An Endothelial Cell-Specific Requirement for the UL133-UL138 Locus of Human Cytomegalovirus for Efficient Virus Maturation

Human cytomegalovirus (HCMV) infects a variety of cell types in humans, resulting in a varied pathogenesis in the immunocompromised host. Endothelial cells (ECs) are considered an important target of HCMV infection that may contribute to viral pathogenesis. Although the viral determinants important for entry into ECs are well defined, the molecular determinants regulating postentry tropism in ECs are not known. We previously identified the UL133-UL138 locus encoded within the clinical strain-specific ULb′ region of the HCMV genome as important for the latent infection in CD34⁺ hematopoietic progenitor cells (HPCs). Interestingly, this locus, while dispensable for replication in fibroblasts, was required for efficient replication in ECs infected with the TB40E or fusion-inducing factor X (FIX) HCMV strains. ECs infected with a virus lacking the entire locus (UL133-UL138_NULL virus) complete the immediate-early and early phases of infection but are defective for infectious progeny virus production. ECs infected with UL133-UL138_NULL virus exhibited striking differences in the organization of intracellular membranes and in the assembly of mature virions relative to ECs infected with wild-type (WT) virus. In UL133-UL138_NULL virus-infected ECs, Golgi stacks were disrupted, and the viral assembly compartment characteristic of HCMV infection failed to form. Further, progeny virions in UL133-UL138_NULL virus-infected ECs inefficiently acquired the virion tegument and secondary envelope. These defects were specific to infection in ECs and not observed in fibroblasts infected with UL133-UL138_NULL virus, suggesting an EC-specific requirement for the UL133-UL138 locus for late stages of replication. To our knowledge, the UL133-UL138 locus represents the first cell-type-dependent, postentry tropism determinant required for viral maturation.     

Dynamics of DDB2-DDB1 complex under different naturally-occurring mutants in Xeroderma Pigmentosum disease

Background

Xeroderma Pigmentosum (XP) is a disease caused by mutations in the nucleotide excision repair (NER) pathway. Patients with XP exhibit a high propensity to skin cancers and some subtypes of XP can even present neurological impairments. During NER, DDB2 (XPE), in complex with DDB1 (DDB-Complex), performs the DNA lesion recognition. However, not much is known about how mutations found in XP patients affect the DDB2 structure and complex assembly. Thus, we searched for structural evidence associated with the role of three naturally occurring mutations found in XPE patients: R273H, K244E, and L350P.

DDB2-Independent Role for p53 in the Recovery from Ultraviolet Light-Induced Replication Arrest

Ultraviolet light (UV light) induces helix distorting DNA lesions that pose a block to replicative DNA polymerases. Recovery from this replication arrest is reportedly impaired in nucleotide excision repair (NER)-deficient xeroderma pigmentosum (XP) fibroblasts and primary fibroblasts lacking functional p53. These independent observations suggested that the involvement of p53 in the recovery from UV-induced replication arrest was related to its role in regulating the global genomic subpathway of NER (GG-NER). Using primary human fibroblasts, we confirm that the recovery from UV-induced replication arrest is impaired in cells lacking functional p53 and in primary XP fibroblasts derived from complementation groups A or C (XP-A and XP-C) that are defective in GG-NER. Surprisingly, DNA synthesis recovered normally in GG-NER-deficient XP complementation group E (XP-E) cells that carry mutations in the p53 regulated DNA repair gene DDB2 and are specifically defective in the repair of cyclobutane pyrimidine dimers (CPD) but not pyrimidine (6-4) pyrimidone photoproducts. Disruption of p53 in these XP-E fibroblasts prevented the recovery from UV-induced replication arrest. Therefore, the roles of p53 and GG-NER in the recovery from UV-induced replication are separable and DDB2-independent. These results further indicate that primary human fibroblasts expressing functional p53 efficiently replicate DNA containing CPD whereas p53-deficient cells do not, consistent with a role for p53 in permitting translesion DNA synthesis of these DNA lesions.     

Human cytomegalovirus UL84 insertion mutant defective for viral DNA synthesis and growth

Human cytomegalovirus (HCMV) UL84 is required for oriLyt-dependent DNA replication, and evidence from transient transfection assays suggests that UL84 directly participates in DNA synthesis. In addition, because of its apparent interaction with IE2, UL84 is implicated as a possible regulatory protein. To address the role of UL84 in the context of the viral genome, we generated a recombinant HCMV bacterial artificial chromosome (BAC) construct that did not express the UL84 gene product. This construct, BAC-IN84/Ep, displayed a null phenotype in that it failed to produce infectious virus after transfection into human fibroblast cells, whereas a revertant virus readily produced viral plaques and, subsequently, infectious virus. Real-time quantitative PCR showed that BAC-IN84/Ep was defective for DNA synthesis in that no increase in the accumulation of viral DNA was observed in transfected cells. We were unable to complement BAC-IN84/Ep in trans; however, oriLyt-dependent DNA replication was observed by the cotransfection of UL84 and BAC-IN84/Ep. An analysis of viral mRNA by real-time PCR indicated that, even in the absence of DNA synthesis, all representative kinetic classes of genes were expressed in cells transfected with BAC-IN84/Ep. The detection of UL44 and IE2 by immunofluorescence in BAC-IN84/Ep-transfected cells showed that these proteins failed to partition into replication compartments, indicating that UL84 expression is essential for the formation of these proteins into replication centers within the context of the viral genome. These results show that UL84 provides an essential DNA replication function and influences the subcellular localization of other viral proteins.     

Human cytomegalovirus UL84 oligomerization and heterodimerization domains act as transdominant inhibitors of oriLyt-dependent DNA replication: evidence that IE2-UL84 and UL84-UL84 interactions are required for lytic DNA replication

Human cytomegalovirus (HCMV) UL84 encodes a 75-kDa protein required for oriLyt-dependent DNA replication and interacts with IE2 in infected and transfected cells. UL84 localizes to the nucleus of transfected and infected cells and is found in viral replication compartments. In transient assays it was shown that UL84 can interfere with the IE2-mediated transactivation of the UL112/113 promoter of HCMV. To determine whether UL84 protein-protein interactions are necessary for lytic DNA synthesis, we purified UL84 and used this protein to generate a monoclonal antibody. Using this antibody, we now show that UL84 forms a stable interaction with itself in vivo. The point of self-interaction maps to a region of the protein between amino acids 151 and 200, a domain that contains a series of highly charged amino acid residues. Coimmunoprecipitation assays determined that UL84 interacts with a protein domain present within the first 215 amino acids of IE2. We also show that an intact leucine zipper domain of UL84 is required for a stable interaction with IE2 and UL84 leucine zipper mutants fail to complement oriLyt-dependent DNA replication. UL84 leucine zipper mutants no longer interfere with IE2-mediated transactivation of the UL112/113 promoter, confirming that the leucine zipper is essential for a functional interaction with IE2. In addition, we demonstrate that both the leucine zipper and oligomerization domains of UL84 can act as transdominant-negative inhibitors of lytic replication in the transient assay, strongly suggesting that both an IE2-UL84 and a UL84-UL84 interaction are required for DNA synthesis.     

Physical and functional interaction between DDB and XPA in nucleotide excision repair

Damaged DNA-binding protein (DDB), consisting of DDB1 and DDB2 subunits recognizes a wide spectrum of DNA lesions. DDB is dispensable for in vitro nucleotide excision repair (NER) reaction, but stimulates this reaction especially for cyclobutane pyrimidine dimer (CPD). Here we show that DDB directly interacts with XPA, one of core NER factors, mainly through DDB2 subunit and the amino-acid residues between 185 and 226 in XPA are important for the interaction. Interestingly, the point mutation causing the substitution from Arg-207 to Gly, which was previously identified in a XP-A revertant cell-line XP129, diminished the interaction with DDB in vitro and in vivo. In a defined system containing R207G mutant XPA and other core NER factors, DDB failed to stimulate the excision of CPD, although the mutant XPA was competent for the basal NER reaction. Moreover, in vivo experiments revealed that the mutant XPA is recruited to damaged DNA sites with much less efficiency compared with wild-type XPA and fails to support the enhancement of CPD repair by ectopic expression of DDB2 in SV40-transformed human cells. These results suggest that the physical interaction between DDB and XPA plays an important role in the DDB-mediated NER reaction.     

The Human Cytomegalovirus DNA Polymerase Processivity Factor UL44 Is Modified by SUMO in a DNA-Dependent Manner

During the replication of human cytomegalovirus (HCMV) genome, the viral DNA polymerase subunit UL44 plays a key role, as by binding both DNA and the polymerase catalytic subunit it confers processivity to the holoenzyme. However, several lines of evidence suggest that UL44 might have additional roles during virus life cycle. To shed light on this, we searched for cellular partners of UL44 by yeast two-hybrid screenings. Intriguingly, we discovered the interaction of UL44 with Ubc9, an enzyme involved in the covalent conjugation of SUMO (Small Ubiquitin-related MOdifier) to cellular and viral proteins. We found that UL44 can be extensively sumoylated not only in a cell-free system and in transfected cells, but also in HCMV-infected cells, in which about 50% of the protein resulted to be modified at late times post-infection, when viral genome replication is accomplished. Mass spectrometry studies revealed that UL44 possesses multiple SUMO target sites, located throughout the protein. Remarkably, we observed that binding of UL44 to DNA greatly stimulates its sumoylation both in vitro and in vivo. In addition, we showed that overexpression of SUMO alters the intranuclear distribution of UL44 in HCMV-infected cells, and enhances both virus production and DNA replication, arguing for an important role for sumoylation in HCMV life cycle and UL44 function(s). These data report for the first time the sumoylation of a viral processivity factor and show that there is a functional interplay between the HCMV UL44 protein and the cellular sumoylation system.     

The Gene Product of Human Cytomegalovirus Open Reading Frame UL56 Binds the pac Motif and Has Specific Nuclease Activity

Using the cis-acting human cytomegalovirus (HCMV) packaging elements (pac 1 and pac 2) as DNA probes, specific DNA-protein complexes were detected by electrophoretic mobility shift assay (EMSA) in both HCMV-infected cell nuclear extracts and recombinant baculovirus-infected cell extracts containing the HCMV p130 (pUL56) protein. DNA-binding proteins, which were common in uninfected and infected cell extracts, were also detected. Mutational analysis showed that only the AT-rich core sequences in these cis-acting motifs, 5′-TAAAAA-3′ (pac 1) and 5′-TTTTAT-3′ (pac 2), were required for specific DNA-protein complex formation. The specificity of the DNA-protein complexes was confirmed by EMSA competition. Furthermore, a specific endonuclease activity was found to be associated with lysates of baculovirus-infected cells expressing recombinant p130 (rp130). This nuclease activity was time dependent, related to the amount of rp130 in the assay, and ATP independent. Nuclease activity remained associated with rp130 after partial purification by sucrose gradient centrifugation, suggesting that this activity is a property of HCMV p130. We propose a possible involvement of p130 in HCMV DNA packaging.Human cytomegalovirus (HCMV), one of eight human herpesviruses, can cause serious illness in neonates as well as in immunocompromised adults (2). For example, transplant and AIDS patients may develop life-threatening diseases as a consequence of primary infection or reactivation of latent infection. Present therapeutic approaches are limited, and new strategies that may result from a better understanding of the molecular events involved in viral maturation are needed.The HCMV virion consists of an envelope, an amorphous tegument, and an icosahedral nucleocapsid, which is assembled in the nuclei of infected cells. The precise molecular events of HCMV capsid assembly and subsequent DNA packaging are not well understood. It is generally accepted that viral DNA is packaged into a procapsid consisting of major capsid protein (UL86), minor capsid protein (UL85), minor capsid protein-binding protein (UL46), smallest capsid protein (UL47/48), assembly protein (UL80.5), and proteinase precursor protein (UL80a) (8). The assembly protein is removed during DNA insertion. It is unclear how the concatenated viral DNA contacts empty capsids and is cleaved and packaged into the capsid.Recent studies with herpes simplex virus type 1 (HSV-1) mutants that were temperature sensitive suggest that cleavage of the concatenated DNA does not occur in the absence of packaging (1). One possible model would be the involvement of cleavage packaging protein(s) which could facilitate incorporation of DNA into the procapsid by attaching to a specific motif within the viral genome. With HSV-1, the UL36 gene product (ICP1) and a smaller protein (possibly encoded by UL37) are part of a complex that recognizes the HSV-specific a sequence and are required for cleavage and packaging of viral DNA from concatemers (6, 7). In addition, the HSV-1 ICP 18.5 (UL28) gene product and the pseudorabies virus (PrV) homolog (16) were also reported to play an important role in DNA packaging (1, 14). Addison et al. (1) demonstrated that empty capsids were observed under conditions nonpermissive for the expression of the HSV-1 ICP 18.5 gene product. The HSV-1 ICP 18.5 mutants failed to cleave concatenated viral DNA in noncomplementing cells, suggesting that cleavage and packaging require ICP 18.5. Similar results were reported by Mettenleiter et al. (14) for PrV mutant protein. These observations suggest that the HSV-1 UL36, UL37, and UL28 gene products are involved in cleavage and packaging of concatenated viral DNA.In a recent study, we identified and partially characterized the gene product of HCMV UL56 (4). The HCMV UL56 gene product of 130 kDa is the homolog of the HSV-1 UL28 gene product. It is therefore postulated that UL56 possesses properties comparable to those of HSV-1 UL28, implying an involvement in cleavage and packaging of DNA. The HCMV genomic a sequence is a short sequence located at both termini of the genome and repeated in an inverted orientation at the L-S junction. The a sequence plays a key role in replication as a cis-acting signal for cleavage and packaging of progeny viral DNA and circularization of the viral genome. The HCMV a sequence contains two conserved motifs, pac 1 and pac 2, which are required for cleavage and packaging of the viral DNA (18). Both sequence motifs are located on one side of the cleavage site. The pac 1 and pac 2 motifs have an AT-rich core flanked by a GC-rich sequence. During the initial step of viral DNA packaging, a capsid-associated protein may bind to the pac sequences and may be involved in cleavage of the viral DNA concatemer.In this study, electrophoretic mobility shift assays (EMSAs) were performed with DNA probes spanning the region of these cis-acting elements. These studies demonstrate that specific proteins from HCMV-infected nuclear extracts or baculovirus-UL56-infected cell extracts bind to the pac motifs. Using affinity-purified monospecific antibodies, we show that p130 is present in specific DNA-protein complexes containing the pac motifs of the viral genome. Furthermore, evidence is presented for a sequence-specific endonuclease activity of recombinant HCMV p130, using circular plasmid DNA bearing the a sequence as a substrate.     

The Cellular Protein MCM3AP Is Required for Inhibition of Cellular DNA Synthesis by the IE86 Protein of Human Cytomegalovirus

Like all DNA viruses, human cytomegalovirus (HCMV) infection is known to result in profound effects on host cell cycle. Infection of fibroblasts with HCMV is known to induce an advance in cell cycle through the G₀-G₁ phase and then a subsequent arrest of cell cycle in early S-phase, presumably resulting in a cellular environment optimum for high levels of viral DNA replication whilst precluding replication of cellular DNA. Although the exact mechanisms used to arrest cell cycle by HCMV are unclear, they likely involve a number of viral gene products and evidence points to the ability of the virus to prevent licensing of cellular DNA synthesis. One viral protein known to profoundly alter cell cycle is the viral immediate early 86 (IE86) protein - an established function of which is to initially drive cells into early S phase but then inhibit cellular DNA synthesis. Here we show that, although IE86 interacts with the cellular licensing factor Cdt1, it does not inhibit licensing of cellular origins. Instead, IE86-mediated inhibition of cellular DNA synthesis requires mini-chromosome-maintenance 3 (MCM3) associated protein (MCM3AP), which can cause subsequent inhibition of initiation of cellular DNA synthesis in a licensing-independent manner.     

DDB2, an Essential Mediator of Premature Senescence

Reactive oxygen species (ROS) is critical for premature senescence, a process significant in tumor suppression and cancer therapy. Here, we reveal a novel function of the nucleotide excision repair protein DDB2 in the accumulation of ROS in a manner that is essential for premature senescence. DDB2-deficient cells fail to undergo premature senescence induced by culture shock, exogenous oxidative stress, oncogenic stress, or DNA damage. These cells do not accumulate ROS following DNA damage. The lack of ROS accumulation in DDB2 deficiency results from high-level expression of the antioxidant genes in vitro and in vivo. DDB2 represses antioxidant genes by recruiting Cul4A and Suv39h and by increasing histone-H3K9 trimethylation. Moreover, expression of DDB2 also is induced by ROS. Together, our results show that, upon oxidative stress, DDB2 functions in a positive feedback loop by repressing the antioxidant genes to cause persistent accumulation of ROS and induce premature senescence.DDB2 is encoded by the nucleotide excision repair (NER) XPE gene (17, 24, 33). Unlike other NER gene-deficient cells or xeroderma pigmentosum (XP) cells, the XPE cells exhibit only a mild deficiency in NER (55). However, because of its high affinity for cyclobutane pyrimidine dimers (CPDs) and 6-4 photoproducts, several studies implicated DDB2 in the early damaged-DNA recognition step of NER (61). However, a direct role of DDB2 in NER is a point of controversy (28, 41, 57). Lower organisms (yeasts), in which other XP genes are conserved, apparently do not encode a DDB2 homolog (55, 64). We showed that DDB2 associates with Cul4, a component of an E3 ubiquitin ligase complex that is now known to involve the DDB2 binding protein DDB1 as its adapter (48). The Cul4-DDB1 E3 ligase associates with a number of substrate-specific adapter proteins to target substrates for ubiquitination (30, 35). DDB2 is believed to be one of those substrate adapters, which allows Cul4-DDB1 to target specific proteins. Two studies suggested that the Cul4A-DDB1-DDB2 complex could participate in the ubiquitination of histones, indicating a role of DDB2 in chromatin remodeling (23, 59). Other investigators suggested a role of Cul4A-DDB1-DDB2 in the ubiquitination of XPC (15, 52). We recently found that DDB2 is involved also in targeting p21 for proteolysis and demonstrated that DDB2 stimulated NER by regulating the level of p21 (51).It was shown elsewhere that DDB2^−/− mouse embryonic fibroblasts (MEFs) are resistant to UV-induced apoptosis (20, 21). Recently, we extended those observations by demonstrating that DDB2^−/− MEFs or DDB2-deficient human cells are resistant to apoptosis induced by a variety of DNA-damaging agents (50). Moreover, DDB2^−/− MEFs are deficient in E2F1-induced apoptosis. The resistance to apoptosis is linked also to high-level accumulation of p21 because deletion of p21 restored apoptosis. The polyubiquitination of p21 is significantly reduced in DDB2-deficient cells (50), suggesting that after DNA damage DDB2 plays a key role in polyubiquitinating p21. Also, we observed evidence for a physical association between DDB2 and p21, which was increased in UV-irradiated cells (50), indicating that DDB2 plays a direct role in targeting p21 for proteolysis after DNA damage. These observations provided evidence that DDB2, in addition to stimulating NER, plays a significant role in terminating DNA damage checkpoint, allowing cells with extensive DNA damage to undergo apoptosis.In addition to its role in the inhibition of cell cycle and apoptosis, p21 has been implicated also in cellular senescence, as its level increases in senescent cells (7). Cellular senescence is defined as a proliferative arrest of a cell after a limited number of cell divisions while the cell remains metabolically and synthetically active (6, 63). Senescence can be triggered by both extrinsic factors such as oncogenic stress, DNA damage, oxidative stress, and culture shock and intrinsic factors such as telomere regression in human cells (19). When grown in cell culture medium, human diploid fibroblasts undergo 60 to 80 population doublings, after which they cease proliferation as a result of telomere erosion and enter into the stage of replicative senescence characterized by enlarged and flattened morphology, increased granularity, and enhanced senescence-associated β-galactosidase (SA-β-Gal) activity (13). In contrast, telomere length does not limit the ability of the murine fibroblasts to proliferate in culture. It was shown that the supraphysiological level of oxygen or reactive oxygen species (ROS) under which the cells are grown led murine fibroblasts to senesce (39). ROS accumulation or oxidative stress induces the senescent phenotype in response to oncogenic stress as well as in response to DNA-damaging agents (56). These pathways have been termed premature senescence, which recapitulates molecular features of replicative senescence. Premature senescence induced by oncogene expression is a significant mechanism of tumor suppression involving the Ink4a/Arf locus (47). Moreover, DNA damage-induced premature senescence is significant, as many anticancer drugs have been shown to induce premature senescence of tumor cells (12, 44).Because DDB2^−/− MEFs express p21 at a high level, we expected those cells to undergo premature senescence at an earlier passage than the wild-type (WT) MEFs. Surprisingly, we found that DDB2^−/− MEFs escape senescence at a very high frequency. Moreover, DDB2^−/− MEFs or DDB2-deficient human cells are resistant to premature senescence induced by a variety of agents, including oncogenic stress, exogenous oxidative stress, and DNA damage. The lack of premature senescence in the presence of high-level p21, especially after DNA damage, suggests that DDB2 functions in the senescence program through a mechanism that is downstream of the p21 pathway senescence. Here we show that DDB2 participates in the senescence program by inducing persistent accumulation of ROS.