Loss of rDNA methylation accompanies the onset of ribosomal gene activity in early development of X. laevis

The methylation pattern of tRNA genes in Xenopus laevis

The methylation sensitive restriction enzymes Hha I and Hpa II were used to analyse the methylation pattern of a tRNA gene cluster in germ line and somatic DNA of Xenopus laevis. A single tDNA repeat containing 8 tRNA genes was studied and all copies were found to be fully modified in sperm DNA. In the DNA from erythroid cells, hepatocytes, kidney and brain, most tDNA repeats were found to be fully modified. However, in a fraction of the repeats, specific demethylated sites can be detected, giving rise to a pattern which does not vary significantly from one tissue to another. Although our results do not allow a straightforward correlation between hypomethylation and tRNA gene transcription, they are in agreement with the observation that hypomethylation accompanies differentiation and development.

Natural fibroin genes purified without using cloning procedures from fibroin-producing and -nonproducing tissues reveal indistinguishable structure and function

Natural fibroin genes were purified from total DNA extracted from the fibroin-producer cells (posterior silk gland) and -nonproducer cells (middle silk gland or pupa) by two cycles of CsCl/actinomycin D centrifugation followed by sucrose density gradient centrifugation. Purity of the final samples was greater than 14%. DNA sequences of these natural genes between positions -171 and +104 were identical and showed no sign of base modification as assayed by the method of Maxam and Gilbert. The determined sequence includes the promoter and a major part of the modulator. When assayed in an in vitro transcription system prepared from middle silk gland, template activities of the purified natural fibroin genes from the producer and the nonproducer were indistinguishable from that of cloned fibroin DNA. Digestion and blotting of total genomic DNAs with several restriction enzymes that recognize methylation changes on DNA revealed no difference of hybridization pattern of fibroin DNAs in a region from -650 to +326 between the producer and nonproducer. Thus, it is unlikely that the differential transcription of the fibroin gene is controlled by a change of base modification in the regions of transcription signals.

Absence of detectable 5-methylcytosine in DNA of embryos of the brine shrimp, Artemia

DNA from three developmental stages of the brine shrimp, Artemia was found to be undermethylated compared to DNA from calf thymus and salmon sperm. Using high-performance liquid chromatography we found that DNA hydrolysates from both dormant cysts and prefeeding nauplii contain less than 1 residue of 5-methylcytosine per 59 kilobases, placing Artemia DNA in the "insect type" category. The absence of detectable 5-methylcytosine in DNA of developing Artemia supports the view that methylation status alone cannot account for regulation of transcription in protostomes, and that DNA methylation may be more common among deuterostomes.

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.

An estrogen-dependent demethylation at the 5' end of the chicken vitellogenin gene is independent of DNA synthesis

A HpaII site 611 base pairs upstream from the 5' end of the chicken vitellogenin II gene exhibits an estrogen-dependent demethylation in hormone-responsive cells. The complete demethylation of this site occurs considerably later than the transcriptional activation of the gene, and therefore appears to be an effect rather than a cause of this activation. In vivo studies using two inhibitors of DNA synthesis (cytosine arabinoside and hydroxyurea) demonstrate that activation of transcription of the gene is independent of DNA synthesis. Surprisingly, the estrogen-dependent demethylation of the HpaII site is also independent of DNA synthesis. The possible involvement of a site-specific demethylase is discussed.

Spacer regulation of Xenopus ribosomal gene transcription: competition in oocytes

Xenopus laevis ribosomal gene plasmids bearing different length spacers were injected into oocyte nuclei in competition with each other. The spacer has two basic effects on transcription from the gene promoter. First, if the competing pair have unequal spacer lengths, the gene promoter attached to the longer spacer is always dominant in transcription (the competition effect). Second, as the total amount of spacer in the reaction increases, the total amount of transcription decreases (the sink effect). Both the competition and the sink effect are attributed to sequence elements that are 60 or 81 bp long, which are present in multiple copies in the spacer and are related in sequence to part of the gene promoter. The 60/81 bp elements confer competitive dominance in either orientation. A model which explains both the competition and the sink effects is discussed in which the 60/81 bp elements are attraction sites for a factor(s) which is needed to activate the gene promoter.

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.

Towards an understanding of the molecular mechanisms regulating gene expression during diploidization in phylogenetically polyploid lower vertebrates

Polyploidization and regional gene duplication have occurred frequently during vertebrate evolution, providing the genetic material necessary for creating evolutionary novelties. Mammals, including man, can be regarded as diploid species with a polyploid history of evolution. Polyploidization steps during the phylogeny of mammals probably took place in the genomes of amphibian- or fish-like mammalian ancestors. The polyploid status has subsequently been shaped by the process of diploidization, leading to genomes that are polyploid with respect to the amount of genetic material and the number of gene copies, and diploid with respect to the level of gene expression and chromosomal characteristics. Phylogenetically tetraploid amphibian and teleost species together with their diploid close relatives can be used as a model system to study the effect of polyploidization and the mechanisms of diploidization of a parallel event during early mammalian evolution. Experimental evidence permits the assumption that the diploidization of gene expression in tetraploid cyprinid fish may be functionally correlated with structural modifications of the ribosomal components, RNA and protein. These findings are discussed in the light of reduced protein synthesis in diploidized tetraploid species and a mechanism to explain diploidization during mammalian evolution.

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.

Isolation and characterization of DNA cytosine 5-methyltransferase from human placenta

DNA cytosine 5-methyltransferase has been extensively purified (about 2600-fold) from the soft tissue of human placenta by chromatography on DEAE-cellulose and hydroxyapatite, and by an affinity step on agarose-immobilized S-adenosylhomocysteine. The isolated enzyme has a molecular weight of 135,000 and methylates DNA from various sources in native and heat-denatured forms. The synthetic copolymer poly(dG-dC) . poly(dG-dC) is methylated in B- and Z-conformation to about the same extent. DNA containing hemimethylated sites was isolated from P815 cells grown in the presence of 5-azacytidine. This P815 DNA was used to measure the "maintenance' DNA methylase activity, whereas 5-methylcytosine-free procaryotic DNA served as a substrate for the "de novo' DNA methylase activity in our enzyme preparation. The crude extract as well as the highly purified DNA methylase are capable of transferring methyl groups to these two types of substrate. The fact that both types of activity co-chromatograph during the isolation procedure suggests that one enzyme molecule may exercise both the "maintenance' and "de novo' activity.

Treatment of sickle cell anemia with 5-azacytidine results in increased fetal hemoglobin production and is associated with nonrandom hypomethylation of DNA around the gamma-delta-beta-globin gene complex

Increased production of fetal hemoglobin (HbF) was observed in a patient with sickle cell anemia treated with 5-azacytidine. Each of four courses of therapy resulted in a rapid and prolonged increase in the percentage of HbF containing reticulocytes (F reticulocytes) and HbF containing erythrocytes (F cells). The percentage of HbF in peripheral blood rose from 1.8 to 8.9%. The rise in HbF production was accompanied by an increase in peripheral blood hemoglobin concentration from 8 to 12 g/dl and an increase in mean erythrocyte volume. Treatment with 5-azacytidine resulted in hypomethylation of total genomic and a Y-chromosome-specific DNA fragment isolated from both peripheral blood and bone marrow. Of 15 restriction enzyme sites around the gamma-delta-beta-globin gene complex, only 2 became hypomethylated: one 107 bases 5' to the gamma G and the other 107 bases 5' to the gamma A globin genes.

Retrovirus genomes methylated by mammalian but not bacterial methylase are non-infectious

The biological importance of DNA methylation for gene expression in eukaryotes is becoming increasingly evident, and a direct role of methylation in gene expression has been suggested by an analysis of the infectivity of integrated retroviral genomes in a transfection assay. These studies, however, did not address whether specific methylatable residues are involved in gene regulation. Methylation by sequence-specific bacterial DNA methylases has been shown to suppress the expression of some genes, but not others. To investigate the effect of methylation on gene expression without having to rely on sequence-specific methylases, a rat liver enzyme was used to methylate in vitro all C-G dinucleotides of a proviral genomic clone. This treatment reduced the biological activity of Moloney murine leukaemia virus (M-MuLV) proviral DNA by more than three orders of magnitude, whereas complete methylation of 35 HpaII sites in the same DNA had only a marginal effect. The rat methylase-induced inactivation was reversible, as treatment of recipient cells with 5-azacytidine rendered the non-infectious viral genomes biologically active. This suggests that methylation in other C-G dinucleotides than those detectable with restriction enzymes can be crucial for gene expression.

Integrated hepatitis B virus DNA sequences specifying the major viral core polypeptide are methylated in PLC/PRF/5 cells

The methylation of various hepatitis B virus (HBV) DNA sequences was examined using the restriction endonucleases Hpa II and Msp I. HBV DNA from virions (Dane particles) and virus-infected liver tissue was digested with Hpa II or Msp I and fractionated by electrophoresis in agarose gels, and the restriction enzyme cleavage pattern was examined by Southern blot analysis. No methylation of the 5' C-C-G-G 3' recognition sequence was detected in either virion DNA or HBV DNA from infected liver tissue. The tissue culture cell line PLC/PRF/5, derived from a human hepatoma, possesses HBV DNA exclusively integrated at several sites. Digestion of PLC/PRF/5 DNA with Hpa II and Msp I revealed that the integrated HBV DNA sequences were methylated. Further analysis using probes specific for various regions of the HBV genome showed that some of the hepatitis B viral DNA sequences, including those specifying the major surface antigen polypeptide, were methylated infrequently or not at all. In contrast, the viral DNA sequences coding for the major core polypeptide were extensively methylated. Because the surface antigen is expressed in these cells while the core antigen is not, our results suggest that DNA methylation could account for the selective expression of HBV genes in this hepatoma cell line.

Transcription and methylation of flax rDNA

The transcription of flax rDNA and the processing of the rRNA precursors is described. The location of methylated regions of the rDNA has been assayed, one of the least methylated regions maps close to the 5' end of the largest identified rRNA precursor.

In contrast to other Xenopus genes the estrogen-inducible vitellogenin genes are expressed when totally methylated

The methylation-sensitive restriction enzymes Hha I and Hpa II were used to analyze the methylation pattern of four Xenopus laevis genes in DNA of embryos, of erythrocytes, and of untreated and estrogen-treated hepatocytes. Within these four genes all sites tested are fully modified in embryonic DNA. However, the adult beta 1-globin gene is unmethylated in DNA of erythrocytes, where it is expressed, and the 68 kd albumin gene, active only in hepatocytes, is specifically hypomethylated in hepatic DNA. The vitellogenin genes A1 and A2, in hepatocytes simultaneously expressed upon estrogen treatment, are heavily methylated in all adult tissues, irrespective of expression. Our results reveal that specific genes can be actively transcribed even when they are fully methylated and that changes in the methylation pattern are not a general prerequisite for gene activation.

Activation of human ribosomal genes by 5-azacytidine

Cultured human fibroblasts were exposed to 5-azacytidine which inhibits methylation of newly synthesized DNA. A significant increase in the mean number of Ag-stained active nucleolus organizers has been observed in treated cells. This suggests that DNA methylation is involved in modulation of human rRNA synthesis.

Integrated hepatitis B virus DNA sequences specifying the major viral core polypeptide are methylated in PLC/PRF/5 cells

The methylation of various hepatitis B virus (HBV) DNA sequences was examined using the restriction endonucleases Hpa II and Msp I. HBV DNA from virions (Dane particles) and virus-infected liver tissue was digested with Hpa II or Msp I and fractionated by electrophoresis in agarose gels, and the restriction enzyme cleavage pattern was examined by Southern blot analysis. No methylation of the 5' C-C-G-G 3' recognition sequence was detected in either virion DNA or HBV DNA from infected liver tissue. The tissue culture cell line PLC/PRF/5, derived from a human hepatoma, possesses HBV DNA exclusively integrated at several sites. Digestion of PLC/PRF/5 DNA with Hpa II and Msp I revealed that the integrated HBV DNA sequences were methylated. Further analysis using probes specific for various regions of the HBV genome showed that some of the hepatitis B viral DNA sequences, including those specifying the major surface antigen polypeptide, were methylated infrequently or not at all. In contrast, the viral DNA sequences coding for the major core polypeptide were extensively methylated. Because the surface antigen is expressed in these cells while the core antigen is not, our results suggest that DNA methylation could account for the selective expression of HBV genes in this hepatoma cell line.

A transcriptional function for the repetitive ribosomal spacer in Xenopus laevis

The function of the Xenopus laevis ribosomal spacer has been studied in vivo and by microinjection of in vitro mutants into Xenopus oocytes. It is shown that the spacer directs specific RNA transcripts which most probably terminate upstream of the ribosomal genes and that it is able to modulate transcription of these genes. The data lead to a model in which the ribosomal spacer is a loading site for RNA polymerase I and spacer transcription is the driving force by which polymerase is delivered to the ribosomal gene promoter.

DNA methylation patterns in the 5S DNAs of Xenopus laevis

The frequency of cytosine methylation at specific sites in the somatic 5S DNA (X1s) and trace oocyte 5S DNA (X1t) of X. laevis has been determined using restriction enzymes that are inhibited by the presence of 5-methylcytosine (5mC) within their cleavage sequences. 5S DNA methylation patterns were determined in genomic DNA from mature red blood cells, which express neither type of 5S gene, and from liver, which expresses only X1s. All the sites examined in X1t are greater than 95% methylated in red cells and liver. In the X1s of red cells all the sites examined are methylated in greater than 95% of repeats, while in liver some sites are modified in only 90% of repeats. Repeats containing unmethylated sites are randomly distributed throughout the tandem arrays in both red cells and liver. The high levels of methylation for X1s are in marked contrast to the situation with other Xenopus genes which do have sites of significant undermethylation in tissues where they are active. Thus, undermethylation in active genetic regions may not be a general feature for all classes of eukaryotic genes.

Expression of transferred thymidine kinase genes is controlled by methylation

Plasmid pTKx-1, containing the herpes simplex virus gene for thymidine kinase (TK) inserted into the BamHI site of plasmid pBR322, was introduced into Ltk- cells by calcium phosphate precipitation in the absence of carrier DNA. Line 101 is a TK+ derivative of Ltk- that contains multiple copies of pTKx-1 in a multimeric structure. A derivative of 101 that retained but no longer expressed the herpes simplex TK genes (termed 101BU1) and derivatives of line 101BU1 that reexpressed the genes (termed 101H1, 101HC, and 101HG) were selected. The TK genes in 101BU1 were hypermethylated relative to those in the TK+ parent and derivatives. Growth of 101BU1 in the presence of the methylation inhibitor 5-azacytidine resulted in an average 13-fold increase in the number of TK+ reexpressors, DNA from 101BU1 was inactive in secondary gene transfer, whereas DNA from 101 and from TK+ reexpressors was active. These data support a causative relationship between DNA methylation and decreased gene expression. All TK+ reexpressors examined had DNA rearrangements involving TK DNA.

DNA methylation in chicken alpha-globin gene expression

We have investigated certain specific methylation sites of the chicken alpha-globin gene cluster in DNA from embryonic and adult erythroid cells as well as from brain and sperm cells. Eight contiguous DNA fragments of the alpha-globin gene cluster were subcloned from a recombinant lambda phage. The subclones were used as probes to map all the Msp I/Hpa II and Hha I sites in the unmethylated cloned DNA and specific sites of methylation in and around the alpha-globin gene cluster in chromosomal DNA. The data show that sperm DNA is totally methylated at these restriction sites in the globin gene region, as is brain DNA, with some exceptions. Interestingly, the methylation status of specific sites 5' to the coding sequences is correlated with expression of the embryonic or adult alpha-globin genes in different stages of erythroid development. Some sites showing partial methylation, however, do not conform to the model that transcribed genes are unmethylated or undermethylated. We also find a well-defined 3.5-kilobase region of DNA 5' to the alpha-globin gene cluster in which all C-C-G-G sites are resistant to Msp I digestion in all tissues. This "Msp block" is presumably caused by 5-MeCpC methylation.

De novo methylation and expression of retroviral genomes during mouse embryogenesis

Retrovirus genomes introduced into mouse zygotes by microinjection of cloned DNA, or into morula stage pre-implantation mouse embryos by infection with Moloney murine leukaemia virus (M-MuLV), became de novo methylated and were blocked in expression. No restriction of virus expression and no de novo methylation were observed when post-implantation mouse embryos were infected with virus. Efficient de novo methylation activity may be an important characteristic of gene regulation in early mouse embryos.

Tissue specificity and clustering of methylated cystosines in bovine satellite I DNA

The positions of all 5-methylcytosine (mC) residues in bovine satellite I DNA were determined by sequence analysis of native purified satellite I DNAs from three bovine tissues as well as from cloned DNA. The EcoRI cleavage units from thymus and liver were found to contain 1,402 residues; that from brain contained 1,401 residues. Satellite I DNA from thymus contained a total of 5.0% mC, whereas that from liver and brain contained 4.4% and 2.6% mC, respectively. Thus, the extent of methylation of this DNA is tissue-specific. So is the location. In each tissue, the location of mCs is nonrandom, consisting of three clusters of heavily methylated regions, each of about 200 bases. However, the extent of methylation within each cluster is tissue-specific. The mCs are located entirely in C-G doublets and primarily in palindromic sequences, C-C-G-G sequences (10 methylatable sites) are almost completely methylated in all tissues examined, but T-G-G-A sequences (16 methylated in all tissues examined, but T-G-G-A sequences (16 metylatable sites) are methylated to different extents in each tissue. Neither the tissue specificity of methylation nor the clustering pattern is detectable by examining only G-C-G-G sites, leading us to emphasize the importance of total sequence determination for genomic DNAs in studies of methylation. The clustering pattern, which is preserved despite a 2-fold difference in mC content between brain and thymus, may indicate a role for DNA methylation in chromatin structure.

DNAase I sensitivity and methylation of active versus inactive rRNA genes in xenopus species hybrids

We studied the chromatin structure and methylation of ribosomal RNA genes (rDNA) in hybrids between Xenopus laevis and Xenopus borealis. S1-nuclease protection experiments showed that 97%-98% of the rRNA precursor in hybrid tadpoles was of the X. laevis type. Preferential expression of the laevis rDNA was correlated with its hypersensitivity to DNAase I compared to borealis rDNA. Borealis and laevis rDNAs gave equivalent methylation patterns, however. The results show that hypomethylated sites in the nontranscribed spacer are not sufficient to ensure DNAase I hypersensitivity or transcription of the borealis rDNA. Also, heavy methylation of the transcribed region of laevis rDNA is compatible with its hypersensitivity to DNAase I. The absence of coupling between hypomethylation and DNAase I sensitivity argues against the view that the methylation pattern directly triggers the active chromatin structure, though it does not exclude a less intimate relationship between transcription and DNA hypomethylation. Examination of borealis sperm rDNA showed that hypomethylated sites were present at the same spacer locations as in somatic cells. This contrasts with X. laevis, where hypomethylated sites are detectable in the spacer of somatic rDNA, but not in sperm. Thus the loss of spacer methylation that is seen in early development of X. laevis does not occur in X. borealis.

Amount and distribution of 5-methylcytosine in human DNA from different types of tissues of cells

Analysis of the total base composition of DNA from seven different normal human tissues and eight different types of homogeneous human cell populations revealed considerable tissue-specific and cell-specific differences in the extent of methylation of cytosine residues. The two most highly methylated DNAs were from thymus and brain with 1.00 and 0.98 mole percent 5-methylcytosine (m5C), respectively. The two least methylated DNAs from in vivo sources were placental DNA and sperm DNA, which had 0.76 and 0.84 mole percent m5C, respectively. The differences between these two groups of samples were significant with p less than 0.01. The m5C content of DNA from six human cell lines or strains ranged from 0.57 to 0.85 mole percent. The major and minor base composition of DNA fractionated by reassociation kinetics was also determined. The distribution of m5C among these fractions showed little or no variation with tissue or cell type with the possible exception of sperm DNA. In each case, nonrepetitive DNA sequences were hypomethylated compared to unfractionated DNA.

Methylation of mouse ribosomal RNA genes

Ribosomal DNA (rDNA) methylation was studied in various strains of mice. We used restriction enzymes that are sensitive to methylation and a cloned probe containing the transcribed spacer and part of the 18S and 28S gene. Strains C3H/He3, C57/B6-3, and AKR/J were found to have less than 9% of the rDNA methylated. In sharp contrast, Balb/c mice showed 30-50% of the Hpa II and Hha I sites to be methylated. Further study of the Balb/c DNA showed that there are three groups of rDNA sequences. In the first group, all the Hpa II and Hha I sites are almost completely unmethylated; in the second group these sites are all methylated (greater than 30 sites for each enzyme); in the third group most sites are methylated, but there are discrete hypomethylation sites. These hypomethylation positions are at similar sites for both Hpa II and Hha I and show a tissue-specific pattern. Comparison of AKR/J with Balb/c copy level showed that AKR/J had about 60% fewer rDNA genes. The rDNA methylation level might thus be correlated directly with the number of rDNA genes. Finally, analysis of F1 mice from a cross between Balb/c and AKR/J showed both low copy number and low methylation levels.

Cytochrome P1-450 structural gene in mouse, rat, and rabbit: differences in DNA methylation and developmental expression of mRNA

Clone 46 previously was shown to represent an 1100-bp cDNA clone of the mouse cytochrome P1-450 structural gene. Clone 46 [32P]DNA was hybridized to DNA and mRNA from mouse, rat, and rabbit of different ages. In Hpa II digests of DNA, two hybridizable fragments of less than 0.5 kb exist in adult "Ah-responsive" C57BL/6N mouse liver but not in C57BL/6N sperm or embryo or in adult "Ah-nonresponsive" DBA/2N mouse liver. The reason for this hypomethylation of adult C57BL/6N liver DNA is not known but might be related to the high degree of expressivity of this gene in adult C57BL/6N liver, compared with adult DBA/2N liver. No differences in Hpa II- or Msp I-digested DNA are seen in C57BL/6N or DBA/2N inbred strains treated with the P1-450 inducer, 3-methylcholanthrene (3-MC), versus untreated controls. The ontogenetic expression of 3-MC-induced P1-450 mRNA (23S) from mouse or rat liver corresponds well to previous developmental studies from this laboratory involving 3-MC-inducible aryl hydrocarbon (benzo[a]pyrene) hydroxylase (AHH) (EC 1.14.14.1) activity. P1-450 mRNA--induced transplacentally by 3-MC given to the mother--is readily detectable by clone 46 as early as gestational day 15. The cloned cDNA probe hybridizes to rat and rabbit DNA fragments of different sizes, and with less intensity, when compared with hybridization to mouse DNA. No hybridization of this DNA is observed with rabbit mRNA of all ages ranging from neonate to adult. These data suggest that sequence homology exists among the mouse, rat, and rabbit P1-450 structural genes and between mouse and rat P1-450 mRNA. The mouse cDNA probe is believed to hybridize to a segment of the rabbit P1-450 gene that is not transcribed.