Methylation of satellite sequences in mouse spermatogenic and somatic DNAs.

The distribution of 5-methyl cytosine (5-MeC) residues in a highly repetitive sequence, mouse major satellite, was examined in germinal versus somatic DNAs by digestion with the methylation sensitive isoschizomers Msp I and Hpa II and Southern blot analysis, using a cloned satellite probe. DNA from liver, brain, and a mouse fibroblast cell line, C3H 10T1/2, yielded a multimeric hybridization pattern after digestion with Msp I (and control Eco RI) but were resistant to digestion with Hpa II, reflecting a high level of methylation of the satellite sequences. In contrast, DNA from mature sperm was undermethylated at these same sequences as indicated by the ability of Hpa II to generate a multimeric pattern. DNAs from purified populations of testis cells in different stages of spermatogenesis were examined to determine when during germ cell differentiation the undermethylation was established. As early as in primitive type A, type A, and type B spermatogonia, an undermethylation of satellite sequences was observed. This suggest that this highly specific undermethylation of germ cell satellite DNA occurs very early in the germ cell lineage, prior to entry into meiosis.     

The methylation status of DNA derived from potato plants recovered from slow growth

The in vitro conservation of potato using tissue culture medium supplemented with the growth retardant mannitol causes morphological changes in the propagated material. These culture conditions seem to have an affect on the DNA extracted from the regenerated plants, when it is digested by the methylation sensitive restriction enzymes Hpa II/Msp I and Eco RII/Bst NI, compared to the control material. In most of these plants, there appears to be preferential methylation of nuclear domains that contain Eco RII/Bst NI recognition sites in contrast to those that contain Hpa II/Msp I sites. The refractory nature of the isolated DNA to these restriction enzymes was attributed to hypermethylation of genomic DNA and the ribosomal RNA genes. These findings indicate that methylation of DNA sequences may be an adaptive response to conditions of high osmotic stress. The importance of these results for the conservation of potato germplasm and international exchange is discussed.     

Methylated and unmethylated DNA compartments in the sea urchin genome.

Sea urchin (Echinus esculentus) DNA has been separated into high and low molecular weight fractions by digestion with the mCpG-sensitive restriction endonucleases Hpa II, Hha I and Ava I. The separation was due to differences in methylation at the recognition sequences for these enzymes because an mCpG-insensitive isoschizomer of Hpa II (Msp I) digested Hpa II-resistant DNA to low molecular weight, showing that many Hpa II sites were in fact present in this fraction; and because 3H-methyl methionine administered to embryos was incorporated into the high molecular weight Hpa II-, Hha I- and Ava I-resistant fraction, but not significantly into the low molecular weight fraction. The fraction resistant to Hpa II, Hha I and Ava I amounted to about 40% of the total DNA. It consisted of long sequence tracts between 15 and well over 50 kg in length, in which many sites for each of these enzymes were methylated consecutively. The remaining 60% of the genome, (m-), was not significantly methylated. Methylated and unmethylated fractions were considered to be subfractions of the genome because enriched unique sequences from one fraction cross-reassociated poorly with the other fraction and specific sequences were found in either (m+) or (m-) but not in both (see below). Similar (m+) and (m-) compartments were found in embryos, germ cells and adult somatic tissues. Furthermor, we found no evidence for changes in the sequence composition of (m+) or (m-) between sperm, embryo or intestine DNAs, although low levels of exchange would not have been detected. Using cloned Echinus histone DNA, heterologous 5S DNA and ribosomal DNA probes, we have found that each of these gene families belongs to the unmethylated DNA compartment in all the tissues examined. In particular, there was no detectable methylation of histone DNA either in early embryos, which are thought to be actively transcribing the bulk of histone genes, or in sperm and gastrulae, in which most histone genes are not being transcribed. In contrast to these gene families, sequences complementary to an internally repetitious Echinus DNA clone were found primarily in the methylated DNA compartment.     

Direct visualization of the sites of DNA methylation in human,and mosquito chromosomes

Human and mosquito fixed chromosomes were digested with restriction endonucleases that are inhibited by the presence of 5-methylcytosine in their restriction sites (Hha I, Hin PI, Hpa II), and with endonucleases for which cleavage is less dependent on the state of methylation (Taq I, Msp I). Methylation-dependent enzymes extracted low DNA amounts from human chromosomes, while methylation-independent enzymes extracted moderate to high amounts of DNA. After DNA demethylation with 5-azacytidine the isoschizomers Hpa II (methylation-dependent) and Msp I (methylation-independent) extracted 12-fold and 1.4-fold amounts of DNA from human chromosomes, respectively. These findings indicate that human DNA has a high concentration of Hpa II and Msp I restriction sites (CCGG), and that the internal C of this sequence is methylated in most cases, while the external cytosine is methylated less often. All the enzymes tested released moderate amounts of DNA from mosquito chromosomes whether or not the DNA was demethylated with 5-azacytidine. Hpa II induced banding in the centromere chromosome regions. After demethylation with 5-azacytidine this banding disappeared. Mosquito DNA has therefore, moderate to high frequencies of nonmethylated CpG duplets. The only exception is the centromeric DNA, in which the high levels of C methylation present produce cleavage by Hpa II and the appearance of banding. Centromere regions of human chromosomes 1 have a moderately low concentration of Hpa II-Msp I restriction sites.     

The 5''-cytosine in CCGG1 is methylated in two eukaryotic DNAs and Msp I is sensitive to methylation at this site.

Novikoff rat hepatoma and bovine liver DNAs were digested with Msp I or Hpa II. Restriction fragments were end-labeled using [alpha-32P]-dCTP and the Klenow fragment of E. coli DNA polymerase I and then digested to 2'-deoxyribonucleoside-3'-monophosphates using micrococcal nuclease and spleen phosphodiesterase. Mononucleotides were separated by two-dimensional thin layer chromatography, localized by radioautography, and the [32P]-label quantitated by scintillation spectrometry. This method, based on known specificities of Msp I and Hpa II, shows that CCGG, CMGG, and MCGG (M refers to 5-methylcytosine) occur at frequencies of 89.6%, 1.4%, and 9.0%, respectively, in the rat DNA and at 41.6%, 48.3%, and 10.0%, respectively, in the bovine DNA. [32P] recovery in 3'-5-MedCMP from end-labeled Msp I digests was negligible compared to recovery from Hpa II digests. Hence, Msp I is sensitive to methylation at the 5' cytosine in the sequence CCGG.     

DNA cloning and hybridization in deer species supporting the chromosome field theory

The Cervidae show the largest variation in chromosome number found within any mammalian family. The eight species of deer which are the subject of this study vary in chromosome number from 2n = 70 to 2n = 6. Three species of Bovidae are also included since they belong to a closely related family. Digestion of nuclear DNAs with the restriction endonucleases Hae III, Hpa II, Msp I, Eco RI, Xba I, Pst I and Bam HI reveals that there is a series of highly repetitive sequences forming similar band patterns in the different species. There are two bands (1100 and 550 base pairs) which are common to all species although the two families separated more than 40 million years ago. To obtain information on the degree of homology among these conserved sequences we isolated a Bam HI restriction fragment of approximately 770 base pairs from red deer DNA. This sequence was 32P labeled and hybridized by the Southern blot technique with DNAs cleaved with Bam HI, Eco RI, Hpa II and Msp I. Moreover, the same sequence was cloned in the plasmid vector pBR322 nick translated with 32P and hybridized with the DNAs of 8 species of Cervidae and 3 of Bovidae. The same cloned probe was labeled with 3H and hybridized in situ with the metaphase chromosomes of red deer (2n = 68) and Muntiacus muntjak (2n = 7 male). Homologies are still present between the highly repetitive sequences of the 8 species of Cervidae despite the drastic reorganization that led to extreme chromosome numbers. Moreover, the cloned DNA sequence was found to occupy the same position, in the proximal regions of the arms, in both red deer (2n = 68) and M. muntjak (2n = 7 male) chromosomes. The ribosomal RNA genes and the centromeres in these species have also maintained their main territory despite the drastic chromosome reorganization. These results are experimental confirmation of the chromosome field theory which predicted that each DNA sequence has an optimal territory within the centromere-telomere field and tends to occupy this same territory following chromosome reorganization.     

Molecular characterization of UV-treated sugar beet somaclones using RFLP markers

Sugar beet plants regenerated from UV-treated calluses were examined by restriction fragment length polymorphism (RFLP) analysis to determine the extent of somaclonal variation occurring at the DNA level. In total, 50 random sugar beet DNA sequences were used to screen 42 somaclones for genetic alterations. Three polymorphisms were detected among the 7 644 alleles analysed. From these data a mutation frequency of 0.03 ± 0.02% per allele was estimated. This frequency is in agreement with similar studies of somaclonal DNA variation using molecular markers and lies in the upper range of the spontaneous gene mutation frequencies found in plants. The two probegenotype combinations showing independent polymorphisms, were further analysed using the restriction enzymes Bam HI, Eco RI, Eco RV and Hind III. Both polymorphisms are likely to result from structural rearrangements rather than from point mutations. Differences in methylation among 10 of the investigated somaclones were tested for by comparing Hpa II and Msp I generated RFLP patterns. The somaclones showed extensive methylation, but no differences in their degree of methylation. Cytological analysis revealed 34 diploid, 8 tetraploid, but no aneuploid plants.     

Absence of cytosine methylation at C-C-G-G and G-C-G-C sites in the rDNA coding regions and intervening sequences of Drosophila and the rDNA of other insects.

Cytosine residues in C-G dinucleotides are frequently methylated in eukaryote DNA. In DNA of the dinoflagellate C. cohnii, the sequence C-MeC-G-G apparently renders Hpa II (C-C-G-G) incapable of digesting whole cell DNA in general, and rDNA in particular. Msp I, which also recognizes C-C-G-G but cleaves irrespective of methylation, degrades C. cohnii DNA and produces rDNA segments of 10.2 to 1.4 kb. We have applied this Hpa II/Msp I test to unfractionated DNA, and to rDNA and the rDNA intervening sequence of Drosophila virilis embryos and adults. There is no evidence of C-MeC-G-G sequences in either developmental stage of this species. Absence of G-MeC-G-C from coding and intervening sequences of rDNA was shown in comparisons of Hha I (G-C-G-C) cleavage patterns of unfractionated DNA and cloned (unmodified) segments of rDNA. Comparisons of Hpa II and Msp I cleavage products of DNA from the house fly, the flesh fly and a bumblebee also revealed no internal cytosine methylation in the sequence C-C-G-G. Because amounts of McC in C-G dinucleotides vary greatly among species, from apparent nonexistence to substantial proportions, no inference may yet be drawn about the role of such base modifications in DNA.     

DNA methylation in stingless bees with low and high heterochromatin contents as assessed by restriction enzyme digestion and image analysis.

BACKGROUND: The stingless bee genus Melipona has been divided into two groups, based on their heterochromatin content. Melipona quadrifasciata and Melipona rufiventris have low and high levels of heterochromatin, respectively. Since condensed chromatin may be rich in methylated DNA sequences, M. quadrifasciata and M. rufiventris nuclei may contain different amounts of methylated CpG. These differences could be assessed by comparing Feulgen-DNA values obtained by image analysis of cells treated with the restriction enzymes Msp I and Hpa II that distinguish between methylated and unmethylated DNA. Msp I and Hpa II cleave the sequence -CCGG-, but there is no cleavage by Hpa II if the cytosine of the central CG dinucleotide is methylated. METHODS: Malpighian tubules of M. quadrifasciata and M. rufiventris were treated with Msp I and Hpa II prior to the Feulgen reaction, and analyzed by automatic scanning microspectrophotometry. RESULTS: The Feulgen-DNA values for the heterochromatin of M. rufiventris and for the small heterochromatin and some euchromatin domains of M. quadrifasciata mostly decreased after treatment with Msp I, but were unchanged after treatment with Hpa II. CONCLUSION: CpG methylation, although detected in diverse chromatin compartments in different bee species, may induce silencing effects required for the same cell physiology.     

The ability of bacterial DNA methyltransferases to use methylcobalamine as a cofactor in DNA methylation reactions

The ability of bacterial DNA methyltransferases Alu I, Cfr I, Cfr 6, Cfr 10, Eco RI, Eco RII, Msp I, Mva I, Pvu I, Pvu II, and Sau 3A to use methylcobalamine and methylmethionine as cofactors of DNA methylation in vitro has been investigated. These bacterial DNA methyltransferases used methylcobalamine, but not methylmethionine for DNA methylation.     

Alu repeated DNAs are differentially methylated in primate germ cells.

A significant fraction of Alu repeats in human sperm DNA, previously found to be unmethylated, is nearly completely methylated in DNA from many somatic tissues. A similar fraction of unmethylated Alus is observed here in sperm DNA from rhesus monkey. However, Alus are almost completely methylated at the restriction sites tested in monkey follicular oocyte DNA. The Alu methylation patterns in mature male and female monkey germ cells are consistent with Alu methylation in human germ cell tumors. Alu sequences are hypomethylated in seminoma DNAs and more methylated in a human ovarian dysgerminoma. These results contrast with methylation patterns reported for germ cell single-copy, CpG island, satellite, and L1 sequences. The function of Alu repeats is not known, but differential methylation of Alu repeats in the male and female germ lines suggests that they may serve as markers for genomic imprinting or in maintaining differences in male and female meiosis.     

Methylation of DNA of the brain and liver of young and old rats.

In vitro methylation of purified DNA and chromatin-DNA in nuclei of the liver and brain of young (18 week) and old (120 week) female rats has been studied using 3H-SAM as the -CH3 group donor. Incorporation of -CH3 group is higher in old liver and brain, but it is far higher in the latter. 5 mC is 11% lower in the old brain, but there is no difference in the liver. Methylation by Hpa II methylase does not show any difference in the incorporation of -CH3 group into DNA of the liver of the two ages. However, its incorporation is lower in the old brain. Methylation by Msp I methylase causes slightly higher incorporation of -CH3 groups in the old brain. This shows a higher percentage of unmethylated external cytosines in the 5'-CCGG-3' sequences. On the contrary, methylation by Eco RI methylase is considerably higher in the old brain. These studies show alterations in the methylation status of the DNA during ageing which may cause changes in the expression of genes.     

Analysis of the methylation pattern of c-Ha-ras oncogene in human prostatic cancer

To determine the methylation pattern of c-Ha-ras oncogene in prostatic tissue and to identify possible changes of methylation associated with cancer, high molecular weight DNA was extracted from 7 normal and 6 carcinomatous human prostates. Analysis of the samples was performed by cleaving DNA with the restriction endonucleases Msp I, Hpa II and Cfo I, and by Southern hybridizing the DNA digests with the 32P-labelled c-Ha-ras (pT24-C3) probe. Several discrete fragments were obtained with Hpa II and Cfo I digestion while the Msp I pattern showed fewer and smaller bands. Therefore, c-Ha-ras appears to be partially methylated. While a considerable polymorphism of the sequence 5'-CCGG-3' was observed at several Msp I sites in all cases, no significant differences could be evidenced in the methylation patterns of normal and neoplastic prostatic DNA samples extracted and purified from each patient.     

DNA methylation controls the inducibility of the mouse metallothionein-I gene in lymphoid cells

The W7 mouse thymoma cell line does not express the metallothionein-I (MT-I) gene in the presence of either cadmium or glucocorticoids, unlike most other cell lines. This cell line was therefore used as a model system for studying the role of DNA methylation on MT-I gene expression. The extent of DNA methylation within the MT-I gene and its flanking regions was determined by comparing the cleavage patterns generated by the isoschizomeric restriction enzymes Hpa II and Msp I. In W7 cells, all of the Hpa II sites in the vicinity of the MT-I gene are methylated, whereas in cells that have an expressible MT-I gene (for example, Friend erythroleukemia cells) all of these Hpa II sites are unmethylated. When W7 cells are treated for a few hours with 5-azacytidine, the MT-I gene becomes inducible by both cadmium and glucocorticoids. Addition of hydroxyurea along with 5-azacytidine prevents MT-I gene induction, suggesting that incorporation of 5-azacytidine into DNA is required before this gene can be activated. To determine whether 5-azacytidine treatment changes the methylation pattern near the MT-I gene, we treated W7 cells with 5-azacytidine and selected inducible cells in 10 μM cadmium. All of the Hpa II sites within the MT-I gene are unmethylated in these cadmium-resistant W7 cells. In addition, flanking DNA sequences are also undermethylated in a pattern similar to that seen in Friend erythroleukemia cells that express the MT-I gene. The possible significance of methylation as a mechanism of gene commitment during cell differentiation is discussed.     

Fragment comparison of hamster mitochondrial DNA: general conclusions about the evolution of mitochondrial DNA

Mitochondrial DNA from heart, liver and kidney of two hamster species, Mesocricetus auratus and Cricetulus griseus has been digested with the restriction endonucleases Bam HI, Bgl I, Eco RI, Hae III, Hind III, Hpa II and Xba I. Cleavage patterns for Hpa II are identical for both species, while only two of seven bands are common with Hae III. All other endonucleases give a species-specific cleavage pattern. The results suggest a fairly high phylogenetic differentiation of the mitochondrial genome between the two hamster species. The large differences in mitochondrial DNA variability between different species is discussed as a function of mutation rate and species-specific generation time.     

Restriction enzyme digestion of hemimethylated DNA.

Hemimethylated duplex DNA of the bacteriophage phi X 174 was synthesized using primed repair synthesis is in vitro with E. coli DNA polymerase I followed by ligation to produce the covalently closed circular duplex (RFI). Single-stranded phi X DNA was used as a template, a synthetic oligonucleotide as primer and 5-methyldeoxycytidine-5'-triphosphate (5mdCTP) was used in place of dCTP. The hemimethylated product was used as substrate for cleavage by various restriction enzymes. Out of the 17 enzymes tested, only 5 (BstN I, Taq I, Hinc II, Hinf I and Hpa I) cleaved the hemimethylated DNA. Two enzymes (Msp I and Hae III) were able to produce nicks on the unmethylated strand of the cleavage site. Msp I, which is known to cleave at CCGG when the internal cytosine residue is methylated, does not cleave when both cytosines are methylated. Another enzyme, Apy I, cleaves at the sequence CCTAGG when the internal cytosine is methylated, but is inactive on hemimethylated DNA in which both cytosines are methylated. Hemimethylated molecules should be useful for studying DNA methylation both in vivo and in vitro.