Viral transcription in KB cells infected by temperature-sensitive "early" mutants of adenovirus type 5

Novel viral splicing events and open reading frames revealed by long-read direct RNA sequencing of adenovirus transcripts

Adenovirus is a common human pathogen that relies on host cell processes for transcription and processing of viral RNA and protein production. Although adenoviral promoters, splice junctions, and polyadenylation sites have been characterized using low-throughput biochemical techniques or short read cDNA-based sequencing, these technologies do not fully capture the complexity of the adenoviral transcriptome. By combining Illumina short-read and nanopore long-read direct RNA sequencing approaches, we mapped transcription start sites and RNA cleavage and polyadenylation sites across the adenovirus genome. In addition to confirming the known canonical viral early and late RNA cassettes, our analysis of splice junctions within long RNA reads revealed an additional 35 novel viral transcripts that meet stringent criteria for expression. These RNAs include fourteen new splice junctions which lead to expression of canonical open reading frames (ORFs), six novel ORF-containing transcripts, and 15 transcripts encoding for messages that could alter protein functions through truncation or fusion of canonical ORFs. In addition, we detect RNAs that bypass canonical cleavage sites and generate potential chimeric proteins by linking distinct gene transcription units. Among these chimeric proteins we detected an evolutionarily conserved protein containing the N-terminus of E4orf6 fused to the downstream DBP/E2A ORF. Loss of this novel protein, E4orf6/DBP, was associated with aberrant viral replication center morphology and poor viral spread. Our work highlights how long-read sequencing technologies combined with mass spectrometry can reveal further complexity within viral transcriptomes and resulting proteomes.

Viral and cellular interactions during adenovirus DNA replication

Adenoviruses represent ubiquitous and clinically significant human pathogens, gene-delivery vectors, and oncolytic agents. The study of adenovirus-infected cells has long been used as an excellent model to investigate fundamental aspects of both DNA virus infection and cellular biology. While many key details supporting a well-established model of adenovirus replication have been elucidated over a period spanning several decades, more recent findings suggest that we have only started to appreciate the complex interplay between viral genome replication and cellular processes. Here, we present a concise overview of adenovirus DNA replication, including the biochemical process of replication, the spatial organization of replication within the host cell nucleus, and insights into the complex plethora of virus-host interactions that influence viral genome replication. Finally, we identify emerging areas of research relating to the replication of adenovirus genomes.

The structure and function of the adenovirus major late promoter

The adenovirus major late promoter (MLP) has played a pre-eminent role in the analysis of transcription initiation in mammalian cells, and is an outstanding example of the ways in which the study of adenovirus has led to fundamental insights into general cellular processes. The aim of this chapter is to give a comprehensive review of the structure and function of this model mammalian promoter. After a brief description of late transcription in the adenovirus replication cycle, the experimental evidence for the current consensus on the genetic structure of the MLP, including a consideration of non-primate adenovirus MLPs, will be reviewed. Next, the functions of the MLP in the viral life cycle will be examined, and some of the problems that remain to be resolved will be addressed. The review ends with some ideas on how the knowledge of the structure and function of the MLP can be used in designing virus vectors for specific experimental purposes.

Readthrough activation of early adenovirus E1b gene transcription

In cells productively infected with adenovirus type 5, transcription is not terminated between the E1a gene and the adjacent downstream E1b gene. Insertion of the mouse beta(maj)-globin transcription termination sequence (GGT) into the E1a coding region dramatically reduces early, but not late, E1b expression (E. Falck-Pedersen, J. Logan, T. Shenk, and J. E. Darnell, Jr., Cell 40:897-905, 1985). In the study described herein, we showed that base substitution mutations in the globin DNA that specifically relieved transcription termination also restored early E1b promoter activity in cis, establishing that maximal early E1b expression requires readthrough transcription originating from the adjacent upstream gene. To identify potential targets of readthrough activation, a series of recombinant viruses with double mutations was constructed. Each double-mutant virus strain had the transcription termination sequences in the first exon of E1a and a deletion within the transcription control region of E1b. Early E1b expression from the double-mutant strains was more defective than that from strains containing either mutation alone, indicating that the deleted regions (positions -362 to -35) are not the target for readthrough activation. Two findings suggested that a cis-dominant property of early viral templates is important for readthrough activation. First, the early E1b defect caused by the GGT insertion was not complemented in trans by factors present in late-infected cells. Second, restoration of E1b transcription at late times occurred concurrently with viral DNA replication. Readthrough activation may help convert virion DNA into a transcriptionally competent template prior to DNA replication and late transcription.

Construction, characterization, and utilization of cell lines which inducibly express the adenovirus DNA-binding protein

To further our understanding of structure-function relationships within the multifunctional adenovirus DNA binding protein (DBP) a more diverse collection of mutants is necessary. DBP-expressing cell lines (gmDBP) were previously constructed that complemented DBP-negative mutants for viral growth. However, they did not allow severely defective viruses to form plaques. Since efficient mutant construction is reliant on plaque isolation of the desired mutant virus as a final step, additional gmDBP cell lines were constructed which allow all DBP-negative mutants to form plaques. Here we describe the construction and characterization of 12 new gmDBP cell lines. The utility of these lines was demonstrated by the efficient construction of a new defective mutant, H5in804, using a combination of DBP-expressing lines. The H5in804 mutation adds 22 amino acids at the carboxyl end of an otherwise wild type protein. Characterization of H5in804 revealed that it was altered in its ability to replicate viral DNA. The depression of DNA synthesis most probably results from a reduced ability of H5in804 DBP to bind ssDNA.

Tumor promoters alter the temporal program of adenovirus replication in human cells

In this study we evaluated the effect of phorbol ester tumor promoters on the kinetics of adenovirus type 5 (Ad5) replication in human cells. When added at the time of infection, 12-O-tetradecanoyl-phorbol-13-acetate (TPA) accelerated the appearance of an early virus antigen (72,000-molecular-weight [72K] deoxyribonucleic acid-binding protein), the onset of viral deoxyribonucleic acid synthesis, and the production of infectious virus. The appearance of an Ad5-specific cytopathic effect (CPE) was also accelerated in infected cultures exposed to TPA, whereas phorbol, 4 alpha-phorbol-12,13-didecanoate and 4-OmeTPA, which are inactive as tumor promoters, were ineffective in inducing this morphological change. The acceleration of the CPE seen in TPA-treated Ad5-infected cells was not caused by TPA induction of the protease plasminogen activator, since the protease inhibitors leupeptin and antipain do not inhibit the earlier onset of this CPE and, in contrast, epidermal growth factor, which induces plasminogen activator in HeLa cells, does not induce an earlier CPE. Evidence for a direct effect of TPA on viral gene expression was obtained by analyzing viral messenger ribonucleic acid (mRNA) synthesis. TPA accelerated the appearance of mRNA from all major early regions of Ad5, transiently stimulated the accumulation of region III mRNA, and accelerated the appearance of late Ad5 mRNA. Thus, TPA altered the temporal program of Ad5 mRNA production and accelerated the appearance of at least some Ad5-specific polypeptides during lytic infection of human cells. These effects presumably explain the earlier onset of the Ad5-specific CPE in TPA-treated cells and may have relevance to the effects of TPA on viral gene expression in nonpermissive cells carrying integrated viral deoxyribonucleic acid sequences.

Immunological analysis of 140-kDa adenovirus-encoded DNA polymerase in adenovirus type 2-infected HeLa cells using antibodies raised against the protein expressed in Escherichia coli

The E2B region of adenovirus genome contains a long open reading frame (ORF) extending from 24 to 14.2 map units which encodes most of the 140-kDa DNA polymerase. It was cloned at the polylinker region of pUC18 vector with Escherichia coli JM109 as the host. A clone was serendipitously isolated that expressed in E. coli a protein of approximately 120 kDa in size at high levels. DNA sequence analysis of this clone showed the presence of an in-frame fusion of a region, encoding 13 amino acids located upstream, to the first ATG of the ORF. Polyclonal antibodies raised against this protein purified from E. coli were used for immunological analysis. The antibodies were able to detect a 140- and a 66-kDa polypeptide from the adenovirus type 2-infected HeLa cells on Western blots. In addition, the antibodies showed evidence of cross-reactivity with partially purified DNA polymerase alpha from uninfected HeLa cells. The subcellular localization of the viral polymerase in the infected HeLa cells by using indirect immunofluorescence showed that the viral protein is associated with globular structures in the nucleus. The replicating viral DNA and the polymerase were colocalized in these globular sites. Furthermore, HeLa cells infected with Ad5ts149, a temperature-sensitive mutant defective in DNA replication, showed the presence of these globular sites only at the permissive temperature, suggesting that these sites are probably involved in viral DNA replication.

Cell-type-specific synthesis of murine immunoglobulin mu RNA from an adenovirus vector

The mouse immunoglobulin heavy-chain mu constant region gene was cloned into the early region 1B of an adenovirus type 5 vector to allow reproducible kinetics of expression of the mu gene in the presence of continuous host protein synthesis after infection by the recombinant. The immunoglobulin-adenovirus recombinant is helper independent in infecting human fibroblastic and B- and T-cell lines and expresses mu in a cell-type-specific manner. By Northern blot analysis, correctly polyadenylated and spliced E1B-mu S and E1B-mu m mRNAs are found to be equally abundant at steady state in fibroblasts. In contrast, and appropriately, only E1B-mu S mRNAs accumulate in a lambda light-chain-secreting myeloma cell line. Analysis of nascent transcripts pulse labeled in isolated nuclei demonstrates equimolar polymerase loading throughout the mu region in all cell types infected by mu-Ad. Thus, correct polyadenylation and splicing of E1B-mu S and E1B-mu m in fibroblasts does not require transcription termination in the region separating the mu S and mu m polyadenylation sites. Furthermore, differential expression of mu transcripts in the background of myeloma cells is regulated at the level of RNA processing and does not require the presence of the immunoglobulin heavy-chain enhancer or promoter element.

Identification of two nuclear subclasses of the adenovirus type 5-encoded DNA-binding protein

The synthesis, accumulation, and subcellular distribution of the adenovirus serotype 5 DNA-binding protein (DBP) has been examined during the infectious cycle in HeLa cells. With the onset of viral DNA replication and entry into the late phase, two nuclear subclasses of DBP are distinguishable by immunofluorescence microscopy and can be separately isolated by in situ cell fractionation. The first subclass, represented by diffuse-staining DBP, is released by the addition of 1% Nonidet P-40-150 mM NaCl. The second subclass of DBP, which is sequestered into intranuclear globular structures, requires a high ionic strength (2 M NaCl) for extraction and appears to be associated with centers of active viral DNA replication. This association is based on the observations that: DBP within the globules and viral DNA, as detected by in situ hybridization, form identical structures that colocalize within the nuclei of infected cells, the formation of DBP globular structures requires the onset and continuation of viral DNA replication, and once formed, the globular structures can be perturbed by modulating viral DNA synthesis.

Cell-type-specific synthesis of murine immunoglobulin mu RNA from an adenovirus vector

The mouse immunoglobulin heavy-chain mu constant region gene was cloned into the early region 1B of an adenovirus type 5 vector to allow reproducible kinetics of expression of the mu gene in the presence of continuous host protein synthesis after infection by the recombinant. The immunoglobulin-adenovirus recombinant is helper independent in infecting human fibroblastic and B- and T-cell lines and expresses mu in a cell-type-specific manner. By Northern blot analysis, correctly polyadenylated and spliced E1B-mu S and E1B-mu m mRNAs are found to be equally abundant at steady state in fibroblasts. In contrast, and appropriately, only E1B-mu S mRNAs accumulate in a lambda light-chain-secreting myeloma cell line. Analysis of nascent transcripts pulse labeled in isolated nuclei demonstrates equimolar polymerase loading throughout the mu region in all cell types infected by mu-Ad. Thus, correct polyadenylation and splicing of E1B-mu S and E1B-mu m in fibroblasts does not require transcription termination in the region separating the mu S and mu m polyadenylation sites. Furthermore, differential expression of mu transcripts in the background of myeloma cells is regulated at the level of RNA processing and does not require the presence of the immunoglobulin heavy-chain enhancer or promoter element.

Premature termination by human RNA polymerase II occurs temporally in the adenovirus major late transcriptional unit

We have recently demonstrated pausing and premature termination of transcription by eucaryotic RNA polymerase II at specific sites in the major late transcriptional unit of adenovirus type 2 in vivo and in vitro. In further developing this as a system for studying eucaryotic termination control, we found that prematurely terminated transcripts of 175 and 120 nucleotides also occur in adenovirus type 5-infected cells. In both cases, premature termination occurs temporally, being found only during late times of infection, not at early times before DNA replication or immediately after the onset of DNA replication when late gene expression has begun (intermediate times). To examine the phenomenon of premature termination further, a temperature-sensitive mutant virus, adenovirus type 5 ts107, was used to uncouple DNA replication and transcription. DNA replication is defective in this mutant at restrictive temperatures. We found that premature termination is inducible at intermediate times by shifting from a permissive temperature to a restrictive temperature, allowing continuous transcription in the absence of continuous DNA replication. No premature termination occurs when the temperature is shifted up at early times before DNA replication. Our data suggest that premature termination of transcription is dependent on both prior synthesis of new templates and cumulative late gene transcription but does not require continuous DNA replication.

Premature termination by human RNA polymerase II occurs temporally in the adenovirus major late transcriptional unit

We have recently demonstrated pausing and premature termination of transcription by eucaryotic RNA polymerase II at specific sites in the major late transcriptional unit of adenovirus type 2 in vivo and in vitro. In further developing this as a system for studying eucaryotic termination control, we found that prematurely terminated transcripts of 175 and 120 nucleotides also occur in adenovirus type 5-infected cells. In both cases, premature termination occurs temporally, being found only during late times of infection, not at early times before DNA replication or immediately after the onset of DNA replication when late gene expression has begun (intermediate times). To examine the phenomenon of premature termination further, a temperature-sensitive mutant virus, adenovirus type 5 ts107, was used to uncouple DNA replication and transcription. DNA replication is defective in this mutant at restrictive temperatures. We found that premature termination is inducible at intermediate times by shifting from a permissive temperature to a restrictive temperature, allowing continuous transcription in the absence of continuous DNA replication. No premature termination occurs when the temperature is shifted up at early times before DNA replication. Our data suggest that premature termination of transcription is dependent on both prior synthesis of new templates and cumulative late gene transcription but does not require continuous DNA replication.

Replication and recombination in adenovirus-infected cells are temporally and functionally related

We have studied the temporal and functional relationships between DNA replication and recombination in adenovirus-infected cells by using Southern blot hybridization to detect recombinant products among intracellular viral genomes. The data show that recombination can be detected soon after DNA replication has commenced and that the proportion of recombinant products increases thereafter. To determine the functional relationship between DNA replication and recombination, replication was blocked with the protein synthesis inhibitor anisomycin, the replication inhibitor cytosine arabinoside, and conditionally lethal mutations in either the virus-specified DNA-binding protein or the DNA polymerase. All treatments that directly or indirectly blocked DNA replication caused a delay in the appearance of recombinant products and a marked decline in their abundance relative to products of parental genotype. These data strongly suggest that DNA replication and recombination are interrelated, either because both processes share functions or because DNA structures produced by replication are suitable substrates for recombination. In addition, we have shown that some recombination function(s) is intrinsically thermolabile at 40.9 degrees C, even in wild-type crosses, since the appearance of recombinant products is delayed and their extent is reduced compared with that from crosses performed at 39.9 degrees C.

Independent mutations in Ad2ts111 cause degradation of cellular DNA and defective viral DNA replication

An adenovirus mutant, Ad2ts111, has previously been shown to be temperature sensitive for viral DNA replication in vivo and also to induce degradation of cellular DNA. Soluble nuclear extracts prepared from Ad2ts111-infected HeLa cells grown at either the permissive (32 degrees C) or the nonpermissive (39.5 degrees C) temperature are thermolabile for elongation but not for initiation of DNA replication in vitro. Adenovirus single-stranded-DNA-binding protein purified from wild-type-infected cells can complement these extracts at the restrictive temperature in vitro. The DNA-binding protein synthesized in Ad2ts111-infected cells is stable at the nonpermissive temperature and is phosphorylated, as is the wild-type protein. In contrast, the mutant DNA-binding protein synthesized in Ad5ts125-infected cells is unstable. Ad2ts111 and Ad5ts125 do not complement each other for virus growth in vivo. These results suggest that Ad2ts111 contains a mutation in the DNA-binding protein that affects viral DNA synthesis. Finally, we demonstrated that, unlike viral DNA synthesis, the induction of cellular DNA degradation in Ad2ts111-infected cells is not temperature sensitive and that this phenotype is a result of a mutation in early region 1 on the virus genome. Thus, the two phenotypes displayed in Ad2ts111-infected cells, namely, the temperature-sensitive replication of viral DNA and the degradation of cell DNA, are the result of two separate mutations.

The function(s) provided by the adenovirus-specified, DNA-binding protein required for viral late gene expression is independent of the role of the protein in viral DNA replication

The adenovirus type 2 (Ad2) host range mutant Ad2hr400 grows efficiently in cultured monkey cells at 37 degrees C, but is cold sensitive for plaque formation and late gene expression at 32.5 degrees C. After nitrous acid mutagenesis of an Ad2hr400 stock, cold-resistant variants were selected in CV1 monkey cells at 32.5 degrees C. One such variant, Ad2ts400, was also temperature sensitive (ts) for growth in both CV1 and HeLa cells. Marker rescue analysis has been used to show that the two phenotypes, cold resistant and temperature sensitive, are due to two independent mutations, each of which resides in a different segment of the gene encoding the 72-kilodalton DNA binding protein (DBP). The cold-resistant mutation (map coordinates 63.6 to 66) is a host range alteration that enhances the ability of the virus to express late genes and grow productively in monkey cells at 32.5 degrees C. The temperature-sensitive mutation is in the same complementation group and maps to the same segment of the DBP gene (map coordinates 61.3 to 63.6) as the well-characterized DBP mutant Ad5ts125. Like Ad5ts125, Ad2ts400 is unable to replicate viral DNA or to properly shut off early mRNA expression at the nonpermissive temperature. Two sets of experiments with Ad2ts400 suggest that DBP contains separate functional domains. First, when CV1 cells are coinfected at the nonpermissive temperature with Ad2 plus Ad2ts400 (Ad2 allows DNA replication and entry into, but not completion of, the late phase of infection), normal late gene expression and productive growth occur. Second, temperature shift experiments show that, although DNA replication is severely restricted at the nonpermissive temperature in ts400-infected monkey cells, late gene expression occurs normally. These results indicate that the DBP activity required for normal late gene expression in monkey cells is functional even when the DBP's DNA replication activity is disrupted.

Construction of human cell lines which contain and express the adenovirus DNA binding protein gene by cotransformation with the HSV-1 tk gene

We have introduced the DNA binding protein (DBP) gene of human adenovirus type 5 (Ad5) into high molecular weight DNA of permissive human cells by cotransformation of tk- cells with the cloned DBP and HSV-1 thymidine kinase genes. 110 tk+ cell lines were isolated after selection in HAT medium. The amount and arrangement of adenovirus sequences in the tk+ cell lines were analyzed by restriction endonuclease digestion and filter hybridization. Twelve of the 110 lines carry at least a segment of the DBP gene while only three of these contain the entire DBP gene at approximately one copy per cell. Cytoplasmic, polyadenylated DBP mRNA is made in all three cell lines though the amount is very low compared to that present in infected HeLa cells. The cell line U13-2 which contains approximately 1/30 the steady-state level of DBP mRNA found in infected HeLa cells produces a few percent of the amount of DBP made during the peak period of DBP synthesis in infected cells. The other two lines contain lower levels of DBP mRNA and do not synthesize detectable levels of the protein. When these DBP-tk+ cell lines are infected with adenovirus mutants containing temperature-sensitive (ts) mutations in the DBP gene, only U13-2 permits some viral DNA replication (and hence late gene expression) at the nonpermissive temperature, indicating that sufficient quantities of DBP from the integrated gene are produced to allow complementation of the ts mutation in this cell line. However, growth of these ts mutants (as measured by virus production) is only partially complemented in U13-2 at the nonpermissive temperature.

Identification of adenovirus genes that require template replication for expression

The relationship between adenovirus type 2 DNA replication and expression of intermediate stage viral genes was investigated. The 1.03-kilobase mRNA from early region 1b (E1b) and the mRNAs coding for proteins IX and IVa2 were first detected between 6 and 8 h postinfection. Inhibition of viral DNA replication with hydroxyurea prevented expression of the IX and IVa2 mRNAs, but not of the E1b mRNA. Pulse-labeling experiments demonstrated that the block of IX and IVa2 expression in hydroxyurea-treated cells was at the level of transcription. By a series of superinfection experiments, it was determined that the viral and cellular factors present during the late stage of adenovirus infection are insufficient to activate IX gene expression. The viral DNA template must first replicate before IX transcription can begin.

Temperature-sensitive initiation and elongation of adenovirus DNA replication in vitro with nuclear extracts from H5ts36-, H5ts149-, and H5ts125-infected HeLa cells

Adenovirus DNA replication was studied in vitro in nuclear extracts prepared from HeLa cells infected at the permissive temperature with H5ts125, H5ts36, or H5ts149, three DNA-negative mutants belonging to two different complementation groups. At the restrictive temperature, H5ts125 extracts, containing a thermolabile 72-kilodalton DNA-binding protein, enable the formation of an initiation complex between the 82-kilodalton terminal protein precursor (pTP) and dCTP, but further elongation of this complex is inhibited. Wild-type DNA-binding protein or a 47-kilodalton chymotryptic DNA-binding fragment can complement the mutant protein in the elongation reaction. No difference in heat inactivation was observed between wild-type extracts and H5ts36 or H5ts149 extracts when the replication of terminal XbaI fragments of adenovirus type 5 DNA-terminal protein complex was studied. In contrast, the formation of a pTP-dCMP initiation complex, as well as the partial elongation reaction up to nucleotide 26, were consistently more temperature sensitive in mutant extracts. The results suggest that the H5ts36/H5ts149 gene product is required for initiation of adenovirus type 5 DNA replication and that the 72-kilodalton DNA-binding protein functions early in elongation.

Host range temperature-conditional mutants in the adenovirus DNA binding protein are defective in the assembly of infectious virus

R(ts107)202 is a host range temperature-conditional mutant of adenovirus type 5. This mutant is temperature sensitive for replication and plaquing in 293 cells but is temperature independent for growth and plaquing in HeLa cells (J. C. Nicolas, F. Suarez, A. J. Levine, and M. Girard (1981) Virology 108, 521-524). The mutant was isolated in HeLa cells as a temperature-independent revertant of the H5ts107 temperature-sensitive mutant that maps in the adenovirus DNA binding protein (DBP). The reasons for the temperature conditional phenotype of this mutant in 293 cells were investigated. The mutant synthesized an unstable DBP in both HeLa and 293 cells at 39 degrees. In 293 cells at 39 degrees, about two- to threefold less viral DNA was synthesized by r(ts107)202 as compared to Ad5wt. R(ts107)202 infected cells at 39 degrees produced normal (wild-type) amounts of all detectable late viral structural proteins. The mutant failed, however, to produce infectious virus or assemble virus particles in 293 cells at 39 degrees. The altered DBP may therefore play a role in the assembly of virus particles, either directly or indirectly via an altered DNA structure. The failure of r(ts107)202 to assemble virion particles in 293 cells at 39 degrees furthermore suggests that virus assembly is dependent upon cellular factors that differ in HeLa and 293 cell.

Detection, rescue, and mapping of mutations in the adenovirus DNA binding protein gene

r(ts107)202 was isolated in HeLa cells as a temperature-independent revertant of H5ts107, an adenovirus mutant that maps in the structural gene of the viral DNA-binding protein. r(ts107)202 is a host-range temperature-conditional mutant: it is temperature independent for growth in HeLa cells but temperature sensitive for growth in 293 cells, a type 5 adenovirus-transformed human cell line. Marker rescue experiments using H5ts107 DNA and restriction enzyme fragments from r(ts107)202 DNA demonstrated that the mutations causing the r(ts107)202 phenotype were localized in HindIII fragment A containing the entire DNA-binding protein gene. To obtain a fine structure map of the r(ts107)202 mutations, overlap recombination between EcoRI fragment A (0-75.9 map units) from either Ad5wt or r(ts107)202 and BamHI fragment B (59.5-100 map units) from either Ad5wt or r(ts107)202 was performed. Segregation of the H5ts107 primary-site mutation away from the accompanying reversion mutation could be demonstrated in 5 of 200 plaques when r(ts107)202 EcoRI fragment A was crossed with the Ad5wt BamHI fragment. In the reciprocal cross, none of 200 plaques contained the H5ts107 mutant. These results permitted a determination of the order of the primary-site mutation (H5ts107) and secondary-site mutation in r(ts107)202, and the frequency of recombination predicted a distance of 50-340 base pairs between these two mutations. This experimental result agrees with the nucleotide sequence of the r(ts107)202 mutant which shows that 182 base pairs separate the primary-site and secondary-site mutations in r(ts107)202.

Purification of an adenovirus-coded DNA polymerase that is required for initiation of DNA replication

Temperature-sensitive mutants in the N complementation group of human adenovirus type 5 are defective at the nonpermissive temperature for replication of virus DNA and for transformation of rat embryo cells. We show that nuclear extracts prepared from Ad5ts 149-infected cells grown at the nonpermissive temperature fail to replicate DNA in vitro. The defect lies in the first step in the initiation of viral DNA synthesis, the formation of a covalent linkage between the terminal protein precursor (pTP) and dCMP. A 140 kilodalton (140 kd) protein which complements these defective extracts and contains DNA polymerase activity has been purified from HeLa cells infected with wild-type Ad2. It is tightly associated with the 80 kd pTP in a replication complex. Both of these proteins are products of the E2B region of the adenovirus genome, and the 140 kd protein coding sequences lie immediately downstream from those encoding the 80 kd protein. These results demonstrate that adenovirus encodes a novel DNA polymerase that is required for priming of DNA synthesis at the origin of replication. This protein may also function in the initiation of transformation of cultured cells.

Protein kinases associated with the adenovirus single-stranded DNA-binding protein

Protein kinase activities copurifying with the 72000-Mr DNA-binding protein of adenovirus on DNA-cellulose chromatography and gel filtration in acrylamide/agarose have been partially characterized and purified. One of these kinases was found to phosphorylate efficiently the viral DNA-binding protein in vitro and to be stimulated severalfold by the addition of histones, protamine, or polyamines. The kinase does not, however, phosphorylate histones, protamine, casein, or phosvitin. A second protein kinase was also recovered from single-stranded DNA-cellulose which is able to phosphorylate the 72000-Mr DNA-binding protein, but which is inhibited by the addition of histones. Phosphorylation in vitro of the 72000-Mr DNA-binding protein from the ts125 mutants of adenovirus by the histone-stimulated protein kinase was found to be thermosensitive.

Two classes of replicating molecules of adenovirus type 2 DNA

Replicating DNA of human adenovirus type 2, identified as partly single-stranded viral DNA in which [3H]thymidine is readily incorporated, was found to be separated into two fractions by chromatography on hydroxyapatite. Whereas one of the these fractions was eluted with 180 mM phosphate, the other one was eluted at the same concentration, 240 mM, as fully double-stranded DNA. The physical properties of the 180 and 240 mM fractions, in particular their buoyant densities in solutions of CsCl and Cs2SO4, were compared both before and after treatment by various enzymes such as Neurospora crassa nuclease, pancreatic ribonuclease, ribonuclease H and the Klenow fragment of DNA polymerase I of Escherichia coli, used alone or in various combinations. Unlike the 240 mM fraction, the 180 mM fraction was found to include a substantial amount of single-stranded DNA, some of it being hydrogen-bonded to RNA. Both of these features confer to the 180 mM fraction the high buoyant density in cesium salt solution which was described, for several adenoviruses, as one of the characteristic properties of replicating DNA.

Tumor promoters alter the temporal program of adenovirus replication in human cells

In this study we evaluated the effect of phorbol ester tumor promoters on the kinetics of adenovirus type 5 (Ad5) replication in human cells. When added at the time of infection, 12-O-tetradecanoyl-phorbol-13-acetate (TPA) accelerated the appearance of an early virus antigen (72,000-molecular-weight [72K] deoxyribonucleic acid-binding protein), the onset of viral deoxyribonucleic acid synthesis, and the production of infectious virus. The appearance of an Ad5-specific cytopathic effect (CPE) was also accelerated in infected cultures exposed to TPA, whereas phorbol, 4 alpha-phorbol-12,13-didecanoate and 4-OmeTPA, which are inactive as tumor promoters, were ineffective in inducing this morphological change. The acceleration of the CPE seen in TPA-treated Ad5-infected cells was not caused by TPA induction of the protease plasminogen activator, since the protease inhibitors leupeptin and antipain do not inhibit the earlier onset of this CPE and, in contrast, epidermal growth factor, which induces plasminogen activator in HeLa cells, does not induce an earlier CPE. Evidence for a direct effect of TPA on viral gene expression was obtained by analyzing viral messenger ribonucleic acid (mRNA) synthesis. TPA accelerated the appearance of mRNA from all major early regions of Ad5, transiently stimulated the accumulation of region III mRNA, and accelerated the appearance of late Ad5 mRNA. Thus, TPA altered the temporal program of Ad5 mRNA production and accelerated the appearance of at least some Ad5-specific polypeptides during lytic infection of human cells. These effects presumably explain the earlier onset of the Ad5-specific CPE in TPA-treated cells and may have relevance to the effects of TPA on viral gene expression in nonpermissive cells carrying integrated viral deoxyribonucleic acid sequences.

DNA replication and the early to late transition in adenovirus infection

Expression of the late genes of adenovirus is only detectable after virus DNA synthesis has occurred. Using a superinfection protocol, we show that replication of the template per se is required for expression of late regions L2--L5 (mapping to the right of position 39) and that the accumulation of early gene products does not suffice. This regulation is probably exerted at the level of transcription rather than by control of processing or selective stabilization of late mRNA or its precursors. The promoter-proximal late gene block L1, however, appears to be subject to processing control. At early times a single member of this gene family (tripartite leader plus coordinates 29--39, encoding the 52,55K polypeptide pair) is expressed, whereas at late times an additional, differently spliced mRNA species is generated from this region (tripartite leader plus coordinates 34--39, encoding polypeptide IIIa).

Regulation of adenovirus mRNA synthesis

The lytic cycle of adenovirus is a tightly regulated sequence of stages. When this regulation is studied at the level of mRNA production, the most significant step in controlling gene expression is initiation of transcription. Thus in preceding from one stage of expression to another, viral factors seem to turn on transcription of new sets of genes. At the moment, it is thought that viral mRNA synthesis involves initiation of transcription at ten different promoter sites. It is likely that in some manner the frequency of an initiation of transcription at nine of these sites is affected by one or more viral gene products. With the recent development of soluble in vitro transcription systems that respond to exogenously added DNA, it should be possible to begin to study regulation of gene expression at this stage of transcription. At present, these systems yield the paradoxical observation that extracts prepared from uninfected human cells more efficiently recognize the late promoter as compared to the early promoter of adenovirus. As more is learned about regulation of synthesis of viral mRNAs, examples will surely be found where RNA processing and RNA turnover play a critical role in determining the level of mRNAs. Such cases are more likely to appear in the balancing of synthesis of different mRNAs derived from one transcriptional unit. Few experiments have been directed to this possibility and the study of adenovirus molecular biology is only now entering the age of maturity where these experiments are feasible.

Transcription and RNA processing by the DNA tumour viruses

Messenger RNA synthesis by the DNA tumour viruses proceeds by a complex but versatile series of transcription and RNA processing steps. The major mechanistic features of this pathway are probably very similar to those used by the animal cell host itself. The viruses have, however, evolved intricate arrangements of protein coding sequences and sites for RNA initiation, polyadenylation and splicing which allow them to use their genetic information to maximum advantage.

The replication pattern of adenovirus DNA in vivo reproduced in vitro

Temperature-sensitive mutants of adenovirus type 5 (H5ts125 and H5ts149), which are conditionally inhibited in the initiation of viral DNA synthesis, have been exploited to investigate the possibility of the initiation of replication in a cell-free system. Nuclei were isolated from human KB cells which had been infected with wild-type or mutant adenovirus. More than 90% of the DNA synthesis taking place in such nuclei was virus-specific and the pattern of drug inhibition suggested that the synthesis required DNA polymerase gamma. Nuclei prepared from cells infected with the H5ts125 temperature-sensitive mutant which have been shifted from 33 degrees C to 39.5 degrees C showed a pattern of synthesis in vitro which began at both ends of the viral genome and gradually spread through the rest of the molecule.

Adenovirus DNA template for late transcription is not a replicative intermediate

The relationship between adenovirus replication and late transcription has been investigated using viral replication and transcription complexes isolated from infected HeLa cell nuclei. These two types of complexes extracted from adenovirus type 2-infected cell nuclei did not sediment at the same rate on sucrose gradients. Viral replicative intermediates were quantitatively precipitated by immunoglobulins raised against purified 72,000-dalton DNA-binding protein, whereas viral transcription complexes remained in the supernatant. These results show that late transcription does not occur on active replication complexes or on 72,000-dalton DNA-binding protein-containing replicative intermediates inactive in DNA synthesis. Additional evidence is presented indicating that it is very unlikely that replicative intermediates lacking the 72,000-dalton DNA-binding protein could be the template for late transcription.

Autoregulation of adenovirus type 5 early gene expression. III. Transcription studies in isolated nuclei

The rate of adenovirus RNA synthesis was compared in nuclei isolated from cells infected at 40.5 degrees C in the presence of 1-beta-d-arabinofuranosylcytosine with adenovirus 5 or an early temperature-sensitive mutant of adenovirus type 5, H5ts125 (ts125). In nuclei isolated at various times after infection, the maximum amount of virus RNA synthesis occurred at 6 h after infection, after which time virus RNA synthesis declined in nuclei from wild-type infections but remained high in nuclei from ts125 infections. At 12 h after infection, the amount of virus RNA synthesis was 8- to 11-fold higher in nuclei from ts125 infections than in nuclei from wild-type infections. However, the kinetics of virus RNA synthesis in nuclei isolated from both infections were similar. When a ts125-infected culture was shifted to 32 degrees C for 3 h (12 to 15 h after infection) before nucleus isolation, the amount of virus RNA synthesis in the isolated nuclei was reduced to nearly wild-type levels. A pulse-chase experiment showed little difference in degradation rates of virus RNA in isolated nuclei from wild-type and ts125 infections. Hybridization of RNA synthesized in vitro to restriction fragments of adenovirus type 5 DNA was consistent with early virus RNA. These results support the idea that the 72,000-dalton DNA-binding protein encoded by the mutant gene in ts125 can regulate early adenovirus gene expression by inhibiting initiation of transcription of the adenovirus genome.

Autoregulation of adenovirus type 5 early gene expression II. Effect of temperature-sensitive early mutations on virus RNA accumulation

The kinetics of accumulation of early virus RNA in the cytoplasm of KB cells infected at 40.5 degrees C by wild-type (WT) adenovirus type 5 and a temperature-sensitive "early" mutant, H5ts125 (ts125), were compared by hybridization of unlabeled RNA in solution to the (3)H-labeled l strand of Ad5 DNA HindIII restriction endonuclease fragment A. In the presence of 1-beta-d-arabinofuranosylcytosine, A(l) RNA accumulated in WT-infected cells for 9 h and then decreased in concentration to 6% of the 9-h concentration by 18 h. In ts125-infected cells, A(l) RNA accumulated for 12 h and then remained at the same concentration for at least 6 h thereafter. The concentrations of virus RNA from the four early transcription regions of the genome were measured at 15 h in cells infected at 40.5 degrees C in the presence of 1-beta-d-arabinofuranosylcytosine by: (i) ts125 and WT; (ii) two other ts early mutants, ts107 and ts149; and (iii) a revertant of ts125. The revertant and ts149, a mutant from a different complementation group than ts125, both accumulated all early virus cytoplasmic RNA species in amounts similar to, or less than, WT. However, both ts125 and ts107, independently isolated mutations in the 72,000-molecular-weight (72K) DNA-binding protein gene, accumulated cytoplasmic early RNA in excess of that found in WT infection. This pattern of RNA accumulation with the mutants and WT virus was the same in the nuclei as in the cytoplasm at 40.5 degrees C. At 32 degrees C, however, the abundance of nuclear virus RNA from all four early regions was the same in cells infected by either ts125 or WT. Differences in the relative abundance of nuclear RNA from the four early regions were observed in cells infected at 40.5 and 32 degrees C, but were not dependent upon the infecting virus genotype. These results are consistent with autoregulation of early gene expression by the 72K protein and support the hypothesis that the 72K protein either decreases the rate of early virus transcription or increases the rate of virus RNA degradation in the nucleus.

Adenovirus core protein synthesis in the absence of viral DNA synthesis late in infection

The acid extraction of the adenovirus type 5 core proteins V, VII, and pVII (the precursor to VII) from infected cells and the subsequent electrophoresis on a 15% acrylamide-2.5 M urea-0.9 N acetic acid (pH 2.7) gel, revealed that peptide VII has a similar electrophoretic mobility to that of histone H1. The core proteins, which are coded by late adenovirus mRNA, continued to be synthesized late in infection when viral DNA synthesis was inhibited either by cytosine arabinoside in wild-type infections or by shifting adenovirus H5 ts 125-infected cells to the nonpermissive temperature (40 degree C). Only the initiation, not the continuation, of viral DNA replication was essential for core protein synthesis. The synthesis of viral core proteins continued for over 8 h after the cassation of DNA synthesis. This was in contrast to the rapid shutdown of cellular histone synthesis in the absence of cellular DNA synthesis.

Possible role of the 72,000 dalton DNA-binding protein in regulation of adenovirus type 5 early gene expression

Relative abundances of early virus RNA species in the cytoplasm of cells infected with wild-type adenovirus type 5 (WT Ad5) and a temperature-sensitive "early" mutant, H5ts125 (ts125), were compared by hybridization kinetics using separated strands of HindIII restriction endonuclease fragments of Ad5 DNA. 1-beta-D-Arabinofuranosylcytosine (ara-C) was used to limit transcription to early virus genes in cells infected by WT virus. At 40.5 degrees C, a restrictive temperature for ts125, three to seven times as much virus RNA from all four early regions of the genome accumulated in the cytoplasm of cells infected by the mutant as accumulated in cells infected by WT. At 32 degrees C, no such difference in the relative abundances of cytoplasmic virus RNA was observed. The capacity to synthesize a 72,000-dalton (72K) virus polypeptide, presumably the single-stranded DNA-binding protein that is defective in ts125 at restrictive temperatures, was compared in cells infected at 40.5 degrees C in the presence of ara-C with the mutant or WT Ad5. The rate of 72K polypeptide synthesis, measured by sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis of [35S]methionine-labeled polypeptides and autoradiography, was greater at 15 h after infection in ts125-infected cells than in cells infected by WT. A time course experiment showed that the rate of synthesis of the 72K polypeptide increased continuously in ts125-infected cells during the first 15 h of infection, relative to the rate in WT-infected cells. These data are consistent with the hypothesis that Ad5 early gene expression is modulated by the product of an early gene, the 72K DNA-binding protein.

Adenovirus DNA-binding protein in cells infected with wild-type 5 adenovirus and two DNA-minus, temperature-sensitive mutants, H5ts125 and H5ts149

Studies have been done to characterize further H5ts125, an adenovirus type 5 conditionally lethal, temperature-sensitive (ts) mutant defective in initiation of DNA synthesis and to investigate whether the single-strand-specific DNA-binding (72,000 molecular weight) protein is coded by the mutated viral gene. When H5ts125-infected cells were labeled with [35S]methionine at 32 degrees C and then incubated without isotope at 39.5 degrees C, the mutant's nonpermissive temperature, the 72,000 molecular weight polypeptide was progressively degraded. Immunofluorescence examination of cells infected with wild-type virus, H5ts125, and H5ts149 (a second, unique DNA-minus mutant) showed that immunologically reactive DNA-binding protein was barely detectable in H5ts125-infected cells at 39.5 degrees C, whereas this protein was present in wild-type- and H5TS149-infected cells, that the protein made at 32 degrees C in H5ts125-infected cells lost its ability to bind specific DNA-binding protein antibody when the infected cells were shifted to 39.5 degrees C, and that if H5ts125-infected cells were shifted from the restrictive temperature to 32 degrees C, even in the presence of cycloheximide to stop protein synthesis, immunologically reactive DNA-binding protein reappeared.

Regulation of early and late simian virus 40 transcription: overproduction of early viral RNA in the absence of a functional T-antigen

Virus-specific RNA synthesized in monkey cells after infection by both wild-type simian virus 40 (SV40) and the early SV40 temperature-sensitive mutant tsA58 has been analyzed. The fraction of SV40-specific RNA increased throughout infection with either wild-type SV40 or with tsA58 in direct proportion to the accumulation of progeny DNA molecules, suggesting their role in the late transcriptional process. Cytoplasmic fractions from cells infected at various temperatures (31.5 to 41 degrees C) by wild-type virus and harvested 48 h later contained 4 to 8% virus-specific RNA, of which 5 to 10% was early SV40 RNA. In contrast, though 5 to 8% of the cytoplasmic RNA from tsA 58-infected cells incubated at 31.5 to 37 degrees C for 48 h was virus specific, the percentage of early virus-specific RNA ranged from 25 to 80% as the incubation temperature increased. In tsA58-infected cultures incubated for 48 h at 41 degrees C (a temperature at which essentially no tsA 58 DNA synthesis occurred), only 0.4% of the cytoplasmic RNA was virus specific, but at least 90% of this RNA was early. In experiments where cells were inoculated at 32 degrees C and shifted at 48 h postinfection to 40 degrees C for various times, the percentage of virus-specific pulse-labeled RNA varied from 3.5 to 10.0%. Of the virus-specific RNA, early SV40 RNA ranged from 14 to 65% in tsA 58-infected cultures. Analogous studies with Sarkosyl-extracted viral transcription complexes to incorporate label into nascent (unprocessed) viral RNA yielded essentially identical results. This finding strongly suggests that the overproduction of early SV40 RNA occurs at the level of synthesis. While cytosine arabinoside effectively terminated most viral DNA replication in wild-type-infected cells, the ratio of early to late viral RNA remained less than 1:9. These results demonstrate that: (1) the amount of virus-specific RNA synthesized depends directly on the amount of viral DNA available for use as templates; once viral DNA replication has occurred, presumably providing progeny SV40 DNA molecules for templates, the level of transcription remains high; (ii) termination of viral DNA replication does not terminate late SV40 transcription; (iii) early SV40 RNA is overproduced by tsA 58 at all temperatures, but especially at higher temperatures; and (iv) overproduction of early SV40 RNA appears to be correlated with defectiveness of the tsA mutant T-antigen. These results suggest that T-antigen may regulate its own production either by repressing the synthesis of early viral RNA or by stimulating the synthesis of late SV40 RNA or both.