表观遗传学与人类疾病的研究进展

在过去的几年里,人们对表观遗传疾病的机理有了新的认识,这些疾病与染色质重塑、基因组印记、X染色体失活以及非编码RNA调控这4个表观遗传过程相关。这4个过程通过调节染色质结构,在染色体或基因簇水平上对基因表达进行调控;异常调控导致复杂的突变且表现为出生前后生长发育和神经功能的异常。对这些疾病的探讨为表观遗传机制的研究提供了很好的模型,进而有助于生物医学的研究。文章就表观遗传学和表观遗传疾病机制的研究进展做一综述。     

Pathogenic chromatin modifiers: Their molecular action linking pathogenicity with genetic variability, epigenetic modifications and environmental factors in Alzheimer disease

Most Alzheimer disease (AD) cases are unexplained. To identify causative agents for AD and to understand this chronic, complex disease process, the pathogenic chromatin modification hypothesis is put forward here, which links pathogenicity with genetic variability, epigenetic modifications and environmental factors. Host chromatin modification by pathogens (disease producers) directly exploiting susceptible genes of their hosts with DNA cleavage, and DNA, histone and other host chromatin protein modifications at defined sites, provide an understanding of the molecular mechanisms for the gene variation associations for AD and the effect of environmental and epigenetic factors. With the pathogenic chromatin modification hypothesis, the erratic success for AD pathogenicity of certain microbes is explained. If a microbe contains the pathogenic chromatin modifiers or their genes, and has the opportunity to infect a host, which has gene variants vulnerable to the pathogenic chromatin modifiers, then the disease process is initiated and promoted. This hypothesis postulates that pathogenic chromatin modifiers contribute to the DNA damage found in AD, and are tied to known risks including the ?4 allele of apolipoprotein E, Down syndrome, the aging process and head injury. Restriction enzymes (REases) and methyltransferases (MTases), previously unrecognized as pathogens in AD or any disease, are a focus with specific suggestions for experiments to elucidate their possible role. The pathogenic chromatin modification hypothesis is relevant to other neurodegenerative disorders including human immunodeficiency virus (HIV) associated dementia and other chronic diseases. This work, integrating a multitude of genetic and environmental factors, presents new targets for therapeutic strategies.     

Epigenetic modifications in rheumatoid arthritis

Over the last decades, genetic factors for rheumatoid diseases like the HLA haplotypes have been studied extensively. However, during the past years of research, it has become more and more evident that the influence of epigenetic processes on the development of rheumatic diseases is probably as strong as the genetic background of a patient. Epigenetic processes are heritable changes in gene expression without alteration of the nucleotide sequence. Such modifications include chromatin methylation and post-translational modification of histones or other chromatin-associated proteins. The latter comprise the addition of methyl, acetyl, and phosphoryl groups or even larger moieties such as binding of ubiquitin or small ubiquitin-like modifier. The combinatory nature of these processes forms a complex network of epigenetic modifications that regulate gene expression through activation or silencing of genes. This review provides insight into the role of epigenetic alterations in the pathogenesis of rheumatoid arthritis and points out how a better understanding of such mechanisms may lead to novel therapeutic strategies.     

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.     

Twin-Based DNA Methylation Analysis Takes the Center Stage of Studies of Human Complex Diseases

The etiology of complex diseases is characterized by the interaction between the genome and environmental conditions and the interface of epigenetics may be a central mechanism. Current technologies already allow us high-throughput profiling of epigenetic patterns at genome level. However, our understanding of the epigenetic processes remains limited. Twins are special samples in genetic studies due to their genetic similarity and rearing-environment sharing. In the past decades, twins have made a great contribution in dissecting the genetic and environmental contributions to human diseases and complex traits. In the era of functional genomics, the valuable samples of twins are helping to bridge the gap between gene activity and environmental conditions through epigenetic mechanisms unlimited to DNA sequence variations. We review the recent progresses in using twins to study disease-related molecular epigenetic phenotypes and link them with environmental exposures especially early life events. Various study designs and application issues will be highlighted and discussed with aim at making uses of twins in assessing the environmental impact on epigenetic changes during the development of complex diseases.     

Chromatin remodeling in development and differentiation

During development and differentiation, early inductive processes that influence cell fate at a later stage leave marks at distinct gene loci that are maintained through several rounds of mitosis. The structure of chromatin is part of this epigenetic memory that restricts or permits differential expression of genes in descendant cells. Establishing a cell-type-specific chromatin pattern thus predestines future cell differentiation and deters cell-lineage infidelity, as it often occurs during neoplastic transformation. As such, understanding the dynamics and mechanisms underlying chromatin remodeling has been a major focus of recent molecular genetic research that holds great promise for biomedical discoveries.     

Epigenetics

Emerging evidence is shedding light on a large and complex network of epigenetic modifications at play in human stem cells. This “epigenetic landscape” governs the fine-tuning and precision of gene expression programs that define the molecular basis of stem cell pluripotency, differentiation and reprogramming. This review will focus on recent progress in our understanding of the processes that govern this landscape in stem cells, such as histone modification, DNA methylation, alterations of chromatin structure due to chromatin remodeling and non-coding RNA activity. Further investigation into stem cell epigenetics promises to provide novel advances in the diagnosis and treatment of a wide array of human diseases.     

Imprinting and disease

Deregulation of imprinted genes has been observed in a number of human diseases such as Beckwith-Wiedemann syndrome, Prader-Willi/Angelman syndromes and cancer. Imprinting diseases are characterised by complex patterns of mutations and associated phenotypes affecting pre- and postnatal growth and neurological functions. Regulation of imprinted gene expression is mediated by allele-specific epigenetic modifications of DNA and chromatin. These modifications preferentially affect central regulatory elements that control in cis over long distances allele-specific expression of several neighbouring genes. Investigations of imprinting diseases have a strong impact on biomedical research and provide interesting models for function and mechanisms of epigenetic gene control.     

Epigenetics: Judge,jury and executioner of stem cell fate

Emerging evidence is shedding light on a large and complex network of epigenetic modifications at play in human stem cells. This “epigenetic landscape” governs the fine-tuning and precision of gene expression programs that define the molecular basis of stem cell pluripotency, differentiation and reprogramming. This review will focus on recent progress in our understanding of the processes that govern this landscape in stem cells, such as histone modification, DNA methylation, alterations of chromatin structure due to chromatin remodeling and non-coding RNA activity. Further investigation into stem cell epigenetics promises to provide novel advances in the diagnosis and treatment of a wide array of human diseases.     

抗原受体基因重组的表观遗传学调控研究新进展

淋巴细胞是哺乳动物唯一能发生体细胞基因组变化的一类细胞,淋巴细胞在发育过程中通过V(D)J重组获得成熟的特异的抗原受体基因,实现了免疫细胞抗原识别惊人的多样性.关于V(D)J重组的调控机制一直是免疫学研究的重要问题,然而直到将表观遗传学研究引入这一领域,综合遗传学和表观遗传学的研究才真正揭示V(D)J重组精细的调控机制.综述了新近发现的V(D)J重组过程中重要的表观遗传学调控机制,如CpG甲基化,组蛋白修饰,核小体重塑及核拓扑学变化.     

Chromatin modifications and remodeling in plant abiotic stress responses

Sensing environmental changes and initiating a gene expression response are important for plants as sessile autotrophs. The ability of epigenetic status to alter rapidly and reversibly could be a key component to the flexibility of plant responses to the environment. The involvement of epigenetic mechanisms in the response to environmental cues and to different types of abiotic stresses has been documented. Different environmental stresses lead to altered methylation status of DNA as well as modifications of nucleosomal histones. Understanding how epigenetic mechanisms are involved in plant response to environmental stress is highly desirable, not just for a better understanding of molecular mechanisms of plant stress response but also for possible application in the genetic manipulation of plants. In this review, we highlight our current understanding of the epigenetic mechanisms of chromatin modifications and remodeling, with emphasis on the roles of specific modification enzymes and remodeling factors in plant abiotic stress responses. This article is part of a Special Issue entitled: Plant gene regulation in response to abiotic stress.     

Die Genetik atopischer Erkrankungen

Allergic disorders (atopic dermatitis, asthma, hay fever) are common chronic inflammatory diseases of the skin and airways that are often associated with allergies (formation of specific IgE antibodies) to environmental allergens. They are complex genetic diseases, so that both genetic and environmental factors are involved in their causation. Most of the research effort devoted to the search for genes that might be responsible has so far focused on the mechanisms behind the immune response. More recent work on gene identification, however, documents the decisive importance of epithelial barrier defects in the pathogenesis of AD and allergic airways disease. These findings represent an important milestone in unraveling the genetic mechanisms underlying these complex diseases and allow new insight into the molecular mechanisms that lead illnesses to develop. In addition, they might point the way to novel preventive and therapeutic strategies for atopic disorders.     

Epigenetics in cardiac development,function, and disease

Substantial new knowledge has accrued, over the past few years, concerning the epigenetic regulation of heart development and disease. Epigenetic mechanisms comprise DNA methylation, ATP-dependent chromatin remodeling, histone modifications, and non-coding RNAs. Many of these processes have been ascertained to influence the tight spatiotemporal control of gene expression during cardiac development. Nevertheless, the relative contribution of each mechanism and their potentially complex interplay remain largely unexplored. Cardiac development and disease are linked through the reactivation of fetal genes upon cardiac hypertrophy and failure. In cardiac disease, changes in gene expression are accompanied and influenced by distinct changes in histone modifications. Detailed knowledge about the epigenetic pathways of cardiac development and function is expected ultimately to lead to novel therapeutic strategies for heart disease and regenerative medicine.     

Epigenetic regulation in human melanoma: past and future

The development and progression of melanoma have been attributed to independent or combined genetic and epigenetic events. There has been remarkable progress in understanding melanoma pathogenesis in terms of genetic alterations. However, recent studies have revealed a complex involvement of epigenetic mechanisms in the regulation of gene expression, including methylation, chromatin modification and remodeling, and the diverse activities of non-coding RNAs. The roles of gene methylation and miRNAs have been relatively well studied in melanoma, but other studies have shown that changes in chromatin status and in the differential expression of long non-coding RNAs can lead to altered regulation of key genes. Taken together, they affect the functioning of signaling pathways that influence each other, intersect, and form networks in which local perturbations disturb the activity of the whole system. Here, we focus on how epigenetic events intertwine with these pathways and contribute to the molecular pathogenesis of melanoma.