Viral messenger RNAs in six lines of adenovirus-transformed cells

Loss of DNA ligase IV prevents recognition of DNA by double-strand break repair proteins XRCC4 and XLF

The repair of DNA double-strand breaks by nonhomologous end-joining (NHEJ) is essential for maintenance of genomic integrity and cell viability. Central to the molecular mechanism of NHEJ is DNA ligase IV/XRCC4/XLF complex, which rejoins the DNA. During adenovirus (Ad5) infection, ligase IV is targeted for degradation in a process that requires expression of the viral E1B 55k and E4 34k proteins while XRCC4 and XLF protein levels remain unchanged. We show that in Ad5-infected cells, loss of ligase IV is accompanied by loss of DNA binding by XRCC4. Expression of E1B 55k and E4 34k was sufficient to cause loss of ligase IV and loss of XRCC4 DNA binding. Using ligase IV mutant human cell lines, we determined that the absence of ligase IV, and not expression of viral proteins, coincided with inhibition of DNA binding by XRCC4. In ligase IV mutant human cell lines, DNA binding by XLF was also inhibited. Expression of both wild-type and adenylation-mutant ligase IV in ligase IV-deficient cells restored DNA binding by XRCC4. These data suggest that the intrinsic DNA-binding activities of XRCC4 and XLF may be subject to regulation and are down regulated in human cells that lack ligase IV.

Identification of a region on the adenovirus E1A gene responsible for induction by phorbol ester tumor promoter

12-O-Tetradecanoylphorbol-13-acetate (TPA) treatment induces human adenovirus (Ad) early region 1A (E1A) messenger ribonucleic acid expression in infected or Ad-transformed cells. Here, we report that deletion analysis has identified a TPA-responsive element (TRE) in the E1A enhancer region. Deletion analysis indicates that the TRE is located upstream of the E1A cap site between nucleotides -237 and -47. Incubation of extracts from TPA-treated cells with radioactively labeled deoxyribonucleic acid (DNA) fragments containing the TRE (-237 to -47) form specific DNA-protein complexes as demonstrated by gel shift analysis and Southwestern blotting. These experiments provide evidence that novel protein-DNA complexes are formed on a region of the E1A promoter required for TPA-enhanced expression. We speculate that these DNA-binding proteins may interact with the TRE and play a critical role in the mechanism through which TPA upregulates transcription from the Ad E1A gene.

Expression and interactions of human adenovirus oncoproteins

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Activation of the major late promoter in adenovirus transformed cells by 5-azacytidine

The adenovirus major late promoter (MLP) is normally not active in transformed cells. We investigated if it could be activated with 5-azacytidine. Three days of treatment with 10 microM 5-azacytidine induced transient activation of the MLP as shown by hybridization with an L1 r-strand-specific probe. The po/III-transcribed VA-RNAs were not activated. L1 activation was not accompanied by detectable changes in methylation of HpaII sites at the promoter or in the body of the transcript. Stably activated cell clones could be obtained at 20% frequency after long-term drug treatment.

Normalization of epidermal growth factor receptor and transforming growth factor production in drug resistant variants derived from adenovirus transformed cells

Variants (G2, G5) resistant to the cancer chemotherapeutic drug methylglyoxal bis (guanylhydrazone) (MGBG) were isolated from adenovirus type 2 transformed rat brain cells (F4; Sircar et al., 1987). Although at least one of these variants continued to express the adenovirus Ela and Elb transforming proteins, they both exhibited a detransformed phenotype as witnessed by flat morphology, loss of anchorage independent growth, and tumor forming capacity. Reverse transformation suggested the possibility of changes in growth factor receptors and the production of transforming growth factors. To test this possibility, we investigated the status of epidermal growth factor receptors (EGF-r) and transforming growth factor alpha (TGF-alpha) production in F4, G2 and G5 cells. The level of 125I-labeled EGF binding to intact drug resistant cells increased by 2- to 3-fold compared to the transformed parental cell. Scatchard analysis suggests that increased binding was the result of increased receptor levels rather than altered affinity of receptor for ligand. The production of growth factors which compete with 125I-labeled EGF binding declined in the detransformed G2 and G5 cells to a level intermediate between transformed (F4) and normal cells (FR3T3). EGF-receptor increase and the complementary decrease in growth factor production in the drug resistant variants may be associated with detransformation.

Lytic and transforming functions of individual products of the adenovirus E1A gene

To distinguish the individual roles of the 13S, 12S, and 9S adenovirus E1A gene products, we isolated the corresponding cDNA clones and recombined them into both plasmids and viruses. Only the expected E1A mRNA products were made from the corresponding 12S and 13S viruses. The 9S mRNA was detected when the 9S virus was coinfected with the 13S virus but not when either virus was infected alone. The 13S virus formed plaques equally well in 293 cells, HeLa cells, and A549 cells, a human lung oat cell carcinoma line. Plaque titers of the 12S virus were much reduced in HeLa and A549 cells compared with 293 cells, although the 12S virus is multiplicity-dependent leaky in both HeLa and A549 cells. A549 cells were significantly more permissive than HeLa cells for growth of the 12S virus. In A549 cells even at low multiplicities of infection the final yield of 12S virus eventually approached the maximum yield from 293 cells. Expression from the adenovirus early region 2 and early region 3 promoters in HeLa cells was activated in the presence of a 13S cDNA E1A region but not in the presence of a 12S E1A cDNA region. Although defective for lytic growth in HeLa cells, the 12S virus immortalized BRK cells at very high efficiency, whereas infection of these cells with 13S virus, as with wild-type E1A virus, resulted mainly in cell death. The 13S product does have an immortalization function, however, revealed in the absence of adenovirus lytic functions when a plasmid containing the E1A 13S cDNA region was transfected into BRK cells. The 9S virus failed to immortalize infected BRK cells or to interfere with focus formation when coinfected with the 12S virus.

Detection of cellular proteins associated with human adenovirus type 5 early region 1A polypeptides

Antisera prepared against synthetic peptides corresponding to the amino and carboxy termini of human adenovirus type 5 (Ad5) early region 1A (E1A) proteins were used to identify polypeptides that are associated with these viral species in lytically infected KB cells. Proteins were sought which coprecipitated with E1A polypeptides using both sera and which were not recognized in extracts from mock-infected cells by either serum. Four such species were identified with apparent molecular weights of 68K, 65K, and a doublet at about 105K. A fifth species migrating with a molecular weight in excess of 250K was also identified consistently with E1A-C1 but not E1A-N1 serum. Addition of an excess of the appropriate synthetic peptide to the immunoprecipitation mixtures prevented the precipitation of all of these species. Mixing experiments demonstrated that all species were cellular proteins expressed in normal uninfected KB cells and in addition showed that an association with E1A proteins could take place in vitro. Studies carried out with the mutants pm975 and hr1 indicated that while the 105K doublet and the greater than 250K species were found with the products of both the 1.1- and 0.9-kb E1A mRNAs, 65K and 68K appeared to be primarily associated with those of the 1.1-kb mRNA. Finally, the 105K doublet and greater than 250K were shown to be phosphoproteins. These data indicated that Ad5 E1A proteins may function in a complex with cellular polypeptides which includes species of 105K, 68K, 65K, and possibly a large protein of greater than 250K.

Analysis of multiple forms of human adenovirus type 5 E1A polypeptides using an anti-peptide antiserum specific for the amino terminus

Studies were carried out to further characterize the proteins coded for by the early 1A region (E1A) of human adenovirus type 5 (Ad5) in lytically infected cells using an antiserum prepared against a synthetic octapeptide corresponding to the amino termini of E1A products as well as another anti-peptide serum specific for the carboxy termini. Both sera precipitated the same collection of four major and two minor acidic phosphoproteins and it was confirmed that each of the 1.1- and 0.9-kb E1A mRNAs code for two major and one minor species. These data also indicated that none of the E1A species was produced by proteolytic cleavage. The deletion mutant dl313 which lacks DNA coding for the last 70 C-terminal amino acids of E1A products also produced multiple species which suggested that post-translational modifications involved in their generation do not take place in this region of the proteins. The N-terminal serum was effective in detecting neither the truncated 1.1-kb mRNA product predicted for the mutant hr1 nor the product of the small 0.6-kb E1A mRNA, suggesting that these species are either very short-lived in infected cells or exist in a conformation in which the amino terminus is inaccessable to the antibody.

Early region 1B of adenovirus 2 encodes two coterminal proteins of 495 and 155 amino acid residues

Partial sequence analysis of tryptic peptides has identified the E1B-495R (E1b-57K) (early transcription region 1B of 495 amino acid residues, with an approximate molecular weight of 57,000) protein of adenovirus 2 as encoded by the 495 amino acid open reading frame located in the adenovirus 2 DNA sequence between nucleotides 2016 and 3500. Additional proteins of 16,000 Mr and 18,000 Mr that are related to the E1B-495R protein were identified by cell-free translation of hybridization-selected mRNA. Analysis of [35S]methionine-containing amino terminal tryptic peptides by thin-layer chromatography showed that the E1B-495R, E1B-18K, and E1B-16K proteins all begin at the same initiation codon. The E1B-495R protein from 293 cells also has the same initial tryptic peptide, acetyl-methionyl-glutamyl-arginine. Sequence analysis of E1B-18K tryptic peptides indicated that this protein also has the same carboxy terminus as the E1B-495R protein and that it is derived from an mRNA that is spliced to remove sequences between nucleotides 2250 and 3269, resulting in a protein product of 155 amino acid residues. Analysis of E1B-16K tryptic peptides has not yet revealed the carboxy terminal structure of this protein. Both the E1B-495R and the E1B-155R (E1B-18K) proteins, as well as the E1B-16K protein, were precipitated from cell-free translations and from extracts of infected cells by antiserum against an amino terminal nonapeptide common to these proteins.

Establishment and characterization of hamster cell lines transformed by restriction endonuclease fragments of adenovirus 5

We have established a library of hamster cells transformed by adenovirus 5 DNA fragments comprising all (XhoI-C, 0 to 16 map units) or only a part (HindIII-G, 0 to 7.8 map units) of early region 1 (E1: 0 to 11.2 map units). These lines have been analyzed in terms of content of viral DNA, expression of E1 antigens, and capacity to induce tumors in hamsters. All cells tested were found to express up to eight proteins encoded within E1A (0 to 4.5 map units) with apparent molecular weights between 52,000 (52K) and 25K. Both G and C fragment-transformed lines expressed a 19K antigen encoded within E1B (4.5 to 11.2 map units), whereas an E1B 58K protein was detected in C fragment-transformed, but not G-fragment-transformed, lines. No clear distinction could be drawn between cells transformed by HindIII-G and by XhoI-C in terms of morphology or tumorigenicity, suggesting that the E1B 58K antigen plays no major role in the maintenance of oncogenic transformation, although possible involvement of truncated forms of 58K cannot be ruled out. Sera were collected from tumor-bearing animals and examined for ability to immunoprecipitate proteins from infected cells. The relative avidity of sera for different proteins was characteristic of the cell line used for tumor induction, and the specificity generally reflected the array of viral proteins expressed by the corresponding transformed cells. However, one notable observation was that even though all transformed lines examined expressed antigens encoded by both the 1.1- and 0.9-kilobase mRNAs transcribed from E1A, tumor sera made against these lines only precipitated products of the 1.1-kilobase message. Thus, two families of E1A proteins, highly related in terms of primary amino acid sequence, appear to be immunologically quite distinct.

The pattern of integration of viral DNA sequences in the adenovirus 5-transformed human cell line 293

The pattern of integrated adenovirus 5 DNA in the adenovirus 5-transformed human cell line 293 was analyzed by DNA blot hybridization. In contrast to a previous report, only sequences from the left end of the genome were detected. The viral DNA was contained in a unique DNA fragment generated by cleavage of 293 DNA with either EcoRI or BamHI, two enzymes which do not cut the integrated viral DNA. Further mapping studies indicated that the integrated sequence was probably colinear with viral DNA. The joining to host cell sequences occurred between viral nucleotide base pairs 1 and 270 (a site for BalI) on one end and 4123 (SmaI site) and 5372 (BalI site) at the other end. The viral DNA was not tandemly repeated. These results suggest that integration of viral sequences into the host genome probably occurred at a single site. If any subsequent duplications of viral DNA took place, then duplication of extensive cellular sequences also must have occurred.

Proteins encoded near the adenovirus late messenger RNA leader segments

Small fragments of adenovirus 2 DNA cloned into the single-strand phage M13 were used to select adenoviral messenger RNAs transcribed from the R-strand between map positions 16 and 30. Cell-free translation of these mRNAs produced proteins of 13.5K, 13.6K, and 11.5K, respectively encoded between the first and second segments of the tripartite major late leader, within the "i"-leader segment, and immediately preceding the third leader segment. Partial sequence analysis of the 13.6K protein is consistent with the hypothesis that it is encoded within the i-leader segment.

Mapping of a 14,000-dalton antigen to early region 4 of the human adenovirus 5 genome

An early 14,000-dalton (14K) antigen of adenovirus 5, hitherto designated 10.5K and thought to be from early region 1 (E1), has been shown to be a product of region E4 on the following evidence. In KB cells infected with the adenovirus 5 mutants dl312 and dl313, containing large deletions in region E1, this antigen was produced in a form having the same mobility as that in wild-type infections. In a range of rodent cells transformed by adenovirus 5 DNA, the synthesis of 14K antigen and the ability of these cells to elicit an immune response to this protein both correlated with the presence of sequences from region E4 of the viral genome. A 14K polypeptide was synthesized in a cell-free system programmed with infected-cell mRNA and was found to be identical to the in vivo antigen in antigenicity, in electrophoretic mobility, and in [35S]methionine-containing tryptic peptides. After labeling with [35S]methionine and several 3H-amino acids, this in vitro product gave an N-terminal sequence identical to that expected from one of the open reading frames (reading region 3) in the DNA sequence for region E4 of Hérissé et al. (Nucleic Acids Res. 9:4023-4042, 1981). It is likely that this antigen is the same as the nucleus-associated 11K polypeptide from E4 described by other authors.

Expression of integrated viral DNA sequences outside the transforming region in eight adenovirus-transformed cell lines

The expression of early and intermediate-early viral regions in eight adenovirus type 5 transformed cell lines was analyzed by radioimmuno-inhibition and RNA-DNA hybridization techniques. Details on the arrangement of the integrated viral DNA sequences in these cell lines have already been published (Visser, L., Wassenaar, A.D.C., Van Maarschalkerweerd, M.W. and Rozijn, T.H. (1981) J. Virol, 39, 684-693). In all cell lines tested, proteins encoded by the transforming region E1 are present. Dependent on the viral DNA content, additional early regions are expressed in most cell lines. In two of the cell lines polypeptides related to the adenoviral terminal protein, encoded by the recently described region E2b, could be detected. The viral DNA sequence encoding the body of the terminal protein mRNA is probably integrated intact, but the promoter region and at least some of the leaders are lacking in these cell lines.

Analysis of expression of adenovirus DNA (fragments) by microinjection in Xenopus oocytes. Independent synthesis of minor early region 2 proteins

Injection of whole adenovirus DNA into Xenopus oocytes results in the synthesis of large amounts of the early region 2A DNA-binding protein (E2A-DBP) and smaller amounts of polypeptide IX. The lack of synthesis of any functional messenger RNAs transcribed from the major late promotor at 16.3 map units is remarkable. Cleavage of the adenovirus DNA outside the E2A gene proper by restriction enzymes decreases synthesis of the DBP to about 10% of the amount produced after injection of intact DNA. On the other hand, presence of the terminal (Bellett) protein on the injected template enhances DBP synthesis considerably. Experiments with injected DNA restriction fragments, as well as reconstructed genes cloned into pBR322, indicate that efficient synthesis of DBP in oocytes requires the presence of either or both of the two main promoters from which the E2A gene is transcribed plus an intact 3' end of the gene. In the absence of any known promotor, 100-fold lower amounts of otherwise normal DBP are produced. Unlike in a regular infection, synthesis of DBP in oocytes does not require the product of the E1A gene. The same series of experiments also demonstrates that the DBP, a phosphoprotein, is the substrate of a cellular rather than a virus-encoded protein kinase. Two minor E2A proteins, although colinear with the major DBP, are synthesized independently. Synthesis of a 44,000 Mr protein, probably corresponding to the carboxy-terminal 360 amino acid residues of the DBP, is not decreased after injection of "promotorless" E2A genes. Unlike the 44,000 Mr protein, production of a 67,000 Mr protein (carboxy-terminal 483 amino acid residues) by one DNA-construct is probably directed by a T-A-T-A-A-A-T-A sequence in the vector DNA.

An altered DNA conformation detected by S1 nuclease occurs at specific regions in active chick globin chromatin

The single-stranded activity of S1-nuclease cleaves globin chromatin in red cell nuclei in specific regions. The cleavages are observed only in tissues in which the globin genes are active, and they "switch" to reflect the switching pattern of globin-gene expression in embryonic and adult red cells. The positions of the S1 cleavages in the beta- and alpha-globin chromatin correspond to the general region of known DNAase I-hypersensitive sites, but can be distinguished in detail. When DNA segments containing these regions are subcloned into pBR322 and the supercoiled molecules are treated with S1, similar sites are cleaved in the purified supercoiled (but not linear) recombinant plasmid DNA. However, the dominant S1 cutting sites are shifted in the plasmid vis-a-vis the chromatin. We believe that some aspect of DNA sequence is translated into an altered DNA structure in chromatin and that it is this altered structure that is recognized by s1 nuclease and possibly by certain chromosomal proteins. Several physical properties reflected in the S1 digestion of supercoiled plasmids suggest a mechanism for generating differences in daughter cells during development.

Expression of the gene encoding the adenovirus DNA terminal protein precursor in productively infected and transformed cells

The major product of in vitro translation of early RNA prepared from H5ts125-infected cells and selected by hybridization to adenoviral DNA fragments spanning the region from 14.7 to 31.5 map units had been shown to be identical to the 87-kilodalton terminal protein precursor. A 72- to 75-kilodalton polypeptide whose rRNA can be selected by DNA from this same region and made in the presence of anisomycin was indistinguishable from the 72-kilodalton single-stranded DNA-binding protein encoded by the region from 60.1 to 66.6 map units. The accumulation of cytoplasmic RNA sequences complementary to these l-strand genes under various conditions of infection and in certain lines of transformed cells has been investigated by solution hybridization of cytoplasmic RNA to the separated strands of restriction endonuclease fragments of adenoviral DNA. During the early phase, RNA sequences complementary to the region from 11.6 to 36.7 map units were present at a concentration of 10 to 60 copies per cell, regardless of the nature of the block used to inhibit viral DNA synthesis. By 24 h after infection in the absence of any such block, sequences complementary to the regions from 11.6 to 18.2 map units (IVa2) and from 18.6 to 36.7 map units (E2B) accumulated to concentrations of 4,800 and 280 copies per cell, respectively. The ratio of cytoplasmic E2A RNA sequences to E2B RNA sequences remained close to 10:1 throughout the time period investigated. Of the transformed cell lines which retained E2B DNA sequences that were examined, only the T2C4 line expressed these sequences in cytoplasmic RNA. The implications of these observations for regulation of expression of the adenoviral early l-strand genes are discussed.