Sequence requirements for activation of the HIV-1 LTR by human cytomegalovirus

Different effects of the TAR structure on HIV-1 and HIV-2 genomic RNA translation

The 5′-untranslated region (5′-UTR) of the genomic RNA of human immunodeficiency viruses type-1 (HIV-1) and type-2 (HIV-2) is composed of highly structured RNA motifs essential for viral replication that are expected to interfere with Gag and Gag-Pol translation. Here, we have analyzed and compared the properties by which the viral 5′-UTR drives translation from the genomic RNA of both human immunodeficiency viruses. Our results showed that translation from the HIV-2 gRNA was very poor compared to that of HIV-1. This was rather due to the intrinsic structural motifs in their respective 5′-UTR without involvement of any viral protein. Further investigation pointed to a different role of TAR RNA, which was much inhibitory for HIV-2 translation. Altogether, these data highlight important structural and functional differences between these two human pathogens.

Enhancement of enteric adenovirus cultivation by viral transactivator proteins

Human enteric adenoviruses (HAdVs; serotypes 40 and 41) are important waterborne and food-borne pathogens. However, HAdVs are fastidious, are difficult to cultivate, and do not produce a clear cytopathic effect during cell culture within a reasonable time. Thus, we examined whether the viral transactivator proteins cytomegalovirus (CMV) IE1 and hepatitis B virus (HBV) X promoted the multiplication of HAdVs. Additionally, we constructed a new 293 cell line expressing CMV IE1 protein for cultivation assays. We analyzed the nucleic acid sequences of the promoter regions of both E1A and hexon genes, which are considered to be the most important regions for HAdV replication. Expression of either HBV X or CMV IE1 protein significantly increased the promoter activities of E1A and hexon genes of HAdVs by as much as 14-fold during cell cultivation. The promotion of HAdV expression was confirmed by increased levels of both adenoviral DNA and mRNA expression. Finally, the newly developed 293 cell line expressing CMV IE1 protein showed an increase in viral DNA ranging from 574% to 619% compared with the conventional 293 cell line. These results suggest that the newly constructed cell line could be useful for efficient cultivation and research of fastidious HAdVs.

Molecular regulation of MHC class I chain-related protein A expression after HDAC-inhibitor treatment of Jurkat T cells

In this study, we characterize the molecular signal pathways that lead to MHC class I chain-related protein A (MICA) expression after histone deacetylase (HDAC)-inhibitor (HDAC-i) treatment of Jurkat T cells. Chelating calcium with BAPTA-AM or EGTA potently inhibited HDAC- and CMV-mediated MICA/B expression. It was further observed that endoplasmic reticulum calcium stores were depleted after HDAC treatment. NF-kappaB activity can be induced by HDAC treatment. However, nuclear translocation of NF-kappaB p65 was not observed after HDAC treatment of Jurkat T cells and even though we could effectively inhibit p65 expression by siRNA, it did not modify MICA/B expression. To identify important elements in MICA regulation, we made a promoter construct consisting of approximately 3 kb of the proximal MICA promoter in front of GFP. Deletion analysis showed that a germinal center-box containing a putative Sp1 site from position -113 to -93 relative to the mRNA start site was important for HDAC and CMV-induced promoter activity. Sp1 was subsequently shown to be important, as targeted mutation of the Sp1 binding sequence or siRNA mediated down modulation of Sp1-inhibited MICA promoter activity and surface-expression.

Neuropathogenesis of chimeric simian/human immunodeficiency virus infection in pig-tailed and rhesus macaques

We recently reported that a chimeric simian/human immunodeficiency virus (SHIVKU-1) developed in our laboratory caused progressive depletion of CD4+ T lymphocytes and AIDS within 6 months of inoculation into pig-tailed macaques (M. nemestrina). None of the pig-tailed macaques showed productive SHIV infection in the central nervous system (CNS). In this report, we show that by further passage of the pathogenic virus in rhesus macaques [M. mulatta], we have derived a new strain of SHIV (SHIVKU-2) that has caused AIDS and productive CNS infection in 3 of 5 rhesus macaques infected with the virus. Productive replication of SHIV in the CNS was clearly shown by high infectivity titers and p27 protein levels in brain homogenates, and in 2 of the 3 rhesus macaques this was associated with disseminated, nodular, demyelinating lesions, including focal multinucleated giant cell reaction, largely confined to the white matter. These findings were reminiscent of HIV-1 associated neurological disease, and our immunohistochemical and in situ hybridization data indicated that the neuropathological lesions were associated with the presence of SHIV-specific viral antigens and nucleic acid respectively. However, the concomitant reactivation of opportunistic infections in these macaques suggested that such pathogens may have influenced the replication of SHIV in the CNS, or modified the neuropathological sequelae of SHIV infection in the rhesus species, but not in pig-tailed macaques. Our findings in the two species of macaques highlight the complexities of lentiviral neuropathogenesis, the precise mechanisms of which are still elusive.

Promoter region architecture and transcriptional regulation of the genes for the MHC class I-related chain A and B ligands of NKG2D

Ligands of the NKG2D receptor, which activates NK cells and costimulates effector T cells, are inducibly expressed under harmful conditions, such as malignancies and microbial infections. Moreover, aberrant expression in autoimmune disease lesions may contribute to disease progression. Among these ligands are the closely related human MHC class I-related chains (MIC) A and B, which appear to be regulated by cellular stress. Analyses of MIC gene 5'-end flanking regions in epithelial tumor cells defined minimal core promoters that directed near maximum heat shock- or oxidative stress-induced transcriptional activation. Considerably larger fully functional promoters were required for maximum proliferation-associated activation. These activities were dependent on core promoter sequences that included heat shock elements, which inducibly bound heat shock factor 1, TATA-like elements, and constitutively occupied Sp1 and inverted CCAAT box factor sites. By contrast, MIC gene activation by CMV infection was largely independent of these and upstream promoter sequences, and expression of viral immediate early gene (IE1 or IE2) products was sufficient for induction of transcription and surface protein expression. Altogether, these results reveal distinct modes of activation of the genes for the MIC ligands of NKG2D and provide a molecular framework for analyses of gene regulation under different cellular insult conditions.

Experimental confirmation of global murine cytomegalovirus open reading frames by transcriptional detection and partial characterization of newly described gene products

Murine cytomegalovirus (MCMV) and human CMV (HCMV) share many features making the mouse system a potential small-animal model for HCMV. Although the genomic DNA sequence and the predicted open reading frames (ORFs) of MCMV have been determined, experimental evidence that the ORFs are actually transcribed has been lacking. We developed an MCMV global-DNA microarray that includes all previously predicted ORFs and 14 potential ones. A total of 172 ORFs were confirmed to be transcribed, including 7 newly discovered ORFs not previously predicted. No gene products from 10 previously predicted ORFs were detected by either DNA microarray analysis or reverse transcriptase PCR in MCMV-infected mouse fibroblasts, although 2 of those were expressed in a macrophage cell line, suggesting that potential gene products from these open reading frames are silenced in fibroblasts and required in macrophages. Immunohistochemical localization of the six newly described ORF products and three recently identified ones in cells transfected with the respective construct revealed four of the products in the nucleus and five in mitochondria. Analysis of two ORFs using site-directed mutagenesis showed that deletion of one of the mitochondrion-localized gene products led to significantly decreased replication in fibroblasts.

Identification of the functional domains of the essential human cytomegalovirus UL34 proteins

The human cytomegalovirus UL34 gene represses expression of the US3 immune evasion gene and is essential for viral replication in cell culture. Two highly related proteins, an early and a late protein, are synthesized at different times during infection from the UL34 gene. The late protein differs from the early protein only by the omission of 21 amino terminal amino acids. Both UL34 proteins repress expression of the US3 promoter and bind specifically to a DNA element in the US3 gene. We have localized the DNA-binding domain of the UL34 open reading frame to amino acids 22 to 243. Surprisingly, this same region of the UL34 open reading frame was also sufficient for transcriptional repression of US3 expression. The UL34 gene is unusual in encoding proteins that have extensively overlapping DNA-binding and transcriptional regulatory domains.

Downregulation of GFAP, TSP-1, and p53 in human glioblastoma cell line, U373MG, by IE1 protein from human cytomegalovirus

Human cytomegalovirus (HCMV) is a member of the beta-herpesvirus family, which has tropism for glial cells. It was recently reported that HCMV might play important roles in the pathogenesis of malignant glioma. In this study, we investigated the effects of the HCMV IE1 protein on the gene expression profile in the human glioblastoma cell line, U373MG by employing cDNA microarray technology. Using DNA chips containing approximately 1,000 human cDNAs, RNA samples from U373MG cells stably expressing IE1 were compared with those from the control cells lacking IE1 cDNA. Fluorescence intensities of 13 genes were significantly decreased in IE1-expressing cells, while one gene was found to be upregulated. Among these 14 genes, we chose to work further on glial fibrillary acidic protein (GFAP), thrombospondin-1 (TSP-1), and p53, because of their previously known involvement in tumorigenesis. The mRNA levels of all these genes were found to be decreased in IE1-expressing glioblastoma cells by real-time quantitative reverse transcription-polymerase chain reaction (RT-PCR) as well as Northern blot analysis. The decreased expression of these genes was also observed at protein levels as measured by immunocytochemistry or fluorescence-activated cell sorting (FACS) analysis. Our data strongly suggested that HCMV IE1 could modulate the expression of cellular genes that might play important roles in the pathogenesis of glial tumors.

Characterization of the elements and proteins responsible for interferon-stimulated gene induction by human cytomegalovirus

Human cytomegalovirus (HCMV) infection of human fibroblast cells activates a large number of interferon-stimulated genes (ISGs) in a viral envelope-cell membrane fusion-dependent mechanism. In this study, we identified two interferon response elements, the interferon-stimulated response element (ISRE) and the gamma interferon-activated site (GAS), which act as HCMV response sites (VRS). Gel mobility shift assays showed that cellular proteins form specific and identical complexes with ISRE and GAS elements, and the binding of these complexes to ISRE and GAS is stimulated by HCMV infection. Point mutations in the consensus sequences of ISRE and GAS completely abolished their activities in response to HCMV-mediated transactivation, as well as their abilities to interact with HCMV-activated VRS-binding proteins. Interferon regulatory factor 3 does not appear to be present in the VRS-binding complexes or to be involved directly in HCMV-mediated ISG activation. Using ProteinChip technology, four potential proteins were identified, ranging from 20 to 42 kDa, in the VRS-binding complexes. The data suggest that HCMV infection activates VRS-binding proteins, which then bind to the VRS and stimulate ISG expression.

Synergistic induction of intercellular adhesion molecule-1 by the human cytomegalovirus transactivators IE2p86 and pp71 is mediated via an Sp1-binding site

Human cytomegalovirus (HCMV) infection of transplant recipients is frequently associated with allograft vasculopathy and rejection. One potential mechanism is vascular injury from HCMV-triggered, immunologically mediated processes. HCMV infection has been shown to increase the expression of intercellular adhesion molecule-1 (ICAM-1). The objective of this study was to determine the molecular basis of HCMV-enhanced ICAM-1 gene expression. Transient transfection experiments identified the IE2p86 protein as a potent activator of the ICAM-1 promoter. The tegument protein pp71 showed a strong synergistic effect on IE2p86-mediated ICAM-1 promoter activation. Mutagenesis experiments defined a DNA element from -110 to -42 relative to the transcription start site as responsive for IE2p86. Further point mutations within this DNA element identified an Sp1-binding site that was essential for strong synergistic activation by IE2p86 and pp71. To confirm the activation of ICAM-1 gene expression, human fibroblasts (HFF) as well as endothelial cells (HUVEC) were infected with recombinant IE2p86- and pp71-expressing baculoviruses, respectively. In FACS analysis, a synergistic induction of ICAM-1 was detectable when cells were co-infected with the two recombinant baculoviruses. These findings clearly demonstrate that IE2p86 and pp71 are crucial regulatory factors for HCMV-induced ICAM-1 upregulation.

Activation of monocyte cyclooxygenase-2 gene expression by human herpesvirus 6. Role for cyclic AMP-responsive element-binding protein and activator protein-1

Prostaglandin E(2) (PGE(2)) is an arachidonic acid metabolite mainly produced by activated monocytes/macrophages (Mo/Mphi) that display broad immunomodulatory activities. Several viruses capable of infecting Mo/Mphi modulate PGE(2) synthesis in a way that favors the infection processes and the spread of virions. In the present work, we studied the effect of human herpesvirus 6 (HHV-6) infection of Mo/Mphi on PGE(2) synthesis. Our results indicate that HHV-6 induces COX-2 gene expression and PGE(2) synthesis within a few hours of infection. We mapped the different promoter elements associated with COX-2 gene activation by HHV-6 to two cis-acting elements: a cyclic AMP-responsive element and an activator protein-1 element. HHV-6 immediate-early protein 2 was identified as a modulator of COX-2 gene expression in Mo/Mphi. Finally, addition of PGE(2) to HHV-6-infected peripheral blood mononuclear cells cultures was found to increase significantly viral replication. Overall, these results further contribute to the immunomodulatory properties of HHV-6 and highlight a potential role for eicosanoids in the replication process of this virus.

Dual regulatory role of human cytomegalovirus immediate-early protein in IL1B transcription is dependent upon Spi-1/PU.1

Activation of IL1B gene transcription has been shown to play a crucial role in human cytomegalovirus (HCMV) infection. We previously reported that HCMV immediate-early (IE) proteins vigorously transactivate IL1B expression without the need for a normally essential upstream enhancer. This activation appears to depend upon protein-protein tethering between IE2, which provides a transcription activation domain (TAD), and the DNA-binding domain of the transcription factor Spi-1. We now show a distinct mechanism by which IE1 and IE2 mediate both weak Spi-1-independent and vigorous Spi-1-dependent IL1B transcription from the -59 to +12 IL1B core promoter. These results demonstrate that in contrast to non-viral, enhancer-mediated, transactivation of IL1B, the IE mechanism is not absolutely dependent upon Spi-1. However, Spi-1 is required for vigorous transcription. Additionally, we have discovered that IE1, which cooperates with IE2 to transactivate IL1B, has minimal activity in the absence of IE2 and Spi-1. Furthermore, IE1 is a dual-acting factor, which can either activate or repress IL1B, depending on the presence of both IE2 and the Spi-1 TADs. Therefore, the relative expression of IE1 and IE2, which varies during HCMV infection, may provide a molecular mechanism by which IL1B can be repressed, thus, avoiding clearance by the host.

Human Herpesvirus 6 immediate-early 1 protein is a sumoylated nuclear phosphoprotein colocalizing with promyelocytic leukemia protein-associated nuclear bodies

Immediate-early (IE) proteins are the first proteins expressed following viral entry and play a crucial role in the initiation of infection. We report the cloning and characterization of a full-length IE1 transcript and protein (IE1B) from human herpesvirus 6 (HHV-6) variant B. The IE1B transcript consists of five exons (3720 nucleotides), three of which are coding for the IE1 protein. The 1078-amino acid-long IE1B protein is 62% identical and 75% similar to the 941-amino acid IE1 from HHV-6 variant A. IE1B protein can be detected at 4 h post-infection (P.I.), and it is distributed as small intranuclear structures. The maximal number of IE1 bodies ( approximately 10-12/nucleus) is detected at 12 h P.I. after which the IE1 bodies condense into 1-3 larger entities by 24-48 h P.I. During infection the IE1B protein is phosphorylated on serine and threonine residues. IE1B undergoes further post-translational modification with its conjugation to the small ubiquitin-like modifier (SUMO-1) peptide. IE1B colocalizes with SUMO-1 and promyelocytic leukemia nuclear bodies during infection as well as in transfection experiments. Finally, IE1 from variant B is a weaker transactivator than IE1 from variant A, when assayed using heterologous promoters. Overall, the characterization of the HHV-6 IE1B protein presented highlights the similarity and divergence between IE1 from both variants and provides useful information pertaining to the early phase of infection.

Open reading frame UL26 of human cytomegalovirus encodes a novel tegument protein that contains a strong transcriptional activation domain

A selection strategy, the activator trap, was used in order to identify genes of human cytomegalovirus (HCMV) that encode strong transcriptional activation domains in mammalian cells. This approach is based on the isolation of activation domains from a GAL4 fusion library by means of selective plasmid replication, which is mediated in transfected cells by a GAL4-inducible T antigen gene. With this screening strategy, we were able to isolate two types of plasmids encoding transactivating fusion proteins from a library of random HCMV DNA inserts. One plasmid contained the exon 3 of the HCMV IE-1/2 gene region, which has previously been identified as a strong transcriptional activation domain. In the second type of plasmid, the open reading frame (ORF) UL26 of HCMV was fused to the GAL4 DNA-binding domain. By quantitative RNA mapping using S1 nuclease analysis, we were able to classify UL26 as a strong enhancer-type activation domain with no apparent homology to characterized transcriptional activators. Western blot analysis with a specific polyclonal antibody raised against a prokaryotic UL26 fusion protein revealed that two protein isoforms of 21 and 27 kDa are derived from the UL26 ORF in both infected and transfected cells. Both protein isoforms, which arise via alternative usage of two in-frame translational start codons, showed a nuclear localization and could be detected as early as 6 h after infection of primary human fibroblasts. By performing Western blot analysis with purified virions combined with fractionation experiments, we provide evidence that pUL26 is a novel tegument protein of HCMV that is imported during viral infection. Furthermore, we observed transactivation of the HCMV major immediate-early enhancer-promoter by pUL26, whereas several early and late promoters were not affected. Our data suggest that pUL26 is a novel tegument protein of HCMV with a strong transcriptional activation domain that could play an important role during initiation of the viral replicative cycle.

The human cytomegalovirus UL35 gene encodes two proteins with different functions

The human cytomegalovirus (HCMV) virion is a complex structure that contains at least 30 proteins, many of which have been identified. We determined that the HCMV UL35 gene encodes two proteins, including a previously unidentified virion protein. A 22-kDa phosphoprotein (ppUL35(A)) was translated from a 1.2-kb UL35 transcript by 4 h postinfection; a second phosphoprotein of 75 kDa (ppUL35) was translated from a 2.2-kb transcript predominantly late in infection. The 22-kDa protein localized to the nucleus, while the 75-kDa protein localized to the juxtanuclear compartment and was packaged into virion particles. The 22-kDa protein was identical to the COOH-terminal end of the 75-kDa protein but was not found in virions, thus defining the NH(2)-terminal portion of the 75-kDa protein as essential for packaging. Expression of the 22-kDa protein inhibited activation of the major immediate-early promoter by ppUL82 (pp71), suggesting that the UL35 22-kDa protein may modulate expression of the major immediate-early gene.

Efficient and tightly regulated expression systems for the human cytomegalovirus major transactivator protein IE2p86 in permissive cells

The 86-kDa IE2 protein (IE2p86) of human cytomegalovirus is a pleiotropic regulatory polypeptide that is essential for activation of viral early promoters and thus, for the entire viral replication cycle. Moreover, this protein modulates cellular gene expression and contributes to the pathogenic features of HCMV. The full spectrum of IE2p86 mediated effects on cellular gene expression has not been defined yet, since efficient expression systems for this protein in HCMV permissive cells are, so far, limited. Here, we report the establishment of two efficient model systems that allow a tightly regulated expression of IE2p86 in various permissive cell types including primary human fibroblasts, primary endothelial cells and U373MG cells. Firstly, we generated a tetracycline-regulated U373MG cell line, which expresses high levels of IE2p86 upon tetracycline removal from the culture medium. Secondly, a recombinant baculovirus was constructed, which expresses IE2p86 under the control of the HCMV major immediate early enhancer/promoter upon transduction of various cell types. Importantly, IE2p86 was functional in both systems, since strong transactivation of luciferase promoter constructs could be measured. Furthermore, a cell cycle arrest was detectable after infection of primary human fibroblasts with IE2p86-expressing baculoviruses. Both expression systems represent useful tools to fully define the effects of this pleiotropic transactivator on cellular gene expression and to establish screening systems for novel antiviral drugs targeting this critical immediate early protein of HCMV.

Identification of a novel transcriptional repressor encoded by human cytomegalovirus

The expression of human cytomegalovirus (HCMV) genes during viral replication is precisely regulated, with the interactions of both transcriptional activators and repressors determining the level of gene expression. One gene of HCMV, the US3 gene, is transcriptionally repressed early in infection. Repression of US3 expression requires viral infection and protein synthesis and is mediated through a DNA sequence, the transcriptional repressive element. In this report, we identify the protein that represses US3 transcription as the product of the HCMV UL34 open reading frame. The protein encoded by UL34 (pUL34) binds to the US3 transcriptional repressive element in yeast and in vitro. pUL34 localizes to the nucleus and alone is sufficient for repression of US3 expression. The data presented here, along with earlier data (B. J. Biegalke, J. Virol. 72:5457-5463, 1998), suggests that pUL34 binding of the transcriptional repressive element prevents transcription initiation complex formation.

From Bittner to Barr: a viral, diet and hormone breast cancer aetiology hypothesis

It is hypothesized that the human homologue of the mouse mammary tumour virus (HHMMTV) and other viruses, such as human papillomavirus (HPV) and Epstein-Barr virus (EBV), act as cofactors with diet, oestrogens and other hormones in the initiation and promotion of some types of breast cancer in genetically susceptible women. It is further hypothesized that diet influences the risk of breast cancer, through its influence on oestrogen metabolism and that of other hormones, in combination with genetic and infectious agents.

Improved expression of vascular endothelial growth factor by naked DNA in mouse skeletal muscles: implication for gene therapy of ischemic diseases

We have constructed an expression vector, pCK, that is able to drive high levels of gene expression in the skeletal muscles of mice. pCK contains not only the full length immediate-early (IE) promoter of human cytomegalovirus but also its entire 5' untranslated region upstream from the start codon of the IE gene. In addition, pCK contains the kanamycin resistance gene, but lacks nucleotide sequences unnecessary for its function as a gene delivery vector, allowing the plasmid size to be 3.7 kb. pCK produced significantly higher levels of vascular endothelial growth factor 165 both in vitro and in vivo than the control vector, the structure of which is similar to naked DNA vectors employed in previous gene therapy trials. pCK would not only significantly increase the therapeutic effects of naked DNA gene therapy but also dramatically cut down the costs for production and treatment.

High efficiency retroviral vectors that contain no viral coding sequences

Almost all currently available retroviral vectors based on murine leukemia virus (MLV) contain one or more viral coding sequences. Because these sequences are also present in the packaging genome, it has been suggested that homologous recombination may occur between the same nucleotide sequence in the packaging genome and the vector, resulting in the production of replication competent retrovirus (RCR). Up until now, it has been difficult to completely remove viral coding sequences since some were thought to be involved in the optimum function of the retroviral vector. For example, the gag coding sequence present in almost all available retroviral vectors has been believed to be necessary for efficient viral packaging, while the pol coding sequence present in the highly efficient vector MFG has been thought to be involved in achieving the high levels of gene expression. However, we have now developed a series of retroviral vectors that are absent of any retroviral coding sequences but produce even higher levels of gene expression without compromising viral titer. In these vectors, the intron and exon sequences from heterologous cellular or viral genes are present. When compared with the well-known MLV-based vectors, some of these newly developed vectors have been shown to produce significantly higher levels of gene expression for a longer period. In an experimental system that can maximize the production of RCR, our newly constructed vectors produced an absence of RCR. These vectors should prove to be safer than other currently available retroviral vectors containing one or more viral coding sequences.

Artificial recruitment of Sp1 or TBP can replace the role of IE1 in the synergistic transactivation by IE1 and IE2

The IE1 and IE2 proteins of human cytomegalovirus transactivate various viral and cellular promoters in a synergistic manner, but the mechanism of their action has not been well elucidated. Here we have examined the IE1-IE2 synergy by artificial recruitment of either Sp1 or TBP to the promoter. We found that in the presence of Sp1, the synergistic effect of IE1 on IE2-mediated transactivation dramatically decreased. Furthermore, a 117-amino acids glutamine-rich fragment of Sp1, which can interact with dTAF(II)110 and hTAF(II)130, was sufficient to replace the role of IE1 in IE1-IE2 synergism. It was also found that TBP recruitment to the promoter markedly decreased the synergistic effect of IE1 on IE2-mediated transactivation. These results suggested that in the context of the synergism between IE1 and IE2, the function of IE1 might overlap with that of Sp1, for example by recruiting the TFIID complex.

Transactivation activity of the human cytomegalovirus IE2 protein occurs at steps subsequent to TATA box-binding protein recruitment

The IE2 protein of human cytomegalovirus transactivates viral and cellular promoters through a wide variety of cis-elements, but the mechanism of its action has not been well characterized. Here, IE2-Sp1 synergy and IE2-TATA box-binding protein (TBP) interaction are examined by artificial recruitment of either Sp1 or TBP to the promoter. It was found that IE2 could cooperate with DNA-bound Sp1. A 117 amino acid glutamine-rich fragment of Sp1, which can interact with Drosophila TAF(II)110 and human TAF(II)130, was sufficient for the augmentation of IE2-driven transactivation. In binding assays in vitro, IE2 interacted directly with the C-terminal region of Sp1, which contains the zinc finger DNA-binding domain, but not with its transactivation domain, suggesting that synergy between IE2 and the transactivation domain of Sp1 might be mediated by other proteins such as TAF or TBP. It was also found that TBP recruitment to the promoter markedly increased IE2-mediated transactivation. Thus, IE2 acts synergistically with DNA-bound Sp1 and DNA-bound TBP. These results suggest that, in human cytomegalovirus IE2 transactivation, Sp1 functions at an early step such as recruitment of TBP and IE2 acts to accelerate rate-limiting steps after TBP recruitment.

Cytomegalovirus IE2 protein stimulates interleukin 1beta gene transcription via tethering to Spi-1/PU.1

Potent induction of the gene coding for human prointerleukin 1beta (il1b) normally requires a far-upstream inducible enhancer in addition to a minimal promoter located between positions -131 and +12. The transcription factor Spi-1 (also called PU.1) is necessary for expression and binds to the minimal promoter, thus providing an essential transcription activation domain (TAD). In contrast, infection by human cytomegalovirus (HCMV) can strongly activate il1b via the expression of immediate early (IE) viral proteins and eliminates the requirement for the upstream enhancer. Spi-1 has been circumstantially implicated as a host factor in this process. We report here the molecular basis for the direct involvement of Spi-1 in HCMV activation of il1b. Transfection of Spi-1-deficient HeLa cells demonstrated both the requirement of Spi-1 for IE activity and the need for a shorter promoter (-59 to +12) than that required in the absence of IE proteins. Furthermore, in contrast to normal, enhancer-dependent il1b expression, which absolutely requires both the Spi-1 winged helix-turn-helix (wHTH) DNA-binding domain and the majority of the Spi-1 TAD, il1b expression in the presence of IE proteins does not require the Spi-1 TAD, which plays a synergistic role. In addition, we demonstrate that a single IE protein, IE2, is critical for the induction of il1b. Protein-protein interaction experiments revealed that the wing motif within the Spi-1 wHTH domain directly recruits IE2. In turn, IE2 physically associates with the Spi-1 wing and requires the integrity of at least one region of IE2. Functional analysis demonstrates that both this region and a carboxy-terminal acidic TAD are required for IE2 function. Therefore, we propose a protein-tethered transactivation mechanism in which the il1b promoter-bound Spi-1 wHTH tethers IE2, which provides a TAD, resulting in the transactivation of il1b.

Human cytomegalovirus US3 gene expression is regulated by a complex network of positive and negative regulators

One immediate early gene of human cytomegalovirus, the US3 gene, causes retention of major histocompatibility locus class I heavy chain proteins in the endoplasmic reticulum and is postulated to have a role in viral pathogenicity. Expression of the US3 gene is regulated by a number of cis-acting elements. In addition, numerous viral proteins are involved in regulating US3 gene expression. US3 transcription was activated modestly by a virion protein, ppUL82. The immediate early proteins encoded by UL122-123 (IE1 and IE2) further activate US3 expression, with the activation enhanced by expression of pTRS1. Other proteins, the immediate early protein encoded by UL37ex1/UL38 and the early protein, pUL84, inhibited IE1 and IE2 activation of US3 expression. US3 transcription is regulated both positively and negatively by a complex network of viral proteins, the interaction of which contributes to precise regulation of US3 gene expression. The ability of pUL37ex1/UL38 to repress expression of the immediate early US3 gene while activating early gene expression suggests that pUL37ex1/UL38 may function to switch viral gene expression from immediate early to early genes.

Sequences downstream of the RNA initiation site of the HTLV type I long terminal repeat are sufficient for trans-activation by human cytomegalovirus immediate-early proteins

Human T cell leukemia virus type I infection is associated with a low incidence of morbidity in the form of adult T cell leukemia and neurologic disease, suggesting that there are other factors determining the pathogenic outcome of infection. We found that HCMV could infect various human cell lines known to be susceptible to HTLV-I infection, including T cell lines already harboring HTLV-I, and that HCMV infection could highly activate gene expression from the HTLV-I LTR. In addition, the coexpression of IE1 and IE2 genes of HCMV increased transcription from the HTLV-I LTR. The deletion analysis indicated that the entire U3 region is not required, but that the 216-bp region from +101 to +316 is sufficient for activation of the LTR by IE1 and IE2. These results suggest that HCMV IE proteins may affect the level of HTLV-I gene expression in coinfected individuals by interacting with HTLV-I LTR sequences.

Effects of human cytomegalovirus major immediate-early proteins in controlling the cell cycle and inhibiting apoptosis: studies with ts13 cells

The major immediate-early (MIE) gene of human cytomegalovirus (HCMV) encodes several MIE proteins (MIEPs) produced as a result of alternative splicing and polyadenylation of the primary transcript. Previously we demonstrated that the HCMV MIEPs expressed from the entire MIE gene could rescue the temperature-sensitive (ts) transcriptional defect in the ts13 cell line. This defect is caused by a ts mutation in TAFII250, the 250-kDa TATA binding protein-associated factor (TAF). These and other data suggested that the MIEPs perform a TAF-like function in complex with the basal transcription factor TFIID. In addition to the transcriptional defect, the ts mutation in ts13 cells results in a defect in cell cycle progression which ultimately leads to apoptosis. Since all of these defects can be rescued by wild-type TAFII250, we asked whether the MIEPs could rescue the cell cycle defect and/or affect the progression to apoptosis. We have found that the MIEPs, expressed from the entire MIE gene, do not rescue the cell cycle block in ts13 cells grown at the nonpermissive temperature. However, despite the maintenance of the cell cycle block, the ts13 cells which express the MIEPs are resistant to apoptosis. MIEP mutants, which have previously been shown to be defective in rescuing the ts transcriptional defect, maintained the ability to inhibit apoptosis. Hence, the MIEP functions which affect transcription appear to be separable from the functions which inhibit apoptosis. We discuss these data in the light of the HCMV life cycle and the possibility that the MIEPs promote cellular transformation by a "hit-and-run" mechanism.

Cell type-dependent and -independent control of HER-2/neu translation

Overexpression of the HER-2 oncogene occurs in a variety of human tumors, including 25-30% of breast carcinomas, and has been associated with an adverse prognosis. Amplification of the HER-2 gene is frequently detected in tumors, but by itself may not fully account for HER-2 overexpression since transcriptional and post-transcriptional mechanisms also regulate HER-2 protein synthesis. Our studies reveal that the efficiency of HER-2 translation differs between primary and transformed cells. In primary human fibroblasts and human mammary epithelial cells, the HER-2 mRNA is associated with monosome and small polysome fractions. In contrast, in BT474 and MCF-7 human breast cancer cell lines and in COS-7 cells the mRNA co-sedimented with larger polysomes, indicating that it is more efficiently translated in these transformed cells. Northern analysis revealed no detectable mRNA size difference, and nuclease S1 protection and sequence analyses showed no differences between the HER-2 transcript leader in primary cells compared to transformed human cells. The transcript leader in all cell types contains a short upstream open reading frame that is also conserved in other mammalian species. Transient transfection assays revealed that the HER-2 transcript leader repressed downstream translation approximately five-fold in both primary and transformed cells and mutation of the upstream initiation codon alleviated most of the inhibitory effect. These results indicate that HER2 expression is translationally controlled both by a short upstream open reading frame that represses HER-2 translation in a cell type-independent manner, and by a distinct cell type-dependent mechanism that increases translational efficiency of HER-2 in transformed cells.

Characterization of the chicken CTCF genomic locus, and initial study of the cell cycle-regulated promoter of the gene

CTCF is a multifunctional transcription factor encoded by a novel candidate tumor suppressor gene (Filippova, G. N., Lindblom, A., Meinke, L. J., Klenova, E. M., Neiman, P. E., Collins, S. J., Doggett, N. D., and Lobanenkov, V. V. (1998) Genes Chromosomes Cancer 22, 26-36). We characterized genomic organization of the chicken CTCF (chCTCF) gene, and studied the chCTCF promoter. Genomic locus of chCTCF contains a GC-rich untranslated exon separated from seven coding exons by a long intron. The 2-kilobase pair region upstream of the major transcription start site contains a CpG island marked by a "Not-knot" that includes sequence motifs characteristic of a TATA-less promoter of housekeeping genes. When fused upstream of a reporter chloramphenicol acetyltransferase gene, it acts as a strong transcriptional promoter in transient transfection experiments. The minimal 180-base pair chCTCF promoter region that is fully sufficient to confer high level transcriptional activity to the reporter contains high affinity binding element for the transcription factor YY1. This element is strictly conserved in chicken, mouse, and human CTCF genes. Mutations in the core nucleotides of the YY1 element reduce transcriptional activity of the minimal chCTCF promoter, indicating that the conserved YY1-binding sequence is critical for transcriptional regulation of vertebrate CTCF genes. We also noted in the chCTCF promoter several elements previously characterized in cell cycle-regulated genes, including the "cell cycle-dependent element" and "cell cycle gene homology region" motifs shown to be important for S/G2-specific up-regulation of cdc25C, cdc2, cyclin A, and Plk (polo-like kinase) gene promoters. Presence of the cell cycle-dependent element/cell cycle gene homology region element suggested that chCTCF expression may be cell cycle-regulated. We show that both levels of the endogenous chCTCF mRNA, and the activity of the stably transfected chCTCF promoter constructs, increase in S/G2 cells.

Characterization of the transcriptional repressive element of the human cytomegalovirus immediate-early US3 gene

Transcriptional repression is utilized by human cytomegalovirus to regulate expression of the immediate-early US3 gene. Sequences located 3' of the US3 TATA box are required for down regulation of expression. Mutagenesis of US3 sequences identified a 10-nucleotide region that is essential for transcriptional repression. In addition to the 10-nucleotide element, an additional region, which includes the US3 initiator element, was needed to confer repression on a heterologous promoter. Thus, a 19-nucleotide element (-18 to +1 relative to the transcription start site) functioned as a transcriptional repressive element (tre). The tre repressed transcription in a position-dependent but orientation-independent manner. In vivo footprinting experiments demonstrated that transcriptional repression is associated with a decrease in protein interactions with the US3 promoter and surrounding sequences. The data presented here suggest that the association of an as yet unidentified repressor protein with the tre represses transcription by inhibiting assembly of the transcription initiation complex on the US3 promoter.

IE2 protein is insufficient for transcriptional repression of the human cytomegalovirus US3 promoter

Expression of the human cytomegalovirus (HCMV) US3 gene is regulated in part by transcriptional repression mediated through a cis-repressive region located between the TATA box and the transcriptional start site. The US3 cis-repressive element has extensive sequence identity with a similar repressive element in UL122-123 (the major immediate-early gene complex). Repression of UL122-123 is mediated through the interaction of the IE2 protein with cis-repressive sequences. In spite of the similarity of the two repressive elements, IE2 activated rather than repressed transcription from the US3 promoter. Additionally, IE1 or IE1 and IE2 in combination also activated US3 expression. These data demonstrate that regulation of HCMV immediate-early genes is quite complex and involves a number of proteins.

TAF-like functions of human cytomegalovirus immediate-early proteins

The human cytomegalovirus (HCMV) major immediate-early (IE) proteins IEP86 (IE2(579aa)) and IEP72 (IE1(491aa)) can transcriptionally activate a variety of simple promoters containing a TATA element and one upstream transcription factor binding site. In our previous studies, transcriptional activation was shown to correlate with IEP86 binding to both the TATA-box binding protein (TBP) and the transcription factor bound upstream. IEP72 often synergistically affects the activation by IEP86, although it has not previously been shown to directly interact in vitro with IEP86, TBP, or transcription factors (e.g., Sp1 and Tef-1) bound by IEP86. We report biochemical and genetic evidence suggesting that the major IE proteins may perform a function similar to that of the TBP-associated factors (TAFs) which make up TFIID. Consistent with this model, we found that the major IE proteins interact with a number of TAFs. In vitro, IEP86 bound with drosophila TAF(II)110 (dTAF(II)110) and human TAF(II)130 (hTAF(II)130), while IEP72 bound dTAF(II)40, dTAF(II)110, and hTAF(II)130. Regions on major IE proteins which mediate binding have been defined. In addition, our data indicate that both IEP72 and IEP86 can bind simultaneously to hTAF(II)130, suggesting that this TAF may provide bridging interactions between the two proteins for transcriptional activation and synergy. In agreement, a transcriptional activation mutant of IEP72 is unable to participate in bridging. Confirmation that these in vitro interactions were relevant was provided by data showing that both IEP72 and IEP86 copurify with TFIID and coimmunoprecipitate with purified TFIID derived from infected cell nuclei. To further support a TAF-like function of the IE proteins, we have found that the IE proteins expressed from the intact major IE gene, and to a lesser extent IEP86 alone, can rescue the temperature-sensitive (ts) transcriptional defect in TAF(II)250 in the BHK-21 cell line ts13. Analyses of mutations in the major IE region show that IEP86 is essential for rescue and that IEP72 augments its effect, and that mutations which affect TAF interactions are debilitated in rescue. Our data, showing that the IE proteins can bind with TFIID and rescue a ts transcriptional defect in TAF(II)250, support the model that the IE proteins perform a TAF-like function as components of TFIID.

Human cytomegalovirus IE2 86-kilodalton protein binds p53 but does not abrogate G1 checkpoint function

Physical interactions between human cytomegalovirus (HCMV) immediate-early (IE) proteins and key cell cycle regulatory proteins have been suggested as a mechanism whereby this herpesvirus modifies cellular control of proliferation. Observed similarities to interactions of other DNA virus proteins (human papillomavirus type 16 E6 and E7, simian virus 40 large T antigen, and adenovirus type 5 E1A and E1B) with cell cycle modulatory proteins such as p53 and Rb have suggested that HCMV IE proteins may likewise alter the G1-to-S phase transition. The IE2 region gene product IE86 has been shown to specifically bind p53, potentially modifying p53 G1 checkpoint function. To examine this possibility, p53-mediated G1 arrest in the presence of IE86 was assessed. Retroviral constructs were created to facilitate the stable expression of IE86 and IE72, another IE protein implicated in HCMV-mediated alteration of cell cycle progression. Western analysis and immunoprecipitation confirmed IE protein expression and binding of IE86 to p53, respectively. Chloramphenicol acetyltransferase assays examining the ability of IE86 to repress activity from the HCMV major IE promoter or activate the HCMV early promoter for the 2.2-kb class of RNAs demonstrated the functional integrity of the IE86 protein. Induction of DNA damage in normal, uninfected fibroblasts (FB) or FB expressing IE86 by actinomycin D (Act D) resulted in increased p53 levels, a predominance of the hypophosphorylated form of Rb, and increased expression of both p21(CIP1/WAF1) and mdm-2. Fluorescence-activated cell sorting revealed that both uninfected and IE86-expressing FB experienced dramatic G1 arrest following exposure to Act D. The clear demonstration of these p53-dependent responses in the presence of IE86 indicates that binding to this viral protein does not compromise the ability of p53 to elicit growth arrest following DNA damage.

A model system for human cytomegalovirus-mediated modulation of human immunodeficiency virus type 1 long terminal repeat activity in brain cells

Previously, our laboratory showed that human cytomegalovirus (HCMV) activates human immunodeficiency virus type 1 (HIV-1) in brain-derived cells with limited HIV-1 gene expression but inhibits HIV-1 in cells fully permissive for replication of both viruses (F. M. Jault, S. A. Spector, and D. H. Spector, J. Virol. 68:959-973, 1994). To investigate these effects further, we developed a model system that uncouples HIV-1 gene expression from long terminal repeat (LTR) activity. Two monoclonal U373-MG astrocytoma/glioblastoma cell lines (LTRIG and LIGHIVDC) were generated, each containing an integrated copy of an LTR-chloramphenicol acetyltransferase (CAT) construct and the Escherichia coli lacI gene. LIGHIVDC also has an inducible HIV-1 genome controlled by a Rous sarcoma virus promoter with lac operator sequences. Basal LTR-mediated CAT activity is 65-fold higher in LIGHIVDC than in LTRIG, and this activity is further increased (20-fold) following incubation of LIGHIVDC with isopropyl-beta-D-thiogalactopyranoside (IPTG). Tat protein can be detected by immunostaining in LIGHIVDC. However, Rev-mediated transport and subsequent translation of the singly spliced and unspliced HIV-1 mRNAs is inefficient. In the absence of Tat, HCMV stimulated CAT activity approximately 20-fold, and this activation required HCMV gene expression but not viral DNA replication. LTR-directed transcription was unaffected by HCMV infection in LIGHIVDC but was inhibited in these cells when they contained increased Tat levels following IPTG induction. These results support the hypothesis that HCMV can induce the HIV-1 LTR when HIV-1 gene expression is minimal and that a threshold level of HIV-1 gene products is necessary for HCMV to inhibit this promoter.

Detection of HIV-1 infection with a green fluorescent protein reporter system

Several systems for the detection of HIV-1 have been described in which HIV-1-susceptible cells contain a reporter gene (chloramphenicol acetyltransferase, beta-galactosidase, or alkaline phosphatase) under the control of the HIV-1 long terminal repeat (LTR). Upon infection by HIV-1, the expression of the viral tat product increases transcription from the HIV-1 LTR promoter, leading to high-level expression of the reporter gene product. Previously described reporter systems require processing of the cells by lysis, fixation, or other steps following infection to detect the reporter gene product. In the present study, the Aequorea green fluorescent protein S65T variant (GFP-S65T) was used in a reporter system for detecting HIV-1. HeLa-CD4 cells transfected with the plasmid pRH1, which encodes GFP-S65T under the control of the HIV-1 LTR promoter, and either co-transfected with a plasmid encoding the HIV-1 tat product or superinfected with HIV-1, expressed high levels of GFP-S65T, which was readily detected by fluorescence microscopy and fluorescence-activated cell-sorting analysis. The advantages of this system include its simplicity, sensitivity, and ability to detect and sort live HIV-1-infected cells using readily available instruments. The construction of cell lines stably transfected with pRH1 will provide a tool for titering HIV-1 and sorting HIV-1-infected cells.

The human cytomegalovirus IE1-72 protein interacts with the cellular p107 protein and relieves p107-mediated transcriptional repression of an E2F-responsive promoter

The Rb-related p107 protein has been implicated as an important control element in proper cell cycle progression. The p107 protein is thought to restrict cellular proliferation in part through its interaction with the E2F family of transcription factors and is, therefore, a specific target for regulation by several DNA viruses. Here, we demonstrate that p107 protein levels are induced in a biphasic manner in human fibroblasts during productive infection by the human cytomegalovirus (HCMV). Expression patterns of p107 protein levels during HCMV infection of human embryonic lung cells (HELs) demonstrate a sustained induction from early to late times of infection. We also demonstrate that the HCMV immediate-early protein IE1-72 complexes in vivo with the p107 protein and that this interaction can be reconstituted in an in vitro system by using reticulocyte-translated protein. Our data demonstrate that the interaction between p107 and the IE1-72 protein occurs at times of infection that temporally match the second tier of p107 protein induction and the phosphorylation pattern of the IE1-72 protein. Furthermore, we show here that the ability of p107 to transcriptionally repress E2F-responsive promoters can be overcome by expression of the IE1-72 protein. This effect appears to be specific, since the IE1-72 protein is not capable of relieving Rb-mediated repression of an E2F-responsive promoter. Finally, our data demonstrate that HCMV infection can induce cellular proliferation in quiescent cells and that IE1-72 expression alone can, to a degree, drive a similar progression through the cell cycle. These data suggest that IE1-72-mediated transactivation of E2F-responsive promoters through alleviation of p107 transcriptional repression may play a key role in the cell cycle progression stimulated by HCMV infection.

Coinfection of individual leukocytes with human cytomegalovirus and human immunodeficiency virus is a rare event in vivo

Infection with the human cytomegalovirus (HCMV) accelerates disease progression in human immunodeficiency virus 1 (HIV-1)-infected individuals. This has been attributed to the transaction of HIV-1 gene expression by HCMV gene products. For transactivation to be effective in vivo both viruses must be present in the same cell. We therefore examined blood samples from 13 HIV-1-infected patients with HCMV viremia for coinfection of individual leukocytes. In four of the patients lymph nodes were also examined. Multiple samples contained defined numbers (between 10 and 1000) of CD4+ lymphocytes or CD14+ monocytes were sorted by a FACS-based automated cell deposition unit. Samples were then analysed by a multiplex nested polymerase chain reaction, which can detect simultaneously HCMV and HIV DNA. The percentage of infected cells was calculated for each virus using the Poisson distribution. Between 0.43% and 6.2% of the CD4+ lymphocytes were infected with HIV and less than 0.15% with HCMV. The level of infection in CD14+ monocytes was always < or = 0.11% for HIV and ranged between < 0.05% and 0.58% for HCMV. Only seven of 1030 sorted samples from blood were positive for both viruses. In lymphnodes, none of the 144 samples tested were double-positive. This clearly shows that coinfection of individual human leukocytes with HIV and HCMV is a very rare event in vivo. Therefore, direct transactivation of HIV by HCMV in coinfected cells obtained from blood and lymphnodes may not explain the effect of HCMV on the prognosis of HIV-infected individuals.

Human cytomegalovirus immediate-early 2 (IE2) protein can transactivate the human hsp70 promoter by alleviation of Dr1-mediated repression

The immediate-early 1 and 2 (IE1 and IE2, respectively) proteins of human cytomegalovirus are known transcription factors, which regulate the expression of viral and cellular genes. Transcriptional activation by IE2 is dependent on the presence of a TATA motif in target promoters, and IE2 can interact directly with the TATA-binding protein (TBP) component of TFIID. TBP is known to be the target for transcriptional repression by the cellular Dr1 protein, and this factor has been shown to repress expression from the hsp70 promoter in vivo. Since this promoter is up-regulated by IE2, we asked whether the effects of Dr1 can be overcome by IE2. We report here that IE2 can overcome Dr1-mediated repression of the hsp70 promoter in vivo and that IE2 can interact with Dr1 in vivo and in vitro. We also demonstrate a previously unreported activity of Dr1, inhibition of DNA binding by TBP, and show that IE2 is able to overcome this inhibition in vitro, suggesting a mechanism for the TATA dependency of IE2-mediated trans activation.

Cell types involved in replication and distribution of human cytomegalovirus

As the number of patients suffering from severe HCMV infections has steadily increased, there is a growing need to understand the molecular mechanisms by which the virus causes disease. The factors that control infection at one time and the events leading to virus multiplication at another time are only beginning to be understood. The interaction of HCMV with different host cells is one key for elucidating these processes. Through modern techniques, much has been learned about the biology of HCMV infections in culture systems. In addition to endothelial cells, epithelial cells, and smooth muscle cells, fibroblasts are one cell population preferentially infected in solid tissues in vivo. From these sites of multiplication, the virus may be carried by peripheral monocytes and circulating endothelial cells to reach distant sites of the body. This would explain the multiorgan involvement in acute HCMV infection and the modes of viral transmission. From what has been learned mainly from human fibroblast culture systems, future studies will focus on how HCMV regulates the expression of its putative 200 genes in different host cells at different stages of cell differentiation and activation to result in viral latency and pathogenesis.

Human cytomegalovirus upregulates NF-kappa B activity by transactivating the NF-kappa B p105/p50 and p65 promoters

During human cytomegalovirus (HCMV) infection, a series of regulated events take place following virus binding and entry into the cell, including the upregulation of cellular transcription factors, such as NF-kappa B, which play an essential role in the viral life cycle. We show here that NF-kappa B message is induced during HCMV infection and that the induction is biphasic, suggesting an initial induction at immediate-early (IE) times and a second round of induction at early times. This hypothesis is supported by experiments using cyclohexamide, which showed that the first tier of induction was drug insensitive, while the second tier was drug sensitive. We then show that virus binding alone is sufficient to stimulate NF-kappa DNA binding activity, supporting its role in the initial induction of NF-kappa B. To begin to elucidate the mechanism(s) for the second tier of NF-kappa B regulation, we examined promoter constructs from the NF-kappa B subunits (p105/p50 and p65) for responsiveness following HCMV infection. HCMV infection transactivated the p105/p50 and p65 promoters. The viral IE proteins (IE1-72, IE2-55, and IE2-86) are expressed during the time we see NF-kappa B induction, so we examined their role in NF-kappa B induction. The IE1-72, IE2-55, and IE2-86 proteins transactivated the p65 promoter, while only the IE2-55 protein transactivated the p105/p50 promoter. The p105/p50 promoter has NF-kappa B sites; therefore, upregulation could also be caused by an autoregulatory mechanism. The p65 promoter, however, has been demonstrated to contain only Sp1 sites. To investigate the potential role of SP1, we examined nuclear extracts from HCMV-infected cells. Here, we show that there is a biphasic increase in SP1 activity during viral infection and that there is apparently an absolute requirement for SP1 in the transactivation of the p65 promoter. In conclusion, we suggest a model in which the initial induction of NF-kappa B occurs through viral modulation of cellular factors and the sustained levels of NF-kappa B induction are regulated by a combination of cellular and viral factors.

Regulation of human cytomegalovirus US3 gene transcription by a cis-repressive sequence

Regulation of immediate-early gene expression in human cytomegalovirus is subject to complex controls. The major immediate-early (mIE) gene is regulated by both positive and negative regulatory signals, including autoregulation mediated by a cis-repressive sequence. A second immediate-early gene, the US3 gene, is transcribed with kinetic similar to those of the mIE gene. I have identified an element present in the US3 gene located from -1 to -13 (relative to the start site of transcription) that mediates a decrease in US3 transcription. The US3 element resembles the cis-repressive element of the mIE gene in sequence, position, and function. The common theme of negative regulation of immediate-early genes shortly after infection suggests that a decrease in the level of immediate-early proteins may be critical for viral replication.

Translational inhibition by a human cytomegalovirus upstream open reading frame despite inefficient utilization of its AUG codon

The second of three short upstream open reading frames (uORF2) in the transcript leader of the human cytomegalovirus gp48 (gpUL4) virion glycoprotein gene inhibits downstream translation approximately 10-fold. Remarkably, this inhibition depends on the amino acid coding information of uORF2. In the current studies we demonstrate that expression of the cistron downstream from uORF2 depends on ribosomes bypassing the uORF2 AUG codon (AUG2) by a leaky scanning mechanism. Replacing the nucleotides surrounding the wild-type AUG2 codon with those optimal for translation initiation reduces downstream translation approximately 10-fold. Analyses of mutants in which uORF2 either overlaps or is in frame with the downstream reading frame reveal that the initiation frequency at the wild-type AUG2 codon is surprisingly low; rather, the majority of ribosomal subunits bypass the wild-type AUG2 codon because of its suboptimal context. We propose a model to explain this unprecedented example of a paradoxically strong inhibitory effect of an upstream ORF despite inefficient utilization of its initiation codon.

CCAAT box-dependent activation of the TATA-less human DNA polymerase alpha promoter by the human cytomegalovirus 72-kilodalton major immediate-early protein

Human cytomegalovirus (HCMV) immediate-early (IE) proteins are known potent transregulators of viral and cellular gene expression upon HCMV infection. HCMV is known to activate a number of cellular genes intimately associated with the cell cycle and DNA replication by mechanisms involving the viral major IE 86-kDa protein (IE2). We have recently shown that IE2 mediates this activation in a TATA-dependent manner and interacts directly with the TATA-binding protein. However, a number of TATA-less cellular promoters, e.g., DNA polymerase alpha and dihydrofolate reductase, are also activated by HCMV infection. Consequently, we have asked how HCMV mediates this activation. We show that, consistent with its known TATA dependency, IE2 does not activate the DNA polymerase alpha promoter. In contrast, this promoter is strongly activated by the major IE 72-kDa protein (IE1). Whilst deletion of ATF or E2F sites within the DNA polymerase alpha promoter had little effect on IE1-mediated activation, removal of the CCAAT box appeared to abolish high levels of activation by IE1. Consistent with this observation, we also find that IE1 interacts directly with the CCAAT box binding factor CTF1 in vitro and massively augments CTF1-mediated activation of the DNA polymerase alpha promoter in transient transfection assays.

Site-specific binding of the human cytomegalovirus IE2 86-kilodalton protein to an early gene promoter

We have previously demonstrated that the human cytomegalovirus (HCMV) immediate-early region 2 86-kDa protein (the IE2 86 protein) is the major transactivator of the HCMV early promoter for the 2.2-kb class of RNAs (open reading frame UL 112-113). Here we show that specific stimulation of this promoter by IE2 86 in transient-expression assays requires sequences located between nucleotides (nt) -113 and -58 relative to the transcription start site; this is also the major regulatory region for this promoter during HCMV infection. To determine whether IE2 86 can bind to this promoter, a glutathione-S-transferase (GST)-IE2 86 fusion protein was incubated with the 32P-labeled promoter and specific binding was assessed by retention of the protein-DNA complex on glutathione-agarose beads. DNase I footprint analysis was also used to map the sequences involved in the binding. Our results indicate that three regions, located between nt -286 and -257, nt -248 and -218, and nt -148 and -120, bind strongly to the IE2 86 protein and share sequence similarity with the previously identified cis repression signal located near the cap site of the major HCMV IE gene. In addition, there is a weaker binding region between nt -113 and -85, which shares some sequence homology with the cis repression signal element and the strong binding regions of the 2.2-kb RNA promoter but lacks one of the two CG dinucleotides present in all of the high-affinity binding sites. With a set of IE2 86 protein deletion mutants, we also show that the DNA-binding domain spans a large region in the carboxy-terminal half of the protein.

Transcriptional activation by the human cytomegalovirus immediate-early proteins: requirements for simple promoter structures and interactions with multiple components of the transcription complex

We have utilized a number of well-defined, simple, synthetic promoters (upstream factor binding sites and TATA elements) to analyze the activation mechanisms of the human cytomegalovirus immediate-early (IE) proteins. We found that the 86-kDa IE protein (known as IEP86, IE2(559aa), or ppUL122a) can recognize and activate a variety of simple promoters, in agreement with the observation that it is a promiscuous activator. However, in the comparison of otherwise identical promoters IEP86 does have preferences for specific TATA elements (hsp70 > adenovirus E2 > simian virus 40 early) and specific upstream transcription factor binding sites (CAAT > SP1 approximately Tef-1 > ATF; no activation with AP1 or OCT). In contrast, the 72-kDa IE protein (known as IEP72, IE1(491aa), or ppUL123) alone did not significantly activate the simple promoters under our experimental conditions. However, each promoter activated by IEP86 was synergistically affected by the addition of IEP72. In addition, the 55-kDa IE protein (IEP55, a splice variant form of IE2, IE2(425aa), or ppUL122b) repeatedly had a negative effect, downregulating the activation of promoters caused by IEP86 and the synergy of IEP86 and IEP72. We show that the ability of IEP86 to activate many simple promoters correlates not only with its previously described ability to interact with the TATA-binding protein (TBP) (B. A. Furnari, E. Poma, T. F. Kowalik, S.-M. Huong, and E.-S. Huang, J. Virol. 67:4981-4991, 1993; C. Hagemeier, S. Walker, R. Caswell, T. Kouzarides, and J. Sinclair, J. Virol. 66:4452-4456, 1992; R. Jupp, S. Hoffman, R. M. Stenberg, J. A. Nelson, and P. Ghazal, J. Virol. 67:7539-7546, 1993) but also with its ability to interact with the transcription factors which bind to the upstream element of promoters it activated (e.g., SP1 and Tef-1 but not Oct-1). This ability to have multiple interactions with the promoter complex may be crucial for transcriptional activation, since the IE proteins cannot activate promoters having only a TATA element or only an upstream transcription factor binding site. In addition, we show that proteins which bind IEP86 also bind to IEP55. Thus, the negative effect on transcription noted with IEP55 may be the result of competition with IEP86 for interaction with the promoter complex. The synergy caused by IEP72 appears to be mediated by a more indirect mechanism. This is suggested by our observation that IEP72 could not bind to any of the proteins tested (TBP, Tef-1, or Oct-1) or to IEP86.

Identification of binding sites for the 86-kilodalton IE2 protein of human cytomegalovirus within an IE2-responsive viral early promoter

The 86-kDa IE2 protein (IE86) of human cytomegalovirus (HCMV) can act as both an activator and a repressor of gene expression. The mechanisms for both of these functions are not well defined. It has recently been demonstrated that this protein has sequence-specific DNA binding properties: it interacts directly with a target sequence that is located between the TATA box and the cap site of its own promoter. This sequence, termed the CRS (cis repression signal) element, is required for negative autoregulation of the IE1/IE2 enhancer/promoter by IE2. We demonstrate now that binding of this protein to DNA is not confined to this site but occurs also within an early promoter of HCMV that has previously been shown to be strongly IE2 responsive. By DNase I protection analysis using a purified, procaryotically expressed IE2 protein, we could identify three binding sites within the region of -290 to -120 of the UL112 promoter of HCMV. Competition in DNase I protection experiments as well as gel retardation experiments showed that the identified binding sites are specific and have high affinity. Deletion of IE2 binding sites from this promoter reduced the level of transactivation; however, the remaining promoter could still be stimulated about 40-fold. Constructs in which IE2 binding sites were fused directly to the TATA box of the UL112 promoter did not reveal a significant contribution of these sequences to transactivation. However, if an IE2 binding site was reinserted upstream of nucleotide -117 of the UL112 promoter, an increase in transactivation by IE2 was obvious, whereas a mutated sequence could not mediate this effect. This finding suggests that DNA-bound IE2 can contribute to transactivation but seems to require the presence of additional transcription factors. Moreover, a comparison of the detected IE2 binding sites could not detect a strong homology, suggesting that this protein may be able to interact with a broad spectrum of different target sequences.

Cytomegalovirus as a co-factor of disease progression in human immunodeficiency virus type 1 infection

Cytomegalovirus has been suggested as a co-factor of disease progression in patients with human immunodeficiency virus type 1 infection. Cytomegalovirus infection is highly prevalent among populations at risk of human immunodeficiency virus 1 infection, and has been associated with both an increased susceptibility to infection and a more rapid course of the disease towards immunodeficiency. Cytomegalovirus can have a direct immunosuppressive effect (through infection of immune cells) and can enhance the replication of human immunodeficiency virus (through the transactivation of the genic immunodeficiency virus expression, the stimulation of cytokine production, and the increase in Fc receptor expression on target cells). The role of cytomegalovirus as a co-factor of the progression towards immunodeficiency in subjects infected with the human immunodeficiency virus type 1 needs to be elucidated with more extensive clinical studies and the application of new molecular biology techniques.

Structure and transcription of an immediate-early region in the human herpesvirus 6 genome

The unique segment of the human herpesvirus 6 (HHV-6) genome is essentially collinear to the unique long DNA segment of another betaherpesvirus, the human cytomegalovirus (HCMV). However, the HHV-6 genomic section that is analogous in position to the major immediate-early (IE) locus of HCMV does not exhibit recognizable sequence homologies. The respective HHV-6 region of 5.5 kbp is flanked on one side by 25 to 28 incomplete tandem repeats of 105 to 110 bp that contain, with one exception, a single KpnI restriction site (KpnI repeats). About 250 reiterations of the sequence motif CACATA are located on the other end. We identified two open reading frames of 375 and 2,595 nucleotides, respectively, on one strand. Strand-specific Northern blot analyses with RNA harvested from HHV-6 (strain U1102)-infected HSB-2 cells or cord blood lymphocytes revealed two transcripts of about 3.5 and 4.7 kb in the corresponding orientation. Sequence analyses of the respective cDNA clones and primer extension experiments were used to map the mRNAs. The two transcripts are coterminal and multiply spliced and code for the same putative 104.6-kDa protein, but they are initiated from different promoters. Characterization of smaller cDNA clones and Northern blotting with other strand-specific probes showed that singly spliced mRNAs of 1.0 and 1.5 kb are transcribed from the opposite strand; they could code for a 17.2-kDa polypeptide. Blocking experiments with cycloheximide led to the conclusion that only the 3.5-kb mRNA is synthesized in the absence of protein biosynthesis upon infection with cell-free virus. This identifies a single IE gene of HHV-6 at the genomic position corresponding to the major IE region of HCMV, although the coding content and transcriptional regulation are quite different for these two herpesvirus IE regions.

Identification and characterization of a human herpesvirus 6 gene segment capable of transactivating the human immunodeficiency virus type 1 long terminal repeat in an Sp1 binding site-dependent manner

The human immunodeficiency virus type 1 (HIV-1) long terminal repeat (LTR) is transactivated by various extracellular signals and viral cofactors that include human herpesviruses. These transactivators are capable of transactivating the HIV-1 LTR through the transactivation response element, NF-kappa B, or other regulatory binding elements. Human herpesvirus 6 (HHV-6) is a potential cofactor of HIV-1. Here, we report that an HHV-6 gene segment, ZVH14, which can neoplastically transform NIH 3T3 and human keratinocytes, is capable of transactivating HIV-1 LTR chloramphenicol acetyltransferase constructs in an Sp1 binding site-dependent manner. Transactivation increased synergistically in the presence of multiple Sp1 sites and was dramatically reduced by cotransfection with oligomers designed to form triplex structures with HIV-1 LTR Sp1 binding sites. HIV-1 LTR NF-kappa B sites were not essential for ZVH14-mediated transactivation. A putative open reading frame in ZVH14, B115, which may encode a highly basic peptide consisting of 115 amino acid residues, showed transactivation capacity similar to that of ZVH14. This open reading frame also transactivated the HIV-1 LTR in an Sp1 site-dependent fashion in African green monkey kidney cells and human T cells. These data suggest that HHV-6 may stimulate HIV-1 replication via transactivation of Sp1 binding sites present in the HIV-1 promoter.