-versus-ONM ratio of gD and gM in infected cells and (ii) the presence of electron-dense regions in the INM, representing nucleocapsid budding sites. We conclude that in addition to their roles in nucleocapsid envelopment and lamina alteration, U(L)31 and U(L)34 play separate but related roles in recruiting appropriate components to nucleocapsid budding sites at the INM.

Published

2009

24. Herpesvirus gB-induced fusion between the virion envelope and outer nuclear membrane during virus egress is regulated by the viral US3 kinase.

Author

Wisner TW, Wright CC, Kato A, Kawaguchi Y, Mou F, Baines JD, Roller RJ, and Johnson DC

Subjects

Amino Acid Substitution genetics, Animals, Cell Line, Humans, Models, Biological, Mutagenesis, Site-Directed, Phosphorylation, Sequence Deletion, Viral Envelope Proteins genetics, Virion metabolism, Herpesvirus 1, Human physiology, Nuclear Envelope virology, Protein Serine-Threonine Kinases metabolism, Viral Envelope Proteins metabolism, Viral Proteins metabolism, Virus Internalization

Abstract

Herpesvirus capsids collect along the inner surface of the nuclear envelope and bud into the perinuclear space. Enveloped virions then fuse with the outer nuclear membrane (NM). We previously showed that herpes simplex virus (HSV) glycoproteins gB and gH act in a redundant fashion to promote fusion between the virion envelope and the outer NM. HSV mutants lacking both gB and gH accumulate enveloped virions in herniations, vesicles that bulge into the nucleoplasm. Earlier studies had shown that HSV mutants lacking the viral serine/threonine kinase US3 also accumulate herniations. Here, we demonstrate that HSV gB is phosphorylated in a US3-dependent manner in HSV-infected cells, especially in a crude nuclear fraction. Moreover, US3 directly phosphorylated the gB cytoplasmic (CT) domain in in vitro assays. Deletion of gB in the context of a US3-null virus did not add substantially to defects in nuclear egress. The majority of the US3-dependent phosphorylation of gB involved the CT domain and amino acid T887, a residue present in a motif similar to that recognized by US3 in other proteins. HSV recombinants lacking gH and expressing either gB substitution mutation T887A or a gB truncated at residue 886 displayed substantial defects in nuclear egress. We concluded that phosphorylation of the gB CT domain is important for gB-mediated fusion with the outer NM. This suggested a model in which the US3 kinase is incorporated into the tegument layer (between the capsid and envelope) in HSV virions present in the perinuclear space. By this packaging, US3 might be brought close to the gB CT tail, leading to phosphorylation and triggering fusion between the virion envelope and the outer NM.

Published

2009

25. VP22 of herpes simplex virus 1 promotes protein synthesis at late times in infection and accumulation of a subset of viral mRNAs at early times in infection.

Author

Duffy C, Mbong EF, and Baines JD

Subjects

Animals, Chlorocebus aethiops, Gene Deletion, Vero Cells, Viral Structural Proteins genetics, Viral Structural Proteins physiology, Herpesvirus 1, Human physiology, RNA, Messenger biosynthesis, RNA, Viral biosynthesis, Viral Nonstructural Proteins biosynthesis, Viral Structural Proteins biosynthesis

Abstract

VP22, encoded by the U(L)49 gene, is one of the most abundant proteins of the herpes simplex virus 1 (HSV-1) tegument. In the present study we show VP22 is required for optimal protein synthesis at late times in infection. Specifically, in the absence of VP22, viral proteins accumulated to wild-type levels until approximately 6 h postinfection. At that time, ongoing synthesis of most viral proteins dramatically decreased in the absence of VP22, whereas protein stability was not affected. Of the individual proteins we assayed, VP22 was required for optimal synthesis of the late viral proteins gE and gD and the immediate-early protein ICP0 but did not have discernible effects on accumulation of the immediate-early proteins ICP4 or ICP27. In addition, we found VP22 is required for the accumulation of a subset of mRNAs to wild-type levels at early, but not late, times in infection. Specifically, the presence of VP22 enhanced the accumulation of gE and gD mRNAs until approximately 9 h postinfection, but it had no discernible effect at later times in infection. Also, VP22 did not significantly affect ICP0 mRNA at any time in infection. Thus, the protein synthesis and mRNA phenotypes observed with the U(L)49-null virus are separable with regard to both timing during infection and the genes affected and suggest separate roles for VP22 in enhancing the accumulation of viral proteins and mRNAs. Finally, we show that VP22's effects on protein synthesis and mRNA accumulation occur independently of mutations in genes encoding the VP22-interacting partners VP16 and vhs.

Published

2009

26. Effects of lamin A/C, lamin B1, and viral US3 kinase activity on viral infectivity, virion egress, and the targeting of herpes simplex virus U(L)34-encoded protein to the inner nuclear membrane.

Author

Mou F, Wills EG, Park R, and Baines JD

Subjects

Animals, Chlorocebus aethiops, Fibroblasts metabolism, Humans, Mice, Mutation, Vero Cells, Gene Expression Regulation, Viral, Herpesvirus 1, Human metabolism, Lamin Type A metabolism, Lamin Type B metabolism, Nuclear Envelope metabolism, Protein Serine-Threonine Kinases metabolism, Viral Proteins metabolism, Virion metabolism

Abstract

Previous results indicated that the U(L)34 protein (pU(L)34) of herpes simplex virus 1 (HSV-1) is targeted to the nuclear membrane and is essential for nuclear egress of nucleocapsids. The normal localization of pU(L)34 and virions requires the U(S)3-encoded kinase that phosphorylates U(L)34 and lamin A/C. Moreover, pU(L)34 was shown to interact with lamin A in vitro. In the present study, glutathione S-transferase/pU(L)34 was shown to specifically pull down lamin A and lamin B1 from cellular lysates. To determine the role of these interactions on viral infectivity and pU(L)34 targeting to the inner nuclear membrane (INM), the localization of pU(L)34 was determined in LmnA(-/-) and LmnB1(-/-) mouse embryonic fibroblasts (MEFs) by indirect immunofluorescence and immunogold electron microscopy in the presence or absence of U(S)3 kinase activity. While pU(L)34 INM targeting was not affected by the absence of lamin B1 in MEFs infected with wild-type HSV as viewed by indirect immunofluorescence, it localized in densely staining scalloped-shaped distortions of the nuclear membrane in lamin B1 knockout cells infected with a U(S)3 kinase-dead virus. Lamin B1 knockout cells were relatively less permissive for viral replication than wild-type MEFs, with viral titers decreased at least 10-fold. The absence of lamin A (i) caused clustering of pU(L)34 in the nuclear rim of cells infected with wild-type virus, (ii) produced extensions of the INM bearing pU(L)34 protein in cells infected with a U(S)3 kinase-dead mutant, (iii) precluded accumulation of virions in the perinuclear space of cells infected with this mutant, and (iv) partially restored replication of this virus. The latter observation suggests that lamin A normally impedes viral infectivity and that U(S)3 kinase activity partially alleviates this impediment. On the other hand, lamin B1 is necessary for optimal viral replication, probably through its well-documented effects on many cellular pathways. Finally, neither lamin A nor B1 was absolutely required for targeting pU(L)34 to the INM, suggesting that this targeting is mediated by redundant functions or can be mediated by other proteins.

Published

2008

27. Domain within herpes simplex virus 1 scaffold proteins required for interaction with portal protein in infected cells and incorporation of the portal vertex into capsids.

Author

Yang K and Baines JD

Subjects

Animals, Cell Line, Chlorocebus aethiops, DNA, Viral metabolism, Hepatocytes chemistry, Hepatocytes virology, Herpesvirus 1, Human genetics, Humans, Immunoprecipitation, Microscopy, Electron, Transmission, Microscopy, Fluorescence, Protein Binding, Protein Structure, Tertiary, Rabbits, Sequence Deletion, Vero Cells, Viral Proteins chemistry, Viral Proteins genetics, Virus Assembly genetics, Capsid metabolism, Herpesvirus 1, Human physiology, Protein Interaction Mapping, Viral Proteins metabolism, Virus Assembly physiology

Abstract

The portal vertex of herpesvirus capsids serves as the conduit through which DNA is inserted during the assembly process. In herpes simplex virus (HSV), the portal is composed of 12 copies of the U(L)6 gene product, pU(L)6. Previous results identified a domain in the major capsid scaffold protein, ICP35, required for interaction with pU(L)6 and its incorporation into capsids formed in vitro (G. P. Singer et al., J. Virol. 74:6838-6848, 2005). In the current studies, pU(L)6 and scaffold proteins were found to coimmunoprecipitate from lysates of both HSV-infected cells and mammalian cells expressing scaffold proteins and pU(L)6. The coimmunoprecipitation of pU(L)6 and scaffold proteins was precluded upon deletion of codons 143 to 151 within U(L)26.5, encoding ICP35. While wild-type scaffold proteins colocalized with pU(L)6 when transiently coexpressed as viewed by indirect immunofluorescence, deletion of U(L)26.5 codons 143 to 151 precluded this colocalization. A recombinant herpes simplex virus, vJB11, was generated that lacked U(L)26.5 codons 143 to 151. A virus derived from this mutant but bearing a restored U(L)26.5 was also generated. vJB11 was unable to cleave or package viral DNA, whereas the restored virus packaged DNA normally. vJB11 produced ample numbers of B capsids in infected cells, but these lacked normal levels of pU(L)6. The deletion in U(L)26.5 also rendered pU(L)6 resistant to detergent extraction from vJB11-infected cells. These data indicate that, as was observed in vitro, amino acids 143 to 151 of ICP35 are critical for (i) interaction between scaffold proteins and pU(L)6 and (ii) incorporation of the HSV portal into capsids.

Published

2008

28. Temperature-sensitive mutations in the putative herpes simplex virus type 1 terminase subunits pUL15 and pUL33 preclude viral DNA cleavage/packaging and interaction with pUL28 at the nonpermissive temperature.

Author

Yang K, Poon AP, Roizman B, and Baines JD

Subjects

Amino Acid Substitution genetics, Capsid metabolism, Genes, Essential genetics, Genes, Essential physiology, Herpesvirus 1, Human genetics, Hot Temperature, Immunoprecipitation, Mutation, Missense, Protein Binding genetics, Viral Proteins genetics, Virus Replication genetics, Virus Replication physiology, DNA, Viral metabolism, Herpesvirus 1, Human physiology, Viral Proteins metabolism, Virus Assembly

Abstract

Terminases comprise essential components of molecular motors required to package viral DNA into capsids in a variety of DNA virus systems. Previous studies indicated that the herpes simplex virus type 1 U(L)15 protein (pU(L)15) interacts with the pU(L)28 moiety of a pU(L)28-pU(L)33 complex to form the likely viral terminase. In the current study, a novel temperature-sensitive mutant virus was shown to contain a mutation in U(L)33 codon 61 predicted to change threonine to proline. At the nonpermissive temperature, this virus, designated ts8-22, replicated viral DNA and produced capsids that became enveloped at the inner nuclear membrane but failed to form plaques or to cleave or package viral DNA. Incubation at the nonpermissive temperature also precluded coimmunoprecipitation of U(L)33 protein with its normal interaction partners encoded by U(L)28 and U(L)15 in ts8-22-infected cells and with pU(L)28 in transient-expression assays. Moreover, a temperature-sensitive mutation in U(L)15 precluded coimmunoprecipitation of pU(L)15 with the U(L)28 and U(L)33 proteins at the nonpermissive temperature. We conclude that interactions between putative terminase components are tightly linked to successful viral DNA cleavage and packaging.

Published

2008

29. Type I interferon production during herpes simplex virus infection is controlled by cell-type-specific viral recognition through Toll-like receptor 9, the mitochondrial antiviral signaling protein pathway, and novel recognition systems.

Author

Rasmussen SB, Sørensen LN, Malmgaard L, Ank N, Baines JD, Chen ZJ, and Paludan SR

Subjects

Animals, Antiviral Agents immunology, Cells, Cultured, Chlorocebus aethiops, Dendritic Cells cytology, Dendritic Cells immunology, Dendritic Cells virology, Female, Fibroblasts cytology, Fibroblasts immunology, Fibroblasts virology, Herpes Simplex virology, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Herpesvirus 2, Human genetics, Herpesvirus 2, Human metabolism, Interferon Type I immunology, Interferon-alpha biosynthesis, Interferon-beta biosynthesis, L Cells, Macrophages cytology, Macrophages immunology, Macrophages virology, Mice, Mice, Inbred C57BL, Rabbits, Spleen cytology, Spleen immunology, Toll-Like Receptor 9 deficiency, Toll-Like Receptor 9 genetics, Vero Cells, Virus Replication, Antiviral Agents metabolism, Gene Expression Regulation, Herpes Simplex immunology, Herpesvirus 1, Human pathogenicity, Herpesvirus 2, Human pathogenicity, Interferon Type I biosynthesis, Toll-Like Receptor 9 metabolism

Abstract

Recognition of viruses by germ line-encoded pattern recognition receptors of the innate immune system is essential for rapid production of type I interferon (IFN) and early antiviral defense. We investigated the mechanisms of viral recognition governing production of type I IFN during herpes simplex virus (HSV) infection. We show that early production of IFN in vivo is mediated through Toll-like receptor 9 (TLR9) and plasmacytoid dendritic cells, whereas the subsequent alpha/beta IFN (IFN-alpha/beta) response is derived from several cell types and induced independently of TLR9. In conventional DCs, the IFN response occurred independently of viral replication but was dependent on viral entry. Moreover, using a HSV-1 UL15 mutant, which fails to package viral DNA into the virion, we found that entry-dependent IFN induction also required the presence of viral genomic DNA. In macrophages and fibroblasts, where the virus was able to replicate, HSV-induced IFN-alpha/beta production was dependent on both viral entry and replication, and ablated in cells unable to signal through the mitochondrial antiviral signaling protein pathway. Thus, during an HSV infection in vivo, multiple mechanisms of pathogen recognition are active, which operate in cell-type- and time-dependent manners to trigger expression of type I IFN and coordinate the antiviral response.

Published

2007

30. Putative terminase subunits of herpes simplex virus 1 form a complex in the cytoplasm and interact with portal protein in the nucleus.

Author

Yang K, Homa F, and Baines JD

Subjects

Animals, Biological Transport, Cell Line, Cell Line, Tumor, Chlorocebus aethiops, Cytoplasm metabolism, Epitopes chemistry, Genome, Viral, Humans, Subcellular Fractions metabolism, Vero Cells, Virus Replication, Cell Nucleus virology, Cytoplasm virology, Endodeoxyribonucleases chemistry, Herpesvirus 1, Human enzymology, Herpesvirus 1, Human metabolism

Abstract

Herpes simplex virus (HSV) terminase is an essential component of the molecular motor that translocates DNA through the portal vertex in the capsid during DNA packaging. The HSV terminase is believed to consist of the UL15, UL28, and UL33 gene products (pUL15, pUL28, and pUL33, respectively), whereas the HSV type 1 portal vertex is encoded by UL6. Immunoprecipitation reactions revealed that pUL15, pUL28, and pUL33 interact in cytoplasmic and nuclear lysates. Deletion of a canonical nuclear localization signal (NLS) from pUL15 generated a dominant-negative protein that, when expressed in an engineered cell line, decreased the replication of wild-type virus up to 80-fold. When engineered into the genome of recombinant HSV, this mutation did not interfere with the coimmunoprecipitation of pUL15, pUL28, and pUL33 from cytoplasmic lysates of infected cells but prevented viral replication, most nuclear import of both pUL15 and pUL28, and coimmunoprecipitation of pUL15, pUL28, and pUL33 from nuclear lysates. When the pUL15/pUL28 interaction was reduced in infected cells by the truncation of the C terminus of pUL28, pUL28 remained in the cytoplasm. Whether putative terminase components localized in the nucleus or cytoplasm, pUL6 localized in infected cell nuclei, as viewed by indirect immunofluorescence. The finding that the portal and terminase do eventually interact was supported by the observation that pUL6 coimmunoprecipitated strongly with pUL15 and weakly with pUL28 from extracts of infected cells in 1.0 M NaCl. These data are consistent with the hypothesis that the pUL15/pUL28/pUL33 complex forms in the cytoplasm and that an NLS in pUL15 is used to import the complex into the nucleus where at least pUL15 and pUL28 interact with the portal to mediate DNA packaging.

Published

2007

31. UL20 protein functions precede and are required for the UL11 functions of herpes simplex virus type 1 cytoplasmic virion envelopment.

Author

Fulmer PA, Melancon JM, Baines JD, and Kousoulas KG

Subjects

Animals, Cell Line, Chlorocebus aethiops, Genotype, Herpesvirus 1, Human genetics, Herpesvirus 1, Human ultrastructure, Kinetics, Microscopy, Electron, Transmission, Mutation genetics, Phenotype, Viral Proteins genetics, Viral Proteins ultrastructure, Viral Structural Proteins genetics, Viral Structural Proteins ultrastructure, Virus Replication, Cytoplasm metabolism, Herpesvirus 1, Human metabolism, Viral Proteins metabolism, Viral Structural Proteins metabolism, Virion metabolism

Abstract

Egress of herpes simplex virus type 1 (HSV-1) from the nucleus of the infected cell to extracellular spaces involves a number of distinct steps, including primary envelopment by budding into the perinuclear space, de-envelopment into the cytoplasm, cytoplasmic reenvelopment, and translocation of enveloped virions to extracellular spaces. UL20/gK-null viruses are blocked in cytoplasmic virion envelopment and egress, as indicated by an accumulation of unenveloped or partially enveloped capsids in the cytoplasm. Similarly, UL11-null mutants accumulate unenveloped capsids in the cytoplasm. To assess whether UL11 and UL20/gK function independently or synergistically in cytoplasmic envelopment, recombinant viruses having either the UL20 or UL11 gene deleted were generated. In addition, a recombinant virus containing a deletion of both UL20 and UL11 genes was constructed using the HSV-1(F) genome cloned into a bacterial artificial chromosome. Ultrastructural examination of virus-infected cells showed that both UL20- and UL11-null viruses accumulated unenveloped capsids in the cytoplasm. However, the morphology and distribution of the accumulated capsids appeared to be distinct, with the UL11-null virions forming aggregates of capsids having diffuse tegument-derived material and the UL20-null virus producing individual capsids in close juxtaposition to cytoplasmic membranes. The UL20/UL11 double-null virions appeared morphologically similar to the UL20-null viruses. Experiments on the kinetics of viral replication revealed that the UL20/UL11 double-null virus replicated in a manner similar to the UL20-null virus. Additional experiments revealed that transiently expressed UL11 localized to the trans-Golgi network (TGN) independently of either gK or UL20. Furthermore, virus infection with the UL11/UL20 double-null virus did not alter the TGN localization of transiently expressed UL11 or UL20 proteins, indicating that these proteins did not interact. Taken together, these results show that the intracellular transport and TGN localization of UL11 is independent of UL20/gK functions, and that UL20/gK are required and function prior to UL11 protein in virion cytoplasmic envelopment.

Published

2007

32. Electron tomography of nascent herpes simplex virus virions.

Author

Baines JD, Hsieh CE, Wills E, Mannella C, and Marko M

Subjects

Animals, Capsid ultrastructure, Carcinoma, Squamous Cell pathology, Cell Line, Tumor, Chlorocebus aethiops, Humans, Imaging, Three-Dimensional, Laryngeal Neoplasms pathology, Vero Cells, Electrons, Herpes Simplex virology, Herpesvirus 1, Human ultrastructure, Tomography methods, Virion ultrastructure

Abstract

Cells infected with herpes simplex virus type 1 (HSV-1) were conventionally embedded or freeze substituted after high-pressure freezing and stained with uranyl acetate. Electron tomograms of capsids attached to or undergoing envelopment at the inner nuclear membrane (INM), capsids within cytoplasmic vesicles near the nuclear membrane, and extracellular virions revealed the following phenomena. (i) Nucleocapsids undergoing envelopment at the INM, or B capsids abutting the INM, were connected to thickened patches of the INM by fibers 8 to 19 nm in length and < or =5 nm in width. The fibers contacted both fivefold symmetrical vertices (pentons) and sixfold symmetrical faces (hexons) of the nucleocapsid, although relative to the respective frequencies of these subunits in the capsid, fibers engaged pentons more frequently than hexons. (ii) Fibers of similar dimensions bridged the virion envelope and surface of the nucleocapsid in perinuclear virions. (iii) The tegument of perinuclear virions was considerably less dense than that of extracellular virions; connecting fibers were observed in the former case but not in the latter. (iv) The prominent external spikes emanating from the envelope of extracellular virions were absent from perinuclear virions. (v) The virion envelope of perinuclear virions appeared denser and thicker than that of extracellular virions. (vi) Vesicles near, but apparently distinct from, the nuclear membrane in single sections were derived from extensions of the perinuclear space as seen in the electron tomograms. These observations suggest very different mechanisms of tegumentation and envelopment in extracellular compared with perinuclear virions and are consistent with application of the final tegument to unenveloped nucleocapsids in a compartment(s) distinct from the perinuclear space.

Published

2007

33. Glycoprotein M of herpes simplex virus 1 is incorporated into virions during budding at the inner nuclear membrane.

Author

Baines JD, Wills E, Jacob RJ, Pennington J, and Roizman B

Subjects

Cell Line, Fluorescent Antibody Technique, Indirect, Gene Deletion, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Herpesvirus 1, Human ultrastructure, Humans, Microscopy, Immunoelectron, Viral Envelope Proteins genetics, Virion ultrastructure, Herpesvirus 1, Human pathogenicity, Nuclear Envelope metabolism, Viral Envelope Proteins metabolism, Virion metabolism

Abstract

It is widely accepted that nucleocapsids of herpesviruses bud through the inner nuclear membrane (INM), but few studies have been undertaken to characterize the composition of these nascent virions. Such knowledge would shed light on the budding reaction at the INM and subsequent steps in the egress pathway. The present study focuses on glycoprotein M (gM), a type III integral membrane protein of herpes simplex virus 1 (HSV-1) that likely contains eight transmembrane domains. The results indicated that gM localized primarily at the perinuclear region, with especially bright staining near the nuclear membrane (NM). Immunogold electron microscopic analysis indicated that, like gB and gD (M. R. Torrisi et al., J. Virol. 66:554-561, 1992), gM localized within both leaflets of the NM, the envelopes of nascent virions that accumulate in the perinuclear space, and the envelopes of cytoplasmic and mature extracellular virus particles. Indirect immunofluorescence studies revealed that gM colocalized almost completely with a marker of the Golgi apparatus and partially with a marker of the trans-Golgi network (TGN), whether or not these markers were displaced to the perinuclear region during infection. gM was also located in punctate extensions and invaginations of the NM induced by the absence of a viral kinase encoded by HSV-1 U(S)3 and within virions located in these extensions. Our findings therefore support the proposition that gM, like gB and gD, becomes incorporated into the virion envelope upon budding through the INM. The localization of viral glycoproteins and Golgi and TGN markers to a perinuclear region may represent a mechanism to facilitate the production of infectious nascent virions, thereby increasing the amount of infectivity released upon cellular lysis.

Published

2007

34. Linker insertion mutations in the herpes simplex virus type 1 UL28 gene: effects on UL28 interaction with UL15 and UL33 and identification of a second-site mutation in the UL15 gene that suppresses a lethal UL28 mutation.

Author

Jacobson JG, Yang K, Baines JD, and Homa FL

Subjects

Amino Acid Sequence, Animals, Blotting, Southern, Chlorocebus aethiops, DNA Packaging genetics, Genetic Complementation Test, Immunoblotting, Immunoprecipitation, Molecular Sequence Data, Mutagenesis, Insertional, Sequence Analysis, DNA, Vero Cells, Herpesvirus 1, Human genetics, Mutation genetics, Viral Proteins genetics, Viral Proteins metabolism

Abstract

The UL28 protein of herpes simplex virus type 1 (HSV-1) is one of seven viral proteins required for the cleavage and packaging of viral DNA. Previous results indicated that UL28 interacts with UL15 and UL33 to form a protein complex (terminase) that is presumed to cleave concatemeric DNA into genome lengths. In order to define the functional domains of UL28 that are important for DNA cleavage/packaging, we constructed a series of HSV-1 mutants with linker insertion and nonsense mutations in UL28. Insertions that blocked DNA cleavage and packaging were found to be located in two regions of UL28: the first between amino acids 200 to 400 and the second between amino acids 600 to 740. Insertions located in the N terminus or in a region located between amino acids 400 and 600 did not affect virus replication. Insertions in the carboxyl terminus of the UL28 protein were found to interfere with the interaction of UL28 with UL33. In contrast, all of the UL28 insertion mutants were found to interact with UL15 but the interaction was reduced with mutants that failed to react with UL33. Together, these observations were consistent with previous conclusions that UL15 and UL33 interact directly with UL28 but interact only indirectly with each other. Revertant viruses that formed plaques on Vero cells were detected for one of the lethal UL28 insertion mutants. DNA sequence analysis, in combination with genetic complementation assays, demonstrated that a second-site mutation in the UL15 gene restored the ability of the revertant to cleave and package viral DNA. The isolation of an intergenic suppressor mutant provides direct genetic evidence of an association between the UL28 and UL15 proteins and demonstrates that this association is essential for DNA cleavage and packaging.

Published

2006

35. Herpes simplex virus 1 DNA packaging proteins encoded by UL6, UL15, UL17, UL28, and UL33 are located on the external surface of the viral capsid.

Author

Wills E, Scholtes L, and Baines JD

Subjects

Animals, Antibodies, Viral biosynthesis, Antibody Specificity, Capsid metabolism, Capsid ultrastructure, Capsid Proteins genetics, Capsid Proteins immunology, Capsid Proteins metabolism, Cell Line, Chickens, DNA, Viral genetics, DNA, Viral metabolism, Herpesvirus 1, Human immunology, Herpesvirus 1, Human physiology, Humans, Microscopy, Immunoelectron, Trypsin metabolism, Viral Proteins genetics, Virus Assembly, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Viral Proteins metabolism

Abstract

Studies to localize the herpes simplex virus 1 portal protein encoded by UL6, the putative terminase components encoded by UL15, UL 28, and UL33, the minor capsid proteins encoded by UL17, and the major scaffold protein ICP35 were conducted. ICP35 in B capsids was more resistant to trypsin digestion of intact capsids than pUL6, pUL15, pUL17, pUL28, or pUL33. ICP35 required sectioning of otherwise intact embedded capsids for immunoreactivity, whereas embedding and/or sectioning decreased the immunoreactivities of pUL6, pUL17, pUL28, and pUL33. Epitopes of pUL15 were recognized roughly equally well in both sectioned and unsectioned capsids. These data indicate that pUL6, pUL17, pUL28, pUL33, and at least some portion of pUL15 are located at the external surface of the capsid.

Published

2006

36. Characterization of a UL49-null mutant: VP22 of herpes simplex virus type 1 facilitates viral spread in cultured cells and the mouse cornea.

Author

Duffy C, Lavail JH, Tauscher AN, Wills EG, Blaho JA, and Baines JD

Subjects

Animals, Chlorocebus aethiops, Herpesvirus 1, Human genetics, Herpesvirus 1, Human pathogenicity, Male, Mice, Mice, Inbred BALB C, Plasmids, Vero Cells, Viral Structural Proteins genetics, Virion metabolism, Virus Replication, Cornea virology, Gene Deletion, Herpesvirus 1, Human physiology, Keratitis, Herpetic transmission, Keratitis, Herpetic virology, Viral Structural Proteins metabolism

Abstract

Herpes simplex virus type 1 (HSV-1) virions, like those of all herpesviruses, contain a proteinaceous layer termed the tegument that lies between the nucleocapsid and viral envelope. The HSV-1 tegument is composed of at least 20 different viral proteins of various stoichiometries. VP22, the product of the U(L)49 gene, is one of the most abundant tegument proteins and is conserved among the alphaherpesviruses. Although a number of interesting biological properties have been attributed to VP22, its role in HSV-1 infection is not well understood. In the present study we have generated both a U(L)49-null virus and its genetic repair and characterized their growth in both cultured cells and the mouse cornea. While single-step growth analyses indicated that VP22 is dispensable for virus replication at high multiplicities of infection (MOIs), analyses of plaque morphology and intra- and extracellular multistep growth identified a role for VP22 in viral spread during HSV-1 infection at low MOIs. Specifically, VP22 was not required for either virion infectivity or cell-cell spread but was required for accumulation of extracellular virus to wild-type levels. We found that the absence of VP22 also affected virion composition. Intracellular virions generated by the U(L)49-null virus contained reduced amounts of ICP0 and glycoproteins E and D compared to those generated by the wild-type and U(L)49-repaired viruses. In addition, viral spread in the mouse cornea was significantly reduced upon infection with the U(L)49-null virus compared to infection with the wild-type and U(L)49-repaired viruses, identifying a role for VP22 in viral spread in vivo as well as in vitro.

Published

2006

37. The putative terminase subunit of herpes simplex virus 1 encoded by UL28 is necessary and sufficient to mediate interaction between pUL15 and pUL33.

Author

Yang K and Baines JD

Subjects

Animals, Cell Line, Endodeoxyribonucleases, Endopeptidases metabolism, Immunoprecipitation, Protein Binding, Protein Subunits, Herpesvirus 1, Human enzymology, Viral Proteins metabolism, Viral Proteins physiology

Abstract

Viral terminases play essential roles as components of molecular motors that package viral DNA into capsids. Previous results indicated that the putative terminase subunits of herpes simplex virus 1 (HSV-1) encoded by U(L)15 and U(L)28 (designated pU(L)15 and pU(L)28, respectively) coimmunoprecipitate with the U(L)33 protein from lysates of infected cells. All three proteins are among six required for HSV-1 DNA packaging but dispensable for assembly of immature capsids. The current results show that in both infected- and uninfected-cell lysates, pU(L)28 coimmunoprecipitates with either pU(L)33 or pU(L)15, whereas pU(L)15 and pU(L)33 do not coimmunoprecipitate unless pU(L)28 is present. The U(L)28 protein was sufficient to stabilize pU(L)33 from proteasomal degradation in an engineered cell line and was necessary to stabilize pU(L)33 in infected cells, whereas pU(L)15 had no such effects. The presence of pU(L)33 was dispensable for the pU(L)15/pU(L)28 interaction in lysates of both infected and uninfected cells but augmented the tendency for pU(L)15 and pU(L)28 to coimmunoprecipitate. These data suggest that pU(L)28 and pU(L)33 interact directly and that pU(L)15 interacts directly with pU(L)28 but only indirectly with pU(L)33. It is logical to propose that the indirect interaction of pU(L)15 and pU(L)33 is mediated through the interaction of both proteins with pU(L)28. The data also suggest that one function of pU(L)33 is to optimize the pU(L)15/pU(L)28 interaction.

Published

2006

38. Herpes simplex virus type 1 infection induces activation and recruitment of protein kinase C to the nuclear membrane and increased phosphorylation of lamin B.

Author

Park R and Baines JD

Subjects

Animals, Chlorocebus aethiops, Enzyme Activation, HeLa Cells, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Humans, Phosphorylation, Protein Kinase C genetics, Protein Serine-Threonine Kinases metabolism, Vero Cells, Viral Proteins metabolism, Herpesvirus 1, Human enzymology, Nuclear Envelope enzymology, Nuclear Lamina metabolism, Nuclear Lamina virology, Protein Kinase C metabolism

Abstract

We report that herpes simplex virus type 1 (HSV-1) infection leads to the recruitment of protein kinase C (PKC) to the nuclear rim. In HEp-2 cells, PKC recruitment to the nuclear rim was initiated between 8 h and 12 h postinfection. PKCdelta, a proapoptotic kinase, was completely recruited to the nuclear rim upon infection with HSV-1. PKCalpha was less dramatically relocalized mostly at the nuclear rim upon infection, although some PKCalpha remained in the cytoplasm. PKCzeta-specific immunofluorescence was not significantly relocated to the nuclear rim. The UL34 and UL31 proteins, as well as their association, were each required for PKC recruitment to the nuclear rim. The HSV-1 US3 protein product, a kinase which regulates the phosphorylation state and localization of UL34, was not required for PKC recruitment to the nuclear rim; however, it was required for proper localization along the nuclear rim, as PKC appeared unevenly distributed along the nuclear rim of cells infected with US3 null and kinase-dead mutants. HSV-1 infection induced the phosphorylation of both lamin B and PKC. Elevated lamin B phosphorylation in HSV-1-infected cells was partially reduced by inhibitors of PKC. The data suggest a model in which kinases that normally disassemble the nuclear lamina during apoptosis are recruited to the nuclear membrane through functions requiring UL31 and UL34. We hypothesize that the recruitment of PKC functions to phosphorylate lamin B to help modify the nuclear lamina and promote budding of nucleocapsids at the inner nuclear membrane.

Published

2006

39. Active intranuclear movement of herpesvirus capsids.

Author

Forest T, Barnard S, and Baines JD

Subjects

Capsid metabolism, Cell Nucleus metabolism, Herpesvirus 1, Human genetics, Humans, Particle Size, Temperature, Capsid physiology, Cell Nucleus physiology, Herpesvirus 1, Human physiology

Abstract

Although small molecules diffuse rapidly through the interphase nucleus, recent reports indicate that nuclear diffusion is limited for particles that are larger than 100 nm in diameter. Given the apparent size limits to nuclear diffusion, there is some debate as to whether the movement of large particles should be attributed to diffusion or to active transport. Here, we show that 125 nm-diameter herpes simplex virus 1 (HSV-1) capsids are actively transported within infected nuclei. Movement is directed, temperature- and energy-dependent, sensitive to the putative myosin inhibitor 2,3-butanedione monoxime (BDM) and to actin depolymerization with latrunculin-A, but insensitive to actin depolymerization with cytochalasin-D.

Published

2005

40. Cell lines that support replication of a novel herpes simplex virus 1 UL31 deletion mutant can properly target UL34 protein to the nuclear rim in the absence of UL31.

Author

Liang L, Tanaka M, Kawaguchi Y, and Baines JD

Subjects

Animals, Cell Line, Chlorocebus aethiops, Herpesvirus 1, Human genetics, Humans, Nuclear Proteins metabolism, Rabbits, Vero Cells, Gene Deletion, Herpesvirus 1, Human physiology, Nuclear Envelope metabolism, Nuclear Proteins genetics, Viral Proteins genetics, Viral Proteins metabolism, Virus Replication

Abstract

Previous results indicated that the herpes simplex virus 1 (HSV-1) U(L)31 gene is necessary and sufficient for localization of the U(L)34 protein exclusively to the nuclear membrane of infected Hep2 cells. In the current studies, a bacterial artificial chromosome containing the entire HSV-1 strain F genome was used to construct a recombinant viral genome in which a gene encoding kanamycin resistance was inserted in place of 262 codons of the 306 codon U(L)31 open reading frame. The deletion virus produced virus titers approximately 10- to 50-fold lower in rabbit skin cells, more than 2000-fold lower in Vero cells, and more than 1500-fold lower in CV1 cells, compared to a virus bearing a restored U(L)31 gene. The replication of the U(L)31 deletion virus was restored on U(L)31-complementing cell lines derived either from rabbit skin cells or CV1 cells. Confocal microscopy indicated that the majority of U(L)34 protein localized aberrantly in the cytoplasm and nucleoplasm of Vero cells and CV1 cells, whereas U(L)34 protein localized at the nuclear membrane in rabbit skin cells, and U(L)31 complementing CV1 cells infected with the U(L)31 deletion virus. We conclude that rabbit skin cells encode a function that allows proper localization of U(L)34 protein to the nuclear membrane. We speculate that this function partially complements that of U(L)31 and may explain why U(L)31 is less critical for replication in rabbit skin cells as opposed to Vero and CV1 cells.

Published

2004

41. The DNA cleavage and packaging protein encoded by the UL33 gene of herpes simplex virus 1 associates with capsids.

Author

Beard PM and Baines JD

Subjects

Animals, Blotting, Western, Chlorocebus aethiops, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Vero Cells, Virus Assembly, Capsid metabolism, DNA, Viral metabolism, Herpesvirus 1, Human physiology, Viral Proteins metabolism

Abstract

The U(L)33 gene of herpes simplex virus 1 (HSV-1) encodes a protein (pU(L)33) that is essential for the cleavage and packaging of concatameric herpesvirus DNA into preformed capsids. Previous data have suggested that the U(L)33 protein interacts with the cleavage and packaging proteins encoded by U(L)15 and U(L)28 that are known to associate with capsids. Examination of purified A capsids that lack DNA and are derived from aborted packaging events, B capsids that lack DNA, and C capsids that contain DNA revealed an association of the U(L)33 protein with all three capsid types. More U(L)33 protein was detected in A capsids than was present in B capsids. Capsid association was susceptible to guanidine-HCl treatment and independent of the presence of U(L)15 or U(L)28. Capsid association of pU(L)33 was also independent of U(L)6, which is believed to encode the portal into which DNA is inserted. These data suggest that pU(L)33 may act as part of the capsid-associated molecular machinery that translocates cleaved genomic DNA into the capsid interior.

Published

2004

42. Conformational changes in the nuclear lamina induced by herpes simplex virus type 1 require genes U(L)31 and U(L)34.

Author

Reynolds AE, Liang L, and Baines JD

Subjects

Cell Line, Cytoplasm metabolism, Herpesvirus 1, Human genetics, Humans, Lamin Type A analysis, Lamin Type A chemistry, Molecular Conformation, Nuclear Proteins genetics, Solubility, Viral Proteins genetics, Herpesvirus 1, Human physiology, Nuclear Lamina chemistry, Nuclear Proteins physiology, Viral Proteins physiology

Abstract

The herpes simplex virus type 1 (HSV-1) U(L)31 and U(L)34 proteins are dependent on each other for proper targeting to the nuclear membrane and are required for efficient envelopment of nucleocapsids at the inner nuclear membrane. In this work, we show that whereas the solubility of lamins A and C (lamin A/C) was not markedly increased, HSV induced conformational changes in the nuclear lamina of infected cells, as viewed after staining with three different lamin A/C-specific antibodies. In one case, reactivity with a monoclonal antibody that recognizes an epitope in the lamin tail domain was greatly reduced in HSV-infected cells. This apparent HSV-induced epitope masking required both U(L)31 and U(L)34, but these proteins were not sufficient to mask the epitope in uninfected cells, indicating that other HSV proteins are also required. In the second case, staining with a rabbit polyclonal antibody that primarily recognizes epitopes in the lamin A/C rod domain revealed that U(L)34 is required for HSV-induced decreased availability of epitopes for reaction with the antibody, whereas U(L)31 protein was dispensable for this effect. Still another polyclonal antibody indicated virtually no difference in lamin A/C staining in infected versus uninfected cells, indicating that the HSV-induced changes are more conformational than the result of lamin depletion at the nuclear rim. Further evidence supporting an interaction between the nuclear lamina and the U(L)31/U(L)34 protein complex includes the observations that (i) overexpression of the U(L)31 protein in uninfected cells was sufficient to relocalize lamin A/C from the nuclear rim into nucleoplasmic aggregates, (ii) overexpression of U(L)34 was sufficient to relocalize some lamin A/C into the cytoplasm, and (iii) both U(L)31 and U(L)34 could directly bind lamin A/C in vitro. These studies suggest that the U(L)31 and U(L)34 proteins modify the conformation of the nuclear lamina in infected cells, possibly by direct interaction with lamin A/C, and that other proteins are also likely involved. Given that the nuclear lamina potentially excludes nucleocapsids from envelopment sites at the inner nuclear membrane, the lamina alteration may reflect a role of the U(L)31/U(L)34 protein complex in perturbing the lamina to promote nucleocapsid egress from the nucleus. Alternatively, the data are compatible with a role of the lamina in targeting the U(L)31/U(L)34 protein complex to the nuclear membrane.

Published

2004

43. The herpes simplex virus type 1 UL20 protein modulates membrane fusion events during cytoplasmic virion morphogenesis and virus-induced cell fusion.

Author

Foster TP, Melancon JM, Baines JD, and Kousoulas KG

Subjects

Animals, Capsid physiology, Chlorocebus aethiops, Morphogenesis, Vero Cells, Viral Envelope Proteins physiology, Cell Fusion, Cytoplasm virology, Herpesvirus 1, Human growth & development, Membrane Fusion, Viral Proteins physiology, Virion growth & development

Abstract

The herpes simplex virus type 1 (HSV-1) UL20 protein is an important determinant for virion morphogenesis and virus-induced cell fusion. A precise deletion of the UL20 gene in the HSV-1 KOS strain was constructed without affecting the adjacent UL20.5 gene. The resultant KOS/UL20-null virus produced small plaques of 8 to 15 cells in Vero cells while it produced wild-type plaques on the complementing cell line G5. Electron microscopic examination of infected cells revealed that the KOS/UL20-null virions predominantly accumulated capsids in the cytoplasm while a small percentage of virions were found as enveloped virions within cytoplasmic vacuoles. Recently, it was shown that UL20 expression was necessary and sufficient for cell surface expression of gK (T. P. Foster, X. Alvarez, and K. G. Kousoulas, J. Virol. 77:499-510, 2003). Therefore, we investigated the effect of UL20 on virus-induced cell fusion caused by syncytial mutations in gB and gK by constructing recombinant viruses containing the gBsyn3 or gKsyn1 mutations in a UL20-null genetic background. Both recombinant viruses failed to cause virus-induced cell fusion in Vero cells while they readily caused fusion of UL20-null complementing G5 cells. Ultrastructural examination of UL20-null viruses carrying the gBsyn3 or gKsyn1 mutation revealed a similar distribution of virions as the KOS/UL20-null virus. However, cytoplasmic vacuoles contained aberrant virions having multiple capsids within a single envelope. These multicapsid virions may have been formed either by fusion of viral envelopes or by the concurrent reenvelopment of multiple capsids. These results suggest that the UL20 protein regulates membrane fusion phenomena involved in virion morphogenesis and virus-induced cell fusion.

Published

2004

44. Quantification of the DNA cleavage and packaging proteins U(L)15 and U(L)28 in A and B capsids of herpes simplex virus type 1.

Author

Beard PM, Duffy C, and Baines JD

Subjects

Animals, Cell Line, DNA, Viral metabolism, Herpesvirus 1, Human genetics, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Viral Proteins genetics, Viral Proteins isolation & purification, Virus Assembly, Capsid metabolism, Herpesvirus 1, Human metabolism, Viral Proteins metabolism

Abstract

The proteins produced by the herpes simplex virus type 1 (HSV-1) genes U(L)15 and U(L)28 are believed to form part of the terminase enzyme, a protein complex essential for the cleavage of newly synthesized, concatameric herpesvirus DNA and the packaging of the resultant genome lengths into preformed capsids. This work describes the purification of recombinant forms of pU(L)15 and pU(L)28, which allowed the calculation of the average number of copies of each protein in A and B capsids and in capsids lacking the putative portal encoded by U(L)6. On average, 1.0 (+/-0.29 [standard deviation]) copies of pU(L)15 and 2.4 (+/-0.97) copies of pU(L)28 were present in B capsids, 1.2 (+/-0.72) copies of pU(L)15 and 1.5 (+/-0.86) copies of pU(L)28 were found in mutant capsids lacking the putative portal protein pU(L)6, and approximately 12.0 (+/-5.63) copies of pU(L)15 and 0.6 (+/-0.32) copies of pU(L)28 were present in each A capsid. These results suggest that the packaging machine is partly comprised of approximately 12 copies of pU(L)15, as found in A capsids, with wild-type B and mutant U(L)6(-) capsids containing an incomplete complement of cleavage and packaging proteins. These results are consistent with observations that B capsids form by default in the absence of packaging machinery in vitro and in vivo. In contrast, A capsids may be the result of initiated but aborted attempts at DNA packaging, resulting in the retention of at least part of the DNA packaging machinery.

Published

2004

45. Ultrastructural localization of the herpes simplex virus type 1 UL31, UL34, and US3 proteins suggests specific roles in primary envelopment and egress of nucleocapsids.

Author

Reynolds AE, Wills EG, Roller RJ, Ryckman BJ, and Baines JD

Subjects

Animals, Cell Line, Cell Nucleus metabolism, Cell Nucleus ultrastructure, Chlorocebus aethiops, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Humans, Microscopy, Confocal, Nuclear Envelope ultrastructure, Protein Serine-Threonine Kinases genetics, Vero Cells ultrastructure, Virion metabolism, Virus Assembly, Herpesvirus 1, Human pathogenicity, Nuclear Envelope metabolism, Nuclear Proteins metabolism, Nucleocapsid metabolism, Protein Serine-Threonine Kinases metabolism, Viral Proteins metabolism

Abstract

The wild-type UL31, UL34, and US3 proteins localized on nuclear membranes and perinuclear virions; the US3 protein was also on cytoplasmic membranes and extranuclear virions. The UL31 and UL34 proteins were not detected in extracellular virions. US3 deletion caused (i) virion accumulation in nuclear membrane invaginations, (ii) delayed virus production onset, and (iii) reduced peak virus titers. These data support the herpes simplex virus type 1 deenvelopment-reenvelopment model of virion egress and suggest that the US3 protein plays an important, but nonessential, role in the egress pathway.

Published

2002

46. DNA cleavage and packaging proteins encoded by genes U(L)28, U(L)15, and U(L)33 of herpes simplex virus type 1 form a complex in infected cells.

Author

Beard PM, Taus NS, and Baines JD

Subjects

Animals, Bacteriophage lambda metabolism, Baculoviridae genetics, Cells, Cultured, Chlorocebus aethiops, DNA, Viral metabolism, DNA-Binding Proteins genetics, Endodeoxyribonucleases chemistry, Endodeoxyribonucleases metabolism, Genetic Vectors, Herpesvirus 1, Human metabolism, Humans, Vero Cells, Viral Proteins genetics, Virus Replication, DNA-Binding Proteins metabolism, Herpesvirus 1, Human physiology, Viral Proteins metabolism

Abstract

Previous studies have indicated that the U(L)6, U(L)15, U(L)17, U(L)28, U(L)32, and U(L)33 genes are required for the cleavage and packaging of herpes simplex viral DNA. To identify proteins that interact with the U(L)28-encoded DNA binding protein of herpes simplex virus type 1 (HSV-1), a previously undescribed rabbit polyclonal antibody directed against the U(L)28 protein fused to glutathione S-transferase was used to immunopurify U(L)28 and the proteins with which it associated. It was found that the antibody specifically coimmunoprecipitated proteins encoded by the genes U(L)28, U(L)15, and U(L)33 from lysates of both HEp-2 cells infected with HSV-1(F) and insect cells infected with recombinant baculoviruses expressing these three proteins. In reciprocal reactions, antibodies directed against the U(L)15- or U(L)33-encoded proteins also coimmunoprecipitated the U(L)28 protein. The coimmunoprecipitation of the three proteins from HSV-infected cells confirms earlier reports of an association between the U(L)28 and U(L)15 proteins and represents the first evidence of the involvement of the U(L)33 protein in this complex.

Published

2002

47. U(L)31 and U(L)34 proteins of herpes simplex virus type 1 form a complex that accumulates at the nuclear rim and is required for envelopment of nucleocapsids.

Author

Reynolds AE, Ryckman BJ, Baines JD, Zhou Y, Liang L, and Roller RJ

Subjects

Animals, Cell Nucleus metabolism, Chlorocebus aethiops, Herpesvirus 1, Human metabolism, Humans, Nuclear Proteins genetics, Nucleocapsid physiology, Protein Serine-Threonine Kinases metabolism, Tumor Cells, Cultured, Vero Cells, Viral Proteins genetics, Herpesvirus 1, Human physiology, Nuclear Proteins metabolism, Nucleocapsid metabolism, Viral Proteins metabolism, Virus Assembly physiology

Abstract

The herpes simplex virus type 1 (HSV-1) U(L)34 protein is likely a type II membrane protein that localizes within the nuclear membrane and is required for efficient envelopment of progeny virions at the nuclear envelope, whereas the U(L)31 gene product of HSV-1 is a nuclear matrix-associated phosphoprotein previously shown to interact with U(L)34 protein in HSV-1-infected cell lysates. For these studies, polyclonal antisera directed against purified fusion proteins containing U(L)31 protein fused to glutathione-S-transferase (U(L)31-GST) and U(L)34 protein fused to GST (U(L)34-GST) were demonstrated to specifically recognize the U(L)31 and U(L)34 proteins of approximately 34,000 and 30,000 Da, respectively. The U(L)31 and U(L)34 gene products colocalized in a smooth pattern throughout the nuclear rim of infected cells by 10 h postinfection. U(L)34 protein also accumulated in pleiomorphic cytoplasmic structures at early times and associated with an altered nuclear envelope late in infection. Localization of U(L)31 protein at the nuclear rim required the presence of U(L)34 protein, inasmuch as cells infected with a U(L)34 null mutant virus contained U(L)31 protein primarily in central intranuclear domains separate from the nuclear rim, and to a lesser extent in the cytoplasm. Conversely, localization of U(L)34 protein exclusively at the nuclear rim required the presence of the U(L)31 gene product, inasmuch as U(L)34 protein was detectable at the nuclear rim, in replication compartments, and in the cytoplasm of cells infected with a U(L)31 null virus. When transiently expressed in the absence of other viral factors, U(L)31 protein localized diffusely in the nucleoplasm, whereas U(L)34 protein localized primarily in the cytoplasm and at the nuclear rim. In contrast, coexpression of the U(L)31 and U(L)34 proteins was sufficient to target both proteins exclusively to the nuclear rim. The proteins were also shown to directly interact in vitro in the absence of other viral proteins. In cells infected with a virus lacking the U(S)3-encoded protein kinase, previously shown to phosphorylate the U(L)34 gene product, U(L)31 and U(L)34 proteins colocalized in small punctate areas that accumulated on the nuclear rim. Thus, U(S)3 kinase is required for even distribution of U(L)31 and U(L)34 proteins throughout the nuclear rim. Taken together with the similar phenotypes of the U(L)31 and U(L)34 deletion mutants, these data strongly suggest that the U(L)31 and U(L)34 proteins form a complex that accumulates at the nuclear membrane and plays an important role in nucleocapsid envelopment at the inner nuclear membrane.

Published

2001

48. Herpes simplex virus DNA packaging sequences adopt novel structures that are specifically recognized by a component of the cleavage and packaging machinery.

Author

Adelman K, Salmon B, and Baines JD

Subjects

Base Sequence, Binding Sites, DNA-Binding Proteins isolation & purification, Herpesvirus 1, Human metabolism, Herpesvirus 1, Human physiology, Humans, Molecular Sequence Data, Nucleic Acid Conformation, Viral Proteins isolation & purification, DNA, Viral metabolism, DNA-Binding Proteins metabolism, Herpesvirus 1, Human genetics, Viral Proteins metabolism, Virus Assembly physiology

Abstract

The product of the herpes simplex virus type 1 U(L)28 gene is essential for cleavage of concatemeric viral DNA into genome-length units and packaging of this DNA into viral procapsids. To address the role of U(L)28 in this process, purified U(L)28 protein was assayed for the ability to recognize conserved herpesvirus DNA packaging sequences. We report that DNA fragments containing the pac1 DNA packaging motif can be induced by heat treatment to adopt novel DNA conformations that migrate faster than the corresponding duplex in nondenaturing gels. Surprisingly, these novel DNA structures are high-affinity substrates for U(L)28 protein binding, whereas double-stranded DNA of identical sequence composition is not recognized by U(L)28 protein. We demonstrate that only one strand of the pac1 motif is responsible for the formation of novel DNA structures that are bound tightly and specifically by U(L)28 protein. To determine the relevance of the observed U(L)28 protein-pac1 interaction to the cleavage and packaging process, we have analyzed the binding affinity of U(L)28 protein for pac1 mutants previously shown to be deficient in cleavage and packaging in vivo. Each of the pac1 mutants exhibited a decrease in DNA binding by U(L)28 protein that correlated directly with the reported reduction in cleavage and packaging efficiency, thereby supporting a role for the U(L)28 protein-pac1 interaction in vivo. These data therefore suggest that the formation of novel DNA structures by the pac1 motif confers added specificity on recognition of DNA packaging sequences by the U(L)28-encoded component of the herpesvirus cleavage and packaging machinery.

Published

2001

49. Characterization of the U(L)33 gene product of herpes simplex virus 1.

Author

Reynolds AE, Fan Y, and Baines JD

Subjects

Animals, Antibodies, Viral, Cell Line, Cell Nucleus virology, Chlorocebus aethiops, DNA, Viral genetics, Gene Expression, Herpesvirus 1, Human pathogenicity, Herpesvirus 1, Human physiology, Humans, Molecular Weight, Mutation, Vero Cells, Viral Proteins chemistry, Viral Proteins metabolism, Virus Replication, Genes, Viral, Herpesvirus 1, Human genetics, Viral Proteins genetics

Abstract

The U(L)33 protein is one of six genes (including U(L)6, U(L)15, U(L)17, U(L)28, and U(L)32) required for cleavage of viral concatemeric DNA into unit-length genomes and packaging of the virus genomes into preformed capsids. The U(L)25 gene product is dispensable for cleavage of viral DNA but essential for packaging of DNA into capsids. A polyclonal antiserum was produced against an affinity-purified protein containing the full-length U(L)33 gene product of herpes simplex virus 1 fused to glutathione-S-transferase. A protein of approximate M(r) 19,000 that reacted with the antiserum was detected in immunoblots of herpes simplex virus 1-infected cellular lysates. This protein was not detected in lysates of mock-infected cells or cells infected with a mutant virus containing a stop codon in U(L)33, indicating that the 19,000 M(r) protein is the product of the U(L)33 open reading frame. The U(L)33 gene product was not detected in purified virions or capsids. Accumulation of the U(L)33 protein to detectable levels required viral DNA synthesis, indicating that the protein was regulated as a late gene. Indirect immunofluorescence analysis demonstrated that U(L)33 protein accumulated predominantly within replication compartments in the central domains of infected cell nuclei and within the cytoplasm. Localization of the U(L)33 gene product in replication compartments was maintained in cells infected with a variety of cleavage/packaging mutants., (Copyright 2000 Academic Press.)

Published

2000

50. Herpes simplex virus type 1 gene UL14: phenotype of a null mutant and identification of the encoded protein.

Author

Cunningham C, Davison AJ, MacLean AR, Taus NS, and Baines JD

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cells, Cultured, DNA, Viral, Female, Herpesvirus 1, Human growth & development, Humans, Mice, Mice, Inbred BALB C, Microscopy, Electron, Molecular Sequence Data, Phenotype, Phosphorylation, Rabbits, Sequence Deletion, Sequence Homology, Amino Acid, Tumor Cells, Cultured, Viral Proteins metabolism, Herpesvirus 1, Human genetics, Mutation, Viral Proteins genetics

Abstract

Herpes simplex virus type 1 (HSV-1) gene UL14 is located between divergently transcribed genes UL13 and UL15 and overlaps the promoters for both of these genes. UL14 also exhibits a substantial overlap of its coding region with that of UL13. It is one of the few HSV-1 genes for which a phenotype and protein product have not been described. Using mass spectrometric and immunological approaches, we demonstrated that the UL14 protein is a minor component of the virion tegument of 32 kDa which is expressed late in infection. In infected cells, the UL14 protein was detected in the nucleus at discrete sites within electron-dense nuclear bodies and in the cytoplasm initially in a diffuse distribution and then at discrete sites. Some of the UL14 protein was phosphorylated. A mutant with a 4-bp deletion in the central region of UL14 failed to produce the UL14 protein and generated small plaques. The mutant exhibited an extended growth cycle at low multiplicity of infection and appeared to be compromised in efficient transit of virus particles from the infected cell. In mice injected intracranially, the 50% lethal dose of the mutant was reduced more than 30,000-fold. Recovery of the mutant from the latently infected sacral ganglia of mice injected peripherally was significantly less than that of wild-type virus, suggesting a marked defect in the establishment of, or reactivation from, latent infection.

Published

2000