Ultrastructural localization of active genes in nuclei of A431 cells

Morphology of nuclear transcription

Gene expression control is a fundamental determinant of cellular life with transcription being the most important step. The spatial nuclear arrangement of the transcription process driven by RNA polymerases II and III is nonrandomly organized in foci, which is believed to add another regulatory layer on gene expression control. RNA polymerase I transcription takes place within a specialized organelle, the nucleolus. Transcription of ribosomal RNA directly responds to metabolic requirements, which in turn is reflected in the architecture of nucleoli. It differs from that of the other polymerases with respect to the gene template organization, transcription rate, and epigenetic expression control, whereas other features are shared like the formation of DNA loops bringing genes and components of the transcription machinery in close proximity. In recent years, significant advances have been made in the understanding of the structural prerequisites of nuclear transcription, of the arrangement in the nuclear volume, and of the dynamics of these entities. Here, we compare ribosomal RNA and mRNA transcription side by side and review the current understanding focusing on structural aspects of transcription foci, of their constituents, and of the dynamical behavior of these components with respect to foci formation, disassembly, and cell cycle.

Ribosomal proteins' association with transcription sites peaks at tRNA genes in Schizosaccharomyces pombe

Ribosomal proteins (RPs) are essential components of ribosomes, but several RPs are also present at transcription sites of eukaryotic chromosomes. Here, we report a genome-wide ChIP-on-chip analysis of the association of three representative 60S RPs with sites in the Schizosaccharomyces pombe chromosomes. All three proteins tend to bind at the same subset of coding and noncoding loci. The data demonstrate selective RNA-dependent interactions between RPs and many transcription sites and suggest that the RPs bind as components of a preassembled multiprotein complex, perhaps 60S or pre-60S subunits. These findings further indicate that the presence of RPs complexes at transcription sites might be a general feature of eukaryotic cells and functionally important. Unexpectedly, the RPs' chromosomal association is highest at centromeres and tRNA genes-the RPs were found at 167 of the 171 tRNA genes assayed. These findings raise the intriguing possibility that RP complexes are involved in tRNA biogenesis and possibly centromere functions.

Spatio-temporal dynamics of replication and transcription sites in the mammalian cell nucleus

To study when and where active genes replicated in early S phase are transcribed, a series of pulse-chase experiments are performed to label replicating chromatin domains (RS) in early S phase and subsequently transcription sites (TS) after chase periods of 0 to 24 h. Surprisingly, transcription activity throughout these chase periods did not show significant colocalization with early RS chromatin domains. Application of novel image segmentation and proximity algorithms, however, revealed close proximity of TS with the labeled chromatin domains independent of chase time. In addition, RNA polymerase II was highly proximal and showed significant colocalization with both TS and the chromatin domains. Based on these findings, we propose that chromatin activated for transcription dynamically unfolds or "loops out" of early RS chromatin domains where it can interact with RNA polymerase II and other components of the transcriptional machinery. Our results further suggest that the early RS chromatin domains are transcribing genes throughout the cell cycle and that multiple chromatin domains are organized around the same transcription factory.

Nucleic acid distribution pattern in avian erythrocytes and mammalian lymphocytes: comparative studies by fluorescence microscopy and digital imaging analytical techniques

Nucleated erythrocytes of healthy domestic chicken and ducks, and lymphocytes of healthy Sprague Dawley rats were evaluated for nucleic acid distribution pattern, employing light and fluorescence microscopy procedures, as well as digital imaging analytical methods. The results demonstrate a unique organization of nuclear DNA of mature chicken and duck erythrocytes, as well as immature duck erythrocytes, as delineated spherical nuclear bodies that mostly corresponded with euchromatin zones of the cells in routine Wright-stain blood smears. The nuclear DNA of the rat lymphocytes, on the other hand, was observed as a more diffuse green fluorescing nuclear areas, with punctate variably-sized diffuse areas of RNA red fluorescence. RNA red color fluorescence was also evident in the narrow cytoplasm of the lymphocytes, especially in large lymphocytes, in comparison with the cytoplasm of the mature avian erythrocytes that completely lacked any nucleic acid fluorescence. Nuclear RNA fluorescence was lacking in the mature chicken erythrocytes, compared with those of the mature and immature duck erythrocytes as well as lymphocytes of both avian and rats blood. The significance of these findings lies in the establishment of normal benchmarks for the nuclear and cytoplasmic nucleic acid pattern in eukaryotic cells. These normal benchmarks become valuable in rapid diagnostic situations associated with pathologies, such as the presence of viral nuclear and cytoplasmic inclusion bodies that can alter the nucleic acid pattern of the host cells, and in conditions of cellular abnormal protein aggregations. Variability of cellular nucleic acid pattern can also aid in prognostic assessments of neoplastic conditions.

Organization of chromatin and histone modifications at a transcription site

According to the transcription factory model, localized transcription sites composed of immobilized polymerase molecules transcribe chromatin by reeling it through the transcription site and extruding it to form a surrounding domain of recently transcribed decondensed chromatin. Although transcription sites have been identified in various cells, surrounding domains of recently transcribed decondensed chromatin have not. We report evidence that transcription sites associated with a tandem gene array in mouse cells are indeed surrounded by or adjacent to a domain of decondensed chromatin composed of sequences from the gene array. Formation of this decondensed domain requires transcription and topoisomerase IIalpha activity. The decondensed domain is enriched for the trimethyl H3K36 mark that is associated with recently transcribed chromatin in yeast and several mammalian systems. Consistent with this, chromatin immunoprecipitation demonstrates a comparable enrichment of this mark in transcribed sequences at the tandem gene array. These results provide new support for the pol II factory model, in which an immobilized polymerase molecule extrudes decondensed, transcribed sequences into its surroundings.

Advances in imaging the interphase nucleus using thin cryosections

The mammalian genome is partitioned amongst various chromosomes and encodes for approximately 30,000 protein-coding genes. Gene expression occurs after exit from mitosis, when chromosomes partially decondense within the cell nucleus to allow the enzymatic activities that work on chromatin to access each gene in a regulated fashion. Differential patterns of gene expression evolve during cell differentiation to give rise to the over 200 cell types in higher eukaryotes. The architectural organisation of the genome inside the interphase cell nucleus, and associated enzymatic activities, reveals dynamic and functional compartmentalization of the genome. In this review, I highlight the advantages of Tokuyasu cryosectioning on the investigation of nuclear structure and function.

Replication and transcription: shaping the landscape of the genome

As the relationship between nuclear structure and function begins to unfold, a picture is emerging of a dynamic landscape that is centred on the two main processes that execute the regulated use and propagation of the genome. Rather than being subservient enzymatic activities, the replication and transcriptional machineries provide potent forces that organize the genome in three-dimensional nuclear space. Their activities provide opportunities for epigenetic changes that are required for differentiation and development. In addition, they impose physical constraints on the genome that might help to shape its evolution.

Nanostructure of specific chromatin regions and nuclear complexes

Spatially modulated illumination (SMI) microscopy is a method of widefield fluorescence microscopy featuring interferometric illumination, which delivers structural information about nanoscale features in fluorescently labeled cells. Using this approach, structural changes in the context of gene activation and chromatin remodeling may be revealed. In this paper we present the application of SMI microscopy to size measurements of the 7q22 gene region, giving us a size estimate of 105+/-16 nm which corresponds to an average compaction ratio of 1:324. The results for the 7q22 domain are compared with the previously measured sizes of other fluorescently labeled gene regions, and to those obtained for transcription factories. The absence of a correlation between the measured and genomic sizes of the various gene regions indicate that a high variability in chromatin folding is present, with factors other than the sequence length contributing to the chromatin compaction. Measurements of the 7q22 region in different preparations and at different excitation wavelengths show a good agreement, thus demonstrating that the technique is robust when applied to biological samples.

Distribution of different phosphorylated forms of RNA polymerase II in relation to Cajal and PML bodies in human cells: an ultrastructural study

The mammalian nucleus is a highly organised organelle that contains many subcompartments with roles in DNA replication and repair, gene expression and RNA processing. Cajal and promyelocytic leukaemia (PML) bodies are discrete nuclear structures with specific molecular signatures. RNA polymerase II and many transcription factors have been identified within these compartments by immunofluorescence microscopy, suggesting a role in polymerase II assembly or transcriptional activity. Here, we have examined the presence of different phosphorylated forms of polymerase II and newly made RNA in Cajal and PML bodies using high-resolution imaging of ultrathin cryosections (approximately 120 nm thick) with fluorescence and electron microscopes. We show that Cajal bodies contain polymerase II phosphorylated on Ser5, and not the Ser2-phosphorylated (active) form or newly made RNA. The presence of polymerase II in the absence of transcriptional activity suggests that Cajal bodies have roles in polymerase assembly or transport, but not in gene transcription. PML bodies contain no detectable polymerase II or nascent RNA in HeLa cells, at the resolution achieved by electron microscopy, but are often surrounded by these markers at distances>25 nm. These results support the view that although PML bodies are present in transcriptionally active areas of the nucleus, they are not generally sites of polymerase II assembly, transport or activity.

Ikaros-family proteins: in search of molecular functions during lymphocyte development

The regulatory steps that lead to the differentiation of hematopoietic cells from a multipotential stem cell remain largely unknown. A beginning to the understanding of these steps has come from the study of DNA-binding proteins that are thought to regulate the expression of genes required for specific developmental events. Ikaros is the founding member of a small family of DNA-binding proteins required for lymphocyte development, but the members of this family differ from other key regulators of lymphopoiesis in that direct target genes have not been conclusively identified, and reasonable support has been presented for only a few potential targets. Therefore, the molecular mechanisms that Ikaros uses for regulating lymphocyte development remain largely unknown. Current data suggest that, in some instances, Ikaros may function as a typical transcription factor. However, recent results suggest that it may function more broadly, perhaps in the formation of silent and active chromatin structures. In this review, our current knowledge of the molecular functions of Ikaros will be discussed.

Nascent RNA synthesis in the context of chromatin architecture

Based on the idea that chromatin domains provide physical barriers for large molecules and multi-enzyme complexes, including the components of the transcription machinery, it has been proposed that transcription should be confined to the surfaces of chromatin domains. As a consequence nascent RNA should accumulate in the interchromatin space, which is thought to provide a special nuclear compartment involved in transcription, as well as in the processing and export of RNA (Cremer et al. 1993, Cremer & Cremer 2001). To further address the relationships between chromatin organization and RNA synthesis, we investigated the localization of BrUTP-labelled nascent RNA in HeLa cells stably expressing green fluorescent protein (GFP)-tagged histone H2B, which highlights the chromatin structure. Our results showed that nascent RNA does not preferentially localize within the interchromatin space. The findings do not support the idea that the interchromatin space provides a nuclear compartment playing an essential role in nascent RNA synthesis. However, the results are in agreement with the emerging view that even condensed chromatin domains display a highly dynamic organization and are not a physical barrier for transcription factors.

Transcription factories: quantitative studies of nanostructures in the mammalian nucleus

Transcription by the three nuclear RNA polymerases is carried out in transcription factories. This conclusion has been drawn from estimates of the total number of nascent transcripts or active polymerase molecules and the number of transcription sites within a cell. Here we summarise the variety of methods used to determine these parameters, discuss their associated problems and outline future prospects.

Measuring the size of biological nanostructures with spatially modulated illumination microscopy

Spatially modulated illumination fluorescence microscopy can in theory measure the sizes of objects with a diameter ranging between 10 and 200 nm and has allowed accurate size measurement of subresolution fluorescent beads ( approximately 40-100 nm). Biological structures in this size range have so far been measured by electron microscopy. Here, we have labeled sites containing the active, hyperphosphorylated form of RNA polymerase II in the nucleus of HeLa cells by using the antibody H5. The spatially modulated illumination-microscope was compared with confocal laser scanning and electron microscopes and found to be suitable for measuring the size of cellular nanostructures in a biological setting. The hyperphosphorylated form of polymerase II was found in structures with a diameter of approximately 70 nm, well below the 200-nm resolution limit of standard fluorescence microscopes.

Cellular genomics: which genes are transcribed, when and where?

Gene expression involves a cascade of events, from transcription factor transactivation and RNA polymerase binding to RNA processing and maturation. mRNA profiling has yielded a vast amount of information about the total RNA content in different tissues physiological states. However, it has been unclear how the variable amounts of mRNA might correlate with transcriptional events. Recent advances in single-cell imaging offer a platform for 'cellular genomics', the high throughput analysis of transcriptional activity in single cells.

High-resolution colocalization of single dye molecules by fluorescence lifetime imaging microscopy

Conventional fluorescence microscopy can be used to determine the positions of objects in space when those objects are separated by distances greater than several hundred nanometers, as restricted by the diffraction limit of light. Fluorescence microscopy/spectroscopy based on fluorescence resonance energy-transfer techniques can be used to measure separation distances below approximately 10 nm. To fill the gap between these fundamental limits, we have developed an alternative technique for high-resolution colocalization of fluorescent dyes. The technique is based on fluorescence lifetime imaging. Under favorable conditions, the method can be used to distinguish, and to measure the distance between, two dye molecules that are less than 30 nm apart. To demonstrate the method, lifetime images of a mixture of Cy5 and JF9 (rhodamine derivative) molecules statistically adsorbed on a glass surface were acquired and analyzed. Since these two molecular species differ in fluorescence lifetime (for Cy5, tau(f) = 2.0 ns, and for JF9, tau(f) = 4.0 ns), it is possible to assign the contribution of fluorescence of the two dye types to each image pixel using a pattern recognition technique. Since both dye types can be excited using the same laser wavelength, the measurement is free of chromatic aberrations. The results presented demonstrate the first high-precision distance measurements between single conventional fluorescent dyes based solely on fluorescence lifetime.

Differences in nuclear retention characteristics of agonist-activated glucocorticoid receptor may determine specific responses

We studied the glucocorticoid response to the synthetic steroid pregna-1,4-diene-11beta-ol-3,20-dione (DeltaHOP) in several cell types and correlated its biological effect with the ability of the glucocorticoid receptor (GR) to be retained in the nuclear compartment. We observed that the DeltaHOP-transformed GR was diffusely distributed in the nucleus compared to the discrete structures observed for the dexamethasone (DEX)-transformed GR. Despite the fact that the receptor was entirely nuclear upon binding of each steroid and exhibited identical nuclear export rates, a greater amount of DeltaHOP-transformed GR was recovered in the cytoplasmic fraction after hypotonic cell lysis. Furthermore, accelerated nuclear export of GR was evidenced in digitonin-permeabilized cells treated with ATP and molybdate. Inasmuch as limited trypsinization of DEX-GR and DeltaHOP-GR complexes yielded different proteolytic products, we conclude that GR undergoes a differential conformational change upon binding of each ligand. We propose that these conformational differences may consequently lead to changes of stability in the interaction of the GR with chromatin. Therefore, the dynamic exchange of liganded GR with chromatin is likely to have significant consequences for the observed pleiotropic physiological responses triggered by glucocorticoid ligands, not only in different tissues but also in the same cell type.

Spatial organization of active and inactive genes and noncoding DNA within chromosome territories

The position of genes within the nucleus has been correlated with their transcriptional activity. The interchromosome domain model of nuclear organization suggests that genes preferentially locate at the surface of chromosome territories. Conversely, high resolution analysis of chromatin fibers suggests that chromosome territories do not present accessibility barriers to transcription machinery. To clarify the relationship between the organization of chromosome territories and gene expression, we have used fluorescence in situ hybridization to analyze the spatial organization of a contiguous approximately 1 Mb stretch of the Wilms' tumor, aniridia, genitourinary anomalies, mental retardation syndrome region of the human genome and the syntenic region in the mouse. These regions contain constitutively expressed genes, genes with tissue-restricted patterns of expression, and substantial regions of intergenic DNA. We find that there is a spatial organization within territories that is conserved between mouse and humans: certain sequences do preferentially locate at the periphery of the chromosome territories in both species. However, we do not detect genes necessarily at the periphery of chromosome territories or at the surface of subchromosomal domains. Intraterritory organization is not different among cell types that express different combinations of the genes under study. Our data demonstrate that transcription of both ubiquitous and tissue-restricted genes is not confined to the periphery of chromosome territories, suggesting that the basal transcription machinery and transcription factors can readily gain access to the chromosome interior.

The Rb/chromatin connection and epigenetic control: opinion

The balance between cell differentiation and proliferation is regulated at the transcriptional level. In the cell cycle, the transition from G1 to S phase (G1/S transition) is of paramount importance in this regard. Indeed, it is only before this point that cells can be oriented toward the differentiation pathway: beyond, cells progress into the cycle in an autonomous manner. The G1/S transition is orchestrated by the transcription factor E2F. E2F controls the expression of a group of checkpoint genes whose products are required either for the G1-to-S transition itself or for DNA replication (e.g. DNA polymerase alpha). E2F activity is repressed in growth-arrested cells and in early G1, and is activated at mid-to-late G1. E2F is controlled by the retinoblastoma tumor suppressor protein Rb. Rb represses E2F mainly by recruiting chromatin remodeling factors (histone deacetylases and SWI/SNF complexes), the DNA methyltransferase DNMT1, and a histone methyltransferase. This review will focus on the molecular mechanisms of E2F repression by Rb during the cell cycle and during cell-cycle exit by differentiating cells. A model in which Rb irreversibly represses E2F-regulated genes in differentiated cells by an epigenetic mechanism linked to heterochromatin, and involving histone H3 and promoter DNA methylation, is discussed.

Experimental observations of a nuclear matrix

Nuclei are intricately structured, and nuclear metabolism has an elaborate spatial organization. The architecture of the nucleus includes two overlapping and nucleic-acid-containing structures - chromatin and a nuclear matrix. The nuclear matrix is observed by microscopy in live, fixed and extracted cells. Its ultrastructure and composition show it to be, in large part, the ribonucleoprotein (RNP) network first seen in unfractionated cells more than 30 years ago. At that time, the discovery of this RNP structure explained surprising observations that RNA, packaged in proteins, is attached to an intranuclear, non-chromatin structure. Periodic and specific attachments of chromatin fibers to the nuclear matrix create the chromatin loop domains that can be directly observed by microscopy or inferred from biochemical experiments. The ultrastructure of the nuclear matrix is well characterized and consists of a nuclear lamina and an internal nuclear network of subassemblies linked together by highly structured fibers. These complex fibers are built on an underlying scaffolding of branched 10-nm filaments that connect to the nuclear lamina. The structural proteins of the nuclear lamina have been well characterized, but the structural biochemistry of the internal nuclear matrix has received less attention. Many internal matrix proteins have been identified, but far less is known about how these proteins assemble to make the fibers, filaments and other assemblies of the internal nuclear matrix. Correcting this imbalance will require the combined application of biochemistry and electron microscopy. The central problem in trying to define nuclear matrix structure is to identify the proteins that assemble into the 10-nm filaments upon which the interior architecture of the nucleus is constructed. Only by achieving a biochemical characterization of the nuclear matrix will we advance beyond simple microscopic observations of structure to a better understanding of nuclear matrix function, regulation and post-mitotic assembly.

Compartmentalization of regulatory proteins in the cell nucleus

The cell nucleus is increasingly recognized as a spatially organized structure. In this review, the nature and controversies associated with nuclear compartmentalization are discussed. The relationship between nuclear structure and organization of proteins involved in the regulation of RNA polymerase II-transcribed genes is then discussed. Finally, very recent data on the mobility of these proteins within the cell nucleus is considered and their implications for regulation through compartmentalization of proteins and genomic DNA are discussed.

Spatial organization of RNA polymerase II transcription in the nucleus

In eukaryotic cells, mRNA synthesis is carried out by large, multifunctional complexes that are also involved in coordinating transcription with other nuclear processes. This survey focuses on the distribution and structural arrangement of these complexes within the nucleus, in relationship with the discrete positioning of particular chromosomal loci. To better understand the link between the spatial organization of the nucleus and the regulation of gene expression, it is necessary to combine information from biochemical studies with results from microscopic observations of preserved nuclear structures. Recent experimental approaches have made this possible. The subnuclear locations of specific chromosome loci, RNA transcripts, RNA polymerases, and transcription and pre-mRNA-processing factors can now be observed with computer-assisted microscopy and specific molecular probes. The results indicate that RNA polymerase II (RNAPII) transcription takes place at discrete sites scattered throughout the nucleoplasm, and that these sites are also the locations of pre-mRNA processing. Transcribing polymerases appear to be grouped into clusters at each transcription site. Cell cycle-dependent zones of transcription and processing factors have been identified, and certain subnuclear domains appear specialized for expression or silencing of particular genes. The arrangement of transcription in the nucleus is dynamic and depends on its transcriptional activity, with the RNAPII itself playing a central role in marshalling the large complexes involved in gene expression.

Association of DNAse sensitive chromatin domains with the nuclear periphery in 3T3 cells in vitro

DNAse sensitive chromatin, putative transcriptionally competent sequences, exists either as pan-nuclear speckles in cells with nuclei which exhibit a flat geometry, or as a shell apposed to the nuclear envelope in cells with spheroidal nuclei. To test the hypothesis that DNAse sensitive chromatin is similarly associated with the nuclear periphery in cell types with a very flat geometry such as 3T3 fibroblasts, cells were subjected to hypotonic expansion to change their nuclei from a flat ellipsoid to a spheriod. This was based on the assumption that such a spatial association is not resolvable due to the interdigitation at the nuclear midplane of DNAse sensitive chromatin associated with the upper and lower nuclear surfaces. In situ nick translation was used to visualize the distribution of DNAse sensitive chromatin as a function of nuclear geometry. Both unexpanded and expanded cells exhibit DNAse sensitive chromatin as a dome at the apical side of the nucleus, i.e., that aspect of the cell facing the culture medium. The results argue for a polarized association of DNAse sensitive chromatin with the nuclear envelope and indicate that the nuclear periphery may function as a compartment for the spatial coupling of transcription and nucleo-cytoplasmic transport.

Key words: nuclear organization, DNAse sensitive chromatin, hypotonic expansion, 3T3 cells.

Spatial relationship between transcription sites and chromosome territories

We have investigated the spatial relationship between transcription sites and chromosome territories in the interphase nucleus of human female fibroblasts. Immunolabeling of nascent RNA was combined with visualization of chromosome territories by fluorescent in situ hybridization (FISH). Transcription sites were found scattered throughout the territory of one of the two X chromosomes, most likely the active X chromosome, and that of both territories of chromosome 19. The other X chromosome territory, probably the inactive X chromosome, was devoid of transcription sites. A distinct substructure was observed in interphase chromosome territories. Intensely labeled subchromosomal domains are surrounded by less strongly labeled areas. The intensely labeled domains had a diameter in the range of 300-450 nm and were sometimes interconnected, forming thread-like structures. Similar large scale chromatin structures were observed in HeLa cells expressing green fluorescent protein (GFP)-tagged histone H2B. Strikingly, nascent RNA was almost exclusively found in the interchromatin areas in chromosome territories and in between strongly GFP-labeled chromatin domains. These observations support a model in which transcriptionally active chromatin in chromosome territories is markedly compartmentalized. Active loci are located predominantly at or near the surface of compact chromatin domains, depositing newly synthesized RNA directly into the interchromatin space.

Large-scale chromatin unfolding and remodeling induced by VP16 acidic activation domain

Analysis of the relationship between transcriptional activators and chromatin organization has focused largely on lower levels of chromatin structure. Here we describe striking remodeling of large-scale chromatin structure induced by a strong transcriptional activator. A VP16-lac repressor fusion protein targeted the VP16 acidic activation domain to chromosome regions containing lac operator repeats. Targeting was accompanied by increased transcription, localized histone hyperacetylation, and recruitment of at least three different histone acetyltransferases. Observed effects on large-scale chromatin structure included unfolding of a 90-Mbp heterochromatic chromosome arm into an extended 25-40-micrometers chromonema fiber, remodeling of this fiber into a novel subnuclear domain, and propagation of large-scale chromatin unfolding over hundreds of kilobase pairs. These changes in large-scale chromatin structure occurred even with inhibition of ongoing transcription by alpha-amanitin. Our results suggest a functional link between recruitment of the transcriptional machinery and changes in large-scale chromatin structure. Based on the observed long-range propagation of changes in large-scale chromatin structure, we suggest a possible rationale for the observed clustering of housekeeping genes within Mbp-sized chromosome bands.

The organization of replication and transcription

Models for replication and transcription often display polymerases that track like locomotives along their DNA templates. However, recent evidence supports an alternative model in which DNA and RNA polymerases are immobilized by attachment to larger structures, where they reel in their templates and extrude newly made nucleic acids. These polymerases do not act independently; they are concentrated in discrete "factories," where they work together on many different templates. Evidence for models involving tracking and immobile polymerases is reviewed.

Spatial organization of four hnRNP proteins in relation to sites of transcription, to nuclear speckles, and to each other in interphase nuclei and nuclear matrices of HeLa cells

RNA polymerase II transcripts are complexed with heterogeneous nuclear ribonucleoprotein (hnRNP) proteins. These proteins are involved in several aspects of the maturation and transport of hnRNA. We performed a detailed study of the spatial distribution of four hnRNP proteins (hnRNP C, I, L, and U) in HeLa nuclei, using immunofluorescent labeling and confocal microscopy. Despite the fact that hnRNP proteins have been shown to coimmunoprecipitate, a hallmark of hnRNP proteins, we find that hnRNP C, I, and L have a spatial nuclear distribution that is not related to that of hnRNP U. We also examined the distribution of hnRNP proteins in relation to that of nascent transcripts. The four hnRNP proteins that we examined are not enriched at sites of RNA synthesis. Using antibodies against the nuclear poly(A)-binding protein (PAB II) we investigated the relationship between the distribution of hnRNP proteins and that of nuclear domains (nuclear speckles) that are enriched in splicing factors, poly(A)+RNA, and PAB II. We found that the four hnRNP proteins are not enriched in these domains. This indicates that the poly(A)+RNA, present in high concentration in speckles, is not complexed with these hnRNP proteins. This is in agreement with the notion that poly(A)+RNA in speckles is different from ordinary hnRNA. Previously, we have shown that hnRNP proteins are the major protein components of the fibrogranular internal nuclear matrix (K. A. Mattern et al. (1996) J. Cell. Biochem. 62, 275-289; K. A. Mattern et al. (1997) J. Cell. Biochem. 65, 42-52). We observed that in nuclear matrices the spatial distributions of the four hnRNP proteins, like that of nascent RNA and PAB II, are essentially the same as observed in intact nuclei. Moreover, also in nuclear matrix preparations, like in intact nuclei, nascent RNA and PAB II have spatial distributions that differ from those of hnRNP proteins. Our results are compatible with the notion that hnRNP proteins are able to form complexes of many different, probably overlapping, compositions.

Transcription sites are not correlated with chromosome territories in wheat nuclei

We have determined the relationship between overall nuclear architecture, chromosome territories, and transcription sites within the nucleus, using three-dimensional confocal microscopy of well preserved tissue sections of wheat roots. Chromosome territories were visualized by GISH using rye genomic probe in wheat/rye translocation and addition lines. The chromosomes appeared as elongated regions and showed a clear centromere-telomere polarization, with the two visualized chromosomes lying approximately parallel to one another across the nucleus. Labeling with probes to telomeres and centromeres confirmed a striking Rabl configuration in all cells, with a clear clustering of the centromeres, and cell files often maintained a common polarity through several division cycles. Transcription sites were detected by BrUTP incorporation in unfixed tissue sections and revealed a pattern of numerous foci uniformly distributed throughout the nucleoplasm, as well as more intensely labeled foci in the nucleoli. It has been suggested that the gene-rich regions in wheat chromosomes are clustered towards the telomeres. However, we found no indication of a difference in concentration of transcription sites between telomere and centromere poles of the nucleus. Neither could we detect any evidence that the transcription sites were preferentially localized with respect to the chromosome territorial boundaries.

Dynamic interactions between splicing snRNPs, coiled bodies and nucleoli revealed using snRNP protein fusions to the green fluorescent protein

The U1, U2, U4/U6, and U5 small nuclear ribonucleoproteins (snRNPs) are subunits of splicing complexes that remove introns from mRNA precursors. snRNPs show a complex, transcription-dependent localization pattern in the nucleoplasm of mammalian cells that results from their association with several distinct subnuclear structures, including interchromatin granule clusters, perichromatin fibrils, and coiled bodies. Here we report the analysis of snRNP localization and interaction with the coiled body in live human cells using fusions of snRNP proteins and p80 coilin to the Green Fluorescent Protein (GFP). Despite the large size of the GFP tag, GFP fusions to both the core snRNP SmE and U1 specific U1A proteins assemble into snRNP particles and give an identical nuclear localization pattern to their endogenous counterparts. GFP-coilin localizes specifically to coiled bodies in a transcription-dependent fashion and provides an accurate marker for coiled bodies in a variety of human cell lines. Treatment of cells with the selective ser/thr-protein phosphatase inhibitor, okadaic acid, causes both GFP-snRNP and GFP-coilin proteins to accumulate within nucleoli, but does not result in nucleolar accumulation of the GFP-fused non-snRNP protein splicing factor ASF/SF2. In all four human cell lines tested, expression of a GFP-fused p80 coilin mutant with a single serine to aspartate substitution also caused nucleolar accumulation of splicing snRNPs and coilin, but not ASF/SF2, in structures resembling coiled bodies when viewed by electron microscopy. This work establishes an experimental system for analyzing snRNP trafficking in living cells and provides evidence that a reversible protein phosphorylation mechanism is involved in regulating interaction of snRNPs and coiled bodies with the nucleolus.

Structure and function in the nucleus

Current evidence suggests that the nucleus has a distinct substructure, albeit one that is dynamic rather than a rigid framework. Viral infection, oncogene expression, and inherited human disorders can each cause profound and specific changes in nuclear organization. This review summarizes recent progress in understanding nuclear organization, highlighting in particular the dynamic aspects of nuclear structure.

Nuclear matrix, dynamic histone acetylation and transcriptionally active chromatin

The nuclear matrix, the RNA-protein skeleton of the nucleus, has a role in the organization and function of nuclear DNA. Nuclear processes associated with the nuclear matrix include transcription, replication and dynamic histone acetylation. Nuclear matrix proteins, which are tissue and cell type specific, are altered with transformation and state of differentiation. Transcription factors are associated with the nuclear matrix, with the spectra of nuclear matrix bound factors being cell type specific. There is compelling evidence that the transcription machinery is anchored to the nuclear matrix, and the chromatin fiber is spooled through this complex. Transcriptionally active chromatin domains are associated with dynamically acetylated histones. The energy exhaustive process of dynamic histone acetylation has several functions. Acetylation of the N-terminal tails of the core histones alters nucleosome and higher order chromatin structure, aiding transcriptional elongation and facilitating the binding of transcription factors to nucleosomes associated with regulatory DNA sequences. Histone acetylation can manipulate the interactions of regulatory proteins that bind to the N-terminal tails of the core histones. Lastly, dynamic acetylation may contribute to the transient attachment of transcriptionally active chromatin to the nuclear matrix. Reversible histone acetylation is catalyzed by histone acetyltransferase and deacetylase, enzymes associated with the nuclear matrix. The recent isolation and characterization of histone acetyltransferase and deacetylase reveals that these enzymes are related to transcriptional regulators, providing us with new insights about how these enzymes are targeted to nuclear matrix sites engaged in transcription.

Major internal nuclear matrix proteins are common to different human cell types

The nuclear matrix may be involved in the structural and functional organization of the cell nucleus. However, we still do not understand the molecular basis of the intranuclear fibrogranular network that is part of the nuclear matrix. We recently described a method to identify internal nuclear matrix proteins [Mattern et al. (1996): J Cell Biochem 62:275-289], which was done by comparing two nuclear matrix preparations: one with and one without the internal structure by using quantitative two-dimensional gel electrophoresis. In the present study, we use the same approach to compare the nuclear matrix proteins of four different human cell types to investigate whether they have a similar internal nuclear matrix protein composition. Major nuclear matrix proteins present in all these cell types likely represent the base of the internal nuclear matrix. We demonstrate that the 25 most abundant internal nuclear matrix proteins are common to all four cell types. Together, these common proteins represent more than 75% of the total internal nuclear matrix protein mass in each cell type. This set of proteins includes B23 and most hnRNP proteins. The quantity of most of these proteins is very similar in the four cell types. The fact that the internal nuclear matrix consists mainly of hnRNP proteins, which may be involved in transcription, transport, and processing of hnRNA, supports the idea that the internal nuclear matrix is the result of these processes.