In vitro synthesis of adenovirus type 5 T antigens. II. Translation of virus-specific RNA from cells transformed by fragments of adenovirus type 5 DNA.

Virus-specific cytoplasmic RNA was isolated from rat cell lines transformed by fragments of adenovirus type 5 DNA, and the RNAs were translated in cell-free systems derived from wheat germ or rabbit reticulocytes. RNA was isolated from cell lines transformed by the following fragments: XhoI-C (leftmost 15.5%), HindIII-G (leftmost 8%), and HpaI-E (leftmost 4.5%). In addition, the adenovirus type 5-transformed human embryonic kidney line 293.C31 was investigated. The products were immunoprecipitated with serum from tumor-bearing hamsters and analyzed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. The results show that all transformed cells investigated contain early region 1a-specific RNAs which can be translated into proteins with molecular weights of 34,000 (34K), 36K, 40K, and 42K. Transformed cells that also contain an intact early region 1b synthesized RNA which can be translated into proteins with molecular weights of 19K and 65K. Minor proteins of 15K, 16K, 17.5K, 18K, 25K, and 29K were also observed, but these proteins could not be mapped unambiguously. Cells transformed by the 8% HindIII-G apparently lack RNA encoding the 65K protein, but they do contain RNA coding for the 19K protein.     

Proteins and messenger RNAs of the transforming region of wild-type and mutant adenoviruses

We have studied the proteins encoded by the transforming region of the closely related human adenovirus serotypes 2 and 5. Messenger RNAs complementary to the two parts of this region, E1A and E1B, were prepared separately by hybridization to cloned DNA fragments encompassing 0.8 to 4.5 map units (for E1A) and 9.8 to 11.1 map units (for E1B). These RNAs were further fractionated by electrophoresis through agarose gels containing methylmercuric hydroxide, and then translated in vitro to identify the proteins encoded by each RNA species. E1A and E1B RNAs isolated at early and at late times after infection were compared. Three size classes of E1A mRNA direct the synthesis of at least five proteins: a28K³ protein encoded by a 0.6 kb mRNA, 42K and 54K proteins encoded by a 0.9 kb mRNA(s), and 48K and 58K proteins encoded by a 1.1 kb mRNA(s). The mRNA for the 28K protein accumulates preferentially at late times. Three size classes of early E1B mRNA direct the synthesis of three proteins: a 15K protein encoded by a 0.9 kb mRNA, an 18K protein encoded by a 1.2 kb mRNA, and a 57K protein encoded by a 2.6 kb mRNA. The mRNA for the 15K protein continues to accumulate at late times, and an additional 22K protein is made, while the 18K and 57K proteins are synthesized poorly, if at all, with late RNA.Substantially different E1A and E1B proteins are encoded by RNA from cells infected with the adenovirus type 5 mutants dl311, dl312, dl313, dl314 and hr1, which are all defective for replication on human cells and, except for dl311, for transformation. dl312, dl314 and hr1 are also defective for early viral gene expression. No viral mRNA could be detected in either dl312 or dl314-infected cells. hr1-infected cells contain a 0.9 kb mRNA encoding E1A 54K and 42K, but instead of 58K and 48K, the 1.1 kb hr1-E1A mRNA is translated into a 26K protein. The E1B mRNAs are present in substantially decreased amounts in hr1-infected cells. dl311-infected cells contain E1A mRNAs of 1.1 and 0.9 kb, encoding 38K and 34K proteins, respectively, and normal E1B mRNAs. The dl313 mRNAs of 1.1 and 0.9 kb contained fused E1A and E1B sequences and were translated into 40K and 36K proteins, respectively. These results are related to the mRNA structures and the biological activity of regions of the individual proteins.     

In vitro translation of adenovirus type 12-specific mRNA isolated from infected and transformed cells.

The early and late gene products of human adenovirus type 12 (Ad12), as well as the viral proteins synthesized in an Ad12-transformed cell line, were identified by translation of viral mRNA in an in vitro protein-synthesizing system. Cytoplasmic RNA was isolated from permissive KB or nonpermissive BHK cells infected with Ad12 and from Ad12-transformed HA12/7 cells. Virus-specific RNA was selected by hybridization to Ad12 DNA covalently bound to cellulose. Viral RNA was then translated in a fractionated rabbit reticulocyte cell-free system or in wheat germ S-30 extracts. The proteins synthesized were characterized by immunoprecipitation and subsequent electrophoresis on sodium dodecyl sulfate-polyacrylamide gels. RNA prepared from KB cells late after infection with Ad12 elicited the synthesis of most of the structural polypeptides of the virion and at least two presumably nonstructural Ad12 proteins. When viral RNA isolated early after infection of KB cells with Ad12 was translated in vitro, 10 polypeptides were observed: E-68K, E-50K, E-42K, E-39K, E-34K, E-21K, E-19K, E-13K, E-12K, and E-10K. Ad12-specific RNA was also isolated from the Ad12-transformed hamster cell line HA12/7, which contains several copies of the Ad12 genome integrated in the host genome. The RNA codes for at least seven polypeptides with molecular weights very similar to those of the early viral proteins.     

Organization of early region 1B of human adenovirus type 2: identification of four differentially spliced mRNAs.

The mRNAs from early region 1B of adenovirus type 2 have been studied by Northern blot, S1 nuclease, and cDNA analysis. Two novel mRNAs, designated 14S and 14.5S, have been observed in addition to the previously identified 9S, 13S, and 22S mRNAs. They are 1.26 and 1.31 kilobases long and differ from the 13S and 22S mRNAs in being composed of three exons instead of two. Their two terminal exons are the same as those present in the 13S mRNA, whereas the middle exon is unique to each of the two novel mRNA species. The structures of the 14S and 14.5S mRNAs allow the prediction of their coding capacities: both mRNA species, like the 22S and 13S mRNAs, contain an uninterrupted translational reading frame encoding a 21,000-molecular-weight (21K) polypeptide. The 14S mRNA can, in addition, encode a 16.5K polypeptide which shares N-terminal and C-terminal sequences with the 55K polypeptide, known to be encoded by the 22S mRNA. The 14.5S mRNA species encodes a hypothetical 9.2K polypeptide which has the same N terminus as the 55K polypeptide but a unique C terminus. The two mRNAs differ in their kinetics of appearance; the 14.5S mRNA is preferentially expressed late after infection in contrast to the 14S mRNA, which is present in approximately equal amounts early and late after infection. Taken together with previously published information the results suggest that early region 1B of adenovirus type 2 encodes five proteins in addition to virion polypeptide IX. These have predicted molecular weights of 55,000, 21,000, 16,500, 9,200, and 8,100.     

An adenovirus mRNA which encodes a 14,700-Mr protein that maps to the last open reading frame of region E3 is expressed during infection.

The E3 regions of adenovirus types 2 and 5, respectively, are known to synthesize proteins of 19,000 Mr (19K) and 11.6K, but information regarding the identity and characterization of other potential E3 proteins encoded by the six remaining open reading frames (ORFs) is lacking. In this study, we show that the last ORF of region E3, which encodes a 14.7K protein, is expressed in adenovirus-infected cells. This information was largely derived from analysis of an E3 deletion mutant (H2dl801) in which an extensive deletion (1,939 base pairs) was found to eliminate all ORFs except for two proteins of 12.5K and 14.7K. The 14.7K protein was translated from RNA isolated from H2dl801-infected cells that had been hybridization selected to E3 DNA; hybridization-selected RNA from wild-type adenovirus type 5-infected cells translated both the 19K and the 14.7K proteins. Moreover, an antiserum directed against a bacterial 14.7K fusion protein (A. E. Tollefson and W. S. M. Wold, J. Virol. 62:33-39, 1988) immunoprecipitated the 14.7K translation product synthesized by wild-type and mutant H2dl801 adenovirus mRNAs.     

Identification of the trans-acting Rep proteins of adeno-associated virus by antibodies to a synthetic oligopeptide.

Prior genetic analysis provided evidence for trans-acting regulatory proteins (Rep) coded by the left-hand open reading frame (orf-1) of adeno-associated virus (AAV). We have used immunoblotting analysis to identify four protein products of orf-1. Antibodies elicited against an oligopeptide encoded by orf-1 were reacted with extracts of cells that were infected with AAV or transfected with AAV recombinant vectors in the presence or absence of helper adenovirus. The antibody recognized four polypeptides with apparent molecular weights of 78,000, 68,000, 52,000, and 40,000. The 78,000-dalton (78K) (Rep78) and 68K (Rep68) proteins appear to be encoded by the unspliced 4.2-kilobase (kb) and spliced 3.9-kb mRNAs, respectively, transcribed from the p5 promoter. The 52K (Rep52) and 40K (Rep40) proteins appear to be the products of the unspliced 3.6-kb and the spliced 3.3-kb mRNAs, respectively, transcribed from the p19 promoter. Rigorous identification of Rep68 as an AAV-coded protein is compromised by a cross-reacting cellular protein of similar size. All four proteins were expressed in the human cell lines 293, HeLa, HT29, and A549 infected with AAV together with adenovirus. Rep78 and Rep52 were detected at lower levels in cells infected with AAV at high multiplicity in the absence of adenovirus. Human 293 cells transfected with a recombinant AAV vector (pAV2) also expressed Rep proteins in the presence or absence of adenovirus. Mutations introduced into the Rep region of pAV2 further identified the Rep proteins. The amount of each Rep protein varied between nuclear and cytoplasmic extracts, but all four proteins accumulated during the lytic cycle of the viral infection. Other studies have indicated that the Rep proteins have independent trans-acting functions in viral DNA replication and negative and positive regulation of gene expression. Correlation of each trans-acting function with individual Rep proteins will be facilitated with the antibodies described herein.     

Detection of adenovirus type 2-induced early polypeptides using cycloheximide pretreatment to enhance viral protein synthesis.

(35S) methionine-labeled polypeptides synthesized by adenovirus type 2-infected cells have been analyzed by polyacrylamide gradient gel electrophoresis and autoradiography. Cycloheximide (CH) was added to infected cultures to accumulate early viral mRNA relative to host cell mRNA. This allowed viral proteins to be synthesized in increased amounts relative to host proteins after removal of CH and pulse-labeling with (35S)methionine. During the labeling period arabinosyl cytosine was added to prevent the synthesis of late viral proteins. This procedure facilitated the detection of six early viral-induced polypeptides, designated EP1 through EP6 (early protein), with apparent molecular weights of 75,000 (75K), 42K, 21K, 18K, 15K, and 11K. Supportive data were obtained by coelectrophoresis of (35S)- and (3H)methionine-labeled polypeptides from infected and uninfected cells, respectively. Three of these early polypeptides have not been previously reported. CH pretreatment enhanced the rates of synthesis of EP4 and EP6 20- to 30-fold and enhanced that of the others approximately twofold. The maximal rates of synthesis of the virus-induced proteins varied, in a different manner, with time postinfection and CH pretreatment. Since CH pretreatment appears to increase the levels of early viral proteins, it may be a useful procedure to assist their isolation and functional characterization.     

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.     

Control of adenovirus early gene expression: A class of immediate early products

We have identified the viral mRNAs present in cells in which protein synthesis has been stringently inhibited prior to infection with adenovirus type 2. These species presumably represent the subset of viral mRNAs that are “immediate early” products, requiring only host cell genes for their expression, and they do not include any of the conventionally recognized early mRNAs. Treatment of cells with 100 μM anisomycin inhibits 99.6% of protein synthesis and substantially depresses (by 20–200 fold) the levels of the conventional early mRNAs from regions E1 A, E1B, E2, E3 and E4. Also depressed are species encoding an 87K protein (11.6–31.5 map units) and a 13.6K protein (encoded a short distance to the right of 21.5 map units). The only mRNAs not depressed by this treatment are an mRNA for a 13.5K protein encoded between 17.0 and 21.5 map units, and the mRNA for the late 52,55K protein encoded between 29 and 34 map units, which is also present in small amounts at early times. Further proof that production of the mRNA for the immediate early 13.5K protein is independent of EIA gene function is provided by the observation that it can be detected in cells infected with the EIA deletion mutant d1312.     

The use of monoclonal antibodies to study the proteins specified by the transforming region of human adenoviruses.

Monoclonal antibodies against two of the proteins specified by one of the transforming genes (early region 1B) of human adenovirus type 2 have been produced and characterized. Two clones (RA1 and PA6), generated by fusion of mouse myeloma NSO cells with splenocytes from rats immunized with whole-cell lysates of an adenovirus-transformed rat cell line (F19), secreted antibodies against a 58 kDa protein. Another clone (DC1) produced antibodies against the same protein, and resulted from fusion of immune rat splenocytes with the rat myeloma Y3.Ag.1.2.3. Immunoprecipitation studies showed that all three antibodies recognized [35S]-methionine-labelled 58 kDa protein, and phosphorylated derivatives of the 58 kDa protein labelled with [32P]orthophosphate present in infected human cells. One clone (EC3) produced antibody against a 19 kDa protein also encoded by early region 1B, but not sharing sequence homology with 58 kDa. The identity of the 19 kDa protein recognized by the EC3 antibody was established by immunoprecipitation from lysates of labelled-infected cells and from products of cell-free translation directed by mRNA isolated from adenovirus 2-infected cells. Indirect immunofluorescent-antibody staining of infected human cells using the RA1 and EC3 antibodies revealed a nuclear location of the 58 kDa protein and a mainly cytoplasmic location of the 19 kDa protein.     

The nucleotide sequence of the transforming early region E1 of adenovirus type 5 DNA

The sequence of the leftmost 11.3% of the non-oncogenic human adenovirus type 5 (Ad5) DNA has been determined. This segment contains the entire early region E1 of the Ad5 genome which has been shown to be involved in in vitro transformation of non-permissive rodent cells (Van der Eb et al., 1980). From the DNA sequence, and from the mRNA sequence data obtained by Perricaudet et al, (1979, 1980) for the E1 mRNAs from the closely related adenovirus type 2 (Ad2), it is possible to predict the primary structure of the polypeptides encoded by this region. The function of these proteins in cell transformation is discussed. From the positions of mapped restriction endonuclease sites and termini of RNA segments in the nucleotide sequence the length of the Ad5 DNA is estimated to be 36.6 kb.     

Identification of human adenovirus early region 1 products by using antisera against synthetic peptides corresponding to the predicted carboxy termini.

Synthetic peptides were prepared which corresponded to the carboxy termini of the human adenovirus type 5 early region 1B (E1B) 58,000-molecular-weight (58K) protein (Tyr-Ser-Asp-Glu-Asp-Thr-Asp) and of the E1A gene products (Tyr-Gly-Lys-Arg-Pro-Arg-Pro). Antisera raised against these peptides precipitated polypeptides from adenovirus type 5-infected KB cells; serum raised against the 58K carboxy terminus was active against the E1B 58K phosphoprotein, whereas serum raised against the E1A peptide immunoprecipitated four major and at least two minor polypeptides. These latter proteins migrated with apparent molecular weights of 52K, 50K, 48.5K, 45K, 37.5K, and 35K, and all were phosphoproteins. By using tryptic phosphopeptide analysis, the four major species (52K, 50K, 48.5K, and 45K) were found to be related, as would be expected if all were products of the E1A region. The ability of the antipeptide sera to precipitate these viral proteins thus confirmed that the previously proposed sequence of E1 DNA and mRNA and the reading frame of the mRNA are correct. Immunofluorescent-antibody staining with the antipeptide sera indicated that the 58K E1B protein was localized both in the nucleus and in the cytoplasm, especially in the perinuclear region. The E1A-specific serum also stained both discrete patches in the nucleus and diffuse areas of the cytoplasm. These data suggest that both the 58K protein and the E1A proteins may function in or around the nucleus. These highly specific antipeptide sera should allow for a more complete identification and characterization of these important viral proteins.     

Adenovirus early gene products may control viral mRNA accumulation and translation in vivo

The mechanisms controlling early adenovirus gene expression in vivo have been studied using inhibitors of protein synthesis. When inhibitors were added shortly before or at the onset of infection, viral mRNA from all early regions was transcribed, spliced and accumulated over a 7 hr period. After longer pretreatment, accumulation of several early mRNAs were suppressed. Addition of inhibitors 1 hr after infection enhanced the accumulation of viral mRNA in the cytoplasm. Translation of early mRNA selected on adenovirus DNA in a cell-free system reflected the amount of viral mRNA present. A viral coded product may therefore control accumulation of viral mRNA.A different pattern emerged when inhibitors of protein synthesis were removed at 5 hr postinfection and cells were pulse-labeled in vivo. If inhibitors were introduced at or before infection, early viral proteins were synthesized only after a lag of 1–3 hr. However, if treatment was introduced 1 hr post-infection, reversion of the protein synthesis block was instantaneous. It appears that protein synthesis inhibitors reveal an in vivo translational block for viral mRNA. This block could be overcome by preinfection with a related virus. Furthermore, no block was observed in a virus-transformed human embryonic kidney cell line (293) which expresses early region 1 of the viral genome. Viral gene product(s) encoded in early region 1 may control translation of early adenovirus messenger RNA in vivo.     

Hybridization selection and cell-free translation of mRNA''s encoded within the inverted terminal repetition of the vaccinia virus genome

Early polypeptides encoded within the 10,000-base pair terminally repeated region of the vaccinia virus genome were mapped by cell-free translation of mRNA that was selected by hybridization to restriction fragments and to separated strands of a recombinant lambda phage. The results, which were confirmed by hybrid arrest of translation, indicated that polypeptides of 7,500 (7.5K), 19,000 (19K), and 42,000 (42K) daltons mapped at approximately 3.2 to 4.3, 6.5 to 7.2, and 7.2 to 8.3 kilobase pairs from the end of the genome, respectively. mRNA's for the 42K and 7.5K polypeptides were transcribed towards the end of the genome, whereas mRNA for the 19K polypeptide was transcribed in the opposite direction. Including polyadenylic acid tails, the lengths of the mRNA's for the 7.5K, 19K, and 42K polypeptides, determined by gel electrophoresis of denatured RNA, hybridization selection, and cell-free translation, were approximately 1,200, 680, and 1,280 nucleotides, respectively. mRNA's for the 42K and 19K polypeptides were only about 100 nucleotides longer than the minimums required to code for their respective polypeptides, whereas mRNA for the 7.5K polypeptide contained 900 nucleotides of untranslated sequence. This long untranslated portion of the latter mRNA was probably located near the 3' end, because this gene was only inactivated by high doses of UV irradiation. This small target size also excluded certain models for RNA processing involving formation of the mRNA's for the 42K and 7.5K polypeptides from a common promoter. Rabbitpox virus, which has an inverted terminal repetition approximately half that of vaccinia virus, was also shown to encode mRNA's that hybridized to the cloned terminal segment of vaccinia virus DNA.     

Association of adenovirus early-region 1A proteins with cellular polypeptides.

Extracts from adenovirus-transformed human 293 cells were immunoprecipitated with monoclonal antibodies specific for the early-region 1A (E1A) proteins. In addition to the E1A polypeptides, these antibodies precipitated a series of proteins with relative molecular weights of 28,000, 40,000, 50,000, 60,000, 80,000, 90,000, 110,000, 130,000, and 300,000. The two most abundant of these polypeptides are the 110,000-molecular-weight protein (110K protein) and 300K protein. Three experimental approaches have suggested that the 110K and 300K polypeptides are precipitated because they form stable complexes with the E1A proteins. The 110K and 300K polypeptides do not share epitopes with the E1A proteins, they copurify with a subset of the E1A proteins, and they bind to the E1A proteins following mixing in vitro. The 110K and 300K polypeptides are not adenoviral proteins, but are encoded by cellular DNA. Both the 12S and the 13S E1A proteins bind to the 110K and 300K species, and these complexes are found in adenovirus-transformed and -infected cells.     

Analysis of adenovirus early region 4-encoded polypeptides synthesized in productively infected cells.

Peptide-specific antisera were developed to analyze the products encoded by adenovirus type 5 early region 4 (E4) open reading frames 6 and 7. Reading frame 6 previously was shown to encode a 34-kilodalton polypeptide (34K polypeptide) that forms a complex with the early region 1B (E1B)-55K antigen and is required for efficient viral growth in lytic infection. Antisera that were generated recognized the E4-34K protein as well as a family of related polypeptides generated by the fusion of open reading frames 6 and 7. These polypeptides shared amino-terminal sequences with the 34K protein. Short-pulse analysis suggested that the heterogeneity observed with the 6/7 fusion products resulted from differential splicing patterns of related E4 mRNAs. An antiserum directed against the amino terminus of reading frame 6 recognized only the free form of the 34K antigen that was not associated with the E1B-55K protein. This observation allowed the determination of the stability of the free and complexed form of this polypeptide. Pulse-chase analyses demonstrated that both forms of the 34K protein had half-lives greater than 24 h, suggesting that complex formation did not result in stabilization of this gene product. The half-lives of the 6/7 fusion products were approximately 4 h. The 34K protein also was shown to have a nuclear localization within infected cells. Finally, analysis of a mutant carrying deletions in both the E4-34K and E1B-55K polypeptides indicated that the complex formed between these two proteins was a functional unit in lytic infection.