Adenovirus type 12 DNA firmly associates with mammalian chromosomes early after virus infection or after DNA transfer by the addition of DNA to the cell culture medium

Evidence for Tethering of Human Cytomegalovirus Genomes to Host Chromosomes

Tethering of viral genomes to host chromosomes has been recognized in a variety of DNA and RNA viruses. It can occur during both the productive cycle and latent infection and may impact viral genomes in manifold ways including their protection, localization, transcription, replication, integration, and segregation. Tethering is typically accomplished by dedicated viral proteins that simultaneously associate with both the viral genome and cellular chromatin via nucleic acid, histone and/or non-histone protein interactions. Some of the most prominent tethering proteins have been identified in DNA viruses establishing sustained latent infections, including members of the papillomaviruses and herpesviruses. Herpesvirus particles have linear genomes that circularize in infected cell nuclei and usually persist as extrachromosomal episomes. In several γ-herpesviruses, tethering facilitates the nuclear retention and faithful segregation of viral episomes during cell division, thus contributing to persistence of these viruses in the absence of infectious particle production. However, it has not been studied whether the genomes of human Cytomegalovirus (hCMV), the prototypical β-herpesvirus, are tethered to host chromosomes. Here we provide evidence by fluorescence in situ hybridization that hCMV genomes associate with the surface of human mitotic chromosomes following infection of both non-permissive myeloid and permissive fibroblast cells. This chromosome association occurs at lower frequency in the absence of the immediate-early 1 (IE1) proteins, which bind to histones and have been implicated in the maintenance of hCMV episomes. Our findings point to a mechanism of hCMV genome maintenance through mitosis and suggest a supporting but non-essential role of IE1 in this process.

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.

Impact of foreign DNA integration on tumor biology and on evolution via epigenetic alterations

The insertion of foreign DNA into mammalian genomes can alter their methylation and transcription patterns at remote sites from the locus of foreign DNA integration. The mechanisms leading to these fundamental changes and their frequencies are unknown. Sites and extent of changes in the recipient cells might depend on the location of foreign DNA integration. In the second part of this review, it will be hypothesized that the insertion event itself, for example, of tumor viral DNA via its epigenetic genome-wide consequences, plays an important role in oncogenesis. During evolution, the impact of ancient retrotransposon or retroviral genomes and the ensuing epigenetic alterations in the recipient genomes might have generated cells with completely different transcriptional profiles. Due to the continued presence of the transgenomes these alterations were genetically stable and were selected for or against by the environmental conditions prevalent at the time. These evolutionary effects are very different from those postulated for insertional mutagenesis, added genetic information or regulatory elements placed into the vicinity of cellular functions.

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.

Human CAR gene expression in nonpermissive hamster cells boosts entry of type 12 adenovirions and nuclear import of viral DNA

Adenovirus type 12 (Ad12) propagation in hamster BHK21 cells is blocked prior to viral DNA replication. The amounts of Ad12 DNA in the nuclei or cytoplasm of hamster cells are about 2 orders of magnitude (2 h postinfection [p.i.]) and 4 to 5 orders of magnitude (48 h p.i.) lower than in permissive human cells. Cell line BHK21-hCAR is transgenic for and expresses the human coxsackie- and adenovirus receptor (hCAR) gene. Nuclear uptake of Ad12 DNA in BHK21-hCAR cells is markedly increased compared to that in naïve BHK21 cells. Ad12 elicits a cytopathic effect in BHK21-hCAR cells but not in BHK21 cells. Quantitative PCR or [(3)H]thymidine labeling followed by zone velocity sedimentation fails to detect Ad12 DNA replication in BHK21 or BHK21-hCAR cells. Newly assembled Ad12 virions cannot be detected. Thus, the block in Ad12 DNA replication in hamster cells is not released by enhanced nuclear import of Ad12 DNA.

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.

A hexanucleotide selected for increased cellular uptake in cis contains a highly active CpG-motif in human B cells and primary peripheral blood mononuclear cells

The relationship between immunostimulation of human B cells by cytosine-phosphate-guanosine (CpG) -containing oligonucleotides and their physical cellular uptake is of mechanistic interest and a prerequisite for rational improvements of the therapeutic potential of CpG-harbouring oligonucleotides. Here, a combinatorial approach was used to identify nucleotide sequence motifs that facilitate increased cellular uptake in mammalian cells. Oligonucleotides harbouring the selected hexanucleotide TCGTGT in cis show increased cellular uptake. This motif contains a CpG dinucleotide within a sequence context that shows a very strong CpG-specific stimulatory activity on human B cells. Here we describe the influence of concentration, length and sequence position of the unmethylated CpG dinucleotide on immunostimulation. A comparison between phosphorothioate-derivatives and unmodified TCGTGT-containing oligonucleotides strongly indicates a great CpG-specificity for the unmodified CpG-harbouring oligonucleotides but not for the phosphorothioate versions. This work describes a link between the physical cellular uptake of naked oligonucleotides harbouring the selected cellular uptake motif TCGTGT, its strong CpG-specific stimulation of human B cells and its relationship with the sequence context of CpG and its cellular uptake.

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?

RNAs are packaged into human cytomegalovirus virions in proportion to their intracellular concentration

The assembly of human cytomegalovirus (HCMV) virions is a complex process and involves the incorporation of viral transcripts. These RNAs are delivered to the newly infected cells and have the potential to be translated in the absence of HCMV gene expression. We have quantified the relative amount of RNAs in HCMV virions and infected cells with real-time reverse transcription-PCR and observed that viral and cellular RNAs are packaged in proportion to the amount of RNA within the cell at the time of assembly. To determine whether cis elements influenced RNA packaging, we constructed a recombinant HCMV mutant virus that expressed the yellow fluorescence protein (YFP) gene fused to the virion RNA UL21.5. We also constructed a mutant virus in which the UL21.5 transcription unit was replaced with the YFP gene. YFP RNA was incorporated into both viruses, indicating that RNA is incorporated in the absence of a virus-specific signal motif. Furthermore, with in situ hybridization, packaged transcripts were observed throughout the cytoplasm of the infected cells, including the site of virus assembly. Several proteins that nonspecifically interact with RNA, including the tegument protein pp28, were found within HCMV virions. These studies demonstrate that both viral and cellular RNAs are nonspecifically incorporated into HCMV, potentially through interactions with several virion proteins.

The abortive infection of Syrian hamster cells with human adenovirus type 12

Human adenovirus type 12 (Ad12) induces undifferentiated tumors in newborn Syrian hamsters, and this tumor model has been investigated in detail in our laboratory. One of the characteristics of the Ad12-hamster cell system is a strictly abortive infection cycle. In this chapter, we summarize previous and more recent results of studies on the interaction of Ad12 with the nonpermissive BHK21 hamster cell line. The block of Ad12 replication lies before viral DNA replication and late gene transcription which cannot be detected with the most sensitive techniques. Ad12 adsorption, cellular uptake and transport of the viral DNA to the nucleus are less efficient in the nonpermissive hamster cells than in permissive human cells. However, most of the early functions of the Ad12 genome are expressed in BHK21 cells, though at a low level. In the downstream region, the first exon, of the major late promoter (MLP) of Ad12 DNA, a mitigator element of 33 nucleotide pairs in length has been identified which contributes to the inactivity of the MLP in hamster cells and its markedly decreased activity in human cells. The E1 functions of Ad2 or Ad5 are capable of partly complementing the Ad12 deficiencies in hamster cells in that Ad12 viral DNA replication and late gene transcription can proceed, e.g. in a BHK hamster cell line, BHK297-C131,which carries in an integrated form and constitutively expresses the E1 region of Ad5 DNA. Nevertheless, the late Ad12 mRNAs, which are synthesized in this system with the authentic nucleotide sequence, fail to be translated to structural viral proteins. Hence, infectious virions are not produced in the partly complementing system. Probably there is also a translational block for late Ad12 mRNAs in hamster cells. We have recently shown that the overexpression of the Ad12 preterminal protein (pTP) gene or of the E1A gene facilitates the synthesis of full-length, authentic Ad12 DNA in BHK21 cells infected with Ad12. Apparently the pTP has a hitherto unknown function in eliciting full cycles of Ad12 DNA replication even in nonpermissive BHK21 cells when sufficient levels of Ad12 pTP are produced. We pursue the possibility that the completely abortive infection cycle of Ad12 in hamster cells ensures the survival of Ad12-induced hamster tumor cells which all carry, integrated in their genomes, multiple copies of Ad12 DNA. In this way, the viral genomes are immortalized and expanded in a huge number of tumor cells.

Integrative recombination between adenovirus type 12 DNA and mammalian DNA in a cell-free system: joining by short sequence homologies

A cell-free system was developed to investigate the mechanism of how junctions are formed between viral and cellular DNAs during adenoviral DNA integration into the hamster cell genome. Recombination between the segment of adenovirus type 12 (Ad12) DNA, that comprises sequence coordinates 20885-24053, subsequently termed PstI-D fragment and the hamster preinsertion DNA sequence p7 was studied in a cell-free system. The p7 DNA segment had served as viral DNA integration site in the Ad12-induced tumor CLAC1. Nuclear extracts initially from uninfected BHK21 hamster cells were fractionated by a series of chromatographic steps. DNAs of the in vitro generated recombinants were analyzed in detail. In the course of the recombination reaction, the two linear molecules were joined. The reaction took place between two short homologous sequences one of which was always at or very close to a DNA terminus, the second one could be several kilobase pairs remote from a DNA terminus. Apparently, the nucleotide sequence at the terminus of one recombining molecule determined the point of junction by searching for short homologies in the partner molecule. The recombination reaction was not conservative, the sequences in-between the short sequence homologies and one of the short sequence homologies were deleted in the in vitro recombinants. Two main criteria influenced the choice of interacting short sequence homologies: perfect homologies of 8-9 bp were most frequently found, they were preferred over more extended, but less perfect homologies. Comparing different short sequence homologies with similar stabilities, those combinations seemed to be chosen in the reaction which led to a minimal loss of nucleotides in the recombinants. The in vitro activity was found in nuclear extracts from both hamster and human cells. The activity was, hence, available for Ad12 DNA in productively infected human and abortively infected hamster cells. The specific recombination activity was increased in nuclear extracts of hamster cells abortively infected with Ad12. The junction sites in the recombinants, which were generated by the cell-free system, were very similar to junctions between adenoviral and cellular DNAs cloned from Ad12-induced tumor cells and Ad12-transformed cell lines.

Cellular and early viral factors in the interaction of adenovirus type 12 with hamster cells: the abortive response

The interaction of human adenovirus type 12 (Ad12) with Syrian hamster cells is remarkable in that there is a block of viral DNA replication and late gene transcription. We have screened several cellular factors known to play a role in adenovirus replication for their possible contributions to the interactions of Ad12 in the abortive BHK21 hamster cell system. (1) Western blot analyses of total protein extracts from Ad12- or Ad2-infected BHK21 cells do not reveal a significant difference in the accumulation of NFIII protein at different times after infection. Transcriptional levels of the NFIII gene in BHK21 cells are not altered upon the abortive infection with Ad12 or the productive infection with Ad2. The amount of NFIII protein is markedly reduced in nuclear extracts from BHK21 cells as compared with extracts from C131 hamster cells or human HeLa cells. A presumptive defect in NFIII transport to the nuclei rather than overall reduced NFIII gene transcription might explain the low abundance of NFIII in the nuclei of uninfected or Ad12-infected BHK21 cells. The productive infection of BHK21 or C131 cells with Ad2 leads to an increase in the NFIII concentration in the nuclei of infected cells, late after infection to a decrease; (2) NFI levels in the nuclei of mock-infected or Ad2- or Ad12-infected BHK21 cells are comparable with those in HeLa or in C131 cells. Thus, deficiencies in NFI may not play a role in the abortive system; (3) The absence of morphological alterations in PML protein domains from globular to track-like structures in the nuclei of Ad12-infected hamster cells correlates with the inability of Ad12 DNA to replicate in BHK21 cells. In BHK21 cells, the E4-ORF3 of Ad12 DNA is only weakly transcribed and only small amounts of the gene product are synthesized. In Ad12-infected C131 cells, which allow the replication of Ad12 DNA, the E4-ORF3 of Ad12 DNA is expressed, and track-like PML protein structures are observed. Transfection of the 12-E4-ORF3-EGFP construct leads to the expression of both the green fluorescent protein (GFP) and of the 12-E4-ORF3 gene product in 20-30% of the transfected BHK21 cells and elicits the morphological reorganization of the PML protein structures in the successfully transfected BHK21 cells. Similar results are obtained upon transfection of the 2-E4-ORF3 construct. Untransfected cells or cells transfected with the empty pIRES2-pEGFP vector carry the globular PML protein phenotype; (4) The expression of the 12-E4-ORF3-EGFP and/or of the NFIII-EGFP constructs upon transfection following Ad12-infection of BHK21 cells fails to promote Ad12 DNA replication. Hence, the formation of track-like PML protein structures in BHK21 cells by itself is not a sufficient precondition for Ad12 DNA replication in this abortive system. The data demonstrate that the expression of NFI, NFIII, and/or the conversion of the PML domains do not suffice to elicit Ad12 DNA replication in the abortive hamster cell system.

Foreign DNA integration--perturbations of the genome--oncogenesis

We have been interested in the consequences of foreign DNA insertion into established mammalian genomes and have initially studied this problem in adenovirus type 12 (Ad12)-transformed cells or in Ad12-induced hamster tumors. Since integrates are frequently methylated de novo, it appears that they might be modified by an ancient defense mechanism against foreign DNA. In cells transgenic for the DNA of Ad12 or for the DNA of bacteriophage lambda, changes in cellular methylation and transcription patterns have been observed. Thus, the insertion of foreign DNA can have important functional consequences that are not limited to the site of foreign DNA insertion. These findings appear to be relevant also for tumor biology and for the interpretation of data derived from experiments with transgenic organisms. For most animals, the main portal of entry for foreign DNA is the gastrointestinal tract. Large amounts of foreign DNA are regularly ingested with the supply of nutrients. Starting in 1987/1988, we have been investigating the fate of orally administered foreign DNA in mice. Naked DNA of bacteriophage M13 and the cloned gene for the green fluorescent protein (GFP) of Aequorea victoria have been used as test molecules. Moreover, the plant-specific gene for the ribulose-1,5-bisphosphate carboxylase (rubisco) has been followed in mice after feeding soybean leaves. At least transiently, food-ingested DNA can be traced to different organs and, after transplacental transfer, to fetuses and newborns. There is no evidence for germ line transmission or for the expression of orally administered GFP DNA.

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.

Integrated viral genomes can be lost from adenovirus type 12-induced hamster tumor cells in a clone-specific, multistep process with retention of the oncogenic phenotype

In adenovirus type 12 (Ad12)-induced tumor cells, in Ad12-transformed cells and in continuously passaged cell lines from these sources, the viral DNA is integrated in multiple copies, usually at a single chromosomal location. In different tumors or cell lines, the sites of integration of Ad12 DNA are all different. Rare exceptions exist. In most instances, the integrated viral DNA resides very stably in the host cell genomes. However, upon continuous serial passage of such cell lines, the integrated viral DNA can be destabilized and lost. In two instances, i.e. in the Ad12-induced hamster tumor cell lines H1111(1) and CLAC1, we have investigated the loss of integrated viral DNA in detail. After extended serial passage, these two cell lines seemed to be devoid of Ad12 DNA sequences, as detectable by Southern blot hybridization, but continued to induce tumors after reinjection into hamsters. Cells from these two cell lines were now recloned three times, and DNAs from cultures derived from several individual clones were reinvestigated for the presence of several parts of the viral genome by the polymerase chain reaction (PCR). Some of the clones still carried parts of the Ad12 genome. However, several clones were isolated that proved free of all parts of the viral genome, except for minute segments from the right terminus of the Ad12 genome. Apparently, the loss of integrated viral DNA from these cell lines proceeded as a continuous, gradual, multistep process whose pattern could differ from cell clone to cell clone, once destabilization had been initiated. The mechanism of destabilization is not understood. Cell populations of 2 x 10(6) to 3 x 10(7), and as low as 10(2), cells from the clones, that contained only minimal remnants from the right viral DNA terminus, were reinjected into newborn or 13-20 day-old weanling Syrian hamsters (Mesocricetus auratus). Tumors developed within 5-17 days after injection. Tumor cell clones also grew in soft agar. The injection of primary hamster skin fibroblasts never elicited tumor formation. The tumor cells induced by this reinjection proved repeatedly free of Ad12 DNA both by Southern blot hybridization and by PCR, except for those cell and tumor clones that contained small segments of the right terminal E4 region of the Ad12 genome. The tumor cells, however, retained their oncogenic phenotype. The results raise questions about the cell clone-specific excision patterns of integrated foreign DNA from the recipient genome and the possibility of a hit-and-run mechanism of adenoviral oncogenesis.