DNA methylation‐mediated epigenetic control

During differentiation and development cells undergo dramatic morphological and functional changes without any change in the DNA sequence. The underlying changes of gene expression patterns are established and maintained by epigenetic processes. Early mechanistic insights came from the observation that gene activity and repression states correlate with the DNA methylation level of their promoter region. DNA methylation is a postreplicative modification that occurs exclusively at the C5 position of cytosine residues (5mC) and predominantly in the context of CpG dinucleotides in vertebrate cells. Here, three major DNA methyltransferases (Dnmt1, 3a, and 3b) establish specific DNA methylation patterns during differentiation and maintain them over many cell division cycles. CpG methylation is recognized by at least three protein families that in turn recruit histone modifying and chromatin remodeling enzymes and thus translate DNA methylation into repressive chromatin structures. By now a multitude of histone modifications have been linked in various ways with DNA methylation. We will discuss some of the basic connections and the emerging complexity of these regulatory networks. J. Cell. Biochem. 108: 43–51, 2009. © 2009 Wiley‐Liss, Inc.     

A 5‐year vision for Annals of Applied Biology

Epigenetic changes including DNA and histone methylation may reorganise the nuclear architecture during in vitro culture. The states of methylation resulting from in vitro cultures are often related to control the somatic embryogenesis and regeneration process via modulating gene expression. By changing the methylation profile, it is possible to alter gene expression which may be applicable to produce large number of high quality planting materials or to improve agronomic traits leading to crop improvement. Understanding the molecular mechanisms of methylation alterations and acquisition of developmental cell fate during in vitro cultures can help in the development of strategies to enhance the embryogenic capability and totipotency in recalcitrant plant species and genotypes. Moreover, the methylation profile may also be useful to adapt crops under adverse environment as the plants undergo through various stresses during in vitro cultures. In this article, we review the literature on the role of DNA and histone methylation in plant variation and discuss the potential of targeted epigenetic variation for crop improvement.     

Epigenetic marking correlates with developmental potential in cloned bovine preimplantation embryos

During differentiation, somatic nuclei acquire highly specialized DNA and chromatin modifications, which are thought to result in cellular memory of the differentiated state. Upon somatic nuclear transfer into oocytes, the donor nucleus may have to undergo reprogramming of these epigenetic marks in order to achieve totipotency. This may involve changes in epigenetic features similar to those that occur in normal embryos during early development. However, there is accumulating evidence that epigenetic reprogramming is severely deficient in cloned embryos. Several reports reveal inefficient demethylation and inappropriate reestablishment of DNA methylation in quantitative and qualitative patterns on somatic nuclear transfer. Here we examine histone H3 lysine 9 (H3-K9) methylation and acetylation in normal embryos and in those created by somatic nuclear transfer. We find that H3-K9 methylation is reprogrammed in parallel with DNA methylation in normal embryos. However, the majority of cloned embryos exhibit H3-K9 hypermethylation associated with DNA hypermethylation, suggesting a genome-wide failure of reprogramming. Strikingly, the precise epigenotype in cloned embryos depends on the donor cell type, and the proportion of embryos with normal epigenotypes correlates closely with the proportion developing to the blastocyst stage. These results suggest a mechanistic link between DNA and histone methylation in the mammalian embryo and reveal an association between epigenetic marks and developmental potential of cloned embryos.     

5-Azacytidine-induced demethylation of DNA to senescent level does not block proliferation of human fibroblasts.

IMR-90 human diploid fibroblasts (HDF) lose from 30-50% of their genomic 5-methyldeoxycytidine (5mdC) during the cellular aging process. In contrast, immortal SV40-transformed IMR-90 maintain a constant level of 5mdC in culture. Precrisis SV40-transformed HDF (AG3204) represent a stage in between normal cell aging and immortalization because these cells still have a finite proliferative lifespan, but it is longer than that of normal HDF and ends in cell death rather than in G1-arrest. We find that AG3204 cells continue to lose from 12-33% of their 5mdC after a population has become 99% positive for SV40 T-antigen. Both IMR-90 cells and AG3204 cells have similar levels of 5mdC (average of 2.25%) at the end of lifespan. We investigated whether this level of 5mdC is an absolute block to further proliferation by treating IMR-90 and AG3204 cells with 5-azacytidine (5azaC) to reduce their 5mdC levels below the terminal level normally achieved at end of lifespan. We find that both IMR-90 and AG3204 cells undergo extensive proliferation with subterminal levels of 5mdC and that the lifespans of both cell types are shortened by 5azaC treatment. These studies indicate that random genomic DNA demethylation to a specific level of 5mdC is not a direct cause of finite proliferative lifespan. However, the correlation between accelerated DNA demethylation and accelerated aging still suggests that these two phenomena are related. Two ways to explain this relationship are: (1) DNA demethylation during aging is not random, and/or (2) both DNA demethylation and other independent aging processes cooperate to produce finite lifespan. In both cases, accelerated random DNA demethylation could accelerate aging, but not necessarily in direct relationship to the final genomic level of 5mdC achieved during the normal aging process.     

Epigenetics: the study of embryonic stem cells by restriction landmark genomic scanning

During mammalian development, it is essential that the proper epigenetic state is established across the entire genome in each differentiated cell. To date, little is known about the mechanism for establishing epigenetic modifications of individual genes during the course of cellular differentiation. Genome-wide DNA methylation analysis of embryonic stem cells by restriction landmark genomic scanning provides information about cell type- and tissue-specific DNA methylation profiles at tissue-specific methylated regions associated with developmental processes. It also sheds light on DNA methylation alterations following fetal exposure to chemical agents. In addition, analysis of embryonic stem cells deficient in epigenetic regulators will contribute to revealing the mechanism for establishing DNA methylation profiles and the interplay between DNA methylation and other epigenetic modifications.     

Tissue-Specific Epigenetic Modifications in Root Apical Meristem Cells of Hordeum vulgare

Epigenetic modifications of chromatin structure are essential for many biological processes, including growth and reproduction. Patterns of DNA and histone modifications have recently been widely studied in many plant species, although there is virtually no data on the spatial and temporal distribution of epigenetic markers during plant development. Accordingly, we have used immunostaining techniques to investigate epigenetic modifications in the root apical meristem of Hordeum vulgare. Histone H4 acetylation (H4K5ac), histone H3 dimethylation (H3K4me2, H3K9me2) and DNA methylation (5mC) patterns were established for various root meristem tissues. Distinct levels of those modifications were visualised in the root cap, epidermis, cortex and vascular tissues. The lateral root cap cells seem to display the highest level of H3K9me2 and 5mC. In the epidermis, the highest level of 5mC and H3K9me2 was detected in the nuclei from the boundary of the proximal meristem and the elongation zone, while the vascular tissues were characterized by the highest level of H4K5ac. Some of the modified histones were also detectable in the cytoplasm in a highly tissue-specific manner. Immunolocalisation of epigenetic modifications of chromatin carried out in this way, on longitudinal or transverse sections, provides a unique topographic context within the organ, and will provide some answers to the significant biological question of tissue differentiation processes during root development in a monocotyledon plant species.     

Aberrant DNA methylation in 5'regions of DNA methyltransferase genes in aborted bovine clones

High rate of abortion and developmental abnormalities is thought to be closely associated with inefficient epigenetic reprogramming of the transplanted nuclei during bovine cloning.It is known that one of the important mechanisms for epigenetic reprogramming is DNA methylation.DNA methylation is established and maintained by DNA methyltransferases(DNMTs),therefore,it is postulated that the inefficient epigenetic reprogramming of transplanted nuclei may be due to abnormal expression of DNMTs.Since DNA methylation can strongly inhibit gene expression,aberrant DNA methylation of DNMT genes may disturb gene expression.But presently,it is not clear whether the methylation abnormality of DNMT genes is related to developmental failure of somatic cell nuclear transfer embryos.In our study,we analyzed methylation patterns of the 5' regions of four DNMT genes including Dnmt3a,Dnmt3b,Dnmtl and Dnmt2 in four aborted bovine clones.Using bisulfite sequencing method,we found that 3 out of 4 aborted bovine clones(AF1,AF2 and AF3)showed either hypermethylation or hypomethylation in the 5' regions of Dnmt3a and Dnmt3b.indicating that Dnmt3a and Dnmt3b genes are not properly reprogrammed.However,the individual AF4 exhibited similar methylation level and pattern to age-matched in vitro fertilized (IVF)fetuses.Besides,we found that tle 5'regions of Dnmtl and Dnmt2 were nearly completely unmethylated in all normal adults.IVF fetuses,sperm and aborted clones.Together,our results suggest that the aberrant methylation of Dnmt3a and Dnmt3b 5' regions is probably associated with the high abortion of bovine clones.     

Methyl CpG Binding Domain Ultra‐Sequencing: a novel method for identifying inter‐individual and cell‐type‐specific variation in DNA methylation

Experience‐dependent changes in DNA methylation can exert profound effects on neuronal function and behaviour. A single learning event can induce a variety of DNA modifications within the neuronal genome, some of which may be common to all individuals experiencing the event, whereas others may occur in a subset of individuals. Variations in experience‐induced DNA methylation may subsequently confer increased vulnerability or resilience to the development of neuropsychiatric disorders. However, the detection of experience‐dependent changes in DNA methylation in the brain has been hindered by the interrogation of heterogeneous cell populations, regional differences in epigenetic states and the use of pooled tissue obtained from multiple individuals. Methyl CpG Binding Domain Ultra‐Sequencing (MBD Ultra‐Seq) overcomes current limitations on genome‐wide epigenetic profiling by incorporating fluorescence‐activated cell sorting and sample‐specific barcoding to examine cell‐type‐specific CpG methylation in discrete brain regions of individuals. We demonstrate the value of this method by characterizing differences in 5‐methylcytosine (5mC) in neurons and non‐neurons of the ventromedial prefrontal cortex of individual adult C57BL/6 mice, using as little as 50 ng of genomic DNA per sample. We find that the neuronal methylome is characterized by greater CpG methylation as well as the enrichment of 5mC within intergenic loci. In conclusion, MBD Ultra‐Seq is a robust method for detecting DNA methylation in neurons derived from discrete brain regions of individual animals. This protocol will facilitate the detection of experience‐dependent changes in DNA methylation in a variety of behavioural paradigms and help identify aberrant experience‐induced DNA methylation that may underlie risk and resiliency to neuropsychiatric disease.     

MIWI2 targets RNAs transcribed from piRNA‐dependent regions to drive DNA methylation in mouse prospermatogonia

Argonaute/Piwi proteins can regulate gene expression via RNA degradation and translational regulation using small RNAs as guides. They also promote the establishment of suppressive epigenetic marks on repeat sequences in diverse organisms. In mice, the nuclear Piwi protein MIWI2 and Piwi‐interacting RNAs (piRNAs) are required for DNA methylation of retrotransposon sequences and some other sequences. However, its underlying molecular mechanisms remain unclear. Here, we show that piRNA‐dependent regions are transcribed at the stage when piRNA‐mediated DNA methylation takes place. MIWI2 specifically interacts with RNAs from these regions. In addition, we generated mice with deletion of a retrotransposon sequence either in a representative piRNA‐dependent region or in a piRNA cluster. Both deleted regions were required for the establishment of DNA methylation of the piRNA‐dependent region, indicating that piRNAs determine the target specificity of MIWI2‐mediated DNA methylation. Our results indicate that MIWI2 affects the chromatin state through base‐pairing between piRNAs and nascent RNAs, as observed in other organisms possessing small RNA‐mediated epigenetic regulation.     

Changes in allele‐specific association of histone modifications at the imprinting control regions during mouse preimplantation development

Allele‐specific association of histone modification is observed at the regulatory region of imprinted genes and has been suggested to work as an epigenetic marker for monoallelic gene expression, along with the allelic CpG methylation of DNA. Although the parent‐origin‐specific epigenetic status in imprinted genes is thought to be established during preimplantation development, little is known about the allelic specificity of histone modifications during this period because of the limited volume of material available for analysis. In this study, we first revealed the allelic enrichment of histone modifications and variant histones at the imprinting control regions (ICRs) of four‐cell to blastocyst stage preimplantation embryos by using carrier chromatin immunoprecipitation and sequence polymorphism analysis of immunoprecipitated DNA. We found relative enrichment of histone H3 lysine 9 dimethylation at the imprinted alleles of ICRs and obtained the results suggesting that histone modifications at ICRs are established during a late preimplantation stage. genesis, 47:611–616, 2009. © 2009 Wiley‐Liss, Inc.     

An epigenetic view of plant cells cultured in vitro: somaclonal variation and beyond

Epigenetic mechanisms are highly dynamic events that modulate gene expression. As more accurate and powerful tools for epigenetic analysis become available for application in a broader range of plant species, analysis of the epigenetic landscape of plant cell cultures may turn out to be crucial for understanding variant phenotypes. In vitro plant cell and tissue culture methodologies are important for many ongoing plant propagation and breeding programmes as well as for cutting-edge research in several plant model species. Although it has long been known that in vitro conditions induce variation at several levels, most studies using such conditions rely on the assumption that in vitro cultured plant cells/tissues mostly conform genotypically and phenotypically. However, when large-scale clonal propagation is the aim, there has been a concern in confirming true-to-typeness using molecular markers for evaluating stability. While in most reports genetic variation has been found to occur at relatively modest frequencies, variation in DNA methylation patterns seems to be much more frequent and in some cases it has been directly implicated in phenotypic variation. Recent advances in the field of epigenetics have uncovered highly dynamic mechanisms of chromatin remodelling occurring during cell dedifferentiation and differentiation processes on which in vitro adventitious plant regeneration systems are based. Here, an overview of recent findings related to developmental switches occurring during in vitro culture is presented. Additionally, an update on the detection of epigenetic variation in plant cell cultures will be provided and discussed in the light of recent progress in the plant epigenetics field.     

Functional characterization of Nicotiana benthamiana chromomethylase 3 in developmental programs by virus‐induced gene silencing

DNA methylation is essential for normal developmental processes and genome stability. DNA methyltransferases are key enzymes catalyzing DNA methylation. Chromomethylase (CMT) genes are specific to the plant kingdom and encode chromodomain‐containing methyltransferases. However, the function of CMT genes in plants remains elusive. In this study, we isolated and characterized a CMT gene from Nicotiana benthamiana, designated NbCMT3. Alignment of the NbCMT3 amino acid sequence with other plant CMT3s showed conservation of bromo‐adjacent‐homology and methyltransferase catalytic domains. We investigated the expression patterns of NbCMT3 and its function in developmental programs. NbCMT3 was expressed predominately in proliferating tissues such as apical shoots and young leaves. NbCMT3 protein showed a nuclear location, which could be related to its putative cellular functions. Knocking down NbCMT3 expression by virus‐induced gene silencing revealed its vital role(s) in leaf morphogenesis. The formation of palisade cells was defective in NbCMT3‐silenced plants as compared with controls. NbCMT3 has a role in developmental programs.