Transcription of the genome of adenovirus type 12. III. Maps of stable RNA from productively infected human cells and abortively infected and transformed hamster cells

Inheritable epigenetic response towards foreign DNA entry by mammalian host cells: a guardian of genomic stability

Apart from its well-documented role in long-term promoter silencing, the genome-wide distribution patterns of ~ 28 million methylated or unmethylated CpG dinucleotides, e. g. in the human genome, is in search of genetic functions. We have set out to study changes in the cellular CpG methylation profile upon introducing foreign DNA into mammalian cells. As stress factors served the genomic integration of foreign (viral or bacterial plasmid) DNA, virus infections or the immortalization of cells with Epstein Barr Virus (EBV). In all instances investigated, alterations in cellular CpG methylation and transcription profiles were observed to different degrees. In the case of adenovirus DNA integration in adenovirus type 12 (Ad12)-transformed hamster cells, the extensive changes in cellular CpG methylation persisted even after the complete loss of all transgenomic Ad12 DNA. Hence, stress-induced alterations in CpG methylation can be inherited independent of the continued presence of the transgenome. Upon virus infections, changes in cellular CpG methylation appear early after infection. In EBV immortalized as compared to control cells, CpG hypermethylation in the far-upstream region of the human FMR1 promoter decreased four-fold. We conclude that in the wake of cellular stress due to foreign DNA entry, preexisting CpG methylation patterns were altered, possibly at specific CpG dinucleotides. Frequently, transcription patterns were also affected. As a working concept, we view CpG methylation profiles in mammalian genomes as a guarding sensor for genomic stability under epigenetic control. As a caveat towards manipulations of cells with foreign DNA, such cells can no longer be considered identical to their un-manipulated counterparts.

Discoveries in Molecular Genetics with the Adenovirus 12 System: Integration of Viral DNA and Epigenetic Consequences

Starting in the 1960s, the human adenovirus type 12 (Ad12) system has been used in my laboratory to investigate basic mechanisms in molecular biology and viral oncology. Ad12 replicates in human cells but undergoes a completely abortive cycle in Syrian hamster cells. Ad12 induces neuro-ectodermal tumors in newborn hamsters (Mesocricetus auratus). Each tumor cell or Ad12-transformed hamster cell carries multiple copies of integrated Ad12 DNA. Ad12 DNA usually integrates at one chromosomal site which is not specific since Ad12 DNA can integrate at many different locations in the hamster genome. Epigenetic research occupies a prominent role in tumor biology. We have been using the human Ad12 Syrian hamster cell system for the analysis of epigenetic alterations in Ad12-infected cells and in Ad12-induced hamster tumors. Virion or free intracellular Ad12 DNA remains unmethylated at CpG sites, whereas the integrated viral genomes become de novo methylated in specific patterns. Inverse correlations between promoter methylation and activity were described for the first time in this system and initiated active research in the field of DNA methylation and epigenetics. Today, promoter methylation has been recognized as an important factor in long-term genome silencing. We have also discovered that the insertion of foreign (Ad12, bacteriophage lambda, plasmid) DNA into mammalian genomes can lead to genome-wide alterations in methylation and transcription patterns in the recipient genomes. This concept has been verified recently in a pilot study with human cells which had been rendered transgenomic for a 5.6 kbp bacterial plasmid. Currently, we study epigenetic effects on cellular methylation and transcription patterns in Ad12-infected cells and in Ad12-induced hamster tumor cells. These epigenetic alterations are considered crucial elements in (viral) oncogenesis.

Tumorigenic adenovirus 12 cells evade NK cell lysis by reducing the expression of NKG2D ligands

Activation of natural killer (NK) cells depends on a balance between signals received from activation and inhibitory ligands expressed on the surface of target cells. Tumorigenic human adenovirus 12 (Ad12) transformed cells express low levels of the NK cell inhibitory ligand MHC I, but do not exhibit increased sensitivity to NK cell lysis compared to their non-tumorigenic counterparts. Analysis of the expression of activation ligands that bind to the NKG2D receptor revealed that RAE1β and H60 were reduced on the surface of Ad12 mouse cells as well as at the level of transcription. In accord with these results, RAE1 localization to the synapse and sensitivity to NK cell cytotoxicity were also diminished. The reduced transcription of the rat NKG2D ligands, RAEt1L and RRTL, in tumorigenic rat cells compared to non-tumorigenic counterparts implies that both mouse and rat cell lines share a common mechanism of NKG2D ligand activation subverted by Ad12.

Epigenetic mechanisms in human adenovirus type 12 oncogenesis

For the past 30 years, my laboratory has concentrated its work on demonstrating that the epigenetic consequences of foreign DNA insertion into established mammalian genomes – de novo DNA methylation of the integrate and alterations of methylation patterns across the recipient genome – are essential elements in setting the stage towards oncogenic transformation. We have primarily studied human adenovirus type 12 (Ad12) which induces undifferentiated tumors in Syrian hamsters (Mesocricetus auratus) either at the site of subcutaneous Ad12 injection or intraperitoneally upon intramuscular injection. Up to 90% of the hamsters injected with Ad12 develop tumors within 3–6 weeks. Integration of foreign DNA, its de novo methylation, and the consequences of insertion on the cellular methylation and transcription profiles have been studied in detail. While viral infections are a frequent source of foreign genomes entering mammalian and other hosts and often their genomes, we have also pursued the fate of food-ingested foreign DNA in the mouse organism. The persistence of this DNA in the animals is transient and there is no evidence for the expression or germ line fixation of foreign DNA. Nevertheless, the occasional cell that carries integrated genomes from that foreign source deserves the oncologist's sustained interest.

Epigenetic status of an adenovirus type 12 transgenome upon long-term cultivation in hamster cells

The epigenetic status of integrated adenovirus type 12 (Ad12) DNA in hamster cells cultivated for about 4 decades has been investigated. Cell line TR12, a fibroblastic revertant of the Ad12-transformed epitheloid hamster cell line T637 with 15 copies of integrated Ad12 DNA, carries one Ad12 DNA copy plus a 3.9-kbp fragment from a second copy. The cellular insertion site for the Ad12 integrate, identical in both cell lines, is a >5.2-kbp inverted DNA repeat. The Ad12 transgenome is packaged around nucleosomes. The cellular junction is more sensitive to micrococcal nuclease at Ad12-occupied sites than at unoccupied sites. Bisulfite sequencing reveals complete de novo methylation in most of the 1,634 CpGs of the integrated viral DNA, except for its termini. Isolated unmethylated CpGs extend over the entire Ad12 integrate. The fully methylated transgenome segments are characterized by promoter silencing and histone H3 and H4 hypoacetylation. Nevertheless, there is minimal transcriptional activity of the late viral genes controlled by the fully methylated major late promoter of Ad12 DNA.

Human Adenovirus Type 12

When viruses cross species barriers, they often change their biological and pathogenetic properties. In the author's laboratory the nonproductive interaction of Syrian hamster cells with human adenovirus type 12 (Ad12) has been studied. Ad12 induces undifferentiated tumors in newborn hamsters (Mesocricetus auratus) at high frequency. Ad12 inefficiently enters hamster (BHK21) cells, and only small amounts of viral DNA reach the nucleus. Viral DNA replication and late transcription are blocked. In Ad12-induced tumor cells, multiple copies of viral DNA are chromosomally integrated. The integrated viral DNA becomes de novo methylated. Cellular DNA methylation and transcription patterns in Ad12-transformed cells and in Ad12- induced tumor cells are altered. These changes may be related to the oncogenic potential of Ad12 in hamsters. In this chapter, concepts and techniques for the study of the Ad12-hamster cell system are summarized.

De novo methylation, long-term promoter silencing, methylation patterns in the human genome, and consequences of foreign DNA insertion

This chapter presents a personal account of the work on DNA methylation in viral and mammalian systems performed in the author's laboratory in the course of the past 30 years. The text does not attempt to give a complete and meticulous account of the work accomplished in many other laboratories; in that sense it is not a review of the field in a conventional sense. Since the author is also one of the editors of this series of Current Topics in Immunology and Microbiology on DNA methylation, to which contributions by many of our colleagues in this field have been invited, the author's conscience is alleviated that he has not cited many of the relevant and excellent reports by others. The choice of viral model systems in molecular biology is well founded. Over many decades, viruses have proved their invaluable and pioneering role as tools in molecular genetics. When our interest turned to the demonstration of genome-wide patterns of DNA methylation, we focused mainly on the human genome. The following topics in DNA methylation will be treated in detail: (1) The de novo methylation of integrated foreign genomes; (2) the long-term gene silencing effect of sequence-specific promoter methylation and its reversal; (3) the properties and specificity of patterns of DNA methylation in the human genome and their possible relations to pathogenesis; (4) the long-range global effects on cellular DNA methylation and transcriptional profiles as a consequence of foreign DNA insertion into an established genome; (5) the patterns of DNA methylation can be considered part of a cellular defense mechanism against foreign or repetitive DNA; which role has food-ingested DNA played in the elaboration of this mechanism? The interest in problems related to DNA methylation has spread-like the mechanism itself-into many neighboring fields. The nature of the transcriptional programs orchestrating embryonal and fetal development, chromatin structure, genetic imprinting, genetic disease, X chromosome inactivation, and tumor biology are but a few of the areas of research that have incorporated studies on the importance of the hitherto somewhat neglected fifth nucleotide in many genomes. Even the fly researchers now have to cope with the presence of this nucleotide, in however small quantities it exists in the genome of their model organism, at least during embryonal development. The bulk of the experimental work accomplished in the author's laboratory has been shouldered by many very motivated undergraduate and graduate students and by a number of talented postdoctoral researchers. Their contributions are reflected in the list of references in this chapter. We have also had the good luck to receive funding through a number or organizations as acknowledged.

On the biological significance of DNA methylation

This chapter presents a personal account of the work on DNA methylation in viral and mammalian systems performed in the author's laboratory in the course of the past thirty years. The text does not attempt to give a complete and meticulous account of the many relevant and excellent reports published by many other laboratories, so it is not a review of the field in a conventional sense. The choice of viral model systems in molecular biology is well founded. Over many decades, viruses have proven their invaluable and pioneering role as tools in molecular genetics. When our interest turned to the demonstration of genome-wide patterns of DNA methylation, we focused mainly on the human genome. The following topics in DNA methylation will be treated in detail: (i) the de novo methylation of integrated foreign genomes; (ii) the long-term gene silencing effect of sequence-specific promoter methylation and its reversal; (iii) the properties and specificity of patterns of DNA methylation in the human genome and their possible relations to pathogenesis; (iv) the long-range global effects on cellular DNA methylation and transcriptional profiles as a consequence of foreign DNA insertion into an established genome; (v) the patterns of DNA methylation can be considered part of a cellular defense mechanism against foreign or repetitive DNA; what role has food-ingested DNA played in the elaboration of this mechanism?

Insertion of foreign DNA into an established mammalian genome can alter the methylation of cellular DNA sequences

The insertion of adenovirus type 12 (Ad12) DNA into the hamster genome and the transformation of these cells by Ad12 can lead to marked alterations in the levels of DNA methylation in several cellular genes and DNA segments. Since such alterations in DNA methylation patterns are likely to affect the transcription patterns of cellular genes, it is conceivable that these changes have played a role in the generation or the maintenance of the Ad12-transformed phenotype. We have now isolated clonal BHK21 hamster cell lines that carry in their genomes bacteriophage lambda and plasmid pSV2neo DNAs in an integrated state. Most of these cell lines contain one or multiple copies of integrated lambda DNA, which often colocalize with the pSV2neo DNA, usually in a single chromosomal site as determined by the fluorescent in situ hybridization technique. In different cell lines, the loci of foreign DNA insertion are different. The inserted bacteriophage lambda DNA frequently becomes de novo methylated. In some of the thus-generated hamster cell lines, the levels of DNA methylation in the retrotransposon genomes of the endogenous intracisternal A particles (IAP) are increased in comparison to those in the non-lambda-DNA-transgenic BHK21 cell lines. These changes in the methylation patterns of the IAP subclone I (IAPI) segment have been documented by restriction analyses with methylation-sensitive restriction endonucleases followed by Southern transfer hybridization and phosphorimager quantitation. The results of genomic sequencing experiments using the bisulfite protocol yielded additional evidence for alterations in the patterns of DNA methylation in selected segments of the IAPI sequences. In these experiments, the nucleotide sequences in >330 PCR-generated cloned DNA molecules were determined. Upon prolonged cultivation of cell lines with altered cellular methylation patterns, these differences became less apparent, perhaps due to counterselection of the transgenic cells. The possibility existed that the hamster BHK21 cell genomes represent mosaics with respect to DNA methylation in the IAPI segment. Hence, some of the cells with the patterns observed after lambda DNA integration might have existed prior to lambda DNA integration and been selected by chance. A total of 66 individual BHK21 cell clones from the BHK21 cell stock have been recloned up to three times, and the DNAs of these cell populations have been analyzed for differences in IAPI methylation patterns. None have been found. These patterns are identical among the individual BHK21 cell clones and identical to the patterns of the originally used BHK21 cell line. Similar results have been obtained with nine clones isolated from BHK21 cells mock transfected by the Ca2+-phosphate precipitation procedure with DNA omitted from the transfection mixture. In four clonal sublines of nontransgenic control BHK21 cells, genomic sequencing of 335 PCR-generated clones by the bisulfite protocol revealed 5'-CG-3' methylation levels in the IAPI segment that were comparable to those in the uncloned BHK21 cell line. We conclude that the observed changes in the DNA methylation patterns in BHK21 cells with integrated lambda DNA are unlikely to preexist or to be caused by the transfection procedure. Our data support the interpretation that the insertion of foreign DNA into a preexisting mammalian genome can alter the cellular patterns of DNA methylation, perhaps via changes in chromatin structure. The cellular sites affected by and the extent of these changes could depend on the site and size of foreign DNA insertion.

Chromosomal insertion of foreign (adenovirus type 12, plasmid, or bacteriophage lambda) DNA is associated with enhanced methylation of cellular DNA segments

Insertion of foreign DNA into an established mammalian genome can extensively alter the patterns of cellular DNA methylation. Adenovirus type 12 (Ad12)-transformed hamster cells, Ad12-induced hamster tumor cells, or hamster cells carrying integrated DNA of bacteriophage lambda were used as model systems. DNA methylation levels were examined by cleaving cellular DNA with Hpa II, Msp I, or Hha I, followed by Southern blot hybridization with 32P-labeled, randomly selected cellular DNA probes. For several, but not all, cellular DNA segments investigated, extensive increases in DNA methylation were found in comparison with the methylation patterns in BHK21 or primary Syrian hamster cells. In eight different Ad12-induced hamster tumors, moderate increases in DNA methylation were seen. Increased methylation of cellular genes was also documented in two hamster cell lines with integrated Ad12 DNA without the Ad12-transformed phenotype, in one cloned BHK21 cell line with integrated plasmid DNA, and in at least three cloned BHK21 cell lines with integrated lambda DNA. By fluorescent in situ hybridization, the cellular hybridization probes were located to different hamster chromosomes. The endogenous intracisternal A particle genomes showed a striking distribution on many hamster chromosomes, frequently on their short arms. When BHK21 hamster cells were abortively infected with Ad12, increases in cellular DNA methylation were not seen. Thus, Ad12 early gene products were not directly involved in increasing cellular DNA methylation. We attribute the alterations in cellular DNA methylation, at least in part, to the insertion of foreign DNA. Can alterations in the methylation profiles of hamster cellular DNA contribute to the generation of the oncogenic phenotype?

The initiation of de novo methylation of foreign DNA integrated into a mammalian genome is not exclusively targeted by nucleotide sequence

The de novo methylation of foreign DNA integrated into the mammalian genome is a fundamental process whose mechanism has not yet been elucidated. We have studied de novo methylation in adenovirus type 12 (Ad12) genomes inserted into the genomes of Ad12-induced hamster tumor cells. De novo methylation of Ad12 DNA, which is not methylated in the virion, is initiated in two paracentrally located regions and spreads from there across the integrated Ad12 genomes. (i) After extensive cultivation of cloned Ad12-induced hamster tumor cell lines, the same segments in integrated Ad12 DNA in different cell lines become methylated or remain unmethylated, depending on their positions in the viral genome. (ii) When Ad12 DNA or Ad12 DNA fragments are transfected into hamster cells and permanent cell lines are established by selection for the cotransfected neomycin phosphotransferase gene, patterns of de novo methylation in terminally or internally located segments of Ad12 DNA are different from those in Ad12-induced tumor cell lines. (iii) A detailed study on the topology of the integrated viral genomes in the Ad12-transformed hamster cell lines T637 and A2497-3 and in the Ad12-induced hamster tumors T191, T1111(1), and T181 has been performed. Some of the integrated viral genomes are inserted into the cellular genome in an orientation colinear with the virion genome; others have been rearranged. An originally internally located Ad12 DNA segment has become transposed to the left-terminal sequences of the viral genome in several cell lines and tumors. In the complete Ad12 genomes, the internally located PstI-D fragment becomes extensively methylated at the 5'-CCGG-3' and 5'-GCGC-3' sequences. When this DNA segment has been juxtaposed to the left-terminal, hypomethylated fragment of Ad12 DNA in rearranged genomes, the PstI-D fragment remains unmethylated. We therefore reason that the initiation of de novo methylation in integrated Ad12 DNA cannot be directed exclusively by the nucleotide sequence. Other parameters, such as site of integration, conformation of integrates, mode of cell selection, or chromatin structure related to transcriptional activity, may play decisive roles.

Late transcripts of adenovirus type 12 DNA are not translated in hamster cells expressing the E1 region of adenovirus type 5

Hamster cells are completely nonpermissive for the replication of human adenovirus type 12 (Ad12), whereas types 2 and 5 can replicate in hamster cells. The Ad5-transformed hamster cell line BHK297-C131, which carries the left terminal 18.7% of the Ad5 genome and expresses at least the viral E1A region, can somehow complement Ad12 DNA replication and the transcription of the late Ad12 genes. Since the interaction of Ad12 with hamster cells must constitute a significant factor in the induction of Ad12 tumors in neonatal hamsters, we have continued to examine details of this abortive virus infection. The late Ad12 mRNAs in BHK297-C131 cells are polyadenylated but are synthesized in reduced amounts compared with the Ad12 products in Ad12-infected human cells, which are permissive for viral replication. The late mRNA derived from the Ad12 fiber gene has been assessed for its structural properties. By cloning cDNA transcripts from this region and determining their nucleotide sequences, the authenticity of the complete Ad12 fiber sequence and the completeness of the Ad12-typical tripartite leader have been confirmed. Moreover, in Ad12-infected BHK297-C131 cells the Ad12 virus-associated RNA, a virus-encoded translational activator with the correct nucleotide sequence, is synthesized. Nevertheless, the synthesis of detectable amounts of Ad12 virion-specific proteins, and in particular that of the main viral antigens, hexons and fibers, cannot be documented. Cellular factors needed to promote late mRNA translation might be missing, or inhibitory factors might exist in Ad12-infected BHK297-C131 cells.

Nucleotide sequence of human adenovirus type 12 DNA: comparative functional analysis

A fresh inoculum of human adenovirus type 12 (Ad12) was obtained from the American Type Culture Collection and passaged once on human embryonic kidney cells, and Ad12 DNA was prepared from the first-passage yield to avoid higher passages which might have generated host-virus DNA recombinants. The 18 PstI fragments of Ad12 DNA were cloned into the pBluescript KS vector, and the entire nucleotide sequence of both strands from all 18 fragments was determined by using successive oligodeoxyribonucleotide primers. Ad12 DNA extends over 34,125 nucleotide pairs, and its molecular weight is calculated to be about 22 x 10(6). The nucleotide sequence of Ad12 DNA was subjected to computer analyses that determined possible open reading of frames on the two strands, the leader sequences, the position of the virus-associated RNA coding region, possible TATA, and polyadenylation signals. The distribution of the Ad12 open reading frames was similar to that in the previously sequenced Ad2 DNA, but there were also distinct differences. Ad12 DNA has an inverted terminal redundancy of 161 nucleotides, compared with 102 nucleotides in Ad2 DNA. There were stretches of sequence identity between Ad2 and Ad12 DNAs at both termini; the overall sequence similarity between the two viral genomes ranged between 59% (polypeptide IX) and 77% (in the E2 region), with high homology also in the sequences for the adenovirus DNA polymerase.

Altered expression of adenovirus 12 DNA-binding protein but not DNA polymerase during abortive infection of hamster cells

Replication of human adenovirus type 12 DNA is blocked in abortively infected baby hamster kidney cells. The activity and accumulation of adenovirus 12 DNA polymerase is equivalent in infected hamster and human cell extracts. However, the accumulation of adenovirus type 12 DNA-binding protein is approximately 120-fold lower in extracts from infected hamster cells when compared to infected permissive human cells. This difference in accumulation is not due to replication of viral DNA during productive infection, since this difference is observed in the presence of hydroxyurea. The DNA-binding protein from infected hamster cells retains the ability to bind denatured DNA-cellulose. An adenovirus 5 early region 1 transformed hamster cell line competent to complement the adenovirus 12 DNA replication defect also stimulates accumulation of the DNA-binding protein even when the cells are treated with hydroxyurea. Thus, the reduced expression of the viral DNA-binding protein may play a role in the mechanism of abortive infection of hamster cells by adenovirus 12.

Extracts of hamster cells abortively infected with human adenovirus type 12 are competent to support initiation of viral DNA replication

Baby hamster kidney (BHK-21) cells do not allow replication of human adenovirus type 12 (Ad12) DNA during abortive infection by this virus. However, we have determined that crude extracts of BHK-21 cells abortively infected with Ad12 support in vitro the initiation reaction of Ad12 DNA replication. Synthesis of the Ad12 pTP-dCMP initiation complex by BHK extracts is two- to five-fold less than when crude infected human (KB) cell extracts are used in the reaction. Combining infected KB cytoplasmic and uninfected BHK nuclear extracts in the reaction indicates that the decreased efficiency is probably due to a lesser ability of hamster nuclear extracts to support the initiation reaction, rather than to decreased synthesis of Ad12 pTP and DNA polymerase during abortive infection, or to the presence of an inhibitor in BHK cells.

Defect of adenovirus type 12 replication in hamster cells: absence of transcription of viral virus-associated and L1 RNAs

The nonpermissive interaction of hamster cells with human adenovirus type 12 (Ad12) is characterized by a total block of Ad12 DNA replication and late transcription, whereas most of the early functions of Ad12 DNA can be transcribed. Ad2 can replicate in hamster cells. The replication and late transcription defects of Ad12 DNA can be complemented to a certain extent by the E1B functions of Ad2 DNA. This complementation fails, however, to lead to the synthesis of the late Ad12 proteins and to the assembly of infectious virions. It will now be demonstrated that the Ad12 L1 (late genes of group 1) and virus-associated (VA) RNAs are not transcribed in hamster cells. Synthesis of these RNAs in productively infected human cells or Ad2-infected hamster cells is readily detectable by S1 nuclease protection experiments and Northern (RNA) blotting. Similarly, the Ad2-transformed hamster cell line BHK-Ad2E1 fails to complement L1 and VA RNA syntheses after superinfection with Ad12. However, Ad12 infection of the Ad5-transformed hamster cell line BHK297-C131 leads to the transcription of the Ad12 L1 and VA segments. This difference in complementation by the two transformed hamster cell lines might be accounted for by functions in the segment of Ad5 DNA extending between map units 30 and 40 and persisting in the Ad5-transformed hamster cells or by hamster host cell functions which might be operative in cell line BHK297-C131 but not in BHK-Ad2E1 or BHK-21 hamster cells.

Arrangement and expression of integrated adenovirus type 12 DNA in the transformed hamster cell line HA12/7: amplification of Ad12 and c-myc DNAs and evidence for hybrid viral-cellular transcripts

In the genome of the adenovirus type 12 (Ad12)-transformed hamster cell line HA12/7 about three copies of the viral DNA are fixed by integration. The results of blot-hybridization, molecular cloning, and nucleotide sequencing experiments suggest a model for the arrangement of Ad12 DNA molecules in which the left hand terminus of one of the Ad12 DNA copies is linked to unique hamster DNA. The right hand end of this DNA molecule is fused to an inverted copy of a left terminal approximately 4.3 kb fragment of Ad12 DNA. This ensemble is followed by the second Ad12 DNA copy whose right terminus is again joined to an inverted, supernumerary left terminal approximately 4.3 kb Ad12 DNA fragment. There is a third Ad12 DNA copy whose right terminus is linked to cellular DNA. In this sequence arrangement, the left terminus of Ad12 DNA is overrepresented, as had been shown earlier (S. Stabel, W. Doerfler and R.R. Friis (1980) J. Virol. 36, 22-40). In the presented model, cellular DNA sequences are interspersed in between the three copies of Ad12 DNA. In the left terminus of the integrated Ad12 DNA, transcription of RNA is initiated which extends out into cellular DNA. The interviral DNA junctions are also transcribed. The c-myc gene in cell line HA12/7 is amplified about 10-fold and considerably more c-myc RNA has been identified in the Ad12-transformed cells than in BHK21 or in LSH hamster cells. It has been shown previously that the E1 region of Ad12 DNA is transcribed into mRNA in HA12/7 cells (Ortin et al. (1976) J. Virol. 20, 355-372). It remains to be investigated whether c-myc amplification and expression are related to the transformed phenotype of HA12/7 cells.

Chromatin structure and levels of expression and DNA methylation in the E3 region of chromosomally integrated adenovirus type 12 DNA

Integrated adenovirus type 12 (Ad12) genes in Ad12-transformed cell lines were investigated for chromatin structure, expression levels and states of DNA methylation. The E3 region in the Ad12-transformed cell line HA12/7 is hypermethylated and not expressed. The same region in the Ad12-transformed hamster cell lines T637 and A2497-3 is transcribed and undermethylated (Kruczek, I. and Doerfler, W. (1982) EMBO J. 1, 409-414). There was no significant difference in the DNase I sensitivity of the E3 region when nuclei of the aforementioned cell lines were incubated with this nuclease. In contrast, incubation of these nuclei with the restriction endonuclease PstI and subsequent cleavage of the DNA with BamHI generated an additional 0.9 kbp fragment in T637 and A2497-3 DNA which was not observed after treating HA12/7 nuclei and DNA in the same way. This finding was interpreted as indicative of differences in the chromatin structure of the E3 region depending on its state of transcriptional activity and its level of methylation. The E1 and major late promoter regions, which were transcriptionally active and inactive, respectively, in all three cell lines investigated, did not exhibit differences in sensitivity towards DNase I or PstI treatment of nuclei. More refined technology will be required to compare the chromatin structure of active versus inactive genes.

E1B functions of type C adenoviruses play a role in the complementation of blocked adenovirus type 12 DNA replication and late gene transcription in hamster cells

Adenovirus type 12 (Ad12) DNA cannot replicate in hamster cells and the late Ad12 genes cannot be expressed. It has been demonstrated previously that these defects can be at least partly overcome by coinfection of hamster cells with Ad12 and wild-type adenovirus type 2 (Ad2) or type 5 (Ad5) or by superinfection of Ad2- or Ad5-transformed cells with Ad12. These transformed cell lines carry in an integrated form and constitutively express the E1 region of Ad2 or Ad5. The compensation in Ad12 DNA replication and late gene transcription does not, however, lead to the assembly of intact Ad12 virions. In the present study, it has been demonstrated that the complementing functions in the Ad5 genome, which can effect Ad12 DNA replication and late transcription in hamster cells, reside predominantly but not exclusively in the E1B region. A supporting role in the E1A region is likely. These conclusions have been adduced from the results of double infection experiments using Ad12 and deletion mutants of Ad5. Inside the E1B region of Ad5 DNA, the complementing functions have not yet been precisely located. Although late Ad12 messenger RNAs are synthesized in Ad12 and Ad5-coinfected hamster cells, most of the late structural Ad12 proteins are not made or are made in minimal amounts, and consequently virions are not assembled. It is necessary to investigate whether hamster cells also exhibit a translational block vis à vis the expression of late Ad12-specific mRNAs. The data presented here also demonstrate that Ad12 functions can effectively complement E1A or to a lesser extent E1B deletions in the Ad5 genome in hamster cells. Upon coinfection with Ad12 and deletion mutants of Ad5 in either the E1A or the E1B region, Ad5 DNA and late proteins are synthesized, although Ad5 E1A or E1B functions cannot complement the deficient late Ad12 protein synthesis in hamster cells.

Adenovirus types 2 and 5 functions elicit replication and late expression of adenovirus type 12 DNA in hamster cells

Human adenovirus type 12 (Ad12) cannot replicate in hamster cells. There is a complete block of viral DNA replication and of the expression of late viral genes. Early viral functions are expressed. In contrast, hamster cells are permissive for human adenovirus type 2 (Ad2). Some of the Ad12-specific functions are insufficient to support viral replication in hamster cells, or else cellular functions are missing or inhibitory for Ad12 replication. It was shown that the block in the replication and late expression of the Ad12 genome in hamster cells could, at least in part, be complemented by Ad2 and adenovirus type 5 (Ad5) functions. When hamster cells were coinfected with Ad2 (or Ad5) and Ad12, both Ad2 (Ad5) and Ad12 DNA replicated. Ad2 (Ad5) virions were produced in double-infected hamster cells. The assembly of intact Ad12 virions was not detectable by the techniques used here. The analysis was further refined by Ad12 superinfecting Ad2- or Ad5-transformed cells which carried in an integrated form defined fragments of the Ad2 or Ad5 genome. Persistence and continued expression of the left terminus of the Ad2 or Ad5 DNA in these cells has been documented and helped to support replication and late expression of Ad12 DNA. It remains to be determined which of the E1 functions of Ad2 or Ad5 were responsible for the helper effect. Investigations on the biochemical mechanism of this complementation will entail studies on very complex viral and possibly cellular functions involved in the control of viral gene expression.

Structure and function of adenovirus DNA binding protein: comparison of the amino acid sequences of the Ad5 and Ad12 proteins derived from the nucleotide sequence of the corresponding genes

The adenoviral DNA binding protein (DBP) is a multifunctional protein involved in DNA replication and gene expression. In order to investigate the relation between structure and function of DBP, the amino acid sequences of the serotypes 5 and 12 (Ad5 and Ad12) have been compared. The amino acid sequence of Ad5 DBP was previously established by nucleotide sequence analysis of the Ad5 DBP gene (W. Kruijer, F. M. A. Van Schaik, and J. S. Sussenbach, Nucl. Acids Res. 9, 4439-4457, 1981). In this study the analysis of the Ad5 DBP gene and adjacent regions by determination of the sequence of the first leader in late DBP mRNA's and the splice point between the tripartite leader and the main body of the mRNA encoding the 100-kDa protein has been extended. The nucleotide sequence of the Ad12 DBP gene is also described. From the nucleotide sequence and RNA mapping data of Ad12 DBP mRNA's (I. Saito, J. Sato H. Handa, K. Shiraki, and H. Shimojo, Virology 114, 379-398, 1981) the complete Ad12 DBP amino acid sequence could be deduced. Ad12 DBP contains 484 amino acids and has an actual Mr of 54,992. It is 45 amino acids shorter than Ad5 DBP. Comparison of the Ad12 and Ad5 DBP amino acid sequences shows that several longer deletions are present in the N-terminal 125 amino acid residues of Ad12 DBP. In contrast, only a single amino acid deletion and insertion is found in the C-terminal 359 amino acids of Ad12 DBP. The N- and C-terminal domains of Ad12 and Ad5 DBP are 45 and 80% homologous, respectively. This suggests that both domains of DBP are subjected to different evolutionary pressures. Analysis of various Ad5 mutants with an altered DBP gene, has indicated that the C-terminal domain is involved in DNA replication and early gene expression, while the N-terminal domain has a role in late gene expression in monkey cells. These results are discussed in relation to the structure and function of adenovirus DBP.

Transformation of rat cells by cyt mutants of adenovirus type 12 and mutants of adenovirus type 5

Several mutants with much reduced oncogenicity (spontaneous mutants H12 cyt 52 and H12 cyt 70 and UV-induced mutants H12 cyt 61, H12 cyt 62, and H12 cyt 68) of the highly oncogenic adenovirus type 12 (Ad12) were studied for their ability to transform primary baby rat kidney cells. Four of the mutants showed much reduced capacity to transform cells in vitro, while H12 cyt 61 transformed cells as efficiently as the wild-type virus. Viral gene expression in several cell lines established from cultures infected by cyt mutants was studied, and it was found that viral sequences belonging to the left 16% of Ad12 were always transcribed. These results suggest that the function of the transformed state is not defective in the cyt mutants studied. Heterotypic complementation studies showed that the defect(s) in a cyt mutant can be corrected by an Ad7 function. Ad5 dl 313, with a deletion between 3.5 and 10.5 map units, transformed rat cells only at high multiplicity. These results suggest that the region E1B of adenoviruses may be required for efficient transformation of rat cells.

Can DNA methylation regulate gene expression?

The E2a region of the Ad2 genome encodes the Ad2-specific DBP. An inverse correlation between the level of DNA methylation at the 5'-CC*GG-3' sites of the E2a region and the extent of expression of DBP has been demonstrated in Ad2-transformed hamster cell lines (Vardimon et al. 1980). Four different leaders are used in the transcription of the E2a region in cells productively infected with Ad2. The leader located at coordinate 75 on the viral genome is used early after infection and the other three leaders are used late after infection (Chow et al. 1979). The analysis of the integration patterns of the viral DNA in the Ad2-transformed cell lines has revealed that the early leader is deleted in the cell lines which do not express the DBP (Vardimon and Doerfler 1981). The late leader located at coordinate 72 on the viral genome is present. The region encoding that late leader has been subcloned, and the cytoplasmic RNA from the cell line which expresses the DBP has been analyzed. It has been shown that the late leader is used in transformed cells. Hence the absence of the early leader cannot be the immediate reason for the lack of expression of the DBP. Correlations between DNA methylation and the absence of gene expression may indicate that methylation regulates gene expression or that methylation is the consequence of lacking gene expression. In order to decide between these alternatives an in vitro system has been employed. The HindIII A fragment of the Ad2 DNA which encodes the DBP has been methylated in vitro by the HpaII DNA methyltransferase. Methylated or unmethylated HindIII A fragment has been microinjected into the nuclei of Xenopus laevis oocytes. Unmethylated HindIII A fragment has been found to be expressed as specific viral RNA, whereas no viral RNA can be found in oocytes microinjected with methylated HindIII A fragment. The possibility of a nonspecific inhibitory factor in the methylated DNA preparation has been ruled out by the simultaneous microinjection of sea urchin histone gene DNA together with the methylated HindIII A fragment. Histone genes are expressed, while the expression of the methylated viral gene is blocked. By using the single-strand-specific endonuclease S1 we have shown that in Xenopus laevis oocytes initiation of transcription of the E2a region starts exactly at the same site as in Ad2 productively infected cells. These results provide direct evidence for the notion that DNA methylation at specific sites is involved in the regulation of gene expression.

In search of more complex genetic codes--can linguistics be a guide?

Striking similarities have been pointed out between the structures of the human language and the genetic code. The primary genetic code utilizes the principle of linear representation much like e.g. the Indo-European languages do. There are numerous indications that more complex secondary and tertiary structural elements in DNA direct highly specific interactions with proteins. Thus, more complex genetic codes might exist which might be superimposed on DNA sequences coding for polypeptides or might be extended to "non-coding" DNA sequences. Structural features of highly complex languages, like Chinese or Egyptian hieroglyphics using conceptual expression patterns have been compared to the more complex ways of encoding. It is proposed that the application of linguistic principles may be helpful in the computer analyses of known DNA sequences. There is considerable evidence for the innate specification at least for the basic structural elements of human languages. This innate specification may be the cause for language university. Based on the striking structural similarities between language and genetic code, the question is raised to what extent and in what way DNA sequences might be related to the innate specification of human languages.

Mapping of an adenovirus function involved in the inhibition of DNA degradation

A function involved in the inhibition of DNA degradation has been assigned through complementation tests to a product of region E1b of the adenovirus genome (between 4.5 and 10.5 map units). DNA degradation induced by the adenovirus type 12 (Ad12) cyt mutant H12cyt70 and the Ad5 early deletion mutant dl313 (with the deletion between 3.5 and 10.7 map units) was inhibited by coinfection with Ad5 region E1a (between 0 and 4.5 map units) mutants dl312 and hr1 and region E1b mutant hr6. The defect of inhibition of DNA degradation in Ad5 dl313 was also complemented in 293 cells. This DNase-inhibitory function does not appear to involve polypeptide IX or the 58,000-dalton polypeptide. Wild-type Ad12 induced DNA degradation in hamster embryo cells, suggesting that the DNase-inhibitory function is not expressed in these nonpermissive cells. Additional evidence suggests the involvement of a second viral product which positively influences the DNase activity and which appears to be an early function.

Viral gene products in adenovirus type-2 transformed hamster cells

I have analyzed viral gene products expressed in five adenovirus type 2 (Ad2)- cytoplasmic, viral RNA which was selected by hybridization to cloned restriction endonuclease fragments of Ad2 DNA. Proteins synthesized in vitro were analyzed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels and compared with those directed by RNAs prepared from productively infected cells. The early regions E1 and E4 of adenovirus type 2 (Ad2) were found to be expressed in all of five Ad2-transformed hamster embryo cells lines. RNA transcribed from early region E2, which codes for the 72,000-molecular-weight (72K) DNA-binding protein was detected in cell line HE1 only, and early region E3 was expressed exclusively in cell line HE4. RNA transcribed from the region between approximately 12 and 35 map units, coding for immediate early (13.5K, 52/53K) and immediate early proteins (13.6K, 16K, 17K, 87K), as well as RNA from late genes, was not found in any of the cell lines HE1 to HE5 had electrophoretic mobilities similar to those programmed by RNA from productively infected cells.

Early RNA of adenovirus type 3 in permissive and abortive infections

Early adenovirus type 3 cytoplasmic polyadenylated RNAs from HeLa and BHK-21 cells were detected and mapped on the viral genome by gel blotting and hybridization techniques. The sizes and locations of the 16 adenovirus type 3 RNAs were identical in the two cell types, although relative molarities of the various RNA species differed. Each of the early adenovirus type 3 RNAs was associated with polysomes in both cell types, suggesting that the abortive infection of hamster cells does not result from a defect in early adenovirus type 3 mRNA biosynthesis. No RNAs from regions transcribed late in infection of permissive cells were detected in BHK-21 cells.

Degradation of intracellular DNA in KB cells infected with cyt mutants of human adenovirus type 12

A group of mutants (cyt mutants) with much reduced oncogenicity was isolated from the highly oncogenic human adenovirus type 12 (Takemori et al., Virology 36: 575-586, 1968). These mutants induce extensive cellular destruction during lytic infection of human cells and produce low yields of virions. We report here that human KB cells infected with cyt mutants synthesized a reduced amount of viral DNA as compared with cells infected with the parental virus. Furthermore, the newly synthesized viral and cellular DNAs were extensively degraded in mutant-infected cells. Viral DNA was first synthesized as complete genome size, and most of it was degraded to subgenomic size within 6 h after synthesis. This virus-induced DNA degradation function, as well as the low yield of virions, was prevented by co-infection with the parental virus.

Expression of viral DNA in adenovirus type 12-transformed cells, in tumor cells, and in revertants

The expression as cytoplasmic RNA of integrated human adenovirus type 12 (Ad12) DNA in transformed and tumor cell lines and in revertants was investigated. The transformed and tumor cells contained multiple copies of the viral genome, 3 to 22 copies per cell in different cell lines. The integrated Ad12 DNA molecules persisted intact or nearly intact and in most cases colinear with the virion DNA. In the revertant cell lines, which were derived from cell line T637 (22 copies of Ad12 DNA per cell), all of the Ad12 DNA molecules were lost (line F10) or only one copy and a fraction of a second copy persisted (line TR12). The size classes and map locations of Ad12-specific cytoplasmic RNAs in three Ad12-transformed hamster cell lines (T637, HA12/7, and A2497-3), in two revertant lines (F10 and TR12), in one Ad12-induced hamster (CLAC3), and in one rat brain tumor line (RBT12/3) were determined. Cytoplasmic RNA from uninfected B3 hamster cells and from human KB cells productively infected with Ad12 served as controls. In the latter control experiments, the RNA was isolated early or late postinfection. With respect to the amounts of Ad12-specific RNAs detected in cytoplasmic RNA from various Ad12-transformed or Ad12-induced tumor cell lines, we could not establish any correlations to the number of Ad12 genome copies integrated into the cellular DNAs. Thus, the expression of the integrated viral genomes in these lines was regulated by mechanisms more complicated than simple gene dosage effects. Using cloned fragments of Ad12 DNA as hybridization probes, we analyzed the cytoplasmic RNAs from the cell lines mentioned by electrophoresis on agarose gels, blotting, and DNA-RNA hybridization. For each transformed and tumor cell line, except for the revertants, several size classes of Ad12-specific cytoplasmic RNA were detected for the early E1, E2, and E4 regions of Ad12 DNA. Some of these size classes were similar but not identical to those observed in cytoplasmic RNA isolated early from human KB cells productively infected with Ad12. Only cell lines A2497-3, T637, and RBT12/3 contained several size classes of cytoplasmic RNA homologous to the E3 region of Ad12 DNA. Weak homologies to the E1 region of Ad12 DNA were also detected in the revertant lines F10 and TR12. Late regions of Ad12 DNA were expressed as cytoplasmic RNA in cell lines CLAC3 and RBT12/3. Weak homologies were detected between certain segments of the Ad12 genome (the EcoRI-B, -C, and -D fragments) and the cytoplasmic RNA from uninfected hamster cells. These homologies had no apparent counterpart at the level of DNA, perhaps because these homologies could be detected only due to an overrepresentation of RNA sequences. In preliminary experiments, we failed to detect the expression as cytoplasmic RNA of the so-called virus-associated RNA in transformed and tumor cell lines. Virus-associated RNA represents a population of low-molecular-weight RNAs that map at around 30 fractional length units on the viral genome.

Complementation of adenovirus type 5 host range mutants by adenovirus type 12 in coinfected HeLa and BHK-21 cells

We have studied the ability of adenovirus type 12 (Ad12) to complement the Ad5 transformation-defective host rang (hr) mutants during infection of human cells (HeLa) or hamster cells (BHK-21). The group I mutant hr3 (mapped within 1.3 to 3.7 map units), which is incapable of synthesizing viral DNA, was complemented for both DNA synthesis and infectious virus production in nonpermissive HeLa cells during coinfection with Ad12. Similarly, the group II mutant hr6 (6.1 to 9.4 map units), which does synthesize DNA, was also shown to be complemented for virus production. When the host cells were BHK-21, an established hamster cell line that is permissive for Ad5 but nonpermissive for Ad12 DNA synthesis and virus production, coinfection with Ad5 and Ad12 did not overcome the block to Ad12 DNA synthesis. Coinfection of BHK-21 cells with Ad12 and either hr3 or hr6 leads to the complementation of only the group I mutant (hr3). The inability of Ad12 to complement hr6 in BHK-21 cells may be due to the failure of Ad12 to express an early gene product from the region corresponding to early region 1B (4.5 to 11 map units) Ad5 where hr6 and the other group II mutations are located.

Mapping of adenovirus 12 mRNA's transcribed from the transforming region

Adenovirus 12 mRNA's transcribed from the transforming region were analyzed and mapped on viral DNA by the nuclease S1 gel and diazobenzyloxymethyl paper blot techniques in cells transformed of adenovirus 12 DNA and in cells early and late after lytic infection with adenovirus 12. Two initiation sites of mRNA transcription and two kinds of splicing were found in each of early regions 1A and 1B. For early region 1A mRNA's, four species were found in lytically infected cells. Three of them were commonly found in cells transformed by either HindIII-G or EcoRI-C. Cells transformed by HindIII-G contained two additional 1A transcripts, which could be the 3' portions of chimeric mRNA's of cellular-viral or viral-viral sequences. Transcription in the 1B region diverged among the above cell lines. Early after lytic infection, no appreciable amount of 1B mRNA was detected, whereas two species of mRNA's, one corresponding to protein IX mRNA and another having splicing, were found at the late stage. In cells transformed by EcoRI-C, a distinct mRNA species with splicing was observed. Cells transformed by HindIII-G contained a transcript from the leftmost part of the 1B sequence at the 5' portion of chimeric mRNA species, suggesting the presence of tandem integration of viral DNA in the cells. Other mRNA species in the 1A and 1B regions were also detected in both transformed cell lines. The results are discussed in relation to the nucleotide sequence of the HindIII-G fragment of adenovirus 12 DNA.

Integration sites of adenovirus type 12 DNA in transformed hamster cells and hamster tumor cells

The patterns and sites of integration of adenovirus type 12 (Ad12) DNA were determined in three lines of Ad12-transformed hamster cells and in two lines of Ad12-induced hamster tumor cells. The results of a detailed analysis can be summarized as follows. (i) All cell lines investigated contained multiple copies (3 to 22 genome equivalents per cell in different lines) of the entire Ad12 genome. In addition, fragments of Ad12 DNA also persisted separately in non-stoichiometric amounts. (ii) All Ad12 DNA copies were integrated into cellular DNA. Free viral DNA molecules did not occur. The terminal regions of Ad12 DNA were linked to cellular DNA. The internal parts of the integrated viral genomes, and perhaps the entire viral genome, remained colinear with virion DNA. (iii) Except for line HA12/7, there were fewer sites of integration than Ad12 DNA molecules persisting. This finding suggested either that viral DNA was integrated at identical sites in repetitive DNA or, more likely, that one or a few viral DNA molecules were amplified upon integration together with the adjacent cellular DNA sequences, leading to a serial arrangement of viral DNA molecules separated by cellular DNA sequences. Likewise, in the Ad12-induced hamster tumor lines (CLAC1 and CLAC3), viral DNA was linked to repetitive cellular sequences. Serial arrangement of Ad12 DNA molecules in these lines was not likely. (iv) In general, true tandem integration with integrated viral DNA molecules directly abutting each other was not found. Instead, the data suggested that the integrated viral DNA molecules were separated by cellular or rearranged viral DNA sequences. (v) The results of hybridization experiments, in which a highly specific probe (143-base pair DNA fragment) derived from the termini of Ad12 DNA was used, were not consistent with models of integration involving true tandem integration of Ad12 DNA or covalent circularization of Ad12 DNA before insertion into the cellular genome. (vi) Evidence was presented that a small segment at the termini of the integrated Ad12 DNA in cell lines HA12/7, T637, and A2497-3 was repeated several times. The exact structures of these repeat units remained to be determined. The occurrence of these units might reflect the mechanism of amplification of viral and cellular sequences in transformed cell lines.

Revertants of adenovirus type 12-transformed hamster cell line T637 as tools in the analysis of integration patterns

Spontaneously arising morphological revertants of the adenovirus type 12 (Ad12)-transformed hamster cell line T637 had been previously isolated, and it had been demonstrated that in these revertants varying amounts of the integrated Ad12 genome were eliminated from the host genome. In this report, the patterns of persistence of the viral genome in the revertants were analyzed in detail. In some of the revertant cell lines, F10, TR3, and TR7, all copies of Ad12 DNA integrated in line T637 were lost. In lines TR1, -2, -4 to -6, -8 to -10, and -13 to -16, only the right-hand portion of one Ad12 genome was preserved; it consisted of the intact right segment of Ad12 DNA and was integrated at the same site as in line T637. In revertant lines G12, TR11, and TR12, one Ad12 DNA and varying parts of a second viral DNA molecule persisted in the host genome. These patterns of persistence of Ad12 DNA molecules in different revertants supported a model for a mode of integration of Ad12 DNA in T637 hamster cells in which multiple (20 to 22) copies of the entire Ad12 DNA were serially arranged, separated from each other by stretches of cellular DNA. The occurrence of such revertants demonstrated that foreign DNA sequences could not only be acquired but could also be lost from eucaryotic genomes. There was very little, if any, expression of Ad12-specific DNA sequences in the revertant lines TR7 and TR12. Moreover, Ad12 DNA sequences which were found to be undermethylated in line T637 were completely methylated in the revertant cell lines G12, TR11, TR12, and TR2. These findings were consistent with the absence of T antigen from the revertant lines reported earlier. Hence it was conceivable that the expression of integrated viral DNA sequences was somehow dependent on their positions in the cellular genome. In cell line TR637, the early segments of Ad12 DNA were expressed and undermethylated; conversely, in the revertant lines G12, TR11, TR12, and TR2, the same segments appeared to be expressed to a limited extent and were strongly methylated.

Comparative sequence analysis of the inverted terminal repetitions from different adenoviruses

The comparative nucleotide sequences of the region of inverted terminal repetition from a representative member of group C (nononcogenic), group B (weakly oncogenic), and group A (highly oncogenic) adenoviruses are analyzed. Our data show that (i) the length of this unique region increases with the oncogenicity of the serotype, (ii) a unique homologous region--14 nucleotides long--is present exactly at the same distance from the terminus, and (iii) a hexanucleotide sequence, T-G-A-C-G-T, is present at the site where the terminal repetition diverges.

DNA methylation and viral gene expression in adenovirus-transformed and -infected cells

The level of DNA methylation in adenovirus type 2 (Ad2) and type 12 (Ad12) DNA was determined by comparing the cleavage patterns generated by the isoschizomeric restriction enzymes HpaII and MspI. As previously reported virion DNA of Ad2 and Ad12 is not methylated. Parental or newly synthesized Ad2 DNA in productively infected human KB or HEK cells is not methylated either, nor is the integrated form of Ad2 DNA in productively infected cells. Hamster cells and Muntiacus muntjak cells are abortively infected by Ad12. We have not detected methylation of Ad12 DNA in hamster or Muntiacus muntjak cells. An inverse correlation between the level of methylation and the extent of expression of viral DNA in Ad12-transformed hamster cells has been described earlier. A similar relation has been found for the EcoRI fragment B of Ad2 DNA which is not methylated but is expressed as the Ad2 DNA-binding (72K) protein in the Ad2-transformed hamster line HE1. Conversely, the same segment is completely methylated in lines HE2 and HE3, and there is apparently no evidence for the expression of the 72K protein in these cell lines.