Inheritance and Variation of Cytosine Methylation in Three Populus Allotriploid Populations with Different Heterozygosity

DNA methylation is an epigenetic mechanism with the potential to regulate gene expression and affect plant phenotypes. Both hybridization and genome doubling may affect the DNA methylation status of newly formed allopolyploid plants. Previous studies demonstrated that changes in cytosine methylation levels and patterns were different among individual hybrid plant, therefore, studies investigating the characteristics of variation in cytosine methylation status must be conducted at the population level to avoid sampling error. In the present study, an F1 hybrid diploid population and three allotriploid populations with different heterozygosity [originating from first-division restitution (FDR), second-division restitution (SDR), and post-meiotic restitution (PMR) 2n eggs of the same female parent] were used to investigate cytosine methylation inheritance and variation relative to their common parents using methylation-sensitive amplification polymorphism (MSAP). The variation in cytosine methylation in individuals in each population exhibited substantial differences, confirming the necessity of population epigenetics. The total methylation levels of the diploid population were significantly higher than in the parents, but those of the three allotriploid populations were significantly lower than in the parents, indicating that both hybridization and polyploidization contributed to cytosine methylation variation. The vast majority of methylated status could be inherited from the parents, and the average percentages of non-additive variation were 6.29, 3.27, 5.49 and 5.07% in the diploid, FDR, SDR and PMR progeny populations, respectively. This study lays a foundation for further research on population epigenetics in allopolyploids.     

Cytosine Methylation Dysregulation in Neonates Following Intrauterine Growth Restriction

Background

Perturbations of the intrauterine environment can affect fetal development during critical periods of plasticity, and can increase susceptibility to a number of age-related diseases (e.g., type 2 diabetes mellitus; T2DM), manifesting as late as decades later. We hypothesized that this biological memory is mediated by permanent alterations of the epigenome in stem cell populations, and focused our studies specifically on DNA methylation in CD34+ hematopoietic stem and progenitor cells from cord blood from neonates with intrauterine growth restriction (IUGR) and control subjects.

Methods and Findings

Our epigenomic assays utilized a two-stage design involving genome-wide discovery followed by quantitative, single-locus validation. We found that changes in cytosine methylation occur in response to IUGR of moderate degree and involving a restricted number of loci. We also identify specific loci that are targeted for dysregulation of DNA methylation, in particular the hepatocyte nuclear factor 4α (HNF4A) gene, a well-known diabetes candidate gene not previously associated with growth restriction in utero, and other loci encoding HNF4A-interacting proteins.

Conclusions

Our results give insights into the potential contribution of epigenomic dysregulation in mediating the long-term consequences of IUGR, and demonstrate the value of this approach to studies of the fetal origin of adult disease.     

Myxosporea (Myxozoa,Cnidaria) Lack DNA Cytosine Methylation

DNA cytosine methylation is central to many biological processes, including regulation of gene expression, cellular differentiation, and development. This DNA modification is conserved across animals, having been found in representatives of sponges, ctenophores, cnidarians, and bilaterians, and with very few known instances of secondary loss in animals. Myxozoans are a group of microscopic, obligate endoparasitic cnidarians that have lost many genes over the course of their evolution from free-living ancestors. Here, we investigated the evolution of the key enzymes involved in DNA cytosine methylation in 29 cnidarians and found that these enzymes were lost in an ancestor of Myxosporea (the most speciose class of Myxozoa). Additionally, using whole-genome bisulfite sequencing, we confirmed that the genomes of two distant species of myxosporeans, Ceratonova shasta and Henneguya salminicola, completely lack DNA cytosine methylation. Our results add a notable and novel taxonomic group, the Myxosporea, to the very short list of animal taxa lacking DNA cytosine methylation, further illuminating the complex evolutionary history of this epigenetic regulatory mechanism.     

Deoxyribonucleic Acid Adenine and Cytosine Methylation in Salmonella typhimurium and Salmonella typhi

The methylations of adenine in the sequence -GATC- and of the second cytosine in the sequence - [Formula: see text] - were studied in Salmonella typhimurium and in Salmonella typhi. The study was carried out by using endonucleases which restrict the plasmid pBR322 by cleavage at the sequences -GATC- (DpnI and MboI) and - [Formula: see text] - (EcoRII). The restriction patterns obtained for this plasmid isolated from transformed S. typhimurium and S. typhi were compared with those of pBR322 isolated from Escherichia coli K-12. In E. coli K-12, adenines at the sequence -GATC- and the second cytosines at - [Formula: see text] - are met hylated by enzymes coded for by the genes dam and dem, respectively. From comparison of the restriction patterns obtained, it is concluded that S. typhimurium and S. typhi contain genes responsible for deoxyribonucleic acid methylation equivalent to E. coli K-12 genes dam and dcm.     

Cytosine Methylation Effects on the Repair of O6-Methylguanines within CG Dinucleotides

O⁶-Alkyldeoxyguanine adducts induced by tobacco-specific nitrosamines are repaired by O⁶-alkylguanine DNA alkyltransferase (AGT), which transfers the O⁶-alkyl group from the damaged base to a cysteine residue within the protein. In the present study, a mass spectrometry-based approach was used to analyze the effects of cytosine methylation on the kinetics of AGT repair of O⁶-methyldeoxyguanosine (O⁶-Me-dG) adducts placed within frequently mutated 5′-CG-3′ dinucleotides of the p53 tumor suppressor gene. O⁶-Me-dG-containing DNA duplexes were incubated with human recombinant AGT protein, followed by rapid quenching, acid hydrolysis, and isotope dilution high pressure liquid chromatography-electrospray ionization tandem mass spectrometry analysis of unrepaired O⁶-methylguanine. Second-order rate constants were calculated in the absence or presence of the C-5 methyl group at neighboring cytosine residues. We found that the kinetics of AGT-mediated repair of O⁶-Me-dG were affected by neighboring 5-methylcytosine (^MeC) in a sequence-dependent manner. AGT repair of O⁶-Me-dG adducts placed within 5′-CG-3′ dinucleotides of p53 codons 245 and 248 was hindered when ^MeC was present in both DNA strands. In contrast, cytosine methylation within p53 codon 158 slightly increased the rate of O⁶-Me-dG repair by AGT. The effects of ^MeC located immediately 5′ and in the base paired position to O⁶-Me-dG were not additive as revealed by experiments with hypomethylated sequences. Furthermore, differences in dealkylation rates did not correlate with AGT protein affinity for cytosine-methylated and unmethylated DNA duplexes or with the rates of AGT-mediated nucleotide flipping, suggesting that ^MeC influences other kinetic steps involved in repair, e.g. the rate of alkyl transfer from DNA to AGT.Metabolic activation of the tobacco carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK)³ produces methyl- and pyridyloxobutyldiazonium ions that can react with DNA to give O⁶-methyldeoxyguanosine (O⁶-Me-dG) and O⁶- pyridyloxobutyl deoxyguanosine (O⁶-POB-dG) lesions (1). Both adducts are strongly mutagenic because DNA polymerases preferentially misinsert thymine opposite O⁶-alkylguanines, resulting in G → A transitions (2). Studies in laboratory animals have provided evidence for a direct involvement of O⁶-Me-dG in NNK-mediated carcinogenesis (3).A specialized repair protein, O⁶-alkylguanine DNA alkyltransferase (AGT), removes the alkyl group from the O⁶ position of modified guanine bases, such as O⁶-Me-dG and O⁶-POB-dG, restoring normal guanine bases and preventing mutagenesis. AGT preferentially binds double-stranded DNA through a helix-turn-helix motif (4). In the resulting AGT-DNA complex, one recognition helix of the protein is found within the minor groove of the DNA, whereas the other one interacts with the phosphodiester backbone (4). The adducted nucleotide is flipped into a binding pocket within the protein, whereas Arg-128 takes its place in the double helix (4). A hydrogen bonding network around the active site involving His-148, Glu-172, and a water molecule promotes the deprotonation of the active site cysteine (Cys-145) (4, 5). The resulting thiolate anion acts as a nucleophile, displacing the O⁶ substituent of O⁶-alk-G and regenerating normal guanine (Fig. 1) (4, 5). The alkylated protein is inactive and is rapidly degraded by the ubiquitin proteolytic pathway (6–8).Open in a separate windowFIGURE 1.Direct repair of O⁶-alkyl-guanine adducts by AGT.AGT-mediated repair of O⁶-Me-dG lesions includes multiple kinetic steps (9). First, the AGT protein must bind adducted DNA in a reactive conformation. The alkylated nucleotide is flipped out of the DNA base stack to enter the hydrophobic pocket within AGT, and the methyl group is transferred from DNA to the protein. Finally, alkylated AGT protein dissociates from the repaired DNA. Zang et al. (9) reported that the chemical step of alkyl transfer is rate-limiting in the case of O⁶-Me-dG, but not O⁶-benzyl-dG. Furthermore, previous studies have shown that the repair of O⁶-Me-dG by mammalian AGT is influenced by the nature of the O⁶-alkyl group, the length of oligonucleotide duplex, the placement of the adduct, and the identities of neighboring nucleotides (10–14).Removing the alkyl group from O⁶-Me-dG by AGT regenerates normal guanine and protects the genome from G → A transition mutations. For example, Wolf et al. (15) examined the relationship between the inactivation of the AGT gene by promoter hypermethylation and the mutational spectrum of the p53 tumor suppressor gene in non-small cell lung cancer. These authors found that only 8% of lung tumors had G → A transition mutations in the p53 gene when the promoter region of the gene coding for AGT was not methylated, thereby allowing protein expression (15). In contrast, 33% of tumors with a methylated AGT promoter had G → A mutations within the p53 gene (15). The p53 gene is mutated in over 50% of non-small cell lung cancer tumors (16).All CpG sites within the coding sequence of the p53 gene are endogenously methylated (17). Importantly, the same sites are among the major p53 mutational “hotspots” in smoking-induced lung cancer, e.g. codons 157, 158, 245, 248, 249, and 273 (18). Of all p53 mutations, G → A transitions account for 18–24% of genetic changes observed in lung cancer, including 35% of mutations at the CG dinucleotides (15, 19). Given the established role of NNK-induced O⁶-alkylguanine lesions in tobacco carcinogenesis and mutagenesis (20), they are likely to be involved in the induction of smoking-associated G → A transitions in the p53 gene.The presence of ^MeC residues may hinder the repair of O⁶-Me-dG lesions within endogenously methylated CG dinucleotides (14). For example, Bentivenga and Bresnick (14) showed that the repair of O⁶-Me-dG by recombinant AGT in the context of codon 248 of the p53 gene was reduced by 75% when ^MeC was placed immediately 5′ to the O⁶-Me-dG lesion. However, the effects of cytosine methylation on AGT repair of O⁶-Me-dG in other sequence contexts have not been previously investigated, and it is not known which individual steps in the removal of O⁶-methyl group are affected by neighboring ^MeC.Cytosine methylation leads to small structural changes of DNA duplex, including an increase in the base pair rise, roll, and local curvature angles, narrowing of the DNA minor groove, and decreased depth of the major groove (21–23). These structural alterations may influence the affinity of the AGT protein for alkylated DNA. Furthermore, ^MeC enhances base stacking (24) and stabilizes the DNA duplex by increasing the molecular polarizability of the cytosine base (25), which can have an effect on the rate of AGT-mediated nucleotide flipping. The alkyl transfer step itself may be mediated by the presence of ^MeC through its effects on transition state geometry.The goal of the present study was to systematically examine the effects of cytosine methylation on AGT-mediated repair of O⁶-Me-dG lesions placed within 5′-CG-3′ dinucleotides representing major p53 mutational hotspots observed in lung cancer. The kinetics of alkyl transfer were analyzed using rapid-quench methods coupled with quantitative analyses of O⁶-Me-dG by isotope dilution-high performance liquid chromatography-electrospray ionization tandem mass spectrometry (HPLC-ESI-MS/MS) (26). Furthermore, we examined the effects of cytosine methylation on AGT binding to O⁶-Me-dG-containing DNA and its influence on the rate of O⁶-Me-dG nucleotide flipping in the presence of AGT protein.     

High-Speed Conversion of Cytosine to Uracil in Bisulfite Genomic Sequencing Analysis of DNA Methylation

Bisulfite genomic sequencing is a widely used technique foranalyzing cytosine-methylation of DNA. By treating DNA withbisulfite, cytosine residues are deaminated to uracil, whileleaving 5-methylcytosine largely intact. Subsequent PCR andnucleotide sequence analysis permit unequivocal determinationof the methylation status at cytosine residues. A major caveatassociated with the currently practiced procedure is that ittakes 16–20 hr for completion of the conversion of cytosineto uracil. Here we report that a complete deamination of cytosineto uracil can be achieved in shorter periods by using a highlyconcentrated bisulfite solution at an elevated temperature.Time course experiments demonstrated that treating DNA with9 M bisulfite for 20 min at 90°C or 40 min at 70°C allcytosine residues in the DNA were converted to uracil. Underthese conditions, the majority of 5-methylcytosines remainedintact. When a high molecular weight DNA derived from a cellline (containing a number of genes whose methylation statuswas known) was treated with bisulfite under the above conditionsand amplified and sequenced, the results obtained were consistentwith those reported in the literature. Although some degradationof DNA occurred during this process, the amount of treated DNArequired for the amplification was nearly equal to that requiredfor the conventional bisulfite genomic sequencing procedure.The increased speed of DNA methylation analysis with this novelprocedure is expected to advance various aspects of DNA sciences.     

Evolutionary Breakpoints in the Gibbon Suggest Association between Cytosine Methylation and Karyotype Evolution

Gibbon species have accumulated an unusually high number of chromosomal changes since diverging from the common hominoid ancestor 15–18 million years ago. The cause of this increased rate of chromosomal rearrangements is not known, nor is it known if genome architecture has a role. To address this question, we analyzed sequences spanning 57 breaks of synteny between northern white-cheeked gibbons (Nomascus l. leucogenys) and humans. We find that the breakpoint regions are enriched in segmental duplications and repeats, with Alu elements being the most abundant. Alus located near the gibbon breakpoints (<150 bp) have a higher CpG content than other Alus. Bisulphite allelic sequencing reveals that these gibbon Alus have a lower average density of methylated cytosine that their human orthologues. The finding of higher CpG content and lower average CpG methylation suggests that the gibbon Alu elements are epigenetically distinct from their human orthologues. The association between undermethylation and chromosomal rearrangement in gibbons suggests a correlation between epigenetic state and structural genome variation in evolution.     

Cytosine Methylation Alteration in Natural Populations of Leymus chinensis Induced by Multiple Abiotic Stresses

Background

Human activity has a profound effect on the global environment and caused frequent occurrence of climatic fluctuations. To survive, plants need to adapt to the changing environmental conditions through altering their morphological and physiological traits. One known mechanism for phenotypic innovation to be achieved is environment-induced rapid yet inheritable epigenetic changes. Therefore, the use of molecular techniques to address the epigenetic mechanisms underpinning stress adaptation in plants is an important and challenging topic in biological research. In this study, we investigated the impact of warming, nitrogen (N) addition, and warming+nitrogen (N) addition stresses on the cytosine methylation status of Leymus chinensis Tzvel. at the population level by using the amplified fragment length polymorphism (AFLP), methylation-sensitive amplified polymorphism (MSAP) and retrotransposon based sequence-specific amplification polymorphism (SSAP) techniques.

Methodology/Principal Findings

Our results showed that, although the percentages of cytosine methylation changes in SSAP are significantly higher than those in MSAP, all the treatment groups showed similar alteration patterns of hypermethylation and hypomethylation. It meant that the abiotic stresses have induced the alterations in cytosine methylation patterns, and the levels of cytosine methylation changes around the transposable element are higher than the other genomic regions. In addition, the identification and analysis of differentially methylated loci (DML) indicated that the abiotic stresses have also caused targeted methylation changes at specific loci and these DML might have contributed to the capability of plants in adaptation to the abiotic stresses.

Conclusions/Significance

Our results demonstrated that abiotic stresses related to global warming and nitrogen deposition readily evoke alterations of cytosine methylation, and which may provide a molecular basis for rapid adaptation by the affected plant populations to the changed environments.     

Analysis of Cytosine Methylation Pattern in Response to Water Deficit in Pea Root Tips

Abstract: The correlation between environmental stress and DNA methylation has been studied by following the methylation status of cytosine residues in the DNA of pea root tips exposed to water deficit. DNA methylation was evaluated by two complementary approaches: (i) immunolabelling by means of a monoclonal antibody against 5-methylcytosine; (ii) MSAP (Methylation-Sensitive Amplified Polymorphism) to verify if methylation and de-methylation in response to water deficit may be related to specific DNA sequences. Immunolabelling showed that water stress induces cytosine hypermethylation in the pea genome. Regarding the CCGG target sequence, an increase in methylation specifically in the second cytosine (about 40 % of total site investigated) was revealed by MSAP analyses. In addition, MSAP band profile detected in three independent repetitions was highly reproducible suggesting that, at least for the CCGG target sequence, methylation was addressed to specific DNA sequences.     

S-adenosylhomocysteine Hydrolase Participates in DNA Methylation Inheritance

DNA (cytosine-5) methyltransferase 1 (DNMT1) is essential for mammalian development and maintenance of DNA methylation following DNA replication in cells. The DNA methylation process generates S-adenosyl-l-homocysteine, a strong inhibitor of DNMT1. Here we report that S-adenosylhomocysteine hydrolase (SAHH/AHCY), the only mammalian enzyme capable of hydrolyzing S-adenosyl-l-homocysteine binds to DNMT1 during DNA replication. SAHH enhances DNMT1 activity in vitro, and its overexpression in mammalian cells led to hypermethylation of the genome, whereas its inhibition by adenosine periodate or siRNA-mediated knockdown resulted in hypomethylation of the genome. Hypermethylation was consistent in both gene bodies and repetitive DNA elements leading to aberrant gene regulation. Cells overexpressing SAHH specifically up-regulated metabolic pathway genes and down-regulated PPAR and MAPK signaling pathways genes. Therefore, we suggest that alteration of SAHH level affects global DNA methylation levels and gene expression.     

Cytosine Methylation Associated with Repeat-Induced Point Mutation Causes Epigenetic Gene Silencing in Neurospora Crassa

Repeated DNA sequences are frequently mutated during the sexual cycle in Neurospora crassa by a process named repeat-induced point mutation (RIP). RIP is often associated with methylation of cytosine residues in and around the mutated sequences. Here we demonstrate that this methylation can silence a gene located in nearby, unique sequences. A large proportion of strains that had undergone RIP of a linked duplication flanking a single-copy transgene, hph (hygromycin B phosphotransferase), showed partial silencing of hph. These strains were all heavily methylated throughout the single-copy hph sequences and the flanking sequences. Silencing was alleviated by preventing methylation, either by 5-azacytidine (5AC) treatment or by introduction of a mutation (eth-1) known to reduce intracellular levels of S-adenosylmethionine. Silenced strains exhibited spontaneous reactivation of hph at frequencies of 10(-4) to 0.5. Reactivated strains, as well as cells that were treated with 5AC, gave rise to cultures that were hypomethylated and partially hygromycin resistant, indicating that some of the original methylation was propagated by a maintenance mechanism. Gene expression levels were found to be variable within a population of clonally related cells, and this variation was correlated with epigenetically propagated differences in methylation patterns.     

Cytosine Methylation Changes in Rice Centromeric and Telomeric Sequences Induced by Foreign DNA Introgression

Cytosine methylation changes (hyper- or hypomethylation) in centromeric and telomeric sequences were observed in all three studied rice introgression lines containing DNA from wild rice, Zizania latifolia Griseb. The changed genomic Southern hybridization patterns were complex and non-concordant between a pair of isoschizomers (HpaII/MspI) digests, indicating methylation modifications at both the inner and outer cytosines of the CCGG sites. The changed patterns were inherited through generations. Possible mechanism for the methylation changes and their potential implications for the phenotypic variation and genome organization are discussed.