Coupled demethylation of sites in a conserved sequence of Xenopus ribosomal DNA

An embryonic demethylation mechanism involving binding of transcription factors to replicating DNA

In vertebrates, transcriptionally active promoters are undermethylated. Since the transcription factor Sp1, and more recently NF-kappaB, have been implicated in the demethylation process, we examined the effect of transcription factors on demethylation by injecting in vitro methylated plasmid DNA into Xenopus fertilized eggs. We found that various transactivation domains, including a strong acidic activation domain from the viral protein VP16, can enhance demethylation of a promoter region when fused to a DNA binding domain which recognizes the promoter. Furthermore, demethylation occurs only after the midblastula transition, when the general transcription machinery of the host embryo becomes available. Nevertheless, transcription factor binding need not be followed by actual transcription, since demethylation is not blocked by alpha-amanitin treatment. Finally, replication of the target DNA is a prerequisite for efficient demethylation since only plasmids that carry the bovine papilloma virus sequences which support plasmid replication after the midblastula transition are demethylated. No demethylation is detectable in the oocyte system where DNA is not replicated. These results suggest that, in the Xenopus embryo, promoters for which transcription factors are available are demethylated by a replication-dependent, possibly passive mechanism.

The enhancers and promoters of the Xenopus laevis ribosomal spacer are associated with histones upon active transcription of the ribosomal genes

The presence of histones on the enhancer-promoter region of the X.laevis ribosomal spacer has been studied in embryos at stage 40, where the ribosomal genes are actively transcribed. Isolated tadpole nuclei were either fixed with formaldehyde or irradiated with UV laser to crosslink histones to DNA. The purified protein-DNA complexes were immunoprecipitated with antibodies to the histones H1, H2A and H4 and the DNA fragments carrying the respective histones were analyzed for the presence of spacer enhancer-promoter sequences by hybridization to specific DNA probe. The two independent crosslinking procedures revealed the presence of these DNA sequences in the precipitated DNA. The quantitative analysis of the UV laser-crosslinked complexes showed that histones H2A and H4 were associated with enhancer-promoter DNA in amounts similar to those found for bulk DNA, whilst the content of H1 was reduced.

Structure, evolution and properties of a novel repetitive DNA family in Caenorhabditis elegans

We have identified a moderately repeated DNA sequence in Caenorhabditis elegans present at least at twenty different locations in the genome. Elements of this intermingled repetitive DNA family are made up of tandem subreapeats whose smaller unit is ten base pairs long. The occurrence of single base changes between units is reminiscent of mammalian satellite DNA. Sequence analysis has shown that the consensus of these repeats is identical to the consensus of the heat-shock element (HSE) common to all eukaryotes (C--GAA--TTC--G). This consensus in our sequences is repeated in tandem with an overlap of four bases (C--GAA--TTC--GAA--TTC...). We studied in detail one cloned element of the family and we were unable to detect transcription in the flanking regions either under normal growth or after heat induction. Nevertheless a 242 bp sequences out of this same element was sufficient, when located on a multicopy plasmid in Saccharomyces cerevisiae, to drive transcription from a downstream gene under heat shock conditions.

Trans-activation of a methylated adenovirus promoter by a frog virus 3 protein

The high degree of methylation of the frog virus 3 (FV3) genome suggests that FV3-infected cells are capable of transcribing highly methylated DNA. We tested this hypothesis by assaying the transcriptional activity of adenovirus promoters known to be inhibited by methylation. Plasmid constructs containing the E1a and E2aE promoters of adenovirus type 12 linked to the gene for chloramphenicol acetyltransferase [(CAT) EC 2.3.1.28], when methylated and introduced into eukaryotic cells, promoted CAT synthesis only when the cells were subsequently infected with FV3. Mapping of transcriptional initiation sites revealed that the same sites in the E1a promoter were used for the initiation of transcription in uninfected and infected cells. Moreover, Southern blots showed that transfected plasmid DNA from FV3-infected cells was not demethylated. The absence of CAT-specific RNA in transfected cells infected with FV3 in the presence of protein synthesis inhibitors demonstrated that a virus-induced protein was responsible for the trans-activation. Inhibition of transcription from the methylated template by alpha-amanitin indicated that a functional host RNA polymerase II is required for transcription of methylated DNA in FV3-infected cells. The virus-induced trans-acting protein presumably alters either host RNA polymerase II or the methylated DNA template to allow transcription from the methylated adenovirus promoters.

The absence of a human-specific ribosomal DNA transcription factor leads to nucleolar dominance in mouse greater than human hybrid cells

The basis for nucleolar dominance in mouse-human cell hybrids which contained all of the mouse chromosomes but an incomplete set of human chromosomes (M greater than H) was examined at the molecular level. S1 mapping data showed that these cells had the expected levels of steady-state rRNA transcribed from mouse ribosomal gene (rDNA) transcription units but undetectable levels of rRNA derived from the human rDNA transcription templates that are also present. RNA polymerase I-dependent, cell-free transcription extracts were made from three hybrid lines and were found to be capable of transcribing cloned rDNA templates of mouse but not human origin. Partially purified human factors required for rDNA transcription in vitro were added to the M greater than H extracts. One fraction with almost no RNA polymerase I activity conferred on these hybrid cell extracts the ability to transcribe a human rDNA template. These rescue experiments suggested that this required human-specific rDNA transcription factor(s) was effectively absent from the lines we examined and could account for nucleolar dominance in M greater than H hybrid cells.

The absence of a human-specific ribosomal DNA transcription factor leads to nucleolar dominance in mouse greater than human hybrid cells

The basis for nucleolar dominance in mouse-human cell hybrids which contained all of the mouse chromosomes but an incomplete set of human chromosomes (M greater than H) was examined at the molecular level. S1 mapping data showed that these cells had the expected levels of steady-state rRNA transcribed from mouse ribosomal gene (rDNA) transcription units but undetectable levels of rRNA derived from the human rDNA transcription templates that are also present. RNA polymerase I-dependent, cell-free transcription extracts were made from three hybrid lines and were found to be capable of transcribing cloned rDNA templates of mouse but not human origin. Partially purified human factors required for rDNA transcription in vitro were added to the M greater than H extracts. One fraction with almost no RNA polymerase I activity conferred on these hybrid cell extracts the ability to transcribe a human rDNA template. These rescue experiments suggested that this required human-specific rDNA transcription factor(s) was effectively absent from the lines we examined and could account for nucleolar dominance in M greater than H hybrid cells.

DNA methylation of three 5' C-C-G-G 3' sites in the promoter and 5' region inactivate the E2a gene of adenovirus type 2

The E2a gene of human adenovirus type 2 (Ad2) encodes the 72-kilodalton DNA-binding protein. We previously described perfect inverse correlations between the methylation of all 5' C-C-G-G 3' sequences in the Ad2 E2a gene in virus-transformed hamster cells containing viral DNA sequences in an integrated state and the extent to which this gene is expressed. We subsequently showed that in vitro methylation of all 14 5' C-C-G-G 3' sequences in the cloned E2a gene by prokaryotic Hpa II DNA methyltransferase leads to transcriptional inactivation after microinjection into Xenopus laevis oocytes. The unmethylated cloned E2a gene is expressed in these cells. We report here the construction of partly methylated clones of the E2a gene. In the promoter (5')-methylated construct, three 5' C-C-G-G 3' sequences at the 5' end of the subclone were methylated. One of these sites is located 215 base pairs (bp) upstream (bp 26,169 of Ad2 DNA), and two sites are located 5 and 23 bp downstream from the cap site (bp 25,931 and 25,949 of Ad2 DNA) of the E2a gene. This construct was transcriptionally inactive upon microinjection into nuclei of X. laevis oocytes. In the gene (3')-methylated construct, 11 5' C-C-G-G 3' sequences in the main part of the transcribed gene region were methylated in vitro. This construct was transcribed in X. laevis oocytes, and at least some of the Ad2-specific RNA synthesized was initiated at the same sites as in Ad2-infected human KB cells. Both mock-methylated constructs were transcribed into Ad2-specific RNA in X. laevis oocytes. These results demonstrate that DNA methylations at or close to the promoter and 5' end of the E2a gene cause transcriptional inactivation. Perhaps only one methyl group would be adequate for inactivation; in vivo methylation of more than one cytosine may be a form of safeguard or redundancy.

In vitro methylation of HpaII sites in Xenopus laevis rDNA does not affect its transcription in oocytes

The effect of methylation of X. laevis rDNA on its transcription was tested by methylating all of the HpaII sites in a series of rDNA plasmids and injecting the methylated rDNA into X. borealis oocytes. Analysis of RNA transcribed from the injected plasmids showed that methylation of rDNA in vitro does not affect transcription of X. laevis ribosomal genes. This result suggests that despite the observed correlation between demethylation of rDNA and synthesis of ribosomal RNA in X. laevis embryos (1), methylation of rDNA does not regulate transcription of the gene.

5-Methyldeoxycytidine in the Physarum minichromosome containing the ribosomal RNA genes

5-Methyldeoxycytidine (5MC) was analyzed by high pressure liquid chromatography (HPLC) and by restriction enzyme digestion in rDNA isolated from Physarum polycephalum. rDNA from Physarum M3C strain microplasmodia has a significant 5MC content (about half that of the whole genomic DNA). This rDNA contains many C5MCGG sites because it is clearly digested further by Msp I than by Hpa II. However, most 5MC is in other sites. In particular, alternating CG sequences appear to be highly methylated. HPLC of deoxyribonucleosides shows tha most of the transcribed regions contain little or no 5MC. Restriction digestion indicates that there is little or no 5MC in any of the transcribed regions including the transcription origin and adjacent sequences. Over 90% of the total 5MC is in or near the central nontranscribed spacer and most methylated restriction sites are in inverted repeats of this spacer. rDNA is very heterogeneous with respect to 5MC. The 5MC pattern doesn't appear to change with inactivation of the rRNA genes during reversible differentiation from microplasmodia (growing) to microsclerotia (dormant), showing that inactivation is due to changes in other chromatin variables. The 5MC pattern is different between Physarum strains. The possible involvement of this 5MC in rDNA chromatin structure and in cruciform and Z-DNA formation is discussed.

Transcription in oocytes of highly methylated rDNA from Xenopus laevis sperm

The genes for ribosomal RNA exist as multiple copies in the genome. Each repeated unit comprises a region that codes for the 40S rRNA precursor, and a spacer region of uncertain function (Fig. 1a). In Xenopus laevis there are about 1,000 copies of the dinucleotide sequence C-G in each repeat unit, and of these about 250 can be tested for the presence of 5-methylcytosine using restriction endonucleases. Most of the detectable C-Gs are heavily methylated, but in somatic cells unmethylated C-Gs occur in a 60 base pair (bp) sequence (NTS-60) that is repeated in the spacer. In contrast, the spacer of sperm rDNA is heavily methylated at these and all other testable C-Gs. Loss of methylation at NTS-60 takes place during the first day of embryonic development, near the time when rDNA transcription begins. In an attempt to assess the significance of this developmental change in methylation, we have isolated sperm rDNA and investigated whether it can be transcribed in oocytes. We have found that sperm rDNA is transcribed as efficiently as cloned rDNA, although no loss of methylation was detectable. Direct sequencing of sperm rDNA showed that all 19 C-GS in the promoter are highly methylated. Thus, in the case of rDNA injected into oocytes, loss of methylation is unnecessary for effective transcription.

Eukaryotic DNA methylation

Eukaryotic genomes contain 5-methylcytosine (5mC) as a rare base.5mC arises by postsynthetic modification of cytosine and occurs, at least in animals, predominantly in the dinucleotide CpG. The base is not distributed randomly in these genomes but conforms to a pattern. This pattern varies between taxa but appears to be inherited in a semi-conservative fashion. At the level of the genome, gross changes in the level of DNA methylation have been noted. This has encouraged speculation that the modification may play a role in cellular differentiation. Tissue-specific patterns of DNA methylation, predicted by various models of differentiation, have been found for most vertebrate genes so far examined. A correlation has emerged between the undermethylation of these regions and their transcription, but this is not always the case. While data for eukaryotic viral sequences are less equivocal, studies of this kind cannot in isolation distinguish between undermethylation being a cause or a consequence of gene activity. If it were a cause, it is probable that the demethylation of specific CpG sites would be a necessary yet not a sufficient condition for transcription to occur. The introduction of artificially methylated DNA sequences into individual eukaryotic cells by microinjection or transformation may provide the means to elucidate these questions in the future. In the meantime, the study of eukaryotic DNA methylation promises to contribute much to our understanding of the regulation of gene expression in these organisms.

DNaseI-hypersensitive sites at promoter-like sequences in the spacer of Xenopus laevis and Xenopus borealis ribosomal DNA

We have detected a DNAseI hypersensitive site in the ribosomal DNA spacer of Xenopus laevis and Xenopus borealis. The site is present in blood and embryonic nuclei of each species. In interspecies hybrids, however, the site is absent in unexpressed borealis rDNA, but is present normally in expressed laevis rDNA. Hypersensitive sites are located well upstream (over lkb) of the pre-ribosomal RNA promoter. Sequencing of the hypersensitive region in borealis rDNA, however, shows extensive homology with the promoter sequence, and with the hypersensitive region in X. laevis. Of two promoter-like duplications in each spacer, only the most upstream copy is associated with hypersensitivity to DNAaseI. Unlike DNAaseI, Endo R. MspI digests the rDNA of laevis blood nuclei at a domain extending downstream from the hypersensitive site to near the 40S promoter. Since the organisation of conserved sequence elements within this "proximal domain" is similar in three Xenopus species whose spacers have otherwise evolved rapidly, we conclude that this domain plays an important role in rDNA function.