Human cytomegalovirus encodes a protein kinase (UL97) that confers sensitivity to ganciclovir by phosphorylating it to the monophosphate. The function of this unusual kinase in viral replication is unknown. We constructed two independent isolates of a recombinant virus, RCΔ97, that contain large deletions in this gene and carry a 4.8-kb insertion containing a selectable genetic marker. These mutant viruses were isolated by using a population of primary cells (HEL97) that express this gene from integrated copies of a defective retroviral vector. The recombinant viruses were severely impaired in their ability to replicate in primary fibroblasts, attaining virus titers that were 2 to 3 orders of magnitude lower than those produced by the parent virus. Despite the severe replication deficit, both of these viruses retained the ability to form small, slowly growing plaques in primary fibroblasts, demonstrating that UL97 is not absolutely essential for replication in cell culture. The replication deficit was relieved when UL97 was provided in trans in the complementing cell line, showing that the phenotype was due to a deficiency in UL97. Thus, theUL97 gene product plays a very important role in viral replication in tissue culture and may be a good target for antiviral chemotherapy.
To investigate how acyclovir-resistant (ACVr) herpes simplex virus (HSV) evades drug therapy and causes disease, HSV-1 isolates from a bone marrow transplant (BMT) patient were studied. The patient developed ACVr disease after an initial BMT and, following a second BMT, reactivated ACVr HSV despite high-dose acyclovir prophylaxis. ACVr isolates from each episode contained the same point mutation in the viral thymidine kinase (tk) gene, documenting the emergence, latency, and reactivation of this mutant. The mutants were exceedingly impaired for TK activity in sensitive enzyme, plaque autoradiography, and drug-susceptibility assays. Nevertheless, these mutants and a tk deletion mutant constructed in the same genetic background reactivated from latency in mouse trigeminal ganglia, in contrast to similar mutants from laboratory strains. It is hypothesized that alleles in the clinical isolate compensate for the loss of TK in this animal model. Such genetic variability may be important for ACVr disease in humans.
A human cytomegalovirus mutant that was isolated for resistance (10-fold) to the antisense oligonucleotide fomivirsen (ISIS 2922) exhibited cross-resistance to a modified derivative of fomivirsen with an identical base sequence but little or no resistance to an oligonucleotide with an unrelated sequence. No changes in the mutant’s DNA corresponding to the fomivirsen target sequence were found.
We have investigated the antiviral mechanism of a phosphorothioate oligonucleotide, ISIS 5652, which has activity against herpes simplex virus (HSV) in the low micromolar range in plaque reduction assays. We isolated a mutant that is resistant to this compound. Marker rescue and sequencing experiments showed that resistance was due to at least one of three mutations in the UL27 gene which result in amino acid changes in glycoprotein B (gB). Because gB has a role in attachment and entry of HSV, we tested the effects of ISIS 5652 at these stages of infection. The oligonucleotide potently inhibited attachment of virus to cells at 4°C; however, the resistant mutant did not exhibit resistance at this stage. Moreover, a different oligonucleotide with little activity in plaque reduction assays was as potent as ISIS 5652 in inhibiting attachment. Similarly, ISIS 5652 was able to inhibit entry of preattached virions into cells at 37°C, but the mutant did not exhibit resistance in this assay. The mutant did not attach to or enter cells more quickly than did wild-type virus. Strikingly, incubation of wild-type virus with 1 to 2 M ISIS 5652 at 37°C led to a time-dependent, irreversible loss of infectivity (virucidal activity). No virucidal activity was detected at 4°C or with an unrelated oligonucleotide at 37°C. The resistant mutant and a marker-rescued derivative containing its gB mutations exhibited substantial resistance to this virucidal activity of ISIS 5652. We hypothesize that the GT-rich oligonucleotide induces a conformational change in gB that results in inactivation of infectivity.Oligonucleotides hold considerable promise for treating viral infections. Although much recent attention has focused on small interfering RNAs, the majority of oligonucleotides that have been studied as antiviral agents to date are modified oligodeoxynucleotides (ODNs) designed to work via an antisense mechanism, such as the licensed anticytomegalovirus drug, fomivirsen (2, 3). However, other ODNs with antiviral activity are not complementary to viral nucleic acid (13,31,35). These ODNs are GT rich and have the propensity to form G-quartet structures stabilized by non-Watson-Crick guanineguanine base pairs (reviewed in references 26 and 33). Certain of these GT-rich ODNs have anti-human immunodeficiency virus (HIV) activity and, evidently, target the HIV envelope protein gp120 (12,35). Others have been reported to exhibit activity against herpes simplex virus (HSV), but their mechanism(s) of action are not known (13).HSV most commonly causes genital herpes, cold sores, and corneal keratitis and can cause more severe disease, particularly in the immunocompromised (reviewed in reference 32). The virion consists of an icosahedral nucleocapsid containing the ϳ150-kbp double-stranded DNA genome, surrounded by a less-ordered layer of proteins called the tegument and a lipid bilayer envelope that contains a number of virus-encoded glycoproteins (reviewed in reference 25). The replication cycle of HSV begins with the initial attachment of viru...
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