The loss of dinucleotides CpG from DNA. IV. Methylation and divergence of genes and pseudogenes of small nuclear RNA

The frequency of neighboring base pairs in nucleotide sequences of over 80 genes and pseudogenes of low molecular weight RNAs U1-U8, 4.5S and 7S in different eukaryotes was determined. The probable frequency of CpG----TpG + CpA substitutions, caused as a result of the deamination of 5-methylcytosine residues in DNA, was determined. It was found that the genes of small RNAs do not reveal a single level of CpG methylation for all the species studied. In most cases CpG in the genes of U1, 4.5S and 7S RNA are methylated, whereas in the genes of U2-U6-RNA these sites must have never been subjected to methylation. Nearly all the investigated pseudogenes of different small RNAs are strongly methylated due to a considerable lack of CpG. It was established that CpG----TpG + CpA transitions may amount to as much third of all the mutations accumulated in the genes of the same RNAs in different species. Such transitions in pseudogenes may account for 40% of all the nucleotide substitutions. This disproportionately high level of mutations in CpG dinucleotides (3-5-fold higher than in other DNA dupletes) must be the direct result of the methylation of these sites. Consequently, CpG methylation causes a dramatic acceleration of the divergence rate of DNA sequences. It has been concluded that protection of most vital genes against methylation is one of the essential conditions for sustaining the high level of stability of the macromolecular structure and for the reliability of macromolecular functioning in a cell.     

Loss of CpG dinucleotides from DNA. VI. Methylation of mitochondrial and chloroplast genes

From nucleotide sequences of mitochondrial and chloroplast genes the probable frequency of the CpG----TpG + CpA substitutions was determined. These substitutions may indicate the level of prior DNA methylation. It was found that the level of this methylation is significantly lower in mitochondrial DNA (mtDNA) and chloroplast DNA (chDNA) than in nuclear DNA (nDNA) of the same species. The species (taxon) specificity of mtDNA and chDNA methylation was revealed. A correlation was found between the level of CpG methylation in nDNA, and mtDNA and chDNA in different organisms. It is shown that cytosine residues in CpG were not subjected to significant methylation in the fungi and invertebrate mtDNA and also in the algae chDNA. In contrast, the vertebrate mtDNA bears the impress of CpG-supression, which is confirmed by direct data on methylation of these DNA. Here the first data on the possible enzymatic methylation of the plant mtDNA and chDNA were obtained. It was shown that the degree of CpG-suppression in the 5S rRNA nuclear genes of lower and higher plants is significantly higher in the chloroplast genes of 4,5S and 5S rRNA. From data on pea chDNA hydrolysis with MspI and HpaII it was established that in CCGG sequences this DNA is not methylated. The role of DNA methylation in increasing the mutation rate and in accelerating the evolutionary rates of vertebrate mtDNA is discussed.     

The loss of CpC dinucleotides from DNA. II. Methylated and non-methylated genes of vertebrates

The frequencies of neighboring b.p. in more than 1100 genes of vertebrates in the EMBL bank (1000 kb) have been analysed. It has been found that the majority of such genes exhibit a lack of CpG duplexes and an excess of TpG+CpA. The loss of CpG may indicate that the major part of these sites in the genome is methylated and has been subjected to the pressure of CpG----TpG+CpA mutations. The methylated genes grouped into compartment M+ are represented by a fraction of repeated sequences and by genes of the most rapidly diverging families of proteins (globins, immunoglobulins, structural proteins, etc.). The genes of this compartment are characterized by a correlation between the G+C content and the value of CpG-suppression. A group of genes has been detected in which the CpG mutation process has gone so far that nearly all of these dinucleotides have disappeared from DNA. Judging by the value of CpG-suppression, these genes, grouped in the Mo+ compartment, used to be strongly methylated before. However, in the now extant vertebrates they have fully depleted their CpG reserve and for this reason lost the methylation capacity. Transitions in methylated CpG may be one of the sources of spontaneous mutagenesis resulting in the enhanced genetic instability of the cell. A gene compartment has been detected with an intermediate level of CpG deficiency; this compartment has been designated as M+. In these genes only a few of the available CpGs have been steadily methylated (and subjected to mutation). It has been found that the genome of vertebrates contains a specific CpG-rich fraction which exhibits no CpG-suppression, irrespective of the overall content of G+C. Probably, CpG sites have persisted unmethylated throughout the existence of these genes. We suggest them to constitute a M- compartment. This compartment comprises the genes of tRNA and rRNA (5S, 5.8S, 18S, 28S) and small nuclear RNAs U2-U6, as well as the genes of core histones, some enzymes, viruses and 5'-flanking sequences of certain protein-coding genes. In the genome of vertebrates, the genes of the evolutionary most conserved proteins and RNAs have not undergone methylation. A list of genes, belonging to different compartments of the vertebrate genome, is given. Compartment Mo+ constitutes 19%, M(+)--35%, M(+/-)--28% and M(-)--8% of all the vertebrate genes studied. Possible mechanisms, protecting the functionally most significant genes of vertebrates from methylation, and discussed.     

The loss of CpG dinucleotides from DNA. I. Methylated and non-methylated genome compartments in eukaryotes with different levels of 5-methylcytosine in DNA

The methylation of cytosine residues in CpG significantly increases the frequency of m5CpG----TpG transitions in DNA and CpG dinucleotides are eliminated from the genome (CpG-suppression). In the millions of years of vertebrates evolution about 3 mol% of 5-methylcytosine have disappeared from their genome, i.e., 2-3-fold more than the amount persisting in the DNA of the now extant species. A computer analysis has been carried out of neighboring b.p. frequencies in more than 2500 sequenced genes of different species in the EMBL bank with an overall extension of over 3000 kb. It has been found that CpG methylated sites exhibit a highly irregular distribution pattern in the genome of eucaryotes. The majority of the vertebrate sequences (92%) bears the impress of a significant lack of CpG and an excess of TpG+CpA; therefore they may be referred to the genome methylated compartment. A group of genes has been discovered (about 8%) where CpG must have never been subjected to methylation. In invertebrates, such a nonmethylated compartment makes up 59% of the genome and in eubacteria--85%. A brief list of genes, belonging to the methylated and the non-methylated compartments of the invertebrate and yeast genome, is given. It has been established that the mean value of CpG-suppression in genes is directly proportional to the methylation level of total DNA in different species.     

Increased G + C content of DNA stabilizes methyl CpG dinucleotides.

The vertebrate genome is a mosaic of regions differing dramatically in their G + C content. Those regions with a high G + C content contain the expected number of CpG dinucleotides and we propose that following methylation these have been protected from deamination by the increased stability of the surrounding DNA duplex. This argument applies both to the microenvironment of the CpG dinucleotide and to whole gene regions.     

Excision of 8-oxoguanine from methylated CpG dinucleotides by human 8-oxoguanine DNA glycosylase

CpG dinucleotides are targets for epigenetic methylation, many of them bearing 5-methylcytosine (mCyt) in the human genome. Guanine in this context can be easily oxidized to 8-oxoguanine (oxoGua), which is repaired by 8-oxoguanine-DNA glycosylase (OGG1). We have studied how methylation affects the efficiency of oxoGua excision from damaged CpG dinucleotides. Methylation of the adjacent cytosine moderately decreased the oxoGua excision rate while methylation opposite oxoGua lowered the rate of product release. Cytosine methylation abolished stimulation of OGG1 by repair endonuclease APEX1. The OGG1 S326C polymorphic variant associated with lung cancer showed poorer base excision and lost sensitivity to the opposite-base methylation. The overall repair in the system reconstituted from purified proteins decreased for CpG with mCyt in the damaged strand.     

Unmethylated and methylated CpG dinucleotides distinctively regulate the physical properties of DNA

In eukaryotic cells, DNA has to bend significantly to pack inside the nucleus. Physical properties of DNA such as bending flexibility and curvature are expected to affect DNA packaging and partially determine the nucleosome positioning patterns inside a cell. DNA CpG methylation, the most common epigenetic modification found in DNA, is known to affect the physical properties of DNA. However, its detailed role in nucleosome formation is less well‐established. In this study, we evaluated the effect of defined CpG patterns (unmethylated and methylated) on DNA structure and their respective nucleosome‐forming ability. Our results suggest that the addition of CpG dinucleotides, either as a (CG)_n stretch or (CGX₈)_n repeats at 10 bp intervals, lead to reduced hydrodynamic radius and decreased nucleosome‐forming ability of DNA. This effect is more predominant for a DNA stretch ((CG)₅) located in the middle of a DNA fragment. Methylation of CpG sites, surprisingly, seems to reduce the difference in DNA structure and nucleosome‐forming ability among DNA constructs with different CpG patterns. Our results suggest that unmethylated and methylated CpG patterns can play very different roles in regulating the physical properties of DNA. CpG methylation seems to reduce the DNA conformational variations affiliated with defined CpG patterns. Our results can have significant bearings in understanding the nucleosome positioning pattern in living organisms modulated by DNA sequences and epigenetic features. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 517–524, 2014.     

CpG dinucleotides in the hMSH2 and hMLHI genes are hotspots for HNPCC mutations

Hereditary nonpolyposis colon cancer (HN-PCC) is an autosomally inherited predisposition to cancer that has recently been linked to defects in the human mismatch repair genes hMSH2 and hMLHI. The identification of the causative mutations in HNPCC families is desirable, since it confirms the diagnosis and allows the carrier status of unaffected relatives at risk to be determined. We report six different new mutations identified in the hMSH2 and hMLH1 genes of Russian and Moldavian HNPCC families. Three of these mutations occur in CpG dinucleotides and lead to a premature stop codon, a splicing defect or an amino-acid substitution in an evolutionary conserved residue. Analysis of a compilation of published mutations including our new data suggests that CpG dinucleotides within the coding regions of the hMSH2 and hMLH1 genes are hotspots for single base-pair substitutions.     

Methylation of CpG dinucleotides in the lacI gene of the Big Blue® transgenic mouse

Cytosine residues at CpG dinucleotides can be methylated by endogenous methyltransferases in mammalian cells. The resulting 5-methylcytosine base may undergo spontaneous deamination to form thymine causing G/C to A/T transition mutations. Methylated CpGs also can form preferential targets for environmental mutagens and carcinogens. The Big Blue® transgenic mouse has been used to investigate tissue and organ specificity of mutations and to deduce mutational mechanisms in a mammal in vivo. The transgenic mouse contains approximately 40 concatenated lambda-like shuttle vectors, each of which contains one copy of an Escherichia coli lacI gene as a mutational target. lacI mutations in lambda transgenic mice are characterized by a high frequency of spontaneous mutations targeted to CpG dinucleotides suggesting an important contribution from methylation-mediated events. To study the methylation status of CpGs in the lacI gene, we have mapped the distribution of 5-methylcytosines along the DNA-binding domain and flanking sequences of the lacI gene of transgenic mice. We analyzed genomic DNA from various tissues including thymus, liver, testis, and DNA derived from two thymic lymphomas. The mouse genomic DNAs and methylated and unmethylated control DNAs were chemically cleaved, then the positions of 5-methylcytosines were mapped by ligation-mediated PCR which can be used to distinguish methylated from unmethylated cytosines. Our data show that most CpG dinucleotides in the DNA binding domain of the lacI gene are methylated to a high extent (>98%) in all tissues tested; only a few sites are partially (70–90%) methylated. We conclude that tissue-specific methylation is unlikely to contribute significantly to tissue-specific mutational patterns, and that the occurrence of common mutation sites at specific CpGs in the lacI gene is not related to selective methylation of only these sequences. The data confirm previous suggestions that the high frequency of CpG mutations in lacI transgenes is related to the presence of 5-methylcytosine bases.     

The Effect of DNA CpG Methylation on the Dynamic Conformation of a Nucleosome

DNA methylation is an important epigenetic mark that is known to induce chromatin condensation and gene silencing. We used a time-domain fluorescence lifetime measurement to quantify the effects of DNA hypermethylation on the conformation and dynamics of a nucleosome. Nucleosomes reconstituted on an unmethylated and a methylated DNA both exhibit dynamic conformations under physiological conditions. The DNA end breathing motion and the H2A-H2B dimer destabilization dominate the dynamic behavior of nucleosomes at low to medium ionic strength. Extensive DNA CpG methylation, surprisingly, does not help to restrain the DNA breathing motion, but facilitates the formation of a more open nucleosome conformation. The presence of the divalent cation, Mg²⁺, essential for chromatin compaction, and the methyl donor molecule SAM, required for DNA methyltransferase reaction, facilitate the compaction of both types of nucleosomes. The difference between the unmethylated and the methylated nucleosome persists within a broad range of salt concentrations, but vanishes under high magnesium concentrations. Reduced DNA backbone rigidity due to the presence of methyl groups is believed to contribute to the observed structural and dynamic differences. The observation of this study suggests that DNA methylation alone does not compact chromatin at the nucleosomal level and provides molecular details to understand the regulatory role of DNA methylation in gene expression.     

The organisation and expression of histone genes from Xenopus borealis.

We have isolated genomic clones from Xenopus borealis representing 3 different types of histone gene cluster. We show that the major type (H1, H2B, H2A, H4, H3), present at about 60-70 copies per haploid genome (1), is tandemly reiterated with a repeat length of 15 kb. In situ hybridization to mitotic chromosomes shows that the majority of histone genes in Xenopus borealis are at one locus. This locus is on the long arm of one of the small sub-metacentric chromosomes. A minor cluster type with the gene order H1, H3, H4, H2A is present at about 10-15 copies. The genome also contains rare or unique cluster types present at less than 5 copies having other types of organisation. An isolate of this type had the gene order H1, H4, H2B, H2A, H1 (no H3 cloned). Microinjection of all of the clones into Xenopus laevis oocyte nuclei shows that most of the genes present are functional or potentially functional and a number of variant histone proteins have been observed. S1 mapping experiments confirm that the genes of the major cluster are expressed in all tissues and at all developmental stages examined.     

On the mechanism of interaction between histone I and DNA and histone III and DNA

A mechanism is suggested at the molecular level whereby histone I can act as a cross-link, or strut, between two DNA strands involved in packing the DNA molecule into the confined space of the chromosome. The amino acid sequence of the N-terminal region is known (to 72). It is suggested that this portion is composed of three main functionally distinct segments: (1) (amino acids 1–18) that forms a broken a-helix (by pro) packed into the depths of the major groove; (2) (amino acids 19–35), rich in lys, which forms a “roof” over segment (1) with nine ionic bonds to phosphate; and (3) (amino acids 41–69) which forms an a-helix. Thus segments (1) and (2) grip the DNA helix and segment (3) forms a strut between two DNA strands. Presumably the rest of the histone molecule forms a second lys-rich “hand” grasping the second DNA helix.The amino acid sequence of histone III suggests that it provides a variant on this thesis. In this case the ionic links to phosphate and the packing of the major groove are provided by successive segments of the protein (e.g. a sequence -arg-lys- followed by a β-turn or a short segment of a-helix). This covers amino acids 1–87. The next segment (88–114) forms an a-helix and the last segment (115–135) repeats the structure of the first segment. Thus histone III might also form cross-links between two parallel DNA strands but its attachment is markedly asymmetrical with one “hand” composed of 87 amino acids filling over $\text{1}\text{1}\text{2}$ turns of the major groove and the other “hand” composed of only 20 amino acids.     

Study of Tissue-Specific CpG Methylation of DNA in Extended Genomic Loci

Modern approaches for studies on genome functioning include investigation of its epigenetic regulation. Methylation of cytosines in CpG dinucleotides is an inherited epigenetic modification that is responsible for both functional activity of certain genomic loci and total chromosomal stability. This review describes the main approaches for studies on DNA methylation. Under consideration are site-specific approaches based on bisulfite sequencing and methyl-sensitive PCR, whole-genome approaches aimed at searching for new methylation hot spots, and also mapping of unmethylated CpG sites in extended genomic loci.