Variation of cytosine methylation in 57 sweet orange cultivars

Sweet orange is an important group of citrus cultivars, which includes a number of bud sport cultivars. Little is known about the CpG methylation status of the CCGG sequences in the orange genome. In this study, methylation-sensitive amplification polymorphism (MSAP), based on the application of isoschizomers (Hpa II and Msp I), was first used to analyze cytosine methylation patterns in 57 orange cultivars that were not fully differentiated by regular DNA molecular markers. Three types of bands were generated from ten primer pairs. Type I bands were present following restriction with Eco RI + Hpa II and Eco RI + Msp I; type II or type III were present only following restriction with either Eco RI + Hpa II or with Eco RI + Msp I. The total number of these three types of bands was 802, 72, and 157, respectively. Among these, the number of polymorphic bands were 244 (30.2%), 23 (31.9%), and 32 (20.4%), in type I, II and III, respectively. The methylation patterns of these 57 cultivars are discussed and assessed by dendrograms derived from the analysis of polymorphic MSAP bands. The distribution of polymorphic bands of the above three types demonstrate the methylation patterns and frequency at the cytosine loci. We suggest that methylation events could be more frequent than demethylation events, and that the methylation patterns maybe associated with phenotypic traits.     

Methylation and expression of a metallothionein promoter ovine growth hormone fusion gene (MToGH1) in transgenic mice

We have examined transgene methylation in the DNA from the livers of a pedigree of mice carrying three copies of an integrated MToGH1 transgene. Utilizing the methylation-sensitive isoschizomersMsp I andHpa II, Southern blot analysis revealed that all second generation animals derived from a transgenic female had hypermethylated DNA, whereas first generation animals sired by a transgenic male displayed a range of methylation phenotypes ranging from no methylation to hypermethylation of the transgene sequences. Of the mice that exhibited hypermethylation of the transgene in CpG dinucleotides (CmCGG), a minority of these animals also exhibited apparent CpC methylation (i.e. inhibition ofMsp I cutting, presumably blocked by methylation of the outer C of CCGG). Methylation was also examined in the inner C of CC(A/T)GG sequences in the MToGH1 transgene using the isoschizomer pairBstN I andEcoR II. A minority of MToGH1 animals in the F₁ generation showed clear evidence of methylation in these sites as well as in the inner and outer Cs of CCGG sites. An examination of MToGH1 expression in terms of oGH levels in serum revealed that there was a high degree of variation in the levels of circulating oGH between animals of this pedigree. There was a weak inverse relationship between the serum level of oGH and the extent of methylation of the transgene. In particular, mice exhibiting CpC together with CpG methylation were found to have very low levels of circulating oGH. Our results highlight the nature and complexity of epigenetic factors associated with transgene sequences which may ultimately influence expression of introduced genes in the mammalian genome.     

Tissue culture-induced locus-specific alteration in DNA methylation and its correlation with genetic variation in <Emphasis Type="Italic">Codonopsis lanceolata</Emphasis> Benth. et Hook. f

We have reported recently that tissue culture induced a high level of genetic variation at the primary nucleotide sequence in regenerants of medicinal plant Codonopsis lanceolata. It is not known, however, whether epigenetic variation in the form of alteration in DNA methylation also occurred in these plants. Here, we investigated possible alterations in level and pattern of cytosine methylation at the CCGG sites in the same set of regenerants relative to the donor plant, by the MSAP method employing a pair of isoschizomers, HpaII and MspI, which recognize the same restriction site but are differentially sensitive to cytosine methylation at the CCGG sites. A total of 1,674 MSAP profiles were resolved using 39 primer combinations. Of these, 177 (10.5%) profiles were polymorphic among the regenerants and/or between the regenerant(s) and the donor plant, in EcoRI + HpaII or EcoRI + MspI digest but not in both, indicating alteration in cytosine methylation patterns of specific loci, though their estimated total level of methylation remained more or less the same as the donor plant. Gel blot analysis validated most of the variant MSAP profiles as bona fide alteration in methylation patterns. Correlation analysis between the MSAP data and the previously reported ISSR and RAPD data revealed significant correlations, suggesting their possible intrinsic interrelatedness. Thirty-seven typical variant MSAP profiles were isolated and sequenced, of which 5 showed significant homology to known-function genes, 2 to chloroplast sequences, whilst the rest 30 did not find a match in the database. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. W. L. Guo and R. Wu contributed equally to this work.     

Hypermethylation of tobacco heterochromatic loci in response to osmotic stress

 Plants have to cope with a number of envi-ronmental stresses which may potentially induce genetic and epigenetic changes and thus contribute to genome variability. In the present study we inspected the DNA methylation status of two heterochromatic loci (defined with repetitive DNA sequences HRS60 and GRS) in a tobacco cell culture exposed to osmotic stress. Investigations were performed on a TBY-2 cell suspension culture, and the stress was elicited with NaCl or D-mannitol. Using the restriction enzymes MspI/HpaII and MboI/Sau3AI in combination with Southern hydridization we observed a reversible hypermethylation of the external cytosine at the CpCpG trinucleotides in cells grown under mild osmotic stress equal to a NaCl concentration of 10 g/l. There were no changes in the methylation of the internal cytosine as the CpG dinucleotides within the CCGG motifs (HpaII sites) appeared to be fully methylated in tobacco DNA repetitive sequences under normal physiological conditions. The data suggest epigenetic changes in the plant genome based on de novo methylation of DNA in response to environmental stress. Received: 26 November 1996/Accepted: 20 December 1996     

DNA methylation profiles differ between field- andin vitro-grown leaves of apple

A reliable method has been previously developed to detect cytosine methylation at the 5′-CCGG-3′ sequence using isoschizomers (Msp I and Hpa II) and a modified amplified fragment length polymorphism (AFLP) technique. With this method, DNA methylation profiles were investigated in leaf tissues of apple (Malus × domestica cv. Gala) grown under two different growth conditions, field and tissue culture. A total of 1,622 AFLP bands were detected using 32 pairs of primers, and these banding patterns were assembled into three groups. Type I AFLP bands were present in both EcoR I/Hpa II and EcoR I/Msp I lanes. Type II bands were present in the EcoR I/Msp I lanes, but not in EcoR I/Hpa II lanes. Type III bands were present in EcoR I/Hpa II lanes, but not in the EcoR I/Msp I lanes. For leaf tissues of field- and in vitro-grown apples, the ratios of types I, II, and III to the total number of amplified fragments were 70 %, 24 %, and 6 %, and 71 %, 23 %, and 6 %, respectively. Although the ratios of the three types of banding patterns were similar in both leaf tissues, a few bands specific to either field-grown trees or in vitro-grown shoots were observed. This study provided evidence that changes in methylation occurred in apple leaf tissues subjected to tissue culture growth conditions.     

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.     

DNA Methylation Occurred around Lowly Expressed Genes of Plastid DNA during Tomato Fruit Development

We have analyzed DNA methylation of plastid DNA from fully ripened red fruits, green mature fruits, and green leaves of tomato (Lycopersicon esculentum var. Firstmore). Essentially identical restriction profiles were obtained between chromoplast and chloroplast DNAs by EcoRI digestion. BstNI/EcoRII and HpaII/MspI are pairs of isoschizomers that can discriminate between methylated and unmethylated DNAs. These endonucleases produced different restriction patterns of plastid DNAs from tomato fruits compared to tomato leaves. Moreover, we have found from Southern blots that methylation was not detected in DNA fragments containing certain genes that are actively expressed in chromoplasts, whereas DNA fragments bearing genes that are barely transcribed in chromoplasts are methylated.     

Isolation of Plant Gene Space-Related Sequence Elements by High C+G Patch (HCGP) Filtration: Model Study on Rice

For the isolation of gene space representative sequence elements, a new methodology—high C+G patch (HCGP) filtration—has been developed using rice as a model. The method is based on the fragmentation of the genomic DNA by methylation-sensitive HpaII and MspI restriction endonucleases having exclusively G/C base pair-containing recognition sites. These enzymes fragment the genome at high C+G content and hypomethylated regions. Cloning fragments spanning such regions in close vicinity (200–2,000 bp) revealed that about 60% of the clones represented gene space sequences resulting in twofold enrichment of these sequences, which is close to the theoretical maximum in rice. The sequence information of clones used in the present study was deposited in the NCBI database under the accession numbers EI 365676–EI 366364.     

The Genome of the Lepidopteran Mamestra brassicae has a Vertebrate-like Content of Methyl-cytosine

Mamestra brassicae genomic DNAs, isolated from larvae and adult tissues and from in vitro cultured CRL-8003 cells, were enzymatically hydrolysed to nucleosides that were separated by HPLC. HPLC analysis showed that 5mC content in cabbage moth larvae, adults and cultured cells was 8.9±0.5, 9.3%±0.2 and 10.2%±0.4 respectively. Cabbage moth 5mC content results the highest reported till now in insects and it is similar to the typical vertebrate one. Analysis of MspI and HpaII restriction pattern on M. brassicae DNA showed that a portion of its genome was methylated at CpG sites. Moreover, the absence of small digestion products after MspI digestion suggested that CpG are not clustered in the cabbage moth genome. Finally, methylation of repeated DNAs has been studied. Comparison of the restriction pattern of MspI and HpaII after hybridisation with the hobo, mariner, 28S and 5S rDNA probes did not evidence any difference indicating the absence of CpG methylation in all the studied repeated DNAs.     

CpG islands detected by self-primed in situ labeling (SPRINS)

We have studied the distribution and methylation of CpG islands on human chromosomes, using the novel technique of self-primed in situ labeling (SPRINS). The SPRINS technique is a hybrid of the two techniques primed in situ labeling (PRINS) and nick translation in situ. SPRINS detects chromosomal DNA breaks, as in nick translation in situ, and not annealed primers, as is the case in PRINS. We analyzed in situ-generated DNA breaks induced by the restriction enzymes HpaII and MspI. These restriction enzymes enable the detection of chromosomal CpG islands. Both HpaII- and MspI-SPRINS produce a banding pattern resembling R-banding, indicating a higher level of CpG islands in R-positive bands than in R-negative bands. Our SPRINS banding observations also indicate differences in sequence copy number in the satellites of homologous acrocentric chromosomes. Furthermore, a comparison of homologous HpaII-SPRINS-banded X chromosomes of females from lymphocyte cultures grown without methotrexate or bromodeoxyuridine revealed methylation difference between them. The same comparison of homologous X chromosomes from the cell line GM01202D, which has four X chromosomes, one active and three inactive, revealed the active X chromosome to be hypermethylated. Received: 5 February 1998; in revised form: 8 May 1998 / Accepted: 11 May 1998     

Unmethylated regions in the intergenic spacer of maize and teosinte ribosomal RNA genes

The restriction endonucleases Hpa II and Msp I were used to examine cytosine methylation in the ribosomal RNA genes (rDNA) of inbred lines of maize and species of teosinte. In all of the rDNAs examined, Msp I (not sensitive to mCpG) digestion yielded a distribution of lower molecular weight fragments indicative of multiple recognition sites. The majority of the rDNA arrays in an individual were inaccessible to Hpa II (sensitive to mCpG) cleavage, but a significant fraction (10–25%) was cleaved at least once by Hpa II into repeat unit length fragments (9.1 kbp). In some maize inbred lines, one or two additional fragment populations (less than 9.1 kbp in length) were also produced by Hpa II digestion. All of the unmethylated Hpa II sites mapped to the intergenic spacer (IGS), and the major unmethylated site was located approximately 800 bp 5 to the start of the 18S RNA coding sequence. An Eco RI polymorphism, present in the 26S gene of certain inbred lines and hybrids, was utilized to investigate the organization of unmethylated repeat units in the rDNA array. In double digest experiments with Hpa II/Eco RI, the fragments from repeat units with two Eco RI sites were sensitive to Hpa II digestion, whereas, the fragments from repeat units with a single Eco RI site were almost completely resistant to Hpa II digestion. Similar digestion patterns were also observed in Eco RII (sensitive to mCNG)/Eco RI digests. These results suggest that unmethylated and Eco RI polymorphic sites occur in the same repeat units.     

Evaluation of Genetic and Epigenetic Modification in Rapeseed （Brassica napus） Induced by Salt Stress

Salinity is an important limiting environmental factor for rapeseed production worldwide. In this study, we assessed the extent and pattern of DNA damages caused by salt stress in rapeseed plants. Amplified fragment length polymorphism （AFLP） analysis revealed dose-related increases in sequence alterations in plantlets exposed to 10-1000 mmol/L sodium chloride. In addition, individual plantlets exposed to the same salt concentration showed different AFLP and selected region amplified polymorphism banding patterns. These observations suggested that DNA mutation in response to salt stress was random in the genome and the effect was dose-dependant. DNA methylation changes in response to salt stress were also evaluated by methylation sensitive amplified polymorphism （MSAP）. Three types of MSAP bands were recovered. Type Ⅰ bands were observed with both isoschizomers Hpa Ⅱ and Msp Ⅰ, while type Ⅱ and type Ⅲ bands were observed only with Hpa Ⅱ and Msp Ⅰ, respectively. Extensive changes in types of MSAP bands after NaCI treatments were observed, including appearance and disappearance of type Ⅰ, Ⅱ and Ⅲ bands, as well as exchanges between either type Ⅰand type Ⅱ or type Ⅰ and type Ⅲ bands. An increase of 0.2-17.6% cytosine methylated CCGG sites were detected in plantlets exposed to 10- 200 mmol/L salt compared to the control, and these changes included both de novo methylation and demethylation events. Nine methylation related fragments were also recovered and sequenced, and one sharing a high sequence homology with the ethylene responsive element binding factor was identified. These results demonstrated clear DNA genetic and epigenetic alterations in planUets as a response to salt stress, and these changes may suggest a mechanism for plants adaptation under salt stress.     

mCCG methylation in angiosperms

Two different methods were used to investigate the abundance of cytosine methylation at the outer (5′) position in 5′-CCG-3′ trinucleotides in angiosperm genomes. Mspl is unable to cut its target site if the outer cytosine is methylated (5′-^mCCGG-3′). Using Mspl restriction analysis, it was shown that 5′-^mCCG-3′ is present in all angiosperm genomes examined, and that the amount of cytosine methylation at this site varies between species. Subsequently, direct measurements were made of the amount of methylation at both cytosines in a subset of 5′-CCG-3′ trinucleotides in the Arabidopsis thaliana genome. Based upon these analyses, it was estimated that approximately 20–30% of 5′-CCG-3′ trinucleotides in A. thaliana are methylated at the outer cytosine. Approximately 20% of the 5′-CCG-3′ trinucleotides contain 5-methyl-cytosine at the inner cytosine position, which corresponds to a previous determination of 5′-^mCG-3′ methylation in A. thaliana. The implications of 5′-^mCCG-3′ methylation are discussed.     

Methylation sites in angiosperm genes

Summary The extent to which CpG dinucleotides were depleted in a large set of angiosperm genes was, on average, very similar to the extent of CpG depletion in total angiosperm genomic DNA and far less than the extent of CpG depletion in vertebrate genes. Gene sequences from Arabidopsis thaliana, a dicotyledonous species with relatively low levels of total 5-methylcytosine, were just as CpG depleted as the angiosperm genes in general. Furthermore, levels of TpG and CpA, the potential deamination mutation products of methylated CpG, were elevated in A. thaliana genes, supporting a high rate of deamination mutation as the cause of the CpG deficiency. Using a method that takes into account the dinucleotide frequencies within each sequence of interest, we calculated the expected frequencies of CpNpG trinucleotides, which are also highly methylated in angiosperm genomes. CpNpG trinucleotides were not extensively enriched or depleted in the angiosperm genes. Two hypotheses could account for our results. Differential depletion of CpG and CpNpG within angiosperm genes and differential depletion of CpG in angiosperm and vertebrate genes could arise from different efficiencies of mismatch repair or from different levels of cytosine methylation in the cell lineages that contribute to germ cells.Offprint requests to: M. Gardiner-Garden     

Tissue culture-induced DNA methylation polymorphisms in repetitive DNA of tomato calli and regenerated plants

The propagation of plants through tissue culture can induce a variety of genetic and epigenetic changes. Variation in DNA methylation has been proposed as a mechanism that may explain at least a part of these changes. In the present study, the methylation of tomato callus DNA was compared with that of leaf DNA, from control or regenerated plants, at MspI/HpaII sites around five middle-repetitive sequences. Although the methylation of the internal cytosine in the recognition sequence CCGG varied from zero to nearly full methylation, depending on the probe used, no differences were found between callus and leaf DNA. For the external cytosine, small differences were revealed between leaf and callus DNA with two probes, but no polymorphisms were detected among DNA samples of calli or DNA samples of leaves of regenerated plants. When callus DNA cut with HindIII was studied with one of the probes, H9D9, most of the signal was found in high-molecular-weight DNA, as opposed to control leaf DNA where almost all the signal was in a fragment of 530 bp. Also, an extra fragment of 630 bp was found in the callus DNA that was not present in control leaf DNA. Among leaves of plants regenerated from tissue culture, the 630-bp fragment was found in 10 of 68 regenerated plants. This 630-bp fragment was present among progeny of only 4 of these 10 plants after selfing, i.e. it was partly inherited. In these cases, the fragment was not found in all progeny plants, indicating heterozygosity of the regenerated plants. The data are interpreted as indicating that a HindIII site becomes methylated in callus tissue, and that some of this methylation persists in regenerated plants and is partly transmitted to their progeny.     

Analysis of DNA methylation patterns of PLBs derived from <Emphasis Type="Italic">Cymbidium hybridium</Emphasis> based on MSAP

The best known and most thoroughly studied epigenetic phenomenon is DNA methylation, which plays an important role in regulating gene expression during plant regeneration and development. In this study, the methylation-sensitive amplified polymorphism (MSAP) technique was carried out to determine differences in methylation profiles between two forms of protocorm-like bodies (PLBs), continuously proliferating PLBs (cPLBs) and spontaneously-differenting PLBs (sdPLBs), derived from cultures of Cymbidium hybridium. A total of 72 selective primer combinations were used to assess the status of cytosine methylation of DNA in these tissues. Of 4,440 fragments obtained 911 fragments, each representing a recognition site cleaved by one or both of the isoschizomers (Hpa II and Msp I), were amplified and were significantly different between the two forms of PLBs. Frequency of total and full-methylation of cPLBs and sdPLBs were 26.7/12.2%, 24.1/11.1%, respectively. In addition, 14 types of MSAP patterns detected in the two forms of PLBs belonged to two classes, type I and II. Sequencing of 14 differentially methylated fragments and their subsequent blast search revealed that cytosine methylated 5′-CCGG-3′ sequences were equally distributed in the coding and non-coding regions. Southern blotting was conducted to verify the methylation polymorphism.     

CpG + CpNpG analysis of protein-coding sequences from tomato

We develop codon-based models for simultaneously inferring the mutational effects of CpG and CpNpG methylation in coding regions. In a data set of 369 tomato genes, we show that there is very little effect of CpNpG methylation but a strong effect of CpG methylation affecting almost all genes. We further show that the CpNpG and CpG effects are largely uncorrelated. Our results suggest different roles of CpG and CpNpG methylation, with CpNpG methylation possibly playing a specialized role in defense against transposons and RNA viruses.     

Plant DNA methyltransferases

DNA methylation is an important modification of DNA that plays a role in genome management and in regulating gene expression during development. Methylation is carried out by DNA methyltransferases which catalyse the transfer of a methyl group to bases within the DNA helix. Plants have at least three classes of cytosine methyltransferase which differ in protein structure and function. The METI family, homologues of the mouse Dnmt1 methyltransferase, most likely function as maintenance methyltransferases, but may also play a role in de novo methylation. The chromomethylases, which are unique to plants, may preferentially methylate DNA in heterochromatin; the remaining class, with similarity to Dnmt3 methyltransferases of mammals, are putative de novo methyltransferases. The various classes of methyltransferase may show differential activity on cytosines in different sequence contexts. Chromomethylases may preferentially methylate cytosines in CpNpG sequences while the Arabidopsis METI methyltransferase shows a preference for cytosines in CpG sequences. Additional proteins, for example DDM1, a member of the SNF2/SWI2 family of chromatin remodelling proteins, are also required for methylation of plant DNA.