Identification and mapping of dimerization and DNA-binding domains in the C terminus of the IE2 regulatory protein of human cytomegalovirus.

The 80-kDa IE2 nuclear phosphoprotein encoded by the human cytomegalovirus (HCMV) major immediate-early (MIE) gene behaves both as a nonspecific transactivator of heterologous reporter genes and as a specific repressor of its own promoter-enhancer region. To begin to examine the biochemical properties of the IE2 protein, we prepared panels of N-terminal and C-terminal truncation mutants by in vitro translation procedures. In cross-linking experiments, the C-terminal half of IE2 (which is sufficient for down-regulation) formed dimers but N-terminal segments did not do so. Cotranslated Oct2/IE2 fusion proteins containing the same IE2 C-terminal region from codons 266 to 579 also formed mixed-subunit DNA-bound oligomeric complexes in gel mobility shift assays. Furthermore, an IE2 domain bounded by codons 388 to 542 proved to immunoprecipitate as heterodimers with cotranslated subunits containing known epitopes for specific antibodies. Deletion up to codon 428 or truncation back to codon 504 prevented this interaction. In direct gel shift DNA-binding assays, a bacterial GST/IE2(346-579) fusion protein bound to a 30-mer oligonucleotide probe encompassing the major immediate-early gene negative cis-regulatory target DNA sequence but failed to bind to a single-base-pair insertion mutant probe (delta CRS). This specific DNA-binding activity was abolished by further deletion up to codon 388 on the N-terminal side or by truncation at codon 542 on the C-terminal side. Therefore, the minimal DNA-binding domain requires additional amino acid motifs on both sides of the dimerization domain. This segment of IE2 is functionally important for both transactivation and down-regulation and contains several highly conserved amino acid motifs that are shared amongst the equivalent HCMV, simian CMV, mouse CMV, rat CMV, and human herpesvirus 6 proteins from other betaherpesviruses.     

Evaluation and mapping of the DNA binding and oligomerization domains of the IE2 regulatory protein of human cytomegalovirus using yeast one and two hybrid interaction assays

The 86-kDa IE2 nuclear phosphoprotein encoded by the human cytomegalovirus (HCMV) major immediate-early (MIE) gene behaves as both a non-specific transactivator of viral and cellular gene expression and as a specific DNA-binding protein targeted to the cis-repression sequence (CRS) at the cap site of its own promoter/enhancer region. Although the IE2 protein produced in bacteria has been shown to bind to the 14-bp palindromic CRS motif and IE2 synthesized in vitro forms stable dimers in solution through the conserved C-terminus of the protein, there is no direct evidence as yet that the intracellular mammalian forms of IE2 do so. Here, we show that the intact HCMV IE2 protein both binds to CRS DNA and dimerizes in yeast cells. In a one-hybrid assay system, a GAL4/IE2 fusion protein expressed in yeast cells activated target HIS3 expression only when CRS sites were located upstream of the GAL1 minimal promoter, but failed to do so on mutant CRS sites, demonstrating a requirement for sequence-specific DNA-binding by IE2. Examination of a series of deletion and triple amino acid point mutations in the C-terminal half of IE2 mapped the domains required for DNA-binding in yeast to the entire region between codons 313 and 579, whereas in the previous in vitro study with truncated bacterial GST fusion proteins, it was mapped to between codons 346 and 579. Transient co-transfection assays with deleted IE2 effector genes in Vero cells showed that the extra segment of IE2 between codons 313 and 346 is also required for both autoregulation and transactivation activity in mammalian cells. In a two-hybrid assay to study IE2 self-interations, we generated both GAL4 DNA-binding (DB) and activation domain (A)/IE2 fusion proteins and showed that IE2 could also dimerize or oligomerize through the C-terminus of the protein in yeast cells. Domains required for this interaction were all mapped to within the region between codons 388 and 542, which is coincident with the domain mapped previously for dimerization by co-translation and immunoprecipitation in vitro. Comparison of the domains of the IE2 protein required for CRS binding and dimerization in yeast suggests that these activities correlate precisely with requirements for the negative autoregulation function of the IE2 protein in mammalian cells.     

A 10-base-pair element of the human immunodeficiency virus type 1 long terminal repeat (LTR) is an absolute requirement for transactivation by the human cytomegalovirus 72-kilodalton IE1 protein but can be compensated for by other LTR regions in transactivation by the 80-kilodalton IE2 protein.

Transient gene expression studies have indicated that human cytomegalovirus (HCMV) specifically transactivates the human immunodeficiency virus (HIV) long terminal repeat (LTR). We show here, by a specific mutational analysis, that only the TATA box region is obligatory for transactivation of the HIV-1 LTR by HCMV. Similarly, this element is also sufficient for transactivation by either the HCMV 72-kDa major immediate-early 1 (IE1) or 80-kDa IE2 gene product independently. However, deletion of a 10-bp region from the minimal responsive element, 5' to the TATA box, dramatically reduced the level of HCMV 72-kDa IE1 or 80-kDa IE2 transactivation, indicating a crucial role for this element in transactivation. Whereas inclusion of the TAR element or Sp1 sites on this 10-bp-deleted minimal promoter had no effect on the removal of IE1 transactivation, TAR and Sp1 elements did compensate for the 10-bp element in transactivation by IE2 and HCMV. Consequently, the sequence requirements of the HIV-1 LTR for transactivation by HCMV can be reproduced by these IE1 and IE2 gene products of HCMV.     

The putative zinc finger of the human cytomegalovirus IE2 86-kilodalton protein is dispensable for DNA binding and autorepression, thereby demarcating a concise core domain in the C terminus of the protein

The IE2 86-kDa gene product is an essential regulatory protein of human cytomegalovirus (HCMV) with several functions, including transactivation, negative autoregulation, and cell cycle regulation. In order to understand the physiological significance of each of the IE2 functions, discriminating mutants of IE2 are required that can be tested in a viral background. However, no such mutants of IE2 are available, possibly reflecting structural peculiarities of the large and ill-defined C-terminal domain of IE2. Here, we revisited the C-terminal domain by analyzing IE2 mutants for transactivation, DNA binding, autoregulation, and cell cycle regulation in parallel. We found it to contain an unexpectedly concise core domain (amino acids 450 to 544) that is defined by its absolute sensitivity to any kind of mutation. In contrast, the region adjacent to the core (amino acids 290 to 449) generally tolerates mutations much better. Although it contributes more specific sequence information to distinct IE2 activities, none of the mutations analyzed abolished any particular function. The core is demarcated from the adjacent region by the putative zinc finger region (amino acids 428 to 452). Surprisingly, the deletion of the putative zinc finger region from IE2 revealed that this region is entirely dispensable for any of the IE2 functions tested here in transfection assays. Our work supports the view that the 100 amino acids of the core domain hold the key to most functions of IE2. A systematic, high-density mutational analysis of this region may identify informative mutants discriminating between various IE2 functions that can then be tested in a viral background.     

Cell-specific effects of human cytomegalovirus unique region on recombinant protein expression

The major immediate-early (MIE) promoter of human cytomegalovirus (CMV) is widely used to express recombinant proteins in mammalian cells. CMV MIE promoter contains a strong enhancer and an AT-rich unique region (UR). The UR can function as an insulator or a negative element of CMV MIE promoter, depending on the cellular proteins associated with it. To examine the effects of UR on recombinant protein expression in mammalian cells, we constructed two CMV MIE promoter-based expression plasmids for comparison to the conventional CMV MIE promoter by removing or adding UR. Addition of UR enhances transgene expression in HEK293 stable cells while removal of UR increases both transient and stably integrated expression in HeLa cells. Our results further demonstrate that the cell-specific effect of UR depends on the protein levels of UR-binding proteins, pancreatic-duodenal homeobox factor-1, special AT-rich sequence binding protein 1, and CCAAT displacement protein, in these cells. Collectively, these modified CMV expression plasmids can be utilized to improve recombinant protein production in specific mammalian cell lines.     

Exon 3 of the human cytomegalovirus major immediate-early region is required for efficient viral gene expression and for cellular cyclin modulation

The human cytomegalovirus (HCMV) major immediate-early (IE) proteins share an 85-amino-acid N-terminal domain specified by exons 2 and 3 of the major IE region, UL122-123. We have constructed IE Delta30-77, a recombinant virus that lacks the majority of IE exon 3 and consequently expresses smaller forms of both IE1 72- and IE2 86-kDa proteins. The mutant virus is viable but growth impaired at both high and low multiplicities of infection and exhibits a kinetic defect that is not rescued by growth in fibroblasts expressing IE1 72-kDa protein. The kinetics of mutant IE2 protein accumulation in IE Delta30-77 virus-infected cells are approximately normal compared to wild-type virus-infected cells, but the IE Delta30-77 virus is delayed in expression of early viral genes, including UL112-113 and UL44, and does not sustain expression of mutant IE1 protein as the infection progresses. Additionally, cells infected with IE Delta30-77 exhibit altered expression of cellular proteins compared to wild-type HCMV-infected cells. PML is not dispersed but is retained at ND10 sites following infection with IE Delta30-77 mutant virus. While the deletion mutant retains the ability to mediate the stabilization of cyclin B1, cdc6, and geminin in infected cells, its capacity to upregulate the expression of cyclin E has been reduced. These data indicate that the activity of one or both of the HCMV major IE proteins is required in vivo for the modulation of cell cycle proteins observed in cells infected with wild-type HCMV.     

Human T-lymphotropic virus tax activates human cytomegalovirus major-immediate early promoter and improves production of recombinant proteins in HEK293 cells

The human cytomegalovirus (CMV) major immediate-early (MIE) promoter is widely used in mammalian cells for production of recombinant proteins. It is of great interest to further enhance protein production driven by the CMV promoter. Here, we report that the Tax protein of human T-lymphotropic virus stimulates the transgene expression under the control of CMV MIE promoter in HEK293 cells. At least threefold increases in transient production of recombinant proteins, including luciferase and two biopharmaceutical proteins (erythropoietin and interferon-γ), were detected. Furthermore, cyclic adenosine monophosphate (AMP)-response element binding protein 2 (CREB2) was identified as a cellular cofactor, which might be responsible for Tax transactivation of the CMV MIE promoter. Our results not only demonstrate the potential use of this novel expression strategy for improvement of recombinant protein production in HEK293 cells but also provide the molecular mechanism for Tax-mediated activation of CMV MIE promoter.     

Alternative splicing of the human cytomegalovirus major immediate-early genes affects infectious-virus replication and control of cellular cyclin-dependent kinase

The major immediate-early (MIE) gene locus of human cytomegalovirus (HCMV) is the master switch that determines the outcomes of both lytic and latent infections. Here, we provide evidence that alteration in the splicing of HCMV (Towne strain) MIE genes affects infectious-virus replication, movement through the cell cycle, and cyclin-dependent kinase activity. Mutation of a conserved 24-nucleotide region in MIE exon 4 increased the abundance of IE1-p38 mRNA and decreased the abundance of IE1-p72 and IE2-p86 mRNAs. An increase in IE1-p38 protein was accompanied by a slight decrease in IE1-p72 protein and a significant decrease in IE2-p86 protein. The mutant virus had growth defects, which could not be complemented by wild-type IE1-p72 protein in trans. The phenotype of the mutant virus could not be explained by an increase in IE1-p38 protein, but prevention of the alternate splice returned the recombinant virus to the wild-type phenotype. The lower levels of IE1-p72 and IE2-p86 proteins correlated with a delay in early and late viral gene expression and movement into the S phase of the cell cycle. Mutant virus-infected cells had significantly higher levels of cdk-1 expression and enzymatic activity than cells infected with wild-type virus. The mutant virus induced a round-cell phenotype that accumulated in the G(2)/M compartment of the cell cycle with condensation and fragmentation of the chromatin. An inhibitor of viral DNA synthesis increased the round-cell phenotype. The round cells were characteristic of an abortive viral infection.     

Transactivation of a human cytomegalovirus early promoter by gene products from the immediate-early gene IE2 and augmentation by IE1: mutational analysis of the viral proteins.

Expression from a human cytomegalovirus early promoter (E1.7) has been shown to be activated in trans by the IE2 gene products (C.-P. Chang, C. L. Malone, and M. F. Stinski, J. Virol. 63:281-290, 1989). Using wild-type and mutant viral proteins, we have defined the protein regions required for transactivation of the E1.7 promoter in IE2 and for augmentation of transactivation in the IE1 protein. Two regions of the IE2 proteins were found to be essential for transactivation. One near the amino terminus is within 52 amino acids encoded by exon 3. The second comprises the carboxyl-terminal 85 amino acids encoded by exon 5. The IE2 protein encoded by an mRNA which lacks the intron within exon 5 and the IE2 protein encoded by exon 5 had no activity for transactivation of the E1.7 promoter. Although the IE1 gene product alone had no effect on this early viral promoter, maximal early promoter activity was detected when both IE1 and IE2 gene products were present. The IE1 protein positively regulated its enhancer-containing promoter-regulatory region. The IE1 protein alone increased the steady-state level of IE2 mRNA; therefore, IE1 and IE2 are synergistic for expression from the E1.7 promoter. Like the IE2 proteins, the IE1 protein requires for activity 52 amino acids encoded by exon 3. IE1 also requires amino acids encoded by exon 4. Since the IE1 and IE2 proteins have 85 amino acids in common at the amino-terminal end encoded by exons 2 and 3, the difference between these specific transactivators resides in their carboxyl-terminal amino acids encoded by exons 4 and 5, respectively.     

Abundant constitutive expression of the immediate-early 94K protein from cytomegalovirus (Colburn) in a DNA-transfected mouse cell line.

A 94-kilodalton phosphoprotein known as IE94 is the only viral polypeptide synthesized in abundance under immediate-early conditions after infection by cytomegalovirus (CMV) strain Colburn in either permissive primate or nonpermissive rodent cells. The IE94 gene, which maps at coordinates 0.71 to 0.73 in the viral genome, contains a large intron in the 5' leader sequence, and its promoter regulatory region contains novel, multiple-palindromic, repeated elements. Two recombinant plasmids (pTJ148 and pTJ198) containing the 10.5-kilobase-pair HindIII-H DNA fragment from CMV (Colburn) were transfected into mouse Ltk- cells, by either linked or unlinked coselection in hypoxanthine-aminopterin-thymidine medium, together with herpes simplex virus thymidine kinase genes. With both procedures, constitutive synthesis of the IE94 immediate-early protein was detected in pools of Ltk+ cells by immunoprecipitation. Subsequently, we isolated a clonal Ltk+ cell line which expressed the [35S]methionine-labeled IE94 polypeptide in sufficient abundance to be visualized directly in autoradiographs after gel electrophoresis of total-cell-culture protein extracts. The IE94 polypeptide synthesized in the transfected cells was indistinguishable in size and overall net charge from that produced in virus-infected cells. In addition, the IE94 protein expressed in LH2p198-3 cells was phosphorylated (presumably by a cellular protein kinase) and generated similar phosphopeptide patterns after partial tryptic digestion to those obtained with the CMV IE94 protein from infected cells. The cell line contained two to four stably integrated copies of the IE94 gene and synthesized a single virus-specific mRNA of 2.5 kilobases detectable on Northern blots. A new antigen, detectable by indirect anticomplement immunofluorescence with monoclonal antibody against the human CMV IE68 protein, was present in the nuclei of more than 95% of the LH2p198-3 cells. This evidence suggests that (unlike most herpesvirus genes) the CMV IE94 gene, together with its complex promoter and spliced mRNA structure, may contain all of the regulatory elements necessary for strong constitutive expression in mammalian cells in the absence of other viral factors.