Adenovirus DNA synthesis in vitro in an isolated complex.

DNA-protein complexes isolated from adenovirus-infected cells by a modification of the M-band technique were used as an in vitro system for the study of adenovirus DNA replication. The synthesis in vitro was semiconservative, inhibited by N-ethylmaleimide, and stimulated by ATP. Studies on DNA-negative mutants of adenovirus showed that the DNA synthesis in vitro represents a continuation of adenovirus DNA replication in vivo. DNA synthesis in vitro was inhibited 38% by 20 microgram of phosphonoacetic acid per ml, which is several-fold higher than the inhibition obtained with purified DNA polymerase beta or gamma, but was similar to the degree of inhibition of DNA polymerase alpha. DNA synthesis in complexes from uninfected cells was much less sensitive to inhibition by phosphonoacetic acid. In addition, complexes from infected cells contained a greater proportion of the alpha-polymerase than complexes from uninfected cells, suggesting that an association of alpha-polymerase with the replication complex may be occurring during adenovirus infection, with subsequent utilization of the alpha-polymerase for viral DNA synthesis.     

Improved Production of Gutted Adenovirus in Cells Expressing Adenovirus Preterminal Protein and DNA Polymerase

Production of gutted, or helper-dependent, adenovirus vectors by current methods is inefficient. Typically, a plasmid form of the gutted genome is transfected with helper viral DNA into 293 cells; the resulting lysate is serially passaged to increase the titer of gutted virions. Inefficient production of gutted virus particles after cotransfection is likely due to suboptimal association of replication factors with the abnormal origins found in these plasmid substrates. To test this hypothesis, we explored whether gutted virus production would be facilitated by transfection into cells expressing various viral replication factors. We observed that C7 cells, coexpressing adenoviral DNA polymerase and preterminal protein, converted plasmid DNA into replicating virus approximately 50 times more efficiently than did 293 cells. This property of C7 cells can be used to greatly increase the efficiency of gutted virus production after cotransfection of gutted and helper viral DNA. These cells should also be useful for generation of recombinant adenovirus from any plasmid-based precursor.     

Postinternalization inhibition of adenovirus gene expression and infectious virus production in human T-cell lines

Detection of adenovirus DNA in human tonsillar T cells in the absence of active virus replication suggests that T cells may be a site of latency or of attenuated virus replication in persistently infected individuals. The lytic replication cycle of Ad5 in permissive epithelial cells (A549) was compared to the behavior of Ad5 in four human T-cell lines, Jurkat, HuT78, CEM, and KE37. All four T-cell lines expressed the integrin coreceptors for Ad2 and Ad5, but only Jurkat and HuT78 express detectable surface levels of the coxsackie adenovirus receptor (CAR). Jurkat and HuT78 cells supported full lytic replication of Ad5, albeit at a level approximately 10% of that of A549, while CAR-transduced CEM and KE37 cells (CEM-CARhi and KE37-CARhi, respectively) produced no detectable virus following infection. All four T-cell lines bind and internalize fluorescently labeled virus. In A549, Jurkat, and HuT78 cells, viral proteins were detected in 95% of cells. In contrast, only a small subpopulation of CEM-CARhi and KE37-CARhi cells contained detectable viral proteins. Interestingly, Jurkat and HuT78 cells synthesize four to six times more copies of viral DNA per cell than did A549 cells, indicating that these cells produce infectious virions with much lower efficiency than A549. Similarly, CEM-CARhi and KE37-CARhi cells, which produce no detectable infectious virus, synthesize three times more viral genomes per cell than A549. The observed blocks to adenovirus gene expression and replication in all four human T-cell lines may contribute to the maintenance of naturally occurring persistent adenovirus infections in human T cells.     

Adenovirus early region 1A modulation of interferon antiviral activity.

Human adenovirus type 5 (Ad5) is a DNA virus which replicates as efficiently in human A549 cells treated with human interferon-alpha 2 (IFN) as in untreated cells. Vesicular stomatitis virus (VSV), on the other hand, is a negative-strand RNA virus which is very sensitive to the effects of IFN treatment in A549 cells. The IFN-mediated inhibition of VSV replication was not observed in cells coinfected with Ad5. Abrogation of IFN-mediated antiviral activity was maximal when Ad5 infection preceded VSV infection by at least 36 h, but did not require adenovirus DNA synthesis for manifestation. Coinfection experiments with VSV and deletion variants of adenovirus demonstrated that neither virus-associated RNA synthesis nor expression of adenovirus early regions E1B, E2A, E3, or E4 are required for abrogation of IFN-mediated inhibition of VSV replication. However, expression of early region E1A was essential, suggesting that E1A products can modulate, either directly or indirectly, IFN activity in adenovirus-infected cells.     

Studies of the identity of the unknown in protein hydrolysates

DNA synthesis in the adenovirus DNA replication complex, containing host DNA polymerases-α and -γ, was inhibited completely by aphidicolin and by 2′,3′-dideoxythymidine triphosphate (ddTTP). Double reciprocal plots of DNA polymerase activity in the replication complex against each dNTP gave a straight line although the complex contained two species of DNA polymerase. Inhibition by aphidicolin of DNA polymerase activity was competitive with dTTP but that of purified DNA polymerase-α isolated from adenovirus infected KB cells was competitive with dCTP. The above results suggest that DNA polymerases-α and -γ are integrated in the replication complex to behave as a single enzyme.     

Temperature-Sensitive Mutants of Adenovirus Type 12 Defective in Viral DNA Synthesis

Ten temperature-sensitive (ts) mutants of adenovirus type 12 which produce plaques at 31 but not at 38.5 C have been isolated after mutagenesis with nitrosoguanidine or nitrous acid. The mutants have been classified into six separate complementation groups. DNA-DNA hybridizations have shown that at 38.5 C the ts 401 and 406 mutants of groups B and E, respectively, synthesized less than 10% of the normal level of viral DNA. The two mutants were also defective in the production of late proteins at the nonpermissive temperature, as shown by fluorescent-antibody tests and analysis by sodium dodecyl sulfatepolyacrylamide gel electrophoresis. Genetic recombination between the ts viruses 401 and 406 has been demonstrated; the recombination frequency for the wild-type virus production was 17.7%. Both mutants induced an increase in thymidine kinase activity at 38.5 C. Moreover, the two viral DNA-defective mutants shut off host DNA synthesis at the restrictive temperature. It is striking that at 38.5 C ts virus 401 transformed two to eight times more hamster cells than the wild-type virus, whereas ts virus 406 transformed at a frequency similar to the wild-type virus.     

Adenovirus type 12 E1B 19-kilodalton protein is not required for oncogenic transformation in rats.

The adenovirus type 12 mutants in700 and pm700 carry site-specific mutations within the reading frame encoding the E1B 19-kilodalton protein (19K protein) which prevent the production of the intact 19K protein. In cultures of human A549 cells, these mutants grow just as well as the wild-type virus does, but they display a large-plaque (lp), cytocidal (cyt) phenotype. DNA in these infected cells is not degraded, but at late times in human KB cells infected by the mutants, the mutants display a DNA degradation (deg) phenotype. The transformation phenotype of these mutants is also host range. Although the mutants are defective for transformation of the 3Y1 rat cell line, they transform rat and mouse primary kidney cells in vitro at wild-type efficiency and are capable of inducing tumors in rats. These results support the view that the type 12 E1B 19K protein is not obligatory for oncogenic transformation.     

Effects of Adenovirus Type 5 E1A Isoforms on Viral Replication in Arrested Human Cells

Human adenovirus has evolved to infect and replicate in terminally differentiated human epithelial cells, predominantly those within the airway, the gut, or the eye. To overcome the block to viral DNA replication present in these cells, the virus expresses the Early 1A proteins (E1A). These immediate early proteins drive cells into S-phase and induce expression of all other viral early genes. During infection, several E1A isoforms are expressed with proteins of 289, 243, 217, 171, and 55 residues being present for human adenovirus type 5. Here we examine the contribution that the two largest E1A isoforms make to the viral life cycle in growth-arrested normal human fibroblasts. Viruses that express E1A289R were found to replicate better than those that do not express this isoform. Importantly, induction of several viral genes was delayed in a virus expressing E1A243R, with several viral structural proteins undetectable by western blot. We also highlight the changes in E1A isoforms detected during the course of viral infection. Furthermore, we show that viral DNA replication occurs more efficiently, leading to higher number of viral genomes in cells infected with viruses that express E1A289R. Finally, induction of S-phase specific genes differs between viruses expressing different E1A isoforms, with those having E1A289R leading to, generally, earlier activation of these genes. Overall, we provide an overview of adenovirus replication using modern molecular biology approaches and further insights into the contribution that E1A isoforms make to the life cycle of human adenovirus in arrested human fibroblasts.     

Adenovirus DNA polymerase: domain organisation and interaction with preterminal protein.

Adenovirus DNA polymerase is one of three viral proteins and two cellular proteins required for replication of the adenovirus genome. During initiation of viral DNA synthesis the viral DNA polymerase transfers dCMP onto the adenovirus preterminal protein, to which it is tightly bound. The domain structure of the 140 kDa DNA polymerase has been probed by partial proteolysis and the sites of proteolytic cleavage determined by N-terminal sequencing. At least four domains can be recognised within the DNA polymerase. Adenovirus preterminal protein interacts with three of the four proteolytically derived domains. This was confirmed by cloning and expression of each of the individual domains. These data indicate that, like other members of the pol alpha family of DNA polymerases, the adenovirus DNA polymerase has a multidomain structure and that interaction with preterminal protein takes place with non-contiguous regions of the polypeptide chain over a large surface area of the viral DNA polymerase.     

Replication properties of human adenovirus in vivo and in cultures of primary cells from different animal species

Oncolytic adenoviruses have emerged as a promising approach for the treatment of tumors resistant to other treatment modalities. However, preclinical safety studies are hampered by the lack of a permissive nonhuman host. Screening of a panel of primary cell cultures from seven different animal species revealed that porcine cells support productive replication of human adenovirus type 5 (Ad5) nearly as efficiently as human A549 cells, while release of infectious virus by cells from other animal species tested was diminished by several orders of magnitude. Restriction of productive Ad5 replication in rodent and rabbit cells seems to act primarily at a postentry step. Replication efficiency of adenoviral vectors harboring different E1 deletions or mutations in porcine cells was similar to that in A549 cells. Side-by-side comparison of the viral load kinetics in blood of swine and mice injected with Ad5 or a replication-deficient adenoviral vector failed to provide clear evidence for virus replication in mice. In contrast, evidence suggests that adenovirus replication occurs in swine, since adenoviral late gene expression produced a 13.5-fold increase in viral load in an individual swine from day 3 to day 7 and 100-fold increase in viral DNA levels in the Ad5-infected swine compared to the animal receiving a replication-deficient adenovirus. Lung histology of Ad5-infected swine revealed a severe interstitial pneumonia. Although the results in swine are based on a small number of animals and need to be confirmed, our data strongly suggest that infection of swine with human adenovirus or oncolytic adenoviral vectors is a more appropriate animal model to study adenoviral pathogenicity or pharmacodynamic and toxicity profiles of adenoviral vectors than infection of mice.     

Involvement of eucaryotic deoxyribonucleic acid polymerases alpha and gamma in the replication of cellular and viral deoxyribonucleic acid.

In an effort to identify the deoxyribonucleic acid (DNA) polymerase activities responsible for mammalian viral and cellular DNA replication, the effect of DNA synthesis inhibitors on isolated DNA polymerases was compared with their effects on viral and cellular DNA replication in vitro. DNA polymerase alpha, simian virus 40 (SV40) DNA replication in nuclear extracts, and CV-1 cell (the host for SV40) DNA replication in isolated nuclei all responded to DNA synthesis inhibitors in a quantitatively similar manner: they were relatively insensitive to 2',3'-dideoxythymidine 5'-triphosphate (d2TTP), but completely inhibited by aphidicolin, 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (araCTP), and N-ethylmaleimide. In comparison, DNA polymerases beta and gamma were inhibited by d2TTP but insensitive to aphidicolin and 20--30 times less sensitive to araCTP than DNA polymerase alpha. Herpes simplex virus type 1 (HSV-1) DNA polymerase and DNA polymerase alpha were the only enzymes tested that were relatively insensitive to d2TTP; DNA polymerases beta and gamma, phage T4 and T7 DNA polymerases, and Escherichia coli DNA polymerase I were 100--250 times more sensitive. The results with d2TTP were independent of enzyme concentration, primer-template concentration, primer-template choice, and the labeled dNTP. A specific requirement for DNA polymerase alpha in the replication of SV40 DNA was demonstrated by the fact that DNA polymerase alpha was required, in addition to other cytosol proteins, to reconstitute SV40 DNA replication activity in N-ethylmaleimide-inactivated nuclear extracts containing replicating SV40 chromosomes. DNA polymerases beta and gamma did not substitute for DNA polymerase alpha. In contrast to SV40 and CV-1 DNA replication, adenovirus type 2 (Ad-2) DNA replication in isolated nuclei was inhibited by d2TTP to the same extent as gamma-polymerase. Ad-2 DNA replication was also inhibited by aphidicolin to the same extent as alpha-polymerase. Synthesis of CV-1 DNA, SV40 DNA, and HSV-1 DNA in intact CV-1 cells was inhibited by aphidicolin. Ad-2 DNA replication was also inhibited, but only at a 100-fold higher concentration. We found no effect of 2'-3'-dideoxythymidine (d2Thd) on cellular or viral DNA replication in spite of the fact that Ad-2 DNA replication in isolated nuclei was inhibited 50% by a ratio of d2TTP/dTTP of 0.02. This was due to the inability of CV-1 and Hela cells to phosphorylate d2Thd to d2TTP. These data are consistent with the hypothesis that DNA polymerase alpha is the only DNA polymerase involved in replicating SV40 DNA and CV-1 DNA and that Ad-2 DNA replication involves both DNA polymerases gamma and alpha.     

Development of a Serum-free Suspension Process for the Production of a Conditionally Replicating Adenovirus using A549 Cells

Conditionally replicating adenoviruses (CRAVs) are a group of recombinant human adenoviruses genetically engineered to replicate in selected tissues, such as tumors. These viruses could potentially offer significant medicinal benefits, since the restrictive replication of these viral vectors leads to the lysis of target cells without harm to the surrounding tissues. The in vitro propagation and amplification of the CRAV vectors often requires special host cells with deregulated growth control pathways. In order to develop an efficient cell culture process for the scaleable production of a CRAV vector, A549 cells, a human lung carcinoma cell line normally cultured in adherent culture, were adapted to suspension culture. CRAV production was demonstrated with the suspension-adapted A549 cells and a baseline production process was developed in shake flasks. The ability to scale-up virus production was confirmed in stirred tank bioreactors. Molecular characterization of the suspension-adapted A549 cells indicates no significant changes in cellular mechanisms related to adenovirus infection.     

Macromolecular Content of Inclusions Produced by a Canine Adenovirus

Early inclusions induced by a canine adenovirus in a canine cell line, appearing before the formation of infectious virus particles, were purified by differential centrifugation in sucrose followed by CsCl density gradient centrifugation. Chemical analysis of these inclusions revealed that they contained deoxyribonucleic acid (DNA), ribonucleic acid, and protein. On the basis of density gradient centrifugation, the DNA extracted from the inclusions was found to be viral DNA. Electron microscope autoradiography showed that these inclusions were the sites of DNA synthesis. In addition, association of DNA polymerase activity with the inclusions was detected by incorporation of radioactivity from (3)H-thymidine triphosphate into a DNA product. The in vitro product of the enzyme had a density equal to that of viral DNA rather than host DNA. The level of DNA polymerase activity in exponentially growing infected and uninfected whole cells was similar, but in cells in stationary phase the enzyme activity of infected cells was twice that in noninfected cells. Furthermore, nuclei isolated from infected cells showed a fourfold increase in DNA polymerase activity over the noninfected cells.