Inhibition of internode growth due to mechanical stress in Bryonia dioica: relationship between changes in DNA methylation and ethylene metabolism

Changes in the level of cytosine methylation were assessed by HPLC in mechanically stressed Bryonia dioica . Rubbing young internodes. which results in growth inhibition and ethylene production, induced a rapid and transient decrease of cytosine methylation in DNA. The level of cytosine methylation was about 25% in young internodes and dropped to nearly 0% in less than 1 h before increasing to the normal level within 3 h. A decreasing gradient of DNA methylation occurred naturally along the plant, from the apex to the base. The pool of S-adenosylmethionine was also measured in order to establish a possible relationship between ethylene metabolism and DNA methylation. The role of DNA methylation in gene regulation is discussed and different mechanisms for methylation are considered.     

Mutations in the dim-1 gene of Neurospora crassa reduce the level of DNA methylation

Mutants that show reduced DNA methylation were identified in a mutant screen based on the assumptions that (i) the nucleoside analog 5-azacytidine (5-azaC) promotes the formation of potentially lethal DNA-methyltransferase adducts; (ii) reduction in DNA methyltransferase will decrease the sensitivity of cells to 5-azaC; and (iii) this potential selective advantage will be enhanced in mutants that are deficient in the repair of 5-azaC-induced DNA damage. Of fifteen potential repair mutants screened for sensitivity to 5-azaC, five (mus-9, mus-10, mus-11, mus-18, and uvs-3) showed moderately increased sensitivity and two (mus-20, mei-3) showed highly increased sensitivity. A mus-20 mutation was used to isolate three non-complementing methylation mutants. The mutations, named dim-1 (defective in methylation), reduced female fertility, reduced methylation by 40–50%, and altered patterns of methylation. In wild-type strains hypomethylation perse fails to alter methylation specificity. We demonstrate a growth-phase-dependent change in methylation patterns, detectable only in hypomethylated DNA from dim ⁺ cultures. This may represent a growth-phase-dependent change in the relative amounts of distinct species of methyltransferase, one of which may be encoded by the dim-1 gene. Received: 3 January 1998 / Accepted: 26 March 1998     

DNA methylation levels in porcine fetal fibroblasts induced by an inhibitor of methylation, 5-azacytidine

Removal of the somatic DNA methylation pattern from donor cells and remodeling of embryonic status have been suggested as integral processes for successful nuclear transfer (NT) reprogramming. This study has investigated the effects of 5-azacytidine (5-azaC), a DNA methylation inhibitor, on global methylation changes in porcine fetal fibroblasts (PFF); this may improve NT attributable to the potential reprogramming of the methyl groups. PFF in 5th passage cultures were treated with 0, 0.5, 1.0, 2.0, and 3.0 μM 5-azaC for 96 h; 5-azaC inhibited the growth at all tested concentrations. At the higher concentrations of 5-azaC used, cells appeared to exhibit morphological changes and to become apoptotic as observed by TUNEL assay. Thus, cells were negatively affected by 5-azaC. Differences in cellular ploidy were also observed at higher concentrations. Analysis showed no considerable changes in the proportion of cells at the G₁-phase of the cell cycle with 5-azaC concentrations. The fractional part of the methylated DNA of these cells was significantly reduced by 5-azaC treatment. Confocal microscopy confirmed the inhibition of methylation levels in PFF with increased concentrations of 5-azaC. Exposure to 5-azaC altered the expression of genes involved in imprinting (IGF2) or pro-apoptosis (BAX), whereas there was a reduction in the expression of the main enzyme responsible for replicating the DNA methylation pattern (DNMT1) and anti-apoptosis (BCL2L1). Therefore, 5-azaC induces a relative reduction in methylation in PFF, and cells treated with 0.5 μM 5-azaC may have enhanced potential for porcine NT.The financial support of BioGreen 21 (grant no. 100052004002000) and KOSEF (grant no. R05-2004-000-10702-0) in Korea is gratefully acknowledged.     

Formation of embryogenic cell clumps from carrot epidermal cells is suppressed by 5-azacytidine, a DNA methylation inhibitor

Using a direct somatic embryogenesis system in carrot, we examined the role of DNA methylation in the change of cellular differentiation state, from somatic to embryogenic. 5-Azacytidine (aza-C), an inhibitor of DNA methylation suppressed the formation of embryogenic cell clumps from epidermal carrot cells. Aza-C also downregulated the expression of DcLEC1c, a LEC1-like embryonic gene in carrot, during morphogenesis of embryos. A carrot DNA methyltransferase gene, Met1-5 was expressed transiently after the induction of somatic embryogenesis by 2,4-dichlorophenoxyacetic acid (2,4-D), before the formation of embryogenic cell clumps. These findings suggested the significance of DNA methylation in acquiring the embryogenic competence in somatic cells in carrot.     

Changes in peroxidase activity,auxin level and ethylene production during root formation by poplar shoots raised in vitro

Shoots of poplar (Populus tremula × P. tremuloïdes) were multiplied in vitro and rooted on a rooting medium in the presence of NAA. No rooting occurred in the absence of exogenous auxin. A peak of soluble peroxidase activity, which corresponded to a decrease in the free IAA level in the shoots, preceded rooting These events were considered as corresponding to the initiative phase of rooting. They are preceded by a peak in free IAA activity which might initiate the inductive phase of the rooting process. A burst of ethylene production was measured in both rooting and non-rooting shoots, but the ethylene peak from rooting shoots appeared earlier and was higher. The use of ACC indicated that the exogenous auxin might have enhanced ACC-synthetase activity.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - NAA naphthaleneacetic acid - IAA indole-3-acetic acid - 2-iP 2-isopentenyladenine - IAAsp indole-3-acetylaspartic acid - IBA indole-3-butyric acid - GC gas-chromatography     

Effect of prolactin on DNA methylation in the liver and kidney of rat

Prolactin is an important growth modulatory hormone in fetal and adult tissues. It stimulates DNA synthesis and enzymatic markers of the G1 phase of cell cycle in rat liver and other tissues. In this study the effects of prolactin on 5-methyl cytosine content in liver and kidney of rats was studied using HPLC. Prolactin treatment caused hypomethylation of DNA in the liver and kidney of immature rats at 48 h after treatment and the effect remained even at 72 h. Prolactin also caused hypomethylation of DNA in the kidney and liver of adult rats at 48 h after treatment. These results indicate that prolactin probably regulates DNA methylation in the liver and kidney of immature and adult rats.     

The slender phenotype of pea: stem growth, peroxidase levels and ethylene responses

Stem elongation growth in a slender line of Pisum sativum L. was much greater than in its two dwarf parental lines due to a greater rate of production of longer internodes. The cellular basis of the greater length of slender internodes was tissue specific. In the epidermis, greater cell length primarily accounted for the longer internodes of the slender plants, but in the outer cortex, greater cell number was the more important factor. The soluble and salt-extractable peroxidase (EC 1.11.1.7) activities of expanding internodes were much lower in slender plants than in dwarf plants. The proportional effects of ethylene treatment on epicotyl length, diameter and orientation were similar in etiolated slender and dwarf seedlings.     

Studies on the activity and stability of immobilized horseradish peroxidase on poly(ethylene terephthalate) grafted acrylamide fiber

Having been activated with glutaraldehyde, modified poly(ethylene terephthalate) grafted acrylamide fiber was used for the immobilization of horseradish peroxidase (HRP). Both the free HRP and the immobilized HRP were characterized by determining the activity profile as a function of pH, temperature, thermal stability, effect of organic solvent and storage stability. The optimum pH values of the enzyme activity were found as 8 and 7 for the free HRP and the immobilized HRP respectively. The temperature profile of the free HRP and the immobilized HRP revealed a similar behaviour, although the immobilized HRP exhibited higher relative activity in the range from 50 to 60 °C. The immobilized HRP showed higher storage stability than the free HRP.     

Clinical and public health research using methylated DNA Immunoprecipitation (MeDIP): A comparison of commercially available kits to examine differential DNA methylation across the genome

The methylated DNA immunoprecipitation method (MeDIP) is a genome-wide, high-resolution approach that detects DNA methylation with oligonucleotide tiling arrays or high throughput sequencing platforms. A simplified high-throughput MeDIP assay will enable translational research studies in clinics and populations, which will greatly enhance our understanding of the human methylome. We compared three commercial kits, MagMeDIP Kit TM (Diagenode), Methylated-DNA IP Kit (Zymo Research) and Methylamp? Methylated DNA Capture Kit (Epigentek), in order to identify which one has better reliability and sensitivity for genomic DNA enrichment. Each kit was used to enrich two samples, one from fresh tissue and one from a cell line, with two different DNA amounts. The enrichment efficiency of each kit was evaluated by agarose gel band intensity after Nco I digestion and by reaction yield of methylated DNA. A successful enrichment is expected to have a 1:4 to 10:1 conversion ratio and a yield of 80% or higher. We also evaluated the hybridization efficiency to genome-wide methylation arrays in a separate cohort of tissue samples. We observed that the MagMeDIP kit had the highest yield for the two DNA amounts and for both the tissue and cell line samples, as well as for the positive control. In addition, the DNA was successfully enriched from a 1:4 to 10:1 ratio. Therefore, the MagMeDIP kit is a useful research tool that will enable clinical and public health genome-wide DNA methylation studies.     

Effects of cadmium on DNA-(Cytosine-5) methyltransferase activity and DNA methylation status during cadmium-induced cellular transformation

Cadmium is a human carcinogen that likely acts via epigenetic mechanisms. Since DNA methylation alterations represent an important epigenetic event linked to cancer, the effect of cadmium on DNA methyltransferase (MeTase) activity was examined using in vitro (TRL1215 rat liver cells) and ex vivo (M.SssI DNA MeTase) systems. Cadmium effectively inhibited DNA MeTases in a manner that was noncompetitive with respect to substrate (DNA), indicating an interaction with the DNA binding domain rather than the active site. Based on these results, the effects of prolonged cadmium exposure on DNA MeTase and genomic DNA methylation in TRL1215 cells were studied. After 1 week of exposure to 0-2.5 microM cadmium, DNA MeTase activity was reduced (up to 40%) in a concentration-dependent fashion, while genomic DNA methylation showed slight but significant reductions at the two highest concentrations. After 10 weeks of exposure, the cells exhibited indications of transformation, including hyperproliferation, increased invasiveness, and decreased serum dependence. Unexpectedly, these cadmium-transformed cells exhibited significant increases in DNA methylation and DNA MeTase activity. These results indicate that, while cadmium is an effective inhibitor of DNA MeTase and initially induces DNA hypomethylation, prolonged exposure results in DNA hypermethylation and enhanced DNA MeTase activity.     

Characterization of the level,target sites and inheritance of cytosine methylation in tomato nuclear DNA

The tomato nuclear genome was determined to have a G+C content of 37% which is among the lowest reported for any plant species. Non-coding regions have a G+C content even lower (32% average) whereas coding regions are considerably richer in G+C (46%).5-methyl cytosine was the only modified base detected and on average 23% of the cytosine residues are methylated. Immature tissues and protoplasts have significantly lower levels of cytosine methylation (average 20%) than mature tissues (average 25%). Mature pollen has an intermediate level of methylation (22%). Seeds gave the highest value (27%), suggesting de novo methylation after pollination and during seed development.Based on isoschizomer studies we estimate 55% of the CpG target sites (detected by Msp I/Hpa II) and 85% of the CpNpG target sites (detected by Bst NI/Eco RI)are methylated. Unmethylated target sites (both CpG and CpNpG) are not randomly distributed throughout the genome, but frequently occur in clusters. These clusters resemble CpG islands recently reported in maize and tobacco.The low G+C content and high levels of cytosine methylation in tomato may be due to previous transitions of 5mCT. This is supported by the fact that G+C levels are lowest in non-coding portions of the genome in which selection is relaxed and thus transitions are more likely to be tolerated. This hypothesis is also supported by the general deficiency of methylation target sites in the tomato genome, especially in non-coding regions.Using methylation isoschizomers and RFLP analysis we have also determined that polymorphism between plants, for cytosine methylation at allelic sites, is common in tomato. Comparing DNA from two tomato species, 20% of the polymorphisms detected by Bst NI/Eco RII could be attributed to differential methylation at the CpNpG target sites. With Msp I/Hpa II, 50% of the polymorphisms were attributable to methylation (CpG and CpNpG sites). Moreover, these polymorphisms were demonstrated to be inherited in a mendelian fashion and to co-segregate with the methylation target site and thus do not represent variation for transacting factors that might be involved in methylation of DNA. The potential role of heritable methylation polymorphism in evolution of gene regulation and in RFLP studies is discussed.     

Cell wall peroxidase activity,hydrogen peroxide level and NaCl-inhibited root growth of rice seedlings

The changes in cell-wall peroxidase (POD) activity and H₂O₂ level in roots of NaCl-stressed rice seedlings and their correlation with root growth were investigated. Increasing concentrations of NaCl from 50 to 150 mM progressively reduced root growth and increased ionically bound cell-wall POD activity. NaCl had no effect on covalently bound cell-wall POD activities. The reduction of root growth by NaCl is closely correlated with the increase in H₂O₂ level. Exogenous H₂O₂ was found to inhibit root growth of rice seedlings. Since ammonium and proline accumulation are associated with root growth inhibition caused by NaCl, we determined the effects of NH₄Cl or proline on root growth, cell-wall POD activity and H₂O₂level in roots. External application of NH₄Cl or proline markedly inhibited root growth, increased cell-wall POD activity and increased H₂O₂ level in roots of rice seedlings in the absence of NaCl. An increase in cell-wall POD activity and H₂O₂ level preceded inhibition of root growth caused by NaCl, NH₄Cl or proline. NaCl or proline treatment also increased NADH-POD and diamine oxidase (DAO) activities in roots of rice seedlings, suggesting that NADH-POD and DAO contribute to the H₂O₂ generation in the cell wall of NaCl- or proline-treated roots. NH₄Cl treatment increased NADH-POD activity but had no effect on DAO activity, suggesting that NADH-POD but not DAO is responsible for H₂O₂ generation in cell wall of NH₄Cl-treated roots.     

Effect of culture conditions on manganese peroxidase production and activity by some white rot fungi

The ligninolytic system of white rot fungi is primarily composed of lignin peroxidase, manganese peroxidase (MnP) and laccase. The present work was carried out to determine the best culture conditions for production of MnP and its activity in the relatively little-explored cultures of Dichomitus squalens, Irpex flavus and Polyporus sanguineus, as compared with conditions for Phanerochaete chrysosporium and Coriolus versicolor. Studies on enzyme production under different nutritional conditions revealed veratryl alcohol, guaiacol, Reax 80 and Polyfon H to be excellent MnP inducers. Electronic Publication     

Patterns of DNA methylation in the normal colon vary by anatomical location,gender, and age

Alterations in DNA methylation have been proposed to create a field cancerization state in the colon, where molecular alterations that predispose cells to transformation occur in histologically normal tissue. However, our understanding of the role of DNA methylation in field cancerization is limited by an incomplete characterization of the methylation state of the normal colon. In order to determine the colon’s normal methylation state, we extracted DNA from normal colon biopsies from the rectum, sigmoid, transverse, and ascending colon and assessed the methylation status of the DNA by pyrosequencing candidate loci as well as with HumanMethylation450 arrays. We found that methylation levels of repetitive elements LINE-1 and SAT-α showed minimal variability throughout the colon in contrast to other loci. Promoter methylation of EVL was highest in the rectum and progressively lower in the proximal segments, whereas ESR1 methylation was higher in older individuals. Genome-wide methylation analysis of normal DNA revealed 8388, 82, and 93 differentially methylated loci that distinguished right from left colon, males from females, and older vs. younger individuals, respectively. Although variability in methylation between biopsies and among different colon segments was minimal for repetitive elements, analyses of specific cancer-related genes as well as a genome-wide methylation analysis demonstrated differential methylation based on colon location, individual age, and gender. These studies advance our knowledge regarding the variation of DNA methylation in the normal colon, a prerequisite for future studies aimed at understanding methylation differences indicative of a colon field effect.     

Patterns of DNA methylation in the normal colon vary by anatomical location,gender, and age

Alterations in DNA methylation have been proposed to create a field cancerization state in the colon, where molecular alterations that predispose cells to transformation occur in histologically normal tissue. However, our understanding of the role of DNA methylation in field cancerization is limited by an incomplete characterization of the methylation state of the normal colon. In order to determine the colon’s normal methylation state, we extracted DNA from normal colon biopsies from the rectum, sigmoid, transverse, and ascending colon and assessed the methylation status of the DNA by pyrosequencing candidate loci as well as with HumanMethylation450 arrays. We found that methylation levels of repetitive elements LINE-1 and SAT-α showed minimal variability throughout the colon in contrast to other loci. Promoter methylation of EVL was highest in the rectum and progressively lower in the proximal segments, whereas ESR1 methylation was higher in older individuals. Genome-wide methylation analysis of normal DNA revealed 8388, 82, and 93 differentially methylated loci that distinguished right from left colon, males from females, and older vs. younger individuals, respectively. Although variability in methylation between biopsies and among different colon segments was minimal for repetitive elements, analyses of specific cancer-related genes as well as a genome-wide methylation analysis demonstrated differential methylation based on colon location, individual age, and gender. These studies advance our knowledge regarding the variation of DNA methylation in the normal colon, a prerequisite for future studies aimed at understanding methylation differences indicative of a colon field effect.     

Cooperative activity of DNA methyltransferases for maintenance of symmetrical and non-symmetrical cytosine methylation in Arabidopsis thaliana

Maintenance of cytosine methylation in plants is controlled by three DNA methyltransferases. MET1 maintains CG methylation, and DRM1/2 and CMT3 act redundantly to enforce non-CG methylation. RPS, a repetitive hypermethylated DNA fragment from Petunia hybrida, attracts DNA methylation when transferred into Petunia or other species. In Arabidopsis thaliana, which does not contain any RPS homologues, RPS transgenes are efficiently methylated in all sequence contexts. To test which DNA methylation pathways regulate RPS methylation, we examined maintenance of RPS methylation in various mutant backgrounds. Surprisingly, CG methylation was lost in a drm1/2/cmt3 mutant, and non-CG methylation was almost completely eliminated in a met1 mutant. An unusual cooperative activity of all three DNA methyltransferases is therefore required for maintenance of both CG and non-CG methylation in RPS. Other unusual features of RPS methylation are the independence of its non-CG methylation from the RNA-directed DNA methylation (RdDM) pathway and the exceptional maintenance of methylation at a CC(m)TGG site in some epigenetic mutants. This is indicative of activity of a methylation system in plants that may have evolved from the DCM methylation system that controls CC(m)WGG methylation in bacteria. Our data suggest that strict separation of CG and non-CG methylation pathways does not apply to all target regions, and that caution is required in generalizing methylation data obtained for individual genomic regions.     

Effect of prenatal arsenic exposure on DNA methylation and leukocyte subpopulations in cord blood

Prenatal arsenic exposure is associated with increased risk of disease in adulthood. This has led to considerable interest in arsenic’s ability to disrupt fetal programming. Many studies report that arsenic exposure alters DNA methylation in whole blood but these studies did not adjust for cell mixture. In this study, we examined the relationship between arsenic in maternal drinking water collected ≤ 16 weeks gestational age and DNA methylation in cord blood (n = 44) adjusting for leukocyte-tagged differentially methylated regions. DNA methylation was quantified using the Infinium HumanMethylation 450 BeadChip array. Recursively partitioned mixture modeling examined the relationship between arsenic and methylation at 473,844 CpG sites. Median arsenic concentration in water was 12 µg/L (range < 1- 510 µg/L). Log₁₀ arsenic was associated with altered DNA methylation across the epigenome (P = 0.002); however, adjusting for leukocyte distributions attenuated this association (P = 0.013). We also observed that arsenic had a strong effect on the distribution of leukocytes in cord blood. In adjusted models, every log₁₀ increase in maternal drinking water arsenic exposure was estimated to increase CD8+ T cells by 7.4% (P = 0.0004) and decrease in CD4+ T cells by 9.2% (P = 0.0002). These results show that prenatal exposure to arsenic had an exposure-dependent effect on specific T cell subpopulations in cord blood and altered DNA methylation in cord blood. Future research is needed to determine if these small changes in DNA methylation alter gene expression or are associated with adverse health effects.     

Effect of prenatal arsenic exposure on DNA methylation and leukocyte subpopulations in cord blood

Prenatal arsenic exposure is associated with increased risk of disease in adulthood. This has led to considerable interest in arsenic’s ability to disrupt fetal programming. Many studies report that arsenic exposure alters DNA methylation in whole blood but these studies did not adjust for cell mixture. In this study, we examined the relationship between arsenic in maternal drinking water collected ≤ 16 weeks gestational age and DNA methylation in cord blood (n = 44) adjusting for leukocyte-tagged differentially methylated regions. DNA methylation was quantified using the Infinium HumanMethylation 450 BeadChip array. Recursively partitioned mixture modeling examined the relationship between arsenic and methylation at 473,844 CpG sites. Median arsenic concentration in water was 12 µg/L (range < 1- 510 µg/L). Log₁₀ arsenic was associated with altered DNA methylation across the epigenome (P = 0.002); however, adjusting for leukocyte distributions attenuated this association (P = 0.013). We also observed that arsenic had a strong effect on the distribution of leukocytes in cord blood. In adjusted models, every log₁₀ increase in maternal drinking water arsenic exposure was estimated to increase CD8+ T cells by 7.4% (P = 0.0004) and decrease in CD4+ T cells by 9.2% (P = 0.0002). These results show that prenatal exposure to arsenic had an exposure-dependent effect on specific T cell subpopulations in cord blood and altered DNA methylation in cord blood. Future research is needed to determine if these small changes in DNA methylation alter gene expression or are associated with adverse health effects.     

DNA content, interphase AgNOR-area, number of 3 HrDNA hybridization signals and the methylation level in coding rDNA sequence in different organs of Lupinus luteus L.

Nuclear DNA and AgNOR-area quantity have been measured cytophotometrically, the number of silver grains afterin situ ³H rDNA/DNA hybridization has been counted, and the level of rDNA methylation has been estimated in root meristems, differentiated root zones, hypocotyls, cotyledons, and leaves of 7-day-old seedlings ofLupinus luteus. DNA content increases by endoreplication, reaching the average DNA C-value of 4.2 in the meristem, 6.6C in hypocotyl, 15.9C in cotyledon, and 3.3C in leaf. The quantity of AgNOR-area, the highest in root meristem, does not follow DNA C-value. Number of grains afterin situ ³H rDNA/DNA hybridization corresponds to DNA amount, but their distribution differs, showing in many cases perinucleolar localization in organs displaying low AgNOR-area quantity. Southern hybridization has not demonstrated detectable changes in level rDNA methylation. We suggest that the low level of rDNA expression in non-meristematic tissues could be related to rDNA inactivation caused by its translocation into nucleolus-associated heterochromatin.     

DNA甲基化和组蛋白修饰在克隆动物发育过程中的作用

体细胞核移植在农业应用、生产疾病模型动物、转基因家畜或产生人胚胎干细胞来治疗人类的疾病方面有巨大的应用潜力。虽然已经成功克隆出多种哺乳动物, 但该技术仍存在一些未解决的问题, 包括产生克隆动物的效率低和克隆动物的异常等。异常的表观遗传重编程是克隆胚胎发育失败的一个重要因素。文章重点论述了DNA甲基化、组蛋白修饰及其与克隆胚胎发育的关系。了解表观遗传调控机制有助于解决核移植技术中存在的问题, 有利于更好地应用这项技术。