Transcriptional analysis of the murine cytomegalovirus HindIII-I region: identification of a novel immediate-early gene region.

Cytomegaloviruses likely encode numerous gene products involved in regulating virus-host cell interactions and pathogenesis. We previously identified a region of murine cytomegalovirus (MCMV) within HindIII-J and -I that regulates pathogenesis of the virus [open reading frames (ORFs) M139-M141] or is likely required for MCMV replication (ORFs m142 and m143). As a prerequisite for further studies on the structure and function of this gene region, we mapped the transcripts encoded within MCMV HindIII-I. Probes for ORFs M140 and M141 hybridized to 5.4- and 7.0-kb RNA, respectively, which were transcribed with early kinetics and were 3' coterminal with HindIII-J ORF M139. Probes representing ORFs m142, m143, or m144 hybridized to 3' coterminal transcripts of 1.8, 3.8, and 5.1 kb, respectively. ORFs m142 and m143 were transcribed with immediate-early kinetics but were most abundantly expressed at early times. Probes for the rightmost end of HindIII-I hybridized to a 5. 1-kb early/late RNA corresponding to m144 and to a 1.8-kb early RNA transcribed from m145. All of the major transcripts were polyadenylated and therefore are likely coding. Additional minor transcripts of intermediate sizes were also detected. ORFs M139-m143 showed homology to the betaherpesvirus-specific HCMV US22 gene family. Because deletion of these viral genes results in attenuated or helper-dependent phenotypes, this conserved region of US22 family genes may have a role in virus replication as well as in the pathogenesis of betaherpesviruses in their natural hosts.

Replication of murine cytomegalovirus in differentiated macrophages as a determinant of viral pathogenesis.

Blood monocytes or tissue macrophages play a pivotal role in the pathogenesis of murine cytomegalovirus (MCMV) infection, providing functions beneficial to both the virus and the host. In vitro and in vivo studies have indicated that differentiated macrophages support MCMV replication, are target cells for MCMV infection within tissues, and harbor latent MCMV DNA. However, this cell type presumably initiates early, antiviral immune responses as well. In addressing this paradoxical role of macrophages, we provide evidence that the proficiency of MCMV replication in macrophages positively correlates with virulence in vivo. An MCMV mutant from which the open reading frames M139, M140, and M141 had been deleted (RV10) was defective in its ability to replicate in macrophages in vitro and was highly attenuated for growth in vivo. However, depletion of splenic macrophages significantly enhanced, rather than deterred, replication of both wild-type (WT) virus and RV10 in the spleen. The ability of RV10 to replicate in intact or macrophage-depleted spleens was independent of cytokine production, as this mutant virus was a poor inducer of cytokines compared to WT virus in both intact organs and macrophage-depleted organs. Macrophages were, however, a major contributor to the production of tumor necrosis factor alpha and gamma interferon in response to WT virus infection. Thus, the data indicate that tissue macrophages serve a net protective role and may function as "filters" in protecting other highly permissive cell types from MCMV infection. The magnitude of virus replication in tissue macrophages may dictate the amount of virus accessible to the other cells. Concomitantly, infection of this cell type initiates the production of antiviral immune responses to guarantee efficient clearance of acute MCMV infection.

Mucosal and parenteral vaccination against acute and latent murine cytomegalovirus (MCMV) infection by using an attenuated MCMV mutant.

We used a live attenuated murine cytomegalovirus (MCMV) mutant to analyze mechanisms of vaccination against acute and latent CMV infection. We selected MCMV mutant RV7 as a vaccine candidate since this virus grows well in tissue culture but is profoundly attenuated for growth in normal and severe combined immunodeficient (SCID) mice (V. J. Cavanaugh et al., J. Virol. 70:1365-1374, 1996). BALB/c mice were immunized twice (0 and 14 days) subcutaneously (s.c.) with tissue culture-passaged RV7 and then challenged with salivary gland-passaged wild-type MCMV (sgMCMV) intraperitoneally (i.p.) on day 28. RV7 vaccination protected mice against challenge with 10(5) PFU of sgMCMV, a dose that killed 100% of mock-vaccinated mice. RV7 vaccination reduced MCMV replication 100- to 500-fold in the spleen between 1 and 8 days after challenge. We used the capacity to control replication of MCMV in the spleen 4 days after challenge as a surrogate for protection. Protection was antigen specific and required both live RV7 and antigen-specific lymphocytes. Interestingly, RV7 was effective when administered s.c., i.p., perorally, intranasally, and intragastrically, demonstrating that attenuated CMV applied to mucosal surfaces can elicit protection against parenteral virus challenge. B cells and immunoglobulin G were not essential for RV7-induced immunity since B-cell-deficient mice were effectively vaccinated by RV7. CD8 T cells, but not CD4 T cells, were critical for RV7-induced protection. Depletion of CD8 T cells by passive transfer of monoclonal anti-CD8 (but not anti-CD4) antibody abrogated RV7-mediated protection, and RV7 vaccination was less efficient in CD8 T-cell-deficient mice with a targeted mutation in the beta2-microglobulin gene. Although gamma interferon is important for innate resistance to MCMV, it was not essential for RV7 vaccination since gamma interferon receptor-deficient mice were protected by RV7 vaccination. Establishment of and/or reactivation from latency by sgMCMV was decreased by RV7 vaccination, as measured by diminished reactivation of MCMV from splenic explants. We found no evidence for establishment of splenic latency by RV7 after s.c. vaccination. We conclude that RV7 administered through both systemic and mucosal routes is an effective vaccine against MCMV infection. It may be possible to design human CMV vaccines with similar properties.

Human cytomegalovirus immediate early interaction with host nuclear structures: definition of an immediate transcript environment.

The development of an induced transcript environment was investigated at the supramolecular level through comparative localization of the human cytomegalovirus immediate early (IE) transcripts and specific nuclear domains shortly after infection. Compact aggregates of IE transcripts form only adjacent to nuclear domain 10 (ND10), and the viral protein IE86 accumulates exclusively juxtaposed to the subpopulation of ND10 with transcripts. The stream of transcripts is funneled from ND10 into the spliceosome assembly factor SC35 domain through the accumulation of IE86 protein, which recruits some components of the basal transcription machinery. Concomitantly the IE72 protein binds to ND10 and later disperses them. The domain containing the zinc finger region of IE72 is essential for this dispersal. Positional analysis of proteins IE86 and IE72, IE transcripts, ND10, the spliceosome assembly factor SC35, and basal transcription factors defines spatially and temporally an immediate transcript environment, the basic components of which exist in the cell before viral infection, providing the structural environment for the virus to usurp.

The role of ATF in regulating the human cytomegalovirus DNA polymerase (UL54) promoter during viral infection.

Previous analysis of the human cytomegalovirus (HCMV) DNA polymerase (UL54) early gene promoter demonstrated that transcriptional activation of this gene is dependent upon the interaction of cellular transcription factors with viral transactivators (J. A. Kerry, M. A. Priddy, T. Y. Jervey, C. P. Kohler, T. L. Staley, C. D. Vanson, T. R. Jones, A. C. Iskenderian, D. G. Anders, and R. M. Stenberg, J. Virol. 70:373-382, 1996). A sequence element, IR1, was shown to be the primary regulatory element of this promoter in transient assays. However, assessment of this element in the context of the viral genome revealed IR1-independent activation at late times after infection. To extend these studies, we aim to identify additional sequence elements involved in the activation of the UL54 promoter. Our present studies demonstrate that the level of binding of proteins to the ATF site in the UL54 promoter is enhanced by viral infection. Furthermore this increase is sensitive to treatment with phosphonoacetic acid (PAA), a DNA synthesis inhibitor. These data suggest that the increase in the level of ATF binding activity is regulated, either directly or indirectly, by HCMV late gene expression. By using specific antibodies, we determined that ATF-1 was a major component of the proteins binding to the UL54 ATF site at late times. In addition, we have demonstrated direct binding of recombinant ATF-1 to the UL54 ATF site. To assess the biological significance of these events, a recombinant virus construct was generated that contained the UL54 promoter with a mutation in the ATF site regulating expression of the chloramphenicol acetyltransferase (CAT) reporter gene inserted between open reading frames US9 and US10. Analysis of this virus (RVATFmCAT) revealed that mutation of the ATF site does not alter the kinetics of UL54 promoter activation. However, levels of CAT mRNA and activity were reduced by 5- to 10-fold compared to those of the wild-type promoter at all stages of infection. These findings indicate that ATF-1 can regulate the levels of UL54 promoter activity at both early and late times. Furthermore, these results imply that HCMV can regulate the activity of cellular factors involved in early gene regulation.

Translational regulation of the human cytomegalovirus pp28 (UL99) late gene.

The pp28 (UL99) gene of human cytomegalovirus is expressed as a true late gene, in that DNA synthesis is absolutely required for mRNA expression. Our previous studies demonstrated that pp28 promoter sequences from position -40 to +106 are sufficient for late gene expression in the context of the viral genome (C. P. Kohler, J. A. Kerry, M. Carter, V. P. Muzithras, T. R. Jones, and R. M. Stenberg, J. Virol. 68:6589-6597, 1994). To extend these studies, we have examined the sequences in the downstream leader region of the pp28 gene for their role in late gene expression. Deletion of sequences from position -6 to +46 (deltaSS) results in a threefold increase in gene expression in transient assays. In contrast, deletion of sequences from position +46 to +88 (deltaA) has little effect on gene expression. These results indicate that the sequences from position -6 to +46 may repress gene expression. To further analyze this region, site-directed mutagenesis was performed. Mutation of residues from either position +1 to +6 (SS1) or position +12 to +17 (SS2) duplicated the effect of the deltaSS deletion mutant, indicating that sequences from position +1 to +17 were important for the inhibitory effect. To assess the biological significance of these events, a recombinant virus construct containing the deltaSS mutant promoter regulating expression of the chloramphenicol acetyltransferase (CAT) reporter gene was generated. Analysis of this virus (RV delta SSCAT) revealed that deletion of sequences from position -6 to +46 does not alter the kinetic class of this promoter. However, the ratio of CAT protein to CAT mRNA levels in RV delta SSCAT-infected cells was 8- to 12-fold higher than that observed in the parental RV24/26CAT-infected cells. These results imply that the leader sequences within the pp28 gene can regulate the translation of this late gene.

Murine cytomegalovirus with a deletion of genes spanning HindIII-J and -I displays altered cell and tissue tropism.

Murine cytomegalovirus (MCMV) gene products dispensable for growth in cell culture are likely to have important functions within the infected host, influencing tissue tropism, dissemination, or immunological responses against the virus. To identify such genes, our strategy was to delete large regions of the MCMV genome likely to contain genes nonessential for virus replication in NIH 3T3 cells. Mutant virus RV7 contained a deletion of 7.7 kb spanning portions of MCMV HindIII-J and -I. This virus grew comparably to wild-type (WT) virus in NIH 3T3 fibroblasts, primary embryo fibroblasts, and bone marrow macrophages. However, RV7 failed to replicate in target organs of immunocompetent BALB/c mice and severe combined immunodeficient mice, which are exquisitely sensitive to MCMV infection. This defect in vivo growth may be related to the observation that RV7 grew poorly in the peritoneal macrophage cell line IC-21, which is highly permissive for growth of WT MCMV. Two other mutant viruses with an insertion or smaller deletion in the region common to the RV7 deletion grew comparably to WT virus in the macrophage cell line and replicated in salivary gland tissue. The poor growth of RV7 in IC-21 cells was due to a block in immediate-early gene expression, as levels of RNA from immediate-early gene IE1 were reduced eightfold compared with levels for WT virus in macrophages infected with RV7. Consequently, levels of RNA from early and late genes were also reduced. The lower expression of IE1 in RV7-infected IC-21 macrophages was not due to defective entry of virus into the cells, as equal amounts of viral DNA were present in cells 3 h after infection with RV7 or WT MCMV. These studies demonstrate that deletion of sequences in HindIII-J and -I confer altered cell and tissue tropism.

The human cytomegalovirus major immediate-early gene.

Immediate-early genes function to regulate viral and cellular gene expression during the course of virus replication. The major immediate-early gene region of human cytomegalovirus plays a key role in affecting activation and repression of viral and cellular genes. These proteins intimately associate and/or interact with viral and cellular proteins during this process. Herein, we will discuss the current understanding of this complex gene region.

Multiple regulatory events influence human cytomegalovirus DNA polymerase (UL54) expression during viral infection.

The human cytomegalovirus (HCMV) DNA polymerase gene (UL54; also called pol) is a prototypical early gene in that expression is mandatory for viral DNA replication. Recently, we have identified the major regulatory element in the UL54 promoter responsive to the major immediate early (MIE) proteins (UL122 and UL123) (J.A. Kerry, M.A. Priddy, and R. M. Stenberg, J. Virol. 68:4167-4176, 1994). Mutation of this element, inverted repeat sequence 1 (IR1), abrogates binding of cellular proteins to the UL54 promoter and reduces promoter activity in response to viral proteins in transient-transfection assays. To extend our studies on the UL54 promoter, we aimed to examine the role of IR1 in UL54 regulation throughout the course of infection. These studies show that viral proteins in addition to the MIE proteins can activate the UL54 promoter. Proteins from UL112-113 and IRS1/TRS1, recently identified as essential loci for transient complementation of HCMV oriLyt-dependent DNA replication, were found to function as transactivators of the UL54 promoter in association with MIE proteins. UL112-113 enhanced UL54 promoter activation by MIE proteins three- to fourfold. Constitutive expression of UL112-113 demonstrated that the MIE protein dependence of UL112-113 transactivational activity was not related to activation of cognate promoter sequences, suggesting that UL112-113 proteins function in cooperation with the MIE proteins. Mutation of IR1 was found to abrogate stimulation of the UL54 promoter by UL112-113, suggesting that this element is also involved in UL112-113 stimulatory activity. These results demonstrate that additional viral proteins influence UL54 promoter expression in transient-transfection assays via the IR1 element. To confirm the biological relevance of IR1 in regulating UL54 promoter activity during viral infection, a recombinant virus construct containing the UL54 promoter with a mutated IR1 element regulating expression of the chloramphenicol acetyltransferase (CAT) reporter gene (RVIRmCAT) was generated. Analysis of RVIRmCAT revealed that mutation of IR1 dramatically reduces UL54 promoter activity at early times after infection. However, at late times after infection CAT expression by RVIRmCAT, as assessed by RNA and protein levels, was approximately equivalent to expression by wild-type RVpolCAT. These data demonstrate IR1-independent regulation of the UL54 promoter at late times after infection. Together these results show that multiple regulatory events affect UL54 promoter expression during the course of infection.

Four of eleven loci required for transient complementation of human cytomegalovirus DNA replication cooperate to activate expression of replication genes.

As previously shown, 11 loci are required to complement human cytomegalovirus (HCMV) DNA replication in a transient-transfection assay (G. S. Pari and D. G. Anders, J. Virol. 67:6979-6988, 1993). Six of these loci encode known or candidate replication fork proteins, as judged by sequence and biochemical similarities to herpes simplex virus homologs of known function; three encode known immediate early regulatory proteins (UL36-38, IRS1/TRS1, and the major immediate early region spanning UL122-123); and two encode early, nucleus-localized proteins of unknown functions (UL84 and UL112-113). We speculated that proteins of the latter five loci might cooperate to promote and regulate expression of the six replication fork proteins. To test this hypothesis we made luciferase reporter plasmids for each of the replication fork gene promoters and measured their activation by the candidate effectors, expressed under the control of their respective native promoters, using a transient-cooperativity assay in which the candidate effectors were subtracted individually from a transfection mixture containing all five loci. The combination of UL36-38, UL112-113, IRS1, or TRS1 and the major immediate early region produced as much as 100-fold-higher expression than the major immediate early region alone; omitting any one of these four loci from complementing mixtures produced a significant reduction in expression. In contrast, omitting UL84 had insignificant (less than twofold), promoter-dependent effects on reporter activity, and these data do not implicate UL84 in regulating HCMV early-gene expression. Most of the effector interactions showed significant positive cooperativity, producing synergistic enhancement of expression. Similar responses to these effectors were observed for the each of the promoters controlling expression of replication fork proteins. However, subtracting UL112-113 had little if any effect on expression by the UL112-113 promoter or by the simian virus 40 promoter-enhancer under the same conditions. Several lines of evidence argue that the cooperative interactions observed in our transient-transfection assays are important to viral replication in permissive cells. Therefore, the data suggest a model in which coordinate expression of multiple essential replication proteins during permissive infection is vitally dependent upon the cooperative regulatory interactions of proteins encoded by multiple loci and thus have broad implications for our understanding of HCMV biology.

The human cytomegalovirus UL98 gene transcription unit overlaps with the pp28 true late gene (UL99) and encodes a 58-kilodalton early protein.

A murine monoclonal antibody (I2) reacts strongly with the nucleus of human cytomegalovirus (HCMV)-infected human fibroblasts. Western blot (immunoblot) analysis using I2 demonstrated that a protein with an apparent molecular mass of 58-kDa (E58) was expressed at 5 h after infection, and levels increased through 72 h. Immunoblot screening of an early cDNA expression library resulted in a positive clone which hybridized to the right end of the XbaI C fragment of the HCMV Towne strain. Further analysis demonstrated that the E58-specific clone was homologous to the putative UL98 open reading frame, which has been proposed to encode the viral alkaline exonuclease homolog. RNA analysis demonstrated a 3.0-kb RNA which is expressed at early times after infection, as well as in the absence of viral DNA replication, and which is 3' coterminal with the pp28 (UL99) gene region. Insertion of the UL98 genomic sequence into a eucaryotic expression vector and subsequent Western blot analysis using I2 demonstrated that the expressed protein comigrated with E58 from infected cells. E58 also reacts specifically with a previously described antibody, anti-P2-1, which was proposed to recognize a putative late 58-kDa protein. E58 comigrates with the putative late 58-kDa protein, indicating that these two proteins are likely the same. Analysis of the UL98 promoter revealed a TATATAA sequence located at nucleotide 142525. Insertion of the putative promoter 5' to a reporter gene demonstrated that the UL98 promoter was activated in cotransfection experiments with IE1 and IE2 proteins. These studies demonstrate that UL98 is a bona fide early gene, which is consistent with its probable role as the viral alkaline exonuclease gene.

Multiple independent loci within the human cytomegalovirus unique short region down-regulate expression of major histocompatibility complex class I heavy chains.

Reduction of major histocompatibility complex class I cell surface expression occurs in adenovirus-, herpes simplex virus-, human cytomegalovirus (HCMV)-, and murine cytomegalovirus-infected cell systems. Recently, it was demonstrated that the down-regulation mediated by HCMV infection is posttranslational, as a result of increased turnover of class I heavy chains in the endoplasmic reticulum (M. F. C. Beersma, M. J. E. Bijlmakers, and H. L. Ploegh, J. Immunol. 151:4455-4464, 1993; Y. Yamashita, K. Shimokata, S. Saga, S. Mizuno, T. Tsurumi, and Y. Nishiyama, J. Virol. 68:7933-7943, 1994. To identify HCMV genes involved in class I regulation, we screened our bank of HCMV deletion mutants for this phenotype. A mutant with a 9-kb deletion in the S component of the HCMV genome (including open reading frames IRS1 to US9 and US11) failed to down-regulate class I heavy chains. By examining the effects of smaller deletions within this portion of the HCMV genome, a 7-kb region containing at least nine open reading frames was shown to contain the genes required for reduction in heavy-chain expression. Furthermore, it was determined that at least two independent loci within the 7-kb region were able to cause class I heavy-chain down-regulation. One of these, US11, encodes a 32-kDa glycoprotein which causes down-regulation of class I heavy chains in the absence of other viral gene products. Hence, a specific function associated with a phenotype of the HCMV replicative cycle has been mapped to a dispensable gene region. These loci may be important for evasion of the host's immune response and viral persistence.

Isolation and characterization of a low-abundance splice variant from the human cytomegalovirus major immediate-early gene region.

The major immediate-early (IE) gene region of human cytomegalovirus (HCMV) encodes several proteins as a result of differential RNA splicing events. By expression vector cloning of HCMV IE mRNA, we isolated and characterized a cDNA for a novel splice variant from the major IE gene region. The RNA product is a derivative of the IE55 mRNA and contains an additional splice from nucleotides 170,635 to 170,307 in the IE2 gene region (UL122), resulting in a 1.4-kb mRNA. The predicted open reading frame codes for a 164-amino-acid protein with a calculated molecular mass of 18 kDa (IE18). Mung bean nuclease analysis and PCR were used to characterize expression of IE18 mRNA in HCMV-infected cells. While the 1.4-kb mRNA was detected in infected human fibroblasts in the presence of a protein synthesis inhibitor, it was not detectable during a normal infection. However, the 1.4-kb mRNA was readily detected in infected human monocyte-derived macrophages at IE times. These results suggest that the novel IE18 mRNA exhibits cell type-specific expression indicating differential regulation of the major IE gene region in different permissive cell types.

Cytomegalovirus genes: their structure and function.

During the past several years, studies have indicated that cytomegalovirus (CMV) genes can be grouped into two broad categories; those essential for replication in cell culture and those dispensible for virus replication. The latter group of genes are likely to be important for pathogenesis and host-virus interactions. As the field progresses, the need to utilize and establish biological systems capable of addressing gene function during a natural infection of cells in culture, or in the infected animal, is becoming more apparent. Herein, we describe the current status of some of those systems, what has been learned and where these studies may lead. Specifically, we address studies that assess mechanisms of gene activation and function in biologically relevant systems. These include (i) the identification of genes dispensible for replication in cell culture, (ii) the use of dispensible regions of the CMV genome to manipulate genetic information for assessing gene function and activation, and (iii) the identification of a related group of essential loci important for replication of human CMV (HCMV) DNA and what is presently known of the function of those genes during HCMV infection.

Use of recombinant virus to assess human cytomegalovirus early and late promoters in the context of the viral genome.

We have developed a system to study human cytomegalovirus (HCMV) cis-acting promoter elements within the context of the viral genome. A recombinant HCMV (RV134) containing a marker gene (beta-glucuronidase) was used to insert HCMV promoter-chloramphenicol acetyltransferase gene constructs into the viral genome between open reading frames US9 and US10. Using this system, we have studied the promoters for the early DNA polymerase gene (UL54), the early-late lower matrix phosphoprotein gene (pp65, UL83), and the true late 28-kDa structural phosphoprotein gene (pp28, UL99). Transient-expression assays demonstrated that the pp65 and pp28 promoters are activated earlier and to higher levels than typically observed with the endogenous gene. In contrast, insertion of these promoters into the viral genome resulted in kinetics which mimicked that of the endogenous genes. In addition, we have also tested a variant of the pp28 promoter (d24/26CAT) which is deleted from -609 to -41. This promoter behaved similarly to the wild-type pp28 promoter, indicating that sequences from -40 to +106 are sufficient for conferring true late kinetics. Taken together, these data demonstrate that the viral genome affords a level of regulation on HCMV gene expression that has been previously unrealized. Therefore, these experiments provide a model system for the analysis of cis-acting promoter regulatory elements in the context of the viral genome.

Identification of sequence elements in the human cytomegalovirus DNA polymerase gene promoter required for activation by viral gene products.

To determine the mechanisms involved in the regulation of human cytomegalovirus early gene expression, we have examined the gene that encodes the viral DNA polymerase (UL54, pol). Our previous studies demonstrated that sequences required for activation of the pol promoter by immediate-early proteins are contained within a region from -128 to +20 and that cellular proteins can bind to this activation domain. In this study, we demonstrate by competition analysis that binding of cellular proteins to pol is associated with an 18-bp region containing a single copy of a novel inverted repeat, IR1. Time course analysis indicated that viral infection increased the level of protein binding to IR1, concurrent with the activation of the pol promoter. Mutation of the IR1 element abrogated binding of cellular factors to the pol promoter and reduced by threefold the activation by immediate-early proteins. Similarly, mutation of IR1 rendered the promoter poorly responsive to activation by viral infection. Mutation of additional sequence elements in the pol promoter had little effect, indicating that IR1 plays the major role in pol promoter regulation. These studies demonstrate that the interaction between cellular factors and IR1 is important for the regulation of expression of the polymerase gene by viral proteins.

Human cytomegalovirus IE86 protein interacts with promoter-bound TATA-binding protein via a specific region distinct from the autorepression domain.

The major immediate-early gene of human cytomegalovirus encodes several isoforms of an immediate-early protein which has distinct transcriptional regulatory properties. The IE86 isoform autorepresses the major immediate-early promoter by directly binding the cis repression signal element located between the TATA box and the mRNA cap site. In addition to this activity, IE86 stimulates other viral and cellular promoters. One mechanism by which eukaryotic regulatory proteins are thought to stimulate transcription is by contacting one or more general transcription factors. We show that the IE86 protein physically interacts with the DNA-binding subunit (TATA-binding protein) human transcription factor IID via the TATA-binding protein-contacting domain in the N terminus of IE86. In a mobility shift assay, IE86 was also observed to stabilize the binding of TATA-binding protein to promoter DNA. The domains within IE86 responsible for mediating transactivation and repression functioned independently. These experiments thus demonstrate the elegant ability of human cytomegalovirus to join different protein domains to produce distinct multifunctional proteins.

Site-specific inhibition of RNA polymerase II preinitiation complex assembly by human cytomegalovirus IE86 protein.

The human cytomegalovirus major immediate-early gene encodes several protein isoforms which autoregulate the major immediate-early promoter (MIEP). One of these isoforms, the IE86 protein (UL122, IE2), is a DNA-binding protein that represses the MIEP through its cognate recognition sequence (designated the cis repression signal [crs]) located between the TATA box and the initiation site of transcription. Purified recombinant IE86 protein was shown to repress MIEP transcription in vitro, in a cis-acting mediated pathway, with nuclear extracts from HeLa S3, U373-MG, and primary human foreskin fibroblast cells. Repression of the MIEP by IE86 was shown by two criteria to be dependent on the direct interaction of IE86 with the crs element. Core promoter constructs containing essentially the MIEP TATA box and crs element were also specifically repressed by IE86 but not by a mutant IE86 protein, indicating the general transcription machinery as the target for IE86 repression. Kinetic and template commitment experiments demonstrated that IE86 affects preinitiation complex formation but not the rate of reinitiation. Sarkosyl inhibition experiments further revealed that IE86 was unable to effect repression by either disassembling or preventing the elongation of a preexisting transcription complex. Further, the ability of IE86 to interact with the DNA-binding subunit of TFIID was shown not to be required for repression. These functional protein-DNA and protein-protein interaction experiments demonstrate that IE86 specifically interferes with the assembly of RNA polymerase II preinitiation complexes. The biological significance of these results and the precise mechanism by which IE86 represses transcription are discussed.

Direct interaction of the human cytomegalovirus IE86 protein with the cis repression signal does not preclude TBP from binding to the TATA box.

The human cytomegalovirus major immediate-early gene encodes several protein isoforms which autoregulate the major immediate-early promoter (MIEP). One of these isoforms, the IE86 protein, represses the MIEP through a DNA sequence located between the TATA box and the transcription initiation site, designated the cis repression signal (crs). Through mutational analysis, amino acid domains within IE86 responsible for binding the crs element were located at the C terminus. Mutation of the putative zinc finger domain, which precluded IE86 from binding DNA, converted the protein from a repressor of MIEP transcription into an activator. DNase I protection analysis demonstrated that the IE86 footprint overlapped the sequence protected by the TATA-binding protein (TBP). Investigation of whether IE86 was able to displace TBP from DNA revealed that both proteins could bind DNA simultaneously. However, higher concentrations of IE86 were required to obtain protection of the crs element in the presence of prebound TBP. Similarly, higher concentrations of TBP were required to obtain protection in the presence of prebound IE86. These observations indicate that steric hinderance impairs but does not prevent both proteins from binding DNA synchronously.

An isoform variant of the cytomegalovirus immediate-early auto repressor functions as a transcriptional activator.

The major immediate-early promoter (MIEP) of human cytomegalovirus directs the expression of several differentially spliced and polyadenylated mRNAs. These mRNAs encode nuclear phosphorproteins (IE55, IE72, and IE86), which consist of common and unique amino acid sequences. To date, very little is known of the functional role of the 55-kDa (IE55) protein. Here we present evidence that the IE55 protein is a positive activator of the MIEP. In human fibroblast cells IE55 protein activated the MIEP between 10- and 30-fold. Fusion of IE55 to the GAL4 DNA binding domain resulted in a chimeric protein capable of trans-activating a reporter with GAL4 recognition sequences. These results strongly suggest that IE55 is a bona fide transcriptional activator protein. In addition, the IE55 protein was found not to act synergistically with the IE72 activator protein. The IE55 protein shares the same amino acid sequence as IE86 except for a 154-amino-acid deletion at the C-terminal end of the protein. These proteins were functionally antagonistic; IE55 relieved repression by IE86 and, conversely, IE86 negated IE55 activation. Mutagenesis of the MIEP revealed that the target sequence for activation by IE55 is different from the IE86 autorepressive response element. These experiments suggest that the mechanism of action of the IE55 and IE86 isoforms is distinct. Moreover, from these results it is apparent that the interplay of these factors might be critical in determining the level of HCMV replication in the host.