Epigenetics,Eh!: A meeting summary of the Canadian Conference on Epigenetics

In May 2011, the Canadian Conference on Epigenetics: Epigenetics Eh! was held in London, Canada. The objectives of this conference were to showcase the breadth of epigenetic research on environment and health across Canada and to provide the catalyst to develop collaborative Canadian epigenetic research opportunities, similar to existing international epigenetic initiatives in the US and Europe. With ten platform sessions and two sessions with over 100 poster presentations, this conference featured cutting-edge epigenetic research, presented by Canadian and international principal investigators and their trainees in the field of epigenetics and chromatin dynamics. An EpigenART competition included ten artists, creating a unique opportunity for artists and scientists to interact and explore their individual interpretations of this scientific discipline. The conference provided a unique venue for a significant cross-section of Canadian epigenetic researchers from diverse disciplines to meet, interact, collaborate and strategize at the national level.     

昆虫滞育表观遗传调控的研究进展

滞育是昆虫躲避不良环境的一种策略,对延续昆虫种群具有重要意义.特别是昆虫的兼性滞育,能够受环境的周期性季节变化影响,表观遗传可能在其中扮演重要角色.表观遗传是不依赖DNA序列改变所产生的可遗传变异,包括DNA、RNA、蛋白质和染色质水平上的各种表观遗传调控过程,可能参与生物的发育可塑性.昆虫滞育表观遗传调控主要包括两个...     

Cancer epigenetics reaches mainstream oncology

Epigenetics is one of the most promising and expanding fields in the current biomedical research landscape. Since the inception of epigenetics in the 1940s, the discoveries regarding its implications in normal and disease biology have not stopped, compiling a vast amount of knowledge in the past decade. The field has moved from just one recognized marker, DNA methylation, to a variety of others, including a wide spectrum of histone modifications. From the methodological standpoint, the successful initial single gene candidate approaches have been complemented by the current comprehensive epigenomic approaches that allow the interrogation of genomes to search for translational applications in an unbiased manner. Most important, the discovery of mutations in the epigenetic machinery and the approval of the first epigenetic drugs for the treatment of subtypes of leukemias and lymphomas has been an eye-opener for many biomedical scientists and clinicians. Herein, we will summarize the progress in the field of cancer epigenetics research that has reached mainstream oncology in the development of new biomarkers of the disease and new pharmacological strategies.     

Epigenetics, eh! A meeting summary of the Canadian Conference on Epigenetics

In May 2011, the Canadian Conference on Epigenetics: Epigenetics Eh! was held in London, Canada. The objectives of this conference were to showcase the breadth of epigenetic research on environment and health across Canada and to provide the catalyst to develop collaborative Canadian epigenetic research opportunities, similar to existing international epigenetic initiatives in the US and Europe. With ten platform sessions and two sessions with over 100 poster presentations, this conference featured cutting-edge epigenetic research, presented by Canadian and international principal investigators and their trainees in the field of epigenetics and chromatin dynamics. An EpigenART competition included ten artists, creating a unique opportunity for artists and scientists to interact and explore their individual interpretations of this scientific discipline. The conference provided a unique venue for a significant cross-section of Canadian epigenetic researchers from diverse disciplines to meet, interact, collaborate and strategize at the national level.     

表观遗传学及其研究方法

表观遗传学是一门重要的生命学科,主要包括DNA的甲基化、组蛋白修饰以及非编码RNA等内容,其中任何一方面的表观遗传学变化对生物体的生命过程都有重要的影响。近年来随着生命科学的快速发展,表观遗传学越来越受到人们的关注,各种先进科技的应用也使得表观遗传学实验技术得到快速的发展。本文对DNA甲基化、组蛋白修饰及非编码RNA的基本内容及实验方法进行了综述,并对不同的研究方法进行分析,有利于表观遗传学的深入研究。     

Translational Epigenetics: Clinical Approaches to Epigenome Therapeutics for Cancer

Cancer epigenetics research is now entering an exciting phase of translational epigenetics whereby novel epigenome therapeutics is being developed for application in clinical settings. Epigenetics refers to all heritable and potentially reversible changes in gene or genome functioning that occurs without altering the nucleotide sequence of the DNA. A range of different epigenetic “marks” can activate or repress gene expression. While epigenetic alterations are associated with most cancers, epigenetic dysregulation can also have a causal role in cancer etiology. Epigenetically disrupted stem or progenitor cells could have an early role in neoplastic transformations, while perturbance of epigenetic regulatory mechanisms controlling gene expression in cancer-relevant pathways will also be a contribution factor. The reversibility of epigenetic marks provides the possibility that the activity of key cancer genes and pathways can be regulated as a therapeutic approach. The growing availability of a range of chemical agents which can affect epigenome functioning has led to a range of epigenetic-therapeutic approaches for cancer and intense interest in the development of second-generation epigenetic drugs (epi-drugs) which would have greater specificity and efficacy in clinical settings. The latest developments in this exciting arena of translational cancer epigenetics were presented at a recent conference on “Epigenetics and New Therapies in Cancer” at the Spanish National Cancer Research Center (CNIO), Spain.     

Plant epigenetics: phenotypic and functional diversity beyond the DNA sequence

Phenotypic variation determines the capacity of plants to adapt to changing environments and to colonize new habitats. Deciphering the mechanisms contributing to plant phenotypic variation and their effects on plant ecological interactions and evolutionary dynamics is thus central to all biological disciplines. In the past few decades, research on plant epigenetics is showing that (1) epigenetic variation is related to phenotypic variation and that some epigenetic marks drive major phenotypic changes in plants; (2) plant epigenomes are highly diverse, dynamic, and can respond rapidly to a variety of biotic and abiotic stimuli; (3) epigenetic variation can respond to selection and therefore play a role in adaptive evolution. Yet, current information in terms of species, geographic ranges, and ecological contexts analyzed so far is too limited to allow for generalizations about the relevance of epigenetic regulation in phenotypic innovation and plant adaptation across taxa. In this report, we contextualize the potential role of the epigenome in plant adaptation to the environment and describe the latest research in this field presented during the symposium “Plant epigenetics: phenotypic and functional diversity beyond the DNA sequence” held within the Botany 2020 conference framework in summer 2020.     

Letter from the Editor

This is the first issue of Epigenetics, which is the first international periodical focusing on the newly emerging field of epigenetics and is the official journal of the DNA Methylation Society. Our goal is that Epigenetics will be the lead primary journal in the field of epigenetics and will provide a comprehensive view of epigenetic modification, which spans biological systems and diseases. This diversity of themes and comprehensive approach to epigenetics is reflected in the composition of our editorial board, which includes world-class leaders in the different fields of epigenetics. The editorial board guides the peer review process and the development of the vision of the journal. We encourage members of the epigenetics community to contact the editorial board members with suggestions and questions regarding potential new submissions to the journal.

The journal will provide a forum where epigenetic approaches to a variety of medical and biological issues could be discussed and where the common basic principles of epigenetics spanning different systems could be revealed and shared. Although cancer has been the main focus of epigenetics in the last decade, recent data suggests that epigenetic plays a critical role in psychology andpsychopathology. It is being realized that normal behaviors such as maternal care and pathologies such as Schizophrenia and Alzheimer’s might have an epigenetic basis. It is also becoming clear that nutrition and life experiences have epigenetic consequences.

The increasing awareness of the potential role of epigenetic deregulation in disease has spawned the development of diagnostic and therapeutic approaches using epigenetics. Although the questions asked are diverse, the unifying hypothesis is epigenetics. The journal will emphasize scientific rigor but will at the same time promote and encourage open mindedness as well as provocative and novel hypotheses and approaches. The journal will provide a platform for developing unifying methodologies,hypotheses, experimental approaches and diagnostic agents and will serve as a meeting place for researchers from different systems such as general biology, plant biology, cancer biology, cancer therapeutics, epigenetic pharmacology, neurobiology and psychiatry who are unraveling the epigenetic facets of their specific fields of interest.

We recognize that our first issue is just a first small step, but we hope that it will be leading to a great journal, which will serve as the flagship of the epigenetics field. The success of the journal depends on the continuous and unswerving support of the epigenetics community by submitting the best papers to the journal, by participation in the review process and the editorial process and by contribution of suggestions and ideas.

Our first issue includes examples of each of the different areas, which we hope to see covered in the journal in the future. The issue starts with a meeting report of the Environmental Epigenomics conference held at Durham North Carolina in November 2005. This report points out the prospect that the environment sculpts our genomes through epigenetic markings and that some of these markings might be passed through the germ line. This emerging relationship between the environment and our epigenomes impacts on our understanding of the relative role of genetic heredity and environmental exposures in normal behavior and disease susceptibility. The key promise in an epigenetic understanding of human disease is its potential reversibility by therapeutic agents. Our two reviews discuss pharmacological and therapeutic approaches directed at the two components ofthe epigenome DNA methylation (Mund et al., pp. 7–13) and chromatin structure (Kim et al., pp. 14–23). Karimi et al. discuss a new method LUMA for quantification of global DNA methylation, and Baron et al. (pp. 55–60) discuss DNA methylation as a tool for cell typing. A new mode of Igf2r imprinting in opossum which does not involve DNA methylation is discussed by Weidman et al. (pp. 49–54) and Rivenbark et al. (pp. 32–44) show that not all gene targets of DNA methylation in breast cancer will contain a CpG island and they propose expansion of the current model for methylation-dependent regulation of gene expression to include genes lacking typical CpG islands.

Thatcher and Lasalle (pp. 24–33) show the global effects that the methylated DNA binding protein Mecp2 has on histone acetylation and modification during postnatal neuronal maturation, a finding, which has interesting implications on our understanding of the MeCP2 deficiency Rett syndrome. Our small first fruits do give us a glimpse of the different facets of the field from DNA methylation to chromatin, from methods development to diagnostics and from the environment totherapeutics. We hope that with the support of the members of the epigenetics community we will be able to establish a journal, of which we all will be proud.     

Epigenetic determinism in science and society

The epigenetic “revolution” in science cuts across many disciplines, and it is now one of the fastest-growing research areas in biology. Increasingly, claims are made that epigenetics research represents a move away from the genetic determinism that has been prominent both in biological research and in understandings of the impact of biology on society. We discuss to what extent an epigenetic framework actually supports these claims. We show that, in contrast to the received view, epigenetics research is often couched in language as deterministic as genetics research in both science and the popular press. We engage the rapidly emerging conversation about the impact of epigenetics on public discourse and scientific practice, and we contend that the notion of epigenetic determinism – or the belief that epigenetic mechanisms determine the expression of human traits and behaviors – matters for understandings of the influence of biology and society on population health.     

UBE3A-mediated regulation of imprinted genes and epigenome-wide marks in human neurons

The dysregulation of genes in neurodevelopmental disorders that lead to social and cognitive phenotypes is a complex, multilayered process involving both genetics and epigenetics. Parent-of-origin effects of deletion and duplication of the 15q11-q13 locus leading to Angelman, Prader-Willi, and Dup15q syndromes are due to imprinted genes, including UBE3A, which is maternally expressed exclusively in neurons. UBE3A encodes a ubiquitin E3 ligase protein with multiple downstream targets, including RING1B, which in turn monoubiquitinates histone variant H2A.Z. To understand the impact of neuronal UBE3A levels on epigenome-wide marks of DNA methylation, histone variant H2A.Z positioning, active H3K4me3 promoter marks, and gene expression, we took a multi-layered genomics approach. We performed an siRNA knockdown of UBE3A in two human neuroblastoma cell lines, including parental SH-SY5Y and the SH(15M) model of Dup15q. Genes differentially methylated across cells with differing UBE3A levels were enriched for functions in gene regulation, DNA binding, and brain morphology. Importantly, we found that altering UBE3A levels had a profound epigenetic effect on the methylation levels of up to half of known imprinted genes. Genes with differential H2A.Z peaks in SH(15M) compared to SH-SY5Y were enriched for ubiquitin and protease functions and associated with autism, hypoactivity, and energy expenditure. Together, these results support a genome-wide epigenetic consequence of altered UBE3A levels in neurons and suggest that UBE3A regulates an imprinted gene network involving DNA methylation patterning and H2A.Z deposition.     

鼻咽癌的表观遗传学研究进展

表观遗传学是功能基因组学的重要组成部分,它实际上是研究理化、生物等环境因素以及饮食习惯等对遗传因素的作用,并由这一作用引起DNA序列以外的遗传物质改变.鼻咽癌是我国南方常见恶性肿瘤,具有明显的家族聚集倾向,存在基因组不稳定性,易受理化、生物等环境因素的影响,是多基因遗传性肿瘤.鼻咽癌这种独特病因体系提示:鼻咽癌是研究肿瘤表观遗传修饰的最佳模型之一.主要从DNA甲基化、组蛋白修饰、染色质重构和非编码RNA的调控4方面对鼻咽癌表观遗传学研究进展进行综述并针对性地提出了一些新的建议,目的是为进一步探究鼻咽癌表观遗传学发病机制,更好地全面理解鼻咽癌的病因发病机制网络体系,寻找鼻咽癌高危易感人群的筛查、早期诊断、治疗、预后判断的表观遗传修饰分子标志物开辟新的前景.     

Epigenetics, a mode for plants to respond to abiotic stresses

Epigenetics has been becoming a hot topic in recent years.It can be mechanisms that regulate gene expression without changing DNA base sequence.In plants epigenetic regulation has been implicated to be...     

How to localize epigenetics in the landscape of biological research?

Today, epigenetics is a very fashionable field of research. Modification of DNA by methylation, and of chromatin by histone modification or substitution represents a major fraction of the studies; but this special issue shows that epigenetic studies are very diverse, and not limited to the study of chromatin. What is common behind these different uses of the word epigenetics? A brief historical survey shows that epigenetics was invented twice, with different meanings: in the 1940s, by Conrad Waddington, as the study of the relations between the genotype and the phenotype; in the 1960s, as the global mechanisms of gene regulation involved in differentiation and development; what is common is that an approach distinct from genetics was in both cases considered as necessary because genetic models were incapable to address these problems. A good way to appreciate the relations between genetics and epigenetics is to realize that the main aim of organisms is to reproduce, and to consider the way organisms perform this task. Genetics is the precise means organisms have invented to reproduce the structure of their macromolecular components; the genome is also used to control the level and place of this reproduction. All the other means organisms have used to reproduce were more or less the result of tinkering, and constitute the field of epigenetics, with its diversity and richness.     

What Do You Mean, “Epigenetic”?

Interest in the field of epigenetics has increased rapidly over the last decade, with the term becoming more identifiable in biomedical research, scientific fields outside of the molecular sciences, such as ecology and physiology, and even mainstream culture. It has become increasingly clear, however, that different investigators ascribe different definitions to the term. Some employ epigenetics to explain changes in gene expression, others use it to refer to transgenerational effects and/or inherited expression states. This disagreement on a clear definition has made communication difficult, synthesis of epigenetic research across fields nearly impossible, and has in many ways biased methodologies and interpretations. This article discusses the history behind the multitude of definitions that have been employed since the conception of epigenetics, analyzes the components of these definitions, and offers solutions for clarifying the field and mitigating the problems that have arisen due to these definitional ambiguities.     

长链非编码RNA与表观遗传调控

近年来,表观遗传学(epigenetics)备受关注.表观遗传调控的方式主要包括DNA甲基化、组蛋白修饰和染色质重塑等.ENCODE计划及随后的研究发现,人类基因组中仅有很小一部分DNA序列负责编码蛋白质,而其余大部分被转录为非编码RNA(non-codingRNA,ncRNA).其中长链非编码RNA(long non-codingRNA,lncRNA)是一类长度大于200nt并且缺乏蛋白质编码能力的RNA分子.越来越多的研究表明,lncRNAs能够通过表观遗传调控、转录调控以及转录后调控等多个层面调节基因的表达,从而参与细胞增殖、分化和凋亡等多种生物学过程.本文将着重综述lncRNAs在表观遗传调控中的作用及其最新的研究进展.     

The epigenetics of CHARGE syndrome

In biology, we continue to appreciate the fact that the DNA sequence alone falls short when attempting to explain the intricate inheritance patterns for complex traits. This is particularly true for human disorders that appear to have simple genetic causes. The study of epigenetics, and the increased access to the epigenetic profiles of different tissues has begun to shed light on the genetic complexity of many basic biological processes, both physiological and pathological. Epigenetics refers to heritable changes in gene expression that are not due to alterations in the DNA sequence. Various mechanisms of epigenetic regulation exist, including DNA methylation and histone modification. The identification, and increased understanding of key players and mechanisms of epigenetic regulation have begun to provide significant insight into the underlying origins of various human genetic disorders. One such disorder is CHARGE syndrome (OMIM #214800), which is a leading cause of deaf-blindness worldwide. A majority of CHARGE syndrome cases are caused by haploinsufficiency for the CHD7 gene, which encodes an ATP-dependent chromatin remodeling protein involved in the epigenetic regulation of gene expression. The CHD7 protein has been highly conserved throughout evolution, and research into the function of CHD7 homologs in multiple model systems has increased our understanding of this family of proteins, and epigenetic mechanisms in general. Here we provide a review of CHARGE syndrome, and discuss the epigenetic functions of CHD7 in humans and CHD7 homologs in model organisms.     

Epigenetic-based therapies in the preclinical and clinical treatment of Huntington's disease

The study of epigenetics is providing novel insights about the functional and developmental complexity of the nervous system. In neuropathology, therapies aimed at correcting epigenetic dysregulation have been extensively documented in a large variety of models for neurodegenerative, neurodevelopmental and psychiatric disorders. Taking the treatment of Huntington's disease as a paradigm for the study of these ameliorative strategies, this review updates the main conclusions derived from the use of epigenetic drugs at the preclinical and clinical stages, including actions beyond epigenetics.This article is part of a Directed Issue entitled: Epigenetics dynamics in development and disease.     

Clinical relevance of epigenetics in the onset and management of type 2 diabetes mellitus

Epigenetics is involved in the altered expression of gene networks that underlie insulin resistance and insufficiency. Major genes controlling β-cell differentiation and function, such as PAX4, PDX1, and GLP1 receptor, are epigenetically controlled. Epigenetics can cause insulin resistance through immunomediated pro-inflammatory actions related to several factors, such as NF-kB, osteopontin, and Toll-like receptors. Hereafter, we provide a critical and comprehensive summary on this topic with a particular emphasis on translational and clinical aspects. We discuss the effect of epigenetics on β-cell regeneration for cell replacement therapy, the emerging bioinformatics approaches for analyzing the epigenetic contribution to type 2 diabetes mellitus (T2DM), the epigenetic core of the transgenerational inheritance hypothesis in T2DM, and the epigenetic clinical trials on T2DM. Therefore, prevention or reversion of the epigenetic changes occurring during T2DM development may reduce the individual and societal burden of the disease.