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

Mutations in the adenovirus major late promoter: effects on viability and transcription during infection

We developed an experimental system to examine the effects of mutations in the adenovirus major late promoter in its correct genomic location during a productive infection. A virus was constructed whose genome could be digested to give a rightward terminal DNA fragment extending from the XhoI site at 22.9 map units, which can be ligated or recombined with plasmid DNA containing adenovirus sequences extending from 0 to 22.9 or 26.5 map units, respectively. Mutations were made by bisulfite mutagenesis in the region between base pairs -52 and -12 with respect to the cap site at +1 and transferred to the appropriate plasmids for viral reconstruction. Of 19 mutant plasmid sequences containing single or multiple G-to-A transitions, 14 could be placed in the viral genome with no apparent change in phenotype. These mutant sequences included those which contained four transitions in the string of G residues immediately downstream of the TATA box. There were no alterations in rates of transcription from the major late promoter, sites of transcription initiation, or steady-state levels of late mRNAs. All of the five mutant sequences which could not be placed in virus contained multiple transitions both up- and downstream of the TATA box. Two of these apparently lethal mutant sequences were used in promoter fusion experiments to test their ability to promote transcription of rabbit beta-globin sequences placed in the dispensable E1 region of the virus. Both sequences showed diminished ability compared with wild-type sequences to promote transcription in this context. Comparisons between these two sequences and the viable mutant sequences suggest a role for the string of G residues located between -38 and -33 in promoting transcription from the major late promoter. The data as a whole also demonstrate that the specific nucleotide sequence of this region of the major late promoter, which overlaps transcription elements of the divergent IVa2 transcription unit and coding sequences of the adenovirus DNA polymerase, is not rigidly constrained but can mutate extensively without loss of these several functions.

Partition of E1A proteins between soluble and structural fractions of adenovirus-infected and -transformed cells

The partition of E1A proteins between soluble and structural framework fractions of human cells infected or transformed by subgroup C adenoviruses was investigated by using gentle cell fractionation conditions. A polyclonal antibody raised against a trpE-E1A fusion protein (K.R. Spindler, D.S.E. Rosser, and A. J. Berk, J. Virol. 132-141, 1984) synthesized in Escherichia coli was used to measure the steady-state levels of E1A proteins recovered in the various fractions by immunoblotting. The relative concentration of E1A proteins recovered in the soluble fraction of adenovirus type 2-infected cells was at least fivefold greater than the relative concentration in the corresponding fraction of transformed 293 cells. The observed distribution of E1A proteins was not altered by the sulfhydryl-blocking reagent N-ethylmaleimide. E1A proteins were recovered in nuclear matrix, chromatin, and cytoskeleton fractions after further fractionation of the structural framework fraction. However, the E1A protein species that could be identified by one-dimensional gel electrophoresis were not uniformly distributed among the subcellular fractions examined. The results obtained when fractionation was performed in the presence of the oxidation catalysts Cu2+ or (ortho-phenanthroline)2 Cu2+ indicate that E1A proteins can be efficiently cross-linked, via disulfide bonds, to the structural framework of both adenovirus-infected and adenovirus-transformed cells.

Genetic analysis of mRNA synthesis in adenovirus region E3 at different stages of productive infection by RNA-processing mutants

Region E3 of adenovirus encodes about nine overlapping mRNAs (a to i) with different spliced structures and with two major RNA 3' end sites termed E3A and E3B. Synthesis of E3 mRNAs was examined by the nuclease-gel procedure at early and late stages of infection by wild-type virus (rec700) and by several E3 deletion mutants. Our results, together with those obtained by electron microscopy (L. T. Chow, T. R. Broker, and J. B. Lewis, J. Mol. Biol. 134:265-303, 1979), suggest that E3 may be differentially regulated at early and late stages at both the promoter and RNA-processing levels. Early after infection, the E3 promoter is used to make mainly mRNAs a and h. Late after infection, the E3 promoter appears to be shut off and the major late promoter is used to make mainly mRNAs d and e. The late L4 mRNA 3' end site is not used early even though early E3 pre-mRNAs transcribe through the L4 RNA 3' end site. The nucleotide 768-951 exon, which is the y leader on many L5 mRNAs, is very abundant late. (Nucleotide +1 is the major E3 transcription initiation site.) Early after infection, the 951 5' splice site is enhanced 5- to 10-fold in the dl712 (delta 1691 to 2122) group of mutants; late after infection, these mutants resemble the wild type. We speculate that the activity of the 951 5' splice site is regulated at early and late stages; it is suppressed early to permit synthesis of mRNA a, and it is activated late to permit synthesis of mRNAs d, e, and L5. With dl719 (delta 2173 to 2237), the 951----2157 splice is enhanced both early and late; we suggest that this deletion enhances the 2157 3' splice site.

Vector expression of adenovirus type 5 E1a proteins: evidence for E1a autoregulation

We transiently expressed adenovirus type C E1a proteins in wild-type or mutant form from plasmid vectors which have different combinations of E1a and simian virus 40 enhancer elements and which contain the DNA replication origin of SV40 and can replicate in COS 7 cells. We measured the levels of E1a mRNA encoded by the vectors and the transition regulation properties of the protein products. Three vectors encoded equivalent levels of E1a mRNA in COS 7 cells: (i) a plasmid encoding the wt 289-amino acid E1a protein (this complemented the E1a deletion mutant dl312 for early region E2a expression under both replicative and nonreplicative conditions); (ii) a vector for the wt 243-amino acid E1a protein (this complemented dl312 weakly and only under conditions of high multiplicities of dl312); (iii) a mutant, pSVXL105, in which amino acid residues-38 through 44 of the 289-amino acid E1a protein (which includes two highly conserved residues) are replaced by 3 novel amino acids (this also complemented dl312 efficiently). A fourth vector, mutant pSVXL3 with which linker substitution shifts the reading frame to encode a truncated 70-amino acid fragment from the amino terminus of the 289-amino acid protein, was unable to complement dl312. Surprisingly, pSVXL3 overexpressed E1a mRNA approximately 30-fold in COS 7 cells in comparison with the other vectors. The pSVXL3 overexpression could be reversed by cotransfection with a wt E1a vector. We suggest that wt E1a proteins regulate the levels of their own mRNAs through the recently described transcription repression functions of the 289- and 243-amino acid E1a protein products and that pSVXL3 fails to autoregulate negatively.

Transcription unit mapping in adenovirus: regions of termination

Using a series of single-stranded clones of adenovirus DNA, we determined the extent of RNA polymerase II transit early in infection for two rightward-reading transcription units. RNA synthesis beginning at the major late promoter (16.5 on the genomic map) continued until approximately 65 to 70 map units so that differential choices of mRNAs within that region were not based primarily on transcriptional decisions but rather on posttranscriptional decisions. Transcription from the major late promoter beginning at 16.5 map units, however, did greatly decrease before approximately 75 map units, ensuring that no mRNAs were formed with sequences beyond approximately 75 map units. Early transcription from E3 then began just past 75 map units (at a higher rate than transcription from the major late promoter); E3 transcripts terminated at least 2 kilobases downstream from a second and final poly(A) site in this transcription unit. The effectiveness of termination in E3 was greater than 95 to 99%.

Structure and function of the S1 nuclease-sensitive site in the adenovirus late promoter

We analyzed an S1 nuclease-sensitive site present in supercoiled, but not linear, recombinant plasmids containing the adenovirus late promoter. S1 nicking was detected on both strands, primarily in the TATA box. Analysis of deletion mutants showed that sequences upstream of -47 and downstream of -12 are not required for S1 cutting. However, a number of different base substitution mutations in stretches of G residues upstream and/or downstream of the TATA box were sufficient to eliminate S1 cutting. When the transcriptional activities of these mutant promoters were assayed in vivo, six of seven mutants lacking the ability to form the S1-sensitive structure showed no reduction in transcriptional potential. In fact, several showed increased promoter activities. These data show that the S1 nuclease cutting site in the adenovirus late promoter has precise nucleotide sequence requirements for its formation. However, the ability of recombinant plasmids to adapt this conformation in vitro is not necessary for such plasmids to serve as templates for transcription in vivo.

Protein factor(s) binding independently to two different regions of the adenovirus 2 major late promoter

The protein factor(s) in a fraction from the HeLa cell nuclear extract required for specific in vitro transcription can specifically bind to adenovirus 2 major late promoter (Ad 2 MLP) DNA. We demonstrate by in vitro footprinting assay that there are two asymmetric protected regions covering the TATA box and the nucleotides upstream from the TATA box. In the coding strand, the DNAse I protected regions span from nucleotides -10 to -50 and from -52 to -68. In the noncoding strand, the protected regions span from nucleotides -10 to -32 and from -45 to -65. Using different Ad 2 MLP point mutants in this assay, we show that the transcriptional down mutants of the TATA box (AC-30 and AC-28) abolish the binding of protein factor(s) to the TATA box but do not affect binding in the upstream region. The new upstream transcriptional down mutant (TA-56) abolishes the binding of protein factor(s) in the upstream region but does not affect binding to the TATA box. The mutants which do not affect transcription efficiency (GA-51 and CG-61) do not modify the binding to either the TATA box or the upstream region. Methylation protection experiments show that the guanosines at -58 and -60 in the coding strand and at -57 (probably also -55) in the noncoding strand are in close contact with protein factor(s). The results indicate that the TATA box and its upstream region of Ad 2 MLP are independently bound by at least two different factors in vitro.

Biosynthesis and properties of the adenovirus 2 L1-encoded 52,000- and 55,000-Mr proteins

The adenovirus type 2 L1 region, which is located at 30.7 to 39.2 map units on the viral genome, is transcribed from the major late promoter during both early and late stages of virus replication, and a 52,000-Mr (52K) protein-55K protein doublet has been translated in vitro on L1-specific RNA. To investigate the biosynthesis and properties of the L1 52K and 55K proteins, we prepared antibody against a synthetic peptide encoded near the predicted N terminus. As determined by immunoprecipitation and immunoblot analysis, the antipeptide antibody recognized major 52K and 55K proteins synthesized in adenovirus type 2-infected cells that appeared to be identical to the 52K-55K doublet translated in vitro. The immunoprecipitated 52K and 55K proteins were very closely related, as shown by a peptide map analysis. Both L1 proteins were phosphorylated, and they were phosphorylated at similar sites. No precursor-product relationship was detected between the 52K and 55K proteins by a pulse-chase analysis. Biosynthesis of the L1 52K and 55K proteins began about 6 to 7 h postinfection, after biosynthesis of the early region 1A and early region 1B 19K (175R) T antigens, and reached a maximum rate at about 15 h; the maximum rate was maintained until at least 25 h postinfection. At all times, the 55K protein appeared to be synthesized at a severalfold-higher level than the 52K protein. Both proteins were quite stable and accumulated until late times after infection. Viral DNA replication was not essential for formation of the L1 proteins. Thus, the L1 52K-55K gene appears to be regulated in a manner different from the classical early and late viral genes but similar to the protein encoded by the i-leader (Symington et al., J. Virol. 57:849-856, 1986). The L1 proteins were detected in the cell nucleus by immunofluorescence microscopy with antipeptide antibody and were found to be primarily associated with the nuclear membrane by an immunoblot analysis of subcellular fractions.

Adenoviral early region 4 is required for efficient viral DNA replication and for late gene expression

H2dl808 is a defective deletion mutant of human adenovirus 2 lacking most of transcriptional early region 4. Although the mutant can be grown in the complementing cell line W162, it is defective in human cell lines normally used to propagate adenovirus. In such nonpermissive cells, H2dl808 exhibits a severe defect in late gene expression, accumulating very small amounts of viral late messages and producing correspondingly small amounts of viral late proteins. H2dl808 also exhibits a defect in viral DNA synthesis: 24 h after infection, H2dl808-infected nonpermissive cells contain five- to sevenfold less viral DNA than those cells infected with wild-type adenovirus. H2dl808-infected nonpermissive cells eventually accumulate a significant amount of viral DNA. However, the rate of synthesis of viral proteins late in mutant infection remains much lower than that observed in wild-type infection at a time when DNA accumulation is comparable. Thus, the mutant's late protein synthesis defect is probably not due solely to its reduced accumulation of viral DNA. Finally, H2dl808 is much less efficient than wild-type virus in the inhibition of host cell protein synthesis in infections of nonpermissive cells. These observations imply roles for early region 4 products in several aspects of the viral growth cycle, including DNA replication, late gene expression, and host cell shutoff.

Control of cellular and viral transcription during adenovirus infection

The control of transcription initiation is an issue central to the regulation of eukaryotic gene expression, and as such, the elucidation of the mechanisms of control of initiation frequency is critical. The study of adenovirus transcription control has provided insights into these mechanisms. Transcription of the early viral genes is activated by the product of the viral E1A gene. Possibly of greater importance is the fact that this activation does not appear to be "viral specific". Rather, the E1A protein effects a general activation of transcription in the cell, resulting in the stimulation of transcription of at least one cellular gene in addition to the viral genes. Furthermore, there appears to be a cellular activity that functions in a manner analogous to E1A. Recent experiments also suggest a role for E1A in negative regulation of transcription, mediated through enhancer elements, that may be one aspect of gene control during cellular differentiation. Therefore, the study of E1A action may well contribute to an understanding of cellular transcription control. Finally, other mechanisms of transcription control in adenovirus infected cells such as genome replication-dependent gene activation and transcription termination control will likely contribute to the overall understanding of the control of mammalian cell gene expression.

Anatomy of region L1 from adenovirus type 2

The structure of r-strand-specific RNAs encoded between coordinates 26 and 32 on the adenovirus type 2 genome was mapped by a combination of S1 endonuclease analysis, primer extension, and in vitro transcription. The region includes the third leader segment (coordinates 26.8 to 27.0), the genes for the low-molecular-weight virus-associated RNAs (VA RNAs) (coordinates 29.5 to 30.7), and the amino-terminal end of the gene for the L1 52,000-55,000 polypeptide (coordinates 30.7 to 32.1). The positions at which the tripartite leader was attached to the three longest L1 mRNAs were mapped at the nucleotide level. The leader splice junction of species L1a was located at coordinate 26.8 and coincided with the 3' splice site for the third leader segment, whereas the leader-body splice junction of species L1b and L1c were located at coordinates 29.0 and 30.7, respectively. No protein products have so far been assigned to the L1a and L1b mRNAs, although it can be predicted from the nucleotide sequence that species L1b encodes a 8,300 polypeptide. The third RNA, species L1c, encodes the well-characterized 52,000-55,000 polypeptide. It was also shown that a previously unidentified class of VA RNAs exists predominantly in the poly(A)-fraction of late RNA preparations. These RNAs are heterogeneous in length (up to 3,000 nucleotides) because of irregular transcription termination and have 5' ends which map precisely to the initiation sites for VA RNAI and VA RNAII transcription. Finally it was shown that an RNA with a 5' end coinciding with the 5' splice site for the third leader segment exists in the poly(A)-fraction of late cytoplasmic RNA. This RNA species might represent an excised intron.

Vector expression of adenovirus type 5 E1a proteins: evidence for E1a autoregulation

We transiently expressed adenovirus type C E1a proteins in wild-type or mutant form from plasmid vectors which have different combinations of E1a and simian virus 40 enhancer elements and which contain the DNA replication origin of SV40 and can replicate in COS 7 cells. We measured the levels of E1a mRNA encoded by the vectors and the transition regulation properties of the protein products. Three vectors encoded equivalent levels of E1a mRNA in COS 7 cells: (i) a plasmid encoding the wt 289-amino acid E1a protein (this complemented the E1a deletion mutant dl312 for early region E2a expression under both replicative and nonreplicative conditions); (ii) a vector for the wt 243-amino acid E1a protein (this complemented dl312 weakly and only under conditions of high multiplicities of dl312); (iii) a mutant, pSVXL105, in which amino acid residues-38 through 44 of the 289-amino acid E1a protein (which includes two highly conserved residues) are replaced by 3 novel amino acids (this also complemented dl312 efficiently). A fourth vector, mutant pSVXL3 with which linker substitution shifts the reading frame to encode a truncated 70-amino acid fragment from the amino terminus of the 289-amino acid protein, was unable to complement dl312. Surprisingly, pSVXL3 overexpressed E1a mRNA approximately 30-fold in COS 7 cells in comparison with the other vectors. The pSVXL3 overexpression could be reversed by cotransfection with a wt E1a vector. We suggest that wt E1a proteins regulate the levels of their own mRNAs through the recently described transcription repression functions of the 289- and 243-amino acid E1a protein products and that pSVXL3 fails to autoregulate negatively.

Repression of simian virus 40 early transcription by viral DNA replication in human 293 cells

The small DNA tumour virus simian virus 40 (SV40) has served as an excellent model for many studies on the mechanism and control of gene expression in eukaryotic cells. The SV40 early region produces two protein products. One product (large-T antigen) is known both to repress early viral transcription and to stimulate viral replication by binding to specific sites in the origin-promoter region. The early promoter has several similarities to other RNA polymerase II promoters, for example, it possesses a TATA box, an upstream element and an enhancer. However, the SV40 early promoter differs from other known RNA polymerase II promoters in that the origin of viral DNA replication is embedded within it. Here we show that the SV40 early region is expressed at an extremely low level following its introduction ito human 293 cells, contrasting with results observed in a large number of other cells lines. We show further that the lack of expression is due to repression of transcription from the SV40 early promoter by viral DNA replication which occurs efficiently in 293 cells.

Presence in infected cells of nonvirion proteins encoded by adenovirus messenger RNAs of the major late transcription regions L0 and L1

The adenovirus major late promoter functions at early and intermediate times to produce a limited set of mRNAs that appear in the cytoplasm of productively infected HeLa cells. These mRNAs may be translated in cell-free systems to produce two unrelated polypeptides of approximately 13,500 Mr (L0-13.5K and L0-13.6K) and a pair of related polypeptides of approximately 55,000 Mr (the L1-52K/55K proteins). Radiochemical protein sequence analysis of in vitro synthesized proteins has identified the N-terminal sequences of the L0-13.5K and L0-13.6K proteins (J. B. Lewis and C. W. Anderson (1983), Virology 127, 112-123). Additional sequence analyses confirmed the identification of the open reading frame for the L0-13.5K protein, and identified the ATG encoded by nucleotides 11,040 to 11,042 from the left end of the adenovirus genome as the initial codon of the L1-52K/55K protein. Antisera raised against synthetic peptides homologous to these three amino termini were used to demonstrate the presence of the L0-13.5K protein, the L0-13.6K protein, and the L1-52K/55K proteins in extracts of HeLa cells infected by adenovirus 2. The L0-13.5K protein was detected at early, intermediate, and late times after infection. The L0-13.6K and L1-52K/55K proteins were detected only at late times. Immunofluorescence microscopy indicated that the L0-13.6K protein is distributed around the periphery of the nucleus and along fibers running the length of the cell. Nonpermeabilized infected cells were stained by anti-L0-13.6K peptide serum at a single spot on the cell surface. Neither the L0-13.6K nor the L1-52K/55K proteins were detected in purified virus.

Transcription termination within the E1A gene of adenovirus induced by insertion of the mouse beta-major globin terminator element

In induced erythroleukemia cells, transcription of the beta-globin gene terminates in a region 600-1500 nucleotides downstream of the poly(A) site. To determine whether this region of the mouse DNA functions to terminate transcription when moved to another genomic site, portions of the putative termination region have been inserted into the E1A transcription unit of the adenovirus (type 5) chromosome. Analysis of RNA labeled either in isolated nuclei or in whole cells early after infection with reconstructed viruses indicated that transcription is terminated if the inserted DNA is oriented in the same direction as in the beta-globin transcription unit and contains the globin poly(A) site plus an additional 1395 nucleotides downstream. In addition to halting transcription within the E1A unit, the insertion of the terminator region had a negative cis effect on the E1B transcription unit, which normally initiates 363 bp downstream of the site of the globin insert. The E1B transcription unit was the only early gene affected, and complementation of the terminator virus with a wild-type E1A gene did not restore transcription of the E1B gene.

HeLa cell beta-tubulin gene transcription is stimulated by adenovirus 5 in parallel with viral early genes by an E1a-dependent mechanism

We report that the rate of transcription of cellular beta-tubulin genes increases during the early phase of adenovirus infection of HeLa cells, with kinetics very similar to those routinely found for viral genes. This activation depends upon adenovirus early region E1a, which encodes products that activate early virus transcription. To compare the responses of viral and cellular genes to E1a, we infected HeLa cells with dl312, a transcriptionally inactive deletion mutant that lacks a functional E1a gene. We then superinfected the cells with a helper virus, dl327, which encodes active E1a products, and measured changes in the rates of transcription of various cell and viral genes. Early region E3 of dl312 was activated 0 to 6 h postinfection and then repressed at 8 h postinfection, thus reproducing the two-step kinetics characteristic of a wild-type infection. Synthesis of beta-tubulin nuclear RNA was also transiently induced two- to six-fold, rising and falling in a manner similar to E3 transcription. An increase in helper virus multiplicity gave an increase in beta-tubulin stimulation, but dl312 alone, even at a high multiplicity of infection, gave no induction, confirming the requirement for E1a. beta-Actin nuclear RNA was actively synthesized before infection, but it was not further stimulated by the virus. Cellular beta-globin gene transcription was not stimulated by the virus, although transcription of a transfected beta-globin plasmid was induced by the virus or from a cotransfected E1a expression plasmid. We conclude that adenovirus 5 can stimulate beta-tubulin gene transcription. We discuss the significance for the viral life cycle of viral stimulation of cell genes and consider possible mechanisms in the light of the results obtained with beta-actin and beta-tubulin.

Interferon regulates c-myc gene expression in Daudi cells at the post-transcriptional level

c-myc gene mRNA is reduced by greater than 75% in the human lymphoblastoid cell line Daudi when growth is inhibited by treatment with human interferon beta (IFN-beta). In the present communication, we describe the effect of IFN-beta treatment on transcription of the c-myc gene and on the steady-state level of c-myc mRNA in the cytoplasm of Daudi cells. The results show that, although the rate of c-myc transcription is not significantly different in nuclei isolated either from untreated cells or from those treated with IFN-beta for 3 or 24 hr, the level of c-myc mRNA in the cytoplasm is reduced by 60% within 3 hr of IFN-beta treatment. These results suggest that IFN-beta regulates the c-myc mRNA at a post-transcriptional level. These results are in contrast to the regulation of two IFN-beta-induced genes that under identical conditions are regulated in these cells at the transcriptional level. We have also detected induction of the (2'-5')oligoadenylate synthetase (2-5A synthetase) gene in IFN-beta-treated Daudi cells. Since certain c-myc transcripts have the capacity to form double-stranded RNA regions, we propose that one mechanism by which c-myc could be regulated post-transcriptionally in IFN-beta-treated cells is by activating, through its own double-strandedness, the 2-5A synthetase/RNase L endonuclease system, which would cause selective degradation of the c-myc RNA.

Identification of the components necessary for adenovirus translational control and their utilization in cDNA expression vectors

A transient expression system was used to study the role of the adenovirus late and simian virus 40 (SV40) early mRNA leader sequences and adenovirus virus-associated (VA) RNAs in mRNA translation. Hybrid transcription units containing the adenovirus late and SV40 early promoters fused to various coding regions were introduced into monkey COS cells on plasmids containing a SV40 origin of replication. The translational efficiencies of the mRNAs produced from these plasmids were determined after alterations in the viral leader sequences or in the presence of VA RNAs provided by adenovirus infection of the transfected cells or by cotransfection with plasmids containing the VA genes. Efficient translation of mRNA with either adenovirus or SV40 leader sequences is dependent upon the presence of VA RNA. Translational stimulation by VA RNA of mRNAs containing the adenovirus tripartite leader sequences is dramatically reduced if leader exons 2 and 3 are removed or if their orientation is altered. Sequence analysis has indicated a homology between the nontranslated 5' end of SV40 early mRNA and sequences at the border of the 2nd and 3rd tripartite leader exons, which may be responsible for the increased translation of these mRNAs in the presence of VA RNA.

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.

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.

Splicing in adenovirus and other animal viruses

Splicing provides viruses with great genetic versatility. It is still too early to say whether this versatility is derived from ingeneous mechanisms evolved by necessity by the viruses, or whether the viruses indeed mimic cellular mechanisms. In any event, it is unlikely that cells will provide a single genomic cluster of genes that utilize splicing in such diverse ways as adenovirus, or the other viruses discussed here. And we may speculate that when the full role of splicing in adenovirus gene expression program is known, its import will continue to be a source of amazement!

High levels of intron-containing RNAs are associated with expression of the Drosophila DOPA decarboxylase gene

We have examined the structure and expression during embryonic development of the Drosophila DOPA decarboxylase gene, Ddc. The Ddc gene is transcribed to make at least five different size classes of RNA. These RNA species first appear late in embryogenesis, coincident with induction of Ddc enzyme activity. The most abundant and smallest RNA appears to be Ddc mRNA. The sequences encoding this RNA are split by two intervening sequences. Each of the larger RNA species contains some or all of the intervening sequences. We have noted two unusual features of Ddc expression during embryogenesis. First, the intervening-sequence-containing RNAs are present as 20% or more of the polyadenylated Ddc RNA molecules, an exceptionally high proportion. Second, these RNAs do not disappear as rapidly as Ddc mRNA after Ddc enzyme activity reaches fully induced levels. These observations indicate slow rates of RNA processing relative to mRNA half-life and suggest that post-transcriptional steps participate in regulating Ddc expression. Although four of the five RNA species were detected at multiple developmental stages during which Ddc is expressed, one was found uniquely during embryogenesis. This RNA differs from Ddc mRNA in length and in time of expression during embryogenesis but is transcribed in the same orientation and from the same genomic sequences as the Ddc primary transcript.

Mouse c-mos oncogene activation is prevented by upstream sequences

Although the molecularly cloned mouse c-mos oncogene locus can be efficiently activated by insertion of a retroviral long terminal repeat (LTR) 5' to its coding region, only low-frequency transformation occurs with the LTR element inserted 3' to this region. Analysis of several of the latter transformed cell lines suggested that loss of 2 kilobases (kb) of normal mouse DNA sequences preceding c-mos was required for oncogene activation. The determination of the transforming potential of deletion mutants containing only portions of this region followed by analysis of their nucleotide sequences identified a region termed upstream mouse sequence (UMS) as a cis-acting locus that prevents c-mos activation by a 3' LTR. The UMS region is approximately 1 kb in length and is located 0.8-1.8 kb upstream from the first ATG in the open reading frame of c-mos. Insertion of UMS 5' to the v-mos coding region also prevents 3' LTR enhancement of its transforming activity, but this inhibition is position dependent and functions only when inserted between v-mos and its putative promoter. The results presented here suggest that UMS may function to regulate c-mos proto-oncogene expression and may explain the lack of detectable c-mos transcripts in normal mouse cells.

HeLa cell beta-tubulin gene transcription is stimulated by adenovirus 5 in parallel with viral early genes by an E1a-dependent mechanism

We report that the rate of transcription of cellular beta-tubulin genes increases during the early phase of adenovirus infection of HeLa cells, with kinetics very similar to those routinely found for viral genes. This activation depends upon adenovirus early region E1a, which encodes products that activate early virus transcription. To compare the responses of viral and cellular genes to E1a, we infected HeLa cells with dl312, a transcriptionally inactive deletion mutant that lacks a functional E1a gene. We then superinfected the cells with a helper virus, dl327, which encodes active E1a products, and measured changes in the rates of transcription of various cell and viral genes. Early region E3 of dl312 was activated 0 to 6 h postinfection and then repressed at 8 h postinfection, thus reproducing the two-step kinetics characteristic of a wild-type infection. Synthesis of beta-tubulin nuclear RNA was also transiently induced two- to six-fold, rising and falling in a manner similar to E3 transcription. An increase in helper virus multiplicity gave an increase in beta-tubulin stimulation, but dl312 alone, even at a high multiplicity of infection, gave no induction, confirming the requirement for E1a. beta-Actin nuclear RNA was actively synthesized before infection, but it was not further stimulated by the virus. Cellular beta-globin gene transcription was not stimulated by the virus, although transcription of a transfected beta-globin plasmid was induced by the virus or from a cotransfected E1a expression plasmid. We conclude that adenovirus 5 can stimulate beta-tubulin gene transcription. We discuss the significance for the viral life cycle of viral stimulation of cell genes and consider possible mechanisms in the light of the results obtained with beta-actin and beta-tubulin.

Transcription of adenovirus cores in vitro

Transcription in whole HeLa cell extracts of the nucleoprotein core complexes released from adenovirus type 2 or type 5 virions has been examined. The average length of transcripts from deproteinized DNA templates increased steadily during a 90-min reaction in vitro, exhibiting an elongation rate of approximately 70 nucleotides per minute. On the other hand, transcripts made from viral core templates were restricted to a length of less than 2000 nucleotides. Accordingly, efficient transcription of cores (50 nucleotides elongated/min) ceased after 10-20 min of incubation in whole-cell extracts. Deproteinized viral DNA and viral nucleoprotein complexes appeared to support the initiation of a similar number of transcripts per template molecule, but the rate of initiation was faster when cores were provided as templates. Deproteinized viral DNA supported the synthesis of VA-RNA and of transcripts that hybridized to the region of the viral genome containing the 5' portion of the major late transcriptional. Viral cores also directed the synthesis of RNA products which hybridized to fragments of the viral genome containing E1A, E1B, and E4 regions. The results of nuclease protection experiments indicated that the presence of core proteins did not preclude accurate initiation of transcription from the E4 region.

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.

High levels of intron-containing RNAs are associated with expression of the Drosophila DOPA decarboxylase gene

We have examined the structure and expression during embryonic development of the Drosophila DOPA decarboxylase gene, Ddc. The Ddc gene is transcribed to make at least five different size classes of RNA. These RNA species first appear late in embryogenesis, coincident with induction of Ddc enzyme activity. The most abundant and smallest RNA appears to be Ddc mRNA. The sequences encoding this RNA are split by two intervening sequences. Each of the larger RNA species contains some or all of the intervening sequences. We have noted two unusual features of Ddc expression during embryogenesis. First, the intervening-sequence-containing RNAs are present as 20% or more of the polyadenylated Ddc RNA molecules, an exceptionally high proportion. Second, these RNAs do not disappear as rapidly as Ddc mRNA after Ddc enzyme activity reaches fully induced levels. These observations indicate slow rates of RNA processing relative to mRNA half-life and suggest that post-transcriptional steps participate in regulating Ddc expression. Although four of the five RNA species were detected at multiple developmental stages during which Ddc is expressed, one was found uniquely during embryogenesis. This RNA differs from Ddc mRNA in length and in time of expression during embryogenesis but is transcribed in the same orientation and from the same genomic sequences as the Ddc primary transcript.

Accumulation of early and intermediate mRNA species during subgroup C adenovirus productive infections

The cytoplasmic, poly(A)-containing RNA species complementary to all regions of the adenovirus type 2 (Ad2) genome expressed before the onset of viral DNA synthesis have been examined by "Northern" blotting. HeLa cells infected with low multiplicities of Ad2 were harvested at 2-hr intervals until late in the infectious cycle to establish the temporal patterns of expression of each viral gene. Under these conditions, such late mRNA products as those of the L3 and L5 families were not detected until 14 hr after infection. Although individual mRNA species complementary to several genes showed different patterns of expression, the order of appearance in the cytoplasm of substantial concentrations of adenoviral mRNA species was E1A, E3, and E4 (4 to 6 hr), E2A and E2B (8 hr), 3.7- and 4.1-kb L1 mRNA species (10-12 hr), IX and IVa2 mRNAs (12 hr), and those encoded in the major late transcriptional unit, such as members of the L3 and L5 families (14 hr). The mRNA species encoding polypeptides IX and IVa2 were not produced when viral DNA synthesis was blocked, whereas the larger L1 mRNA species was made under these conditions. Two E2B mRNA species, some 5.0 and 7 kb, were observed at low concentrations at 8 hr after infection and their concentration increased until 24 hr after infection, as did that of the E2A mRNA species: the products of the E2 transcription unit appeared to be expressed coordinately and at a constant ratio throughout infection. Few of the early mRNA species decreased in concentration after the onset of the late phase of infection. Examination of the viral mRNA produced when protein synthesis was inhibited by 10 microM anisomycin added 3 hr after infection suggested that processing of certain viral, early transcripts was altered in the presence of the drug.

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.

Kinetics and efficiency of polyadenylation of late polyomavirus nuclear RNA: generation of oligomeric polyadenylated RNAs and their processing into mRNA

The rate and efficiency of polyadenylation of late polyomavirus RNA in the nucleus of productively infected mouse kidney cells were determined by measuring incorporation of [3H]uridine into total and polyadenylated viral RNAs fractionated by oligodeoxythymidylic acid-cellulose chromatography. Polyadenylation is rapid: the average delay between synthesis and polyadenylation of viral RNA in the nucleus is 1 to 2 min. However, only 10 to 25% of viral RNA molecules become polyadenylated. Polyadenylated RNAs in the nucleus are a family of molecules which differ in size by an integral number of viral genome lengths (5.3 kilobases). These RNAs are generated by repeated passage of RNA polymerase around the circular viral DNA, accompanied by addition of polyadenylic acid to a unique 3' end situated 2.2 + n(5.3) kilobases from the 5' end of the RNAs (n can be an integer from 0 to at least 3). Between 30 and 50% of the sequences in nuclear polyadenylated RNA are conserved during processing and transport to the cytoplasm as mRNA. This is consistent with the molar ratios of nuclear polyadenylated RNAs in the different size classes, and it suggests that most polyadenylated nuclear RNA is efficiently processed to mRNA. Thus, the low overall conservation of viral RNA sequences between nucleus and cytoplasm is explained by (i) low efficiency of polyadenylation of nuclear RNA and (ii) removal of substantial parts of polyadenylated RNAs during splicing. The correlation between inefficient termination of transcription and inefficient polyadenylation of transcripts suggests that these two events may be causally linked.

The interplay between host and viral genes in adenovirus gene expression

Only the left end of adenovirus DNA comprising the early E1A and E1B regions is required for transformation of rodent cells and for tumorigenicity in mice and rats. The E1A early region encodes a protein which probably indirectly through a cellular component controls mRNA expression from at least four other early regions at the transcriptional or post-transcriptional level. Viral early proteins also combine with or control the expression of the cellular transplantation antigens to prepare the host cell for tumor rejection or alternatively to suppress the cellular immune response. DNA replication of the viral genome requires three virus-coded proteins and two cellular proteins and is the first mammalian system where DNA can be efficiently replicated in an in vitro system. Adenovirus late expression is also subject to cellular controls since the virus uses the host cell machinery for transcription and splicing. A late translational control has also been identified which is mediated by a small virus coded RNA (VAI RNA) transcribed by the cellular polymerase III. The viral RNA is probably complexed with a cellular protein when exerting its effect. All these control mechanisms, involving both viral and cellular genes, are now being dissected, and several of the molecules involved have been identified.

Kinetics and efficiency of polyadenylation of late polyomavirus nuclear RNA: generation of oligomeric polyadenylated RNAs and their processing into mRNA

The rate and efficiency of polyadenylation of late polyomavirus RNA in the nucleus of productively infected mouse kidney cells were determined by measuring incorporation of [3H]uridine into total and polyadenylated viral RNAs fractionated by oligodeoxythymidylic acid-cellulose chromatography. Polyadenylation is rapid: the average delay between synthesis and polyadenylation of viral RNA in the nucleus is 1 to 2 min. However, only 10 to 25% of viral RNA molecules become polyadenylated. Polyadenylated RNAs in the nucleus are a family of molecules which differ in size by an integral number of viral genome lengths (5.3 kilobases). These RNAs are generated by repeated passage of RNA polymerase around the circular viral DNA, accompanied by addition of polyadenylic acid to a unique 3' end situated 2.2 + n(5.3) kilobases from the 5' end of the RNAs (n can be an integer from 0 to at least 3). Between 30 and 50% of the sequences in nuclear polyadenylated RNA are conserved during processing and transport to the cytoplasm as mRNA. This is consistent with the molar ratios of nuclear polyadenylated RNAs in the different size classes, and it suggests that most polyadenylated nuclear RNA is efficiently processed to mRNA. Thus, the low overall conservation of viral RNA sequences between nucleus and cytoplasm is explained by (i) low efficiency of polyadenylation of nuclear RNA and (ii) removal of substantial parts of polyadenylated RNAs during splicing. The correlation between inefficient termination of transcription and inefficient polyadenylation of transcripts suggests that these two events may be causally linked.

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.

Growth-dependent expression of dihydrofolate reductase mRNA from modular cDNA genes

Dihydrofolate reductase (DHFR) synthesis is regulated in a growth-dependent fashion. Dividing cells synthesize DHFR at a 10-fold-higher rate than do stationary cells. To study this growth-dependent synthesis. DHFR genes have been constructed from a DHFR cDNA segment, the adenovirus major late promoter, and fragments of simian virus 40 (SV40) which provide signals for polyadenylation. These genes have been introduced into Chinese hamster ovary cells. The DHFR mRNAs produced in different transformants are identical at their 5' ends, but differ in sequences in their 3' ends as different sites are utilized for polyadenylation. Three transformants that utilize either DHFR polyadenylation signals or the SV40 late polyadenylation signal exhibit growth-dependent DHFR synthesis. The level of DHFR mRNA in growing cells is approximately 10 times that in stationary cells for these transformants. This growth-dependent DHFR mRNA production probably results from posttranscriptional events. In contrast, three transformants that utilize the SV40 early polyadenylation signal and another transformant that utilizes a cellular polyadenylation signal do not exhibit growth-dependent DHFR synthesis. In these three cell lines, the fraction of mRNAs polyadenylated at different sites in a tandem array shifts between growing and stationary cells. These results suggest that the metabolic state of the cell is important in determining either the efficiency of polyadenylation at various sites or the stability of mRNA polyadenylated at various sites.

Polyadenylic acid addition sites in the adenovirus type 2 major late transcription unit

The cytoplasmic mRNAs which are transcribed from the major late adenovirus promoter can be arranged into five 3'-coterminal families, L1 to L5. We have defined the polyadenylation sites of the mRNAs that belong to the five families at the nucleotide level. From the results, the following conclusions can be made. (i) The hexanucleotide sequence AAUAAA is present at the 3' end of all late adenovirus type 2 mRNAs and precedes the site of polyadenylation by 12 to 30 nucleotides. (ii) Between one and three A residues are present in the genomic sequence at the polyadenylation site. (iii) A sequence with the composition (T)n (A)p (T)q (n, p, q greater than or equal to 1) is found 4 to 24 nucleotides beyond all the adenovirus-specific polyadenylation sites except the 3'-coterminal family L4. This sequence is also found beyond many cellular polyadenylation sites. (iv) The L1 and L2 polyadenylation sites are very similar in structure. The other polyadenylation sites show no apparent sequence relationship, except for the hexanucleotide sequence.

Signals regulating hepatitis B surface antigen transcription

About 200 million people are chronic carriers of hepatitis B surface antigen (HBsAg), but since hepatitis B virus (HBV) cannot be propagated in vitro, HBsAg transcription has been studied only in cell lines containing HBV DNA integrated into chromosomes, and HBsAg-related mRNAs 2.0 to 2.5 kilobases (kb) long have been described. We have analysed the transcripts produced in an infected chimpanzee liver and in a rat cell line containing HBV DNA. In contrast to previous suppositions we report here that the major S gene transcript initiates close to the S gene, that is, within the 'pre-S' region and is processed/polyadenylated at a site situated within the core gene. The efficiency of processing/polyadenylation at this site varies between the chimpanzee liver and the rat cell line studied. The S gene promoter does not contain a TATA box but instead has a sequence homologous to that which positions the 5' ends of the major simian virus 40 (SV40) late transcript.

Growth-dependent expression of dihydrofolate reductase mRNA from modular cDNA genes

Dihydrofolate reductase (DHFR) synthesis is regulated in a growth-dependent fashion. Dividing cells synthesize DHFR at a 10-fold-higher rate than do stationary cells. To study this growth-dependent synthesis. DHFR genes have been constructed from a DHFR cDNA segment, the adenovirus major late promoter, and fragments of simian virus 40 (SV40) which provide signals for polyadenylation. These genes have been introduced into Chinese hamster ovary cells. The DHFR mRNAs produced in different transformants are identical at their 5' ends, but differ in sequences in their 3' ends as different sites are utilized for polyadenylation. Three transformants that utilize either DHFR polyadenylation signals or the SV40 late polyadenylation signal exhibit growth-dependent DHFR synthesis. The level of DHFR mRNA in growing cells is approximately 10 times that in stationary cells for these transformants. This growth-dependent DHFR mRNA production probably results from posttranscriptional events. In contrast, three transformants that utilize the SV40 early polyadenylation signal and another transformant that utilizes a cellular polyadenylation signal do not exhibit growth-dependent DHFR synthesis. In these three cell lines, the fraction of mRNAs polyadenylated at different sites in a tandem array shifts between growing and stationary cells. These results suggest that the metabolic state of the cell is important in determining either the efficiency of polyadenylation at various sites or the stability of mRNA polyadenylated at various sites.

Characterization of cytochrome P2-450 (20-S) mRNA. Association with the P1-450 genomic gene and differential response to the inducers 3-methylcholanthrene and isosafrole

Mouse liver cytochrome P2-450 is defined as the major isosafrole-inducible form of P-450 which is most specific for isosafrole metabolism. lambda AhP-1 represents a 15.5 X 10(3)-base-pair segment of mouse genomic DNA having the cytochrome P1-450 gene (approximately equal to 4600 base pairs) located in the middle portion. Using various subclones as probes, we investigated the differential expression of P1-450 mRNA and P2-450 mRNA induction as a function of association with the Ah locus, 3-methylcholanthrene or isosafrole dosage, tissue specificity, and developmental age. Both P1-450 (23-S) mRNA and P2-450 (20-S) mRNA induction processes are regulated by the Ah receptor. P2-450 mRNA is about 10-fold more sensitive than P1-450 mRNA to induction by either 3-methylcholanthrene or isosafrole. Phenobarbital pretreatment has no effect at all on either P1-450 mRNA or P2-450 mRNA. Whereas both P1-450 mRNA and P2-450 mRNA are induced by 3-methylcholanthrene in C57BL/6N liver, P1-450 (23-S) mRNA but not P2-450 (20-S) mRNA is induced by 3-methylcholanthrene in C57BL/6N kidney. P1-450 mRNA induction by 3-methylcholanthrene is measurable in C57BL/6N liver at day 15 of gestation, and the expression becomes enhanced with increasing age. P2-450 mRNA induction by 3-methylcholanthrene in C57BL/6N liver appears about 7 days later during development than 3-methylcholanthrene-inducible P1-450 mRNA. Both 3-methylcholanthrene-induced P1-450 mRNA and P2-450 mRNA are detectable in DBA/2N liver; their appearance is later in development, however, and at lower concentrations than that seen with C57BL/6N liver. P1-450 (23-S) mRNA and P2-450 (20-S) mRNA appear to hybridize to a common 5' fragment of the P1-450 gene.

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.

Analysis in Cos-1 cells of processing and polyadenylation signals by using derivatives of the herpes simplex virus type 1 thymidine kinase gene

Bal31 nuclease was used to resect the herpes simplex virus type 1 thymidine kinase (tk) gene from its 3' end, and a plasmid, pTK206, was isolated that lacked the processing and polyadenylation signals normally found at the 3' end of the gene. The wild-type gene, pTK2, and pTK206 were each transferred to pSV010, a plasmid containing the simian virus 40 (SV40) origin of DNA replication, allowing replication and analysis of the patterns of transcription in Cos-1 cells. Fragments of DNA containing processing and polyadenylation signals from SV40 and polyoma virus were inserted into the 3' end of the resected tk gene, pTK206. We found that tk gene expression requires a processing and polyadenylation signal, that signals from SV40 and polyoma virus could substitute for the herpes simplex virus tk signal, and that considerable differences in the levels of tk mRNA were present in Cos-1 cells transfected by these gene constructs. In addition, tk gene expression was restored to a low level after the insertion of an 88-base-pair fragment from the middle of the SV40 early region. Processing and polyadenylation do not occur in the vicinity of this fragment in SV40, even though it contains the hexanucleotide 5'-AAUAAA-3'.

Core and E antigen synthesis in rodent cells transformed with hepatitis B virus DNA is associated with greater than genome length viral messenger RNAs

The viral RNA sequences in a number of rodent cell lines which contain integrated hepatitis B virus DNA were examined. In one of the cell lines, which produces the hepatitis B virus surface, core and e antigens, there are four polyadenylated, cytoplasmic RNA species, estimated to be 4425, 3968, 2435 and 1054 nucleotides in length, which hybridize with hepatitis B virus DNA. All four were shown to be transcripts of the coding strand of the virus genome and the regions contained in each RNA molecule were determined by hybridization with probes from different parts of the genome. The two largest RNAs hybridized with probes from all parts of the genome. The 2.4 x 10(3) nucleotide RNA, which is the same size as the previously identified surface antigen messenger RNA, hybridized with probes covering the surface antigen gene but not with probes corresponding to the core antigen gene. It also hybridized with a probe mapping upstream of a sequence previously suggested to be its promoter. The 10(3) nucleotide RNA was mapped to the X gene region and thus provides evidence that this open translational reading frame does encode a product. This RNA is possibly 3' coterminal with the surface antigen mRNA. The two largest RNAs, which are greater than the length of the hepatitis B virus genome, are present in three independent cell lines which produce core antigen and e antigen in addition to surface antigen, but absent from two cell lines which produce only surface antigen. Therefore, it appears that these RNAs are entirely hepatitis B virus-specified, rather than being co-transcripts with cellular sequences, and also that one of them encodes the core and e antigen produced by these cells.

Construction of a modular dihydrofolate reductase cDNA gene: analysis of signals utilized for efficient expression

Dihydrofolate reductase (DHFR) modular genes have been constructed with segments containing the adenovirus major late promoter, a 3' splice site from a variable region immunoglobulin gene, a DHFR cDNA, and portions of the simian virus 40 (SV40) genome. DNA-mediated transfer of these genes transformed Chinese hamster ovary DHFR- cells to the DHFR+ phenotype. Transformants contained one to several copies of the transfected DNA integrated into the host genome. Clones subjected to growth in increasing concentrations of methotrexate eventually gave rise to lines containing several hundred copies of the transforming DNA. Analysis of the DHFR mRNA produced in amplified lines indicated the following. (i) All clones utilize the adenovirus major late promoter for transcription initiation. (ii) A hybrid intron formed by the 5' splice site of the adenovirus major late leader and a 3' splice site from a variable-region immunoglobulin gene is properly excised. (iii) The mRNA is not efficiently polyadenylated at sequences in the 3' end of the DHFR cDNA but rather uses polyadenylation signals downstream from the DHFR cDNA. Three independent clones produce a DHFR mRNA containing SV40 or pBR322 and SV40 sequences, and the RNA is polyadenylated at the SV40 late polyadenylation site. Another clone has recombined into cellular DNA and apparently uses a cellular sequence for polyadenylation. Introduction of a segment containing the SV40 early polyadenylation signal into the 3' end of the DHFR cDNA gene generated a recombinant capable of transforming cells to the DHFR+ phenotype with at least a 10-fold increase in efficiency, demonstrating the necessity for an efficient polyadenylation signal. Attachment of a DNA segment containing the transcription enhancer (72-base pair repeat) of SV40 further increased the biological activity of the modular DHFR gene 50- to 100-fold.

Far upstream initiation sites for adenovirus early region 1A transcription are utilized after the onset of viral DNA replication

Adenovirus early region 1A (E1A) is the first transcription unit expressed after infection. It encodes a protein which controls the expression of all other early viral genes. The E1A mRNAs have one major capped 5' terminus which maps 31 nucleotides downstream from a T-A-T-A sequence (C. Baker and E. Ziff. J. Mol. Biol. 149:189-221, 1981). In addition, a minor set of E1A mRNAs are observed during the early phase of infection which have 5' termini mapping at approximately -160, -185, and -230 relative to the major cap site (Osborne et al., Cell 29:139-148, 1982). Here we report the occurrence of another set of minor E1A mRNAs which were observed exclusively after the initiation of viral DNA replication. These late specific E1A mRNAs had cap sites which mapped at approximately -300, -325, -360, and -375 relative to the major cap site. The appearance of these minor late E1A mRNAs was blocked by the DNA synthesis inhibitor cytosine arabinoside. These same late specific E1A mRNAs were synthesized from E1A-containing plasmids which replicate in monkey cells. This demonstrated that neither late specific adenovirus proteins nor adenovirus-specific chromatin structure was required for the production of the late specific E1A mRNAs. Adenovirus mutants in which the E1A T-A-T-A box region had been deleted also synthesized the corresponding deleted forms of the late specific mRNAs after initiation of DNA replication. These results indicate that the process of DNA replication alters the specificity of E1A transcription initiation in a promoter region which is at least 375 nucleotides in length.

Analysis in Cos-1 cells of processing and polyadenylation signals by using derivatives of the herpes simplex virus type 1 thymidine kinase gene

Bal31 nuclease was used to resect the herpes simplex virus type 1 thymidine kinase (tk) gene from its 3' end, and a plasmid, pTK206, was isolated that lacked the processing and polyadenylation signals normally found at the 3' end of the gene. The wild-type gene, pTK2, and pTK206 were each transferred to pSV010, a plasmid containing the simian virus 40 (SV40) origin of DNA replication, allowing replication and analysis of the patterns of transcription in Cos-1 cells. Fragments of DNA containing processing and polyadenylation signals from SV40 and polyoma virus were inserted into the 3' end of the resected tk gene, pTK206. We found that tk gene expression requires a processing and polyadenylation signal, that signals from SV40 and polyoma virus could substitute for the herpes simplex virus tk signal, and that considerable differences in the levels of tk mRNA were present in Cos-1 cells transfected by these gene constructs. In addition, tk gene expression was restored to a low level after the insertion of an 88-base-pair fragment from the middle of the SV40 early region. Processing and polyadenylation do not occur in the vicinity of this fragment in SV40, even though it contains the hexanucleotide 5'-AAUAAA-3'.

Sequence arrangement and protein coding capacity of the adenovirus type 2 "i" leader

The adenovirus type 2 (Ad-2) "i" leader is an RNA segment which is preserved in some mRNA species from the Ad-2 late transcription unit. It maps between the second and third segments of the standard tripartite leader. We located the boundaries of the i leader in genomic Ad-2 DNA and determined its nucleotide sequence. The leader contains an ATG initiator near its 5' boundary, followed by a reading frame which is open for translation. We suggest that the i leader constitutes an Ad-2 coding sequence whose novel position within the leader of major late transcription unit messengers allows it to be translated in preference to coding sequences in mRNA main bodies. The i leader potentially contributes to the coding sequences of a family of proteins. Also, a Northern blot analysis of late mRNAs containing the i leader suggests that it may be retained in the leaders of many different late transcription unit mRNAs. We compare the i leader to the simian virus 40 agnogene.