Integration and expression of viral DNA in cells transformed by host range mutants of adenovirus type 5

Inclusion of Moloney murine leukemia virus elements upstream of the transgene cassette in an E1-deleted adenovirus leads to an unusual genomic integration in epithelial cells

Classically, the 5' and 3' long terminal repeats (LTRs) are considered necessary but not sufficient for retroviral integration. Recently, we reported that inclusion of these and additional elements from Moloney murine leukemia virus (MoMLV) facilitated transgene integration, without retroviral integrase, when placed in an adenoviral context (AdLTR-luc vector) (Nat. Biotech. 18 (2000), 176; Biochem. Biophys. Res. Commun. 300 (2003), 115). To help understand this nonhomologous DNA recombination event, we constructed another vector, AdELP-luc, with 2.7 kb of MoMLV elements identically placed into an E1-deleted adenovirus type 5 backbone upstream of a luciferase cDNA reporter gene. Unlike AdLTR-luc, no MoMLV elements were placed downstream of the expression cassette. AdELP-luc readily infected epithelial cells in vitro. Southern hybridizations with DNA from cloned cells showed that disruption of the MoMLV sequences occurred. One cell clone, grown in vitro without any special selection medium for 9 months, exhibited stable vector integration and luciferase activity. Importantly, both Southern hybridization and FISH analyses showed that in addition to the MoMLV elements and expression cassette, substantial adenoviral sequence downstream of the luciferase cDNA was genomically integrated. These results suggest that the 2.7 kb of MoMLV sequence included in AdELP-luc have cis-acting functions and mediates an unusual integration event.

Transduction of the CHO aprt gene into mouse L cells using an adeno-5/APRT recombinant virus

An adenovirus-5 recombinant virus Adapt1 carrying the Chinese hamster ovary (CHO) adenine phosphoribosyltransferase (aprt) gene was constructed by insertion of a 2.5-kb fragment containing the complete CHO aprt structural gene linked to a Moloney murine sarcoma virus (MSV) promoter into the E3 region of adenovirus-5. The CHO aprt gene was in the opposite orientation to the adenovirus E3 promoter. Mouse Lapt- tk- (LAT) cells expressed the CHO aprt gene when infected with the virus, even at low MOI (O.1). APRT activity was detectable from approximately 20 h postinfection. At a low frequency, LAT cells were transformed to aprt+, and four stable transductants were selected in adenine, azaserine (AA) medium. Such cells expressed APRT at approximately 50% wild-type activity and the enzyme was shown to be CHO APRT by starch gel electrophoresis. DNA was isolated from the transductants and probed with CHO aprt-specific DNA and with viral DNA probes. The results indicated that the CHO aprt gene was integrated into the LAT cells at a site other than mouse aprt. Although neighboring viral sequences were integrated and maintained in the transductants, viral sequences further upstream and downstream of the aprt gene were absent.

The effect of E1 mutations on biochemical transformation by an adenovirus carrying the herpes simplex virus thymidine kinase gene in region E3

A series of human adenovirus type 5 (Ad5) vectors has been constructed in which a vector containing the human herpes simplex virus thymidine kinase (TK) gene has been recombined with several Ad5 early region 1 (E1) mutants. The resulting viruses were used to study host-virus interactions in TK- rat cells and to examine the importance of E1 functions in a biochemical transformation assay. One of the most important parameters affecting transformation efficiency in this system was the cytotoxicity of the transforming virus. Ad5 viruses expressing the E1a 289 amino acid protein were all highly cytotoxic and induced significantly fewer colonies than did less cytotoxic mutants which were defective in expression of the 289 amino acid product. When correction was made for differential cell viability the variation in transformation efficiencies was considerably reduced although some E1a mutants still demonstrated an enhanced ability to transform in comparison to wt virus. The significance of these results to morphological transformation by adenoviruses is discussed.

Adenovirus E1a ras cooperation activity is separate from its positive and negative transcription regulatory functions

The E1a gene of adenovirus encodes two proteins, 289 and 243 amino acids long, which have positive (transactivator) and negative (enhancer repressor) RNA polymerase II transcriptional regulatory properties and cell transformation activities including cooperation with an activated ras gene. The E1a transforming functions more closely correlate with the repressor property than with transactivation in that both E1a proteins express the repressor and transformation functions while only the 289-amino-acid protein is an efficient transactivator. To understand whether the transcriptional regulatory activities of E1a are related to its ras cooperation activity, we generated a series of mutant E1a expression vectors by linker insertion mutagenesis of the 289-amino-acid protein. Here we describe a new class of mutants which although defective for enhancer repression still can cooperate with the ras oncogene in cell transformation. The mutants are also defective in transcription transactivation. Our data suggest that enhancer repression and transformation via ras cooperation are separate E1a functions and that cooperation with ras does not rely on either of the RNA polymerase II transcription regulatory functions of E1a. We also show that mutations which inactivate enhancer repression are not confirmed to a single critical domain necessary for repression. We therefore propose that the integrity of the overall configuration of the E1a proteins is important for the repression activity.

Adenovirus E1a ras cooperation activity is separate from its positive and negative transcription regulatory functions

The E1a gene of adenovirus encodes two proteins, 289 and 243 amino acids long, which have positive (transactivator) and negative (enhancer repressor) RNA polymerase II transcriptional regulatory properties and cell transformation activities including cooperation with an activated ras gene. The E1a transforming functions more closely correlate with the repressor property than with transactivation in that both E1a proteins express the repressor and transformation functions while only the 289-amino-acid protein is an efficient transactivator. To understand whether the transcriptional regulatory activities of E1a are related to its ras cooperation activity, we generated a series of mutant E1a expression vectors by linker insertion mutagenesis of the 289-amino-acid protein. Here we describe a new class of mutants which although defective for enhancer repression still can cooperate with the ras oncogene in cell transformation. The mutants are also defective in transcription transactivation. Our data suggest that enhancer repression and transformation via ras cooperation are separate E1a functions and that cooperation with ras does not rely on either of the RNA polymerase II transcription regulatory functions of E1a. We also show that mutations which inactivate enhancer repression are not confirmed to a single critical domain necessary for repression. We therefore propose that the integrity of the overall configuration of the E1a proteins is important for the repression activity.

In vivo evolution of adenovirus 2-transformed cell virulence associated with altered E1A gene function

Neoplastic cell populations may evolve to a state of higher virulence in immunocompetent hosts. Transforming gene involvement in this process of tumor progression was evaluated using adenovirus type 2 (Ad2)-transformed hamster cells that are highly susceptible to destruction by natural killer cells and activated macrophages, due to Ad E1A gene function, and are nontumorigenic in immunocompetent animals. Cells selected for increased tumorigenicity retained parental cell patterns of viral gene integration and methylation and expressed Ad2 E1A proteins but exhibited altered E1A function evidenced by decreased susceptibility to killer cell-mediated lysis and inability to support E1A(-) mutant virus replication. The data suggest that an interruption in cellular pathways of E1A expression may result in increased transformed cell virulence.

Adenovirus E1A 12S protein induces DNA synthesis and proliferation in primary epithelial cells in both the presence and absence of serum

Infection of primary baby rat kidney (BRK) cells with an adenovirus that carries an E1A 12S cDNA in place of the normal E1A region (adenovirus 5 [Ad5] 12S) resulted in the induction of cellular DNA synthesis and proliferation of the epithelial cells in the population, even in the absence of serum. Increased cellular DNA synthesis was first detectable by 12 h after infection and was maintained at a 10- to 20-fold higher level than in mock-infected cells. By 5 days after infection there was a 10-fold-greater number of 12S virus-infected BRK cells. These infected BRK cells retained many of their normal epithelial cell characteristics and were not transformed. The expression of the E1A 12S protein(s) occurred early after infection. There was no induction of adenoviral gene expression or viral DNA replication in these cells. The early effects of a fully transforming gene product(s) were also examined. The Ad5-simian virus 40 hybrid virus, Ad5.SVR4, in which the early region of simian virus 40 has replaced the E1 region of Ad5, was used to infect BRK cells. The kinetics of expression of the T antigens were similar to those of the 12S polypeptides. Infection with Ad5.SV4 also resulted in the induction of cellular DNA synthesis and cell proliferation at levels similar to those observed with the 12S virus. However, infection with Ad5.SVR4 resulted in cells that had lost some of their epithelial cell characteristics and were fully transformed. Thus, although the early cellular events induced by the two genes were similar, they did not yield the same final cellular phenotype.

Multiple effects of the 72-kDa, adenovirus-specified DNA binding protein on the efficiency of cellular transformation

The early region 2A gene (E2A) of adenovirus types 2 and 5 encodes a 72-kDa DNA binding protein (DBP) which contains two physical domains comprising approximately the amino-terminal one-third and carboxyl-terminal two-thirds of the protein, respectively. Previous work has shown that some Ad5 mutants containing temperature-sensitive (ts) mutations in the carboxyl-terminal domain of DBP, such as Ad5ts125, show a 3- to 8-fold enhanced ability to transform rat cells. We have examined the transformation characteristics of a series of Ad5 E2A deletion mutants, Ad5dl801-5, which encode either no functional DBP or encode truncated, defective DBPs. The E2A deletion mutants transformed rat embryo cells at frequencies similar to wild-type (wt) Ad5. These results suggest that the high transformation phenotype of carboxyl-terminal E2A mutants like Ad5ts125 is not due to the simple inactivation of DBP function, but rather results from an activity possessed by an altered DBP. This hypothesis is supported by the fact that the transformation phenotype of Adsts125 and similar mutants is dominant over the wild-type phenotype. A number of additional Ad2 and Ad5 E2A mutants were examined with respect to their ability to transform primary rat embryo cells. It was found that a carboxyl-terminal E2A mutant, Ad2+ND1ts23, also showed the enhanced transformation phenotype. In contrast, several amino-terminal E2A host-range (hr) mutants, originally isolated on the basis of their ability to replicate in monkey cells, transformed rat embryo cells at a frequency similar to wild-type virus. Ad2ts400, and E2A mutant with alterations in both DBP domains, showed a wild-type frequency of transformation, while two similar mutants, Ad5ts125 X 405 and Ad5ts125 X 404, showed an enhanced frequency. Last, it was found that coinfection of primary rat embryo cells with the hr mutants plus Ad5ts125 or Ad2+ND1ts23 resulted in a wild-type frequency of transformation, demonstrating that the hr mutants are dominant to the ts mutants with regard to transformation phenotype. Thus, DBP can both positively and negatively affect viral transformation in this system.

Different activities of the adenovirus types 5 and 12 E1A regions in transformation with the EJ Ha-ras oncogene

We have compared the capacities of the E1A regions of nononcogenic adenovirus type 5 (Ad5) and highly oncogenic Ad12 to cooperate with the EJ bladder carcinoma Ha-ras-1 oncogene in the transformation of primary baby rat kidney cells. Both E1A regions, when cotransfected with the Ha-ras oncogene, transformed the primary cells with a low frequency. Ad5 E1A plus Ha-ras-transformed cells differed in phenotype from cells transformed by Ad12 E1A plus Ha-ras. The cells expressing Ad5 E1A appeared highly transformed and practically failed to adhere to plastic. This phenotype may be due to the virtually complete absence of fibronectin gene expression in these cells. In contrast, the cells expressing Ad12 E1A were flatter and adhered to plastic, whereas fibronectin gene expression was reduced but not absent. The oncogenic potential of the two types of E1A plus ras-transformed cells was tested by their injection into both athymic nude mice and weanling syngeneic rats. The Ad5 E1A plus ras-transformed cells were found to be highly oncogenic in both animal species, whereas the Ad12 E1A plus ras-transformed cells were only weakly oncogenic in both syngeneic rats and nude mice. The difference in oncogenic potential of the Ad5 E1A plus ras- and the Ad12 E1A plus ras-transformed cells is discussed in terms of the different capacities of the Ad5 and Ad12 E1A-encoded proteins to modulate cellular gene expression.

Transforming properties of a 15-kDa truncated Ad12 E1A gene product

A mutant Ad12 E1A region (Ad12 R11E1A) was constructed, which directs the synthesis of only a 15-kDa N-terminal E1A product. When controlled by the SV40 early promoter plus enhancer region (SVR11E1A) this mutant E1A region is capable of immortalizing primary baby rat kidney (BRK) cells, showing that the information essential for immortalization is located in the N-terminal part of region E1A and is shared by the 13 S and 12 S mRNA gene products. This immortalization is thought to be an essential step in the process of oncogenic transformation. Primary BRK cells transformed by SVR11E1A in the presence of Ad12 E1B are nononcogenic. This implies that the E1A region also codes for activities required for oncogenicity. However, in the presence of an activated c-Ha-ras oncogene the SVR11E1A region can oncogenically transform primary BRK cells, showing that the c-Ha-ras oncogene not only can complement for the Ad12 E1B region, but also for the E1A function lost by the R11 deletion.

Immortalization of rat embryo fibroblasts by an adenovirus 2 mutant expressing a single functional E1a protein

Expression of the adenovirus E1a and E1b genes is required for transformation of nonpermissive rodent cells. Differential splicing of the E1a precursor RNA molecules results in the production of two early mRNAs, 13S and 12S, which encode a 289-amino-acid-residue (289R) and 243R protein, respectively. Previously we constructed a mutant virus, dl231, which can only produce normal 289R protein from the E1a gene. In this report we demonstrate that dl231 induced focal transformation of primary rat embryo fibroblasts at 20% of the level of wild-type virus. dl231 transformants were immortalized and produced normal levels of E1a 13S and E1b mRNAs but only minute levels of defective E1a 12S mRNA. These transformants only minimally expressed the transformation phenotype and were similar to untransformed cells. Unlike wild-type transformants, they had a more fibroblastic morphology, were contact inhibited, grew to only low saturation density, and were limited in their ability to grow in an anchorage-independent manner in soft agar. We conclude that the 289R E1a protein can mediate immortalization of primary cells and that the 243R E1a protein is required to elicit the full transformation phenotype.

Transformation properties of type 5 adenovirus mutants that differentially express the E1A gene products

Type 5 adenovirus mutants that differentially express E1A 13S, 12S, or 9S mRNAs were constructed to study the role of their gene products in transformation. H5dl520 expresses the 243-amino-acid (AA) protein encoded in the 12S mRNA but not the 13S mRNA-encoded 289-AA protein. This mutant transformed both cloned rat embryo fibroblast (CREF) cells and baby rat kidney (BRK) cells at a frequency 40-100 times greater than did wild-type viruses. In addition, all of the foci produced were fibroblastic and grew very slowly at 32 degrees C. In contrast, H5dl21, which was mutated so that only the 54-AA protein encoded by the 9S mRNA was synthesized, did not transform either cell type. DNA transfection studies with plasmids from which these mutants were constructed demonstrated that the differences in transformation frequencies were not as marked. The plasmid pD1/D2, which directs the synthesis of the 54-AA protein only, was found to transform baby rat kidney cells at low frequency, provided the gene was linked to a fragment from the simian virus 40 genome containing the transcriptional enhancer element.

Dissection of overlapping functions within the adenovirus type 5 E1A gene

The adenovirus E1A gene encodes multiple, overlapping mRNAs whose products function both to regulate mRNA levels during the lytic cycle of the virus and to facilitate transformation of non-permissive cells. To assign specific functions to the E1A gene products, two adenovirus type 5 variants have been constructed. Mutants dl347 and 348 carry cloned segments corresponding to the E1A 12 and 13S mRNAs, respectively, in place of the normal E1A gene. The variants produced the predicted E1A-specific mRNAs and polypeptides. Both viruses grew efficiently in HeLa cells. Although the 13S mRNA products were more effective, the products of either mRNA species could stimulate the accumulation of mRNAs from additional transcription units. Both viruses could induce the formation of transformed foci in an established rat cell line. Neither virus could transform primary rat embryo cells at normal frequency, and the dl347 foci which were induced were incomplete or abortive transformants. Thus, functions encoded by both 12S and 13S mRNAs are required for efficient and complete transformation of primary rat cells.

Oncogenicity by adenovirus is not determined by the transforming region only

We have constructed a nondefective recombinant virus between the nononcogenic adenovirus 5 (Ad5) and the highly oncogenic Ad12. The recombinant genome consists essentially of Ad5 sequences, with the exception of the transforming early region 1 (E1) which is derived from Ad12. HeLa cells infected with the recombinant virus were shown to contain the Ad12-specific E1 proteins of 41 kilodaltons (E1a) and 19 and 54 kilodaltons (both encoded by E1b). The recombinant virus replicated efficiently in human embryonic kidney cells and HeLa cells, showing that the transforming regions of Ad5 and Ad12 had similar functions in productive infection. After the recombinant virus was injected into newborn hamsters, no tumors were produced during an observation period of 200 days. Thus, despite the fact that all products required for oncogenic transformation in vitro were derived from the highly oncogenic Ad12, the recombinant virus did not produce tumors in vivo. These data show that tumor induction by adenovirus virions is not determined only by the gene products of the transforming region.

Infection of eucaryotic cells by helper-independent recombinant adenoviruses: early region 1 is not obligatory for integration of viral DNA

Recombinant viral genomes carrying a selectable drug resistance marker have been constructed by insertion of a hybrid gene for neomycin resistance into the helper-independent adenovirus vector, delta E1/X. The hybrid gene consists of sequences coding for the aminoglycoside 3'-phosphotransferase II from Tn5, under the control of the simian virus 40 early promoter, and renders mammalian cells resistant to the neomycin analog, G-418. Most of adenovirus early region 1 is deleted from delta E1/X (nucleotides 455 to 3330), and recombinant viral genomes carry the hybrid gene in its place. The large and small XbaI fragments of delta E1/X were ligated to the hybrid gene, and the mixture was transfected into 293 cells. Single plaques were isolated and subsequently passaged in 293 cells to produce virus stocks. The recombinant viruses efficiently rendered cultured rat (Rat2) and simian (CV1) cells resistant to G-418. Cloned cell lines selected for resistance to G-418 contained viral DNA integrated into the host cell genome, demonstrating that early region 1 is not essential for integration of the viral genome. Southern transfer experiments revealed that (i) the sites of integration in the host genome were not unique; (ii) in general, transformed CV1 cell lines contained single-copy, full-length viral genomes, colinear with the infecting virus; (iii) transformed Rat2 cell lines generally contained one to several copies of full-length viral genomes integrated colinearly with the infecting viral DNA; and (iv) three of these five lines of transformed Rat2 cell lines contained tandemly repeated viral DNA sequences in which the right and left ends of the viral genome were joined to each other.

Complete transformation by adenovirus 2 requires both E1A proteins

Rodent cells transformed by adenovirus 2 (Ad2) express two highly related viral proteins of 289 and 243 amino acids encoded in early region 1A (E1A). Transformation studies were performed with adenovirus mutants that express only one or the other E1A protein. We found that the 289 amino acid protein, which has transcription inducing activity, and the 243 amino acid protein, which has little if any of this activity, were both required to produce the fully transformed phenotype. Expression of either E1A protein induced a partially transformed phenotype. The 243 amino acid protein was particularly important for anchorage independent growth. As found in previous studies with several other E1A mutants, the process of transformation by the mutant that expresses the 243 amino acid protein only was cold-sensitive. While the 289 amino acid protein is the only E1A protein required for efficient viral replication under standard cell culture conditions, the 243 amino acid protein in addition to the 289 amino acid protein was found to be required for efficient viral replication in growth-arrested human cells.

Transformation by human adenoviruses

When, approximately 10 years ago, it was shown that the functions essential for cell transformation were localized in a small region of the adenovirus genome, a DNA segment which at that time was thought to be capable of encoding two or three average-sized proteins at most, it seemed reasonable to hope that an understanding of the mechanisms by which adenoviruses transform cells might be quickly achieved. While such optimism might be forgiven, it was quite clearly naive in the extreme. As a consequence of mRNA splicing and the use of overlapping reading frames the number of proteins encoded within E1 is 2-3-times greater than would have been predicted a decade ago, and post-translational modifications may add another dimension of complexity. In fact it has taken nearly all of the past decade just to identify the proteins encoded in E1 and to characterize them in the most rudimentary way. However, we have now entered a period in which new information is accumulating at an extremely rapid rate as a result of several major technical and fundamental advances. Chief among these are the use of recombinant DNA techniques, particularly site-directed mutagenesis, which combined with methods for introducing mutations made in cloned sequences back into infectious virus, clearly represents a powerful approach to studying the functions of transforming proteins. In addition, the ability to express transforming proteins in bacteria and to produce large amounts of highly purified proteins which previously were only just detectable in infected and transformed cells is a major breakthrough. Advances in immunological techniques, particularly the development of monoclonal antibodies and antisera against synthetic peptides, have enormously simplified the task of detecting and characterizing E1 proteins. Finally, recent results suggesting that adenovirus transforming proteins may be functionally and structurally similar to other oncogenes brings a new perspective to the study of oncogenic transformation. Have all the proteins involved in transformation by adenoviruses been identified? It seems probable that all those virally coded proteins which play a major role are now known but of course minor players in the cast could still be waiting in the wings. We have pointed out that viral functions encoded outside region E1 may have some importance at least in initiation of transformation by virions and have speculated on the possibility that one or more of these may be involved in the integration of viral DNA into the host cell chromosome.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Transformation of rodent cells by DNA extracted from transformation-defective adenovirus mutants

Complementation group II host range mutants of adenovirus type 5 which map in early region 1B (E1B, 4.5 to 11.0 map units) have been shown to be defective for the synthesis of the E1B 58,000-dalton (58K) antigen in infections of HeLa or KB cells (Lassam et al., Cell 18:781-791, 1979) and unable to transform cultured rodent cells (Graham et al., Virology 86:10-21, 1978). In this report we show that DNA extracted from group II mutants hr6 and hr50 can transform rat cells with the same efficiency as wild-type DNA. Furthermore, group II mutant-transformed hamster cells were shown to contain no detectable E1B 58K tumor antigen but were capable of inducing tumors in newborn hamsters. Hamster cell lines 1019-3 and 1019-C3, transformed by hr50 DNA, produced no detectable quantities of either the E1B 58K or 19K antigen but nonetheless exhibited a fully transformed oncogenic phenotype. Our results show that the E1B 58K antigen is not absolutely required for oncogenic transformation and suggest that even cells lacking the 19K protein can be oncogenic.

Cold-sensitive expression of transformation by a host range mutant of type 5 adenovirus

hr1, an E1a (0-4.5 map units) host range mutant of type 5 adenovirus (Ad5), transformed a cloned rat embryo fibroblast (CREF) cell line at about a 5-fold higher frequency than wild-type (wt) Ad5 when cells were cultured at 37 degrees C. However, if the cells were infected with hr1 and maintained at 32 degrees C morphological transformation did not occur. When infected cells were shifted from 32 degrees C to 37 degrees C 2 wk postinfection, the frequency of transformation by 6 wk was identical to that of cells grown continuously at 37 degrees C, whereas cultures shifted from 37 degrees C to 32 degrees C 2 wk postinfection displayed a greater than 96% reduction in morphological transformation. hr1-transformed cells had a fibroblastic morphology as contrasted with the typical epithelioid morphology of wt Ad5-transformed cells, but hr1- and wt Ad5-transformed cells had similar saturation densities, growth rates, and agar cloning efficiencies when assayed at 37 degrees C. However, when cells transformed by hr1 at 37 degrees C were grown at 32 degrees C, they had a saturation density close to that of normal CREF cells and grew at a lower efficiency in agar than wt-transformed cells. DNA transfer/hybridization analysis of two hr1-transformed cloned cell lines, A2 and B3, indicated that A2 cells contained a complete integrated copy of the Ad5 genome, whereas in B3 cells only part of the Ad5 genome was integrated. RNA transfer and RNA/DNA filter hybridization analyses indicated that the types of viral messenger RNAs and the relative amounts of RNA transcribed were similar in the A2 and B3 cell lines when they were grown at 32 degrees C and 37 degrees C. Indirect immunofluorescence, with antisera from hamsters bearing Ad-induced tumors, indicated a temperature dependence in staining--i.e., cells grown at 37 degrees C or shifted from 32 degrees C to 37 degrees C contained intense, particulate staining in the nuclear region, whereas the staining was decreased significantly in cells cultured at 32 degrees C and in cells shifted from 37 degrees C to 32 degrees C. These findings indicate that the gene product affected by the hr1 mutation is cold sensitive and is essential for the expression of the characteristics that identify the transformed cell.

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.

Covalently closed circles of adenovirus 5 DNA

The genome of adenoviruses is a double-stranded linear DNA molecule with inverted terminal repeats about 100 base pairs (bp) in length and a terminal protein covalently linked to the 5' nucleotide of each strand. Both of these features permit the formation of DNA circles, the inverted repeats allowing the circularization of single-stranded DNA and the terminal protein the joining of one or more molecules to yield double-stranded circles or concatemers. However, although the existence of covalently closed circles has been postulated, double-stranded viral DNA purified from virions or infected cells by conventional methods (that is, using proteases and phenol or chloroform) has always been obtained in a linear form. Here, we present evidence for the existence in adenovirus 5 (Ad5) infected cells of novel structures resulting from covalent head-to-tail joining of viral DNA molecules and show that these structures are due at least in part to the formation of covalently closed circles.

Tn5 mutagenesis of the transforming genes of human adenovirus type 5

We have cloned the entire human adenovirus type 5 (Ad5) genome into the pBR322 plasmid in two segments: the BamHI-A fragment (21 kb) and the BamHI-B fragment (15 kb). We have also generated a series of clones with smaller Ad5 DNA inserts, all containing the left-end of the viral genome. One such clone, pXCl, containing the left 16% of the Ad5 DNA molecule, has been shown to transform rodent cells by DNA transfection. We have used the transposable element Tn5 as an insertion mutator to isolate pXCl mutants containing Tn5 inserted at a large number of sites. By assaying transforming activity of selected pXC::Tn5 plasmids we have identified Ad5 sequences which are essential for DNA-mediated transformation. Our results with these mutants and with a plasmid pCD1, containing a deletion within the Ad5-transforming region, indicate that sequences present in both early region 1a and the N-terminal region of early region 1b are essential for DNA-mediated transformation.