CRISPR-based genomic loci labeling revealed ordered spatial organization of chromatin in living diploid human cells

The eukaryotic genome is compacted in the form of chromatin within the nucleus. Whether the spatial distribution of the genome is ordered or not has been a longstanding question. Answering this question would enable us to understand nuclear organization and cellular processes more deeply. Here, we applied a modified CRISPR/dCas9 system to label the randomly selected genomic loci in diploid living cells, which were visualized by high-resolution wide-field imaging. To analyze the spatial positions of three pairs of genomic loci, three sets of parameters were progressively measured: i) the linear distance between alleles; ii) the radial distribution of the genomic loci; and iii) the linear distances between three pairs of genomic loci on nonhomologous chromosomes. By accurate labeling, geometric measuring and statistical analysis, we demonstrated that the distribution of these genomic loci in the 3D space of the nucleus is relatively stable in both late G1 and early S phases. Collectively, our data provided visual evidence in live cells, which implies the orderly spatial organization of chromatin in the nucleus. The combination of orderliness and flexibility ensures the methodical and efficient operation of complex life systems. How the nucleus adopts this ordered 3D structure in living cells is thought-provoking.     

Meet the neighbours: tools to dissect nuclear structure and function

The eukaryotic cell nucleus displays a high degree of spatial organization, with discrete functional subcompartments that provide microenvironments where specialized processes take place. Concordantly, the genome also adopts defined conformations that, in part, enable specific genomic regions to interface with these functional centers. Yet the roles of many subcompartments and the genomic regions that contact them have not been explored fully. More fundamentally, it is not entirely clear how genome organization impacts function, and vice versa. The past decade has witnessed the development of a new breed of methods that are capable of assessing the spatial organization of the genome. These stand to further our understanding of the relationship between genome structure and function, and potentially assign function to various nuclear subcompartments. Here, we review the principal techniques used for analyzing genomic interactions, the functional insights they have afforded and discuss the outlook for future advances in nuclear structure and function dynamics.     

凝溶胶蛋白的结构与功能

凝溶胶蛋白（gelsolin）是凝溶胶蛋白超家族的成员之一,是一种重要的肌动蛋白结合蛋白,其通过切断、封端肌动蛋白丝,或使肌动蛋白聚集成核等方式来控制肌动蛋白的结构.凝溶胶蛋白除了在重组肌动蛋白丝中发挥作用以外,还在细胞运动、控制细胞程序性死亡等细胞活动中发挥重要的作用.此外,肿瘤细胞中凝溶胶蛋白的表达量也发生变化.凝溶胶蛋白的变异还是某些遗传疾病的基础.最近的研究发现,凝溶胶蛋白可以作为转录辅激活蛋白,促进雄激素受体的转录活性.本文对凝溶胶蛋白的结构特点、参与调节细胞的功能和机制及其研究现状进行概述.     

The Organism: A Crucial Genomic Context in Molecular Epigenetics?

Summary Whereas genetics refers to the study and mapping of linear nucleotide sequences, their mutations and inheritance, epigenetics refers to the structural organization and evolution of the genome. Epigenetic studies indicate that not all heritable information leading to the phenotype is “inscribed” in the DNA base sequence. In this sense, epigenetics — as the term indicates — goes beyond genetics, thereby (1) leaving behind the gene-centered view from within molecular biology itself, and (2) urging bio-philosophers to change their focus from criticizing the central dogma to evaluating new developments in molecular research. In the epigenetic approach, a hierarchy of genomic contexts can be revealed, consisting basically of an intracellular, an intercellular, and an organismic level. The first explorations on the organismic level suggest that under certain conditions the somatic constitution of the organism and how it stands in close interaction with its environment are to be taken into account as factors influencing the genomic constitution. Depending on the specificity of these conditions, the organism and its history and actuality can be seen as a crucial genomic context — leading to a more complex perception of the local dynamics and the structure of the genome and its consequences for development and evolution. This “organism in the world” view fits well with the philosophical tradition of Developmental Systems Theory, although epigeneticists seek to enlarge the genetic picture of biology by gradually expanding the range of molecular processes which influence the genome, thereby decentralizing the sovereign role of the genome, without loosing track of experimental demands.     

The genome in space and time: Does form always follow function?

Recent systematic studies using newly developed genomic approaches have revealed common mechanisms and principles that underpin the spatial organization of eukaryotic genomes and allow them to respond and adapt to diverse functional demands. Genomes harbor, interpret, and propagate genetic and epigenetic information, and the three-dimensional (3D) organization of genomes in the nucleus should be intrinsically linked to their biological functions. However, our understanding of the mechanisms underlying both the topological organization of genomes and the various nuclear processes is still largely incomplete. In this essay, we focus on the functional relevance as well as the biophysical properties of common organizational themes in genomes (e.g. looping, clustering, compartmentalization, and dynamics), and examine the interconnection between genome structure and function from this angle. Present evidence supports the idea that, in general, genome architecture reflects and influences genome function, and is relatively stable. However, the answer as to whether genome architecture is a hallmark of cell identity remains elusive.     

Somatic genome variations in health and disease

It is hard to imagine that all the cells of the human organism (about 10(14)) share identical genome. Moreover, the number of mitoses (about 10(16)) required for the organism's development and maturation during ontogeny suggests that at least a proportion of them could be abnormal leading, thereby, to large-scale genomic alterations in somatic cells. Experimental data do demonstrate such genomic variations to exist and to be involved in human development and interindividual genetic variability in health and disease. However, since current genomic technologies are mainly based on methods, which analyze genomes from a large pool of cells, intercellular or somatic genome variations are significantly less appreciated in modern bioscience. Here, a review of somatic genome variations occurring at all levels of genome organization (i.e. DNA sequence, subchromosomal and chromosomal) in health and disease is presented. Looking through the available literature, it was possible to show that the somatic cell genome is extremely variable. Additionally, being mainly associated with chromosome or genome instability (most commonly manifesting as aneuploidy), somatic genome variations are involved in pathogenesis of numerous human diseases. The latter mainly concerns diseases of the brain (i.e. autism, schizophrenia, Alzheimer's disease) and immune system (autoimmune diseases), chromosomal and some monogenic syndromes, cancers, infertility and prenatal mortality. Taking into account data on somatic genome variations and chromosome instability, it becomes possible to show that related processes can underlie non-malignant pathology such as (neuro)degeneration or other local tissue dysfunctions. Together, we suggest that detection and characterization of somatic genome behavior and variations can provide new opportunities for human genome research and genetics.     

Interplay between genome organization and epigenomic alterations of pericentromeric DNA in cancer

In eukaryotic genome biology, the genomic organization inside the three-dimensional(3 D) nucleus is highly complex, and whether this organization governs gene expression is poorly understood. Nuclear lamina(NL)is a filamentous meshwork of proteins present at the lining of inner nuclear membrane that serves as an anchoring platform for genome organization. Large chromatin domains termed as lamina-associated domains(LADs), play a major role in silencing genes at the nuclear periphery. The interaction of the NL and genome is dynamic and stochastic. Furthermore, many genes change their positions during developmental processes or under disease conditions such as cancer, to activate certain sorts of genes and/or silence others. Pericentromeric heterochromatin(PCH) is mostly in the silenced region within the genome, which localizes at the nuclear periphery. Studies show that several genes located at the PCH are aberrantly expressed in cancer. The interesting question is that despite being localized in the pericentromeric region,how these genes still manage to overcome pericentromeric repression. Although epigenetic mechanisms control the expression of the pericentromeric region, recent studies about genome organization and genome-nuclear lamina interaction have shed light on a new aspect of pericentromeric gene regulation through a complex and coordinated interplay between epigenomic remodeling and genomic organization in cancer.     

基因编辑技术在斑马鱼中的应用及研究进展

基因编辑技术通过对特定DNA片段的插入、敲除、修饰或替换等,实现对生物体中目标基因的编辑。与早期基因工程技术将遗传物质随机插入宿主基因组中的方式不同的是,基因编辑技术能够定点需要插入的位置,从而实现对生物体基因组特定位点的准确修饰、人为地改造生物体的遗传信息,目前广泛应用于斑马鱼的基因组学、遗传发育和基因功能研究中。其方法包括诱变技术、Tol2转座子、Morpholino、ZFNs、TALEN和CRISPR/Cas系统等。本研究主要介绍了基因编辑技术的作用机理与发展概况。作为一种精准而高效的基因工程方法,基因编辑技术在近年来得到了飞速地发展。它既可以采用对特定基因的靶向突变来研究基因的功能,也可以通过将功能性基因插入并替代缺陷基因而用于某些遗传性疾病的基因治疗。可以肯定的是,基因编辑技术未来将在基础生物学、医学、生物技术等多个领域具有重要的研究价值和应用价值。     

Unconventional Myosins,Actin Dynamics and Endocytosis: A Ménage à Trois?

Ever since the discovery of class I myosins, the first nonmuscle myosins, about 30 years ago, the history of unconventional myosins has been linked to the organization and working of actin filaments. It slowly emerged from studies of class I myosins in lower eukaryotes that they are involved in mechanisms of endocytosis. Most interestingly, a flurry of recent findings assign a more active role to class I myosins in regulating the spatial and temporal organization of actin filament nucleation and elongation. The results highlight the multiple links between class I myosins and the major actin nucleator, the Arp2/3 complex, and its newly described activators. Two additional types of unconventional myosins, myosinIX, and Dictyostelium discoideum MyoM, have recently been tied to the signaling pathways controlling actin cytoskeleton remodeling. The present review surveys the links between these three classes of molecular motors and the complex cellular processes of endocytosis and actin dynamics, and concentrates on a working model accounting for the function of class I myosins via recruitment of the machinery responsible for actin nucleation and elongation .     

Drosophila as a screening tool to study human neurodegenerative diseases

In an aging society, research involving neurodegenerative disorders is of paramount importance. Over the past few years, research on Alzheimer's and Parkinson's diseases has made tremendous progress. Experimental studies, however, rely mostly on transgenic animal models, preferentially using mice. Although experiments on mice have enormous advantages, they also have some inherent limitations, some of which can be overcome by the use of Drosophila melanogaster as an experimental animal. Among the major advantages of using the fly is its small genome, which can also be modified very easily. The fact that its genome lends itself to diverse alterations (e. g. mutagenesis, transposons) has made the fly a useful organism to perform large‐scale and genome‐wide screening approaches. This has opened up an entirely new field of experimental research aiming to elucidate genetic interactions and screen for modifiers of disease processes in vivo. Here, we provide a brief overview of how flies can be used to analyze molecular mechanisms underlying human neurodegenerative diseases.     

Regulation of global acetylation in mitosis through loss of histone acetyltransferases and deacetylases from chromatin

Histone acetylation, a reversible modification of the core histones, is widely accepted to be involved in remodeling chromatin organization for genetic reprogramming. Histone acetylation is a dynamic process that is regulated by two classes of enzymes, the histone acetyltransferases (HATs) and histone deacetylases (HDACs). Although promoter-specific acetylation and deacetylation has received most of the recent attention, it is superimposed upon a broader acting and dynamic acetylation that profoundly affects many nuclear processes. In this study, we monitored this broader histone acetylation as cells enter and exit mitosis. In contrast to the hypothesis that HATs and HDACs remain bound to mitotic chromosomes to provide an epigenetic imprint for postmitotic reactivation of the genome, we observed that HATs and HDACs are spatially reorganized and displaced from condensing chromosomes as cells progress through mitosis. During mitosis, HATs and HDACs are unable to acetylate or deacetylate chromatin in situ despite remaining fully catalytically active when isolated from mitotic cells and assayed in vitro. Our results demonstrate that HATs and HDACs do not stably bind to the genome to function as an epigenetic mechanism of selective postmitotic gene activation. Our results, however, do support a role for spatial organization of these enzymes within the cell nucleus and their relationship to euchromatin and heterochromatin postmitotically in the reactivation of the genome.     

Biochemical and cell biological analysis of actin in the nematode Caenorhabditis elegans

The nematode Caenorhabditis elegans has long been a useful model organism for muscle research. Its body wall muscle is obliquely striated muscle and exhibits structural similarities with vertebrate striated muscle. Actin is the core component of the muscle thin filaments, which are highly ordered in sarcomeric structures in striated muscle. Genetic studies have identified genes that regulate proper organization and function of actin filaments in C. elegans muscle, and sequence of the worm genome has revealed a number of conserved candidate genes that may regulate actin. To precisely understand the functions of actin-binding proteins, such genetic and genomic studies need to be complemented by biochemical characterization of these actin-binding proteins in vitro. This article describes methods for purification and biochemical characterization of actin from C. elegans. Although rabbit muscle actin is commonly used to characterize actin-binding proteins from many eukaryotic organisms, we detect several quantitative differences between C. elegans actin and rabbit muscle actin, highlighting that use of actin from an appropriate source is important in some cases. Additionally, we describe probes for cell biological analysis of actin in C. elegans.     

Impact of transposable elements on the evolution of mammalian gene regulation

Transposable elements (TEs) are present in all organisms and nearly half of the human and mouse genome is derived from ancient transpositions. This fact alone suggests that TEs have played a major role in genome organization and evolution. Studies undertaken over the last two decades or so clearly show that TEs of various kinds have played an important role in organism evolution. Here we review the impact TEs have on the evolution of gene regulation and gene function with an emphasis on humans. Understanding the mechanisms resulting in genomic change is central to our understanding of gene regulation, genetic disease and genome evolution. Full comprehension of these biological processes is not possible without an in depth knowledge of how TEs impact upon the genome.