Association between active genes occurs at nuclear speckles and is modulated by chromatin environment

Transcription factories and spatial organization of eukaryotic genomes

The phenomenon of association of transcribed genes into so-called transcription factories and also the role of these associations in spatial organization of the eukaryotic genome are actively discussed in the modern literature. Some authors think that the association of transcribed genes into transcription factories constitutes a major factor supporting the function-dependent three-dimensional organization of the interphase genome. In spite of the obvious interest in the problem of spatial organization of transcription in the eukaryotic cell nucleus, the number of experimental studies of transcriptional factories remains rather limited and the results of these studies are often contradictory. In the current review we have tried to critically re-evaluate the published experimental results that constitute the basis for current models and also the models themselves. We have especially analyzed the existing contradictions and attempted to explain them whenever possible. We also discuss new models that can explain the biological significance of clustering of transcribed genes and show possible mechanisms of the origin of transcription factories in the course of evolution.

Herpesviral replication compartments move and coalesce at nuclear speckles to enhance export of viral late mRNA

The role of the intranuclear movement of chromatin in gene expression is not well-understood. Herpes simplex virus forms replication compartments (RCs) in infected cell nuclei as sites of viral DNA replication and late gene transcription. These structures develop from small compartments that grow in size, move, and coalesce. Quantitative analysis of RC trajectories, derived from 4D images, shows that most RCs move by directed motion. Directed movement is impaired in the presence of actin and myosin inhibitors as well as a transcription inhibitor. In addition, RCs coalesce at and reorganize nuclear speckles. Lastly, distinct effects of actin and myosin inhibitors on viral gene expression suggest that RC movement is not required for transcription, but rather, movement results in the bridging of transcriptionally active RCs with nuclear speckles to form structures that enhance export of viral late mRNAs.

Diverse gene reprogramming events occur in the same spatial clusters of distal regulatory elements

The spatial organization of genes in the interphase nucleus plays an important role in establishment and regulation of gene expression. Contradicting results have been reported to date, with little consensus about the dynamics of nuclear organization and the features of the contact loci. In this study, we investigated the properties and dynamics of genomic loci that are in contact with glucocorticoid receptor (GR)-responsive loci. We took a systematic approach, combining genome-wide interaction profiling by the chromosome conformation capture on chip (4C) technology with expression, protein occupancy, and chromatin accessibility profiles. This approach allowed a comprehensive analysis of how distinct features of the linear genome are organized in the three-dimensional nuclear space in the context of rapid gene regulation. We found that the transcriptional response to GR occurs without dramatic nuclear reorganization. Moreover, contrary to the view of transcription-driven organization, even genes with opposite transcriptional responses colocalize. Regions contacting GR-regulated genes are not particularly enriched for GR-regulated loci or for any functional group of genes, suggesting that these subnuclear environments are not organized to respond to a specific factor. The contact regions are, however, highly enriched for DNase I-hypersensitive sites that comprehensively mark cell-type-specific regulatory sites. These findings indicate that the nucleus is pre-organized in a conformation allowing rapid transcriptional reprogramming, and this organization is significantly correlated with cell-type-specific chromatin sites accessible to regulatory factors. Numerous open chromatin loci may be arranged in nuclear domains that are poised to respond to diverse signals in general and to permit efficient gene regulation.

Functional and mechanistic diversity of distal transcription enhancers

Biological differences among metazoans and between cell types in a given organism arise in large part due to differences in gene expression patterns. Gene-distal enhancers are key contributors to these expression patterns, exhibiting both sequence diversity and cell type specificity. Studies of long-range interactions indicate that enhancers are often important determinants of nuclear organization, contributing to a general model for enhancer function that involves direct enhancer-promoter contact. However, mechanisms for enhancer function are emerging that do not fit solely within such a model, suggesting that enhancers as a class of DNA regulatory element may be functionally and mechanistically diverse.

Gene positioning and expression

Within the nucleus, the genome is spatially organized. Individual chromosomes are non-randomly positioned with respect to each other and with respect to nuclear landmarks [1,2]. Furthermore, the position of individual genes can reflect their expression. Here we discuss two well-characterized examples of gene relocalization associated with transcriptional activation: 1) developmentally regulated genes that move from the nuclear periphery to transcription factories in the nucleoplasm upon induction and 2) genes that are targeted from the nucleoplasm to the nuclear periphery, through interactions with the nuclear pore complex (NPC), upon activation. Finally, we speculate as to the mechanistic and functional commonalities of these phenomena.

Nuclear speckles

Nuclear speckles, also known as interchromatin granule clusters, are nuclear domains enriched in pre-mRNA splicing factors, located in the interchromatin regions of the nucleoplasm of mammalian cells. When observed by immunofluorescence microscopy, they usually appear as 20-50 irregularly shaped structures that vary in size. Speckles are dynamic structures, and their constituents can exchange continuously with the nucleoplasm and other nuclear locations, including active transcription sites. Studies on the composition, structure, and dynamics of speckles have provided an important paradigm for understanding the functional organization of the nucleus and the dynamics of the gene expression machinery.

Global gene expression analysis of human erythroid progenitors

Understanding the pattern of gene expression during erythropoiesis is crucial for a synthesis of erythroid developmental biology. Here, we isolated 4 distinct populations at successive erythropoietin-dependent stages of erythropoiesis, including the terminal, pyknotic stage. The transcriptome was determined using Affymetrix arrays. First, we demonstrated the importance of using defined cell populations to identify lineage and temporally specific patterns of gene expression. Cells sorted by surface expression profile not only express significantly fewer genes than unsorted cells but also demonstrate significantly greater differences in the expression levels of particular genes between stages than unsorted cells. Second, using standard software, we identified more than 1000 transcripts not previously observed to be differentially expressed during erythroid maturation, 13 of which are highly significantly terminally regulated, including RFXAP and SMARCA4. Third, using matched filtering, we identified 12 transcripts not previously reported to be continuously up-regulated in maturing human primary erythroblasts. Finally, using transcription factor binding site analysis, we identified potential transcription factors that may regulate gene expression during terminal erythropoiesis. Our stringent lists of differentially regulated and continuously expressed transcripts containing many genes with undiscovered functions in erythroblasts are a resource for future functional studies of erythropoiesis. Our Human Erythroid Maturation database is available at https://cellline.molbiol.ox.ac.uk/eryth/index.html. [corrected].

Gadd45a is an RNA binding protein and is localized in nuclear speckles

Background

The Gadd45 proteins play important roles in growth control, maintenance of genomic stability, DNA repair, and apoptosis. Recently, Gadd45 proteins have also been implicated in epigenetic gene regulation by promoting active DNA demethylation. Gadd45 proteins have sequence homology with the L7Ae/L30e/S12e RNA binding superfamily of ribosomal proteins, which raises the question if they may interact directly with nucleic acids.

Principal Findings

Here we show that Gadd45a binds RNA but not single- or double stranded DNA or methylated DNA in vitro. Sucrose density gradient centrifugation experiments demonstrate that Gadd45a is present in high molecular weight particles, which are RNase sensitive. Gadd45a displays RNase-sensitive colocalization in nuclear speckles with the RNA helicase p68 and the RNA binding protein SC35. A K45A point mutation defective in RNA binding was still active in DNA demethylation. This suggests that RNA binding is not absolutely essential for demethylation of an artificial substrate. A point mutation at G39 impared RNA binding, nuclear speckle localization and DNA demethylation, emphasizing its relevance for Gadd45a function.

Significance

The results implicate RNA in Gadd45a function and suggest that Gadd45a is associated with a ribonucleoprotein particle.

Spatial Organization and Dynamics of Transcription Elongation and Pre-mRNA Processing in Live Cells

During the last 30 years, systematic biochemical and functional studies have significantly expanded our knowledge of the transcriptional molecular components and the pre-mRNA processing machinery of the cell. However, our current understanding of how these functions take place spatiotemporally within the highly compartmentalized eukaryotic nucleus remains limited. Moreover, it is increasingly clear that “the whole is more than the sum of its parts” and that an understanding of the dynamic coregulation of genes is essential for fully characterizing complex biological phenomena and underlying diseases. Recent technological advances in light microscopy in addition to novel cell and molecular biology approaches have led to the development of new tools, which are being used to address these questions and may contribute to achieving an integrated and global understanding of how the genome works at a cellular level. Here, we review major hallmarks and novel insights in RNA polymerase II activity and pre-mRNA processing in the context of nuclear organization, as well as new concepts and challenges arising from our ability to gather extensive dynamic information at the single-cell resolution.

Dynamic plasticity of large-scale chromatin structure revealed by self-assembly of engineered chromosome regions

Interphase chromatin compaction well above the 30-nm fiber is well documented, but the structural motifs underlying this level of chromatin folding remain unknown. Taking a reductionist approach, we analyzed in mouse embryonic stem (ES) cells and ES-derived fibroblasts and erythroblasts the folding of 10-160-megabase pair engineered chromosome regions consisting of tandem repeats of bacterial artificial chromosomes (BACs) containing approximately 200 kilobases of mammalian genomic DNA tagged with lac operator (LacO) arrays. Unexpectedly, linear mitotic and interphase chromatid regions formed from noncontiguously folded DNA topologies. Particularly, in ES cells, these model chromosome regions self-organized with distant sequences segregating into functionally distinct, compact domains. Transcriptionally active and histone H3K27me3-modified regions positioned toward the engineered chromosome subterritory exterior, with LacO repeats and the BAC vector backbone localizing within an H3K9me3, HP1-enriched core. Differential compaction of Dhfr and alpha- and beta-globin transgenes was superimposed on dramatic, lineage-specific reorganization of large-scale chromatin folding, demonstrating a surprising plasticity of large-scale chromatin organization.

Human transcriptional interactome of chromatin contribute to gene co-expression

Background

Transcriptional interactome of chromatin is one of the important mechanisms in gene transcription regulation. By chromatin conformation capture and 3D FISH experiments, several chromatin interactions cases among sequence-distant genes or even inter-chromatin genes were reported. However, on genomics level, there is still little evidence to support these mechanisms. Recently based on Hi-C experiment, a genome-wide picture of chromatin interactions in human cells was presented. It provides a useful material for analysing whether the mechanism of transcriptional interactome is common.

Results

The main work here is to demonstrate whether the effects of transcriptional interactome on gene co-expression exist on genomic level. While controlling the effects of transcription factors control similarities (TCS), we tested the correlation between Hi-C interaction and the mutual ranks of gene co-expression rates (provided by COXPRESdb) of intra-chromatin gene pairs. We used 6,084 genes with both TF annotation and co-expression information, and matched them into 273,458 pairs with similar Hi-C interaction ranks in different cell types. The results illustrate that co-expression is strongly associated with chromatin interaction. Further analysis using GO annotation reveals potential correlation between gene function similarity, Hi-C interaction and their co-expression.

Conclusions

According to the results in this research, the intra-chromatin interactome may have relation to gene function and associate with co-expression. This study provides evidence for illustrating the effect of transcriptional interactome on transcription regulation.

Association of adipogenic genes with SC-35 domains during porcine adipogenesis

Spatial organization of the genome within interphase nuclei is non-random. It has been shown that not only whole chromosomes but also individual genes occupy specific nuclear locations and these locations can be changed during different processes like differentiation or disease. Using a porcine in vitro adipogenesis stem cell differentiation system as a model to study nuclear organization, it was demonstrated that nuclear position of selected genes involved in porcine adipogenesis was altered with the up-regulation of gene expression, correlating with these genes becoming more internally located within nuclei, without whole territory relocation. Here, we investigated whether the gene relocation observed during porcine adipogenesis is related to spatial co-association with SC-35 domains. These domains are nuclear speckles enriched in numerous splicing and RNA metabolic factors. Using a DNA immuno-FISH approach we investigated the localisation of three adipogenic genes (PPARG, SREBF1, and FABP4) with SC-35 domains in porcine mesenchymal stem cells and after they were differentiated into adipocytes. We found that the location of these genes relative to SC-35 domains was non-random and correlated with the up-regulation of gene expression. In addition, we observed more frequent clustering of the studied genes located on different chromosomes around the same nuclear speckle in differentiated adipocytes than in mesenchymal stem cells. However, the choice of the domain was more random. This study adds to the evidence that SC-35 domains are hubs of gene activity and gene-domain association may be considered as a common mechanism to enhance gene expression.

Distance between homologous chromosomes results from chromosome positioning constraints

The organization of chromosomes is important for various biological processes and is involved in the formation of rearrangements often observed in cancer. In mammals, chromosomes are organized in territories that are radially positioned in the nucleus. However, it remains unclear whether chromosomes are organized relative to each other. Here, we examine the nuclear arrangement of 10 chromosomes in human epithelial cancer cells by three-dimensional FISH analysis. We show that their radial position correlates with the ratio of their gene density to chromosome size. We also observe that inter-homologue distances are generally larger than inter-heterologue distances. Using numerical simulations taking radial position constraints into account, we demonstrate that, for some chromosomes, radial position is enough to justify the inter-homologue distance, whereas for others additional constraints are involved. Among these constraints, we propose that nucleolar organizer regions participate in the internal positioning of the acrocentric chromosome HSA21, possibly through interactions with nucleoli. Maintaining distance between homologous chromosomes in human cells could participate in regulating genome stability and gene expression, both mechanisms that are key players in tumorigenesis.

Neighbourhood continuity is not required for correct testis gene expression in Drosophila

Disrupting the linear organization of testis gene expression neighborhoods in the Drosophila genome does not affect gene expression, suggesting that neighborhood organization is not primarily driven by gene expression requirements.

It is now widely accepted that gene organisation in eukaryotic genomes is non-random and it is proposed that such organisation may be important for gene expression and genome evolution. In particular, the results of several large-scale gene expression analyses in a range of organisms from yeast to human indicate that sets of genes with similar tissue-specific or temporal expression profiles are clustered within the genome in gene expression neighbourhoods. While the existence of neighbourhoods is clearly established, the underlying reason for this facet of genome organisation is currently unclear and there is little experimental evidence that addresses the genomic requisites for neighbourhood organisation. We report the targeted disruption of three well-defined male-specific gene expression neighbourhoods in the Drosophila genome by the synthesis of precisely mapped chromosomal inversions. We compare gene expression in individuals carrying inverted chromosomes with their non-inverted but otherwise identical progenitors using whole-transcriptome microarray analysis, validating these data with specific quantitative real-time PCR assays. For each neighbourhood we generate and examine multiple inversions. We find no significant differences in the expression of genes that define each of the neighbourhoods. We further show that the inversions spatially separate both halves of a neighbourhood in the nucleus. Thus, models explaining neighbourhood organisation in terms of local sequence interactions, enhancer crosstalk, or short-range chromatin effects are unlikely to account for this facet of genome organisation. Our study challenges the notion that, at least in the case of the testis, expression neighbourhoods are a feature of eukaryotic genome organisation necessary for correct gene expression.

The order of genes within eukaryotic genomes is not completely random. In all genomes characterised to date there are regions of the genome, known as gene expression neighbourhoods, which contain clusters of genes that are expressed together in a particular tissue or at a particular developmental stage. Comparative genomics indicates that at least some neighbourhoods have been conserved during evolution, suggesting that this facet of genome organisation may be functionally advantageous. While several models explaining the organisation of the genome into neighbourhoods have been proposed, the functional significance of neighbourhood organisation has not been experimentally tested. Here, we report experiments that disrupt defined testis gene expression neighbourhoods in the Drosophila genome. We generated chromosomal inversions with a breakpoint within a neighbourhood, defined as having genes co-expressed within the testis. Comparing gene expression in flies carrying inversions with their otherwise identical progenitors shows that maintaining the linear organisation of genes in a neighbourhood is not necessary for correct gene expression. We also show that it is not necessary for genes in a neighbourhood to be in close proximity in the nucleus for them to be co-expressed, since the inversions disrupt the spatial organisation of neighbourhood genes in the nucleus. Our experiments indicate that the current models used to account for the existence of gene expression neighbourhoods are unlikely to be sufficient.

A role for TREX components in the release of spliced mRNA from nuclear speckle domains

The TREX complex, which functions in mRNA export, is recruited to mRNA during splicing. Both the splicing machinery and the TREX complex are concentrated in 20-50 discrete foci known as nuclear speckle domains. In this study, we use a model system where DNA constructs are microinjected into HeLa cell nuclei, to follow the fates of the transcripts. We show that transcripts lacking functional splice sites, which are inefficiently exported, do not associate with nuclear speckle domains but are instead distributed throughout the nucleoplasm. In contrast, pre-mRNAs containing functional splice sites accumulate in nuclear speckles, and our data suggest that splicing occurs in these domains. When the TREX components UAP56 or Aly are knocked down, spliced mRNA, as well as total polyA+ RNA, accumulates in nuclear speckle domains. Together, our data raise the possibility that pre-mRNA undergoes splicing in nuclear speckle domains, before their release by TREX components for efficient export to the cytoplasm.

[Organization of the nucleus during cell differentiation in the mammary tissue]

In many tissues, the features of cell nuclei are specific to their differentiated state, notably in terms of the nature and distribution of nuclear compartments and the position of chromosomes and genes. This spatial organization of the nucleus reveals domains that are differentially permissive for gene expression and may constitute an epigenetic mechanism that is involved in maintaining tissue-specific expression profiles. The mammary gland is a complex tissue in which mammary epithelial cells (MECs), which synthesize and secrete milk components, interact with other cell types (myoepithelial cells, adipocytes) and the extracellular matrix. MECs cultures can to some extent recreate cell differentiation in vitro and have been used to follow the development and functional importance of nuclear organization. They have made it possible to show how hormonal stimulation can lead to a remodeling of nuclear domains and the repositioning of genes specific to the mammary gland, such as milk protein genes. By modulating the growth conditions of culture in order to replace cells in a microenvironment similar to that of mammary gland tissue, it should be possible to study the role of this cellular microenvironment in nuclear organization.

[Embryonic genome organization after fertilization in mammals]

In mammals, the embryonic genome is first transcriptionally inactive after fertilization. Embryonic development is then strictly dependent on the maternally inherited RNA and proteins accumulated before ovulation and present in the oocyte cytoplasm. The onset of embryonic gene expression is initiated later during development, i.e. during the "embryonic genome activation (EGA)". EGA takes place at various preimplantation stages according to species and is dependent on the presence of the basal transcriptional machinery components but also on parental genomes reorganizations after fertilization. Indeed, during the first embryonic cycles, nuclei undergo intense remodeling that could be a key regulator of embryonic development.

Analysis of β-globin chromatin micro-environment using a novel 3C variant, 4Cv

Higher order chromatin folding is critical to a number of developmental processes, including the regulation of gene expression. Recently developed biochemical techniques such as RNA TRAP and chromosome conformation capture (3C) have provided us with the tools to probe chromosomal structures. These techniques have been applied to the β-globin locus, revealing a complex pattern of interactions with regions along the chromosome that the gene resides on. However, biochemical and microscopy data on the nature of β-globin interactions with other chromosomes is contradictory. Therefore we developed a novel 4C variant, Complete-genome 3C by vectorette amplification (4Cv), which allows an unbiased and quantitative method to examine chromosomal structure. We have used 4Cv to study the microenvironment of the β-globin locus in mice and show that a significant proportion of the interactions of β-globin are inter-chromosomal. Furthermore, our data show that in the liver, where the gene is active, β-globin is more likely to interact with other chromosomes, compared to the brain where the gene is silent and is more likely to interact with other regions along the same chromosome. Our data suggest that transcriptional activation of the β-globin locus leads to a change in nuclear position relative to the chromosome territory.

Impact of nuclear organization and dynamics on epigenetic regulation in the central nervous system: implications for neurological disease states

Epigenetic mechanisms that are highly responsive to interoceptive and environmental stimuli mediate the proper execution of complex genomic programs, such as cell type-specific gene transcription and posttranscriptional RNA processing, and are increasingly thought to be important for modulating the development, homeostasis, and plasticity of the central nervous system (CNS). These epigenetic processes include DNA methylation, histone modifications, and chromatin remodeling, all of which play roles in neural cellular diversity, connectivity, and plasticity. Further, large-scale transcriptomic analyses have revealed that the eukaryotic genome is pervasively transcribed, forming interleaved protein-coding RNAs and regulatory nonprotein-coding RNAs (ncRNAs), which act through a broad array of molecular mechanisms. Most of these ncRNAs are transcribed in a cell type- and developmental stage-specific manner in the CNS. A broad array of posttranscriptional processes, such as RNA editing and transport, can modulate the functions of both protein-coding RNAs and ncRNAs. Additional studies implicate nuclear organization and dynamics in mediating epigenetic regulation. The compartmentalization of DNA sequences and other molecular machinery into functional nuclear domains, such as transcription factories, Cajal bodies, promyelocytic leukemia nuclear bodies, nuclear speckles, and paraspeckles, some of which are found prominently in neural cells, is associated with regulation of transcriptional activity and posttranscriptional RNA processing. These observations suggest that genomic architecture and RNA biology in the CNS are much more complex and nuanced than previously appreciated. Increasing evidence now suggests that most, if not all, human CNS diseases are associated with either primary or secondary perturbations in one or more aspects of the epigenome. In this review, we provide an update of our emerging understanding of genomic architecture, RNA biology, and nuclear organization and highlight the interconnected roles that deregulation of these factors may play in diverse CNS disorders.

Integrating one-dimensional and three-dimensional maps of genomes

Genomes exist in vivo as complex physical structures, and their functional output (i.e. the gene expression profile of a cell) is related to their spatial organization inside the nucleus as well as to local chromatin status. Chromatin modifications and chromosome conformation are distinct in different tissues and cell types, which corresponds closely with the diversity in gene-expression patterns found in different tissues of the body. The biological processes and mechanisms driving these general correlations are currently the topic of intense study. An emerging theme is that genome compartmentalization - both along the linear length of chromosomes, and in three dimensions by the spatial colocalization of chromatin domains and genomic loci from across the genome - is a crucial parameter in regulating genome expression. In this Commentary, we propose that a full understanding of genome regulation requires integrating three different types of data: first, one-dimensional data regarding the state of local chromatin - such as patterns of protein binding along chromosomes; second, three-dimensional data that describe the population-averaged folding of chromatin inside cells and; third, single-cell observations of three-dimensional spatial colocalization of genetic loci and trans factors that reveal information about their dynamics and frequency of colocalization.

Organization of transcription

Investigations into the organization of transcription have their origins in cell biology. Early studies characterized nascent transcription in relation to discernable nuclear structures and components. Advances in light microscopy, immunofluorescence, and in situ hybridization helped to begin the difficult task of naming the countless individual players and components of transcription and placing them in context. With the completion of mammalian genome sequences, the seemingly boundless task of understanding transcription of the genome became finite and began a new period of rapid advance. Here we focus on the organization of transcription in mammals drawing upon information from lower organisms where necessary. The emerging picture is one of a highly organized nucleus with specific conformations of the genome adapted for tissue-specific programs of transcription and gene expression.

Differentiation and large scale spatial organization of the genome

The spatial organization of the genome plays an important role in the regulation of nuclear functions and undergoes large scale changes during differentiation. These changes in the nuclear distribution of chromatin are, in a complex way, related to transcriptional status and epigenetic modifications. Recent studies emphasize the roles that gene promoters and alterations in replication timing play in the spatial reorganization of chromatin during cell differentiation. Changes in the association of chromatin regions with the nuclear lamina also emerge as a significant factor of transcriptional regulation. New results suggest that the spatial organization of chromatin in embryonic stem cells may be important for maintenance of the pluripotent state, whereas the nuclear architecture of differentiated cells facilitates formation of transcriptionally active zones with shared transcription and splicing machinery.

Functional nuclear topography of transcriptionally inducible extra-chromosomal transgene clusters

A new experimental approach was designed to test different predictions of current models of the nuclear architecture with respect to the topography of transcription. We constructed a plasmid, termed pIndi, which carries a reporter gene coding for a red cytoplasmic fluorescent reporter protein. Transcription of the reporter gene is regulated by the inducible promoter of the human immunodeficiency virus (HIV) and is strongly dependent on the HIV-1 Tat protein. Expressing the red fluorescent reporter protein allowed us to distinguish between cells with active and silent reporter genes. Importantly, transient transfection resulted in the clustering of plasmids, forming one or several extra-chromosomal pIndi bodies. Repetitive lac operator sequences in pIndi allowed us to visualize these bodies in living cells by the binding of LacI proteins tagged with a fluorescent protein. Using this model, we analyzed the three-dimensional nuclear topography of pIndi bodies with active or silent reporter genes. Our results are compatible with predictions of the chromosome territory-interchromatin compartment (CT-IC) model. We demonstrate that pIndi bodies localize in the IC, both in the silent and active state. Activation of transgene transcription resulted in the recruitment of RNA polymerase II and NFkappaB and a closer positioning to splicing speckles.

Gene positioning

Eukaryotic gene expression is an intricate multistep process, regulated within the cell nucleus through the activation or repression of RNA synthesis, processing, cytoplasmic export, and translation into protein. The major regulators of gene expression are chromatin remodeling and transcription machineries that are locally recruited to genes. However, enzymatic activities that act on genes are not ubiquitously distributed throughout the nucleoplasm, but limited to specific and spatially defined foci that promote preferred higher-order chromatin arrangements. The positioning of genes within the nuclear landscape relative to specific functional landmarks plays an important role in gene regulation and disease.

3D shortcuts to gene regulation

Recent technologies have allowed high-resolution genome-wide binding profiles of numerous transcription factors and other proteins. A widespread observation has emerged from studies in diverse mammalian systems: most binding events are located at great distances from gene promoters. It is becoming apparent that the traditional one-dimensional view of gene regulation via the proximal cis regulatory elements is over-simplified. True proximity and functional relevance can be revealed by studying the three-dimensional structure of the genome packaged inside the nucleus. Thus the spatial architecture of the genome has attracted a lot of interest and has intensified its significance in modern cell biology. Here we discuss current methods, concepts, and controversies in this rapidly evolving field.

Activation of estrogen-responsive genes does not require their nuclear co-localization

The spatial organization of the genome in the nucleus plays a role in the regulation of gene expression. Whether co-regulated genes are subject to coordinated repositioning to a shared nuclear space is a matter of considerable interest and debate. We investigated the nuclear organization of estrogen receptor alpha (ERalpha) target genes in human breast epithelial and cancer cell lines, before and after transcriptional activation induced with estradiol. We find that, contrary to another report, the ERalpha target genes TFF1 and GREB1 are distributed in the nucleoplasm with no particular relationship to each other. The nuclear separation between these genes, as well as between the ERalpha target genes PGR and CTSD, was unchanged by hormone addition and transcriptional activation with no evidence for co-localization between alleles. Similarly, while the volume occupied by the chromosomes increased, the relative nuclear position of the respective chromosome territories was unaffected by hormone addition. Our results demonstrate that estradiol-induced ERalpha target genes are not required to co-localize in the nucleus.

Interchromosomal association and gene regulation in trans

The nucleus is an ordered three-dimensional entity, and organization of the genome within the nuclear space might have implications for orchestrating gene expression. Recent technological developments have revealed that chromatin is folded into loops bringing distal regulatory elements into intimate contact with the genes that they regulate. Such intrachromosomal contacts appear to be a general mechanism of enhancer-promoter communication in cis. Tantalizing evidence is emerging that regulatory elements might have the capacity to act in trans to regulate genes on other chromosomes. However, unequivocal data required to prove that interchromosomal gene regulation truly represents another level of control within the nucleus is lacking, and this concept remains highly contentious. Such controversy emphasizes that our current understanding of the mechanisms that govern gene expression are far from complete.

The effect of translocation-induced nuclear reorganization on gene expression

Translocations are known to affect the expression of genes at the breakpoints and, in the case of unbalanced translocations, alter the gene copy number. However, a comprehensive understanding of the functional impact of this class of variation is lacking. Here, we have studied the effect of balanced chromosomal rearrangements on gene expression by comparing the transcriptomes of cell lines from controls and individuals with the t(11;22)(q23;q11) translocation. The number of differentially expressed transcripts between translocation-carrying and control cohorts is significantly higher than that observed between control samples alone, suggesting that balanced rearrangements have a greater effect on gene expression than normal variation. Many of the affected genes are located along the length of the derived chromosome 11. We show that this chromosome is concomitantly altered in its spatial organization, occupying a more central position in the nucleus than its nonrearranged counterpart. Derivative 22-mapping chromosome 22 genes, on the other hand, remain in their usual environment. Our results are consistent with recent studies that experimentally altered nuclear organization, and indicated that nuclear position plays a functional role in regulating the expression of some genes in mammalian cells. Our study suggests that chromosomal translocations can result in hitherto unforeseen, large-scale changes in gene expression that are the consequence of alterations in normal chromosome territory positioning. This has consequences for the patterns of gene expression change seen during tumorigenesis-associated genome instability and during the karyotype changes that lead to speciation.

The transcriptional interactome: gene expression in 3D

Transcription in the eukaryotic nucleus has long been thought of as conforming to a model in which RNA polymerase complexes are recruited to and track along isolated templates. However, a more dynamic role for chromatin in transcriptional regulation is materializing: enhancer elements interact with promoters forming loops that often bridge considerable distances and genomic loci, even located on different chromosomes, undergo chromosomal associations. These associations amass to form an extensive 'transcriptional interactome', enacted at functional subnuclear compartments, to which genes dynamically relocate. The emerging view is that long-range chromosomal associations between genomic regions, and their repositioning in the three-dimensional space of the nucleus, are key contributors to the regulation of gene expression.

Epigenetic modifications in 3D: nuclear organization of the differentiating mammary epithelial cell

During the development of tissues, complex programs take place to reach terminally differentiated states with specific gene expression profiles. Epigenetic regulations such as histone modifications and chromatin condensation have been implicated in the short and long-term control of transcription. It has recently been shown that the 3D spatial organization of chromosomes in the nucleus also plays a role in genome function. Indeed, the eukaryotic interphase nucleus contains sub-domains that are characterized by their enrichment in specific factors such as RNA Polymerase II, splicing machineries or heterochromatin proteins which render portions of the genome differentially permissive to gene expression. The positioning of individual genes relative to these sub-domains is thought to participate in the control of gene expression as an epigenetic mechanism acting in the nuclear space. Here, we review what is known about the sub-nuclear organization of mammary epithelial cells in connection with gene expression and epigenetics. Throughout differentiation, global changes in nuclear architecture occur, notably with respect to heterochromatin distribution. The positions of mammary-specific genes relative to nuclear sub-compartments varies in response to hormonal stimulation. The contribution of tissue architecture to cell differentiation in the mammary gland is also seen at the level of nuclear organization, which is sensitive to microenvironmental stimuli such as extracellular matrix signaling. In addition, alterations in nuclear organization are concomitant with immortalization and carcinogenesis. Thus, the fate of cells appears to be controlled by complex pathways connecting external signal integration, gene expression, epigenetic modifications and chromatin organization in the nucleus.

Centromeric localization of dispersed Pol III genes in fission yeast

The eukaryotic genome is a complex three-dimensional entity residing in the nucleus. We present evidence that Pol III-transcribed genes such as tRNA and 5S rRNA genes can localize to centromeres and contribute to a global genome organization. Furthermore, we find that ectopic insertion of Pol III genes into a non-Pol III gene locus results in the centromeric localization of the locus. We show that the centromeric localization of Pol III genes is mediated by condensin, which interacts with the Pol III transcription machinery, and that transcription levels of the Pol III genes are negatively correlated with the centromeric localization of Pol III genes. This centromeric localization of Pol III genes initially observed in interphase becomes prominent during mitosis, when chromosomes are condensed. Remarkably, defective mitotic chromosome condensation by a condensin mutation, cut3-477, which reduces the centromeric localization of Pol III genes, is suppressed by a mutation in the sfc3 gene encoding the Pol III transcription factor TFIIIC subunit, sfc3-1. The sfc3-1 mutation promotes the centromeric localization of Pol III genes. Our study suggests there are functional links between the process of the centromeric localization of dispersed Pol III genes, their transcription, and the assembly of condensed mitotic chromosomes.

Detection of nascent RNA transcripts by fluorescence in situ hybridization

The development of cellular diversity within any organism depends on the timely and correct expression of differing subsets of genes within each tissue type. Many techniques exist which allow a global, average analysis of RNA expression; however, RNA-FISH permits the sensitive detection of specific transcripts within individual cells while preserving the cellular morphology. The technique can provide insight into the spatial and temporal organization of gene transcription as well the relationship of gene expression and mature RNA distribution to nuclear and cellular compartments. It can also reveal the intercellular variation of gene expression within a given tissue. Here, we describe RNA-FISH methodologies that allow the detection of nascent transcripts within the cell nucleus as well as protocols that allow the detection of RNA alongside DNA or proteins. Such techniques allow the placing of gene transcription within a functional context of the whole cell.

3D-FISH on cultured cells combined with immunostaining

Fluorescence in situ hybridization on three-dimensionally preserved nuclei (3D-FISH), in combination with immunocytochemistry and 3D fluorescence microscopy, is a key tool to analyze the functional organization of the interphase nucleus. In the last decade, 3D-FISH on cultured cells has become a routine technique and is now widely used in nuclear biology. This method allows visualization of chromosome territories, chromosome subregions, single genes, and RNA transcripts preserving their spatial positions in the cell nucleus. In many cases, it is desirable to combine 3D-FISH and immunostaining to map DNA/RNA and protein targets in the same cells. Some steps of the FISH procedure, however, may interfere with immunostaining and special efforts have to be done to combine FISH and antibody staining successfully. The protocol suggested in this chapter describes three variants of combined 3D-FISH and immunostaining which have been successfully used in our laboratory for many years.

Preferential associations between co-regulated genes reveal a transcriptional interactome in erythroid cells

The discovery of interchromosomal interactions in higher eukaryotes points to a functional interplay between genome architecture and gene expression, challenging the view of transcription as a one-dimensional process. However, the extent of interchromosomal interactions and the underlying mechanisms are unknown. Here we present the first genome-wide analysis of transcriptional interactions using the mouse globin genes in erythroid tissues. Our results show that the active globin genes associate with hundreds of other transcribed genes, revealing extensive and preferential intra- and interchromosomal transcription interactomes. We show that the transcription factor Klf1 mediates preferential co-associations of Klf1-regulated genes at a limited number of specialized transcription factories. Our results establish a new gene expression paradigm, implying that active co-regulated genes and their regulatory factors cooperate to create specialized nuclear hot spots optimized for efficient and coordinated transcriptional control.

Changing nuclear landscape and unique PML structures during early epigenetic transitions of human embryonic stem cells

The complex nuclear structure of somatic cells is important to epigenomic regulation, yet little is known about nuclear organization of human embryonic stem cells (hESC). Here we surveyed several nuclear structures in pluripotent and transitioning hESC. Observations of centromeres, telomeres, SC35 speckles, Cajal Bodies, lamin A/C and emerin, nuclear shape and size demonstrate a very different "nuclear landscape" in hESC. This landscape is remodeled during a brief transitional window, concomitant with or just prior to differentiation onset. Notably, hESC initially contain abundant signal for spliceosome assembly factor, SC35, but lack discrete SC35 domains; these form as cells begin to specialize, likely reflecting cell-type specific genomic organization. Concomitantly, nuclear size increases and shape changes as lamin A/C and emerin incorporate into the lamina. During this brief window, hESC exhibit dramatically different PML-defined structures, which in somatic cells are linked to gene regulation and cancer. Unlike the numerous, spherical somatic PML bodies, hES cells often display approximately 1-3 large PML structures of two morphological types: long linear "rods" or elaborate "rosettes", which lack substantial SUMO-1, Daxx, and Sp100. These occur primarily between Day 0-2 of differentiation and become rare thereafter. PML rods may be "taut" between other structures, such as centromeres, but clearly show some relationship with the lamina, where PML often abuts or fills a "gap" in early lamin A/C staining. Findings demonstrate that pluripotent hES cells have a markedly different overall nuclear architecture, remodeling of which is linked to early epigenomic programming and involves formation of unique PML-defined structures.

Comprehensive mapping of long-range interactions reveals folding principles of the human genome

We describe Hi-C, a method that probes the three-dimensional architecture of whole genomes by coupling proximity-based ligation with massively parallel sequencing. We constructed spatial proximity maps of the human genome with Hi-C at a resolution of 1 megabase. These maps confirm the presence of chromosome territories and the spatial proximity of small, gene-rich chromosomes. We identified an additional level of genome organization that is characterized by the spatial segregation of open and closed chromatin to form two genome-wide compartments. At the megabase scale, the chromatin conformation is consistent with a fractal globule, a knot-free, polymer conformation that enables maximally dense packing while preserving the ability to easily fold and unfold any genomic locus. The fractal globule is distinct from the more commonly used globular equilibrium model. Our results demonstrate the power of Hi-C to map the dynamic conformations of whole genomes.

Comprehensive mapping of long-range interactions reveals folding principles of the human genome

We describe Hi-C, a method that probes the three-dimensional architecture of whole genomes by coupling proximity-based ligation with massively parallel sequencing. We constructed spatial proximity maps of the human genome with Hi-C at a resolution of 1 megabase. These maps confirm the presence of chromosome territories and the spatial proximity of small, gene-rich chromosomes. We identified an additional level of genome organization that is characterized by the spatial segregation of open and closed chromatin to form two genome-wide compartments. At the megabase scale, the chromatin conformation is consistent with a fractal globule, a knot-free, polymer conformation that enables maximally dense packing while preserving the ability to easily fold and unfold any genomic locus. The fractal globule is distinct from the more commonly used globular equilibrium model. Our results demonstrate the power of Hi-C to map the dynamic conformations of whole genomes.

Chromosome crosstalk in three dimensions

The genome forms extensive and dynamic physical interactions with itself in the form of chromosome loops and bridges, thus exploring the three-dimensional space of the nucleus. It is now possible to examine these interactions at the molecular level, and we have gained glimpses of their functional implications. Chromosomal interactions can contribute to the silencing and activation of genes within the three-dimensional context of the nuclear architecture. Technical advances in detecting these interactions contribute to our understanding of the functional organization of the genome, as well as its adaptive plasticity in response to environmental changes during development and disease.

Spatial organization of genes as a component of regulated expression

The DNA of living cells is highly compacted. Inherent in this spatial constraint is the need for cells to organize individual genetic loci so as to facilitate orderly retrieval of information. Complex genetic regulatory mechanisms are crucial to all organisms, and it is becoming increasingly evident that spatial organization of genes is one very important mode of regulation for many groups of genes. In eukaryotic nuclei, it appears not only that DNA is organized in three-dimensional space but also that this organization is dynamic and interactive with the transcriptional state of the genes. Spatial organization occurs throughout evolution and with genes transcribed by all classes of RNA polymerases in all eukaryotic nuclei, from yeast to human. There is an increasing body of work examining the ways in which this organization and consequent regulation are accomplished. In this review, we discuss the diverse strategies that cells use to preferentially localize various classes of genes.

SR proteins in vertical integration of gene expression from transcription to RNA processing to translation

SR proteins have been studied extensively as a family of RNA-binding proteins that participate in both constitutive and regulated pre-mRNA splicing in mammalian cells. However, SR proteins were first discovered as factors that interact with transcriptionally active chromatin. Recent studies have now uncovered properties that connect these once apparently disparate functions, showing that a subset of SR proteins seem to bind directly to the histone 3 tail, play an active role in transcriptional elongation, and colocalize with genes that are engaged in specific intra- and interchromosome interactions for coordinated regulation of gene expression in the nucleus. These transcription-related activities are also coupled with a further expansion of putative functions of specific SR protein family members in RNA metabolism downstream of mRNA splicing, from RNA export to stability control to translation. These findings, therefore, highlight the broader roles of SR proteins in vertical integration of gene expression and provide mechanistic insights into their contributions to genome stability and proper cell-cycle progression in higher eukaryotic cells.

Transcription factories: gene expression in unions?

Transcription is a fundamental step in gene expression, yet it remains poorly understood at a cellular level. Visualization of transcription sites and active genes has led to the suggestion that transcription occurs at discrete sites in the nucleus, termed transcription factories, where multiple active RNA polymerases are concentrated and anchored to a nuclear substructure. However, this concept is not universally accepted. This Review discusses the experimental evidence in support of the transcription factory model and the evidence that argues against such a spatially structured view of transcription. The transcription factory model has implications for the regulation of transcription initiation and elongation, for the organization of genes in the genome, for the co-regulation of genes and for genome instability.

Transcription, chromatin condensation, and gene migration

The binding of fluorescently tagged proteins to tandem DNA arrays has been instrumental in understanding nuclear organization and function. Through the use of more natural tandem DNA arrays, Hu et al. (Hu, Y., I. Kireev, M. Plutz, N. Ashourian, and A.S. Belmont. 2009. J. Cell Biol. 185:87–100) gain new insights into chromatin organization and dynamics, and into the association of splicing factors with active genes.

Lack of bystander activation shows that localization exterior to chromosome territories is not sufficient to up-regulate gene expression

Position within chromosome territories and localization at transcription factories are two facets of nuclear organization that have been associated with active gene expression. However, there is still debate about whether this organization is a cause or consequence of transcription. Here we induced looping out from chromosome territories (CTs), by the activation of Hox loci during differentiation, to investigate consequences on neighboring loci. We show that, even though flanking genes are caught up in the wave of nuclear reorganization, there is no effect on their expression. However, there is a differential organization of active and inactive alleles of these genes. Inactive alleles are preferentially retained within the CT, whereas actively transcribing alleles, and those associated with transcription factories, are found both inside and outside of the territory. We suggest that the alleles relocated further to the exterior of the CT are those that were already active and already associated with transcription factories before the induction of differentiation. Hence active gene regions may loop out from CTs because they are able to, and not because they need to in order to facilitate gene expression.

Nuclear neighborhoods and gene expression

The eukaryotic nucleus is a highly compartmentalized and dynamic environment. Chromosome territories are arranged nonrandomly within the nucleus and numerous studies have indicated that a gene's position in the nucleus can impact its transcriptional activity. Here, we focus on recent advances in our understanding of the influence of specific nuclear neighborhoods on gene expression or repression. Nuclear neighborhoods associated with transcriptional repression include the inner nuclear membrane/nuclear lamina and perinucleolar chromatin, whereas neighborhoods surrounding the nuclear pore complex, PML nuclear bodies, and nuclear speckles seem to be transcriptionally permissive. While nuclear position appears to play an important role in gene expression, it is likely to be only one piece of a flexible puzzle that incorporates numerous parameters. We are still at a very early, yet exciting stage in our journey toward deciphering the mechanism(s) that govern(s) the permissiveness of gene expression/repression within different nuclear neighborhoods.