Resistance of Human Cytomegalovirus to Benzimidazole Ribonucleosides Maps to Two Open Reading Frames: UL89 and UL56

2,5,6-Trichloro-1-β-d-ribofuranosyl benzimidazole (TCRB) is a potent and selective inhibitor of human cytomegalovirus (HCMV) replication. TCRB acts via a novel mechanism involving inhibition of viral DNA processing and packaging. Resistance to the 2-bromo analog (BDCRB) has been mapped to the UL89 open reading frame (ORF), and this gene product was proposed as the viral target of the benzimidazole nucleosides. In this study, we report the independent isolation of virus that is 20- to 30-fold resistant to TCRB (isolate C4) and the characterization of the virus. The six ORFs known to be essential for viral DNA cleavage and packaging (UL51, UL52, UL56, UL77, UL89, and UL104) were sequenced from wild-type HCMV, strain Towne, and from isolate C4. Mutations were identified in UL89 (D344E) and in UL56 (Q204R). The mutation in UL89 was identical to that previously reported for virus resistant to BDCRB, but the mutation in UL56 is novel. Marker transfer analysis demonstrated that each of these mutations individually caused ∼10-fold resistance to the benzimidazoles and that the combination of both mutations caused ∼30-fold resistance. The rate and extent of replication of the mutants was the same as for wild-type virus, but the viruses were less sensitive to inhibition of DNA cleavage by TCRB. Mapping of resistance to UL56 supports and extends recent work showing that UL56 codes for a packaging motif binding protein which also has specific nuclease activity (E. Bogner et al., J. Virol. 72:2259–2264, 1998). Resistance which maps to two different genes suggests that their putative proteins interact and/or that either or both have a benzimidazole ribonucleoside binding site. The results also suggest that the gene products of UL89 and UL56 may be antiviral drug targets.Human cytomegalovirus (HCMV) can cause significant morbidity and mortality in immunocompromised populations (3). It is a common opportunistic disease in patients with AIDS and is often a factor in their death (38). HCMV infection has been implicated in increased risk of organ rejection following heart (28) and kidney transplants (8) and in restenosis of diseased arteries following angioplasty (41, 63). It is also a leading cause of birth defects (16).Current therapies for HCMV infection include ganciclovir (GCV) (22), cidofovir (30), and foscarnet (20). Each of these drugs has several limitations to its use: none are orally bioavailable, all have dose-limiting toxicity, and resistance has developed to each (26). Because all three of these drugs inhibit viral replication through an interaction with the virally encoded DNA polymerase (25, 31, 37), the possibility of cross-resistance exists. Thus, additional drugs with unique mechanisms of action are needed for the treatment of HCMV infections.In 1995, we reported that 2-bromo-5,6-dichloro-1-(β-d-ribofuranosyl)benzimidazole (BDCRB; Fig. ​Fig.1)1) and the 2-chloro analog [2,5,6-trichloro-1-(β-d-ribofuranosyl)benzimidazole TCRB] are potent and selective inhibitors of HCMV replication (55). These compounds have a novel mechanism of action, which unlike the current therapies for HCMV infection, does not involve inhibition of DNA synthesis. The benzimidazole ribonucleosides prevent the cleavage of high-molecular-weight viral DNA concatemers to monomeric genomic lengths (57). Resistance to BDCRB has been mapped to the HCMV UL89 open reading frame (ORF), which, by analogy to gene gp17 from bacteriophage T4, may be a terminase (23, 57). Consequently, we have proposed that the benzimidazole ribonucleosides inhibit the product of this gene and that the UL89 gene product is involved in the viral DNA concatemer cleavage process (57). Open in a separate windowFIG. 1Structure of benzimidazole ribonucleosides. TCRB, R = Cl; BDCRB, R = Br.HCMV replication proceeds in a manner which is conserved among herpesviruses. The virally encoded DNA polymerase produces large, complex head-to-tail concatemers (10, 29, 33) which must be cleaved into genomic-length pieces before insertion into preformed capsids (59). With herpes simplex virus type 1 (HSV-1), temperature-sensitive mutants which are unable to cleave and package the concatemeric DNA have been derived (1, 2, 4, 45, 49, 50, 61). By this process, six HSV-1 genes have been found to be involved in concatemer cleavage and packaging. They are UL6, UL15, UL25, UL28, UL32, and UL33. In addition, recent studies in Homa’s laboratory have established that the product of UL25 is required for viral DNA encapsidation but not cleavage (39). Homologs of these genes exist in HCMV and are UL104, UL89, UL77, UL56, UL52, and UL51, respectively (18).In our continuing investigation of the mode of action of benzimidazole nucleosides, we report herein the independent isolation of HCMV strains resistant to TCRB, characterization of these strains, and identification of the mutations responsible for the development of resistance. The results demonstrate that the mechanism of action of the benzimidazole ribonucleosides is more complex than previously proposed and that a second gene product implicated in DNA cleavage and packaging is involved.     

Distinct Pathways for Tumor Necrosis Factor Alpha and Ceramides in Human Cytomegalovirus Infection

Human cytomegalovirus (HCMV) infection can be fatal to immunocompromised individuals. We have previously reported that gamma interferon and tumor necrosis factor alpha (TNF-α) synergistically inhibit HCMV replication in vitro. Ceramides have been described as second messengers induced by TNF-α. To investigate the mechanisms involved in the inhibition of HCMV by TNF-α, in the present study we have analyzed ceramide production by U373 MG astrocytoma cells and the effects of TNF-α versus ceramides on HCMV replication. Our results show that U373 MG cells did not produce ceramides upon incubation with TNF-α. Moreover, long-chain ceramides induced by treatment with exogenous bacterial sphingomyelinase inhibited HCMV replication in synergy with TNF-α. Surprisingly, short-chain permeant C6-ceramide increased viral replication. Our results show that the anti-HCMV activity of TNF-α is independent of ceramides. In addition, our results suggest that TNF-α and endogenous long-chain ceramides use separate pathways of cell signalling to inhibit HCMV replication, while permeant C6-ceramide appears to activate a third pathway leading to an opposite effect.Human cytomegalovirus (HCMV) infections are well controlled in the immunocompetent host. Cellular immune responses (CD4⁺ and CD8⁺ T cells and NK cells) which accompany both acute and latent infections (for a review, see reference 4) are thought to be the main components of this control. HCMV infection during immunosuppression such as in cancer, transplantations, or AIDS results in severe pathology (4). We have previously shown that tumor necrosis factor alpha (TNF-α), in synergy with gamma interferon (IFN-γ), inhibits the replication of HCMV (7). In mice, TNF-α is involved in the clearance of CMV infection (25). TNF-α is a cytokine with multiple effects which is produced by many cell types, including macrophages and CD8⁺ and CD4⁺ T lymphocytes (for a review, see reference 40), and is known to possess antiviral effects (20, 47). The molecular mechanisms involved in the signalling by TNF-α depend on the type of receptor, p55 (TNF-R1) or p75 (TNF-R2) (5), to which it binds. Some cells express only one type of TNF-α receptor; however, expression of these receptors is not always mutually exclusive (5). The cytotoxicity of TNF-α has been reported to be mediated by TNF-R1 (38), whose intracellular region carries a death domain which signals for programmed cell death (39). Signalling through TNF-R1 with specific antibodies can also protect Hep-G2 cells from vesicular stomatitis virus-mediated cytopathic effects (48). Ceramide production after TNF-α treatment has been widely reported (16, 19, 31) and has also been shown to depend on signalling through the TNF-R1 receptor (45). In these experiments concerning myeloid cells, TNF-α induced the activation of a sphingomyelinase, which cleaved sphingomyelin to release ceramide and phosphocholine. The production of ceramides can lead to cell apoptosis (11, 14, 23) or cell cycle arrest (13). Induction of apoptosis by TNF-α has been mimicked by exogenous sphingomyelinase and by synthetic, short-chain, permeant ceramides, which suggests that ceramides, as second messengers, are sufficient to induce the cytotoxic effects of TNF-α (11, 23). Acidic and neutral sphingomyelinases activated in different cell compartments may be responsible for the diverse effects of TNF-α (46), with the former being involved in signalling through NF-κB (34) and the latter being involved in signalling through a ceramide-activated protein kinase and phospholipase A₂ (46).One of the characteristics of HCMV infection is the increase in the content of intracellular DNA, reported to be of viral (3, 8, 18) or cellular (12, 37) origin. Since TNF-α has been known to display antiproliferative properties and to block cells in the G₁ phase (29), we initially tested its effects on the cell cycle of infected cells. Then, based on studies reporting that TNF-α induces ceramides in cells (16, 19, 31) and on a study showing the role of ceramide in cell cycle blockade (13), we originally postulated that ceramide was responsible for the antiviral effect of TNF-α. In the present study, we used astrocytoma cells (U373 MG) as a model for brain cells, which are important targets of HCMV in vivo (22). In contrast to fibroblasts, infected U373 MG cells release smaller quantities of virus particles even though all the cells were infected in our experiments. We believe that the U373 MG model is closer to HCMV infection in vivo. We show that ceramides are not produced by U373 MG cells upon incubation with even high concentrations of TNF-α. In addition, we demonstrate that exogenously added sphingomyelinase induces anti-HCMV effects whereas permeant C6-ceramide increases HCMV proliferation in U373 MG cells. This suggests that lipid second messengers can modulate HCMV infection and that TNF-α and ceramides use distinct signalling pathways in the control of HCMV infection. This is supported by our observation that the protein kinase JNK1 is activated exclusively by TNF-α in U373 MG cells and that TNF-α and exogenous sphingomyelinase act in synergy on HCMV infection.     

Two Regions of Simian Virus 40 T Antigen Determine Cooperativity of Double-Hexamer Assembly on the Viral Origin of DNA Replication and Promote Hexamer Interactions during Bidirectional Origin DNA Unwinding

Phosphorylation of simian virus 40 large tumor (T) antigen on threonine 124 is essential for viral DNA replication. A mutant T antigen (T124A), in which this threonine was replaced by alanine, has helicase activity, assembles double hexamers on viral-origin DNA, and locally distorts the origin DNA structure, but it cannot catalyze origin DNA unwinding. A class of T-antigen mutants with single-amino-acid substitutions in the DNA binding domain (class 4) has remarkably similar properties, although these proteins are phosphorylated on threonine 124, as we show here. By comparing the DNA binding properties of the T124A and class 4 mutant proteins with those of the wild type, we demonstrate that mutant double hexamers bind to viral origin DNA with reduced cooperativity. We report that T124A T-antigen subunits impair the ability of double hexamers containing the wild-type protein to unwind viral origin DNA, suggesting that interactions between hexamers are also required for unwinding. Moreover, the T124A and class 4 mutant T antigens display dominant-negative inhibition of the viral DNA replication activity of the wild-type protein. We propose that interactions between hexamers, mediated through the DNA binding domain and the N-terminal phosphorylated region of T antigen, play a role in double-hexamer assembly and origin DNA unwinding. We speculate that one surface of the DNA binding domain in each subunit of one hexamer may form a docking site that can interact with each subunit in the other hexamer, either directly with the N-terminal phosphorylated region or with another region that is regulated by phosphorylation.

The initiation of simian virus 40 (SV40) DNA replication by the viral T antigen is a complex series of events that begins when T antigen binds specifically to a palindromic arrangement of four GAGGC pentanucleotide sequences in the minimal origin of viral DNA replication (recently reviewed in references 1, 2, 3, 22, and 48). In the presence of Mg-ATP, T antigen assembles cooperatively on the two halves of the palindrome as a double hexamer (10, 11, 13, 24, 30, 38, 51, 53). The DNA conformation flanking the T-antigen binding sites is locally distorted upon hexamer assembly (reference 7 and references therein). One pair of pentanucleotides is sufficient to direct double-hexamer assembly and local distortion of the origin DNA but not to initiate DNA replication (25). ATP hydrolysis by T-antigen hexamers then catalyzes bidirectional unwinding of the parental DNA (reference 53 and references therein). A mutant origin with a single nucleotide insertion in the center of the palindromic T-antigen binding site prevents cooperative interactions between hexamers and cannot support bidirectional origin unwinding (8, 51), suggesting that both processes require interactions between T-antigen hexamers. After assembly of the two replication forks, bidirectional replication is carried out by 10 cellular proteins and T antigen, which remains at the forks as the only essential helicase (reviewed in references 3, 22, and 48).The phosphorylation state of SV40 T antigen governs its ability to initiate viral DNA replication (reviewed in references 15 to 17 and 39). T antigen contains two clusters of phosphorylation sites located at the N and C termini (40, 41). Phosphorylation of T antigen on threonine 124 in the N-terminal cluster was shown to be essential for viral DNA replication in monkey cells and in vitro (5, 14, 32–36, 44). Efforts to define what step in viral DNA replication requires modification of threonine 124 revealed that Mg-ATP-induced hexamer formation of T antigen in solution and DNA helicase activity of T antigen did not require phosphorylation at this site (33, 36). Origin DNA binding of T antigen lacking the modification at residue 124 was weaker than that of the modified T antigen (33, 34, 36, 44), but the reduction in binding was modest under the conditions used for SV40 DNA replication in vitro (36). Moreover, a mutant T antigen containing alanine in place of the phosphorylated threonine (T124A) assembled as a double hexamer on the viral origin and altered the conformation of the early palindrome and AT-rich sequences flanking the T-antigen binding sites in the viral origin in the same manner as the wild-type protein, except that higher concentrations were required (36). However, even at an elevated concentration, these mutant double hexamers were unable to unwind closed circular duplex DNA containing the viral origin (33, 36), suggesting that the defect in unwinding was responsible for the inability of T124A T antigen to replicate SV40 DNA. One possible explanation for the unwinding defect of the mutant T antigen, despite its helicase activity, was that some essential interaction between the two hexamers during bidirectional unwinding depended upon phosphorylation of threonine 124. Electron micrographs of SV40 DNA unwinding intermediates, which showed two single-stranded DNA loops protruding between two hexamers of T antigen, provided support for this explanation, implying that a double hexamer pulled the parental duplex DNA into the protein complex and spooled the single-stranded DNA out (53). Furthermore, double-hexamer formation significantly enhanced the helicase activity of T antigen (47, 47a).Most of the T antigen isolated from mammalian cells is in a hyperphosphorylated form, containing multiple phosphoserines, as well as two phosphothreonines, and supports SV40 DNA replication in vitro poorly but can be stimulated by treatment with alkaline phosphatase or protein phosphatase 2A (19, 28, 37, 42, 49, 50). Hyperphosphorylated T antigen is unable to unwind duplex closed circular duplex DNA harboring the viral origin (4, 6, 51). Dephosphorylation of serines 120 and 123 restores its ability to unwind origin DNA (14, 43, 51). Studies of double-hexamer assembly on the origin indicate that phosphorylation of T antigen on serines 120 and 123 also impairs the cooperativity of double-hexamer assembly (14, 51). These results demonstrate that hyperphosphorylation of T antigen interferes with interactions between hexamers that are required for origin unwinding and raise the question of whether the phosphorylation state of threonine 124 might also affect the cooperativity of double-hexamer assembly on the viral origin.One class of T antigen mutants with single-amino-acid substitutions in the DNA binding domain (class 4) has been reported to display properties similar to those of the T124A mutant and the hyperphosphorylated form of T antigen (54). Class 4 mutant proteins are defective in viral DNA replication in vivo and in vitro, bind to the viral origin as double hexamers and alter the local DNA conformation, and have helicase activity but do not unwind closed circular duplex viral DNA. The replication and unwinding defects could be due to faulty phosphorylation patterns or to other malfunctions not dependent on phosphorylation status.The work presented here was undertaken to reevaluate the assembly of wild-type and T124A T antigen on SV40 origin DNA by using more-sensitive quantitative assays and to compare them with the class 4 mutants. We report that cooperativity of T124A T antigen in double-hexamer assembly on the viral origin is impaired. The class 4 mutant T antigens were also found to have defects in cooperativity of double-hexamer assembly. T124A T antigen inhibited the ability of the wild-type protein to unwind closed circular duplex origin DNA. Both T124A and the class 4 mutants displayed dominant-negative phenotypes in viral DNA replication in vitro. Based on these observations, we propose that the N-terminal cluster of phosphorylation sites and the DNA binding domain mediate cooperative hexamer-hexamer interactions during assembly on the viral origin and speculate that these regions of T antigen may interact during origin DNA unwinding.     

Roles of Human AND-1 in Chromosome Transactions in S Phase

Coordinated execution of DNA replication, checkpoint activation, and postreplicative chromatid cohesion is intimately related to the replication fork machinery. Human AND-1/chromosome transmission fidelity 4 is localized adjacent to replication foci and is required for efficient DNA synthesis. In S phase, AND-1 is phosphorylated in response to replication arrest in a manner dependent on checkpoint kinase, ataxia telangiectasia-mutated, ataxia telangiectasia-mutated and Rad3-related protein, and Cdc7 kinase but not on Chk1. Depletion of AND-1 increases DNA damage, delays progression of S phase, leads to accumulation of late S and/or G₂ phase cells, and induces cell death in cancer cells. It also elevated UV-radioresistant DNA synthesis and caused premature recovery of replication after hydroxyurea arrest, indicating that lack of AND-1 compromises checkpoint activation. This may be partly due to the decreased levels of Chk1 protein in AND-1-depleted cells. Furthermore, AND-1 interacts with cohesin proteins Smc1, Smc3, and Rad21/Scc1, consistent with proposed roles of yeast counterparts of AND-1 in sister chromatid cohesion. Depletion of AND-1 leads to significant inhibition of homologous recombination repair of an I-SceI-driven double strand break. Based on these data, we propose that AND-1 coordinates multiple cellular events in S phase and G₂ phase, such as DNA replication, checkpoint activation, sister chromatid cohesion, and DNA damage repair, thus playing a pivotal role in maintenance of genome integrity.Replication fork is not only the site of DNA synthesis but also the center for coordinated execution of various chromosome transactions. The preparation for replication forks starts in the G₁ phase, when the prereplicative complex composed of origin recognition and minichromosome maintenance assembles on the chromosome. At the G₁-S boundary, Cdc45, GINS complex, and other factors join the prereplicative complex to generate a complex capable of initiating DNA replication. A series of phosphorylation events mediated by cyclin-dependent kinase and Cdc7 kinase play crucial roles in this process and facilitate the generation of active replication forks (1–6). Purification of the putative replisome complex in yeast indicated the presence of the checkpoint mediator Mrc1 and fork protection complex proteins Tof1 and Csm3 in the replication fork machinery (7), consistent with a previous report on the genome-wide analyses with chromatin immunoprecipitation analyses on chip (microarray) (8). Mcm10 is another factor present in the isolated complex, required for loading of replication protein A (RPA)² and primase-DNA polymerase α onto the replisome complex (7, 9, 10).Replication fork machinery can cope with various stresses, including shortage of the cellular nucleotide pool and replication fork blockages that interfere with its progression. Stalled replication forks activate checkpoint pathways, leading to cell cycle arrest, DNA repair, restart of DNA replication, or cell death in some cases (11–14). Single-stranded DNAs coated with RPA at the stalled replication forks are recognized by the ATR-ATR-interacting protein kinase complex and Rad17 for loading of the Rad9-Rad1-Hus1 checkpoint clamp (14–16). Factors present in the replisome complex are also known to be required for checkpoint activation. Claspin, Tim, and Tipin functionally and physically associate with sensor and effector kinases and serve as mediator/adaptors (17–23). Mcm7, a component of the replicative DNA helicase in eukaryotes, was reported to associate with the checkpoint clamp loader Rad17 (24) and to have a distinct function in checkpoint (24, 25). We recently reported that Cdc7 kinase, known to be required for DNA replication initiation, plays a role in activation of DNA replication checkpoint possibly through regulating Claspin phosphorylation (26). Thus, it appears that DNA replication and checkpoint activation functionally and physically interact with each other.Another crucial cellular event for maintenance of genome stability is sister chromatid cohesion. The cohesin complex, a conserved apparatus required for sister chromatid cohesion, contains Smc1, Smc3, and Rad21/Scc1/Mcd1 proteins. The assembled cohesin complexes are loaded onto chromatin prior to DNA replication in G₁ phase and link the sister chromosomes during S and G₂ phase until mitosis when they separate (27, 28). The mitotic cohesion defects are not rescued by supplementing cohesin in G₂ phase, and it has been suggested that establishment of sister chromatid cohesion is coupled with DNA replication (29, 30). Indeed, yeast mutants in some replisome components show defect in sister chromosome cohesion or undergo chromosome loss (31–33). Cdc7 kinase is also required for efficient mitotic chromosome cohesion (34, 35).Human AND-1 is the putative homolog of budding yeast CTF4/Pob1/CHL15 and fission yeast Mcl1/Slr3. The budding yeast counterpart was identified as a replisome component described above (7), which travels along with the replication fork (29). CTF4 is nonessential for viability, but its interactions with primase, Rad2 (FEN1 family of nuclease), and Dna2 have implicated CTF4 in lagging strand synthesis and/or Okazaki fragment processing (36–39). Yeast CTF4 and Mcl1 are involved in chromosome cohesion (33, 40, 41) and genetically interact with a cohesin, Mcd1/Rad21 (40, 42). Recently, it was reported that human AND-1 protein interacts with human primase-DNA polymerase α and Mcm10 and is required for DNA synthesis (43).Here we confirm that human AND-1 protein is required for DNA replication and efficient progression of S phase, and we further show that it facilitates replication checkpoint. Depletion of AND-1 causes accumulation of DNA damage and cell cycle arrest at late S to G₂ phase, ultimately leading to cell death. Furthermore, we also show that human AND-1 physically interacts with cohesin proteins Smc1, Smc3, Rad21/Scc1, suggesting a possibility that AND-1 may physically and functionally link replisome and cohesin complexes in vivo. Recent studies indicate that sister chromatid cohesion is required for recombinational DNA repair (44–47). Thus, we examined the requirement of AND-1 for repair of artificially induced double-stranded DNA breaks and showed that AND-1 depletion leads to significant reduction of the double strand break repair. Possible roles of AND-1 in coordination of various chromosome transactions at a replication fork and in maintenance of genome integrity during S phase will be discussed.     

Analysis of Free Energy Signals Arising from Nucleotide Hybridization Between rRNA and mRNA Sequences during Translation in Eubacteria

A decoding algorithm is tested that mechanistically models the progressive alignments that arise as the mRNA moves past the rRNA tail during translation elongation. Each of these alignments provides an opportunity for hybridization between the single-stranded, -terminal nucleotides of the 16S rRNA and the spatially accessible window of mRNA sequence, from which a free energy value can be calculated. Using this algorithm we show that a periodic, energetic pattern of frequency 1/3 is revealed. This periodic signal exists in the majority of coding regions of eubacterial genes, but not in the non-coding regions encoding the 16S and 23S rRNAs. Signal analysis reveals that the population of coding regions of each bacterial species has a mean phase that is correlated in a statistically significant way with species () content. These results suggest that the periodic signal could function as a synchronization signal for the maintenance of reading frame and that codon usage provides a mechanism for manipulation of signal phase.[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32]