Gene expression and nuclear architecture during development and differentiation

Development requires a precise program of gene expression to be carried out. Much work has focussed on the regulatory networks that control gene expression, for example in response to external cues. However, it is important to recognize that these regulatory events take place within the physical context of the nucleus, and that the physical position of a gene within the nuclear volume can have strong influences on its regulation and interactions. The first part of this review will summarize what is currently known about nuclear architecture, that is, the large-scale three-dimensional arrangement of chromosome loci within the nucleus. The remainder of the review will examine developmental processes from the point of view of the nucleus.     

Dynamics of a neural system with a multiscale architecture

The architecture of the brain is characterized by a modular organization repeated across a hierarchy of spatial scales-neurons, minicolumns, cortical columns, functional brain regions, and so on. It is important to consider that the processes governing neural dynamics at any given scale are not only determined by the behaviour of other neural structures at that scale, but also by the emergent behaviour of smaller scales, and the constraining influence of activity at larger scales. In this paper, we introduce a theoretical framework for neural systems in which the dynamics are nested within a multiscale architecture. In essence, the dynamics at each scale are determined by a coupled ensemble of nonlinear oscillators, which embody the principle scale-specific neurobiological processes. The dynamics at larger scales are 'slaved' to the emergent behaviour of smaller scales through a coupling function that depends on a multiscale wavelet decomposition. The approach is first explicated mathematically. Numerical examples are then given to illustrate phenomena such as between-scale bifurcations, and how synchronization in small-scale structures influences the dynamics in larger structures in an intuitive manner that cannot be captured by existing modelling approaches. A framework for relating the dynamical behaviour of the system to measured observables is presented and further extensions to capture wave phenomena and mode coupling are suggested.     

DNA replication and nuclear architecture

The model of in situ DNA replication provided by immunofluorescence and confocal imaging is compared with observations obtained by electron microscopic studies. Discrepancies between both types of observations call into question the replication focus as a persistent nuclear structure and as a replication entity where DNA replication takes place. Most electron microscopic analyses reveal that replication sites are confined to dispersed chromatin areas at the periphery of condensed chromatin, and the distribution of replication factors exhibits the same localization pattern. Moreover, rapid migration of newly synthesized DNA from the replication sites towards the interior of condensed chromatin regions obviously takes place during S-phase. It implies modifications of replication domains, hardly detectable by fluorescence microscopy. The confrontation of different observations carried out at light microscopic or electron microscopic levels of resolution lead to a conclusion that a combination of in vivo fluorescence analysis with a subsequent ultrastructural investigation performed on the same cells will represent an optimal approach in future studies of nuclear functions in situ.     

Histone modifications and nuclear architecture: a review.

Epigenetic modifications, such as acetylation, phosphorylation, methylation, ubiquitination, and ADP ribosylation, of the highly conserved core histones, H2A, H2B, H3, and H4, influence the genetic potential of DNA. The enormous regulatory potential of histone modification is illustrated in the vast array of epigenetic markers found throughout the genome. More than the other types of histone modification, acetylation and methylation of specific lysine residues on N-terminal histone tails are fundamental for the formation of chromatin domains, such as euchromatin, and facultative and constitutive heterochromatin. In addition, the modification of histones can cause a region of chromatin to undergo nuclear compartmentalization and, as such, specific epigenetic markers are non-randomly distributed within interphase nuclei. In this review, we summarize the principles behind epigenetic compartmentalization and the functional consequences of chromatin arrangement within interphase nuclei.     

长链非编码RNA通过细胞核高级结构调控真核基因表达及其临床意义

长链非编码RNA(long non-coding RNA, lncRNA)是一类转录本长度超过200nt、不编码蛋白质的RNA。近年来,随着染色质构象捕获及转录组测序等技术的发展,lncRNA与染色质构象间的关系越来越受到重视。多项研究表明,lncRNA在基因调控网络中具有重要的作用,可通过影响细胞核高级结构的动态变化来调控真核基因的表达。因其广泛的基因调控功能及在肿瘤发生过程中的重要作用,lncRNA被认为是未来肿瘤临床诊断和预后判定的新型标志物之一。本文旨在介绍lncRNA改变细胞核高级结构从而调控关键基因表达的分子机制,并详细介绍lncRNA在肿瘤治疗中的临床意义。     

Rapidly evolving lamins in a chordate, Oikopleura dioica, with unusual nuclear architecture

Metazoan lamins are implicated in the organization of numerous critical nuclear processes. Among chordates, the appendicularian, Oikopleura dioica, has an unusually short life cycle involving rapid growth through extensive recourse to endoreduplication, a characteristic more associated with some invertebrates. In some tissues, this is accompanied by the formation of elaborate, bilaterally symmetric nuclear morphologies associated with specific gene expression patterns. Lamin composition can mediate nuclear shape in spermiogenesis as well as during pathological and normal aging and we have analyzed the O. dioica lamin and intermediate filament (IF) complement, comparing it to that present in other deuterostomes. O. dioica has one lamin gene coding two splice variants. Both variants share with the sister class ascidians a highly reduced C-terminal tail region lacking the immunoglobulin fold, indicating this derivation occurred at the base of the urochordate lineage. The OdLamin2 variant has a unique insertion of 63 amino acids in the normally short N-terminal region and has a developmental expression profile corresponding to the occurrence of endocycling. O. dioica has 4 cytoplasmic IF proteins, IF-A, C, Dalpha, and Dbeta. No homologues to the ascidian IF-B or F proteins were identified, reinforcing the suggestion that these proteins are unique to ascidians. The degree of sequence evolution in the rod domains of O. dioica cytoplasmic IF proteins and their closest ascidian and vertebrate homologues was similar. In contrast, whereas the rate of lamin B rod domain sequence evolution has also been similar in vertebrates, cephalochordates and the sea urchin, faster rates have occurred among the urochordates, with the O. dioica lamin displaying a far greater rate than any other lamin.     

Dynamic genome architecture in the nuclear space: regulation of gene expression in three dimensions

The regulation of gene expression is mediated by interactions between chromatin and protein complexes. The importance of where and when these interactions take place in the nucleus is currently a subject of intense investigation. Increasing evidence indicates that gene activation or silencing is often associated with repositioning of the locus relative to nuclear compartments and other genomic loci. At the same time, however, structural constraints impose limits on chromatin mobility. Understanding how the dynamic nature of the positioning of genetic material in the nuclear space and the higher-order architecture of the nucleus are integrated is therefore essential to our overall understanding of gene regulation.     

The nuclear envelope as an integrator of nuclear and cytoplasmic architecture

Initially perceived as little more than a container for the genome, our view of the nuclear envelope (NE) and its role in defining global nuclear architecture has evolved significantly in recent years. The recognition that certain human diseases arise from defects in NE components has provided new insight into its structural and regulatory functions. In particular, NE defects associated with striated muscle disease have been shown to cause structural perturbations not just of the nucleus itself but also of the cytoplasm. It is now becoming increasingly apparent that these two compartments display co-dependent mechanical properties. The identification of cytoskeletal binding complexes that localize to the NE now reveals a molecular framework that can seamlessly integrate nuclear and cytoplasmic architecture.     

Gene dynamics and nuclear architecture during differentiation

Abstract Recent advances have demonstrated that placing genes in a specific nuclear context plays an important role in the regulation of coordinated gene expression, thus adding an additional level of complexity to the mechanisms of gene regulation. Differentiation processes are characterized by dynamic changes in gene activation and silencing. These alterations are often accompanied by gene relocations in relation to other genomic regions or to nuclear compartments. Unraveling of mechanisms and dynamics of chromatin positioning will thus expand our knowledge about cellular differentiation.