Visualization of G1 chromosomes: a folded, twisted, supercoiled chromonema model of interphase chromatid structure

Changes of chromatin condensation in one patient with ataxia telangiectasia disorder: a structural study

Differential scanning calorimetry and quantitative fluorescence microscopy have been employed to characterize the structure and organization of in situ chromatin in lymphoblastoid cells obtained from one ataxia telangiectasia (A-T) patient and one healthy family member. The proven capability of these biophysical techniques to measure changes of chromatin condensation directly inside the cells makes them very powerful in studying the eventual structural changes associated with the appearance of a pleiotropic genetic disorder such as ataxia telangiectasia. A-T syndrome is genetically heterogeneous and can be induced by different mutations of a single gene. The aim of this work is to determine whether the genetic mutation exhibited by the A-T patient of this study may be associated with modifications of chromatin structure and organization. Both the calorimetric and the fluorescence microscopy results acquired on cells from the A-T patient show that the structure and distribution of nuclear chromatin in situ change considerably with respect to the control. A significant decondensation of the nuclear chromatin is in fact associated with the appearance of the A-T disorder in the A-T patient under analysis, together with a rearrangement of the chromatin domains inside the nucleus.

The spatial position and replication timing of chromosomal domains are both established in early G1 phase

Mammalian chromosomal domains replicate at defined, developmentally regulated times during S phase. The positions of these domains in Chinese hamster nuclei were established within 1 hr after nuclear envelope formation and maintained thereafter. When G1 phase nuclei were incubated in Xenopus egg extracts, domains were replicated in the proper temporal order with nuclei isolated after spatial repositioning, but not with nuclei isolated prior to repositioning. Mcm2 was bound both to early- and late-replicating chromatin domains prior to this transition whereas specification of the dihydrofolate reductase replication origin took place several hours thereafter. These results identify an early G1 phase point at which replication timing is determined and demonstrate a provocative temporal coincidence between the establishment of nuclear position and replication timing.

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.

Chromosomes as well as chromosomal subdomains constitute distinct units in interphase nuclei

Fluorescence in situ hybridization has demonstrated that chromosomes form individual territories in interphase nuclei. However, this technique is not suitable to determine whether territories are mutually exclusive or interwoven. This notion, however, is essential for understanding functional organizations in the cell nucleus. Here, we analyze boundary areas of individual chromosomes during interphase using a sensitive method based on replication labeling and immunocytochemistry. Thymidine analogues IdUrd and CldUrd were incorporated during S-phase into DNA of Chinese Hamster fibroblasts. Cells labeled with IdUrd were fused with cells labeled with CldUrd. Fused nuclei contained both IdUrd or CldUrd labeled chromosomes. Alternatively, the two labels were incorporated sequentially during successive S-phases and segregated to separate chromosomes by culturing the cells one more cell cycle. Metaphase spreads showed IdUrd-, CldUrd- and unlabeled chromosomes. Some chromatids were divided sharply in differently labeled subdomains by sister chromatid exchanges. With both methods, confocal imaging of interphase nuclei revealed labeled chromosomal domains containing fiber-like structures and unlabeled areas. At various sites, fiber-like structures were embedded in other territories. Even so, essentially no overlap between chromosome territories or between subdomains within a chromosome was observed. These observations indicate that chromosome territories and chromosomal subdomains in G(1)-phase are mutually exclusive at the resolution of the light microscope.

Nuclear organization of mammalian genomes. Polar chromosome territories build up functionally distinct higher order compartments

We investigated the nuclear higher order compartmentalization of chromatin according to its replication timing (Ferreira et al. 1997) and the relations of this compartmentalization to chromosome structure and the spatial organization of transcription. Our aim was to provide a comprehensive and integrated view on the relations between chromosome structure and functional nuclear architecture. Using different mammalian cell types, we show that distinct higher order compartments whose DNA displays a specific replication timing are stably maintained during all interphase stages. The organizational principle is clonally inherited. We directly demonstrate the presence of polar chromosome territories that align to build up higher order compartments, as previously suggested (Ferreira et al. 1997). Polar chromosome territories display a specific orientation of early and late replicating subregions that correspond to R- or G/C-bands of mitotic chromosomes. Higher order compartments containing G/C-bands replicating during the second half of the S phase display no transcriptional activity detectable by BrUTP pulse labeling and show no evidence of transcriptional competence. Transcriptionally competent and active chromatin is confined to a coherent compartment within the nuclear interior that comprises early replicating R-band sequences. As a whole, the data provide an integrated view on chromosome structure, nuclear higher order compartmentalization, and their relation to the spatial organization of functional nuclear processes.

Organization of chromatin in cancer cells: role of signalling pathways

The role of mechanical and chemical signalling pathways in the organization and function of chromatin is the subject of this review. The mechanical signalling pathway consists of the tissue matrix system that links together the three-dimensional skeletal networks, the extracellular matrix, cytoskeleton, and nuclear matrix. Intermediate filament proteins are associated with nuclear DNA, suggesting that intermediate filaments may have a role in the organization of chromatin. In human hormone-dependent breast cancer cells, the interaction between cytokeratins and chromatin is regulated by estrogens. Transcription factors, histone acetyltransferases, and histone deacetylases, which are associated with the nuclear matrix, are components of the mechanical signalling pathway. Recently, we reported that nuclear matrix-bound human and chicken histone deacetylase 1 is associated with nuclear DNA in situ, suggesting that histone deacetylase has a role in the organization of nuclear DNA. Chemical signalling pathways such as the Ras/mitogen-activated protein kinase (Ras/MAPK) pathway stimulate the activity of kinases that modify transcription factors, nonhistone chromosomal proteins, and histones. The levels of phosphorylated histones are increased in mouse fibroblasts transformed with oncogenes, the products of which stimulate the Ras/MAPK pathway. Histone phosphorylation may lead to decondensation of chromatin, resulting in aberrant gene expression.Key words: histone acetylation, histone phosphorylation, nuclear matrix, cytoskeleton, histone deacetylase, cancer.

13S condensin actively reconfigures DNA by introducing global positive writhe: implications for chromosome condensation

Xenopus 13S condensin converts interphase chromatin into mitotic-like chromosomes, and, in the presence of ATP and a type I topoisomerase, introduces (+) supercoils into DNA. The specific production of (+) trefoil knots in the presence of condensin and a type II topoisomerase shows that condensin reconfigures DNA by introducing an ordered, global, (+) writhe. Knotting required ATP hydrolysis and cell cycle-specific phosphorylation of condensin. Condensin bound preferentially to (+) supercoiled DNA in the presence of ATP but not in its absence. Our results suggest a mechanism for the compaction of chromatin by condensin during mitosis.

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.

Dynamics of structure-function relationships in interphase nuclei

The interphase nucleus is a topologically ordered, three-dimensional structure. While it remains unclear whether this structural organization also represents compartmentalization of function, the presence of the latter would likely be reflected in the spatial coupling of molecular factors involved in related events. This review summarizes morphological evidence, derived from in situ experiments, which indicates the existence of compartmentalization of both chromatin and non-chromatin components in the interphase nucleus. Moreover, the review addresses the spatial relationships of these components relative to each other and correlates these spatial relationships with such nuclear functions as transcription, splicing and nucleo-cytoplasmic transport of pre-mRNA. Given that it is increasingly recognized that such spatial relationships are dynamic, the review also addresses the emerging concept that the spatial intranuclear organization changes with changes in cell function, a concept which supports the hypothesis that the spatial organization of the interphase nucleus may represent one of the fundamental control mechanisms in gene expression.

Large-scale chromatin structure and function

Recent results in living cells have now established the existence of levels of chromatin folding above the 30 nm fiber within interphase chromosomes. We discuss the potential functional impact of this large-scale chromatin organization, including its possible role in regulating gene expression.

Compartmentalization of interphase chromosomes observed in simulation and experiment

Human interphase chromosomes were simulated as a flexible fiber with excluded volume interaction, which represents the chromatin fiber of each chromosome. For the higher-order structures, we assumed a folding into 120 kb loops and an arrangement of these loops into rosette-like subcompartments. Chromosomes consist of subcompartments connected by small fragments of chromatin. Number and size of subcompartments correspond with chromosome bands in early prophase. We observed essentially separated chromosome arms in both our model calculations and confocal laser scanning microscopy, and measured the same overlap in simulation and experiment. Overlap, number and size of chromosome 15 subcompartments of our model chromosomes agree with subchromosomal foci composed of either early or late replicating chromatin, which were observed at all stages of the cell cycle and possibly provide a functionally relevant unit of chromosome territory compartmentalization. Computed distances of chromosome specific markers both on Mb and 10-100 Mb scale agree with fluorescent in situ hybridization measurements under different preparation conditions.

Linker histones stabilize the intrinsic salt-dependent folding of nucleosomal arrays: mechanistic ramifications for higher-order chromatin folding

Defined nucleosomal arrays reconstituted from core histone octamers and twelve 208 bp tandem repeats of Lytechinus 5S rDNA (208-12 nucleosomal arrays) possess the ability to form an unstable folded species in MgCl2 whose extent of compaction equals that of canonical higher-order 30 nm diameter chromatin structures [Schwarz, P. M., and Hansen, J. C. (1994) J. Biol. Chem. 269, 16284-16289]. To address the mechanistic functions of linker histones in chromatin condensation, purified histone H5 has been assembled with 208-12 nucleosomal arrays in 50 mM NaCl. Novel purification procedures subsequently were developed that yielded preparations of 208-12 chromatin model systems in which a majority of the sample contained both one histone octamer per 5S rDNA repeat and one molecule of histone H5 per histone octamer. The integrity of the purified 208-12 chromatin has been extensively characterized under low-salt conditions using analytical ultracentrifugation, quantitative agarose gel electrophoresis, electron cryomicroscopy, and nuclease digestion. Results indicate that histone H5 binding to 208-12 nucleosomal arrays constrains the entering and exiting linker DNA in a way that produces structures that are indistinguishable from native chicken erythrocyte chromatin. Folding experiments performed in NaC1 and MgC12 have shown that H5 binding markedly stabilizes both the intermediate and extensively folded states of nucleosomal arrays without fundamentally altering the intrinsic nucleosomal array folding pathway. These results provide new insight into the mechanism of chromatin folding by demonstrating for the first time that distinctly different macromolecular determinants are required for formation and stabilization of higher-order chromatin structures.

Spatial distributions of early and late replicating chromatin in interphase chromosome territories

The surface area of chromosome territories has been suggested as a preferred site for genes, specific RNAs, and accumulations of splicing factors. Here, we investigated the localization of sites of replication within individual chromosome territories. In vivo replication labeling with thymidine analogues IdUrd and CldUrd was combined with chromosome painting by fluorescent in situ hybridization on three-dimensionally preserved human fibroblast nuclei. Spatial distributions of replication labels over the chromosome territory, as well as the territory volume and shape, were determined by 3D image analysis. During late S-phase a previously observed shape difference between the active and inactive X-chromosome in female cells was maintained, while the volumes of the two territories did not differ significantly. Domains containing early or mid to late replicating chromatin were distributed throughout territories of chromome 8 and the active X. In the inactive X-chromosome early replicating chromatin was observed preferentially near the territory surface. Most important, we established that the process of replication takes place in foci throughout the entire chromosome territory volume, in early as well as in late S-phase. This demonstrates that activity of macromolecular enzyme complexes takes place throughout chromosome territories and is not confined to the territory surface as suggested previously.

Organization of highly acetylated chromatin around sites of heterogeneous nuclear RNA accumulation

Histones found within transcriptionally competent and active regions of the genome are highly acetylated. Moreover, these highly acetylated histones have very short half-lives. Thus, both histone acetyltransferases and histone deacetylases must enrich within or near these euchromatic regions of the interphase chromatids. Using an antibody specific for highly acetylated histone H3, we have investigated the organization of transcriptionally active and competent chromatin as well as nuclear histone acetyltransferase and deacetylase activities. We observe an exclusion of highly acetylated chromatin around the periphery of the nucleus and an enrichment near interchromatin granule clusters (IGCs). The highly acetylated chromatin is found in foci that may reflect the organization of highly acetylated chromatin into "chromonema" fibers. Transmission electron microscopy of Indian muntjac fibroblast cell nuclei indicates that the chromatin associated with the periphery of IGCs remains relatively condensed, most commonly found in domains containing chromatin folded beyond 30 nm. Using electron spectroscopic imaging, we demonstrate that IGCs are clusters of ribonucleoprotein particles. The individual granules comprise RNA-rich fibrils or globular regions that fold into individual granules. Quantitative analysis of individual granules indicates that they contain variable amounts of RNA estimated between 1.5 and >10 kb. We propose that interchromatin granules are heterogeneous nuclear RNA-containing particles, some of which may be pre-mRNA generated by nearby transcribed chromatin. An intermediary zone between the IGC and surrounding chromatin is described that contains factors with the potential to provide specificity to the localization of sequences near IGCs.

Chromatin remodeling: a marriage between two families?

The compaction of the eukaryotic genome into a highly folded chromatin structure necessitates cellular mechanisms for allowing access of regulatory proteins to the DNA template. Recent advances in the fields of gene silencing, transcription, recombination, and DNA repair have led to the identification of two distinct families of chromatin remodeling enzymes--nuclear histone acetyltransferases and multisubunit complexes that harbor a SWI2/SNF2 ATPase family member. This paper reviews the current notion of how these enzymes function in remodeling chromatin; we then discuss some tantalizing lines of evidence that lead to the hypothesis that members of both families may actually function in concert to facilitate cellular processes in the context of chromatin.

Structure, dynamics, and function of chromatin in vitro

The substrates for the essential biological processes of transcription, replication, recombination, DNA repair, and cell division are not naked DNA; rather, they are protein-DNA complexes known as chromatin, in one or another stage of a hierarchical series of compactions. These are exciting times for students of chromatin. New studies provide incontrovertible evidence linking chromatin structure to function. Exceptional progress has been made in studies of the structure of chromatin subunits. Surprising new dynamic properties have been discovered. And, much progress has been made in dissecting the functional roles of specific chromatin proteins and domains. This review focuses on in vitro studies of chromatin structure, dynamics, and function.

Partial denaturation of small chromatin fragments: direct evidence for the radial distribution of nucleosomes in folded chromatin fibers

To examine the internal structure of chromatin fibers, we have developed procedures for partial denaturation of small chromatin fragments (8–30 nucleosomes) from chicken erythrocytes. Electron micrographs of samples prepared under conditions that cause nucleosome dissociation show rods and loops projecting from short compact fibers fixed by glutaraldehyde in 1.7 mM Mg2+. According to previous studies in our laboratory, these images correspond to the top view of partially denatured fibers. Our results indicate that rods and loops consist of extended duplex DNA of different lengths. DNA in loops is nicked, as demonstrated by experiments performed in the presence of high concentrations of ethidium bromide. Length measurements indicate that the radial projections of DNA are produced by unfolding of nucleosomal units. Loops are formed by DNA from denatured nucleosomes in internal positions of the fiber; DNA from denatured nucleosomes in terminal positions form rods. Our micrographs show clearly a radial distribution of DNA loops and rods projecting from fibers. Rods are orthogonal to the surface of the chromatin fragments. Considering that the high ionic strength used in this study (0.8-2.0 M NaCl) neutralizes the electrostatic repulsions between rods and fiber, this observation suggests that rods are extensions of nucleosomes radially organized inside the fiber. The position of the entry points of DNA loops into the fiber could be influenced by constraint on loops, but our results showing that the arc that separates these points in dinucleosome loops is relatively short suggest that consecutive nucleosomes are relatively close to each other in the folded fiber.

Histone-GFP fusion protein enables sensitive analysis of chromosome dynamics in living mammalian cells

BACKGROUND

The amplification of oncogenes in cancer cells is often mediated by paired acentric chromatin bodies called double minute chromosomes (DMs), which can accumulate to a high copy number because of their autonomous replication during the DNA synthesis phase of the cell cycle and their subsequent uneven distribution to daughter cells during mitosis. The mechanisms that control DM segregation have been difficult to investigate, however, as the direct visualization of DMs in living cells has been precluded because they are far smaller than normal chromosomes. We have visualized DMs by developing a highly sensitive method for observing chromosome dynamics in living cells.

RESULTS

The human histone H2B gene was fused to the gene encoding the green fluorescent protein (GFP) of Aequorea victoria and transfected into human HeLa cells to generate a stable line constitutively expressing H2B-GFP. The H2B-GFP fusion protein was incorporated into nucleosomes without affecting cell cycle progression. Using confocal microscopy, H2B-GFP allowed high-resolution imaging of both mitotic chromosomes and interphase chromatin, and the latter revealed various chromatin condensation states in live cells. Using H2B-GFP, we could directly observe DMs in living cancer cells; DMs often clustered during anaphase, and could form chromosomal 'bridges' between segregating daughter chromosomes. Cytokinesis severed DM bridges, resulting in the uneven distribution of DMs to daughter cells.

CONCLUSIONS

The H2B-GFP system allows the high-resolution imaging of chromosomes, including DMs, without compromising nuclear and chromosomal structures and has revealed the distinctive clustering behavior of DMs in mitotic cells which contributes to their asymmetric distribution to daughter cells.

Interphase cell cycle dynamics of a late-replicating, heterochromatic homogeneously staining region: precise choreography of condensation/decondensation and nuclear positioning

Recently we described a new method for in situ localization of specific DNA sequences, based on lac operator/repressor recognition (Robinett, C.C., A. Straight, G. Li, C. Willhelm, G. Sudlow, A. Murray, and A.S. Belmont. 1996. J. Cell Biol. 135:1685-1700). We have applied this methodology to visualize the cell cycle dynamics of an approximately 90 Mbp, late-replicating, heterochromatic homogeneously staining region (HSR) in CHO cells, combining immunostaining with direct in vivo observations. Between anaphase and early G1, the HSR extends approximately twofold to a linear, approximately 0.3-mum-diam chromatid, and then recondenses to a compact mass adjacent to the nuclear envelope. No further changes in HSR conformation or position are seen through mid-S phase. However, HSR DNA replication is preceded by a decondensation and movement of the HSR into the nuclear interior 4-6 h into S phase. During DNA replication the HSR resolves into linear chromatids and then recondenses into a compact mass; this is followed by a third extension of the HSR during G2/ prophase. Surprisingly, compaction of the HSR is extremely high at all stages of interphase. Preliminary ultrastructural analysis of the HSR suggests at least three levels of large-scale chromatin organization above the 30-nm fiber.

In vivo visualization of chromosomes using lac operator-repressor binding

This article describes a new technique for direct, in vivo visualization of chromosome dynamics based on lac repressor recognition of direct repeats of the lac operator. The method allows the tagging of specific chromosomal sites and thus in situ localization with minimal perturbation of structure. Detection by light microscopy, using GFP-repressor fusion proteins or immunofluorescence, can be complemented by higher-resolution electron microscopy using immunogold staining. Applications of this method will facilitate the investigation of interphase chromosome dynamics, as well as chromosome segregation during cell division in organisms that lack cytologically condensed chromosomes.

Junk DNA and sectorial gene repression

Transcriptional repression in eukaryotes often involves tens or hundreds of kilobase pairs, two to three orders of magnitude more than the bacterial operator/repressor model does. Classical repression, represented by this model, was maintained over the whole span of evolution under different guises, and consists of repressor factors interacting primarily with promoters and, in later evolution, also with enhancers. The use of much larger amounts of DNA in the other mode of repression, here called the sectorial mode ('superrepression'), results in the conceptual transfer of so-called junk DNA to the domain of functional DNA. This contribution to the solution of the c-value paradox involves perhaps 15% of genomic 'junk,' and encompasses the bulk of the introns, thought to fill a stabilizing role in sectorially repressed chromatin structures. In the case of developmental genes, such structures appear to be heterochromatoid in character. However, solid clues regarding general structural features of superrepressed terminal differentiation genes remain elusive. The competition among superrepressible DNA sectors for sectorially binding factors offers, in principle, a molecular mechanism for developmental switches. Position effect variegation may be considered an abnormal manifestation of normal processes that underly development and involve heterochromatoid sectorial repression, which is apparently required for local elimination or modulation of morphological features (morpholysis). Sectorial repression of genes participating either in development or in terminal differentiation is considered instrumental in establishing stable cell types, and provides a basis for the distinction between determination and cell type specification. The gamut of possible stable cell types may have been broadened by the appearance in evolution of heavy isochores. Additional types of relatively frequent GC-rich cis-acting DNA motifs may offer reiterated binding sites to factors endowed with a selective (though not individually strong) affinity for these motifs. The majority of sequence motifs thought to be used in superrepression need not be individually maintained by natural selection. It is re-emphasized that the dispensability of sequences is not an indicator of their nonfunctionality and that in many cases, along noncoding sequences, nucleotides tend to fill functions collectively, rather than individually.

Visualization of chromatin folding patterns in chicken erythrocytes by atomic force microscopy (AFM)

The organization of the higher order structure of chromatin in chicken erythrocytes has been examined with tapping-mode scanning force microscopy under conditions close to their native environment. Reproducible high-resolution AFM images of chromatin compaction at several levels can be demonstrated. An extended beads-on-astring (width of approximately 15-20 nm, height of approximately 2-3 nm for each individual nucleosome) can be consistently observed. Furthermore, superbeads (width of approximately 40 nm, height of approximately 7 nm) are demonstrated. Visualization of the solenoid conformation at the level of 30 nm chromatin fiber is attained either by using AFM or by using electron microscopy. In addition, tightly coiled chromatin fibers (approximately 50-60 nm and approximately 90-110 nm) can be revealed. Our data suggest that the chromatin in the interphase nucleus of chicken erythrocyte represents a high-order conformation and AFM provides useful high-resolution structural information concerning the folding pattern of interphase chromatin fibers.

High order DNA structure as inferred by optical fluorimetry and scanning calorimetry

New quantitative insights on the native high order chromatin-DNA structure existing within interphase nuclei are obtained by monitoring the effects of two common well-characterized fixatives, glutaraldehyde and ethanol/acetic acid mixture, at the level of the intranuclear DNA distribution and structures. Reproducible distinct levels of DNA fluorescence intensity and their intranuclear distribution are apparent in unfixed and fixed thymocytes by using DAPI and quantitative optical microscopy based on a charge coupled device. The fluorescent histograms correlated with the calorimetric thermograms on the very same thymocytes fixed and unfixed, establish an unequivocal baseline for the different levels of structural organization of the chromatin within the intact nucleus; namely their number, DNA packing ratio and fiber diameter. A systematic comparison among all the numerous models, being so far proposed for the quinternary and quaternary levels of DNA folding, to identifies the rope or ribbon-like and the chromonema as the ones that best fit with the in situ distribution.

Hybrid trypsinized nucleosomal arrays: identification of multiple functional roles of the H2A/H2B and H3/H4 N-termini in chromatin fiber compaction

A defined 12-mer nucleosomal array in solution exists in a complex equilibrium between an unfolded 29S conformation, a 40S folding intermediate, an extensively folded 55S conformation, and soluble oligomeric states formed from cooperative intermolecular association of individual 12-mer arrays. Proteolytic removal of all of the core histone N-terminal tail domains previously has been shown to abolish both salt-dependent nucleosomal array folding and oligomerization. To elucidate the individual contributions of the H2A/H2B and H3/H4 tail domains to nucleosomal array condensation, "hybrid" trypsinized nucleosomal arrays have been assembled from tandemly repeated 5S rDNA and either trypsinized H3/H4 tetramers and intact H2A/H2B dimers or trypsinized H2A/H2B dimers and intact H3/H4 tetramers. Neither of the hybrid trypsinized arrays formed either the 40S or the 55S folded conformations in 2 mM MgCl2. In >/=4 mM MgCl2, however, both fully trypsinized arrays and each hybrid trypsinized array formed the 40S folding intermediate, but not the 55S conformation. In contrast to folding, each hybrid trypsinized nucleosomal array oligomerized completely in MgCl2. These studies have identified three mechanistically distinct functions performed by the core histone N-termini during salt-dependent condensation of nucleosomal arrays. The complexity of tail domain function in chromatin is discussed in the context of a competitive interaction model in which the core histone N-termini provide direct mechanistic links between the structure and function of the chromatin fiber.

The N-terminal tail of histone H2A binds to two distinct sites within the nucleosome core

Each of the core histone proteins within the nucleosome has a central "structured" domain that comprises the spool onto which the DNA superhelix is wrapped and an N-terminal "tail" domain in which the structure and molecular interactions have not been rigorously defined. Recent studies have shown that the N-terminal domains of core histones probably contact both DNA and proteins within the nucleus and that these interactions play key roles in the regulation of nuclear processes (such as transcription and replication) and are critical in the formation of the chromatin fiber. An understanding of these complex mechanisms awaits identification of the DNA or protein sites within chromatin contacted by the tail domains. To this end, we have developed a site-specific histone protein-DNA photocross-linking method to identify the DNA binding sites of the N-terminal domains within chromatin complexes. With this approach, we demonstrate that the N-terminal tail of H2A binds DNA at two defined locations within isolated nucleosome cores centered around a position approximately 40 bp from the nucleosomal dyad and that this tail probably adopts a defined structure when bound to DNA.

Studies on the structure of sperm heads of Eledone cirrhosa by means of CLSM linked to bioimage-oriented devices

We have used a confocal laser scanning optical microscope imaging device and a bioimage-oriented workstation equipped for augmented reality to study the helical sperm head of the octopus Eledone cirrhosa. This approach allows us to study different complex organisational motifs due to the spatial arrangement of linear helical structures. We consider this helical specimen an enlarged copy of one of the most important biostructures governing cell functioning such as chromatin-DNA. Moreover, this very same sample is made of highly compacted chromatin that can be studied at higher resolution, i.e., by means of scanning force microscopy. Fluorescence optical sectioning has been used to enter the spatial organisation. Three-dimensional images of single, twisted, and folded fibers are shown.

In vivo localization of DNA sequences and visualization of large-scale chromatin organization using lac operator/repressor recognition

We report a new method for in situ localization of DNA sequences that allows excellent preservation of nuclear and chromosomal ultrastructure and direct, in vivo observations. 256 direct repeats of the lac operator were added to vector constructs used for transfection and served as a tag for labeling by lac repressor. This system was first characterized by visualization of chromosome homogeneously staining regions (HSRs) produced by gene amplification using a dihydrofolate reductase (DHFR) expression vector with methotrexate selection. Using electron microscopy, most HSRs showed approximately 100-nm fibers, as described previously for the bulk, large-scale chromatin organization in these cells, and by light microscopy, distinct, large-scale chromatin fibers could be traced in vivo up to 5 microns in length. Subsequent experiments demonstrated the potential for more general applications of this labeling technology. Single and multiple copies of the integrated vector could be detected in living CHO cells before gene amplification, and detection of a single 256 lac operator repeat and its stability during mitosis was demonstrated by its targeted insertion into budding yeast cells by homologous recombination. In both CHO cells and yeast, use of the green fluorescent protein-lac repressor protein allowed extended, in vivo observations of the operator-tagged chromosomal DNA. Future applications of this technology should facilitate structural, functional, and genetic analysis of chromatin organization, chromosome dynamics, and nuclear architecture.

Ultrastructural localization of active genes in nuclei of A431 cells

We have studied the ultrastructural localization of active genes in nuclei of the human epidermoid carcinoma cell line A431. Nascent RNA was labeled by incorporation of 5-bromouridine 5'-triphosphate, followed by pre-embedment or postembedment immunogold labeling and electron microscopy using ultrasmall gold-conjugated antibodies and silver enhancement. This combination of techniques allowed a sensitive and high resolution visualization of RNA synthesis in the nucleus. Transcription sites were identified as clusters of 3-20 gold particles and were found throughout the nucleoplasm. The clusters had a diameter of less than 200 nm. The distribution of clusters of gold particles in nuclei is preserved in nuclear matrix preparations. Nascent RNA is associated with fibrillar as well as with granular structures in the matrix. A431 nuclei contained on average about 10,000 clusters of gold particles. This means that each cluster represents transcription of probably one active gene or, at most, a few genes. Our study does not provide evidence for aggregation of active genes. We found transcription sites distributed predominantly on the surface of electron-dense nuclear material, probably lumps of chromatin. This supports a model of transcription activation preferentially on the boundary between a chromosome domain and the interchromatin space.

Reversible oligonucleosome self-association: dependence on divalent cations and core histone tail domains

Regularly spaced nucleosomal arrays equilibrate between unfolded and highly folded conformations in <2 mM MgCl2, and self-associate above 2 mM MgCl2 [Schwarz, P. M., & Hansen, J. C. (1994) J. Biol. Chem. 269, 16284-16289]. Here we use analytical and differential sedimentation techniques to characterize the molecular mechanism and determinants of oligonucleosome self-association. Divalent cations induce self-association of intact nucleosomal arrays by binding to oligonucleosomal DNA and neutralizing its negative charge. Neither linker histones nor H2A/H2B dimers are required for Mg2+ - dependent self-association. However, divalent cations are unable to induce self-association of trypsinized nucleosomal arrays lacking their N- and C-terminal core histone tail domains. This suggests that the H3/H4 tail domains directly mediate oligonucleosome self-association through a non-Coulombic-based mechanism. Self-association occurs independently of whether the oligonucleosome monomers are folded or unfolded. The first step in the self-association pathway is strongly cooperative and produces a soluble association intermediate that sediments approximately 10 times faster than the oligonucleosome monomers. The size of the oligonucleosome polymers increases rapidly as a consequence of small increases in the divalent cation concentration, eventually producing polymeric species that sediment at >> 10 000 S. Importantly, all steps in the self-association pathway are freely reversible upon removal of the divalent cations. Taken together, these data indicate that short oligonucleosome fragments composed of only core histone octamers and DNA possess all of the structural features required to achieve chromosome-level DNA compaction. These findings provide a molecular basis for explaining many of the recently uncovered structural features of interphase and metaphase chromosomal fibers.