Stimulation of expression of a herpes simplex virus DNA-binding protein by two viral functions

Herpes simplex virus 1 alpha regulatory protein ICP0 interacts with and stabilizes the cell cycle regulator cyclin D3

The herpes simplex virus 1 (HSV-1) infected-cell protein 0 (ICP0) has the characteristics of a promiscuous transactivator of genes introduced into cells by infection or transfection. To identify cellular proteins interacting with ICP0, we used a domain of exon II of ICP0 that is known to be crucial for regulatory function of the protein as bait in the yeast two-hybrid screen. Our results were as follows. (i) A cDNA in a positive yeast colony was found to encode cyclin D3, a cell cycle regulator of G1 phase. (ii) A purified chimeric protein consisting of glutathione S-transferase (GST) fused to cyclin D3 specifically formed complexes with ICP0 contained in HSV-1-infected cell lysate. (iii) To enhance the expression of cyclin D3, the gene was inserted into the viral genome and overexpressed in infected cells. The overexpressed cyclin D3 colocalized with ICP0 in nuclear structures characteristic of ND10 and which earlier have been reported to contain ICP0. (iv) The accumulation of cyclin D3 protein in Vero cells infected with an alpha0 deletion mutant was reduced relative to that of cells infected with wild-type virus or a recombinant virus in which the deleted alpha0 sequences were restored. (v) Lysates of Spodoptera frugiperda Sf9 cells doubly infected with baculoviruses genetically engineered to express cyclin D3 and cyclin-dependent kinase 4 (CDK4) phosphorylated GST fused to retinoblastoma protein (GST-pRb) but did not phosphorylate the GST-alpha0(20-241) or GST-alpha0(543-768) fusion protein or immunoprecipitated ICP0 proteins. Moreover, the chimeric GST-ICP0(exon II) protein shown to bind cyclin D3 had no effect on the activity of the kinase on GST-pRb when added to mixtures of lysates of Sf9 cells which coexpressed cyclin D3 and CDK4. These results indicate that ICP0 interacts with, colocalizes with, and stabilizes the cyclin D3 cell cycle regulator and does not affect its interaction with the cyclin-dependent kinase.

Assembly of complete, functionally active herpes simplex virus DNA replication compartments and recruitment of associated viral and cellular proteins in transient cotransfection assays

Early during the herpes simplex virus (HSV) lytic cycle or in the presence of DNA synthesis inhibitors, core viral replication machinery proteins accumulate in intranuclear speckled punctate prereplicative foci, some of which colocalize with numerous sites of host cellular DNA synthesis initiation known as replisomes. At later times, in the absence of inhibitors, several globular or large irregularly shaped replication compartments are formed; these compartments also contain progeny viral DNA and incorporate the IE175(ICP4) transcription factor together with several cellular proteins involved in DNA replication and repair. In this study, we demonstrate that several forms of both prereplication foci and active viral replication compartments that display an appearance similar to that of the compartments in HSV-infected cells can be successfully assembled in transient assays in DNA-transfected cells receiving genes encoding all seven essential HSV replication fork proteins together with oriS target plasmid DNA. Furthermore, bromodeoxyuridine (BrdU)-pulse-labeled DNA synthesis initiation sites colocalized with the HSV single-stranded DNA-binding protein (SSB) in these replication compartments, implying that active viral DNA replication may be occurring. The assembly of complete HSV replication compartments and incorporation of BrdU were both abolished by treatment with phosphonoacetic acid (PAA) and by omission of any one of the seven viral replication proteins, UL5, UL8, UL9, UL42, UL52, SSB, and Pol, that are essential for viral DNA replication. Consistent with the fact that both HSV IE175 and IE63(ICP27) localize within replication compartments in HSV-infected cells, the assembled HSV replication compartments were also able to recruit both of these essential regulatory proteins. Blocking viral DNA synthesis with PAA, but not omission of oriS, prevented the association of IE175 with prereplication structures. The assembled HSV replication compartments also redistributed cotransfected cellular p53 into the viral replication compartments. However, the other two HSV immediate-early nuclear proteins IE110(ICP0) and IE68(ICP22) did not enter the replication compartments in either infected or transfected cells.

Interaction of herpes simplex virus 1 alpha regulatory protein ICP0 with elongation factor 1delta: ICP0 affects translational machinery

The herpes simplex virus 1 (HSV-1)-infected cell protein 0 (ICP0) is a promiscuous transactivator, and by necessity, its functions must be mediated through cellular gene products. In an attempt to identify cellular factors interacting with ICP0, we used the carboxyl-terminal domain of ICP0 as "bait" in the yeast (Saccharomyces cerevisiae) two-hybrid system. Our results were as follows: (i) All 43 cDNAs in positive yeast colonies were found to encode the same translation factor, elongation factor delta-1 (EF-1delta). (ii) Purified chimeric protein consisting of glutathione S-transferase (GST) fused to EF-1delta specifically formed complexes with ICP0 contained in HSV-1-infected cell lysate. (iii) Fractionation of infected HEp-2 cells and immunofluorescence studies revealed that ICP0 was localized both in the nucleus and in the cytoplasm. In primary human foreskin fibroblasts, ICP0 was localized predominantly in the cytoplasm throughout HSV-1 infection even early in infection. (iv) Addition of the chimeric protein GST-carboxyl-terminal domain of ICP0 to the rabbit reticulocyte lysate in vitro translation system resulted in a dose-dependent decrease in protein synthesis. In contrast, GST alone or GST fused to the amino-terminal domain of ICP0 had no effect on the in vitro translation system. (v) The predominant forms of EF-1delta on electrophoresis in denaturing gels have apparent Mrs of 38,000 and 40,000. The higher-Mr form is a minor species in mock-infected cells, whereas in human fibroblasts and Vero cells infected with HSV-1, this isoform becomes dominant. These results indicate that ICP0 is present and may have a significant role in the cytoplasm of infected cells, possibly by altering the efficiency of translation of viral mRNAs.

Physical and functional interactions between herpes simplex virus immediate-early proteins ICP4 and ICP27

The ordered expression of herpes simplex virus type 1 (HSV-1) genes, during the course of a productive infection, requires the action of the virus immediate-early regulatory proteins. Using a protein interaction assay, we demonstrate specific in vitro protein-protein interactions between ICP4 and ICP27, two immediate-early proteins of HSV-1 that are essential for virus replication. We map multiple points of contact between these proteins. Furthermore, by coimmunoprecipitation experiments, we demonstrate the following. (i) ICP4-ICP27 complexes are present in extracts from HSV-1 infected cells. (ii) ICP27 binds preferentially to less modified forms of ICP4, a protein that is extensively modified posttranslationally. We also demonstrate, by performing electrophoretic mobility shift assays and supershifts with monoclonal antibodies to ICP4 or ICP27, that both proteins are present in a DNA-protein complex with a noncanonical ICP4 binding site present in the HSV thymidine kinase (TK) gene. ICP4, in extracts from cells infected with ICP27-deficient viruses, is impaired in its ability to form complexes with the TK site but not with the canonical site from the alpha4 gene. However, ICP4 is able to form complexes with the TK probe, in the absence of ICP27, when overproduced in mammalian cells or expressed in bacteria. These data suggest that the inability of ICP4 from infected cell extracts to bind the TK probe in the absence of ICP27 does not reflect a requirement for the physical presence of ICP27 in the complex. Rather, they imply that ICP27 is likely to modulate the DNA binding activity of ICP4 by affecting its posttranslational modification status. Therefore, we propose that ICP27, in addition to its established role as a posttranscriptional regulator of virus gene expression, may also modulate transcription either through direct or indirect interactions with HSV regulatory regions, or through its ability to modulate the DNA binding activity of ICP4.

Characterization of an abundant, unique 1.7-kilobase bovine herpesvirus 4 (BHV-4) late RNA and mapping of a BHV-4 IE2 transactivator-binding site in its promoter-regulatory region

We characterized an abundant late 1.7-kb cytoplasmic polyadenylated RNA (L1.7 RNA) transcribed from the bovine herpesvirus 4 (BHV-4) HindIII W fragment, in a region of the genome not conserved with Epstein-Barr virus and herpesvirus saimiri. L1.7 RNA contains only extremely short (<100 nucleotides) open reading frames followed by two repeat arrays. The first repeat array contains 11 copies of a 23-bp unit, TGGCACTA GTAGCATTTAACCCC. The second and third copies are each interrupted by 15- to 17-bp sequences that are identical to each other for the first 15 bp. In addition, the second and third copies of the repeat unit each contain two copies of nucleotides 5 to 9 (ACTAG) of the repeat unit, one at each end of the interruption. The second repeat array contains 12 copies of a 25-bp sequence, GCTGTGTATTATTGAGTATTTTTTA. The promoter-regulatory region of L1.7 was activated by the BHV-4 immediate-early gene 2 product (IE2), a homolog of the Epstein-Barr virus R transactivator, in cotransfection assays. We mapped an IE2 recognition site within a 167-bp fragment approximately 10 bp 5' to the start of L1.7 RNA transcription, using cotransfection assays and gel retardation assays. Using gel retardation assays, we mapped an IE2-binding site within this fragment to a 31-bp region from 56 to 86 bp 5' to the start of L1.7 RNA transcription. This IE2-binding site was able to transfer IE2 responsiveness to a heterologous promoter. However, IE2 responsiveness was affected by both position and orientation. Alignment of the L1.7 IE2-binding site sequence with sequences of two other BHV-4 IE2-binding sites resulted in a provisional IE2-binding site consensus sequence different from the Epstein-Barr virus R transactivator-binding site.

Mutational analysis of ICP0R, a transrepressor protein created by alternative splicing of the ICP0 gene of herpes simplex virus type 1

The immediate-early protein ICP0 (infected-cell polypeptide 0) of herpes simplex virus type 1 (HSV-1) is a promiscuous transactivator of both viral and nonviral promoters in transient expression assays. Failure to splice the second of two introns in the ICP0 gene results in the utilization of an alternate stop codon that generates a truncated form of ICP0 called ICP0R. This protein exists in low levels in HSV-1-infected cells and functions as a dominant negative repressor of ICP0-mediated transactivation in transient expression assays. To conduct a detailed structure-function analysis of ICP0R, a series of insertion and deletion mutants of this protein were generated and analyzed in transfection assays. These studies indicated that segments of ICP0R that were rich in acidic amino acid residues (amino acids 9 to 76 and 233 to 241) or glycine residues (amino acids 242 to 262) were dispensable for the dominant negative phenotype. In contrast, the RING finger domain (amino acids 116 to 156) and surprisingly the sequences carboxy terminal to it (amino acids 157 to 232) were absolutely essential for transdominant repression. Consistent with these findings, the amino acid sequences of these two regions were conserved among other alphaherpesvirus ICP0 homologs. A construct containing only amino acids 76 to 232 inhibited ICP0-mediated transactivation almost as efficiently as wild-type ICP0R and represented the minimal sequences necessary for the dominant negative phenotype. These results demonstrated that the critical functional domain shared by both ICP0R and ICP0 is much more complex than a simple RING finger motif. Western blot (immunoblot) analyses of transfected cell lysates revealed that nearly all of the mutant constructs directed the expression of stable ICP0R proteins of the predicted molecular weight. However, there was a striking inverse correlation between the ability of a mutant construct to mediate transrepression and the amount of protein that it synthesized, indicating that dominant negative inhibition is achieved through the action of very little ICP0R protein.

Prolonged gene expression and cell survival after infection by a herpes simplex virus mutant defective in the immediate-early genes encoding ICP4, ICP27, and ICP22

Very early in infection, herpes simplex virus (HSV) expresses four immediate-early (IE) regulatory proteins, ICP4, ICP0, ICP22, and ICP27. The systematic inactivation of sets of the IE proteins in cis, and the subsequent phenotypic analysis of the resulting mutants, should provide insights into how these proteins function in the HSV life cycle and also into the specific macromolecular events that are altered or perturbed in cells infected with virus strains blocked very early in infection. This approach may also provide a rational basis to assess the efficacy and safety of HSV mutants for use in gene transfer experiments. In this study, we generated and examined the phenotype of an HSV mutant simultaneously mutated in the ICP4, ICP27, and ICP22 genes of HSV. Unlike mutants deficient in ICP4 (d120), ICP4 and ICP27 (d92), and ICP4 and ICP22 (d96), mutants defective in ICP4, ICP27, and ICP22 (d95) were visually much less toxic to Vero and human embryonic lung cells. Cells infected with d95 at a multiplicity of infection of 10 PFU per cell retained a relatively normal morphology and expressed genes from the viral and cellular genomes for at least 3 days postinfection. The other mutant backgrounds were too toxic to allow examination of gene expression past 1 day postinfection. However, when cell survival was measured by the capacity of the infected cells to form colonies, d95 inhibited colony formation similarly to d92. This apparent paradox was reconciled by the observation that host cell DNA synthesis was inhibited in cells infected with d120, d92, d96, and d95. In addition, all of the mutants exhibited pronounced and distinctive alterations in nuclear morphology, as determined by electron microscopy. The appearance of d95-infected cells deviated from that of uninfected cells in that large circular structures formed in the nucleus. d95-infected cells abundantly expressed ICP0, which accumulated in fine punctate structures in the nucleus at early times postinfection and coalesced or grew to the large circular objects that were revealed by electron microscopy. Therefore, while the abundant accumulation of ICPO in the absence of ICP4, ICP22, and ICP27 may allow for prolonged gene expression, cell survival is impaired, in part, as a result of the inhibition of cellular DNA synthesis.

Overexpression of the herpes simplex virus type 1 immediate-early regulatory protein, ICP27, is responsible for the aberrant localization of ICP0 and mutant forms of ICP4 in ICP4 mutant virus-infected cells

ICP0 and ICP4 are immediate-early regulatory proteins of herpes simplex virus type 1. Previous studies by Knipe and Smith demonstrated that these two proteins are characteristically observed in the nuclei of wild-type virus-infected cells but predominantly in the cytoplasms of cells infected with several ICP4 temperature-sensitive (ts) mutant viruses at the nonpermissive temperature (NPT) (D. M. Knipe and J. L. Smith, Mol. Cell. Biol. 6:2371-2381, 1986). Consistent with this observation, it has been shown previously that ICP0 is present predominantly in the cytoplasms of cells infected with an ICP4 null mutant virus (n12) at high multiplicities of infection and that the level of ICP27, a third viral regulatory protein, plays an important role in determining the intracellular localization of ICP0 (Z. Zhu, W. Cai, and P. A. Schaffer, J. Virol. 68:3027-3040, 1994). To address whether the cytoplasmic localization of ICP0 is a common feature of cells infected with all ICP4 mutant viruses or whether mutant ICP4 polypeptides, together with ICP27, determine the intracellular localization of ICP0, we used double-staining immunofluorescence tests to examine the intracellular staining patterns of ICP0 and ICP4 in cells infected with an extensive series of ICP4 mutant viruses. In these tests, compared with the localization pattern of ICP0 in wild-type virus-infected cells, more ICP0 was detected in the cytoplasms of cells infected with all ICP4 mutants tested at high multiplicities of infection. Each of the mutant forms of ICP4 exhibiting predominantly cytoplasmic staining contains both the nuclear localization signal and the previously mapped ICP27-responsive region (Z. Zhu and P. A. Schaffer, J. Virol. 69:49-59, 1995). No correlation between the intracellular staining patterns of ICP0 and mutant forms of ICP4 was demonstrated, suggesting that mutant ICP4 polypeptides per se are not responsible for retention of ICP0 in the cytoplasm. This observation was confirmed in studies of cells cotransfected with plasmids expressing ICP0 and mutant forms of ICP4, in which the staining pattern of ICP0 was not changed in the presence of mutant ICP4 proteins. Studies of cells infected at low multiplicities with a variety of ICP4 ts mutant viruses at the NPT showed that both ICP0 and ts forms of ICP4 were localized predominantly within the nucleus. These observations are a further indication that the aberrant localization of the ts forms of ICP4 at the NPT is not a direct result of specific mutations in the ICP4 gene. In the final series of tests, the localization of ICP0 in cells infected with a double-mutant virus unable to express either ICP4 or ICP27 was examined. In these tests, ICP0 was detected exclusively in the nuclei of Vero cells but in both the nuclei and the cytoplasms of ICP27-expressing cells infected with the double mutant. These results demonstrate that ICP27, rather than the absence of functional ICP4, is responsible for the cytoplasmic localization of ICP0 in ICP4 mutant virus-infected cells. Taken together, these findings demonstrate that the aberrant localization of ICP0 and certain mutant forms of ICP4 in cells infected with ICP4 mutant viruses is mediated by high levels of ICP27 resulting from the inability of mutant forms of ICP4 to repress the expression of ICP27.

Interaction of the viral activator protein ICP4 with TFIID through TAF250

ICP4 of herpes simplex virus is responsible for the activation of viral transcription during infection. It also efficiently activates and represses transcription in vitro depending on the promoter context. The contacts made between ICP4 and the cellular proteins that result in activated transcription have not been identified. The inability of ICP4 to activate transcription with TATA-binding protein in place of TFIID and the requirement for an initiator element for efficient ICP-4-activated transcription suggest that coactivators, such as TBP-associated factors, are involved (B. Gu and N. DeLuca, J. Virol. 68:7953-7965, 1994). In this study we showed that ICP4 activates transcription in vitro using an immunopurified TFIID, indicating that TBP-associated factors may be a sufficient subset of coactivators for ICP4-activated transcription. Similar to results seen in vivo, the presence of the ICP4 C-terminal region (amino acids 774 to 1298) was important for activation in vitro. With epitope-tagged ICP4 molecules in immunoaffinity experiments, it was shown that the C-terminal region was also required for ICP4 to interact with TFIID present in a crude transcription factor fraction. In the same assay, ICP4 was unable to interact with the basal transcription factors, TFIIB, TFIIE, TFIIF, and TFIIH and RNA polymerase II. ICP4 could also interact with TBP, independent of the C-terminal region. However, reflective of the interaction between ICP4 and TFIID, the ICP4 C-terminal region was required for an interaction with FAF250-TBP complexes and with TAF250 alone. Therefore, the interfaces or conformation of TBP mediating the interaction between ICP4 and TBP in solution is probably masked when TBP is bound to TAF250. With a series of mutant ICP4 molecules purified from herpes simplex virus-infected cells, it was shown that ICP4 molecules that can bind DNA and interact with TAF250 could activate transcription. Taken together, these results demonstrate that ICP4 interaction with TFIID involves the TAF250 molecule and the C-terminal region of ICP4 and that this interaction is part of the mechanism by which ICP4 activates transcription.

Analysis of phosphorylation sites of herpes simplex virus type 1 ICP4

The herpes simplex virus ICP4 protein is required for induction of early and late viral gene transcription as well as for repression of expression of its own gene and several other viral genes. Several electrophoretic forms of ICP4 have been observed, and phosphorylation is thought to contribute to this heterogeneity and possibly to the multiple functions of ICP4. To define the complexity of the site(s) of phosphorylation of ICP4 and to initiate mapping of this site(s), we have performed two-dimensional phosphopeptide mapping of wild-type and mutant forms of ICP4 labeled in infected cells or in vitro. Wild-type ICP4 labeled in infected cells shows a complex pattern of phosphopeptides, and smaller mutant forms of ICP4 show progressively fewer phosphopeptides, arguing that multiple sites on ICP4 are phosphorylated. The serine-rich region of ICP4, residues 175 to 198, was shown to be a site for phosphorylation. Furthermore, the serine-rich region itself or the phosphorylation of this region increases phosphorylation of all phosphopeptides. A mutant ICP4 molecule lacking the serine-rich region showed low levels of phosphorylation by protein kinase A or protein kinase C in vitro. These results suggest that there may be a sequential phosphorylation of ICP4, with phosphorylation of the serine-rich region stimulating phosphorylation of the rest of the molecule. In addition, purified ICP4 showed an associated kinase activity or an autophosphorylation activity with properties different from those of protein kinase A or protein kinase C.

The promoter and transcriptional unit of a novel herpes simplex virus 1 alpha gene are contained in, and encode a protein in frame with, the open reading frame of the alpha 22 gene

The herpes simplex virus type 1 genome encodes a set of genes (alpha genes) expressed in the absence of de novo viral protein synthesis. Earlier studies have shown that the product of the alpha 22 gene, a member of this set, is nucleotidylylated by casein kinase II and phosphorylated by viral protein kinases encoded by UL13 and US3. Mutants lacking the carboxyl-terminal domain starting with amino acid 200 exhibit reduced capacity to replicate in primary human cell strains or in cells of rodent derivation and also exhibit reduced expression of a subset of gamma or late genes. We report that the domain of the alpha 22 gene is transcribed by two 3'-coterminal mRNAs. The longer transcript reported encodes the 420-amino-acid alpha 22 protein, whereas the shorter transcript reported here encodes a protein containing the carboxyl-terminal 273 amino acids of the alpha 22 protein. The shorter gene is designated US1.5. The US1.5 mRNA is synthesized in cells infected and maintained in the presence of cycloheximide and under other conditions which restrict viral gene expression to alpha genes. In-frame insertion of linkers encoding 18, 21, or 22 amino acids after codon 200 or 240 of the alpha 22 protein did not affect the known functions or phenotype associated with the wild-type alpha 22 gene or its product. Earlier studies have placed the nucleotidylylated sequences in the amino-terminal portion of the protein. The results of these studies indicate that the US1.5 gene encodes the functions associated with replication in human primary or rodent cells and optimal expression of alpha 0 and gamma genes. This finding brings the number of genes known to map in the unique short region of the herpes simplex virus type 1 DNA to 14 and the total number of different genes to 78.

An activity specified by the osteosarcoma line U2OS can substitute functionally for ICP0, a major regulatory protein of herpes simplex virus type 1

Among the five immediate-early regulatory proteins of herpes simplex virus (HSV) type 1, only ICP0 is capable of activating all kinetic classes of viral genes. Consistent with its broad transactivating activity, ICP0 plays a major role in enhancing the reactivation of HSV from latency both in vivo and in vitro. Although not essential for viral replication, ICP0 confers a significant growth advantage on the virus, especially at low multiplicities of infection. In this report we describe the expression of a novel activity by the osteosarcoma cell line U2OS that can substitute functionally for ICP0. Compared with Vero cells, both U2OS cells and cells of the ICP0-expressing line 0-28 significantly enhanced the plating efficiency of an ICP0 null mutant, 7134. In contrast, the plating efficiencies of the wild-type virus in all three cell types were similar. Single-step growth experiments demonstrated that the yield of 7134 in U2OS cells was severalfold higher than that in 0-28 cells and about 100-fold higher than that in Vero cells. In order to identify the viral genes whose expression is enhanced by the activity in U2OS cells, levels of expression of selected viral proteins in extracts of Vero and U2OS cells were compared by Western blot (immunoblot) analysis following low-multiplicity infection. At a multiplicity of 0.1 PFU per cell, the levels of expression of the immediate-early protein ICP4 and the early protein gD in 7134-infected U2OS cells were significantly higher than those in 7134-infected Vero cells. When infections were carried out at a multiplicity of 1 PFU per cell, however, no major differences in the levels of expression of these proteins in U2OS and Vero cells were observed. Cycloheximide reversal experiments demonstrated that the cellular activity expressed in U2OS cells that promotes high-level expression of ICP4 is not synthesized de novo but appears to exist as a preformed protein(s). To confirm this observation and to determine whether, like immediate-early genes, early, delayed-early, and late viral genes are also responsive to the cellular activity, transient-expression assays were performed. The results of these tests demonstrated that basal levels of expression from immediate-early, early, and delayed-early promoters, but not that from a late promoter, were significantly higher in U2OS cells than in Vero cells and that this enhancement occurred in the absence of viral proteins.(ABSTRACT TRUNCATED AT 400 WORDS)

Functional interactions between herpes simplex virus immediate-early proteins during infection: gene expression as a consequence of ICP27 and different domains of ICP4

Two of the five immediate-early gene products, ICP4 and ICP27, expressed by herpes simplex virus type 1 have profound effects on viral gene expression and are absolutely essential for virus replication. Functional interactions between ICP4 and ICP27 may contribute to establishing the program of viral gene expression that ensues during lytic infection. To evaluate this possibility, viral mutants simultaneously deleted for ICP27 and defined functional domains of ICP4 were constructed. These mutant viruses allowed a comparison of gene expression as a function of different domains of ICP4 in the presence and absence of ICP27. Gene expression in the absence of both ICP4 and ICP27 was also examined. The results of this study demonstrate a clear involvement for ICP27 in the induction of early genes, in addition to its known role in enhancing late gene expression during viral infection. In the absence of both ICP4 and ICP27, viral early gene expression, as measured by the accumulation of thymidine kinase and ICP6 messages was dramatically reduced relative to the amounts of these messages seen in the absence of only ICP4. Therefore, elevated levels of early gene expression as a consequence of ICP27 occurred in the absence of any ICP4 activity. Evidence is also presented regarding the modulation of the ICP4 repression function by ICP27. When synthesized in the absence of ICP27, a mutant ICP4 protein was impaired in its ability to repress transcription from the L/ST promoter in the context of viral infection and in vitro. This defect correlated with the loss of the ability of this mutant protein to bind to its recognition sequence when produced in infected cells in the absence of ICP27. These observations indicate that ICP27 can regulate the activity of at least one domain of the ICP4 protein as well as contribute to elevated early gene expression independently of ICP4.

Repression of activator-mediated transcription by herpes simplex virus ICP4 via a mechanism involving interactions with the basal transcription factors TATA-binding protein and TFIIB

Infected-cell polypeptide 4 (ICP4) of herpes simplex virus is both a transcriptional activator and a repressor. It has been previously demonstrated that both SP1-activated transcription and USF-activated transcription are repressed by ICP4 without affecting basal transcription (B. Gu, R. Rivera-Gonzalez, C. A. Smith, and N. A. DeLuca, Proc. Natl. Acad. Sci. USA 90:9528-9532, 1993; R. Rivera-Gonzalez, A. N. Imbalzano, B. Gu, and N.A. DeLuca, Virology 202:550-564, 1994). In this study, it was found that ICP4 repressed the activation function of two other activators, VP16 and ICP4 itself, in vitro. ICP4 inhibited transcription by interfering with the formation of transcription initiation complexes without affecting transcription elongation. Repression of activator function required that an ICP4 DNA binding site was present in one orientation within approximately 45 bp 3' to the TATA box. DNA binding by ICP4 was necessary but not sufficient for repression. ICP4 has been shown to form tripartite complexes cooperatively with the TATA box-binding protein and TFIIB on DNA containing an ICP4 binding site and a TATA box (C. A. Smith, P. Bates, R. Rivera-Gonzalez, B. Gu, and N. DeLuca, J. Virol. 67:4676-4687, 1993). A region of ICP4 that enables the molecule to form tripartite complexes was also required in addition to the DNA binding domain for efficient repression. Moreover, repression was observed only when the ICP4 binding site was in a position that resulted in the formation of tripartite complexes. Together, the data suggest that ICP4 represses transcription by binding to DNA in a precise way so that it may interact with the basal transcription complex and inhibit some general step involved in the function of activators. The steps or interactions involved in transcriptional activation that are inhibited by ICP4 are discussed.

Two overlapping transcription units which extend across the L-S junction of herpes simplex virus type 1

A region of the herpes simplex virus type 1 genome located upstream of the alpha 0 promoter contains a promoter which regulates transcription in the opposite orientation to that driven by alpha 0. Analyses of mutants from which this promoter, alpha X, was deleted and a mutant in which a fragment that serves as a transcription terminator and polyadenylation signal was inserted upstream of this promoter demonstrate that two distinct transcription units overlap this region of the genome and are transcribed in a direction antisense to the neurovirulence gene gamma (1)34.5. One unit, dependent on the alpha X promoter, is active when cells are infected in the presence of the protein synthesis inhibitor cycloheximide. The second unit, independent of alpha X, is active during the course of productive infection. This transcription unit originates from a promoter upstream of alpha X which is distinct from the latency-associated promoter (LAP). Two polyadenylated transcripts of 0.9 and 4.9 kb accumulate from this region of the genome during productive infection, but no mature transcripts accumulate in infected cells maintained in the presence of cycloheximide. Kinetic analyses demonstrate that the transcripts that accumulate during productive infection fall into the beta class of herpes simplex virus type 1 genes.

Evaluation of colocalization interactions between the IE110, IE175, and IE63 transactivator proteins of herpes simplex virus within subcellular punctate structures

A number of previous studies have implied that three herpes simplex virus-encoded nuclear transactivator proteins, IE175 (ICP4), IE110 (ICP0), and IE63 (ICP27), may cooperate in transcriptional and posttranscriptional stimulation of viral gene expression. Using double-label immunofluorescence assays (IFA) in transient expression assays, we have examined the intracellular localization of these three proteins in DNA-transfected cells. The IE110 protein on its own forms spherical punctate domains within the nucleus, whereas the IE175 and IE63 proteins alone give uniform and speckled diffuse patterns, respectively. In infected cells, the IE110 punctate granules have been shown to correspond to novel preexisting subnuclear structures referred to as ND10 domains or PODs that contain a variety of cellular proteins, including SP100 and the PML proto-oncogene product. Cotransfection experiments with wild-type nuclear forms of both IE175 and IE110 provided direct evidence for partial redistribution of IE175 into the same punctate granules that contained IE110. Surprisingly, nuclear forms of IE110 were found to move a cytoplasmic form of IE175 into nuclear punctate structures, and a cytoplasmic form of IE110 was able to retain nuclear forms of IE175 in cytoplasmic punctate structures. Therefore, the punctate characteristic of IE110 appeared to both dominate the interactions and override the normal nuclear localization signals. The domains responsible for the interaction mapped to between codons 518 and 768 in 1E110 and to between codons 835 and 1029 in IE175. Importantly, a truncated nuclear form of the 1,298-amino-acid IE175 protein, which lacked the C-terminal domain beyond codon 834, was found to be excluded from the IE110 punctate granules. Cotransfection of nuclear or cytoplasmic IE110 with a truncated nuclear form of IE63 also led to partial redistribution of IE63 into either nuclear or cytoplasmic punctate granules containing IE110. Both the IE63-IE110 and IE175-IE110 colocalization interactions were demonstrated in Vero cells but not in 293 cells. Consequently, they differ from IE110 self-interactions, which correlate with in vitro dimerization and occur efficiently in both cell types. These interactions may help to explain the altered promoter target specificity and synergism observed when IE175 is cotransfected with IE110 in transactivation studies.

Intracellular localization of the herpes simplex virus type 1 major transcriptional regulatory protein, ICP4, is affected by ICP27

Infected-cell protein 4 (ICP4) is the major transcriptional activator of herpes simplex virus (HSV) gene expression during productive infection. ICP0 has broad transactivating activity for all classes of HSV genes as well as cellular genes and genes of heterologous viruses. Together, the transactivating activities of ICP4 and ICP0 are synergistic. ICP27, which alone does not exhibit major transregulatory activity, is able to differentially activate and repress viral gene expression induced by ICP4 and ICP0. Thus, ICP27 plays a modulatory role in viral gene expression. In order to explore the functional relationships among ICP4, ICP0, and ICP27 in the regulation of viral gene expression, we have used indirect immunofluorescence to examine the intracellular localization of ICP4 in cells infected with wild-type virus or with mutant viruses that did not express functional forms of ICP0 or ICP27. Although ICP4 localized to both the nuclei and cytoplasm of cells infected with either the wild-type virus or an ICP0 null mutant virus, this protein was present exclusively in the nuclei of cells infected with an ICP27 null mutant virus, suggesting that ICP27 is able to inhibit the nuclear localization of ICP4 during virus infection. Transient expression assays with pairs of plasmids that express wild-type forms of ICP4 and ICP0 or of ICP4 and ICP27 demonstrated that ICP27 has a significant inhibitory effect on the nuclear localization of ICP4, confirming the observations made with the mutant-virus-infected cells. By using a plasmid expressing wild-type ICP4 and a series of ICP27 mutant plasmids in transient expression assays, the C-terminal half of ICP27 was shown to be required for its inhibitory effect on the nuclear localization of ICP4. In similar studies using a series of ICP4 mutant plasmids, the region of ICP4 responsive to wild-type ICP27 was mapped to the C-terminal portion of the molecule between amino acid residues 820 and 1029. The level of expression of ICP27 was shown to have a significant effect on the intracellular localization of ICP4 in transient assays. These findings are consistent with previous studies in which ICP27 was shown to have an inhibitory effect on the nuclear localization of ICP0 (Z. Zhu, W. Cai, and P. A. Schaffer J. Virol. 68:3027-3040, 1994). Thus, ICP27 has a significant inhibitory effect on the ability of the two major HSV type 1 (HSV-1) regulatory proteins to localize to the nucleus. Collectively, these findings indicate that cooperative regulation of HSV-1 gene expression may well involve intracellular compartmental constraints.

Requirements for activation of the herpes simplex virus glycoprotein C promoter in vitro by the viral regulatory protein ICP4

During infection with herpes simplex virus, infected-cell polypeptide 4 (ICP4) activates transcription of most herpes simplex virus genes. In the present study, the mechanism of activation of transcription by ICP4 was investigated by using a reconstituted in vitro system with fractionated and purified general transcription factors, coupled with DNA-binding assays. The templates used in the reactions included regions of the gC and thymidine kinase (tk) promoters in plasmids, and on isolated fragments, allowing for the evaluation of the potential function of naturally occurring and inserted ICP4-binding sites and elements of the core promoter. ICP4 efficiently activated transcription of the gC promoter by facilitating the formation of transcription initiation complexes. ICP4 could not substitute for any of the basal transcription factors. Moreover, TATA-binding protein (TBP) could not substitute for TFIID in activation, suggesting a requirement for TBP-associated factors. Interactions between ICP4 and DNA 3' to the start site was necessary for activation of the gC promoter. The requirement for DNA-protein contacts could be met either by the presence of an ICP4-binding site in the gC leader, by the presence of a site more than 150 nucleotides further downstream, by an inserted site that normally acts to repress transcription, or by the addition of sufficient non-site-containing DNA. The gC TATA box and start site, or initiator element (inr), were individually sufficient for activation by ICP4 and together contributed to optimal activation. In contrast to gC, the tk promoter was poorly activated in the reconstituted system. However, the tk TATA box was efficiently activated when the tk start site region was replaced with the gC inr, suggesting that activation was mediated through the inr and inr-binding proteins. In addition, mutation of the inr core resulted in a gC promoter that was very poorly activated by ICP4. The results of this and previous studies demonstrate that ICP4 activates transcription in a complex manner involving contacts with DNA 3' to the start site, TBP, TFIIB, TBP-associated factors, and possibly proteins functioning at the start site of transcription.

Physical interaction between the herpes simplex virus type 1 immediate-early regulatory proteins ICP0 and ICP4

The herpes simplex virus type 1 immediate-early protein ICP0 enhances expression of a spectrum of viral genes alone and synergistically with ICP4. To test whether ICP0 and ICP4 interact physically, we performed far-Western blotting analysis of proteins from mock-, wild-type-, and ICP4 mutant virus-infected cells with in vitro-synthesized [35S]Met-labeled ICP0 and ICP4 as probes. The ICP4 and ICP0 polypeptides synthesized in vitro exhibited molecular weights similar to those of their counterparts in herpes simplex virus type 1-infected cells, and the in vitro-synthesized ICP4 was able to bind to a probe containing the ICP4 consensus binding site. Far-Western blotting experiments demonstrated that ICP0 interacts directly and specifically with ICP4 and with itself. To further define the interaction between ICP0 and ICP4, we generated a set of glutathione S-transferase (GST)-ICP0 fusion proteins that contain GST and either ICP0 N-terminal amino acids 1 to 244 or 1 to 394 or C-terminal amino acids 395 to 616 or 395 to 775. Using GST-ICP0 fusion protein affinity chromatography and in vitro-synthesized [35S]Met-labeled ICP0 and ICP4, ICP4 was shown to interact preferentially with the fusion protein containing ICP0 C-terminal amino acids 395 to 775, whereas ICP0 interacted efficiently with both the N-terminal GST-ICP0 fusion proteins and the C-terminal GST-ICP0 fusion proteins containing amino acids 395 to 775. Fusion protein affinity chromatography also demonstrated that the C-terminal 235 amino acid residues of ICP4 are important for efficient interaction with ICP0. Collectively, these results reveal a direct and specific physical interaction between ICP0 and ICP4.

Effect of the transcription start region of the herpes simplex virus type 1 latency-associated transcript promoter on expression of productively infected neurons in vivo

It has been previously reported that the latency-associated transcript (LAT) promoter contains a DNA sequence at the LAT transcription start site which resembles the ICP4 consensus DNA binding site and that this site allows ICP4-mediated downregulation of the LAT promoter in transient assays (A. H. Batchelor and P. O'Hare, J. Virol. 64:3269-3279, 1990). We have confirmed these data by showing that an ICP4-expressing plasmid will downregulate lacZ expression from a plasmid containing the LAT promoter and transcription start site (pJA1) and does not downregulate lacZ expression from a plasmid in which the start site has been mutagenized (pWAG15). To determine the role of the LAT transcription start site in regulating LAT promoter activity in the context of the virus, two recombinant viruses, KOS-1 and KOS-15, were studied. KOS-1 contains an 863-bp portion of the LAT promoter, including the LAT cap site, fused to the lacZ gene and inserted into the gC locus (T.P. Margolis, F. Sedarati, A.T. Dobson, L.T. Feldman, and J.G. Stevens, Virology 189:150-160, 1992). The second virus (KOS-15) was constructed in identical fashion, using plasmid pWAG-15, which is not downregulated by ICP4. Vero cells productively infected with KOS-15 produce 10-fold more beta-galactosidase than do those infected with KOS-1. In murine dorsal root ganglia acutely infected with KOS-1, only 1.2% of dorsal root ganglion neurons that expressed viral antigen also expressed beta-galactosidase. In contrast, in KOS-15-infected mice, beta-galactosidase was detected in 18% of viral antigen-positive neurons. Similar findings were observed in trigeminal ganglia acutely infected with KOS-1 and KOS-15. Thus, the region encompassing the LAT transcription start site appears to play an important role in repression of the LAT promoter activity not only in vitro but also in acutely infected neurons in vivo. These results suggest that during productive infection with HSV-1, LAT expression is tightly regulated.

Identification of a dimerization domain in the C-terminal segment of the IE110 transactivator protein from herpes simplex virus

The 775-amino-acid IE110 (or ICP0) phosphoprotein of herpes simplex virus (HSV) functions as an accessory transcription factor during the lytic cycle and plays a critical role in reactivation from latent infection. By immunofluorescence analysis, IE110 localizes in a novel pattern consisting of several dozen spherical punctate granules in the nuclei of DNA-transfected cells. We constructed a hybrid version of IE110 that contained an epitope-tagged domain from the N terminus of the HSV IE175 protein and lacked the IE110 N-terminal domain that confers punctate characteristics. This hybrid IE175(N)/IE110(C) protein gave an irregular nuclear diffuse pattern on its own but was redistributed very efficiently into spherical punctate granules after cotransfection with the wild-type HSV-1 IE110 protein. Similar colocalization interactions occurred with internally deleted forms of IE110 that lacked the zinc finger region or large segments from the center of the protein, including both cytoplasmic and elongated punctate forms, but C-terminal truncated versions of IE110 did not interact. In all such interactions, the punctate phenotype was dominant. Evidence that C-terminal segments of IE110 could also form stable mixed-subunit oligomers in vitro was obtained by coimmunoprecipitation of in vitro-translated IE110 polypeptides with different-size hemagglutinin epitope-tagged forms of the protein. This occurred only when the two forms were cotranslated, not when they were simply mixed together. An in vitro-synthesized IE110 C-terminal polypeptide also gave immunoprecipitable homodimers and heterodimers when two different-size forms were cross-linked with glutaraldehyde and reacted specifically with a bacterial glutathione S-transferase/IE110 C-terminal protein in far-Western blotting experiments. The use of various N-terminal and C-terminal truncated forms of IE110 in the in vivo assays revealed that the outer boundaries of the interaction domain mapped between codons 617 and 711, although inclusion of adjacent codons on either side increased the efficiency severalfold in some assays. We conclude that the C-terminal region of IE110 contains a high-affinity self-interaction domain that leads to stable dimer and higher-order complex formation both in DNA-transfected cells and in in vitro assays. This segment of IE110 is highly conserved between HSV-1 and HSV-2 and appears to have the potential to play an important role in the interaction with the IE175 protein, as well as in correct intracellular localization, but it is not present in the equivalent proteins from varicella-zoster virus, pseudorabies virus, or equine abortion virus.

Mapping of intracellular localization domains and evidence for colocalization interactions between the IE110 and IE175 nuclear transactivator proteins of herpes simplex virus

Transcriptional regulation by the IE175 (ICP4) and IE110 (ICP0) phosphorylated nuclear proteins encoded by herpes simplex virus (HSV) appears to be a key determinant for the establishment of successful lytic cycle infection. By indirect immunofluorescence in transient DNA transfection assays, we have examined the intracellular distribution of deletion and truncation mutants of both IE175 and IE110 from HSV-1. Insertion of short oligonucleotides encoding the basic amino acid motifs 726-GRKRKSP-732 from IE175 and 500-VRPRKRR-506 from IE110 into deleted cytoplasmic forms of the two proteins restored the karyophilic phenotype and confirmed that these motifs are both necessary and sufficient for proper nuclear localization. Analysis of IE110 deletion mutants and a panel of IE110/IE175 hybrid proteins was also used to evaluate the characteristic IE110 distribution within nuclear punctate granules as seen by immunofluorescence and phase-contrast microscopy. The phase-dense punctate pattern persisted with both large C-terminal truncations and deletions of the Cys-rich zinc finger region and even with a form of IE110 that localized in the cytoplasm, implying that the punctate characteristic is an intrinsic property of the N-terminal segment of the IE110 protein. Transfer of the full IE110-like punctate phenotype to the normally uniform diffuse nuclear pattern of the IE175 protein by exchange of the N-terminal domains of the two proteins demonstrated that the first 105 to 244 amino acids of IE110 represent the most important region for conferring punctate characteristics. Surprisingly, cotransfection of a wild-type nuclear IE175 gene together with the IE110 gene revealed that much of the IE175 protein produced was redistributed into a punctate pattern that colocalized with the IE110-associated punctate granules seen in the same cells. This colocalization did not occur after cotransfection of IE110 with the IE72 (IE1) nuclear protein of human cytomegalovirus and therefore cannot represent simple nonspecific trapping. Evidently, the punctate phenotype of IE110 represents a dominant characteristic that reveals the potential of IE110 and IE175 to physically interact with each other either directly or indirectly within the intracellular environment.

A novel latency-active promoter is contained within the herpes simplex virus type 1 UL flanking repeats

Herpes simplex virus type 1 (HSV-1) expresses a unique series of RNA molecules, the latency-associated transcripts or LATs, during latent infection of neuronal tissues. Previous studies by others have described a TATA box-containing latency-active promoter, referred to here as LAP1, located approximately 700 bp upstream of the 5' end of the major 2.0-kb LAT. In this report, transient gene expression assays were employed to identify a second, novel latency-active promoter (LAP2) present within a region downstream of LAP1 and 5' proximal to the major 2.0-kb LAT. In contrast to LAP1, this promoter lacks a TATA box but possesses cis-acting regulatory elements and other features frequently observed within eukaryotic housekeeping gene promoters. Unlike most other HSV promoters, LAP2 was down-regulated by the viral transcriptional activators ICP4 and ICP0. The majority of LAP2-positive regulatory elements were located within sequences from -257 to -58 relative to the 5' end of the 2.0-kb LAT, and the basal promoter mapped within sequences from -14 to +28. RNase protection experiments demonstrated that chimeric LAT-chloramphenicol acetyltransferase transcripts produced in the transient assays initiated at or near the 5' end of the major 2-kb LAT. Tn5 insertional mutagenesis of the ICP4 regulatory gene determined that down-regulation of LAP2 required the ICP4 transactivating domain and targeted the minimal promoter region as the site of action by ICP4. Replicating recombinant viruses containing a LAP2-lacZ reporter gene cassette in an ectopic site (glycoprotein C locus) were shown to be active in mouse trigeminal ganglia. Taken together, these experiments suggest that the LAT region of the HSV-1 genome contains at least two latency-active promoters which may play different roles in expressing the various LATs. Alternatively, these promoters may comprise a larger promoter-regulatory complex which may influence transcription during latency.

Binding sites for the herpes simplex virus immediate-early protein ICP4 impose an increased dependence on viral DNA replication on simple model promoters located in the viral genome

We examined the ability of binding sites for the herpes simplex virus immediate-early protein ICP4 to alter the regulation of closely linked promoters by placing strong ICP4 binding sites upstream or downstream of simple TATA promoters in the intact viral genome. We found that binding sites strongly reduced the levels of expression at early times postinfection and that this effect was partially overcome after the onset of viral DNA replication. These data confirm that DNA-bound ICP4 can inhibit the activity of a closely linked promoter and raise the possibility that ICP4 binding sites contribute to temporal regulation during infection.

The herpes simplex virus type 1 regulatory protein ICP0 enhances virus replication during acute infection and reactivation from latency

ICP0 is a potent activator of herpes simplex virus type 1 gene expression in transient assays and in productive infection. A role for ICP0 in reactivation from latency in vivo has also been suggested on the basis of the observation that viruses with mutations in both copies of the diploid gene for ICP0 reactivate less efficiently than wild-type virus. Because the ICP0 gene is contained entirely within the coding sequences for the latency-associated transcripts (LATs), ICP0 mutants also contain mutations in LAT coding sequences. This overlap raises the question of whether mutations in ICP0 or the LATs, which have also been implicated in reactivation, are responsible for the reduced reactivation frequencies characteristic of ICP0 mutants. Two approaches were taken to examine more definitively the role of ICP0 in the establishment and reactivation of latency. First, a series of ICP0 nonsense, insertion, and deletion mutant viruses that exhibit graded levels of ICP0-specific transactivating activity were tested for parameters of the establishment and reactivation of latency in a mouse ocular model. Although these mutants are ICP0 LAT double mutants, all nonsense mutants induced the synthesis of near-wild-type levels of the 2-kb LAT, demonstrating that the nonsense linker did not disrupt the synthesis of this LAT species. All mutants replicated less efficiently than the wild-type virus in mouse eyes and ganglia during the acute phase of infection. The replication efficiencies of the mutants at these sites corresponded well with the ICP0 transactivating activities of individual mutant peptides in transient expression assays. All mutants exhibited reduced reactivation frequencies relative to those of wild-type virus, and reactivation frequencies, like replication efficiencies in eyes and ganglia, correlated well with the level of ICP0 transactivating activity exhibited by individual mutant peptides. The amount of DNA of the different mutants varied in latently infected ganglia, as demonstrated by polymerase chain reaction analysis. No correlation was evident between reactivation frequencies and the levels of viral DNA in latently infected ganglia. Thus, replication and reactivation efficiencies of ICP0 mutant viruses correlated well with the transactivating efficiency of the corresponding mutant peptides. In a second approach to examining the role of ICP0 in latency, a single copy of the wild-type gene for ICP0 was inserted into the genome of an ICP0- LAT- double mutant, 7134, which exhibits a marked impairment in its ability to replicate in the mouse eye and reactivate from latency.(ABSTRACT TRUNCATED AT 400 WORDS)

The RR1 gene of herpes simplex virus type 1 is uniquely trans activated by ICP0 during infection

As has been demonstrated for herpes simplex virus type 2, we show in this report that the herpes simplex virus type 1 ribonucleotide reductase large subunit (RR1) gene is trans activated in transient transfection assays by VP16 and ICP0 but not by ICP4. Deletion analysis demonstrated that responsiveness to induction to VP16 resides in an octamer/TAATGARAT sequence of the RR1 promoter and that the TATA box alone is sufficient to provide induction by ICP0. The induction of the RR1 gene by ICP0 but not by ICP4 suggested that it might be possible to identify the cis-acting element(s) responsive to ICP4 in an ICP4-inducible promoter. To this end, a series of chimeric promoters containing various portions of the regulatory sequences of the RR1 promoter and thymidine kinase (TK) promoter were constructed. The TK promoter is trans activated by both ICP0 and ICP4 in transient transfection assays and by ICP4 in infection. The data show that replacing the RR1 TATA region with the TK TATA region permits ICP4 inducibility even if the rest of the RR1 promoter elements remain intact. To test whether the RR1 gene is induced by ICP0 during infection, four mutant viruses were constructed. (i) TAATGARAT+ has the wild-type RR1 promoter driving chloramphenicol acetyltransferase (CAT) and the RR2 promoter driving the lacZ gene. The RR2 gene codes for the small subunit of the ribonucleotide reductase and is expressed as a beta gene. (ii) TAATGARAT- has a triple-base change in the octamer/TAATGARAT element which renders it unresponsive to VP16 trans activation, eliminating that portion of the activation of the RR1 gene. (iii) TAATGARAT- delta alpha 0 has a deletion of the alpha 0 gene. (iv) TAATGARAT- delta alpha 4 has a deletion of the alpha 4 gene. Infections were carried out in Vero cells at a multiplicity of infection of 10 per cell; cells were assayed for CAT and beta-galactosidase (beta-Gal) activities and for virus yields. The first two infections gave strong CAT and beta-Gal activities and high yields of progeny virus. Infection with the third virus showed no CAT activity but did produce high levels of beta-Gal activity and virus progeny. The fourth infection resulted in strong CAT activity but no beta-Gal activity or progeny virus. The data demonstrated that the RR1 promoter was activated in the absence of ICP4 but not in the absence of ICP0 in these infections.(ABSTRACT TRUNCATED AT 400 WORDS)

ICP4, the major transcriptional regulatory protein of herpes simplex virus type 1, forms a tripartite complex with TATA-binding protein and TFIIB

The ICP4 protein of herpes simplex virus can either increase or decrease the rate of transcription mediated by RNA polymerase II, depending on the target promoter. The interplay of DNA-protein and protein-protein contacts determining ICP4 function has yet to be characterized, and consequently the molecular mechanism by which the protein acts remains unclear. ICP4 can transactivate minimal promoters containing only TATA homologies, and therefore it is reasonable to hypothesize that ICP4 works by influencing the TATA-dependent assembly of general transcription factors via specific protein-protein interactions. This study directly addresses this hypothesis by determining whether ICP4 affects the assembly of general transcription factors on templates bearing a TATA box and an ICP4-binding site. Using gel retardation and footprinting assays, we found that ICP4 forms a tripartite complex with TFIIB and either the TATA-binding protein (TBP) or TFIID. The formation of this complex was not the result of simple tripartite occupancy of the DNA but the consequence of protein-protein interactions. In the presence of all three proteins, the affinity of ICP4 and TBP for their respective binding sites was substantially increased. Using mutant derivatives of ICP4 and defective versions of promoters, we also demonstrated that the ability of ICP4 to regulate gene expression correlated with its ability to form a tripartite complex with TFIIB and TBP in vitro.

Guanylylation and adenylylation of the alpha regulatory proteins of herpes simplex virus require a viral beta or gamma function

Herpes simplex virus genes form several groups whose expression is coordinately regulated and sequentially ordered in a cascade fashion. Most of the products of the first group, the alpha genes, appear to have regulatory functions. We report that the alpha proteins, infected cell proteins 4, 0, 22, and 27 of herpes simplex virus 1 and 4, 0, and 27 of herpes simplex virus 2, were labeled in the isolated nuclei of infected HeLa cells with [alpha-32P]GTP or [alpha-32P]ATP late in infection and that these proteins represent the largest group of virus-specific proteins labeled in this fashion. Studies with [2-3H]ATP, in which the label is in the purine ring, showed that a portion of the label in alpha proteins and in at least one other infected cell protein is due to nucleotidylylation. Analyses of the labeling reactions in nuclei of (i) cells infected with temperature-sensitive mutants at nonpermissive temperatures, (ii) cells infected with wild-type virus and harvested at different times postinfection, and (iii) cells treated with inhibitors of protein synthesis or of synthesis of viral DNA led to the conclusion that viral gene functions expressed after the synthesis of alpha proteins are required for the labeling of the alpha proteins with [alpha-32P]GTP. We conclude that several of the alpha proteins are extensively posttranslationally modified and that these modifications include nucleotidylylation.

The acidic amino-terminal region of herpes simplex virus type 1 alpha protein ICP27 is required for an essential lytic function

The herpes simplex virus type 1 (HSV-1) alpha protein ICP27 regulates the transition between the delayed-early and late phases of the viral infection. Previous genetic analyses have suggested that the important functional domains of ICP27 map to its carboxyl-terminal half. One striking feature of the primary sequence of ICP27, however, is an extremely acidic region near its amino terminus. To determine whether this region is required for ICP27 function, we deleted the sequences in the ICP27 gene which encode it (codons 12 through 63). In transient expression assays, the deletion mutant was unable to efficiently repress the expression of a cotransfected reporter gene or to efficiently complement the growth of d27-1, an HSV-1 ICP27 null mutant. These results suggested that the acidic region of ICP27 is involved in a regulatory function required for lytic growth. To test this possibility further, we introduced the mutant allele into the HSV-1 genome by marker transfer. Two independently derived isolates of the mutant virus, designated d1-2a and d1-2b, were recovered and analyzed. Both isolates were defective for growth in Vero cells, exhibiting a 100-fold reduction in virus yield compared with the wild-type infection. Vero cells infected with the d1-2 isolates showed a three- to eightfold reduction in viral DNA replication, a moderate reduction in the expression of viral gamma genes, and a delay in the repression of beta genes. The phenotype of the d1-2 isolates differs substantially from the phenotypes of previously isolated ICP27 mutants, which show much more severe defects in viral gene expression. Our results demonstrate that the amino-terminal half of ICP27 participates in its regulatory activities in both infected and transfected cells.

Identification of a promoter mapping within the reiterated sequences that flank the herpes simplex virus type 1 UL region

Analysis of the promoter for the herpes simplex virus (HSV) immediate-early (alpha) gene alpha 0 in a short-term transient expression assay revealed that a SacI-to-NcoI fragment from -786 to +148 relative to the cap site directed the synthesis of chloramphenicol acetyltransferase when the fragment was present in either orientation. Although the constitutive levels of promoter activity were similar with either orientation, the reverse-orientation promoter was not induced in response to infection with HSV. Analysis of sequences composing the putative promoter in the opposite orientation revealed the presence of important regulatory elements associated with alpha promoters. These include an alpha-trans-inducing factor (alpha-TIF)-like response element, a high-affinity ICP4-binding site, numerous Sp1-binding sites, and a TATA box. Sequences contained within this region formed specific DNA-protein complexes in extracts from mock-infected and HSV-infected HeLa cells. Transient expression assays revealed that this sequence was positively regulated by the alpha 0 and alpha-TIF genes but negatively regulated by alpha 4. Finally, nuclear run-on transcription assays revealed that this promoter is active in its correct genomic context during the course of virus infection. We suggest that the promoter is a hybrid between an alpha and beta promoter because it exhibits maximal expression at 8 h postinfection and is expressed in the presence of cycloheximide.

Replication-defective mutants of herpes simplex virus (HSV) induce cellular immunity and protect against lethal HSV infection

Live viruses and live virus vaccines induce cellular immunity more readily than do inactivated viruses or purified proteins, but the mechanism by which this process occurs is unknown. A trivial explanation would relate to the ability of live viruses to spread and infect more cells than can inactivated virus. We have used live but replication-defective mutants to investigate this question. Our studies indicate that the immune responses of mice to live virus differ greatly from the responses to inactivated virus even when the virus does not complete a replicative cycle. Further, these studies indicate that herpes simplex virus-specific T-cell responses can be generated by infection with replication-defective mutant viruses. These data indicate that the magnitude of the cellular immunity to herpes simplex virus may be proportional to the number or quantity of different viral gene products expressed by an immunizing virus.

Multimerization of ICP0, a herpes simplex virus immediate-early protein

ICP0, a herpes simplex virus immediate-early gene product, is a highly phosphorylated nuclear protein that is a potent activator of virus and host genes. Using biochemical and genetic assays employing plasmids encoding mutant forms of ICP0 and a recombinant adenovirus that expresses ICP0, we mutant forms of ICP0 and a recombinant adenovirus that expresses ICP0, we provide evidence that the protein multimerizes. Some mutant forms of ICP0 were transdominant and interfered with activation of a target reporter gene or with complementation of an ICP0-minus virus.

Association of ICP0 but not ICP27 with purified virions of herpes simplex virus type 1

Recent studies have shown that ICP4, one of the major immediate-early proteins of herpes simplex virus type 1 is present within the tegument region of the virion (F. Yao and R. J. Courtney, J. Virol. 63:3338-3344, 1989). With monoclonal antibodies to two additional immediate-early proteins, ICP0 and ICP27, and Western blot (immunoblot) analysis, ICP0, but not ICP27, was also found to be associated with purified virus particles. In an effort to localize the ICP0 within the virion, purified virions were treated with trypsin in the presence and absence of detergent. The data suggest that ICP0 is located within the tegument region of the virion and is not localized in the envelope or within the nucleocapsid. The number of molecules of ICP0 per virion was estimated to be approximately 150.

Herpes simplex virus type 1 ICP0 regulates expression of immediate-early, early, and late genes in productively infected cells

The herpes simplex virus type 1 protein, ICP0, can activate expression of all kinetic classes of viral promoters in transient expression assays. To examine the role of ICP0 in the regulation of viral gene expression during productive infection, we characterized the wild-type virus, an ICP0 null mutant (7134), and several ICP0 nonsense mutant viruses with regard to virus replication and protein synthesis in Vero cells. Relative to wild-type virus, 7134 was severely deficient in viral growth and protein synthesis at low multiplicities of infection but exhibited a nearly wild-type phenotype at high multiplicities. The phenotypes of the ICP0 nonsense mutants were intermediate between those of the wild-type virus and 7134 in that the more ICP0-coding sequence expressed by a given nonsense mutant, the more wild type-like was its phenotype. The location of the ICP0 domain responsible for transactivation during productive infection was confirmed to be within the N-terminal portion of the protein, as previously shown in transient expression assays. Immunoprecipitation and immunofluorescence tests were used to detect low-level expression of selected immediate-early (IE), early (E), and late (L) proteins by mutant and wild-type viruses following low-multiplicity infection. The 7134 deletion mutant and several nonsense mutants expressed markedly reduced levels of E and L proteins but wild-type levels of the IE protein, ICP4. Because the latency-associated transcripts (LATs) are specified by the strand opposite that which encodes ICP0, the ICP0 deletion and nonsense mutants are by definition ICP0-LAT double mutants. The ability of a LAT- ICP0+ mutant to replicate as efficiently as wild-type virus at low multiplicities and the ability of ICP0-expressing 0-28 cells to complement the defects of the mutants in E and L protein synthesis indicates that the phenotypes of the mutants are caused by mutations in ICP0 and not the LATs. Thus, we conclude that ICP0 up-regulates E and L but not necessarily IE gene expression during productive infection. The activation of IE gene expression by ICP0 during productive infection is likely overshadowed by the activity of the virion-associated protein, VP16. This hypothesis was tested by transfection of Vero cells with infectious mutant and wild-type viral DNAs. In such tests, no VP16 is present at early times posttransfection. Significantly fewer cells transfected with infectious 7134 DNA expressed ICP4 than cells transfected with KOS DNA. This reduction was fully reversed by cotransfection with an ICP0-expressing plasmid.(ABSTRACT TRUNCATED AT 400 WORDS)

Herpes simplex viruses with mutations in the gene encoding ICP0 are defective in gene expression

Herpes simplex virus type 1 (HSV-1) mutants with codon insertions and deletions in IE-0, the gene encoding ICP0, were constructed. The HSV-1 deletion mutant dl1403 (N. D. Stow and E. C. Stow, J. Gen. Virol. 67:2571-2585, 1986) and an IE-0:lacZ transplacement vector isolated in this study were used to facilitate the construction of mutant viruses. Mutant viruses, all of which produced stable ICP0, were examined for their ability to plaque and grow on both Vero and HeLa cells because previous results showed that HSV-1 immediate-early (IE) gene promoters and their products are differentially expressed in these cells (J. Chen, X. Zhu, and S. Silverstein, Virology 180:207-220, 1991; I. H. Gelman and S. Silverstein, J. Virol. 61:2286-2296, 1987). Viruses with IE-0 genes that only poorly activated reporter genes in transient expression assays plaqued less efficiently on Vero cells and consistently accumulated decreased levels of late proteins. These mutants were also examined in single-step growth curve experiments and for the dependence of virus yield on multiplicity of infection (MOI). At low MOIs, their yields were less in Vero cells than in HeLa cells; by contrast, at high MOIs, there was no apparent difference in yield in either cell type, although each virus produced considerably fewer progeny than wild-type virus. Analysis of steady-state levels of RNA from genes representing each of the three major kinetic classes demonstrated that lower levels of RNAs accumulate in these mutants. We conclude from these studies that while ICP0 is not essential for virus growth in tissue culture, defects in this gene result in impairment of virus replication and delay the expression of early and late gene transcripts.

Identification of dominant-negative mutants of the herpes simplex virus type 1 immediate-early protein ICP0

ICP0 is a 110,000-molecular-weight immediate-early protein of herpes simplex virus type 1 (HSV-1) which is encoded by three exons. It has been shown to function as a promiscuous transactivator of a variety of different HSV-1 and non-HSV-1 promoters in transient expression assays. Analysis of mutations which truncated the carboxy-terminal end of this 775-amino-acid (aa) protein demonstrated that a polypeptide which contained only aa 1 to 553 still possessed significant transactivation potential. Additional carboxy-terminal truncations which sequentially removed aa 245 to 553 and thus the remainder of the third exon resulted in the eventual loss of transactivation capability in these mutants. However, further analysis of these truncated derivatives demonstrated that they behaved as dominant-negative mutants to the wild-type polypeptide. Moreover, one of the mutants was found to act as a promiscuous repressor, in that it could dramatically inhibit a variety of HSV-1 promoters, non-HSV-1 promoters, and heterologous transactivator proteins in transient expression assays, despite having lost almost the entire third exon. These results indicate that a domain encoded by the first two exons probably interacts with, and can effectively titrate, the unknown cellular factor(s) through which ICP0 mediates transactivation.

Characterization of the regulatory functions of the equine herpesvirus 1 immediate-early gene product

Use of the translation-inhibiting drug cycloheximide has indicated that the equine herpesvirus 1 (EHV-1) immediate-early (IE) gene, the sole EHV-1 IE gene, encodes a major viral regulatory protein since IE mRNA translation is a prerequisite for all further viral gene expression (W.L. Gray, R. P. Baumann, A. T. Robertson, G. B. Caughman, D. J. O'Callaghan, and J. Staczek, Virology 158:79-87, 1987). An EHV-1 IE gene expression vector (pSVIE) in combination with chimeric EHV-1 promoter-chloramphenicol acetyltransferase (CAT) reporter constructs was used in transient transfection assays to characterize the regulatory functions of the IE gene product. These experiments demonstrated that (i) the EHV-1 IE gene product is a bifunctional protein capable of both positive and negative modulation of gene expression; (ii) the IE gene product possesses an autoregulatory function which represses the IE promoter; (iii) IE autoregulation is dependent on IE promoter sequences mapping within positions -288 to +73 relative to the transcription initiation site (+1) of the IE gene; (iv) the IE gene product can independently activate the EHV-1 tk promoter (an early promoter) by as much as 60-fold; (v) two EHV-1 beta-gamma (leaky late) promoters, those of IR5 (gene 5 in the inverted repeat) and the glycoprotein D gene, demonstrate a requirement for both the IE gene product as well as a gene product encoded within the EHV-1 XbaI G fragment for significant activation; and (vi) the IE gene product is capable of activating heterologous viral promoters.

High level expression and purification of herpes simplex virus type 1 immediate early polypeptide Vmw110

Herpes simplex virus type 1 (HSV-1) encodes five immediate early (IE) polypeptides. This paper reports the construction of a baculovirus vector which expresses large amounts of Vmw110, the product of IE gene 1. The expressed protein has been purified to near homogeneity and has a mobility on SDS polyacrylamide gels identical to that of Vmw110 produced during HSV-1 infection. Characterisation of its properties indicated that it forms dimers and perhaps higher order oligomers in solution and that the purified protein binds to both single stranded and double stranded calf thymus DNA cellulose columns. However, filter binding experiments were unable to detect any stable association of Vmw110 with DNA in solution.

Characterization of the bovine herpesvirus 4 major immediate-early transcript

The major immediate-early (IE) RNA of bovine herpesvirus 4 (BHV-4) has been identified and characterized by analyzing cytoplasmic polyadenylated RNA isolated from Madin-Darby bovine kidney cells infected with BHV-4(DN-599) in the presence of cycloheximide. Hybridization of cDNA to Southern blots of viral DNA, Northern (RNA) blot analysis, and S1 nuclease analyses showed that the major BHV-4 IE RNA is a spliced, 1.7-kb RNA, which is transcribed from right to left on the restriction map of the BHV-4 genome from DNA contained in the 8.3-kb HindIII fragment E. The major IE RNA contains three small exons at its 5' end, spliced to a 1.3-kb 3' exon. This RNA is present in much-reduced amounts when cells are infected in the absence of cycloheximide. However, late in infection, the major IE RNA gene region encodes abundant RNAs which differ in structure from the major IE RNA. Nucleotide sequence analysis of the gene encoding the major IE RNA revealed an open reading frame encoding 284 amino acids. A homology search of amino acid sequence data bases showed that a 141-amino-acid region near the amino terminus of the predicted amino acid sequence is similar to sequences near the amino terminus of herpes simplex virus type 1 IE110. This region of homology includes CXXC pairs, which could be involved in zinc finger structures. The region encoding this putative zinc finger domain is also found in RNAs transcribed from this IE region late in infection, but it is spliced to different sequences than those used in IE RNA. Thus, the major IE region of the BHV-4 genome could encode a family of proteins sharing a zinc finger domain.

Characterization of a potent varicella-zoster virus-encoded trans-repressor

Using a transient expression assay in Vero cells, we have shown that the protein product from gene 61 of varicella-zoster virus (VZV) can repress the function of the VZV encoded trans-activators on putative viral immediate-early, early, and late gene promoters. The repression is exerted at the transcriptional level and requires functional gene 61 protein. This trans-repressor is the herpes simplex type 1 ICP0 (a trans-activator) homolog, as defined by gene location, the sharing of a cysteine-rich putative zinc-binding finger in the amino-terminal region, and limited amino acid homology. Open reading frame 61 (ORF61)-mediated trans-repression appears to be specific for VZV-encoded trans-activators in that it has no effect on simian virus 40 and Rous sarcoma virus promoters. Moreover, it does not inhibit trans-activation of the human T-lymphotropic virus type I and human immunodeficiency virus long terminal repeats by tax and tat genes, respectively. We constructed plasmids with mutations in ORF61 and tested them for their ability to inhibit trans-activator (VZV genes 4 and 62)-mediated activation of the viral thymidine kinase promoter-chloramphenicol acetyltransferase construct. Mutants containing interruptions in ORF61 lost their trans-repressing ability, as demonstrated at both the protein and steady-state RNA levels. These results suggest that the ORF61 protein product can mediate down-regulation of VZV gene expression.

A cellular function can enhance gene expression and plating efficiency of a mutant defective in the gene for ICP0, a transactivating protein of herpes simplex virus type 1

ICP0 transactivates herpes simplex virus type 1 genes of all classes as well as a number of heterologous viral and cellular genes, yet it is not essential for virus replication in vitro or in vivo. Stocks of ICP0 deletion mutants, however, exhibit significantly lower plating efficiencies on standard 24-h-old Vero cell monolayers than do stocks of wild-type virus. In an attempt to determine whether the growth status of cells in the monolayer affects the ability of ICP0 mutants to initiate plaque formation, the plating efficiencies and abilities of an ICP0 null mutant (7134) and of wild-type virus (KOS) to express selected viral proteins were determined on Vero cell monolayers whose growth had been arrested either by contact inhibition-trypsinization or by isoleucine deprivation and had then been released from growth arrest. The proportion of cells cycling synchronously after release from growth arrest was assessed by flow cytometry. The results of these studies indicate that the plating efficiency of 7134 was greatest on Vero cell monolayers 8 h after release from growth arrest induced by either treatment. Monolayers of both types released from growth arrest at other times supported 7134 plaque formation less efficiently. In contrast, the plating efficiency of KOS was nearly equal on monolayers at all times after release from growth arrest. Notably, both KOS and 7134 were equally efficient in entering cells and inducing expression of the immediate-early protein ICP4 in either 8- or 24-h monolayers. Relative to KOS, however, 7134 was significantly impaired in the expression of selected early and late genes in cells at 24 h postrelease. When the plating efficiencies of 7134 and KOS were examined in 0-28 cells (Vero cells that are stably transformed with the ICP0 gene) whose growth had been arrested and then released, no differences in the plating efficiencies of the two viruses as a function of growth status were noted. These findings suggest that a cellular function expressed maximally in cells 8 h after release from growth arrest can substitute operationally for ICP0 to enhance plaque formation and viral gene expression by 7134. They further suggest that one role of ICP0 in viral infection is to facilitate virus replication in cells that do not express this function.

Herpes simplex virus latency-associated transcript is a stable intron

The latency-associated transcript (LAT) is the major viral transcript detected by in situ hybridization of mouse and human sensory ganglia latently infected with herpes simplex virus type 1. The last 750 bases of LAT are complementary to infected-cell polypeptide 0, a herpes simplex virus type 1 immediate-early gene that encodes a transactivating protein that may facilitate re-activation of the virus from the latent state. Several laboratories have shown that LAT accumulates in the nucleus and is not polyadenylylated. Recently, we showed that the promoter for LAT lies 688 bases upstream from its 5' end. We report here that LAT is actually a uniquely stable intron. Furthermore, LAT effectively inhibits transactivation of gene expression by infected-cell polypeptide 0 in transient transfection assays.

Isolation and characterization of a functional cDNA encoding ICP0 from herpes simplex virus type 1

The IE-0 gene of herpes simplex virus type 1 (HSV-1) contains two introns and encodes ICP0, a powerful transcriptional activator. We have isolated a cDNA clone that encodes ICP0 from a lambda gt10 cDNA library constructed from RNAs made from HSV-1-infected HeLa cells. DNA sequence analysis of this clone confirmed the predicted intron/exon boundaries (L. J. Perry, F. J. Rixon, R. D. Everett, M. C. Frame, and D. J. McGeoch, J. Gen. Virol. 67:2365-2380, 1986). Following transfection, a plasmid containing the cDNA copy of IE-0 directed the synthesis of ICP0, which was appropriately compartmentalized and distributed in the nucleus, as revealed by immunofluorescence. A transient expression assay was used to demonstrate that this cDNA copy retained the ability to transactivate the HSV-1 promoters for the IE-0 gene (an immediate-early gene), the thymidine kinase gene (an early gene), and the glycoprotein C gene (a late gene). The product of this cDNA clone cooperated with ICP4 to activate expression from the thymidine kinase gene promoter in a synergistic manner. The availability of a functional cDNA copy encoding ICP0 provides the opportunity to express this protein in vector systems that do not recognize eucaryotic donor and acceptor splicing signals to overexpress ICP0.

The repressing and enhancing functions of the herpes simplex virus regulatory protein ICP27 map to C-terminal regions and are required to modulate viral gene expression very early in infection

The phenotypic properties of ICP27 temperature-sensitive and deletion mutants and the results of transient expression assays have demonstrated that ICP27 has a modulatory effect on viral gene expression induced by ICPs 0 and 4. In order to identify the regions of the ICP27 molecule that are responsible for its enhancing and repressing activities, 10 nonsense and 3 in-frame deletion mutations were introduced into the coding sequence of the cloned ICP27 gene. These mutant genes were tested in transient expression assays for their ability to complement an ICP27 null mutant and to enhance and repress expression from a spectrum of herpes simplex virus type 1 promoters in reporter CAT genes when expression was induced by ICP0 or ICP4. The results of assays with cloned mutant genes demonstrate that the ICP27 polypeptide contains two regions, located between amino acid residues 327 and 407 and residues 465 and 511, that contribute to its repressing activity. The amino acid region located between the two repressing regions (residues 407 to 465) is able to interfere with ICP27 repressing activity. None of the mutant genes exhibited efficient enhancing activity for any of the herpes simplex type 1 promoters tested, demonstrating that amino acids comprising the carboxy-terminal half of the ICP27 molecule, including the terminal phenylalanine residue, are required for wild-type enhancement as well as for efficient complementation of an ICP27 null mutant. Phenotypic characterization of an in-frame deletion mutant, vd3, and a previously isolated null mutant, 5dl 1.2 (A. M. McCarthy, L. and P. A. Schaffer, J. Virol. 63:18-27, 1989), demonstrated that ICP27 is required to induce the expression of all classes of viral genes very early in infection and confirmed the requirement for ICP27 later in infection (i) to repress early gene expression, (ii) to induce wild-type levels of delayed-early or gamma 1 gene expression, and (iii) to induce true late or gamma 2 gene expression. The vd3 mutant, which specifies an ICP27 peptide lacking the repressing region between residues 327 and 407, is able to (i) repress early gene expression, consistent with the repressing ability of the d3 mutation in transient expression assays, (ii) induce the synthesis of significant but reduced levels of delayed-early (gamma 1) proteins and no gamma 2 proteins (thus vd3 exhibits a late protein phenotype intermediate between that of the wild-type virus and 5dl 1.2), and (iii) confer altered electrophoretic mobility on ICP4, demonstrating a role for ICP27 in the posttranslational modification of this essential regulatory protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Recombinogenic properties of herpes simplex virus type 1 DNA sequences resident in simian virus 40 minichromosomes

In a previous work, it was demonstrated that the bacterial transposon Tn5 is capable of undergoing sequence inversion via recombination between its duplicated IS50 elements when replicated by the herpes simplex virus type 1 (HSV-1) origin oris but not by the simian virus 40 (SV40) origin orisv. Further analysis of the latter phenomenon indicated that this lack of recombination was the result of topological constraints imposed by the SV40 minichromosome, such that recombination events could be readily detected in Tn5 derivatives in which the IS50 elements were arranged in a direct rather than inverted orientation. With this information, a second set of experiments were carried out to examine how the highly recombinogenic sequences which mediate the inversion of the long (L) and short (S) components of the HSV-1 genome behave in an SV40 minichromosome. Tandem copies of the L-S junction of the HSV-1 genome were observed to promote deletions in an SV40 shuttle plasmid at a frequency that was considerably greater than that of duplicated bacterial plasmid vector DNA. However, the presence of superinfecting HSV-1 did not enhance the frequency of these recombination events. These results support our previous findings that HSV-1 genome isomerization is mediated by a homologous recombination mechanism which is intimately associated with the act of viral DNA synthesis. Moreover, they demonstrate that the sequences which comprise the L-S junction appear to be inherently recombinogenic and, therefore, do not contain specific signals required for HSV-1 genome isomerization.

Genetic evidence for multiple nuclear functions of the herpes simplex virus ICP8 DNA-binding protein

We have isolated several mutant herpes simplex viruses, specifically mutated in the infected cell protein 8 (ICP8) gene, to define the functional domains of ICP8, the major viral DNA-binding protein. To facilitate the isolation of these mutants, we first isolated a mutant virus, HD-2, with the lacZ gene fused to the ICP8 gene so that an ICP8-beta-galactosidase fusion protein was expressed. This virus formed blue plaques on ICP8-expressing cell lines in the presence of 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside. Mutated ICP8 gene plasmids cotransfected with HD-2 DNA yielded recombinant viruses with the mutant ICP8 gene incorporated into the viral genome. These recombinants were identified by formation of white plaques. Four classes of mutants were defined: (i) some expressed ICP8 that could bind to DNA but could not localize to the cell nucleus; (ii) some expressed ICP8 that did not bind to DNA but localized to the nucleus; (iii) some expressed ICP8 that neither bound to DNA nor localized to the nucleus; and (iv) one expressed ICP8 that localized to the cell nucleus and bound to DNA in vitro, but the mutant virus did not replicate its DNA. These classes of mutants provide genetic evidence that DNA binding and nuclear localization are distinct functions of ICP8 and that ICP8 has nuclear functions other than binding to DNA. Furthermore, the portion of ICP8 needed for a nuclear function(s) distinct from DNA binding is the part of ICP8 showing sequence similarity to that of the cellular protein cyclin or proliferating cell nuclear antigen.

The regions important for the activator and repressor functions of herpes simplex virus type 1 alpha protein ICP27 map to the C-terminal half of the molecule

The herpes simplex virus type 1 (HSV-1) alpha or immediate-early proteins ICP4 (IE175), ICP0 (IE110), and ICP27 (IE63) are trans-acting proteins which affect HSV-1 gene expression. We previously showed that ICP27 in combination with ICP4 and ICP0 could act as a repressor or an activator in transfection assays, depending on the target gene (R. E. Sekulovich, K. Leary, and R. M. Sandri-Goldin, J. Virol. 62:4510-4522, 1988). To investigate the regions of the ICP27 protein which specify these functions, we constructed a series of in-frame insertion and deletion mutants in the ICP27 gene. These mutants were analyzed in transient expression assays for the ability to repress or to activate two different target genes. The target plasmids used consisted of the promoter regions from the HSV-1 beta or early gene which encodes thymidine kinase and from the beta-gamma or leaky late gene. VP5, which encodes the major capsid protein, each fused to the chloramphenicol acetyltransferase gene. Our previous studies showed that induction of pTK-CAT expression by ICP4 and ICP0 was repressed by ICP27, whereas the stimulation of pVP5-CAT expression seen with ICP4 and ICP0 was significantly increased when ICP27 was also added. In this study, a series of transfection assays was performed with each of the ICP27 mutant plasmids in combination with plasmids containing the ICP4 and ICP0 genes with each target. The results of these experiments showed that mutants containing insertions or deletions in the region from amino acids 262 to 406 in the carboxy-terminal half of the protein were unable to stimulate expression of pVP5-CAT but were able to repress induction of pTK-CAT activity by ICP4 and ICP0. Mutants in the carboxy-terminal 78 amino acids lost both activities; that is, these mutants did not show repression of pTK-CAT activity or stimulation of pVP5-CAT activity, whereas mutants in the hydrophilic amino-terminal half of ICP27 were able to perform both functions. These results show that the carboxy-terminal half of ICP27 is important for the activation and repression functions. Furthermore, the carboxy-terminal 62 amino acids are required for the repressor activity, because mutants with this region intact were able to repress. Analysis of the DNA sequence showed that there are a number of cysteine and histidine residues encoded by this region which have some similarity to zinc finger metal-binding regions found in other eucaryotic regulatory proteins. These results suggest that the structural integrity of this region is important for the function of ICP27.

Herpes simplex virus type 1 ICP0 plays a critical role in the de novo synthesis of infectious virus following transfection of viral DNA

As a first step in identifying the functions and intramolecular functional domains of herpes simplex virus type 1 infected cell protein 0 (ICP0) in productive infection and latency, a series of mutant plasmids specifying varying amounts of the ICP0 primary amino acid sequence were constructed. In transient expression assays with mutant and wild-type plasmids, the N-terminal half of the ICP0 molecule was found to be sufficient to transactivate a variety of viral promoters. Although promoters representing the immediate-early, early, and late kinetic classes were transactivated by wild-type ICP0, individual promoters responded to mutant forms of ICP0 in a manner consistent with the possibility that ICP0 transactivates different promoters by different mechanisms. Unlike infection with virus particles, which contain the 65-kilodalton transcriptional transactiovator, the initiation of viral replication after transfection of cells with purified viral DNA requires de novo protein synthesis. In order to assess the role of ICP0 in the de novo synthesis of infectious virus, Vero cells were transfected with purified DNA of wild-type virus or an ICP0 null mutant and the production of infectious virus was monitored. In cells transfected with mutant DNA, virus production was delayed by 2 days and the level of virus was reduced by several orders of magnitude relative to Vero cells transfected with wild-type viral DNA, suggesting an important role for ICP0 in the de novo synthesis of infectious particles. In cotransfection experiments with infectious DNA of the ICP0 null mutant and a plasmid specifying wild-type ICP0 titers of infectious virus were significantly enhanced relative to transfection with mutant DNA alone, confirming the role of ICP0 in de novo synthesis. These findings are consistent with the proposed role of ICP0 in reactivation of herpes simplex virus from latency (D. A. Leib, D. M. Coen, C. L. Bogard, K. A. Hicks, D. R. Yager, D. M. Knipe, K. L. Tyler, and P. A. Schaffer, J. Virol. 63:759-768, 1989), a process also thought to require de novo protein synthesis. The complementing activities of ICP0 mutant plasmids for ICP0 null mutant DNA in cotransfection assays correlated well with their transactivating activities for viral promoters in transient assays, indicating that the transactivating function of ICP0 is a critical factor in the de novo synthesis of infectious particles.(ABSTRACT TRUNCATED AT 400 WORDS)

The adenovirus E4 gene, in addition to the E1A gene, is important for trans-activation of E2 transcription and for E2F activation

Previous experiments have demonstrated that adenovirus infection of human and mouse cells leads to an E1A-dependent activation of the DNA-binding capacity of a cellular transcription factor termed E2F. E2F binds to two sites in the adenovirus E2 early promoter which have been shown to be critical for E1A-dependent E2 early transcription, and the E2F-binding sites can confer E1A-induced transcription to a heterologous promoter. In addition, under a variety of circumstances, the increase in E2F-binding activity coincides with the activation of E2 transcription. We now find that, in addition to the E1A gene, another early viral gene, the E4 gene, is necessary for the activation of E2F-binding activity. Extracts prepared from human 293 cells, which express the E1A and E1B genes, had low levels of E2F activity, whereas infection of 293 cells with the E1A mutant dl312 increased E2F activity. This increase did not occur when 293 cells were infected with dl366, an E4 deletion mutant, nor was there an increase in E2F activity in HeLa cells infected with either dl366 or dl312; however, a coinfection with the two mutants yielded the normal wild-type increase in E2F. Furthermore, infection of HeLa cells with a high multiplicity of dl312, conditions that allow E4 gene expression in the absence of E1A, did not yield an increase in E2F activity. Thus, it appears that both the E1A gene and the E4 gene are directly involved in E2F activation. Measurements of E2 RNA production in a dl366 infection as compared with a wild-type or dl312 infection demonstrate that the E4 gene is essential for full E2 transcription. Furthermore, transfection assays of the E2 promoter demonstrate that, although E1A alone can trans-activate the E2 promoter, it is not as effective as the combination of E1A and E4 in the induction of the E2 promoter. We therefore conclude that the activation of the E2F factor leading to the activation of E2 transcription requires the combined action of both the E1A 289-amino-acid protein and an E4 product.

A subset of herpes simplex virus replication genes induces DNA amplification within the host cell genome

Herpes simplex virus (HSV) induces DNA amplification of target genes within the host cell chromosome. To characterize the HSV genes that mediate the amplification effect, combinations of cloned DNA fragments covering the entire HSV genome were transiently transfected into simian virus 40 (SV40)-transformed hamster cells. This led to amplification of the integrated SV40 DNA sequences to a degree comparable to that observed after transfection of intact virion DNA. Transfection of combinations of subclones and of human cytomegalovirus immediate-early promoter-driven expression constructs for individual open reading frames led to the identification of six HSV genes which together were necessary and sufficient for the induction of DNA amplification: UL30 (DNA polymerase), UL29 (major DNA-binding protein), UL5, UL8, UL42, and UL52. All of these genes encode proteins necessary for HSV DNA replication. However, an additional gene coding for an HSV origin-binding protein (UL9) was required for origin-dependent HSV DNA replication but was dispensible for SV40 DNA amplification. Our results show that a subset of HSV replication genes is sufficient for the induction of DNA amplification. This opens the possibility that HSV expresses functions sufficient for DNA amplification but separate from those responsible for lytic viral growth. HSV infection may thereby induce DNA amplification within the host cell genome without killing the host by lytic viral growth. This may lead to persistence of a cell with a new genetic phenotype, which would have implications for the pathogenicity of the virus in vivo.