A cis repression sequence adjacent to the transcription start site of the human cytomegalovirus US3 gene is required to down regulate gene expression at early and late times after infection

Conserved motifs in the invertebrate iridescent virus 6 (IIV6) genome regulate virus transcription

Invertebrate iridescent virus 6 (IIV6) is the type species of the Iridovirus genus in the Betairidovirinae subfamily of the Iridoviridae family. Transcription of the 215 predicted IIV6 genes is temporally regulated, dividing the genes into three kinetic classes: immediate-early (IE), delayed-early (DE), and late (L). So far, the transcriptional class has been determined for a selection of virion protein genes and only for three genes the potential promoter regions have been analyzed in detail. In this study, we investigated the transcriptional class of all IIV6 genes that had not been classified until now. RT-PCR analysis of total RNA isolated from virus-infected insect cells in the presence or absence of protein and DNA synthesis inhibitors, placed 113, 23 and 22 of the newly analyzed viral ORFs into the IE, DE and L gene classes, respectively. Afterwards, in silico analysis was performed to the upstream regions (200 bp) of all viral ORFs using the MEME Suite Software. The AA(A/T)(T/A)TG(A/G)A and (T/A/C)(T/G/C)T(T/A)ATGG motifs were identified in the upstream region of IE and DE genes, respectively. These motifs were validated by luciferase reporter assays as crucial sequences for promoter activity. For the L genes two conserved motifs were identified for all analyzed genes: (T/G)(C/T)(A/C)A(T/G/C)(T/C)T(T/C) and (C/G/T)(G/A/C)(T/A)(T/G) (G/T)(T/C). However, the presence of these two motifs did not influence promoter activity. Conversely, the presence of these two sequences upstream of the reporter decreased its expression. Single nucleotide mutations in the highly conserved nucleotides at the end of the second motif (TTGT) showed that this motif acted as a repressor sequence for late genes in the IIV6 genome. Next, upstream sequences of IIV6 L genes from which we removed this second motif in silico, were re-analyzed for the presence of potential conserved promoter sequences. Two additional motifs were identified in this way for L genes: (T/A)(A/T)(A/T/G)(A/T)(T/C)(A/G)(A/C)(A/C) and (C/G)(T/C)(T/A/C)C(A/T)(A/T)T(T/G) (T/G)(T/G/A). Independent mutations in either motif caused a severe decrease in luciferase expression. Information on temporal classes and upstream regulatory sequences will contribute to our understanding of the transcriptional mechanisms in IIV6.

The 5' Untranslated Region of the Major Immediate Early mRNA Is Necessary for Efficient Human Cytomegalovirus Replication

The human cytomegalovirus (HCMV) immediate early 1 (IE1) and IE2 proteins are critical regulators of virus replication. Both proteins are needed to efficiently establish lytic infection, and nascent expression of IE1 and IE2 is critical for reactivation from latency. The regulation of IE1 and IE2 protein expression is thus a central event in the outcome of HCMV infection. Transcription of the primary transcript encoding both IE1 and IE2 is well studied, but relatively little is known about the posttranscriptional mechanisms that control IE1 and IE2 protein synthesis. The mRNA 5' untranslated region (5' UTR) plays an important role in regulating mRNA translation. Therefore, to better understand the control of IE1 and IE2 mRNA translation, we examined the role of the shared 5' UTR of the IE1 and IE2 mRNAs (MIE 5' UTR) in regulating translation. In a cell-free system, the MIE 5' UTR repressed translation, as predicted based on its length and sequence composition. However, in transfected cells we found that the MIE 5' UTR increased the expression of a reporter gene and enhanced its association with polysomes, demonstrating that the MIE 5' UTR has a positive role in translation control. We also found that the MIE 5' UTR was necessary for efficient IE1 and IE2 translation during infection. Replacing the MIE 5' UTR with an unstructured sequence of the same length decreased IE1 and IE2 protein expression despite similar levels of IE1 and IE2 mRNA and reduced the association of the IE1 and IE2 mRNAs with polysomes. The wild-type MIE 5'-UTR sequence was also necessary for efficient HCMV replication. Together these data identify the shared 5' UTR of the IE1 and IE2 mRNAs as an important regulator of HCMV lytic replication.IMPORTANCE The HCMV IE1 and IE2 proteins are critical regulators of HCMV replication, both during primary infection and during reactivation from viral latency. Thus, defining factors that regulate IE1 and IE2 expression is important for understanding the molecular events controlling the HCMV replicative cycle. Here we identify a positive role for the MIE 5' UTR in mediating the efficient translation of the IE1 and IE2 mRNAs. This result is an important advance for several reasons. To date, most studies of IE1 and IE2 regulation have focused on defining events that regulate IE1 and IE2 transcription. Our work reveals that in addition to the regulation of transcription, IE1 and IE2 are also regulated at the level of translation. Therefore, this study is important in that it identifies an additional layer of regulation controlling IE1 and IE2 expression and thus HCMV pathogenesis. These translational regulatory events could potentially be targeted by novel antiviral therapeutics that limit IE1 and IE2 mRNA translation and thus inhibit lytic replication or prevent HCMV reactivation.

Multiple Transcripts Encode Full-Length Human Cytomegalovirus IE1 and IE2 Proteins during Lytic Infection

Expression of the human cytomegalovirus (HCMV) IE1 and IE2 proteins is critical for the establishment of lytic infection and reactivation from viral latency. Defining the mechanisms controlling IE1 and IE2 expression is therefore important for understanding how HCMV regulates its replicative cycle. Here we identify several novel transcripts encoding full-length IE1 and IE2 proteins during HCMV lytic replication. Two of the alternative major immediate early (MIE) transcripts initiate in the first intron, intron A, of the previously defined MIE transcript, while others extend the 5' untranslated region. Each of the MIE transcripts associates with polyribosomes in infected cells and therefore contributes to IE1 and IE2 protein levels. Surprisingly, deletion of the core promoter region of the major immediate early promoter (MIEP) from a plasmid containing the MIE genomic locus did not completely abrogate IE1 and IE2 expression. Instead, deletion of the MIEP core promoter resulted in increased expression of alternative MIE transcripts, suggesting that the MIEP suppresses the activity of the alternative MIE promoters. While the canonical MIE mRNA was the most abundant transcript at immediate early times, the novel MIE transcripts accumulated to levels equivalent to that of the known MIE transcript later in infection. Using two HCMV recombinants, we found that sequences in intron A of the previously defined MIE transcript are required for efficient IE1 and IE2 expression and viral replication. Together, our results identify new regulatory sequences controlling IE1 and IE2 expression and suggest that multiple transcription units act in concert to regulate IE1 and IE2 expression during lytic infection.

IMPORTANCE

The HCMV IE1 and IE2 proteins are critical regulators of HCMV replication, both during primary infection and reactivation from viral latency. This study expands our understanding of the sequences controlling IE1 and IE2 expression by defining novel transcriptional units controlling the expression of full-length IE1 and IE2 proteins. Our results suggest that alternative promoters may allow for IE1 and IE2 expression when MIEP activity is limiting, as occurs in latently infected cells.

A myeloid progenitor cell line capable of supporting human cytomegalovirus latency and reactivation, resulting in infectious progeny

Human cytomegalovirus (HCMV) is a herpesvirus that establishes a lifelong, latent infection within a host. At times when the immune system is compromised, the virus undergoes a lytic reactivation producing infectious progeny. The identification and understanding of the biological mechanisms underlying HCMV latency and reactivation are not completely defined. To this end, we have developed a tractable in vitro model system to investigate these phases of viral infection using a clonal population of myeloid progenitor cells (Kasumi-3 cells). Infection of these cells results in maintenance of the viral genome with restricted viral RNA expression that is reversed with the addition of the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA, also known as PMA). Additionally, a latent viral transcript (LUNA) is expressed at times where viral lytic transcription is suppressed. Infected Kasumi-3 cells initiate production of infectious virus following TPA treatment, which requires cell-to-cell contact for efficient transfer of virus to other cell types. Importantly, lytically infected fibroblast, endothelial, or epithelial cells can transfer virus to Kasumi-3 cells, which fail to initiate lytic replication until stimulated with TPA. Finally, inflammatory cytokines, in addition to the pharmacological agent TPA, are sufficient for transcription of immediate-early (IE) genes following latent infection. Taken together, our findings argue that the Kasumi-3 cell line is a tractable in vitro model system with which to study HCMV latency and reactivation.

The human cytomegalovirus gene products essential for late viral gene expression assemble into prereplication complexes before viral DNA replication

The regulation of human cytomegalovirus (HCMV) late gene expression by viral proteins is poorly understood, and these viral proteins could be targets for novel antivirals. HCMV open reading frames (ORFs) UL79, -87, and -95 encode proteins with homology to late gene transcription factors of murine gammaherpesvirus 68 ORFs 18, 24, and 34, respectively. To determine whether these HCMV proteins are also essential for late gene transcription of a betaherpesvirus, we mutated HCMV ORFs UL79, -87, and -95. Cells were infected with the recombinant viruses at high and low multiplicities of infection (MOIs). While viral DNA was detected with the recombinant viruses, infectious virus was not detected unless the wild-type viral proteins were expressed in trans. At a high MOI, mutation of ORF UL79, -87, or -95 had no effect on the level of major immediate-early (MIE) gene expression or viral DNA replication, but late viral gene expression from the UL44, -75, and -99 ORFs was not detected. At a low MOI, preexpression of UL79 or -87, but not UL95, in human fibroblast cells negatively affected the level of MIE viral gene expression and viral DNA replication. The products of ORFs UL79, -87, and -95 were expressed as early viral proteins and recruited to prereplication complexes (pre-RCs), along with UL44, before the initiation of viral DNA replication. All three HCMV ORFs are indispensable for late viral gene expression and viral growth. The roles of UL79, -87, and -95 in pre-RCs for late viral gene expression are discussed.

Effect of inducible expressed human cytomegalovirus immediate early 86 protein on cell apoptosis

Human cytomegalovirus is a common human pathogen that can cause life-threatening disease under certain conditions. During infection of host cells, the virus expresses regulatory proteins such as IE72 and IE86 that are important for viral propagation. IE86 plays a critical role in the modulation of viral replication as well as host cell cycle control and apoptosis. In this study, a Tet-On system was used to quantify the effect of IE86 on apoptosis and p53 expression. Our results indicate that IE86 inhibits tumor necrosis factor (TNF)-alpha induced apoptosis and that the anti-apoptotic activity of this viral protein correlates with its expression levels. In addition, IE86 did not alter the mRNA level of p53. The system developed should provide a method for functional analysis of human cytomegalovirus (HCMV) IE86 protein.

Dynamic histone H3 acetylation and methylation at human cytomegalovirus promoters during replication in fibroblasts

Human cytomegalovirus DNA is packaged in virions without histones but associates with histones upon reaching the nucleus of an infected cell. Since transcription is modulated by the interplay of histone modifications, we used chromatin immunoprecipitation to detect acetylation and methylation of histone H3 at viral promoters at different times during the viral replication cycle. Histone H3 at immediate-early promoters is acetylated at the start of infection, while it is initially methylated at early and late promoters. Acetylation at immediate-early promoters is dynamic, with a high level of activating modifications at 3 and 6 h postinfection (hpi), followed by a marked reduction at 12 hpi. All viral promoters, as well as nonpromoter regions, are modified with activating acetylations at 24 to 72 hpi. The transient reduction in histone H3 acetylation at the major immediate-early promoter depends on the cis-repressive sequence to which the UL122-coded IE2 protein binds. A mutant virus lacking this element exhibited decreased IE2 binding at the major immediate-early promoter and failed to show reduced acetylation of histone H3 residing at this promoter at 12 hpi. Our results demonstrate that cytomegalovirus chromatin undergoes dynamic, promoter-specific histone modifications early in the infectious cycle, after which the entire chromosome becomes highly acetylated.

Silencing of episomal transgene expression in liver by plasmid bacterial backbone DNA is independent of CpG methylation

Minicircle DNA vectors devoid of plasmid bacterial backbone, (BB) DNAs, are transcriptionally persistent, whereas their parent plasmid counterparts are silenced in the liver. In this study we establish that circular plasmid BB provided in trans did not silence a transgene expression cassette in vivo, further confirming our previous conclusions that the covalent attachment of the plasmid BB to the expression cassette is required for DNA silencing. Given the high concentration of CpG dinucleotides in the plasmid BB, we investigated the role of DNA methylation on transgene silencing in vivo. The presence or absence of methylation in CpG motifs in routine plasmid BBs had no significant effect on transcriptional silencing. Furthermore, the removal of the CpG motifs from the BB did not ameliorate transcriptional silencing. Transgene silencing was partially inhibited when two tandem copies of the chicken cHS4 insulator at each end of a routine plasmid vector were used. These results are consistent with the idea that the transcriptional repression observed with plasmid DNA vectors in the liver is caused by formation of repressive heterochromatin on the plasmid DNA backbone, which then spreads and inactivates the transgene in cis, and that CpG content or methylation has little or no influence in the process.

Nuts and bolts of human cytomegalovirus lytic DNA replication

HCMV lytic DNA replication is complex and highly regulated. The cis-acting lytic origin of DNA replication (oriLyt) contains multiple repeat motifs that comprise two main functional domains. The first is a bidirectional promoter element that is responsive to UL84 and IE2. The second appears to be an RNA/DNA hybrid region that is a substrate for UL84. UL84 is required for oriLyt-dependent DNA replication along with the six core proteins, UL44 (DNA processivity factor), UL54 (DNA polymerase), UL70 (primase), UL105 (helicase), UL102 (primase-associated factor) and UL57 (single-stranded DNA-binding protein). UL84 is an early protein that shuttles from the nucleus to the cytoplasm, binds RNA, suppresses the transcriptional activation function of IE2, has UTPase activity and is proposed to be a member of the DExH/D box family of proteins. UL84 is a key factor that may act in concert with the other core replication proteins to initiate lytic replication by altering the conformation of an RNA stem loop structure within oriLyt. In addition, new data suggests that UL84 interacts with at least one member of the viral replication proteins and several cellular encoded proteins.

Noncanonical TATA sequence in the UL44 late promoter of human cytomegalovirus is required for the accumulation of late viral transcripts

During productive infection, human cytomegalovirus (HCMV) UL44 transcription initiates at three distinct start sites that are differentially regulated. Two of the start sites, the distal and the proximal, are active at early times, whereas the middle start site is active only at late times after infection. The UL44 early viral gene product is essential for viral DNA synthesis. The UL44 gene product from the late viral promoter affects primarily viral gene expression at late times after infection rather than viral DNA synthesis (H. Isomura, M. F. Stinski, A. Kudoh, S. Nakayama, S. Iwahori, Y. Sato, and T. Tsurumi, J. Virol. 81:6197, 2007). The UL44 early viral promoters have a canonical TATA sequence, "TATAA." In contrast, the UL44 late viral promoter has a noncanonical TATA sequence. Using recombinant viruses, we found that the noncanonical TATA sequence is required for the accumulation of late viral transcripts. The GC boxes that surround the middle TATA element did not affect the kinetics or the start site of UL44 late transcription. Replacement of the distal TATA element with a noncanonical TATA sequence did not affect the kinetics of transcription or the transcription start site, but it did induce an alternative transcript at late times after infection. The data indicate that a noncanonical TATA box is used at late times after HCMV infection.

A cis element between the TATA Box and the transcription start site of the major immediate-early promoter of human cytomegalovirus determines efficiency of viral replication

The promoter of the major immediate-early (MIE) genes of human cytomegalovirus (HCMV), also referred to as the CMV promoter, possesses a cis-acting element positioned downstream of the TATA box between positions -14 and -1 relative to the transcription start site (+1). We determined the role of the cis-acting element in viral replication by comparing recombinant viruses with the cis-acting element replaced with other sequences. Recombinant virus with the simian CMV counterpart replicated efficiently in human foreskin fibroblasts, as well as wild-type virus. In contrast, replacement with the murine CMV counterpart caused inefficient MIE gene transcription, RNA splicing, MIE and early viral gene expression, and viral DNA replication. To determine which nucleotides in the cis-acting element are required for efficient MIE gene transcription and splicing, we constructed mutations within the cis-acting element in the context of a recombinant virus. While mutations in the cis-acting element have only a minor effect on in vitro transcription, the effects on viral replication are major. The nucleotides at -10 and -9 in the cis-acting element relative to the transcription start site (+1) affect efficient MIE gene transcription and splicing at early times after infection. The cis-acting element also acts as a cis-repression sequence when the viral IE86 protein accumulates in the infected cell. We demonstrate that the cis-acting element has an essential role in viral replication.

The late promoter of the human cytomegalovirus viral DNA polymerase processivity factor has an impact on delayed early and late viral gene products but not on viral DNA synthesis

Transcription of the DNA polymerase processivity factor gene (UL44) of human cytomegalovirus initiates at three distinct start sites, which are differentially regulated during productive infection. Two of these start sites, the distal and proximal sites, are active at early times, and the middle start site is active at only late times after infection (F. Leach and E. S. Mocarski, J. Virol. 63:1783-1791, 1989). Compared to the wild type, UL44 gene expression was lower for recombinant viruses with the distal or the middle TATA element mutated. The transcripts initiating from the distal or middle start site facilitated late viral gene expression. The level of viral DNA synthesis was affected by mutation of the distal TATA element. In contrast, mutation of the middle TATA element did not affect the level of viral DNA synthesis, but it did affect significantly the level of late viral gene expression. Recombinant viruses with the distal or middle TATA element mutated grew more slowly than the wild type at both low and high multiplicities of infection. Reduced expression of the UL44 gene from the late middle viral promoter correlated with decreased late viral protein expression and decreased viral growth.

Autorepression of the human cytomegalovirus major immediate-early promoter/enhancer at late times of infection is mediated by the recruitment of chromatin remodeling enzymes by IE86

The human cytomegalovirus major immediate-early protein IE86 is pivotal for coordinated regulation of viral gene expression throughout infection. A relatively promiscuous transactivator of viral early and late gene transcription, IE86 also acts during infection to negatively regulate its own promoter via direct binding to a 14-bp palindromic IE86-binding site, the cis repression sequence (crs), located between the major immediate-early promoter (MIEP) TATA box and the start of transcription. Although such autoregulation does not involve changes in the binding of basal transcription factors to the MIEP in vitro, it does appear to involve selective inhibition of RNA polymerase II recruitment. However, how this occurs is unclear. We show that autorepression by IE86 at late times of infection correlates with changes in chromatin structure around the MIEP during the course of infection and that this is likely to result from physical and functional interactions between IE86 and chromatin remodeling enzymes normally associated with transcriptional repression of cellular promoters. Firstly, we show that IE86-mediated autorepression is inhibited by histone deacetylase inhibitors. We also show that IE86 interacts, in vitro and in vivo, with the histone deacetylase HDAC1 and histone methyltransferases G9a and Suvar(3-9)H1 and that coexpression of these chromatin remodeling enzymes with IE86 increases autorepression of the MIEP. Finally, we show that mutation of the crs in the context of the virus abrogates the transcriptionally repressive chromatin phenotype normally found around the MIEP at late times of infection, suggesting that negative autoregulation by IE86 results, at least in part, from IE86-mediated changes in chromatin structure of the viral MIEP.

Two Sp1/Sp3 binding sites in the major immediate-early proximal enhancer of human cytomegalovirus have a significant role in viral replication

We previously demonstrated that the major immediate early (MIE) proximal enhancer containing one GC box and the TATA box containing promoter are minimal elements required for transcription and viral replication in human fibroblast cells (H. Isomura, T. Tsurumi, M. F. Stinski, J. Virol. 78:12788-12799, 2004). After infection, the level of Sp1 increased while Sp3 remained constant. Here we report that either Sp1 or Sp3 transcription factors bind to the GC boxes located at approximately positions -55 and -75 relative to the transcription start site (+1). Both the Sp1 and Sp3 binding sites have a positive and synergistic effect on the human cytomegalovirus (HCMV) major immediate-early (MIE) promoter. There was little to no change in MIE transcription or viral replication for recombinant viruses with one or the other Sp1 or Sp3 binding site mutated. In contrast, mutation of both the Sp1 and Sp3 binding sites caused inefficient MIE transcription and viral replication. These data indicate that the Sp1 and Sp3 binding sites have a significant role in HCMV replication in human fibroblast cells.

Cellular repressor inhibits human cytomegalovirus transcription from the UL127 promoter

The region of the human cytomegalovirus (HCMV) genome between the UL127 promoter and the major immediate-early (MIE) enhancer is referred to as the unique region. The role of this region during a viral infection is not known. In wild-type HCMV-infected permissive fibroblasts, there is no transcription from the UL127 promoter at any time during productive infection. Our investigators previously reported that the region upstream of the UL127 TATA box repressed expression from the UL127 promoter (C. A. Lundquist et al., J. Virol. 73:9039-9052, 1999). The region was reported to contain functional NF1 DNA binding sites (L. Hennighausen and B. Fleckenstein, EMBO J. 5:1367-1371, 1986). Sequence analysis of this region detected additional consensus binding sites for three transcriptional regulatory proteins, FoxA (HNF-3), suppressor of Hairy wing, and CAAT displacement protein. The cis-acting elements in the unique region prevented activation of the early UL127 promoter by the HCMV MIE proteins. In contrast, deletion of the region permitted very high activation of the UL127 promoter by the viral MIE proteins. Mutation of the NF1 sites had no effect on the basal activity of the promoter. To determine the role of the other sites in the context of the viral genome, recombinant viruses were generated in which each putative repressor site was mutated and the effect on the UL127 promoter was analyzed. Mutation of the putative Fox-like site resulted in a significant increase in expression from the viral early UL127 promoter. Insertion of wild-type Fox-like sites between the HCMV immediate-early (IE) US3 TATA box and the upstream NF-kappaB-responsive enhancer (R2) also significantly decreased gene expression, but mutated Fox-like sites did not. The wild-type Fox-like site inhibits activation of a viral IE enhancer-containing promoter. Cellular protein, which is present in uninfected or infected permissive cell nuclear extracts, binds to the wild-type Fox-like site but not to mutated sites. Reasons for repression of UL127 gene transcription during productive infection are discussed.

Characterisation of transcripts from the human cytomegalovirus genes TRL7, UL20a, UL36, UL65, UL94, US3 and US34

The genome of human cytomegalovirus (HCMV) has been studied extensively in some regions, but not others. In this study, transcripts of the genome were further characterised for open reading frames (ORFs) TRL7, UL36, UL65, UL94, US3 and US34, and for the previously unrecognised ORF, UL20a. Reverse transcription-PCR demonstrated the presence of spliced transcripts from the putative glycoprotein gene, UL20a, at early and late times post-infection. US3 full-length and spliced transcripts, including a previously unidentified transcript (US3ii), were described at immediate early times. Sequencing of the complete ORFs of UL20a and US3 from 21 clinical isolates showed that US3 is well conserved in all isolates (97-100% identity), whereas UL20a shows more variation at the nucleotide level, with 90-100% identity. The limits of transcription, and splice donor and acceptor sequences for UL20a and US3 were conserved in all isolates, indicating likely conservation of mRNA splicing patterns. Sequencing a late cDNA library identified the limits of transcription for ORFs TRL7, UL94 and US34 and transcription from the TRL7 ORF was confirmed by northern blotting. Transcripts were found that were congruent with UL36 and UL65, but these differed in the limits previously predicted for these ORFs. These findings show the variation between predicted and actual transcription and indicate the complex nature of transcription from HCMV ORFs.

The human cytomegalovirus major immediate-early enhancer determines the efficiency of immediate-early gene transcription and viral replication in permissive cells at low multiplicity of infection

To determine the effect of the human cytomegalovirus (CMV) major immediate-early (MIE) enhancer or promoter on the efficiency of viral replication in permissive human cells, we constructed recombinant viruses with their human MIE promoter, enhancer, and promoter plus enhancer replaced with the murine CMV components. After a low multiplicity of infection (MOI) (0.01 PFU/cell), recombinant human CMV with the murine CMV promoter replicated like the wild type but recombinant virus with the murine enhancer replicated less efficiently. Immediate-early (IE) viral protein pIE72 (UL123), early viral protein (UL44), and viral DNA synthesis were significantly decreased. The effect of the human CMV enhancer substitution with the murine CMV enhancer was also demonstrated in different cell types by using recombinant virus with the UL127 promoter, driving the expression of green fluorescent protein (GFP). After an MOI of 1, GFP expression was high with the human CMV enhancer and significantly lower with the murine CMV enhancer. Even though at a high MOI (10 PFU/cell), the murine CMV enhancer was as efficient as the human CMV enhancer for the transcription of IE genes in human foreskin fibroblast cells, at lower MOIs, the murine CMV enhancer was less efficient. Proximal and distal chimeras of the human and murine enhancers also replicated less efficiently at a low MOI and expressed lower levels of GFP from the UL127 promoter. These experiments demonstrate that the entire human CMV enhancer has evolved for the efficient expression of the viral IE and early genes in human cells. Possible functions of the human CMV enhancer and promoter at a low MOI are discussed.

Human cytomegalovirus binding to DC-SIGN is required for dendritic cell infection and target cell trans-infection

Cytomegalovirus (CMV) infection is characterized by host immunosuppression and multiorganic involvement. CMV-infected dendritic cells (DC) were recently shown to display reduced immune functions, but their role in virus dissemination is not clear. In this report, we demonstrated that CMV could be captured by DC through binding on DC-SIGN and subsequently transmitted to permissive cells. Moreover, blocking DC-SIGN by specific antibodies inhibited DC infection by primary CMV isolates and expression of DC-SIGN or its homolog DC-SIGNR rendered susceptible cells permissive to CMV infection. We demonstrated that CMV envelope glycoprotein B is a viral ligand for DC-SIGN and DC-SIGNR. These results provide new insights into the molecular interactions contributing to cell infection by CMV and extend DC-SIGN implication in virus propagation.

Cellular proteins bind to sequence motifs in the R1 element between the HCMV immune evasion genes

The viral US3 and US6 gene products of human cytomegalovirus (CMV) are sequentially expressed at immediate-early and early times after infection, respectively. They downregulate the surface expression of HLA class I molecules. There are two repeat-containing regulatory regions between the US3 promoter and the US6 transcription unit designated R1 and R2. R2 contains repetitions of the NF-kappa B responsive element and enhances the immediate-early expression of the US3 gene. R1 contains 19 repetitions of a 5'-TRTCG-3' pentanucleotide arranged as everted repeats, inverted repeats, and variably spaced single pentanucleotides. In the context of the viral genome, R1 also enhances immediate-early US3 gene expression by an unknown mechanism (G. C. Bullock, et al., 2001, Virology 288, 164-174). We report a sequence motif within the R1 element that binds a human cell nuclear protein which is antigenically related to the Drosophila boundary element-associated factor (BEAF). The potential role of a 35-kDa cellular protein that binds to sequence motifs within the R1 element in regulating the expression of the CMV US3 immune evasion gene is discussed.

Effect of the R1 element on expression of the US3 and US6 immune evasion genes of human cytomegalovirus

Human cytomegalovirus (HCMV) has several gene products that are important for escape from immune surveillance. These viral gene products downregulate the expression of HLA molecules on the cell surface. The viral US3 and US6 gene products are expressed at immediate-early and early times after infection, respectively. There are two regulatory regions between the US3 and the US6 transcription units. The first region is an NF-kappaB responsive enhancer that promotes the immediate-early expression of the US3 gene and is designated the R2 enhancer. Upstream of the R2 enhancer is a region designated the R1 element that in transient transfection assays behaves as a silencer by repressing the effect of the enhancer on downstream gene expression (A. R. Thrower et al., J. Virol. 1996, 70, 91; Y.-J. Chan et al., J. Virol. 1996, 70, 5312). We constructed recombinant viruses with wild-type or mutated R1 elements. The expression of the US3 gene at 6 h after infection and the US6 gene at 24 h was higher when the R1 element was present. The R1 element in the context of the viral genome is not a silencer of US3 or US6 gene expression. The R1 element has multiple effects on the US3 and US6 RNAs. It enhances the level of US3 and US6 mRNA; it determines the 3'-end cleavage and polyadenylation of US6 RNA, and it stabilizes read-through viral RNAs. The potential mechanisms of R1 enhancement of US3 and US6 gene expression are discussed.

Quantitative competitive NASBA for measuring mRNA expression levels of the immediate early 1, late pp67, and immune evasion genes US3, US6 and US11 in cells infected with human cytomegalovirus

Different cell types were infected with human cytomegalovirus (HCMV) and RNA expression dynamics were analyzed by quantitative NASBA assays for IE1 (UL123), pp67 (UL65) and the immune evasion genes (US3, US6 and US11). The quantitative NASBA assays gave reproducible quantification in the range of 10(3)-10(6) RNA copies for IE1 and pp67 RNA, from 3x10(3) to 1x10(6) RNA copies for US6 and US11 RNA, and from 1x10(4) to 1x10(6) RNA copies for US3 RNA. SMC, HAEC and HUVEC cells infected with an, in endothelial cells, propagated HCMV strain (VHL/E) showed similar RNA expression dynamics for the analyzed genes. Expression of all genes studied was observed within the first 4 h post-infection. The first gene for which expression could be detected was IE1, followed by US3, US11, pp67 and US6. Fibroblasts infected with HCMV strain AD169 showed a different RNA expression pattern for US3. Translation of the mRNA studied was demonstrated by detection of the proteins 48 h post-infection by immunofluorescence.

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.

Human cytomegalovirus chemokine receptor gene US28 is transcribed in latently infected THP-1 monocytes

The human cytomegalovirus (HCMV) US28 gene product, pUS28, is a G protein-coupled receptor that interacts with both CC and CX(3)C chemokines. To date, the role of pUS28 in immune evasion and cell migration has been studied only in cell types that can establish productive HCMV infection. We show that HCMV can latently infect THP-1 monocytes and that during latency US28 is transcribed. We also show that the transcription is sustained during differentiation of the THP-1 monocytes. Since cells expressing pUS28 were previously shown to adhere to immobilized CX(3)C chemokines (C. A. Haskell, M. D. Cleary, and I. F. Charo, J. Biol. Chem. 275:34183-34189, 2000), we hypothesize that latently infected circulating monocytes express pUS28, thereby enabling adhesion of these cells to CX(3)C-exposing endothelium. Consequently, the US28-encoded chemokine receptor may play an important role in dissemination of latent HCMV.

Activation of transcription of the human cytomegalovirus early UL4 promoter by the Ets transcription factor binding element

The human cytomegalovirus (HCMV) early UL4 promoter has served as a useful model for studying the activation of early viral gene expression. Previous transient-transfection experiments detected cis-acting elements (the NF-Y site and site 2) upstream of the transcriptional start site (L. Huang and M. F. Stinski, J. Virol. 69:7612-7621, 1995). The roles of two of these sites, the NF-Y site and site 2, in the context of the viral genome were investigated further by comparing mRNA levels from the early UL4 promoter in human foreskin fibroblasts infected by recombinant viruses with either wild-type or mutant cis-acting elements. Steady-state mRNA levels from the UL4 promoter with a mutation in the NF-Y site were comparable to that of wild type. A mutation in an Elk-1 site plus putative IE86 protein binding sites decreased the steady-state mRNA levels compared to the wild type at early times after infection. Electrophoretic mobility shift assays and antibody supershifts detected the binding of cellular transcription factor Elk-1 to site 2 DNA with infected nuclear extracts but not with mock-infected nuclear extracts. The role of cellular transcription factors activated by the mitogen activated protein kinase/extracellular signal-regulated kinase pathway in activating transcription from early viral promoters is discussed.

A strong negative transcriptional regulatory region between the human cytomegalovirus UL127 gene and the major immediate-early enhancer

The region of the human cytomegalovirus (CMV) genome between the UL127 open reading frame and the major immediate-early (MIE) enhancer is referred to as the unique region. DNase I protection analysis with human cell nuclear extracts demonstrated multiple protein binding sites in this region of the viral genome (P. Ghazal, H. Lubon, C. Reynolds-Kohler, L. Hennighausen, and J. A. Nelson, Virology 174:18-25, 1990). However, the function of this region in the context of the viral genome is not known. In wild-type human CMV-infected human fibroblasts, cells permissive for viral replication, there is little to no transcription from UL127. We determined that the unique region prevented transcription from the UL127 promoter but had no effect on the divergent MIE promoter. In transient-transfection assays, the basal level of expression from the UL127 promoter increased significantly when the wild-type unique sequences were mutated. In recombinant viruses with similar mutations in the unique region, expression from the UL127 promoter occurred only after de novo viral protein synthesis, typical of an early viral promoter. A 111-bp deletion-substitution of the unique sequence caused approximately a 20-fold increase in the steady-state level of RNA from the UL127 promoter and a 245-fold increase in the expression of a downstream indicator gene. This viral negative regulatory region was also mutated at approximately 50-bp regions proximal and distal to the UL127 promoter. Although some repressive effects were detected in the distal region, mutations of the region proximal to the UL127 promoter had the most significant effects on transcription. Within the proximal and distal regions, there are potential cis sites for known eucaryotic transcriptional repressor proteins. This region may also bind unknown viral proteins. We propose that the unique region upstream of the UL127 promoter and the MIE enhancer negatively regulates the expression from the UL127 promoter in permissive human fibroblast cells. This region may be a regulatory boundary preventing the effects of the very strong MIE enhancer on this promoter.

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.