Patterns of DNA methylation in selected human genes in different Hodgkin's lymphoma and leukemia cell lines and in normal human lymphocytes.

The human genome, like many other genomes, harbors highly specific patterns of DNA methylation which have not yet been systematically studied. In a limited investigation on the genes for tumor necrosis factors-alpha and -beta, a surprising interindividual concordance in the patterns of DNA methylation at the nucleotide level has been demonstrated earlier by using the genomic sequencing method on DNA from individuals of very different ethnic origins. Patterns of DNA methylation could perhaps serve as indicators for genetic activities. These activities would not have to be restricted to gene transcription but could relate to other genetic activities in the cell. DNA methylation patterns are known to be cell type-specific. We have now initiated a study of these DNA patterns in human lymphocytes and in human cell lines of different malignant origins. Several of the proto-oncogenes, parts of the genes for tumor necrosis factor-alpha and -beta, the insulin receptor and lamin C have been used as hybridization probes. We have relied to some extent on the documented observation that the methylation patterns at 5'-CCGG-3' (HpaII/MspI) sequences yield a reflection of patterns at all 5'-CG-3' sequences. Three main types of patterns have been observed. Some of the probed segments are completely unmethylated; others are fully methylated, most of the areas are partly methylated exhibiting complex patterns at the 5'-CCGG-3' sites. In different tumor cell lines, different DNA methylation patterns are apparent for the same DNA probes. Comparisons of the methylation patterns in a given DNA segment between DNA from primary normal human lymphocytes and DNA from different tumor cell lines reveal changes in these patterns in several instances.

Eukaryotic DNA methylation: facts and problems.

Patterns of DNA methylation in complex genomes like those of mammalian cells have been viewed as indicators of different levels of genetic activities. It is as yet unknown how these complicated patterns are generated and maintained during cell replication. There is evidence from many different biological systems that the sequence-specific methylation of promoters in higher eukaryotes is one of the important factors in controlling gene activity at a long-term level. In general, the fifth nucleotide 5-methyldeoxycytidine can be considered as a modulator of protein-DNA interactions. The degree and direction of this modulation has to be assessed experimentally in each individual instance. The establishment of de novo patterns of DNA methylation is characterized by the gradual non-random spreading of DNA methylation by an essentially unknown mechanism. In this review, some of the general concepts of DNA methylation in mammalian systems are presented, and research currently performed in the authors' laboratory has been summarized.

DNA-DNA dot hybridization technique used as DNA determination method in the alkaline elution analysis of DNA damage.

A DNA-DNA ('Southern') dot hybridization technique was adapted for use as a quantitative DNA detection method during alkaline elution analysis of irradiated rat cell material. In comparison to standard microfluorometric methods, similar gamma-ray dose-response relationships were obtained with less than 1% of the cell material when the dot hybridization assay was used. When a highly repetitive, long interspersed DNA element of the rat genome is used as a hybridization probe, as few as 10(4) cells of rat tissue or rat cell culture cells per sample with approx. 50 ng of DNA were sufficient to detect single-strand breaks and protein cross-links in the DNA of rat hepatocytes and cells of the nasal epithelium after in vitro gamma-irradiation. Since highly repetitive DNA elements are available from nearly all higher eukaryotes, this alternative approach of detecting DNA in alkaline elution analysis is generally proposed for tissues which yield only low amounts of cell material and/or which are difficult to label by radioactive DNA precursors.

Promoter inactivation or inhibition by sequence-specific methylation and mechanisms of reactivation.

In studies on adenovirus promoters, predominantly on the late E2A promoter of adenovirus type 2 (Ad2), we have demonstrated by a number of experimental approaches that the sequence-specific methylation of three 5'-CCGG-3' sequences inactivates this promoter. Recently, we have developed a cell-free transcription system in which the methylation-inactivation of eukaryotic promoters can be studied in detail. It has also been shown that methylation-caused promoter inactivation can be reversed by the 289 amino acid E1A protein of Ad2 or of adenovirus type 5. In the presence of this protein with a transactivating effect, transcription is initiated at the authentic cap site of the methylated late E2A promoter. A similar reactivation of the methylated late E2A promoter can also be effected by a cis-acting genetic element, i.e., the strong enhancer of human cytomegalovirus. Further studies will be directed toward the biochemical mechanisms of promoter silencing by sequence-specific methylations.

Reactivation of the methylation-inhibited late E2A promoter of adenovirus type 2 by a strong enhancer of human cytomegalovirus.

Promoter inactivation by sequence-specific methylation was demonstrated by using a construct which contained the late E2A promoter of adenovirus type 2 (Ad2) DNA and the prokaryotic gene for chloramphenicol acetyltransferase (CAT) as indicator. After the in vitro methylation of 5'-CCGG-3' sequences at positions -215, +6, and +24 relative to the cap site of the promoter, the construct was inactive upon transfection into mammalian cells. The same pAd2E2AL-CAT construct was active in the unmethylated form. Promoter inactivation could be overcome when the strong immediate early enhancer of human cytomegalovirus DNA, which lacked 5'-CCGG-3' sites, was inserted into the construct either in a position immediately antecedent to the promoter or in a location several thousand nucleotides remote from it. Reactivation of the 5'-CCGG-3' methylated pAd2E2AL-CAT construct entailed initiation of transcription at the authentic cap site of the late E2A promoter and maintenance of methylation at least during the duration of the transient expression experiment. Reactivation of the methylated late E2A promoter had also been demonstrated by the trans-activating 289 amino acid protein which was encoded in the E1A region of adenoviruses (B. Weisshaar et al., 1988, J. Mol. Biol. 202, 255-270). Thus there are several ways in which a methylated and silenced promoter can be reactivated in mammalian cells.

Characterization of a member of the highly repeated long interspersed rat DNA family with long open reading frames.

A highly repetitive long interspersed sequence from rat DNA has been isolated and partly characterized. This sequence comprises at least a 1300 base-pair and a 2400 base-pair EcoRI fragment and probably additional elements. The 2400 base-pair segment has been analyzed in detail. It appears to be part of the chromosomal DNA in rat cells. The 2400 base-pair repeat is likely to be distributed over several regions in the rat genome. The 2400 base-pair segment has been cloned, mapped for restriction sites, and part of its nucleotide sequence has been determined. The 2400 base-pair sequence is a member of a typical highly repetitive long interspersed sequence with high copy number and restriction site polymorphism. There are sequence homologies to mouse and human DNA. A striking homology has been detected to the flanking sequences of a repetitive mouse DNA sequence that has been described to be located adjacent to one of the kappa-immunoglobulin variable genes. Elements in the 2400 base-pair rat repeat are transcribed in cells from most rat organs and from several continuous rat cell lines. This RNA from rat cell lines was found polyadenylated or not polyadenylated. The nucleotide sequence of parts of the 2400 base-pair DNA segment revealed open reading frames for polypeptide sequences. Such open reading frames have been detected in two different segments of the 2400 base-pair DNA repeat. Open reading frames exist in the two complementary strands in the same DNA segment. The hypothetical polypeptide whose sequence has been determined in toto has a length of 190 amino acid residues and is enriched in hydrophobic amino acids, reminiscent of the amino acid composition in membrane proteins. Hence, it is conceivable that the 2400 base-pair repeat sequence from rat DNA, at least in part, encodes messenger RNAs that might be translated into functional proteins.

Virus-specific proteins in adenovirus type 12-transformed and tumour cells as detected by immunoprecipitation.

Adenovirus type 12 (Ad12)-specific proteins were determined in nine well-characeterized Ad12-transformed hamster cell lines and in Ad12-induced hamster and rat tumour lines by immunoprecipitation, gel electrophoresis and autoradiography. All cell lines expressed a 60K mol. wt. polypeptide. In several cell lines, the presence of a 58K mol. wt. protein could also be demonstrated by these techniques. Smaller Ad12-specific proteins could be detected only in the Ad12-transformed hamster cell lines HA12/7 and A2497-3, and in the Ad12-induced hamster tumour line CLAC3. The quality of the immunoprecipitation tests performed depended primarily on the sera used; their antibody titres varied widely. For at least one of the Ad12-transformed hamster cell lines (HA12/7), there was good agreement in the number and mol. wt. of Ad12-specific proteins detected by both immunoprecipitation and in vitro translation of hybrid-selected cytoplasmic RNA. There was no clear-cut correlation between the number and the nature of Ad12-specific proteins and the way in which the cell lines or tumours were obtained. Cell lines with the least number of copies of Ad12 DNA persisting appeared to express the largest number of Ad12-specific proteins.

Tumor induction by human adenovirus type 12 in hamsters: loss of the viral genome from adenovirus type 12-induced tumor cells is compatible with tumor formation.

The patterns of integration of adenovirus type 12 (Ad12) DNA in 39 virus-induced hamster tumors were determined. Both the amount of Ad12 DNA persisting and the apparent sites of insertion differed from tumor to tumor. In 30 tumors, the intact Ad12 genome persisted in colinear arrangement and in multiple copies. In nine tumors, only the left- or the left- and right-hand parts of the Ad12 genome persisted in the tumor cells. In three other cell lines the Ad12 genomes were lost completely during continuous passage in culture. A shift from epithelioid to fibroblastic morphology correlated with loss of Adl2 genomes. The cell line H1111(1) derived from an Ad12-induced tumor had lost all viral DNA by the thirteenth subpassage, but was still oncogenic when reinjected into animals. This finding raises the question, to what extent persistence of the Ad12 genome is essential for the oncogenic phenotype. Tumor cells could be detected histologically inside local lymphatic vessels. In those experiments in which Ad12 preparations were used which contained sizeable proportions of the symmetric recombinant between Ad12 and KB cellular DNA (Deuring et al., 1981), tumors were observed in the nuchal region of the animals.