A new stage in the development of genetics and term epigenetics

Genetics requires verification of the notion of gene. In this article, DNA and DNA parts are proposed to be named progenes, while the term gene refers to the informational products produced on DNA. These are RNA genes, protein genes, and DNA genes (transposable elements). The focus of genetics is switched today from characters of intraspecies difference to characters of intraspecies similarity. Regulatory genes controlling ontogeny (ontogenes) become the main object of research. These genes can be isolated by methods of both reverse and direct genetics. The properties of ontogene mutations, isolated by methods of direct genetics, are described. The problematic of epigenetics is related to the expression of ontogenes. The term epigenetics is not correct because of its ambiguity.     

DNA methylation in embryonic stem cells

Embryonic stem cells (ESCs) are pluripotent, self‐renewing cells. These cells can be used in applications such as cell therapy, drug development, disease modeling, and the study of cellular differentiation. Investigating the interplay of epigenetics, genetics, and gene expression in control of pluripotence and differentiation could give important insights on how these cells function. One of the best known epigenetic factors is DNA methylation, which is a major mechanism for regulation of gene expression. This phenomenon is mostly seen in imprinted genes and X‐chromosome inactivation where DNA methylation of promoter regions leads to repression of gene expression. Differential DNA methylation of pluripotence‐associated genes such as Nanog and Oct4/Pou5f1 has been observed between pluripotent and differentiated cells. It is clear that tight regulation of DNA methylation is necessary for normal development. As more associations between aberrant DNA methylation and disease are reported, the demand for high‐throughput approaches for DNA methylation analysis has increased. In this article, we highlight these methods and discuss recent DNA methylation studies on ESCs. J. Cell. Biochem. 109: 1–6, 2010. © 2009 Wiley‐Liss, Inc.     

Epigenetic mechanisms in memory formation

Discoveries concerning the molecular mechanisms of cell differentiation and development have dictated the definition of a new sub-discipline of genetics known as epigenetics. Epigenetics refers to a set of self-perpetuating, post-translational modifications of DNA and nuclear proteins that produce lasting alterations in chromatin structure as a direct consequence, and lasting alterations in patterns of gene expression as an indirect consequence. The area of epigenetics is a burgeoning subfield of genetics in which there is considerable enthusiasm driving new discoveries. Neurobiologists have only recently begun to investigate the possible roles of epigenetic mechanisms in behaviour, physiology and neuropathology. Strikingly, the relevant data from the few extant neurobiology-related studies have already indicated a theme - epigenetic mechanisms probably have an important role in synaptic plasticity and memory formation.     

表观遗传学: 生物细胞非编码RNA调控的研究进展

表观遗传学是研究基因表达发生了可遗传的改变, 而DNA序列不发生改变的一门生物学分支, 对细胞的生长分化及肿瘤的发生发展至关重要。表观遗传学的主要机制包括DNA甲基化、组蛋白修饰及新近发现的非编码RNA。非编码RNA 是指不能翻译为蛋白的功能性RNA分子, 其中常见的具调控作用的非编码RNA包括小干涉RNA、miRNA、piRNA 以及长链非编码RNA。近年来大量研究表明非编码RNA在表观遗传学的调控中扮演了越来越重要的角色。文章综述了近年来生物细胞非编码RNA调控的表观遗传学研究进展, 以有助于理解哺乳动物细胞中非编码RNA及其调控机制和功能。     

作物数量性状研究进展

作物主要农艺性状和经济性状大多属于数量性状。传统数量遗传学采用数理统计方法,把控制数量性状的多基因系统作为一个整体进行研究。DNA分子标记技术的出现和发展,为数量性状研究提供了重要工具。自20世纪80年代以来,QTL定位的统计分析方法发展很快,先后提出单标记分析法、区间作图法及复合区间作图法等。目前,作物QTL研究取得了重要进展,一些重要作物、重要农艺性状的主效QTL基因已被相继克隆成功,作物数量性状的研究已经成为一个具有勃勃生机的热门领域。     

Epigenetics and cell cycle regulation in cystogenesis

The role of genetic mutations in the development of polycystic kidney disease (PKD), such as alterations in PKD1 and PKD2 genes in autosomal dominant PKD (ADPKD), is well understood. However, the significance of epigenetic mechanisms in the progression of PKD remains unclear and is increasingly being investigated. The term of epigenetics describes a range of mechanisms in genome function that do not solely result from the DNA sequence itself. Epigenetic information can be inherited during mammalian cell division to sustain phenotype specifically and physiologically responsive gene expression in the progeny cells. A multitude of functional studies of epigenetic modifiers and systematic genome-wide mapping of epigenetic marks reveal the importance of epigenomic mechanisms, including DNA methylation, histone/chromatin modifications and non-coding RNAs, in PKD pathologies. Deregulated proliferation is a characteristic feature of cystic renal epithelial cells. Moreover, defects in many of the molecules that regulate the cell cycle have been implicated in cyst formation and progression. Recent evidence suggests that alterations of DNA methylation and histone modifications on specific genes and the whole genome involved in cell cycle regulation and contribute to the pathogenesis of PKD. This review summarizes the recent advances of epigenetic mechanisms in PKD, which helps us to define the term of “PKD epigenetics” and group PKD epigenetic changes in three categories. In particularly, this review focuses on the interplay of epigenetic mechanisms with cell cycle regulation during normal cell cycle progression and cystic cell proliferation, and discusses the potential to detect and quantify DNA methylation from body fluids as diagnostic/prognostic biomarkers. Collectively, this review provides concepts and examples of epigenetics in cell cycle regulation to reveal a broad view of different aspects of epigenetics in biology and PKD, which may facilitate to identify possible novel therapeutic intervention points and to explore epigenetic biomarkers in PKD.     

Epigenetics Alterations in Preneoplastic and Neoplastic Lesions of the Cervix

ABSTRACT: Cervical cancer (CC) is one of the most malignant tumors and the second or third most common type of cancer in women worldwide. The association between human papillomavirus (HPV) and CC is widely known and accepted (99.7% of cases). At present, the pathogenesis mechanisms of CC are not entirely clear. It has been shown that inactivation of tumor suppressor genes and activation of oncogenes play a significant role in carcinogenesis, caused by the genetic and epigenetic alterations. In the past, it was generally thought that genetic mutation was a key event of tumor pathogenesis, especially somatic mutation of tumor suppressor genes. With deeper understanding of tumors in recent years, increasing evidence has shown that epigenetic silencing of those genes, as a result of aberrant hypermethylation of CpG islands in promoters and histone modification, is essential to carcinogenesis and metastasis. The term epigenetics refers to heritable changes in gene expression caused by regulation mechanisms, other than changes in DNA sequence. Specific epigenetic processes include DNA methylation, chromotin remodeling, histone modification, and microRNA regulations. These alterations, in combination or individually, make it possible to establish the methylation profiles, histone modification maps, and expression profiles characteristic of this pathology, which become useful tools for screening, early detection, or prognostic markers in cervical cancer. This paper reviews recent epigenetics research progress in the CC study, and tries to depict the relationships between CC and DNA methylation, histone modification, as well as microRNA regulations.     

原发性肝癌的表观遗传学及其治疗

肝癌是一种严重危害人类健康的恶性疾病,在全世界患癌人群中,肝癌的发生率排第五,死亡率排第二。原发性肝癌(Hepatocellular carcinoma, HCC)是最普遍的肝癌组织学亚型,属于异质性疾病,对其治疗涉及遗传学、基因组学、环境毒理学等多个领域。尽管许多分子靶向治疗药物如索拉菲尼等已经进入临床应用并证明有效,但细胞毒性等负效应不容忽视,目前迫切需要新的治疗靶点和药物高效并选择性的杀伤肝癌细胞。大量证据表明,肝脏肿瘤的发生和发展与表观遗传学密切相关,DNA甲基化、组蛋白修饰、miRNA表达的异常及表观遗传相关基因表达的异常都是HCC中显著的表观遗传异常现象。表观治疗药物可能会逆转异常基因的表达,从而使HCC的发生和发展得以控制。文章综述了HCC表观遗传学治疗方面的研究进展,展望了未来利用类似的疗法治疗肝癌的潜力。     

Current progress in epigenetic research for hepatocarcinomagenesis

Hepatocellular carcinoma is the main type of primary liver cancer, and also one of the most malignant tumors. At present, the pathogenesis mechanisms of liver cancer are not entirely clear. It has been shown that inactivation of tumor suppressor genes and activation of oncogenes play a significant role in carcinogenesis, caused by the genetic and epigenetic aberrance. In the past, people generally thought that genetic mutation is a key event of tumor pathogenesis, and somatic mutation of tumor suppressor genes is in particular closely associated with oncogenesis. With deeper understanding of tumors in recent years, increasing evidence has shown that epigenetic silencing of those genes, as a result of aberrant hypermethylation of CpG islands in promoters and histone modification, is essential to carcinogenesis and metastasis. The term epigenetics refers to heritable changes in gene expression caused by regulation mechanisms, other than changes in the underlying DNA sequence. Specific epigenetic processes include DNA methylation, genome imprinting, chromotin remodeling, histone modification and microRNA regulations. This paper reviews recent epigenetics research progress in the hepatocellular carcinoma study, and tries to depict the relationships between hepatocellular carcinomagenesis and DNA methylation as well as microRNA regulation. Supported by National Basic Research Program of China (Grant No. 2006CD910402) and Science and Technology Commission of Shanghai Municipality (Grant No. 05DZ22201 and 08JC1416400).     

The Russian Biological Student Microscopes

Our out-of-school practical exercise was designed to bring upper secondary school students in contact with one of the most exciting and expanding topics in biology today: epigenetics. In school, students only study the basics in genetics and the respective investigation techniques as provided by the syllabus. For a practical exercise in epigenetics, however, they need additional knowledge. Hence, they are introduced to the subject of epigenetics and its molecular mechanisms. Students are asked to examine the different DNA methylation conditions of lambda DNA using both a restriction assay and gel electrophoresis in an out-of-school laboratory. DNA methylation is one of the major epigenetic mechanisms which have significant effects on gene expression; studies on monozygotic twins have shown that it is influenced by the environment. This exercise enables students to correctly identify the different methylation conditions of distributed lambda DNA samples. In doing so, they receive a first introduction to one epigenetic mechanism. The necessity for students to experience science in out-of-school settings has been shown by several scholars. The practical exercise we are proposing in this article was elaborated for such learning opportunities for upper secondary students to gain insight into contemporary science issues.     

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.     

Epigenetic gene regulation in stem cells and correlation to cancer

Through the classic study of genetics, much has been learned about the regulation and progression of human disease. Specifically, cancer has been defined as a disease driven by genetic alterations, including mutations in tumor-suppressor genes and oncogenes, as well as chromosomal abnormalities. However, the study of normal human development has identified that in addition to classical genetics, regulation of gene expression is also modified by ‘epigenetic’ alterations including chromatin remodeling and histone variants, DNA methylation, the regulation of polycomb group proteins, and the epigenetic function of non-coding RNA. These changes are modifications inherited during both meiosis and mitosis, yet they do not result in alterations of the actual DNA sequence. A number of biological questions are directly influenced by epigenetics, such as how does a cell know when to divide, differentiate or remain quiescent, and more importantly, what happens when these pathways become altered? Do these alterations lead to the development and/or progression of cancer? This review will focus on summarizing the limited current literature involving epigenetic alterations in the context of human cancer stems cells (CSCs). The extent to which epigenetic changes define cell fate, identity, and phenotype are still under intense investigation, and many questions remain largely unanswered. Before discussing epigenetic gene silencing in CSCs, the different classifications of stem cells and their properties will be introduced. This will be followed by an introduction to the different epigenetic mechanisms. Finally, there will be a discussion of the current knowledge of epigenetic modifications in stem cells, specifically what is known from rodent systems and established cancer cell lines, and how they are leading us to understand human stem cells.     

The use of selection in recovery of transgenic targets for mutation analysis

Transgenic animal mutagenesis assays using lambda shuttle vectors have recently been described for isolation and characterization of spontaneous and chemical induced DNA mutations. Extensive information on lambda and E. coli genetics provides a wealth of techniques to allow selection of mutant target genes. Here we describe the modification of an E. coli host which permits two methods for the direct selection of mutant genes. These methods reduce the number of plates needed to be screened for a comparable amount of frequency data by 20–100-fold and thus provide a significant savings of the materials and time required for the screening of mutations. In addition, mutants selected by these approaches described here may alter or broaden the spectrum of mutations that are recoverable. Ultimately, a combination of selective and nonselective techniques may prove valuable for the analysis of mutations produced in vivo in transgenic animals.     

Discovery of gene families and alternatively spliced variants by RecA-mediated cloning

Probing the functional complexity of the human genome will require new gene cloning techniques, not only to discover intraspecies gene homologs and interspecies gene orthologs, but also to identify alternatively spliced gene variants. We report homologous cDNA cloning methods that allow cloning of gene family members, genes from different species, and alternatively spliced gene variants. We cloned human 14-3-3 gene family members using DNA probes with as much as 35% sequence divergence, cloned alternatively spliced gene forms of Rad51D, and cloned a novel splice form of the human 14-3-3 theta gene with a unique expression pattern. Interspecies gene cloning was demonstrated for the mouse Rad51C and mouse beta-actin genes using human gene probes. The gene family cloning method is fast, efficient, and free from PCR errors; moreover, it exploits the abilities of RecA protein to pair homologous or partially homologous DNA sequences stably in kinetically trapped, multistranded DNA hybrids that can be used for subsequent gene clone enrichment.     

外因遗传学及其重要意义

本文综述外因遗传学的提出、发展的各个主要阶段和该学科的确立。基因特性可以从两个层面来进行研究,（1）是遗传物质的传递,（2）是从基因型到表型这个过程。外因遗传学从1942年沃丁顿提出,经1987年霍利迪的发展,到现今在各类生物包括人类中积累了丰富的资料,并能够用化学分子来说明其作用机理。外因遗传学现代的定义为：基因功能的改变,凡未牵涉到DNA的序列,又可通过细胞的有丝或减数分裂而遗传者,称为外因遗传。作者介绍了外因遗传的范围,如：X染色体剂量补偿、基因组印记、分化细胞的基因组重新编程、癌基因、转录的分子调节、RNA介导的基因沉默、组蛋白码、着丝粒的遗传和进化以及外因遗传的进化。此外,还有科学界的反应和评价,包括其在人类生物学和医学方面的重要性和该理论的重大的意义。组蛋白码不同于DNA码,DNA码需要精确拷贝,而且是静止的;而外因遗传就不是如此之僵硬,而具有一定的弹性,因为组蛋白码是决定于其上下文的,可在不同场景下组合成不同的码,它是为其他的蛋白质所读的。遗传需要稳定性,也需要根据内因和外因的变化而有灵活性,DNA码和组蛋白码相辅相成,对复杂的生物是必备的。 The Meaning of Epigenetics HU Kai The Tropical Biology Center,Hainan University,Haikou,Hainan 570028,China Abstract:Epigenetics,the term was introduced by Conrad H.Waddington,in 1942,he said that to compare genetics with epigenetics,the study of the processes by which genotype gives rise to phenotype.In 1987,Robin Holliday redefined epigenetic as “Nuclear inheritance which is not based on differences in DNA sequence”.The author of this paper introduced that in Science,10 August 2001,there was a special collection of review articles focused on the topic of epigenetics.The new “histone code” hypothesis states that the highly modifiable amino termini could carry their own combinatorial codes to help control phenotype,and that part of this code is heritable.And in light of this hypothesis,researchers are approaching further possibilities in human biology and types of cancer and other diseases. Key words：epigenetics; gene expressing     

Synergy of Homocysteine, MicroRNA, and Epigenetics: A Novel Therapeutic Approach for Stroke

Homocysteine (Hcy) is a thiol-containing amino acid formed during methionine metabolism. Elevated level of Hcy is known as hyperhomocysteinemia (HHcy). HHcy is an independent risk factor for cerebrovascular diseases such as stroke, dementia, Alzheimer’s disease, etc. Stroke, which is caused by interruption of blood supply to the brain, is one of the leading causes of death and disability in a number of people worldwide. The HHcy causes an increased carotid artery plaque that may lead to ischemic stroke but the mechanism is currently not well understood. Though mutations or polymorphisms in the key genes of Hcy metabolism pathway have been well elucidated in stroke, emerging evidences suggested epigenetic mechanisms equally play an important role in stroke development such as DNA methylation, chromatin remodeling, RNA editing, noncoding RNAs (ncRNAs), and microRNAs (miRNAs). However, there is no review available yet that describes the role of genetics and epigenetics during HHcy in stroke. The current review highlights the role of genetics and epigenetics in stroke during HHcy and the role of epigenetics in its therapeutics. The review also highlights possible epigenetic mechanisms, potential therapeutic molecules, putative challenges, and approaches to deal with stroke during HHcy.