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

Transcription of adenovirus type 2 genes in a cell-free system: apparent heterogeneity of initiation at some promoters

We examined the transcription of a variety of adenovirus type 2 genes in a cell-free system containing purified ribonucleic acid polymerase II and a crude extract from cultured human cells. The early EIA, EIB, EIII, and EIV genes and the intermediate polypeptide IX gene, all of which contain a recognizable TATAA sequence upstream from the cap site, were actively transcribed in vitro, albeit with apparently different efficiencies, whereas the early EII (map position 74.9) and IVa2 genes, both of which lack a TATAA sequence, were not actively transcribed. A reverse transcriptase-primer extension analysis showed that the 5' ends of the in vitro transcripts were identical to those of the corresponding in vivo ribonucleic acids and that, in those instances where initiation was heterogeneous in vivo, a similar kind of heterogeneity was observed in the cell-free system. Transcription of the polypeptide IX gene indicated that this transcript was not terminated at, or processed to, the polyadenylic acid addition site in vitro. We also failed to observe, using the in vitro system, any indication of transcriptional regulation based on the use of adenovirus type 2-infected cell extracts.

Efficient dual transcomplementation of adenovirus E1 and E4 regions from a 293-derived cell line expressing a minimal E4 functional unit

Transgene expression after the administration of recombinant adenovirus with E1 deleted is constantly transient. It is admitted that E1A-substituting activities of cellular or viral origin allow viral antigen synthesis and trigger cytotoxic lymphocyte-mediated clearance of the recipient cells. Our approach to solving this problem relies on the additional deletion of the E4 region from the vector backbone as this region upregulates viral gene expression at both transcriptional and posttranscriptional levels. As a prerequisite to the construction of E1 E4 doubly defective adenoviruses, we investigated the possibility of transcomplementing both functions within a single cell. In particular, the distal ORF6+ORF7 segment from the E4 locus of adenovirus type 5 was cloned under the control of the dexamethasone-inducible mouse mammary tumor virus long terminal repeat. Following transfection into 293 cells, clone IGRP2 was retained and characterized as it can rescue the growth defect of all E1+ E4- adenoviral deletants tested. DNA and RNA analysis experiments verified that the mouse mammary tumor virus promoter drives the expression of the ORF6+ORF7 unit and permits its bona fide alternative splicing, generating ORF6/7 mRNA in addition to the ORF6-expressing primary transcript. Importantly, IGRP2 cells sustain cell confluence for a period longer than that of 293 parental cells and allow the plaque purification of E1- or E4- defective viruses. The dual expression of E1 and E4 regulatory genes within IGRP2 cells is demonstrated by the construction, plaque purification, and helper-free propagation of recombinant lacZ-encoding doubly defective adenoviruses harboring different E4 deletions. In addition, the emergence, if any, of replicative particles during viral propagation in this novel packaging cell line will be drastically impaired as only a limited segment of E4 has been integrated.

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.

Different biological activities of the hetero- and homodimers formed by the 47- and 43-kilodalton proteins of transcription factor ATF/E4TF3

The transcription factor ATF/E4TF3 stimulates transcription from the adenovirus early region 4 (E4) promoter by binding to specific promoter elements. Among the multiple forms of ATF/E4TF3, two forms with molecular masses of 47 and 43 kDa, which are most active in transcription in vitro from the E4 promoter, have been purified to homogeneity from HeLa cells by sequence-specific DNA affinity chromatography and biochemically characterized. Each purified protein formed a homodimer. These two homodimers were easily altered into a heterodimer when mixed together in the absence, but not in the presence, of the specific DNA sequence. All of these dimers were able to activate transcription in vitro from the E4 promoter by binding to the specific DNA sequence. Their activities to bind to DNA or stimulate transcription were different. The ability of the 47-kDa homodimer to stimulate transcription in vitro from the E4 promoter was approximately nine and three times higher than the abilities of the 43 kDa homodimer and the heterodimer, respectively, at the same level of DNA-binding activity. However, the affinity of the 47-kDa homodimer for DNA was lower than that of the 43-kDa homodimer, and the heterodimer had intermediate affinity. These results are the first to show differential binding and transcriptional activation activities of the different dimers of ATF/E4TF3, using purified cellular proteins rather than cloned gene products.

Effect of DNA supercoiling on in vitro transcription from the adenovirus early region 4

The effect of DNA supercoiling on in vitro transcription from the early region 4 (E4) promoter of adenovirus type 5 (Ad5) has been investigated by using a cell-free transcription system that maintains supercoiled DNA templates. The supercoiled DNAs yield several-fold higher levels of E4 transcripts and more faithfully reflect the regulation of in vivo transcription than the linear DNAs.

Identification of two transcription factors that bind to specific elements in the promoter of the adenovirus early-region 4

Two kinds of trans-acting factors that regulate transcription from the promoter of the adenovirus early-region 4 (E4) have been identified by reconstituting nuclear extracts of HeLa cells. They were designated E4TF1 and E4TF3 for E4 transcription factors. These factors were responsible for efficient and accurate transcription in vitro from the E4 promoter, as were another transcription factor, designated E4TF2, and a crude fraction containing endogenous RNA polymerase II. E4TF1 stimulated transcription from the E4 promoter but not from the major late promoter or the E4 mutant promoter lacking the E4TF1-binding site. Footprint analysis of E4TF1 revealed that it binds to a specific region, residing between 132 and 152 base pairs upstream from the initiation site of the E4 mRNA. E4TF3 also regulated transcription from the E4 promoter. E4TF3 protected four ca. 20-base-pair regions in a DNase I footprinting assay. They were located around 40, 160, 230, and 260 base pairs upstream from the initiation site of E4 mRNA. Specific inhibition of E4 transcription was observed by addition of DNA fragments covering one of the E4TF1- and E4TF3-binding sites to in vitro transcription assays. These results suggest that both E4TF1 and E4TF3 regulate E4 transcription by binding to the specific upstream elements in the E4 promoter. These factors may be involved in the E1A transactivation of E4 transcription.

Identification of two transcription factors that bind to specific elements in the promoter of the adenovirus early-region 4

Two kinds of trans-acting factors that regulate transcription from the promoter of the adenovirus early-region 4 (E4) have been identified by reconstituting nuclear extracts of HeLa cells. They were designated E4TF1 and E4TF3 for E4 transcription factors. These factors were responsible for efficient and accurate transcription in vitro from the E4 promoter, as were another transcription factor, designated E4TF2, and a crude fraction containing endogenous RNA polymerase II. E4TF1 stimulated transcription from the E4 promoter but not from the major late promoter or the E4 mutant promoter lacking the E4TF1-binding site. Footprint analysis of E4TF1 revealed that it binds to a specific region, residing between 132 and 152 base pairs upstream from the initiation site of the E4 mRNA. E4TF3 also regulated transcription from the E4 promoter. E4TF3 protected four ca. 20-base-pair regions in a DNase I footprinting assay. They were located around 40, 160, 230, and 260 base pairs upstream from the initiation site of E4 mRNA. Specific inhibition of E4 transcription was observed by addition of DNA fragments covering one of the E4TF1- and E4TF3-binding sites to in vitro transcription assays. These results suggest that both E4TF1 and E4TF3 regulate E4 transcription by binding to the specific upstream elements in the E4 promoter. These factors may be involved in the E1A transactivation of E4 transcription.

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.

Regulation of in vitro and in vivo transcription of early-region IV of adenovirus type 5 by multiple cis-acting elements

A series of deletion mutants spanning the promoter of the adenovirus early-region IV (EIV) gene were tested for transcriptional activity, using both in vitro and in vivo assays. Four distinct domains had additive effects on efficient transcription from the EIV promoter in HeLa whole-cell extracts. The first resided 20 to 27 bases upstream of the initiation site and included the TATA box. Deletion of the TATA box drastically reduced the transcriptional activity in vitro but had a lesser effect in vivo. The second region extended from -32 to -177 and contained two 17-base-pair inverted repeats, centered around -40 and -162. Sequences lying between -140 and -173 were important for efficient transcription since deletion of this region reduced the activity fourfold. Deletion of either one of the two inverted repeats or insertion of DNA fragments between them resulted in the synthesis of extra transcripts that initiated at sites upstream from the EIV site. The third region was located between -198 and -250 and contains three guanosine-plus-cytosine-rich sequences, present around -212 (GGGCGG), -233 (GGGCGG), and -251 (CGCGGG). The fourth, most upstream region was located between -260 and -307. Deletion of this region, which contains the NF-1 factor-binding site, slightly reduced transcriptional activity both in vivo and in vitro. The data indicate that multiple cis-acting elements are required for efficient transcription from the EIV promoter in both in vitro and in vivo systems.

Regulation of in vitro and in vivo transcription of early-region IV of adenovirus type 5 by multiple cis-acting elements

A series of deletion mutants spanning the promoter of the adenovirus early-region IV (EIV) gene were tested for transcriptional activity, using both in vitro and in vivo assays. Four distinct domains had additive effects on efficient transcription from the EIV promoter in HeLa whole-cell extracts. The first resided 20 to 27 bases upstream of the initiation site and included the TATA box. Deletion of the TATA box drastically reduced the transcriptional activity in vitro but had a lesser effect in vivo. The second region extended from -32 to -177 and contained two 17-base-pair inverted repeats, centered around -40 and -162. Sequences lying between -140 and -173 were important for efficient transcription since deletion of this region reduced the activity fourfold. Deletion of either one of the two inverted repeats or insertion of DNA fragments between them resulted in the synthesis of extra transcripts that initiated at sites upstream from the EIV site. The third region was located between -198 and -250 and contains three guanosine-plus-cytosine-rich sequences, present around -212 (GGGCGG), -233 (GGGCGG), and -251 (CGCGGG). The fourth, most upstream region was located between -260 and -307. Deletion of this region, which contains the NF-1 factor-binding site, slightly reduced transcriptional activity both in vivo and in vitro. The data indicate that multiple cis-acting elements are required for efficient transcription from the EIV promoter in both in vitro and in vivo systems.

Transcription control region within the protein-coding portion of adenovirus E1A genes

A single-base deletion within the protein-coding region of the adenovirus type 5 early region 1A (E1A) genes, 399 bases downstream from the transcription start site, depresses transcription to 2% of the wild-type rate. Complementation studies demonstrated that this was due to two effects of the mutation: first, inactivation of an E1A protein, causing a reduction by a factor of 5; second, a defect which acts in cis to depress E1A mRNA and nuclear RNA concentrations by a factor of 10. A larger deletion within the protein-coding region of E1A which overlaps the single-base deletion produces the same phenotype. In contrast, a linker insertion which results in a similar truncated E1A protein does not produce the cis-acting defect in E1A transcription. These results demonstrate that a critical cis-acting transcription control region occurs within the protein coding sequence in adenovirus type 5 E1A. The single-base deletion occurs in a sequence which shows extensive homology with a sequence from the enhancer regions of simian virus 40 and polyomavirus. This region is not required for E1A transcription during the late phase of infection.

Transcription control region within the protein-coding portion of adenovirus E1A genes

A single-base deletion within the protein-coding region of the adenovirus type 5 early region 1A (E1A) genes, 399 bases downstream from the transcription start site, depresses transcription to 2% of the wild-type rate. Complementation studies demonstrated that this was due to two effects of the mutation: first, inactivation of an E1A protein, causing a reduction by a factor of 5; second, a defect which acts in cis to depress E1A mRNA and nuclear RNA concentrations by a factor of 10. A larger deletion within the protein-coding region of E1A which overlaps the single-base deletion produces the same phenotype. In contrast, a linker insertion which results in a similar truncated E1A protein does not produce the cis-acting defect in E1A transcription. These results demonstrate that a critical cis-acting transcription control region occurs within the protein coding sequence in adenovirus type 5 E1A. The single-base deletion occurs in a sequence which shows extensive homology with a sequence from the enhancer regions of simian virus 40 and polyomavirus. This region is not required for E1A transcription during the late phase of infection.

Requirement for distal upstream sequences for maximal transcription in vitro of early region IV of adenovirus

A series of deletion mutants spanning the adenovirus early region IV (EIV) promoter were tested for transcription activity in vitro. At least three elements were found to be important for maximal transcription in HeLa whole-cell extracts. Deletion of the TATA box drastically reduced the transcription activity from the EIV promoter. Sequences between nucleotides -58 and -44 are also important for efficient transcription since deletion of this region reduced activity by 50%. More importantly, sequences residing upstream from -140 critically influence the level of EIV transcription. Deletion of sequences between nucleotides -325 (the right terminus of adenovirus genome) and -140 reduced the level of transcription more than 10-fold. It is possible that a specific cellular factor stimulates EIV transcription by recognition of these upstream sequences. The dependence of transcription from the EIV promoter on a distal upstream element may explain some aspects of the regulation of this promoter.

Accelerated onset of viral transcription in adenovirus-infected HeLa cells treated with the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate

When adenovirus type 5-infected HeLa cells were exposed to the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate, short pulse-labeling with [3H]uridine in vivo and [3H]UTP incorporation by isolated nuclei in vitro were both consistent with a decreased latent period before initiation by RNA polymerase at early viral promoters. Acceleration was not dependent upon concurrent protein synthesis and could not be attributed to rapid entry of virus into the cell nucleus. 12-O-tetradecanoyl-phorbol-13-acetate suppressed the transcription-delay phenotype of the E1a mutant, hr1, without restoring its ability to replicate.

Requirement for distal upstream sequences for maximal transcription in vitro of early region IV of adenovirus

A series of deletion mutants spanning the adenovirus early region IV (EIV) promoter were tested for transcription activity in vitro. At least three elements were found to be important for maximal transcription in HeLa whole-cell extracts. Deletion of the TATA box drastically reduced the transcription activity from the EIV promoter. Sequences between nucleotides -58 and -44 are also important for efficient transcription since deletion of this region reduced activity by 50%. More importantly, sequences residing upstream from -140 critically influence the level of EIV transcription. Deletion of sequences between nucleotides -325 (the right terminus of adenovirus genome) and -140 reduced the level of transcription more than 10-fold. It is possible that a specific cellular factor stimulates EIV transcription by recognition of these upstream sequences. The dependence of transcription from the EIV promoter on a distal upstream element may explain some aspects of the regulation of this promoter.

Accelerated onset of viral transcription in adenovirus-infected HeLa cells treated with the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate

When adenovirus type 5-infected HeLa cells were exposed to the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate, short pulse-labeling with [3H]uridine in vivo and [3H]UTP incorporation by isolated nuclei in vitro were both consistent with a decreased latent period before initiation by RNA polymerase at early viral promoters. Acceleration was not dependent upon concurrent protein synthesis and could not be attributed to rapid entry of virus into the cell nucleus. 12-O-tetradecanoyl-phorbol-13-acetate suppressed the transcription-delay phenotype of the E1a mutant, hr1, without restoring its ability to replicate.

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.

Independent, spontaneous mutants of adenovirus type 2-simian virus 40 hybrid Ad2+ND3 that grow efficiently in monkey cells possess indentical mutations in the adenovirus type 2 DNA-binding protein gene

Four independent, spontaneous mutants of the adenovirus type 2-simian virus 40 hybrid Ad2+ND3 that allow efficient growth in monkey cells were isolated previously (C. W. Anderson, Virology 111:263-269, 1981). All four mutations have been mapped within the coding sequence for the adenovirus DNA-binding protein by marker rescue analysis. DNA sequence analysis of a region of ca. 1,000 base pairs shown by marker rescue to contain the host range mutations demonstrated that the host range mutant hr602 differs from its parent, Ad2+ND3, at only a single nucleotide. Mutant hr602 has a thymine in place of a cytosine at the first position of the 130th codon, as measured from the initiation site for the DNA-binding protein. This change results in the replacement of a histidine by a tyrosine in mutant hr602 DNA-binding protein. Each of the other three Ad2+ND3 host range mutants have exactly the same nucleotide alteration as does hr602. This same nucleotide change was recently reported for a similarly derived host range mutant of adenovirus 5.

Inhibition of adenovirus early region IV transcription in vitro by a purified viral DNA binding protein

Adenoviruses depend on cellular mechanisms for the decoding of their genetic information, and so provide a useful and simple model system for the investigation of mammalian gene expression. The five regions transcribed early in adenovirus infection are termed EIa, EIb, EII, EIII and EIV. We report here that the primary product of the EII region, a 72,000 molecular weight DNA-binding protein (DBP), specifically represses transcription from the EIV promoter in an in vitro transcription system. Single-stranded DNA binds to the DBP with high affinity, and as a result inhibits its repressor activity. Our data extend previous genetic evidence that the DBP represses EIV transcription in vivo, and suggest that it acts directly by suppressing transcription from the EIV promoter.

Structural characterization of the proteins encoded by adenovirus early region 2A

Proteins encoded by adenovirus type 2 and type 5 early region 2A isolated from infected HeLa cells were compared to translation products of E2A-specific messenger RNA in a reticulocyte cell-free system and in Xenopus oocytes. The main cell-free translation product is a 72,000 Mr polypeptide which in HeLa cells as well as in Xenopus oocytes is converted into a 75,000 Mr phosphoprotein capable of binding to single-stranded DNA. Some minor proteins are proteolytic cleavage products of the major protein. In the cell-free system, three E2A polypeptides, 32,000, 37,000 and 44,000 Mr, are translated from minor polyadenylated mRNA species that can be separated from the major mRNA. Synthesis of all E2A polypeptides in vitro is inhibited by cap-analogs. The 44,000 Mr protein is also synthesized in Xenopus oocytes. Tryptic peptide maps of [35S]methionine-labeled E2A proteins were constructed using high pressure liquid chromatography and the position of the methionyl residues within each peptide was determined by amino acid sequencing procedures. This information and the DNA sequence of the adenovirus 5 E2A gene published by Kruijer et al. (1981) were used to align the peptides and to construct a map of the E2A proteins. Our data demonstrate that the major 75,000 Mr protein is coded for by a leftward reading frame of 529 amino acid residues located between 62 and 66 map units. The data also map six sites as targets for proteolytic enzymes. The minor E2A translation products have the same carboxy terminus as the major protein. The initiation codons of the 44,000, 37,000 and 32,000 Mr polypeptides probably correspond to amino acids 170, 243 or 244 and 290 of the major protein. Some functional properties of the major E2A protein are shared by the minor proteins and thus could be mapped. Major sites of phosphorylation, the region involved in binding to single-stranded DNA and the antigenic regions recognized by immune sera are located between amino acid residues 50 to 120, 170 to 470 and 170 to 240, respectively.

Synthesis of human adenovirus early RNA species is similar in productive and abortive infections of monkey and human cells

Northern (RNA) blot analysis has been used to show that synthesis of early mRNA species is similar in monkey cells productively or abortively infected with human adenovirus. mRNA species from all five major early regions (1A, 1B, 2, 3, 4) are identical in size and comparable in abundance whether isolated from monkey cells infected with adenovirus type 2 or with the host range mutant Ad2hr400 or coinfected with adenovirus type 2 plus simian virus 40. The mRNA species isolated from monkey cells are identical in size to those isolated from human cells. Production of virus-associated RNA is also identical in productive and abortive infections of monkey cells. Synthesis of virus-associated RNA is, however, significantly greater in HeLa cells than in CV1 cells at late times after infection regardless of which virus is used in the infection.

Transcription of adenovirus type 2 genes in a cell-free system: apparent heterogeneity of initiation at some promoters

We examined the transcription of a variety of adenovirus type 2 genes in a cell-free system containing purified ribonucleic acid polymerase II and a crude extract from cultured human cells. The early EIA, EIB, EIII, and EIV genes and the intermediate polypeptide IX gene, all of which contain a recognizable TATAA sequence upstream from the cap site, were actively transcribed in vitro, albeit with apparently different efficiencies, whereas the early EII (map position 74.9) and IVa2 genes, both of which lack a TATAA sequence, were not actively transcribed. A reverse transcriptase-primer extension analysis showed that the 5' ends of the in vitro transcripts were identical to those of the corresponding in vivo ribonucleic acids and that, in those instances where initiation was heterogeneous in vivo, a similar kind of heterogeneity was observed in the cell-free system. Transcription of the polypeptide IX gene indicated that this transcript was not terminated at, or processed to, the polyadenylic acid addition site in vitro. We also failed to observe, using the in vitro system, any indication of transcriptional regulation based on the use of adenovirus type 2-infected cell extracts.

Coordinate regulation of two cytoplasmic RNA species transcribed from early region 2 of the adenovirus 2 genome

Early region 2 (E2) of the adenovirus 2 genome specifies a 72,000-dalton DNA-binding protein that is required for viral DNA replication. Electron microscopy studies have detected two major forms of 20S E2 mRNA, one species with a 5' leader from map position 75 and a second form having a leader from position 72 (Chow et al., J. Mol. Biol. 134:265-303, 1979). Only the species with a leader from position 75 was detected at early times; however, both forms were found at late times. We have analyzed the temporal regulation of E2 expression by documenting mRNA accumulation in the cytoplasm. Kinetic studies of pulse-labeled RNAs demonstrated a peak of E2 cytoplasmic RNa synthesis at 10 to 12 h, coinciding with the time of maximal synthesis of the 72,000-dalton DNA binding protein and viral DNA. To estimate the relative abundances of the two major E2 RNA species at various times during infection, total E2 cytoplasmic and polysomal 20S RNAs were isolated by hybridization-selection with specific DNA probes. The leader sequences in the selected RNAs were then quantitated by further RNA-DNA hybridization. We found that the elevated accumulation rate for E2 cytoplasmic RNA at late times reflected an increase in formation of both major species. Moreover, for all time points examined 66% of the mRNA species had a 5' end from map position 75, and 33% had a 5' terminus from position 72. Continuous labeling experiments provided evidence that both RNA forms have comparable half-lives. The results suggest that the two major species encoded by E2 are regulated in a coordinate fashion late in infection.

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.

Transcripts from the adenovirus-2 major late promoter yield a single early family of 3' coterminal mRNAs and five late families

The major late promoter of adeovirus-2 is located at coordinate 16.45 and initiates synthesis of nuclear precursors that are processed into mRNAs which fall into five 3- co-terminal families, L1-L5. These mRNAs all share a common tripartite 5' leader with a capped terminus encoded at th RNA initiation site. We show that the coorindate 16.45 RNA initiation site is also an early promoter, and yields transcripts detectable as early as 1 hr post-infection, prior to DNA replication and the early-late switch at 6-8 hr. Polyadenylated cytoplasmic RNA from the first 3- co-terminal family, L1, is also produced from the earliest stages of infection. L1 mRNA accumulates in the cytoplasm in the presence of cycloheximide, which blocks DNA replication and the onset of the late phase. Early nuclear RNA contains the same capped 5' terminal RNAase T-1 undecanucleotide and promoter proximal oligonucleotides present in late transcripts. This implies that precisely the same transcription start site is utilized for early L1 mRNA synthesis as is used during the late stage for L1-L5 late mRNA synthesis. In contrast to the early apperance of L1 mRNA, neither L2 nor L3 mRNAs are detected until 5-6 hr post infection. We cnclude that a major event in the Ad-2 early-late switch is a novel form of control which activates L2-L5 mRNA production.

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.

Adenovirus helper function for growth of adeno-associated virus: effect of temperature-sensitive mutations in adenovirus early gene region 2

Adeno-associated virus (AAV) grows efficiently only in cells that are also infected with an adenovirus (Ad). We employed Ad mutants to determine which genes may be required for the AAV helper function. Two mutants of Ad type 5 (Ad5), Ad5ts125 and Ad5ts107, with temperature-sensitive lesions in the E72 DNA-binding protein coded by the Ad early region 2, were deficient for AAV helper functions at the nonpermissive temperature (40 degrees C). In contrast, Ad5ts149, with a temperature-sensitive lesion in the Ad early region 5, was an efficient helper of AAV at the nonpermissive temperature. In KB cells, with the Ad5ts125 or Ad5ts107 mutant as the helper, the accumulation of AAV capsid proteins and AAV particles was decreased by about two logs, whereas AAV DNA synthesis was decreased only severalfold. Cytoplasmic, polyadenylic acid-containing AAV RNA is composed of a set of overlapping, spliced RNAs having different 5' start points. With the ts125 helper at 40 degrees C there was a decreased accumulation of some but not all of these AAV RNAs. The Ad5 E72 protein may have an effect on transcription or more likely posttranscriptional processing of AAV RNA. These observations suggest additional pleiotropic effects of the multifunctional E72 protein and suggest further similarities in the actions of E72 and the simian virus 40 T-antigen.

Regulation of early adenovirus transcription: a protein product of early region 2 specifically represses region 4 transcription

An aspect of the regulation of early adenovirus gene expression has been studied by measuring the rates of transcription of several viral transcription units during infection by wild-type (WT) adenovirus type 5 and a temperature-sensitive mutant, H5ts125. It has previously been shown that two transcription units (regions 2 and 4) are subject to negative control. During the course of early infection, transcription of regions 2 and 4 increased to a maximal rate and then declined. The decline from each of these transcription units appeared to be a specific shutoff of transcription, because the transcription of another early transcription unit (region 1A) remained constant during early infection and, in the absence of protein synthesis, the apparent shutoff of region 2 and region 4 transcription did not occur. At the nonpermissive temperature for the mutant, the kinetics of transcription of early region 2 were identical to the kinetics of transcription of WT. Thus, the repression of transcription of region 2 occurred in H5ts125-infected cells as well as in WT-infected cells. Region 4 transcription, however, was not repressed during H5ts125 infection at the nonpermissive temperature. After a maximal rate of transcription was reached, this rate was maintained throughout the course of the experiment. Furthermore, the repression of region 4 transcription appears to be the result of a block of initiation of transcription rather than the result of an inducement of premature termination of transcription. Therefore, it can be concluded that a product of the adenovirus region 2 gene, which is the site of the mutation for H5ts125, is responsible for the specific shutoff of region 4 transcription.

Regulation of the primary expression of the early adenovirus transcription units

The time course of appearance of transcriptional activity from five early adenovirus type 2 transcription units has been determined. RNA complementary to region 1A (1-4.4 map units), the first region to be transcribed, was detectable at 45 min after infection; a maximal rate of RNA synthesis was reached at 3 h after infection and was maintained thereafter for at least 6 h. RNA from region 2 (75-56 map units), which encodes the mRNA for the 72,000-dalton DNA-binding protein, was the last to be synthesized; transcription commenced at about 2 h postinfection, reached a maximum at 7 h, and then declined. Transcription of regions 3 (76-86 map units) and 4 (99-91 map units) reached a maximal value at 3 h postinfection. The rates of RNA synthesis from these regions then declined over the next 6 h. The decline of transcription from regions 2 and 4 appeared to be a specific repression of these transcription units. The repression did not occur in the absence of protein synthesis, suggesting that a viral protein might be involved. Transcription of all early regions was initiated and continued for at least 2 to 3 h in cells that were treated with cycloheximide or emetine before and during infection, suggesting that at least the initiation of RNA synthesis from the five early adenovirus type 2 transcription units does not depend on the formation of a viral protein. Moreover, mRNA was formed in the absence of protein synthesis that hybridized to DNA fragments representing each of the five early transcription units. The increase in mRNA accumulation in the presence of cycloheximide (or emetine) does not appear to be due to increased RNA synthesis; thus, either increased mRNA stability or increased efficiency of nuclear RNA processing must occur.

Messenger RNA for the Ad2 DNA binding protein: DNA sequences encoding the first leader and heterogenity at the mRNA 5' end

During the early stage of Ad2 infection of human cells, RNA is transcribed from five separate transcription units. Early region II encodes the mRNA for a 72K single-stranded DNA binding protein (DBP) which functions in DNA replication. This report describes the structure of the first leader of the DBP mRNA and the flanking sequences in the DNA. The leader, labeled in vivo with 32P, was isolated by DNA filter hybridization to the viral restriction fragment Eco RI F, and its RNAase T1 and RNAase A oligonucleotides were analyzed by RNA fingerprinting techniques. Comparison of this RNA sequence information with the DNA sequence of Eco RI F has located a 68 nucleotide region of the Hae III C subfragment at coordinate 75.1 that encodes the leader. This position is near the coordinate to which nascent chain analysis and ultraviolet transcription mapping have mapped an RNA initiation site, or promoter, for the DBP mRNA. The DNA sequence that overlaps the leader on the 3' side contains a donor sequence for splicing this leader to a second downstream leader. The splicing sequence shows a seven base homology with the comparable structure of the Ad2 major late leader, and a mouse globin mRNA splicing sequence. The DNA sequence upstream from the cap, the region oof the potential promoter site does not, however, contain a "TA-TAAA"-type homology of the sort noted by D. Hogness, M. Goldberg and R. Lifton (personal communication) for many cellular transcription units, and by other investigations for the Ad2 major late transcription unit. Also, the leader is found with two distinct capped 5' termini, 7meGpppA and 7meGpppG, which are encoded at adjacent positions in the DNA and thus are from mRNAs which are staggered by one nucleotide in length at the 5' end. The staggering at the 5' terminus and the lack of the upstream homolgy distinguish the DBP mRNA from many viral and cellular messenger. In both these respects, however, the DBP mRNA resembles the late messengers of SV40 and polyoma viruses. In this paper, we discuss the implications of these findings for the mechanism of specifying mRNA 5' ends.