Differentiation and DNA contact points of host proteins binding at the cis site for virion-mediated induction of alpha genes of herpes simplex virus 1

Stress Induced Transcription Factors Transactivate the Herpes Simplex Virus 1 Infected Cell Protein 27 (ICP27) Transcriptional Enhancer

Following acute infection, herpes simplex virus 1 (HSV-1) establishes lifelong latency in neurons, including sensory neurons within trigeminal ganglia. During latency, lytic cycle viral gene expression is silenced. However, stressful stimuli can trigger reactivation from latency. The viral tegument protein, VP-16, transactivates all immediate early (IE) promoters during productive infection. Conversely, cellular factors are expected to trigger viral gene expression during early stages of reactivation from latency and in non-neuronal cells that do not support high levels of productive infection. The glucocorticoid receptor (GR), synthetic corticosteroid dexamethasone, and certain stress-induced transcription factors cooperatively transactivate infected cell protein 0 (ICP0) and ICP4 promoters. Since ICP27 protein expression is required for productive infection, we hypothesized that the ICP27 promoter is transactivated by stress-induced transcription factors. New studies have demonstrated that ICP27 enhancer sequences were transactivated by GR and Krüppel-like factor 15 (KLF15). Mutation of a consensus Sp1 binding site within ICP27 enhancer sequences impaired transactivation by GR and KLF15. Chromatin immunoprecipitation studies have demonstrated that GR and KLF15 occupy ICP27 promoter sequences during productive infection. Cells transfected with an ICP27 enhancer fragment revealed the GR and KLF15 occupancy of ICP27 enhancer sequences required the intact Sp1 binding site. Notably, GR and KLF15 form a feed-forward transcription loop in response to stress, suggesting these cellular factors promote viral replication following stressful stimuli.

The canonical Wnt/β-catenin signaling pathway stimulates herpes simplex virus 1 productive infection

The ability of herpes simplex virus 1 (HSV-1) to replicate efficiently in differentiated cells is regulated by cellular factors that stimulate viral gene expression, cell survival, and viral morphogenesis. Activation of the canonical Wnt signaling pathway generally increases β-catenin protein levels, cell survival, and growth in dividing cells suggesting this important signaling pathway regulates productive infection. In this study, we demonstrated that a β-catenin specific small molecule inhibitor (iCRT14) reduced HSV-1 titers approximately 10-fold in primary human lung fibroblasts and Vero cells. Furthermore, β-catenin dependent transcription was increased at late times after infection and as expected iCRT14 reduced β-catenin dependent transcription. Although HSV-1 infection increased β-catenin steady state protein levels approximately 4-fold in Vero cells, there was only a nominal increase in human lung fibroblasts. We hypothesized that VP16 regulates β-catenin dependent transcription because VP16 is a viral regulatory protein expressed at late times after infection. In the absence of other viral proteins, VP16 increased β-catenin dependent transcription and β-catenin steady state protein levels. Collectively, these studies suggested the cellular transcription factor β-catenin stimulates productive infection, in part because VP16 enhances β-catenin dependent transcription.

The number of alphaherpesvirus particles infecting axons and the axonal protein repertoire determines the outcome of neuronal infection

Infection by alphaherpesviruses invariably results in invasion of the peripheral nervous system (PNS) and establishment of either a latent or productive infection. Infection begins with long-distance retrograde transport of viral capsids and tegument proteins in axons toward the neuronal nuclei. Initial steps of axonal entry, retrograde transport, and replication in neuronal nuclei are poorly understood. To better understand how the mode of infection in the PNS is determined, we utilized a compartmented neuron culturing system where distal axons of PNS neurons are physically separated from cell bodies. We infected isolated axons with fluorescent-protein-tagged pseudorabies virus (PRV) particles and monitored viral entry and transport in axons and replication in cell bodies during low and high multiplicities of infection (MOIs of 0.01 to 100). We found a threshold for efficient retrograde transport in axons between MOIs of 1 and 10 and a threshold for productive infection in the neuronal cell bodies between MOIs of 1 and 0.1. Below an MOI of 0.1, the viral genomes that moved to neuronal nuclei were silenced. These genomes can be reactivated after superinfection by a nonreplicating virus, but not by a replicating virus. We further showed that viral particles at high-MOI infections compete for axonal proteins and that this competition determines the number of viral particles reaching the nuclei. Using mass spectrometry, we identified axonal proteins that are differentially regulated by PRV infection. Our results demonstrate the impact of the multiplicity of infection and the axonal milieu on the establishment of neuronal infection initiated from axons.

Alphaherpesvirus genomes may remain silent in peripheral nervous system (PNS) neurons for the lives of their hosts. These genomes occasionally reactivate to produce infectious virus that can reinfect peripheral tissues and spread to other hosts. Here, we use a neuronal culture system to investigate the outcome of axonal infection using different numbers of viral particles and coinfection assays. We found that the dynamics of viral entry, transport, and replication change dramatically depending on the number of virus particles that infect axons. We demonstrate that viral genomes are silenced when the infecting particle number is low and that these genomes can be reactivated by superinfection with UV-inactivated virus, but not with replicating virus. We further show that viral invasion rapidly changes the profiles of axonal proteins and that some of these axonal proteins are rate limiting for efficient infection. Our study provides new insights into the establishment of silent versus productive alphaherpesvirus infections in the PNS.

The 3 facets of regulation of herpes simplex virus gene expression: A critical inquiry

On entry into the body herpes simplex viruses (HSV) replicate in a series of steps that involves derepression of viral DNA activated by VP16, a virion protein, and sequential transcription of viral genes in a cascade fashion. HSV also enters into neurons in which viral DNA maintained as heterochromatin and with few exceptions viral gene expression is silenced. A third face of the interaction of HSV with its host cells takes place at the moment when the silenced viral genome in neurons is abruptly derepressed. The available data do no reveal evidence that HSV encodes different regulatory programs for each facet of its interaction with its host cells. Rather the data point to significant gaps in our knowledge of the mechanisms by which each facet is initiated and the roles of the infected cells at each facet of the interaction of viral gene products with the host cell.

Virus infections in the nervous system

Virus infections usually begin in peripheral tissues and can invade the mammalian nervous system (NS), spreading into the peripheral (PNS) and more rarely the central (CNS) nervous systems. The CNS is protected from most virus infections by effective immune responses and multilayer barriers. However, some viruses enter the NS with high efficiency via the bloodstream or by directly infecting nerves that innervate peripheral tissues, resulting in debilitating direct and immune-mediated pathology. Most viruses in the NS are opportunistic or accidental pathogens, but a few, most notably the alpha herpesviruses and rabies virus, have evolved to enter the NS efficiently and exploit neuronal cell biology. Remarkably, the alpha herpesviruses can establish quiescent infections in the PNS, with rare but often fatal CNS pathology. Here we review how viruses gain access to and spread in the well-protected CNS, with particular emphasis on alpha herpesviruses, which establish and maintain persistent NS infections.

The molecular basis of herpes simplex virus latency

Herpes simplex virus type 1 is a neurotropic herpesvirus that establishes latency within sensory neurones. Following primary infection, the virus replicates productively within mucosal epithelial cells and enters sensory neurones via nerve termini. The virus is then transported to neuronal cell bodies where latency can be established. Periodically, the virus can reactivate to resume its normal lytic cycle gene expression programme and result in the generation of new virus progeny that are transported axonally back to the periphery. The ability to establish lifelong latency within the host and to periodically reactivate to facilitate dissemination is central to the survival strategy of this virus. Although incompletely understood, this review will focus on the mechanisms involved in the regulation of latency that centre on the functions of the virus-encoded latency-associated transcripts (LATs), epigenetic regulation of the latent virus genome and the molecular events that precipitate reactivation.

This review considers current knowledge and hypotheses relating to the mechanisms involved in the establishment, maintenance and reactivation herpes simplex virus latency.

Mammalian alphaherpesvirus miRNAs

Mammalian alphaherpesviruses are major causes of human and veterinary disease. During productive infection, these viruses exhibit complex and robust patterns of gene expression. These viruses also form latent infections in neurons of sensory ganglia in which productive cycle gene expression is highly repressed. Both modes of infection provide advantageous opportunities for regulation by microRNAs. Thus far, published data regarding microRNAs are available for six mammalian alphaherpesviruses. No microRNAs have yet been detected from varicella zoster virus. The five other viruses-herpes simplex viruses-1 and -2, herpes B virus, bovine herpesvirus-1, and pseudorabies virus-representing both genera of mammalian alphaherpesviruses have been shown to express microRNAs. In this article, we discuss these microRNAs in terms of where they are encoded in the viral genome relative to other viral transcripts; whether they are expressed during productive or latent infection; their potential targets; what little is known about their actual targets and functions during viral infection; and what little is known about the interactions of these viruses with the host microRNA machinery. This article is part of a Special Issue entitled: "MicroRNAs in viral gene regulation".

Direct interactions of Kaposi's sarcoma-associated herpesvirus/human herpesvirus 8 ORF50/Rta protein with the cellular protein octamer-1 and DNA are critical for specifying transactivation of a delayed-early promoter and stimulating viral reactivation

The Kaposi's sarcoma-associated herpesvirus (KSHV) delayed-early K-bZIP promoter contains an ORF50/Rta binding site whose sequence is conserved with the ORF57 promoter. Mutation of the site in the full-length K-bZIP promoter reduced Rta-mediated transactivation by greater than 80%. The K-bZIP element contains an octamer (Oct) binding site that overlaps the Rta site and is well conserved with Oct elements found in the immediate-early promoters of herpes simplex virus type 1(HSV-1). The cellular protein Oct-1, but not Oct-2, binds to the K-bZIP element in a sequence-specific fashion in vitro and in vivo and stimulates Rta binding to the promoter DNA. The coexpression of Oct-1 enhances Rta-mediated transactivation of the wild type but not the mutant K-bZIP promoter, and Oct-1 and Rta proteins bind to each other directly in vitro. Mutations of Rta within an amino acid sequence conserved with HSV-1 virion protein 16 eliminate Rta's interactions with Oct-1 and K-bZIP promoter DNA but not RBP-Jk. The binding of Rta to both Oct-1 and DNA contributes to the transactivation of the K-bZIP promoter and viral reactivation, and Rta mutants deficient for both interactions are completely debilitated. Our data suggest that the Rta/Oct-1 interaction is essential for optimal KSHV reactivation. Transfections of mouse embryo fibroblasts and an endothelial cell line suggest cell-specific differences in the requirement for Oct-1 or RBP-Jk in Rta-mediated transactivation of the K-bZIP promoter. We propose a model in which Rta transactivation of the promoter is specified by the combination of DNA binding and interactions with several cellular DNA binding proteins including Oct-1.

Herpesvirus quiescence in neuronal cells. V: forskolin-responsiveness of the herpes simplex virus type 1 alpha0 promoter and contribution of the putative cAMP response element

The herpes simplex virus (HSV)-1 alpha0 promoter contains a putative cAMP response element (CRE) located at positions -68 to -60 with respect to the initiation of transcription. In this report, the authors examined the functionality of this element using (1) luciferase reporter gene assays in nerve growth factor-differentiated (ND)-PC12 cells and (2) virus-induced activation from quiescently infected (QIF)-PC12 cells. The putative alpha0 CRE was completely eliminated by digestion with the restriction enzyme Tsp45I followed by mung bean nuclease treatment. The mutated region was verified by DNA sequencing and was inserted into the alpha0-luciferase reporter plasmid (pRDalpha0-LUC) creating (pRDalpha0deltaCRE-LUC), and into the HSV-1 genome of strain 17(+)(alpha0deltaCRE). Insertion into both copies of the alpha0 promoter was verified by Southern blot analysis. ND-PC12 cells transfected with pRDalpha0-LUC and pRDalpha0deltaCRE-LUC plasmids responded similarly to forskolin (50 microM), with approximately 250% increases in luciferase activity compared to mock-treated cultures as measured 3 days following treatment. When QIF-PC12 cultures established with HSV-1 strain 17(+) and alpha0deltaCRE were treated with forskolin (50 microM) 17 days post infection, virus was detected in 9/24 (37.5%) and 13/24 (54.2%) of induced cultures by day 8 post treatment, respectively. In contrast, virus was detected in 0/23 and 1/24 (4.2%) of mock-treated cultures by day 8 post treatment for wild-type and mutant viruses, respectively. These findings indicate that the alpha0 promoter is forskolin responsive, the purported CRE of the alpha0 promoter does not confer forskolin responsiveness in ND-PC12 cells, and this element is not required for reactivation of HSV-1 from QIF-PC12 cells.

Herpes simplex virus type 1 and bovine herpesvirus 1 latency

Primary infection by herpes simplex virus type 1 (HSV-1) can cause clinical symptoms in the peripheral and central nervous system, upper respiratory tract, and gastrointestinal tract. Recurrent ocular shedding leads to corneal scarring that can progress to vision loss. Consequently, HSV-1 is the leading cause of corneal blindness due to an infectious agent. Bovine herpesvirus 1 (BHV-1) has similar biological properties to HSV-1 and is a significant health concern to the cattle industry. Latency of BHV-1 and HSV-1 is established in sensory neurons of trigeminal ganglia, but latency can be interrupted periodically, leading to reactivation from latency and spread of infectious virus. The ability of HSV-1 and BHV-1 to reactivate from latency leads to virus transmission and can lead to recurrent disease in individuals latently infected with HSV-1. During latency, the only abundant HSV-1 RNA expressed is the latency-associated transcript (LAT). In latently infected cattle, the latency-related (LR) RNA is the only abundant transcript that is expressed. LAT and LR RNA are antisense to ICP0 or bICP0, viral genes that are crucial for productive infection, suggesting that LAT and LR RNA interfere with productive infection by inhibiting ICP0 or bICP0 expression. Numerous studies have concluded that LAT expression is important for the latency-reactivation cycle in animal models. The LR gene has recently been demonstrated to be required for the latency-reactivation cycle in cattle. Several recent studies have demonstrated that LAT and the LR gene inhibit apoptosis (programmed cell death) in trigeminal ganglia of infected animals and transiently transfected cells. The antiapoptotic properties of LAT map to the same sequences that are necessary for promoting reactivation from latency. This review summarizes our current knowledge of factors regulating the latency-reactivation cycle of HSV-1 and BHV-1.

DNA elements of the type 1 adenylyl cyclase gene locus enhance reporter gene expression in neurons and pinealocytes

The Ca2+-stimulated type 1 adenylyl cyclase (AC1) contributes to several forms of synaptic plasticity and is the only known neurospecific adenylyl cyclase. Furthermore, the protein and mRNA levels of AC1 undergo a circadian oscillation in the pineal gland, and AC1 may play a pivotal role in regulating nocturnal melatonin synthesis. To better understand the expression of AC1, we isolated mouse genomic DNA clones of AC1. The transcription and translation start regions of mouse AC1 share extensive homologies with the bovine counterpart. The upstream proximal region has potential binding sites for transcription factors, including the steroid receptor family, the E-box factors, and Sp1. A 280-bp fragment that contains the transcription start site directed reporter gene expression in cultured cortical neurons and pinealocytes functioning as a basal neuro- and pineal-directed promoter. Interestingly, pinealocyte expression of the reporter gene was inhibited by increases in cAMP. This cAMP sensitivity may explain why AC1 mRNA in the pineal is low at night when cAMP is elevated and high during the day when cAMP signals drop. An adjacent 330-bp fragment interacted specifically with nuclear factor(s) that we designate binary E-box factor (BEF). Methylation interference and DNase I footprinting identified the BEF-binding site sequence as 5'-CCAAGGTCACGTGGC-3'. When linked to the basal tissue-directed promoter, this 15-bp sequence further enhanced reporter expression in neurons and pinealocytes. We propose that this 15-bp sequence may contribute to increased expression of AC1 in neurons and pinealocytes relative to other cells.

The mouse homologue of the human transcription factor C1 (host cell factor). Conservation of forms and function

The assembly of the herpes simplex virus (HSV) alpha/IE gene enhancer complex is determined by the interactions of the Oct-1 POU domain protein, the viral alphaTIF (alpha-trans-induction factor, VP16, ICP25, VMW65), and the C1 factor (host cell factor, HCF). A unique transcription factor, C1 consists of a family of polypeptides derived from a common precursor by site-specific proteolytic processing. To analyze the role of this factor in the determination of HSV lytic-latent infection, cDNAs and genomic DNAs encoding the mouse homologue have been isolated. This factor is nearly identical to the human protein, contains multiple consensus proteolytic processing sites, and functions efficiently in the assembly of a specific HSV enhancer complex. Interestingly, the differential expression of the C1 factors in both human and mouse tissues may be important for the determination of HSV tissue tropism in these two organisms.

Infected cell protein 22 of herpes simplex virus 1 regulates the expression of virion host shutoff gene U(L)41

The U(L)41 protein of herpes simplex virus 1 (HSV-1) is packaged into virions, and in newly infected cells the protein mediates indiscriminate degradation of mRNA, which causes a shutoff of protein synthesis. We report that in cells infected with mutant virus in which either alpha22/U(S)1.5 or U(L)13 had been deleted: (i) the shutoff of protein synthesis and the degradation of mRNA did not take place or were greatly reduced, and consistent with these observations (ii) cells infected with mutant viruses accumulated less U(L)41 mRNA and protein than cells infected with the parent virus; and (iii) purified virions from cells infected with deltaU(L)13 or delta alpha22/deltaU(S)1.5 viruses contained less U(L)41 protein than virions produced by the wild-type parent virus. We conclude that the failure of the U(L)13- mutant virus to shut off protein synthesis immediately after infection is due to the failure of posttranslational modification of infected cell protein 22 and/or the related U(S)1.5 protein by the U(L)13 protein kinase. The regulatory effect of U(L)13 on U(L)41 is indirect and not contingent on direct interaction of this protein with the U(L)41 protein.

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.

Transcription factors interacting with herpes simplex virus alpha gene promoters in sensory neurons

Interference with VP16-mediated activation of herpes virus immediate-early (or alpha) genes is thought to be the major cause of establishing viral latency in sensory neurons. This could be brought about by lack of a key activating transcription factor(s) or active repression. In this study we find that sensory neurons express all important components for VP16-mediated alpha gene induction, such as the POU transcription factor Oct-1, host cell factor (HCF) and GABP alpha/beta. However, Oct-1 and GABP alpha/beta are only present at low levels and the VP16-induced complex (VIC) appears different. We do not find protein expression of the transcription factor Oct-2, implicated by others as an alpha gene repressor. The POU factor N-Oct3 (Brn 2 or POU3F2) is also present in sensory neurons and binds viral TAATGARAT motifs with higher affinity than Oct-1, indicating that it may be a candidate repressor for competitive binding to TAATGARAT motifs. When transfected into HeLa cells, where Oct-1 and GABP alpha/beta are highly abundant, N-Oct3 represses model promoters with multimerized TAATGARAT motifs, but fails to repress complete alpha gene promoters. Taken together our findings suggest that modulation of alpha gene promoters could contribute to viral latency when low concentrations of the activating transcription factors Oct-1 and GABP alpha/beta prevail. Our data, however, refute the notion that competing Oct factors are able to block alpha gene transcription to achieve viral latency.

The cellular C1 factor of the herpes simplex virus enhancer complex is a family of polypeptides

The alpha/immediate early genes of herpes simplex virus are regulated by the specific assembly of a multiprotein enhancer complex containing the Oct-1 POU domain protein, the viral alpha-transinduction factor alpha TIF, (VP16, ICP25), and the C1 cellular factor. The C1 factor from mammalian cells is a heterogeneous but related set of polypeptides that interact directly with the alpha-transinduction factor to form a heteromeric protein complex. The isolation of cDNAs encoding the polypeptides of the C1 factor suggests that these proteins are proteolytic products of a novel precursor. The sequence of the amino termini of these polypeptide products indicate that the proteins are generated by site-specific cleavages within a reiterated 20-amino acid sequence. Although the C1 factor appears to be ubiquitously expressed, it is localized to subnuclear structures in specific cell types.

An 85-kilodalton herpes simplex virus type 1 alpha trans-induction factor (VP16)-VP13/14 fusion protein retains the transactivation and structural properties of the wild-type molecule during virus infection

The 65-kDa herpes simplex virus type 1 encoded alpha trans-induction factor (alpha TIF or VP16) has two important functions: it is required for the efficient transcriptional induction of the alpha or immediate-early genes, and it acts as an essential structural component of the virion. The transcription properties of alpha TIF have been well studied in vitro. The protein is a powerful inducer of RNA polymerase II-directed transcription and, similar to the cellular transcriptional transactivators GAL4 and CGN4, contains separable DNA binding and transactivation domains. In contrast, little is known about the structural function of alpha TIF because this function can be studied only during virus replication and structural mutants are lethal. The in vivo analysis of alpha TIF is further complicated by the likelihood that the transcription and structural functions are not entirely separable. In this study, we take an alternate approach toward the development of alpha TIF mutants and their subsequent characterization. Rather than analyzing the effects of intragenic mutations, we have examined the properties of a mutant virus which expresses an alpha TIF fusion protein containing 61 amino acids of another herpes simplex virus type 1 virion protein, VP13/14, fused to its C terminus. This is the first report which demonstrates that the C-terminus of alpha TIF can tolerate the addition of an adjacent protein domain without compromising its transactivation function in vivo. Moreover, the VP13/14 sequences do not interfere with the protein-protein interactions required for virion targeting and assembly.

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.

The herpes simplex virus type 1 ICP6 gene is regulated by a 'leaky' early promoter

Expression from the promoter for the large subunit (ICP6) of the ribonucleotide reductase encoded by herpes simplex virus type 1 (HSV-1) has been examined. Using the lacZ reporter gene fused in-frame with ICP6 regulatory sequences to assay expression quantitatively, we showed that the ICP6 promoter responded very weakly to the alpha-transinducing factor (TIF) in the absence of all other viral gene products, but much more strongly to immediate early proteins. Similar patterns of regulation were observed when the reporter gene construct was located at two different positions within the the viral genome or in a stably transfected Vero cell line. Infection of the stably transfected cells with various HSV-1 mutants identified ICP0 as the major transactivator of the ICP6 promoter.

Immediate early and functional AP-1 cis-response elements are involved in the transcriptional regulation of the large subunit of herpes simplex virus type 2 ribonucleotide reductase (ICP10)

Expression from the promoter of the herpes simplex virus type 2 (HSV-2) large subunit of ribonucleotide reductase (ICP10) is stimulated by co-transfection with DNA that encodes the virion protein Vmw65 previously shown to activate in trans the transcription of all IE genes (Wymer et al., 1989). Specific cis response elements involved in ICP10 transcriptional regulation were studied by chloramphenicol acetyltransferase analysis with hybrid ICP10 promoter/CAT structural gene constructions containing wild type or site-directed mutations of the promoter sequences. The data indicate that Vmw65 activation requires an intact TAAT-GARAT motif while complex formation requires an intact Oct-1 element, and the AP-1 consensus elements in the ICP10 promoter are functional in vitro. Thus, expression from the wild type and GA-rich mutant constructions was enhanced 10-20-fold by co-transfection with DNA encoding Vmw65. The GARAT and POU homeobox (PHB) binding motifs were required for Vmw65 mediated activation but the mutant in the POU specific box (PSB) binding motif was activated at higher concentrations of Vmw65 DNA (1.0-3.0 micrograms). The PHB and PSB binding motifs were necessary for complex formation as determined by gel retardation analysis with in vitro synthesized OTF-1 and Vmw65 proteins. The GARAT and GA-rich elements were not required. CAT expression from pICP10-cat was enhanced by co-transfection with jun and fos encoding DNA, and the ICP10 promoter complexed with in vitro synthesized jun protein.

Deletion of the VP16 open reading frame of herpes simplex virus type 1

VP16 (also called Vmw65 and alpha TIF) is a structural protein of herpes simplex virus type 1 (HSV-1) that trans-induces HSV-1 immediate-early gene transcription. This report describes an HSV-1 VP16 deletion mutant that was constructed and propagated in a cell line transformed with a VP16 expression vector. The VP16 deletion mutant replicated like wild-type HSV-1 during infection of the VP16-expressing cell line. Deletion mutant virions propagated in this cell line contained wild-type, cell-derived VP16 protein that was recruited during virion assembly and was functional for immediate-early gene trans-induction. The mutant failed to replicate during subsequent infection of cells that do not express VP16, as determined in plaque assays and single-step replication assays. The deletion mutant induced nearly normal levels of viral DNA synthesis and capsid production during these infections, but it induced slightly lower levels of viral DNA encapsidation and appeared by transmission electron microscopy to be defective in further steps of virion maturation. A genetic revertant of the deletion mutant that was restored for VP16-coding sequences exhibited fully wild-type replication properties in both VP16-expressing and nonexpressing cells. The absence of VP16 protein synthesis at late times of HSV-1 infection prevents the production of infectious progeny virus and correlates with a profound defect in HSV-1 particle assembly.

Regulation of immunoglobulin gene transcription

Analysis of the immunoglobulin gene suggests that their expression is controlled through the combinatorial action of tissue- and stage-specific factors (OTF-2, TF-microB, NF-kappa B), as well as more widely expressed E motif-binding factors such as E47/E12. Two basic issues cloud understanding of how these factors are involved in immunoglobulin gene regulation. First, cloning of these factors shows them to be members of families of proteins, all with similar DNA-binding specificities. OTF-2 is a member of the POU domain family, NF-kappa B is a related protein, and the microE5/kappa E2-binding factors are members of the bHLH family. Second, these binding sites and associated factors are involved in the regulation of many genes, not only the immunoglobulin genes, and in fact not only lymphoid-specific genes. These facts complicate understanding which member of a family is in fact responsible for interaction with, and activation of, a particular binding element in an enhancer/promoter. Recently, more detailed analysis of the interactions between such proteins and their related binding sites suggest that a certain level of specificity may in fact be encoded by the DNA element such that one family member of a protein is preferentially bound, or alternatively that the protein-DNA interactions that occur give subtle alterations in protein conformation that unmask an activation or protein-protein interactive domain. An additional level of regulation is imparted by combinatorial mechanisms such as adjacent DNA-binding elements and factors that may alter activity, as well as "cofactors" that, by forming a complex with the bound factor, affect its activation of a gene in a particular cell type. A third level of specificity may be obtained by factors such as NF-kappa B and the bHLH family due to their ability to create heterogeneous complexes, creating unique complexes in a tissue- or stage-specific manner. The multiple functions transcription factors such as NF-kappa B and OTF-2 play in the transcriptional regulation of multiple genes seems complex in contrast to a one factor, one gene regulation model. However, this type of organization may limit the number of factors lymphocytes would require if each lymphoid-specific gene were activated by a unique factor. Thus what appears to be complexity at the molecular level may reflect an economical organization at the cellular level. Investigation of the key factors controlling these genes suggests an ordered cascade of transcription factors becomes available in the cell during B cell differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

Differential dependence of herpes simplex virus immediate-early gene expression on de novo-infected cell protein synthesis

The time course of accumulation of herpes simplex virus immediate-early (IE) mRNA and the requirement for infected cell protein synthesis for mRNA transcription and accumulation were compared. Measurements of transcription in nuclear run-on assays, accumulation of cytoplasmic mRNA by Northern (RNA) blot hybridization, and rates of infected cell protein synthesis by pulse-labeling did not indicate differences among the five IE gene, consistent with previous studies. However, as a result of varying the amount of de novo protein synthesis after infection, at least three patterns of maximal expression of the IE genes were revealed. Addition of the protein synthesis inhibitor anisomycin to cells coincident with infection resulted in maximal rates of transcription and accumulation of functional ICP0 mRNA, while 0.5 h of infected cell protein synthesis prior to addition of the drug was required for maximal expression of ICP22/47 and ICP27 mRNAs. Maximal expression of ICP4 mRNA occurred only when 1 h of de novo protein synthesis occurred prior to the addition of the drug. These results are discussed in the context of alternative mechanisms for regulating IE gene expression.

The interactions of transcription factors and their adaptors, coactivators and accessory proteins

Consistent with the complexity of the temporally regulated processes that must occur for growth and development of higher eukaryotes, it is now apparent that transcription is regulated by the formation of multicomponent complexes that assemble on the promoters of genes. These complexes can include (in addition to the five or more general transcription factors and RNA polymerase II) DNA-binding proteins, transcriptional activators, coactivators, adaptors and various accessory proteins. The best studied example of a complex that includes a transcriptional adaptor, accessory proteins and a DNA-binding protein is that involving the herpes simplex virus VP16 protein. Evidence suggests that the adenovirus E1a protein and the cellular Sp1 and CTF/NF1 transcription factors also function through adaptors or coactivators. Each additional component of the transcription complex provides the cell with another point at which to exert control of gene expression.

Role of alpha-transinducing factor (VP16) in the induction of alpha genes within the context of viral genomes

In herpes simplex virus 1, the five alpha genes are induced by alpha-transinducing factor (alpha TIF; VP16), a virion protein, acting in concert with Oct-1 and other cellular proteins on a cis-acting site in the promoter domain of alpha genes. Because alpha TIF is an essential virion protein, its function as an inducer can best be evaluated only by mutating the cis-acting site. Earlier we reported on a series of 17 mutations in and around the cis-acting site of a 275-bp alpha 27 promoter fused to a reporter gene and recombined into the viral genome. These recombinant viruses were tested in Vero cells in the presence of cycloheximide, and we demonstrated that mutations in the sequence required for Oct-1 binding abolished transactivation whereas mutations in the alpha TIF-dependent GARAT sequence decreased but did not abolish transactivation. We now report that (i) in limited-passage human embryonic lung cells, alpha gene expression from promoters mutated in the GARAT sequences is often higher and more variable than in Vero cells, (ii) in the absence of cycloheximide, the mutant viruses show less significant impairment of reporter gene expression, (iii) Oct-1 can bind either to the overlapping octamer element or to various TAATGARAT sequences with differing degrees of binding strength and these relative binding levels correlate well with levels of gene expression observed in infected cells, (iv) in the cis-acting site upstream of the alpha 4 gene, no degenerate overlapping Oct-1 sequence exists, and therefore in this instance Oct-1 must be binding directly to the TAATGARAT sequence, (v) extension of the alpha 27 promoter by an additional 1,334 bp results in much higher expression of the reporter gene as a result of additional upstream cis-acting sites, and (vi) obliteration of the most proximal Oct-1 binding element within the 275-bp promoter dramatically reduces gene expression even in the presence of the additional upstream cis-acting sites.

Expression of the herpes simplex virus 1 alpha transinducing factor (VP16) does not induce reactivation of latent virus or prevent the establishment of latency in mice

A feature of the cascade regulation of herpes simplex virus 1 gene expression in productive infection is that the first genes to be expressed, the alpha genes, are transactivated by a structural component of the virion designated as the alpha transinducing factor (alpha TIF). In this study, we have tested the hypothesis that latent infection of sensory neurons results from the failure of alpha TIF, a tegument protein, to be transported from the nerve endings to the nucleus of the sensory neuron. Two viruses were constructed. The first recombinant virus (R6003) contained a second copy of the alpha TIF gene placed under the control of a metallothionein promoter. The second recombinant virus (R6004) is identical to R6003 except for the presence of a stop codon inserted at amino acid 70 of the second alpha TIF gene. The metallothionein promoter inserted into the viral genome was shown to be expressed, and alpha TIF mRNA was detected by in situ hybridization of sections of trigeminal ganglia of mice infected with R6003, both untreated and those given cadmium injections. In all experiments, there were no significant differences in the recovery of latent virus from mice infected with R6003 or R6004, whether injected with cadmium or not. Cadmium administration at the time of infection and at intervals thereafter did not preclude establishment of latency. In another series of experiments, transgenic mice expressing the metallothionein-driven alpha TIF did not differ from nontransgenic siblings with respect to the incidence of latent virus in trigeminal ganglia. We conclude that the absence of alpha TIF cannot alone account for the establishment of latency.

EBNA-2 transactivates a lymphoid-specific enhancer in the BamHI C promoter of Epstein-Barr virus

Among the few Epstein-Barr virus (EBV) genes expressed during latency are the Epstein-Barr nuclear antigens (EBNAs), at least one of which contributes to the ability of the virus to transform B lymphocytes. We have analyzed a promoter located in the BamHI-C fragment of EBV which is responsible for the expression of EBNA-1 in some cell lines. Deletion analysis of a 1.4-kb region 5' of the RNA start site has identified a 700-bp fragment that is required for optimal promoter activity in latently infected B lymphocytes, as shown by promoter constructs linked to the chloramphenicol acetyltransferase reporter gene. This fragment is also able to enhance activity, in an orientation-independent manner, of the simian virus 40 early promoter linked to the chloramphenicol acetyltransferase gene. The enhancer element has some constitutive activity in EBV-negative lymphoid cells, which is increased in the presence of the EBNA-2 gene product. Further deletions have shown that the EBNA-2-responsive region requires a 98-bp region that contains a degenerate octamer-binding motif. In epithelial cells there was no enhancer activity regardless of the presence of EBNA-2. These results demonstrate that BamHI-C promoter activity may be dependent not on an enhancer contained in the ori-P, as was previously assumed, but rather on EBNA-2 transactivation of this more proximal enhancer located in the upstream region of the BamHI C promoter itself.

Role of herpes simplex virus type 1 UL46 and UL47 in alpha TIF-mediated transcriptional induction: characterization of three viral deletion mutants

The transcriptional induction of the alpha or immediate-early gene class of herpes simplex virus type 1 effected by the alpha trans-induction factor (alpha TIF, ICP25, VP16, Vmw65) requires an alpha-specific cis-acting site. Increased transcription does not result from the direct, independent binding of alpha TIF, but rather from an alpha TIF-dependent formation of a protein-DNA complex containing, in addition to alpha TIF, at least one host cell factor. One of the host factors is a POU domain protein which recognizes an octamer element in the alpha-specific consensus. There is evidence that alpha TIF may drive the formation of multiple protein-DNA complexes containing a POU protein and additional host factors. Previously, the gene products of UL46 and UL47 have been implicated in modulating the alpha TIF-dependent transcriptional induction of alpha genes. Our current studies have extended these analyses from a transient-expression system to a series of viral deletion mutants. In these studies we demonstrate that neither UL46- nor UL47-encoded gene product, either separately or in combination, is required for viral growth in cell culture. The absence of UL47 reduces by up to 80% the ability of the virus to induce an alpha-regulated thymidine kinase reporter gene resident in 143TK- cells. Autoradiograms of [35S]methionine pulse-labeled infected cell proteins, separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, show that deleting UL46 and/or UL47 has no discernable effect on the synthesis of alpha TIF or alpha TIF-containing proteins. Subsequent Western immunoblot analysis, with rabbit anti-alpha TIF antibodies made to an alpha TIF-Staphylococcus aureus protein A fusion, demonstrated that the accumulation and steady-state levels of alpha TIF or alpha TIF-containing proteins was indistinguishable from that of the thymidine kinase-negative isogenic parental virus, R delta 305.

A cellular factor binds to the herpes simplex virus type 1 transactivator Vmw65 and is required for Vmw65-dependent protein-DNA complex assembly with Oct-1

The herpes simplex virus transactivator Vmw65 assembles into a multicomponent protein-DNA complex along with the octamer binding protein Oct-1. Using affinity chromatography on columns conjugated with purified Vmw65 fusion protein expressed in Escherichia coli, we demonstrate that a cellular factor, distinct from Oct-1, binds to Vmw65 in the absence of target DNA and is necessary for Vmw65-mediated complex assembly with Oct-1.

Reactivation of latent herpes simplex virus by adenovirus recombinants encoding mutant IE-0 gene products

We have previously shown that adenovirus recombinants expressing functional ICP0 reactivate latent herpes simplex virus type 2 (HSV-2) in an in vitro latency system. This study demonstrated that ICP0, independent of other HSV gene products, is sufficient to reactivate latent HSV-2 in this in vitro system. To assess the effects of defined mutations in the sequence encoding ICP0 (IE-0) on reactivation, seven in-frame insertion and three in-frame deletion mutants were moved into an adenovirus expression vector. Each recombinant directed the synthesis of stable ICP0 of the correct size. The transactivation activity of the mutated sequences in these recombinants was similar to that when they were tested in plasmids. When these recombinants were examined for their ability to reactivate in the in vitro latency system, mutants with dramatic defects in transactivation (Ad-0/125, Ad-0/89, Ad-0/2/7, and Ad-0/88/93) were unable to reactivate latent HSV-2 independent of the multiplicity of infection. An exception to this correlation was the finding that Ad-0/89, which transactivated poorly, was able to reactivate latent virus after prolonged incubation whereas other transactivation-deficient mutants could not. Moreover, the presence of ICP4 did not compensate for the inability of any of the recombinants tested to reactivate HSV-2. These results show that (i) the transactivation domains of ICP0 are also used in reactivation, (ii) the presence of another essential HSV regulatory protein ICP4 does not alter the pattern of reactivation by ICP0, and (iii) mutations in some regions of IE-0 previously shown to affect viral growth and plaque formation did not alter its ability to reactivate in this in vitro system.

A cellular factor binds to the herpes simplex virus type 1 transactivator Vmw65 and is required for Vmw65-dependent protein-DNA complex assembly with Oct-1

The herpes simplex virus transactivator Vmw65 assembles into a multicomponent protein-DNA complex along with the octamer binding protein Oct-1. Using affinity chromatography on columns conjugated with purified Vmw65 fusion protein expressed in Escherichia coli, we demonstrate that a cellular factor, distinct from Oct-1, binds to Vmw65 in the absence of target DNA and is necessary for Vmw65-mediated complex assembly with Oct-1.

Ubiquitous and cell-type-specific protein interactions with human papillomavirus type 16 and type 18 enhancers

We have studied the protein-DNA interactions of human papillomavirus types 16 and 18 constitutive enhancer elements using DNasel footprinting experiments with nuclear extracts from four cervical carcinoma cell lines (C33A, HeLa, SiHa, and CaSki) and one fibroblast cell line (143B). Among nine footprints for the HPV 16 enhancer region, six footprints contain nuclear factor 1 (NF1) binding GCCAA motif. In vitro competition experiments suggest that the same factors are shared by all six of these motifs. Two other sequence motifs have consensus sequences for transcription factor AP1. Another sequence motif, for which uv crosslinking studies reveal interaction with four protein molecules, is a strong positive modulator of HPV 16 enhancer function in vivo and shares 100% homology to a sequence motif, GTTTTAA, in the tissue-specific enhancer of the c-mos oncogene. Footprints on the HPV 18 enhancer show five protected regions with homologies to NF1, AP1 and EFII transcription factor binding motifs. One sequence motif of the HPV 18 enhancer has three repeats of a TTTTA sequence contained within the c-mos sequence motif and interacts with at least four different individual polypeptides, as judged by uv crosslinking experiments.

Mutational analysis of the promoter region of the alpha 27 gene of herpes simplex virus 1 within the context of the viral genome

In herpes simplex virus 1-infected cells, the first set of genes to be expressed (alpha genes) is induced by the alpha gene trans-inducing factor (alpha TIF), a virion structural protein. The cis-acting site in the 5' untranscribed domain of alpha genes was previously reported to be the sequence 5'-GYATGNTAATGARATTCYTTGNGGG noncoding (where Y is a pyrimidine, R is a purine, N is any base), which binds a host protein designated alpha H1 (also termed the octamer binding protein, OTF-1, Oct-1, etc.) and which, together with this and possibly other proteins, forms complexes with alpha TIF. To determine the role of the various components of this cis-acting site and of other sequences shared by the alpha genes, we constructed 17 mutants spanning 110 nucleotides of the promoter domain of the alpha 27 gene and made a series of chimeric genes. Each chimeric gene embodying one set of these mutations was inserted into the viral genome and measurements were made of (i) accumulated mRNA under conditions in which only alpha genes were expressed and (ii) the capacity of the mutated sequence to form complexes containing alpha TIF and alpha H1 proteins. We report that (i) transversions in the "TAAT" sequence abolished both complex formation and induction of the chimeric alpha gene, (ii) mutations in the octamer binding site sequence upstream from TAAT or of the downstream GARAT abolished alpha TIF complex formation and also reduced alpha mRNA accumulation, (iii) mutations in a "CAAT" box also reduced expression of mRNA without affecting the formation of DNA-protein complexes containing alpha TIF, and (iv) mutations in sequences immediately downstream from TAATGARAT and in a pair of GA-rich elements reduced alpha mRNA expression whereas mutations between these elements had no effect on the accumulation of the mRNA. The results are consistent with the conclusion that both the alpha H1 octamer binding site ATGNTAAT and the GARAT sequence play a significant role in the induction of alpha genes. For optimal gene expression, however, additional elements downstream from the GARAT sequence and in other regions of the alpha promoter must be present.

Specific effect of interferon on the herpes simplex virus type 1 transactivation event

Human recombinant gamma interferon and to a lesser extent alpha interferon were shown to inhibit herpes simplex virus type 1 replication in the human cell lines WISH and HEp-2. Dot blot analysis of viral DNA synthesis and viral RNA transcription indicated that the inhibition occurred at an early step in infection. A study of the early events after herpes simplex virus type 1 infection indicated that adsorption, penetration, uncoating, and transport of viral DNA were not affected by interferon. Northern (RNA) blot analysis revealed that both immediate-early and delayed-early gene transcription was inhibited by interferon. Transactivation of the immediate-early responsive element linked to a reporter gene (CAT or tk) was specifically inhibited by both classes of interferon. Our data would indicate that either the transactivating protein VP16 or the complex formed between VP16 and a host protein(s) is attenuated by interferon.

Structural requirements in the herpes simplex virus type 1 transactivator Vmw65 for interaction with the cellular octamer-binding protein and target TAATGARAT sequences

Herpes simplex virus type 1 virion protein Vmw65 forms a complex (TRF.C) with TAATGARAT sequences and the cellular transcription factor oct-1, which has been implicated as an intermediate in the activation of gene expression by Vmw65. To examine structural requirements within Vmw65 for this interaction, we analyzed extracts of transfected cells that express mutant Vmw65 proteins by gel retardation assay and identified two regions in the primary sequence of Vmw65 which are necessary for in vitro assembly of TRF.C. The amino-terminal boundary for complex assembly and trans activation mapped between residues 49 and 75. At the carboxyl terminus, deletion as far as residue 388 did not affect in vitro TRF.C assembly, although trans-activating activity was abolished. Deletion beyond residue 388 rapidly impaired the ability of the protein to participate in the TRF.C complex, such that a truncated mutant of 380 residues was completely inactive. These requirements towards the carboxyl terminus overlap a region of strong local sequence similarity between Vmw65 and terminal protein p3 of bacteriophage phi 29. Although substitution of corresponding p3 residues into Vmw65 failed to produce a functional chimera, site-directed mutagenesis within the region of similarity identified a number of single-point mutant proteins which were completely deficient for TRF.C formation. These mutant proteins were also unable to trans activate expression from immediate-early promoters, despite the integrity of the acidic carboxyl terminus. The extreme sensitivity of both TRF.C formation and trans activation to single-residue substitutions within this region of Vmw65 suggests that it is directly involved in the protein-protein or protein-DNA interactions required for assembly of a transcriptional complex containing oct-1.

A herpes simplex virus type 1 mutant containing a nontransinducing Vmw65 protein establishes latent infection in vivo in the absence of viral replication and reactivates efficiently from explanted trigeminal ganglia

Vmw65, a herpes simplex virus type 1 (HSV-1) tegument protein, in association with cellular proteins, transactivates viral immediate early genes. In order to examine the role of Vmw65 during acute and latent infection in vivo, a mutant virus (in1814), containing a 12-base-pair insertion in the Vmw65 gene, which lacks the transactivating function of Vmw65 (C. I. Ace, T. A. McKee, J. M. Ryan, J. M. Cameron, and C. M. Preston, J. Virol. 63:2260-2269, 1989) was examined in mice. Following corneal inoculation, the parental virus (17+) and the revertant (1814R) replicated effectively in eyes and trigeminal ganglia with 30 to 60% mortality. At either equal PFU or equal particle numbers, in1814 did not replicate in trigeminal ganglia and none of the infected mice died. Although in1814 did not replicate following corneal inoculation, it established latent infection in trigeminal ganglia. HSV-1 in1814 reactivated at explant as efficiently and rapidly as did 17+ and 1814R. Even low amounts of inoculated in1814 (10(2) PFU) were sufficient to establish latent infection in some animals. Since infectious in1814 was not detected at any time in mouse trigeminal ganglia, in1814 provided a unique opportunity to determine how soon after primary infection latency begins. Latent in1814 infection was detected shortly after virus reached the sensory ganglia, between 24 to 48 h postinfection. Thus, though Vmw65 may be required for lytic infection in vivo, it is dispensable for the establishment of and reactivation from latent infection. These data support the hypotheses that the latent and lytic pathways of HSV-1 are distinct and that latency is established soon after infection without a requirement for viral replication. However, the levels of Vmw65 reaching neuronal nuclei may be a critical determinant of whether HSV-1 forms a lytic or latent infection.

Herpes simplex type 1 activation by Epstein-Barr virus nuclear antigen 1

We have investigated the effect of Epstein-Barr virus nuclear antigen 1 (EBNA-1), a nuclear protein encoded by EBV, on herpes simplex virus type 1 (HSV-1) infection either in cells constitutively expressing EBNA-1 or in transient expression assays. Rat-1 cells and rat embryo fibroblasts (REF) immortalized by c-myc or E1A were transfected with a specific EBV DNA fragment coding for EBNA-1. Cloned cell lines which constitutively expressed this antigen were infected with HSV-1. Our results indicate that in EBNA-1-expressing cells, virus growth was higher than in control cells for different virus strains or rodent cell lines. This increase was maximal when cells were infected at low multiplicity, as determined by virus growth, and correlated with the stimulation of viral DNA synthesis. REF + c-myc and Vero cells were cotransfected by an EBNA-1 expression vector driven by Moloney murine leukaemia virus LTR and HSV-1 immediate-early (alpha 0) or early thymidine kinase upstream promoter regulatory regions linked to chloramphenicol acetyltransferase (CAT) coding sequences as effectors. In both cell lines, stimulation of CAT expression by EBNA-1 was observed only with the immediate-early promoter. These results suggest that EBNA-1 can transactivate immediate-early HSV-1 expression.

Binding of the herpes simplex virus major regulatory protein to viral DNA

Infected-cell protein 4 (ICP4), the major regulatory protein specified by herpes simplex virus 1 in infected cells, binds to homologs of the sequence ATCGTCnnnnYCGRC (A sites, where n is any nucleotide, Y is a pyrimidine, and R is a purine) and to unrelated sequences for which no consensus sequence has been derived (B sites). We have examined the binding of ICP4 to each of two A and two B binding sites by using Fab fragments of a monoclonal antibody that is reactive with an epitope located at the N terminus of ICP4 and that decreases the mobility of ICP4-DNA complexes in non-denaturing gels. The results indicate that each type of site binds two monomers of ICP4. Methylation-interference studies on the type B sites mapped the guanines whose methylation interfered with the binding of ICP4. The methylation-interference pattern obtained with one of the B sites was similar to that obtained on an A site but differed from that of the other B site. The ability of ICP4 to bind to DNA fragments containing the binding site appears to be dependent on length and on the proximity of the binding site to the fragment end. Short DNA fragments did not form stable complexes with ICP4 even though they contained all of the purines whose methylation interfered with the binding of the regulatory protein.

The Oct-2 protein binds cooperatively to adjacent octamer sites

Recombinant proteins derived from the cloned human oct-2 gene were used to investigate cooperative binding by Oct-2 to adjacent DNA-binding sites. Oct-2, a B-cell-specific transcription factor, binds tightly to the octamer sequence in immunoglobulin promoters. A second apparently unrelated consensus sequence in heavy chain promoters, the heptamer site, also is recognized by the Oct-2 protein but with 1000-fold lower affinity. Simultaneous occupancy of both the octamer and heptamer sites is favored by cooperative interactions. The heptamer site is probably recognized by the same binding surface in the Oct-2 protein as the octamer site and thus is conserved as a lower-affinity binding site. This permits the immunoglobulin promoter to respond to a much broader range of levels of Oct-2 protein. Substitution of prototype octamer sequences for heptamer sequences yields a probe with two octamer sites spaced by 2 nucleotides, which also binds Oct-2 protein cooperatively. Only the POU domain in the Oct-2 protein is required for this cooperative interaction. Similar protein-protein interactions between bound Oct-2 proteins may promote promoter-enhancer synergism in the heavy chain gene.

Purification of a set of cellular polypeptides that bind to the purine-rich cis-regulatory element of herpes simplex virus immediate early genes

Expression of herpes simplex virus type 1 (HSV1) immediate early (IE) genes is activated by a polypeptide component of the mature virion termed viral protein 16 (VP16). Stimulation of IE expression by VP16 operates via two cis-regulatory sequences: TAATGARAT, and the purine-rich hexanucleotide sequence GCGGAA. VP16 does not bind directly to either of the IE cis-regulatory sequences. Rather, these elements appear to represent binding sites for host cell proteins. Herein, we report the purification of a host cell factor that binds to the GCGGAA motif. We show further that this factor is capable of binding in vitro to an oligomerized form of the hexanucleotide sequence GAAACG, which is common to a variety of virus- and interferon-inducible genes. The GAAACG repeats of interferon- and virus-inducible genes, and the GA-rich repeats of HSV1 IE genes confer similar functional properties when appended to the promoter of a heterologous gene. These observations raise the possibility that HSV1 may activate its IE genes in a manner that exploits one of the components used by mammalian cells to combat virus infection.

The C-terminal 79 amino acids of the herpes simplex virus regulatory protein, Vmw65, efficiently activate transcription in yeast and mammalian cells in chimeric DNA-binding proteins

Activation of herpes simplex virus immediate early gene expression normally requires the formation of a ternary complex between a virus trans-activator, Vmw65, a cellular octamer-binding protein, TRF and the cis-acting target sequence, the TAATGARAT motif. We report that the C-terminal 79 amino acids of Vmw65, which contain a potential acidic amphipathic helix, can activate transcription in both yeast and mammalian cells in the absence of TRF interaction when fused to the DNA-binding domain of the yeast transcription factor, GAL4. Together with our previous report which showed that the recruitment of TRF to the DNA by Vmw65 is insufficient for transcription activation, these results indicate that the octamer binding protein may not be directly involved in transcriptional induction mediated by Vmw65. The TRF-Vmw65 complex may therefore represent a novel class of transcription activator in which the protein domain responsible for sequence-specific DNA binding, present in TRF, and that necessary for induction of transcription, within Vmw65, are located on separate proteins. These results are discussed with reference to combinatorial transcriptional control and the role of octamer-binding proteins in other systems.

Overlapping octamer and TAATGARAT motifs in the VF65-response elements in herpes simplex virus immediate-early promoters represent independent binding sites for cellular nuclear factor III

Expression of the immediate-early (IE) genes of herpes simplex virus (HSV) is specifically stimulated by a 65-kilodalton virion transcription factor (VF65 or VP16) that is introduced as a component of infecting virions. In both the IE175(ICP4) and IE110(ICP0) promoters, this activation requires an upstream cis-acting target response element that contains a single TAATGARAT consensus element. Furthermore, many HSV IE TAATGARAT elements overlap with ATGCTAAT octamer motifs that are similar to the OTF-1-binding sites found in both immunoglobulin and histone H2b genes and to the nuclear factor III (NFIII)-binding site within the adenovirus type 2 origin of DNA replication. Purified HeLa cell NFIII protein proved to form specific DNA-protein complexes with several upstream regions from both the IE110 and IE175 promoters, and this interaction was subject to efficient competition with an adenovirus type 2 DNA fragment containing an intact NFIII-binding site. Surprisingly, the NFIII protein bound to synthetic oligonucleotides containing only the TAATGARAT consensus elements as well as to those containing the ATGCTAAT octamer sequence, although the former exhibited lower affinity and gave complexes with slightly different electrophoretic mobility. The ATGCTAAT oligonucleotide also competed more efficiently than the TAATGARAT sequence itself for binding to a TAATGARAT probe, indicating that the same protein species binds to both sites. The oligonucleotides also formed novel supershifted complexes with lysed virion proteins, but only in the presence of a crude nuclear extract and not with affinity-purified NFIII alone. We conclude that the cellular NFIII protein can recognize both the ATGCTAAT and TAATGARAT elements independently but that only the interaction with TAATGARAT represents an intermediate step in the transcriptional stimulation of IE genes by the HSV virion factor.

Construction and characterization of a herpes simplex virus type 1 mutant unable to transinduce immediate-early gene expression

A herpes simplex virus mutant, in1814, possessing a 12-base-pair insertion in the gene encoding the transinducing factor Vmw65 has been constructed. The insertion abolished the ability of Vmw65 to transinduce immediate-early (IE) gene expression and to form a protein-DNA complex with cell proteins and the IE-specific regulatory element TAATGAGAT. Accumulation of IE RNA 1 and 2 was reduced four- to fivefold in in1814-infected cells, but the level of IE RNA 4 was reduced only by twofold, and IE RNA 3 was unaffected. Mutant in1814 had a high particle/PFU ratio, but many of the particles, although unable to form plaques, were capable of normal participation in the early stages of infection at high multiplicity of infection. The defect of in1814 was overcome partially by transfection of a plasmid encoding the IE protein Vmw110 into cells prior to titration and by prior infection with ultraviolet light-inactivated herpes simplex virus. Mutant in1814 was essentially avirulent when injected into mice. The results demonstrate that transinduction of IE transcription by Vmw65 is important at low multiplicity of infection and in vivo but that at high multiplicity of infection the function is redundant.

Separation of requirements for protein-DNA complex assembly from those for functional activity in the herpes simplex virus regulatory protein Vmw65

A transient expression system was developed which results in efficient synthesis of the regulatory protein Vmw65 of herpes simplex virus type 1 in eucaryotic cells. The gene for Vmw65 was linked to the cytomegalovirus immediate-early (IE) promoter-enhancer region in a plasmid containing the simian virus 40 origin of replication. When transfected into COS cells, Vmw65 was expressed from this vector in 25 to 50% of the cells, with total levels of the protein approaching 20% of those observed in infected cells. Vmw65 expressed in this system is functional for specific DNA-binding complex formation with the host cell octamer-binding protein TRF and for transactivation of IE gene expression. We therefore produced a series of carboxy-terminal truncated forms of Vmw65 to examine the structural requirements of the protein for these activities. Deletion of the acidic carboxy-terminal 56 amino acids had no effect on DNA-binding complex formation but completely abolished the ability to transactivate. Amino acids between residues 434 and 453, a region which exhibits a high negative charge, were critical for IE transactivation. In contrast, the requirements for complex formation are located entirely within the N-terminal 403 amino acids, and our results indicate a requirement for this activity for residues between 316 and 403. Together with our previous work, the results presented here indicate that recruitment of TRF into a specific DNA-binding complex on IE consensus signals is required but not sufficient for functional IE transactivation by Vmw65.

Activation of human papillomavirus type 18 gene expression by herpes simplex virus type 1 viral transactivators and a phorbol ester

Several viral trans-activators and a tumor promoter were examined for the ability to activate human papillomavirus type 18 (HPV-18) gene expression. A plasmid containing the HPV-18 noncoding region placed upstream of the chloramphenicol acetyltransferase reporter gene was cotransfected with different herpes simplex virus type 1 (HSV-1) genes into several cell lines. Both HSV-1 TIF and ICP0 activated HPV-18 expression; however, activation by TIF was observed only in epithelial cells, while ICP0 stimulated expression in a wide variety of cells. The element activated by both TIF and ICP0 was mapped to a 229-base-pair fragment which also contains an HPV-18 epithelial cell-preferred enhancer. The inclusion of a papillomavirus E2 trans-activator with TIF and ICP0 further increased HPV-18 expression. In contrast, the HSV-1 ICP4 and ICP27 genes, as well as the human T-cell lymphotropic virus type I and human immunodeficiency virus type 1 tat genes, were found to have no effect on HPV-18 expression. In transient assays, the addition of the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) also activated HPV-18 expression. The region of HPV-18 activated by TPA was localized to a sequence which is homologous to other TPA-responsive elements.