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.     

Reconstitution of Uracil DNA Glycosylase-initiated Base Excision Repair in Herpes Simplex Virus-1

Herpes simplex virus-1 is a large double-stranded DNA virus that is self-sufficient in a number of genome transactions. Hence, the virus encodes its own DNA replication apparatus and is capable of mediating recombination reactions. We recently reported that the catalytic subunit of the HSV-1 DNA polymerase (UL30) exhibits apurinic/apyrimidinic and 5′-deoxyribose phosphate lyase activities that are integral to base excision repair. Base excision repair is required to maintain genome stability as a means to counter the accumulation of unusual bases and to protect from the loss of DNA bases. Here we have reconstituted a system with purified HSV-1 and human proteins that perform all the steps of uracil DNA glycosylase-initiated base excision repair. In this system nucleotide incorporation is dependent on the HSV-1 uracil DNA glycosylase (UL2), human AP endonuclease, and the HSV-1 DNA polymerase. Completion of base excision repair can be mediated by T4 DNA ligase as well as human DNA ligase I or ligase IIIα-XRCC1 complex. Of these, ligase IIIα-XRCC1 is the most efficient. Moreover, ligase IIIα-XRCC1 confers specificity onto the reaction in as much as it allows ligation to occur in the presence of the HSV-1 DNA polymerase processivity factor (UL42) and prevents base excision repair from occurring with heterologous DNA polymerases. Completion of base excision repair in this system is also dependent on the incorporation of the correct nucleotide. These findings demonstrate that the HSV-1 proteins in combination with cellular factors that are not encoded by the virus are capable of performing base excision repair. These results have implications on the role of base excision repair in viral genome maintenance during lytic replication and reactivation from latency.Herpes simplex virus-1 (HSV-1)² is a large double-stranded DNA virus with a genome of ∼152 kilobase pairs (for reviews, see Refs. 1 and 2). HSV-1 switches between lytic replication in epithelial cells and a state of latency in sensory neurons during which there is no detectable DNA replication (1). Viral DNA replication is mediated by seven essential virus-encoded factors (3–5). Of these, two encode subunits of the viral replicase (for review, see Refs. 6 and 7). The catalytic subunit (UL30) exhibits DNA polymerase (Pol), 3′-5′ proofreading exonuclease, and RNase H activities (8–11). UL30 exists as a heterodimer with the UL42 protein that confers a high degree of processivity on the Pol (11–17).Viral DNA replication is accompanied by vigorous recombination that leads to the formation of large networks of viral DNA replication intermediates (18). The HSV-1 single-strand DNA-binding protein (ICP8) has been shown to play a major role in mediating these recombination reactions (19–21). One role for the high frequency of recombination is to restart DNA replication at sites of fork collapse. Further mechanisms that contribute to genome maintenance are processes that survey and repair damage to the DNA to ensure the availability of a robust replication template. In this regard base excision repair (BER) is essential to remove unusual bases from the DNA and to repair apurinic/apyrimidinic (AP) sites resulting from spontaneous base loss (for review, see Ref. 22). With respect to HSV-1, a recent study showed that viral DNA from infected cultured fibroblasts contains a steady state of 2.8–5.9 AP sites per viral genome equivalent (23). Because AP sites are non-instructional, the failure to repair such sites would terminate viral replication. Indeed, UL30 cannot replicate beyond a model AP site (tetrahydrofuran residue) (23), indicating that the virus must enable a process to repair such lesions. In this regard HSV-1 possesses several enzymes that would safeguard from the accumulation of unusual bases, specifically uracil, and base loss. Hence, HSV-1 encodes a uracil DNA glycosylase (UDG) (UL2) as well as a dUTPase to reduce the pool of dUTP and prevent misincorporation by the viral Pol (24, 25). Moreover, we recently showed that the catalytic subunit of the viral Pol (UL30) exhibits AP and 5′-deoxyribose phosphate (dRP) lyase activities (26). The presence of a virus-encoded UDG and DNA lyase indicates that HSV-1 has the capacity to perform integral steps of BER, specifically for the removal of uracil. Indeed, the excision of uracil may be important for viral replication. Hence, it has been shown that uracil substitutions in the viral origins of replication alters their recognition by the viral initiator protein (27). Moreover, whereas UL2 may be dispensable for viral replication in fibroblast (24), UL2 mutants exhibit reduced neurovirulence and a decreased frequency of reactivation from latency (28). Thus, UDG action in HSV-1 may be important for viral reactivation after quiescence in neuronal cells during which the genome may accumulate uracil as a result of spontaneous deamination of cytosine. In another herpesvirus, cytomegalovirus, the viral UDG was shown to be required for the transition to late-phase DNA replication (29, 30). Consequently, it is possible that BER plays a significant role in various aspects of the herpesvirus life cycle.In mammalian single-nucleotide BER initiated by monofunctional DNA glycosylases, the resulting AP sites are incised hydrolytically at the 5′ side by AP endonuclease (APE), generating a 3′-OH. This is followed by template-directed incorporation of one nucleotide by Pol β to generate a 5′-dRP flap (22, 31, 32). The 5′-dRP residue is subsequently removed by the 5′-dRP lyase activity of Pol β to leave a nick with a 3′-OH and 5′-phosphate that is ligated by DNA ligase I or the physiologically more relevant ligase IIIα-XRCC1 complex (for review, see Refs. 33 and 34). Here we show that the HSV-1 UDG (UL2) and Pol (UL30) cooperate with human APE and human ligase IIIα-XRCC1 complex to perform BER in vitro. This finding has implications on the role of BER in viral genome maintenance during lytic replication and in the emergence of the virus from neuronal latency.     

In Vitro and In Vivo Biology of Recombinant Adenovirus Vectors with E1, E1/E2A,or E1/E4 Deleted

Isogenic, E3-deleted adenovirus vectors defective in E1, E1 and E2A, or E1 and E4 were generated in complementation cell lines expressing E1, E1 and E2A, or E1 and E4 and characterized in vitro and in vivo. In the absence of complementation, deletion of both E1 and E2A completely abolished expression of early and late viral genes, while deletion of E1 and E4 impaired expression of viral genes, although at a lower level than the E1/E2A deletion. The in vivo persistence of these three types of vectors was monitored in selected strains of mice with viral genomes devoid of transgenes to exclude any interference by immunogenic transgene-encoded products. Our studies showed no significant differences among the vectors in the short-term maintenance and long-term (4-month) persistence of viral DNA in liver and lung cells of immunocompetent and immunodeficient mice. Furthermore, all vectors induced similar antibody responses and comparable levels of adenovirus-specific cytotoxic T lymphocytes. These results suggest that in the absence of transgenes, the progressive deletion of the adenovirus genome does not extend the in vivo persistence of the transduced cells and does not reduce the antivirus immune response. In addition, our data confirm that, in the absence of transgene expression, mouse cellular immunity to viral antigens plays a minor role in the progressive elimination of the virus genome.Replication-deficient human adenoviruses (Ad) have been widely investigated as ex vivo and in vivo gene delivery systems for human gene therapy. The ability of these vectors to mediate the efficient expression of candidate therapeutic or vaccine genes in a variety of cell types, including postmitotic cells, is considered an advantage over other gene transfer vectors (3, 28, 49). However, the successful application of currently available E1-defective Ad vectors in human gene therapy has been hampered by the fact that transgene expression is only transient in vivo (2, 15, 16, 33, 36, 46). This short-lived in vivo expression of the transgene has been explained, at least in part, by the induction in vivo of cytotoxic immune responses to cells infected with the Ad vector. Studies with rodent systems have suggested that cytotoxic T lymphocytes (CTLs) directed against virus antigens synthesized de novo in the transduced tissues play a major role in eliminating cells containing the E1-deleted viral genome (56–58, 61). Consistent with the concept of cellular antiviral immunity, expression of transgenes is significantly extended in experimental rodent systems that are deficient in various components of the cellular immune system or that have been rendered immunocompromised by administration of pharmacological agents (2, 33, 37, 48, 60, 64).Based on the assumption that further reduction of viral antigen expression may lower the immune response and thus extend persistence of transgene expression, previous studies have investigated the consequences of deleting both E1 and an additional viral regulatory region, such as E2A or E4. The E2A region encodes a DNA binding protein (DBP) with specific affinity for single-stranded Ad DNA. The DNA binding function is essential for the initiation and elongation of viral DNA synthesis during the early phase of Ad infection. During the late phase of infection, DBP plays a central role in the activation of the major late promoter (MLP) (for a recent review, see reference 44). The E4 region, located at the right end of the viral genome, encodes several regulatory proteins with pleiotropic functions which are involved in the accumulation, splicing, and transport of early and late viral mRNAs, in DNA replication, and in virus particle assembly (reviewed in reference 44). The simultaneous deletion of E1 and E2A or of E1 and E4 should therefore further reduce the replication of the virus genome and the expression of early and late viral genes. Such multidefective vectors have been generated and tested in vitro and in vivo (9, 12, 17, 19–21, 23, 24, 26, 34, 40, 52, 53, 59, 62, 63). Recombinant vectors with E1 deleted and carrying an E2A temperature-sensitive mutation (E2Ats) have been shown in vitro to express much smaller amounts of virus proteins, leading to extended transgene expression in cotton rats and mice (19, 20, 24, 59). To eliminate the risks of reversion of the E2Ats point mutation to a wild-type phenotype, improved vectors with both E1 and E2A deleted were subsequently generated in complementation cell lines coexpressing E1 and E2A genes (26, 40, 63). In vitro analysis of human cells infected by these viruses demonstrated that the double deletion completely abolished viral DNA replication and late protein synthesis (26). Similarly, E1/E4-deleted vectors have been generated in various in vitro complementation systems and tested in vitro and in vivo (9, 17, 23, 45, 52, 53, 62). These studies showed that deletion of both E1 and E4 did indeed reduce significantly the expression of early and late virus proteins (17, 23), leading to a decreased anti-Ad host immune response (23), reduced hepatotoxicity (17, 23, 52), and improved in vivo persistence of the transduced liver cells (17, 23, 52).Interpretation of these results is difficult, however, since all tested E1- and E1/E4-deleted vectors encoded the bacterial β-galactosidase (βgal) marker, whose strong immunogenicity is known to influence the in vivo persistence of Ad-transduced cells (32, 37). Moreover, the results described above are not consistent with the conclusions from other studies showing, in various immunocompetent mouse models, that cellular immunity to Ad antigens has no detectable impact on the persistence of the transduced cells (37, 40, 50, 51). Furthermore, in contrast to results of earlier studies (19, 20, 59), Fang et al. (21) demonstrated that injection of E1-deleted/E2Ats vectors into immunocompetent mice and hemophilia B dogs did not lead to an improvement of the persistence of transgene expression compared to that with isogenic E1-deleted vectors. Similarly, Morral et al. (40) did not observe any difference in persistence of transgene expression in mice injected with either vectors deleted in E1 only or vectors deleted in both E1 and E2A. Finally, the demonstration that some E4-encoded products can modulate transgene expression (1, 17, 36a) makes the evaluation of E1- and E1/E4-deleted vectors even more complex when persistence of transgene expression is used for direct comparison of the in vivo persistence of cells transduced by the two types of vectors.The precise influence of the host immune response to viral antigens on the in vivo persistence of the transduced cells, and hence the impact of further deletions in the virus genome, therefore still remains unclear. To investigate these questions, we generated a set of isogenic vectors with single deletions (AdE1°) and double deletions (AdE1°E2A° and AdE1°E4°) and their corresponding complementation cell lines and compared the biologies and immunogenicities of these vectors in vitro and in vivo. To eliminate any possible influence of transgene-encoded products on the interpretation of the in vivo results, we used E1-, E1/E2A-, and E1/E4-deleted vectors with no transgenes.