Reversible and irreversible changes in nucleosome structure along the c-fos and c-myc oncogenes following inhibition of transcription

Nup50 is required for cell differentiation and exhibits transcription-dependent dynamics

Nup50 is a mobile nucleoporin with a pronounced presence both at the nuclear pore complex and in the nucleoplasm that can move between these different localizations. The dynamic behavior of Nup50 in both locations is dependent on active transcription by RNA polymerase II.

The nuclear pore complex (NPC) plays a critical role in gene expression by mediating import of transcription regulators into the nucleus and export of RNA transcripts to the cytoplasm. Emerging evidence suggests that in addition to mediating transport, a subset of nucleoporins (Nups) engage in transcriptional activation and elongation at genomic loci that are not associated with NPCs. The underlying mechanism and regulation of Nup mobility on and off nuclear pores remain unclear. Here we show that Nup50 is a mobile Nup with a pronounced presence both at the NPC and in the nucleoplasm that can move between these different localizations. Strikingly, the dynamic behavior of Nup50 in both locations is dependent on active transcription by RNA polymerase II and requires the N-terminal half of the protein, which contains importin α– and Nup153-binding domains. However, Nup50 dynamics are independent of importin α, Nup153, and Nup98, even though the latter two proteins also exhibit transcription-dependent mobility. Of interest, depletion of Nup50 from C2C12 myoblasts does not affect cell proliferation but inhibits differentiation into myotubes. Taken together, our results suggest a transport-independent role for Nup50 in chromatin biology that occurs away from the NPC.

The nucleosome family: dynamic and growing

Ever since the discovery of the nucleosome in 1974, scientists have stumbled upon discrete particles in which DNA is wrapped around histone complexes of different stoichiometries: octasomes, hexasomes, tetrasomes, "split" half-nucleosomes, and, recently, bona fide hemisomes. Do all these particles exist in vivo? Under what conditions? What is their physiological significance in the complex DNA transactions in the eukaryotic nucleus? What are their dynamics? This review summarizes research spanning more than three decades and provides a new meaning to the term "nucleosome." The nucleosome can no longer be viewed as a single static entity: rather, it is a family of particles differing in their structural and dynamic properties, leading to different functionalities.

Transcription through chromatin: understanding a complex FACT

In eukaryotic cells, genomic DNA is assembled with chromosomal proteins, mainly histones, in a highly compact structure termed chromatin. In this form, DNA is not readily accessible to the cellular machineries, which require DNA as a template. Dynamic changes in chromatin organization play a critical role in regulation of DNA-dependent processes such as transcription, DNA replication, recombination and repair. Chromatin structure is altered in transcriptionally active loci: the basic chromatin unit, the nucleosome, appears to be depleted for one histone H2A/H2B dimer. Previously, reconstitution of RNA polymerase II (PolII)-driven transcription on chromatin templates in a highly purified in vitro system led to identification of FACT (for facilitates chromatin transcription), which was required for productive transcript elongation through nucleosomes. FACT was proposed to promote PolII transcription through nucleosomes by removing either one or both H2A/H2B dimers. Here we present an overview of the earlier studies, which resulted in the initial identification and characterization of FACT, as well as the recent findings that refine the model for the mechanism of FACT function in transcription.

Growth arrest of HPV-positive cells after histone deacetylase inhibition is independent of E6/E7 oncogene expression

Inhibitors of histone deacetylase (HDAC) are capable of arresting growth in cervical carcinoma cells in the G1 phase of the cell cycle. Although HPV E6/E7 mRNA steady-state levels appeared to be constant after prolonged treatment, time-course experiments revealed that viral transcription was transiently down-regulated between 7-10 h prior to cdk2 suppression. To test whether transitory suppression was a prerequisite for the biological outcome after HDAC inhibition, we took advantage of two immortalized human keratinocyte cell lines in which E6/E7 oncogene expression was controlled by different regulatory regions. After treatment with sodium butyrate (NaB) or trichostatin A (TSA), HPV16 upstream regulatory region (URR)-directed transcription was down-regulated, showing kinetics similar to those in cervical carcinoma cells. In contrast, beta-actin promoter controlled E6/E7 transcription was even temporarily increased and finally declined to levels initially detected in the untreated controls. Both cell lines, however, were arrested in G1 and showed complete suppression of cdk2 activity that was preceded by a strong up-regulation of the cdk2 inhibitors p21(CIP1) and p27(KIP1). These results demonstrate that growth of HPV16/18-positive cells can be arrested by HDAC inhibitors despite ongoing HPV transcription and thus independently of any potential position effects uncoupling URR-directed gene expression by adjacent cellular promoters or by downstream 3'-polyadenylation sites after viral integration into the host genome during multistep carcinogenesis.

Transcript elongation on a nucleoprotein template

Chromatin forms a general, repeating barrier to elongation of transcripts by eukaryotic RNA polymerases. Recent studies of nucleosome structure and histone modifications reveal a set of likely mechanisms for control of elongation through chromatin. Genetic and biochemical studies of transcription have identified a set of accessory factors for transcript elongation by RNA polymerase II (Pol II) that appear to function in the context of chromatin. The C-terminal repeated domain (CTD) of Pol II may also play a role in regulating elongation through chromatin.

Conformational dynamics of the chromatin fiber in solution: determinants, mechanisms, and functions

Chromatin fibers are dynamic macromolecular assemblages that are intimately involved in nuclear function. This review focuses on recent advances centered on the molecular mechanisms and determinants of chromatin fiber dynamics in solution. Major points of emphasis are the functions of the core histone tail domains, linker histones, and a new class of proteins that assemble supramolecular chromatin structures. The discussion of important structural issues is set against a background of possible functional significance.

Chromatin elongation factors

As RNA polymerase II leaves a gene promoter to transcribe the coding region, it faces a major obstacle - nucleosomes tightly wrapped into chromatin. Mechanisms to deal with this obstacle clearly exist in cells, as transcription through chromatin is very efficient in vivo, whereas nucleosomal templates pose a considerable problem for polymerase progression in reconstituted in vitro systems. Advances in our understanding of transcriptional elongation through chromatin have been made possible recently by the identification of several accessory factors that assist polymerase in the process. Insights into the function of these factors have been gained by a combination of yeast genetics and biochemical studies in mammalian systems.

Quantification of DNaseI-sensitivity by real-time PCR: quantitative analysis of DNaseI-hypersensitivity of the mouse beta-globin LCR

We employ real-time PCR to allow us to quantify the sensitivity of chromatin to digestion by DNaseI. This approach has three clear advantages over the more conventional use of the Southern hybridization assay: the accuracy of quantification is improved; the resolution of the assay is enhanced, by designing primers to amplify small amplicons it is possible to analyze sequences both co-incident and proximal to sites of DNaseI-hypersensitivity; less material is needed, as little as 5 ng of treated genomic DNA. We applied this method in an analysis of the chromatin structure of the previously described mouse beta-globin locus control region (LCR) using fetal liver cells. The four hypersensitive sites of the canonical mouse LCR, HS1 to HS4, are shown to have kinetics of digestion consistent with these sequences being nucleosome-free in vivo. A different pattern was seen for HS6, a recently described "weak" hypersensitive site. The site was also rapidly lost but more of the sites proved resistant, we interpreted this to show that this hypersensitive was only forming in a portion of the erythroid cells. This finding implies that in vivo the LCR is structurally heterogeneous. Sequences proximal to the hypersensitive sites show a third pattern of intermediate sensitivity, consistent with the chromatin being unfolded but the sites still bound by a continual nucleosomal array. Our results demonstrate that this method has the potential to achieve accurate and detailed mapping of chromatin structure from small amounts of tissue samples.

An immuno-electron microscopical analysis of transcribing multinucleosomal templates: what happens to the histones?

Immuno-electron microscopy was used to visualize the structure of reconstituted chromatin after in vitro transcription by purified T7 RNA polymerase. T7 RNA polymerase disrupts the nucleosomal structure in the transcribed region. This disruption is not influenced by the template, linear or supercoiled, and the presence or absence of nucleosomal positioning sequences in the transcribed region. In this study, we used monoclonal autoantibodies reacting with the nucleosome core particles and epitopes within several regions of the four different core histones. Some of the residues recognized by the autoantibodies are accessible on the surface of the nucleosomes and some are more internal and therefore less exposed at the surface. We show that the loss of the nucleosomal configuration during transcription is due to the loss of histone/DNA binding and that at least part of the histones are transferred to the nascent RNA chains. Consequently, after in vitro transcription by T7 RNA polymerase, the nucleosomal template does not conserve its original configuration, and no interaction of antigen/antibodies is observed anymore in the region that has been transcribed. Therefore, we conclude that in our in vitro transcription assay, nucleosomes are detached from the template, and not simply unfolded with histones remaining attached to the DNA.

Growth regulation of human variant histone genes and acetylation of the encoded proteins

The family of human histone genes consists of replication-dependent and independent subtypes. The replication-independent histone genes, also known as variants, give rise to distinct mRNAs, whose expression is regulated depending on the growth state of the cell, tissue type and developmental stage. In turn, the histone variants are differentially synthesized and modified by acetylation. Consequently, chromatin structure is altered resulting in complex changes in gene expression. The high conservation among histone protein subtypes suggests that they are indispensable. In addition, conservation of the positions of acetylation within subtypes suggests that the location of these sites is functionally important for the eukaryotic cell. For example, the structures of transcriptionally active and repressed chromatin are different depending on the acetylation state of histone proteins [1-3]. In addition, transcriptionally active and repressed chromatin contains distinct histone variants [4]. Specialized histone variants are targeted to the centromere of the chromosome, where they are essential for chromosome segregation [5]. Other specialized histones exist that are essential for development [6]. Changes in histone acetylation have been implicated in the down-regulation of a tumour suppressor gene in human breast cancer [7]. Acetylation also plays an important role in X chromosome inactivation as well as hormone-mediated transcriptional regulation [8, 9]. We propose here a novel model for histone variant gene regulation at the post-transcriptional level, which provides the groundwork to define the pathways regulating the synthesis of these variants.

Purification and initial characterization of primate satellite chromatin

Nucleoprotein hybridization, a method for the purification of specific DNA sequences as chromatin, was employed to fractionate primate centromeric alpha satellite chromatin as a first step in the identification and analysis of novel centromere-enriched proteins. In order to optimize the amount of material available for further study, cultured African green monkey cells were employed because satellite DNA represents approximately 25% of the genome. Two chromatin preparations were compared for the yield and total protein content of purified material. Regardless of the preparation, alpha satellite sequences were enriched to near purity. Since intact satellite chromatin is relatively refractile to the enzymatic digestion steps in the method, the total amount of solubilized material available for purification is rather low. In contrast, nuclei treated with acidic washes to extract histone H1 provided solubilized material enriched in satellite sequences. In addition, this material is more efficiently utilized in an affinity chromatography step. However, the extraction of many non-histones at low pH resulted in very low yields of protein in the purified fraction. Two-dimensional gel comparisons of proteins associated with H1-containing satellite chromatin after iodination of total chromatin proteins revealed a number of polypeptides enriched to varying degrees in the purified fraction. The electrophoretic mobilities of a few enriched polypeptides corresponded to previously identified heterochromatin-associated proteins while many others appear to be novel. The work presented validates nucleoprotein hybridization as a purification method for highly repeated sequences as chromatin in analytical amounts. The fact that a number of the enriched proteins are visible in stained gels of bulk chromatin proteins suggests that further biochemical analysis can be carried out on these polypeptides directly.

Influence of nucleosome structure on the three-dimensional folding of idealized minichromosomes

BACKGROUND

The closed circular, multinucleosome-bound DNA comprising a minichromosome provides one of the best known examples of chromatin organization beyond the wrapping of the double helix around the core of histone proteins. This higher level of chain folding is governed by the topology of the constituent nucleosomes and the spatial disposition of the intervening protein-free DNA linkers.

RESULTS

By simplifying the protein-DNA assembly to an alternating sequence of virtual bonds, the organization of a string of nucleosomes on the minichromosome can be treated by analogy to conventional chemical depictions of macromolecular folding in terms of the bond lengths, valence angles, and torsions of the chain. If the nucleosomes are evenly spaced and the linkers are sufficiently short, regular minichromosome structures can be identified from analytical expressions that relate the lengths and angles formed by the virtual bonds spanning the nucleosome-linker repeating units to the pitch and radius of the organized quaternary structures that they produce.

CONCLUSIONS

The resulting models with 4-24 bound nucleosomes illustrate how a minichromosome can adopt the low-writhe folding motifs deduced from biochemical studies, and account for published images of the 30 nm chromatin fiber and the simian virus 40 (SV40) nucleohistone core. The marked sensitivity of global folding to the degree of protein-DNA interactions and the assumed nucleosomal shape suggest potential mechanisms for chromosome rearrangements upon histone modification.

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.

Isolation of differentially expressed genes by cloning transcriptionally active DNA fragments

During studies of erythroid cell growth and differentiation induced by erythropoietin (Epo), we developed a method that allows the identification and isolation of genes based upon their transcriptional activity. Transcriptionally active genomic DNA fragments from Epo-treated cells and control cells are purified from inactive chromatin using mercury affinity chromatography, based on the mechanism that the thiol groups of histone H3 on transcriptionally active chromatin are exposed to the solvent and therefore are easily accessible. Using the purified genomic DNA fragments from the two populations of cells, a subtractive hybridization strategy is used to isolate and clone genes that are differentially expressed in the absence or in the presence of Epo.

Chromatin disruption and modification

Chromatin disruption and modification are associated with transcriptional regulation by diverse coactivators and corepressors. Here we discuss the possible structural basis and functional consequences of the observed alterations in chromatin associated with transcriptional activation and repression. Recent advances in defining the roles of individual histones and their domains in the assembly and maintenance of regulatory architectures provide a framework for understanding how chromatin remodelling machines, histone acetyltransferases and deacetylases function.

Alteration of nucleosome structure as a mechanism of transcriptional regulation

The nucleosome, which is the primary building block of chromatin, is not a static structure: It can adopt alternative conformations. Changes in solution conditions or changes in histone acetylation state cause nucleosomes and nucleosomal arrays to behave with altered biophysical properties. Distinct subpopulations of nucleosomes isolated from cells have chromatographic properties and nuclease sensitivity different from those of bulk nucleosomes. Recently, proteins that were initially identified as necessary for transcriptional regulation have been shown to alter nucleosomal structure. These proteins are found in three types of multiprotein complexes that can acetylate nucleosomes, deacetylate nucleosomes, or alter nucleosome structure in an ATP-dependent manner. The direct modification of nucleosome structure by these complexes is likely to play a central role in appropriate regulation of eukaryotic genes.

Regulation of c-fos expression by RNA polymerase elongation competence

The molecular mechanisms underlying transcription elongation and their role in gene regulation are poorly characterized in eukaryotes. A number of genes, however, have been proposed to be regulated at the level of transcription elongation, including c-myc, c-fos and c-myb. Here, we analyze the control of transcription elongation at the mouse c-fos gene at the nucleotide level in intact cells. We find that RNA polymerases are engaged in the promoter-proximal part of the gene in the absence of gene activation signals and mRNA synthesis. Importantly, we determine that the engaged RNA polymerases originate from a continuous initiation of transcription which, in the absence of gene activation signals, terminate close to the promoter. We also observe that the c-fos gene presents an active chromatin conformation, with the promoter and upstream regulatory sequences constitutively occupied by proteins, accounting for the continuous initiation of RNA polymerase complexes. We propose that activation of c-fos gene expression results primarily from the assembly of elongation-competent RNA polymerases that can transcribe the complete gene. Our results suggest that the engaged RNA polymerases found downstream of a number of other eukaryotic promoters may be associated with transcription termination of elongation-incompetent polymerases in the absence of activating signals.

ERE environment- and cell type-specific transcriptional effects of estrogen in normal endometrial cells

Our previous results have suggested a repression of E2 (17beta-estradiol) effect on the c-fos gene of cultured guinea-pig endometrial cells. To investigate this repression, the expression of three human c-fos gene recombinants, pFC1-BL (-2250/+41), pFC2-BL (-1400/+41) and pFC2E (-1300/-1050 and -230/+41), known to be E2-responsive in Hela cells, was studied in stromal (SC) and glandular epithelial cells (GEC). In both cellular types, pFC1-BL was not induced by E2, even in the presence of growth factors or co-transfected estrogen receptor. The pattern of pFC2-BL and pFC2E expression was strikingly different and depended on the cellular type: pFC2-BL and pFC2E induction was restricted to the glandular epithelial cells and did not occur in the SCs. We argue for a repression of E2 action which is dependent on the estrogen-responsive cis-acting element (ERE) environment and also cell type-specific involving DNA/protein and/or protein/protein interactions with cellular type-specific factors.

Activation of SRF-regulated chromosomal templates by Rho-family GTPases requires a signal that also induces H4 hyperacetylation

Constitutively active forms of the small GTPases RhoA (RhoA.V14) and Cdc42 (Cdc42.V12) induce expression of extrachromosomal SRF reporter genes in microinjection experiments, but only Cdc42.V12 can efficiently activate a chromosomal template. Both SAPK/JNK-dependent or -independent signals can cooperate with RhoA.V14 to activate chromosomal SRF reporters, and it is SAPK/JNK activation by Cdc42.V12 that allows it to activate chromosomal templates. Cooperating signals can be bypassed by deacetylase inhibitors. Three findings show that histone H4 hyperacetylation is one target for cooperating signals, although it alone is not sufficient: (1) Cdc42.V12, but not RhoA.V14, induces H4 hyperacetylation; (2) cooperating signals use the same SAPK/JNK-dependent or -independent pathways to induce H4 hyperacetylation; (3) growth factor and stress stimuli induce substantial H4 hyperacetylation, detectable in reporter gene chromatin. These data establish a link between signal-regulated acetylation events and gene transcription.

High resolution microanalysis and three-dimensional nucleosome structure associated with transcribing chromatin

The nucleosome is the ubiquitous and fundamental DNA-protein complex of the eukaryotic chromosome, participating in the packaging of DNA and in the regulation of gene expression. Biophysical studies have implicated changes in nucleosome structure from chromatin that is quiescent to active in transcription. Since DNA within the nucleosome contains a high concentration of phosphorus whereas histone proteins do not, the nucleosome structure is amenable to microanalytical electron energy loss mapping of phosphorus to delineate the DNA within the protein-nucleic acid particle. Nucleosomes associated with transcriptionally active genes were separated from nucleosomes associated with quiescent genes using mercury-affinity chromatography. The three-dimensional image reconstruction methods for the total nucleosome structure and for the 3D DNA-phosphorus distribution combined quaternion-assisted angular reconstitution of sets of single particles at random orientations and electron spectroscopic imaging. The structure of the active nucleosome has the conformation of an open clam-shell, C- or U-shaped in one view, elongated in another, and exhibits a protein asymmetry. A three-dimensional phosphorus map reveals a conformational change in nucleosomal DNA compared to DNA in the canonical nucleosome structure. It indicates an altered superhelicity and is consistent with unfolding of the particle. The results address conformational changes of the nucleosome and provide a direct structural linkage to biochemical and physiological changes which parallel gene expression.

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.

Histone acetylation: influence on transcription, nucleosome mobility and positioning, and linker histone-dependent transcriptional repression

We demonstrate using a dinucleosome template that acetylation of the core histones enhances transcription by RNA polymerase III. This effect is not dependent on an increased mobility of the core histone octamer with respect to DNA sequence. When linker histone is subsequently bound, we find both a reduction in nucleosome mobility and a repression of transcription. These effects of linker histone binding are independent of core histone acetylation, indicating that core histone acetylation does not prevent linker histone binding and the concomitant transcriptional repression. These studies are complemented by the use of a Xenopus egg extract competent both for chromatin assembly on replicating DNA and for RNA polymerase III transcription. Incorporation of acetylated histones and lack of linker histones together facilitate transcription by >10-fold in this system; however, they have little independent effect on transcription. Thus core histone acetylation significantly facilitates transcription, but this effect is inhibited by the assembly of linker histones into chromatin.

Invasion of the CAG triplet repeats by a complementary peptide nucleic acid inhibits transcription of the androgen receptor and TATA-binding protein genes and correlates with refolding of an active nucleosome containing a unique AR gene sequence

The DNA sequence of the genes for the androgen receptor (AR) and TATA-binding protein (TBP), like many other genes encoding transcription factors, contains a series of tandem CAG repeats. Here we explore the capacity of complementary peptide nucleic acids (PNAs) to invade the CAG triplets of the AR and TBP genes in human prostatic cancer cells and show that the PNAs readily entered the nuclei of lysolecithin-permeabilized cells and effectively inhibited sense transcription of unique AR and TBP DNA sequences downstream of the site of PNA.DNA hybridization, but not upstream of that site. These PNAs had little or no effect on transcription of the c-myc gene, which lacks a CAG triplet domain. Conversely, a PNA complementary to a unique sequence of the c-myc gene did not inhibit transcription of the AR or TBP genes but did inhibit c-myc transcription. Comparisons of PNA effects on sense and antisense transcription of the AR, TBP, and c-myc genes confirm that progression of the RNA polymerase complex beyond the site of PNA.DNA hybridization is impaired in both directions. Suppression of the AR gene results in refolding of a transcriptionally active nucleosome containing a unique 17-mer AR DNA sequence.

Transcription factor-mediated chromatin remodelling: mechanisms and models

The association of DNA with nucleosomes in chromatin severely restricts the access of the regulatory factors that bring about transcription. In vivo active promoters are characterised by altered, almost transparent chromatin structures that allow the interaction of the transcriptional machinery. Recently, enzymatic activities have been discovered that facilitate the binding of transcription factors to chromatin by modifying nucleosomal structures in a process that requires energy. The mechanisms by which chromatin is remodelled may involve nucleosome movements, their transient unfolding, their partial or even complete disassembly. The dynamic properties of chromatin that underlie these structural changes are fundamental to the process of regulated gene expression.

Isolation of active genes containing CAG repeats by DNA strand invasion by a peptide nucleic acid

An amplification of tandem CAG trinucleotide sequences in DNA due to errors in DNA replication is involved in at least four hereditary neurodegenerative diseases. The CAG triplet repeats when translated into protein give rise to tracts of glutamine residues, which are a prominent feature of many transcription factors, including the TATA-binding protein of transcription factor TFIID. We have used a biotin-labeled, complementary peptide nucleic acid (PNA) to invade the CAG repeats in intact chromatin and then employed a method for the selective isolation of transcriptionally active chromatin restriction fragments containing the PNA.DNA hybrids. The PNA-containing chromatin fragments were captured on streptavidin-agarose magnetic beads and shown to contain all the CAG.PNA hybrids of the active chromatin fraction. DNA hybridization experiments using a DNA probe specific for unique sequences downstream of the CAG-tandem repeats confirmed that the PNA.DNA hybrids contained the transcribed gene for the TATA-binding protein. In contrast, no hybridization signal was detected with a DNA probe specific for the c-myc protooncogene, which is amplified and transcriptionally active in COLO 320DM cells but lacks CAG tandem repeats.

Studies on the isolated transcriptionally active and inactive chromatin fractions from rat liver nuclei

Using mild sonication, nucleoplasmic, nucleolar, and subnucleolar P-3 and S-3 chromatin fractions are isolated from rat liver nuclei. These fractions differ widely (over 80-fold) from each other in transcriptional activity as measured by the chromatin bound engaged RNA polymerases. Chemical analyses indicate that the active chromatin, e.g. P-3 and nucleolar fractions, are rich in RNA and protein as compared to the inactive chromatin, e.g. nucleoplasmic, and S-3 fractions. However, the DNA base content are all the same, showing 40% GC and 60% AT, including P-3 which is enriched in rDNA. Polyacrylamide gel electrophoresis of the 0.25 N HCl extracted proteins shows that all five histones are present in active chromatin. Additionally, the gel reveals two protein bands, one ahead of histone H2B and another ahead of histone H4, that are diminished or missing from the inactive chromatin. On the other hand, there is a fast moving protein band ahead of H4 in the inactive chromatin that is almost absent in the active chromatin. Transcriptional tests using E. coli RNA polymerase and several synthetic DNA templates of known base content and sequence indicate that the 0.25 N HCl soluble protein extracts from active chromatin contain activator proteins which are capable of countering the histone suppressors present in the extracts in a DNA base and sequence specific manner. The data show that although the histone suppressors are able to strongly inhibit the template function of poly[d(A-T)], the protein activators are able to overcome the suppressor activity and stimulate RNA synthesis several-fold when poly(dA).poly(dT) or poly(dT) is used.

Cell transformation by c-Ha-rasVal12 oncogene is accompanied by a decrease in histone H1 zero and an increase in nucleosomal repeat length

The activated c-Ha-rasVal12 oncogene is often involved in the genesis of human malignancies. We show here that in c-Ha-rasVal12 oncogene-transformed mouse NIH 3T3 fibroblasts the copy number and expression level of the mutant ras oncogene correlates with the degree of chromatin decondensation, as assessed by micrococcal nuclease (MNase) and DNase I digestion. MNase and DNase I analyses further revealed that the nucleosomal repeat lengths were different in the normal and ras oncogene-transformed cells, 162.3 bp and 178.1 bp, respectively. These chromatin changes were accompanied by alterations in the content of histone H1 zero. Furthermore, using DNase I as a probe, we discovered that serum stimulation of normal and transformed cells, synchronized by serum starvation, induces rapid reversible changes in the structure of bulk chromatin that may be linked to transcriptional activation. Our data thus indicate that cell transformation by ras is associated with specific changes in chromatin structure that make it more vulnerable, and prone to additional mutations characteristic of cancer development in vivo.

Methylation status and chromatin structure of an early response gene (ornithine decarboxylase) in resting and stimulated NIH-3T3 fibroblasts

The early response gene ornithine decarboxylase (odc) is indispensable for normal and malignant cell growth. Although DNA methylation is generally associated with chromatin condensation and gene inactivation, the odc gene is heavily methylated at CCGG-sequences in animal cell lines. In this work we analyzed the chromatin structure and the DNA methylation status at the CpG-rich promoter sequences at the odc locus in mouse 3T3 fibroblasts. We show that the proximal promoter region of the odc locus is not hypermethylated, while the distal promoter sequences appear to have a few methylated CCGG-sites and display methylation polymorphism. Furthermore, it was found that the 5' promoter region of odc is constitutively more sensitive to micrococcal nuclease than the coding and 3' regions of the odc gene. Stimulation of the cells with serum resulted in an appearance of a DNase I sensitive site at the promoter region. The chromatin structure of the mid-coding and 3' regions of the odc gene also underwent structural changes that were accompanied by the rapid accumulation of odc mRNA. Such changes were not detected in the chromatin structure of glyceraldehyde-3-phosphate dehydrogenase (gadph) gene, whose expression remains invariant upon serum stimulation. These data suggest that the chromatin structure may play an important role in the rapid transcriptional activation of odc and other immediate early genes during serum stimulation.

Dynamics of the interactions of histones H2A,H2B and H3,H4 with torsionally stressed DNA

The interactions of histones H2A,H2B and H3,H4 with closed circular DNA maintained in either a positively or negatively coiled state have been studied. The interactions were assayed by measuring the rate at which negative stress was stored in the DNA by the histones and by the salt concentration sufficient to cause dissociation on sucrose gradients. Additional experiments were performed in which DNAs of substantially different molecular weights and opposite topological states were mixed with the histones in order to study histone mobility under varied conditions. This mobility was characterized by separating the complexes on sucrose gradients and by analyzing the DNA's topological state after topoisomerase I treatment. Histones H3,H4 were found to differ substantially from histones H2A,H2B with regard to the DNA topology with which they prefer to interact. The results are consistent with a model in which transcription-induced positive stress in advance of the RNA polymerase unfolds the nucleosome to facilitate the release of H2A,H2B. The data are also consistent with a model in which histones H3,H4 remain associated with the DNA during polymerase passage and serve as a nucleation site for the reassociation of H2A,H2B. The rapid production of transcription-induced negative stress in the wake of a polymerase would have substantial importance in facilitating the reassociation of histones H2A,H2B.

A role for histones H2A/H2B in chromatin folding and transcriptional repression

Histone octamers or histone H3/H4 tetramers were reconstituted onto either closed circular plasmids containing a single Xenopus 5S rRNA gene or a reiterated array of Lytechinus 5S rRNA genes. All "reconstitutes" were found to undergo both Na(+)-dependent and Mg(2+)-dependent compaction. However, in each case, the compaction of nucleosomal templates containing H2A/H2B was much more extensive than compaction of templates containing only H3/H4 tetramers. Inclusion of 5 mM MgCl2 in the transcription buffer increased the level of compaction of nucleosomal templates and led to a marked inhibition of both transcription initiation and elongation by RNA polymerase III. The inhibitory effect of Mg2+ was reduced significantly when DNA templates contained only H3/H4 tetramers, consistent with their lesser extent of Mg(2+)-dependent compaction. Thus, the removal of histones H2A/H2B from nucleosomal arrays enhances gene activity, in part because of decreased levels of chromatin folding.

Effects of histone acetylation, ubiquitination and variants on nucleosome stability

The properties of the nucleosomes of a salt-soluble, transcriptionally active gene-enriched fraction of chicken erythrocyte chromatin were evaluated by hydroxyapatite dissociation chromatography. We have demonstrated previously that the salt-soluble, transcriptionally active gene-enriched polynucleosomes are enriched in dynamically acetylated and ubiquitinated histones, and in an atypical U-shaped nucleosome that possessed about 20% less protein than a typical nucleosome. Further, newly synthesized histones H2A and H2B exchange preferentially with the nucleosomal histones H2A and H2B of this salt-soluble chromatin fraction. Analysis of the histones eluting from the hydroxyapatite-bound chromatin demonstrated that hyperacetylated and ubiquitinated (u), including multi-ubiquitinated, H2A-H2B.1 dimers dissociated at lower concentrations of NaCl than unmodified dimers or dimers with histone variants H2A.Z and/or H2B.2. Cross-linking studies revealed that at least 50% of uH2B.1 was paired with uH2A. uH2A-uH2B.1 dimers dissociated at lower NaCl concentrations than H2A-uH2B.1 dimers. Hyperacetylated histone (H3-H4)2 tetramers also eluted at lower concentrations of NaCl than unmodified tetramers. Our results support the idea that acetylation and ubiquitination of histones H2A and H2B.1 increase the lability of H2A-H2B.1 dimers in transcriptionally active nucleosomes. In contrast, our observations suggest that histone variants H2A.Z and H2B.2. stabilize the association of the H2A-H2B dimer in nucleosomes. The elevated lability of the H2A-H2B dimer may facilitate processes such as the exchange of these dimers with newly synthesized histones, the elongation process of transcription and transcription factor binding.

Flexibility of DNA within transcriptionally active nucleosomes: analysis by circular dichroism measurements

The conformational flexibility of DNA in transcriptionally active chromatin fractions has been estimated by circular dichroism spectroscopy analysis and was found to be restricted in the same fashion as in bulk chromatin. The observation is discussed in the context of different models of active chromatin organization.

A positive role for histone acetylation in transcription factor access to nucleosomal DNA

Acetylation of the N-terminal tails of the core histones directly facilitates the recognition by TFIIIA of the 5S RNA gene within model chromatin templates. This effect is independent of a reduction in the extent of histone-DNA interactions or a change in DNA helical repeat; it is also independent of whether a histone tetramer or octamer inhibits TFIIIA binding. Removal of the N-terminal tails from the core histones also facilitates the association of TFIIIA with nucleosomal templates. We suggest that the histone tails have a major role in restricting transcription factor access to DNA and that their acetylation releases this restriction by directing dissociation of the tails from DNA and/or inducing a change in DNA configuration on the histone core to allow transcription factor binding. Acetylation of core histones might be expected to exert a major influence on the accessibility of chromatin to regulatory molecules.

Role of individual histone tyrosines in the formation of the nucleosome complex

We have determined the accessibility of histone tyrosine residues to react with p-nitrobenzenesulfonyl fluoride (NBSF) in intact nuclei, salt-dissociated nucleosomes, isolated histone complexes, and individual core histones. Of the 15 core histone tyrosine residues, 13 are inaccessible in native nucleosomes; only Tyr121 near the C-terminus of H2B is fully accessible, and Tyr54 of H3 is partially accessible under near-physiological conditions. When H1 and the basic N-terminal tails of the core histones are dissociated from the DNA by treating nuclei with 0.4 and 0.8 M NaCl, the two tyrosines which are adjacent to the basic regions of H2B and H3 become accessible as well. This indicates that these tyrosine residues may be involved in histone-DNA interactions, either directly or indirectly. When the H2A-H2B dimers are dissociated from the chromatin by raising the NaCl concentration to 1.2 M, three to four tyrosines located in the structured regions of H2B and H4 are exposed, suggesting that these tyrosine residues may be located at the dimer-tetramer interface. Dissociating all the histones from the DNA at an even higher ionic strength as a mixture of dimers, tetramers, and octamers does not change the pattern of Tyr exposure, but reduces the reactivity of the tyrosines at the dimer-tetramer interface as would be expected from the reassociation of H2A-H2B dimers and H3-H4 tetramers.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of chromatin folding on transcription initiation and elongation by RNA polymerase III

Nucleosomes were assembled onto either closed circular plasmids containing a single Xenopus 5S RNA gene or a linear tandemly repeated array of Lytechinus 5S RNA genes. Both chromatin templates were found to vary in their extent of compaction, depending upon the type and concentration of cation in solution. Compaction of these chromatin templates led to a significant inhibition of both transcription initiation and elongation by RNA polymerase III. Thus, the transcriptional repression observed after incorporation of genes into chromatin depends not only on occlusion of the promoter elements through direct contact with histones but also on compaction of nucleosomal arrays which occurs under the conditions of the transcription reactions.

Ellipticine increases the superhelical density of intracellular SV40 DNA by intercalation

We investigated the in vivo effect of ellipticine, a mammalian topoisomeraseII(topoII) inhibitor, on SV40 DNA topology. In contrast to epipodophyllotoxins, ellipticine did not cause significant double stranded cleavage of intracellular SV40 DNA. Furthermore, ellipticine reduced cleavage induced by epipodophyllotoxins, VP16 and VM26. Unexpectedly, ellipticine dramatically increased the superhelical density of a fraction of intracellular SV40 DNA. Several lines of evidence suggest that the formation of this highly supercoiled DNA species (Ih form DNA) is not due to the inhibition of topoII per se, but is the result of intercalation by ellipticine in a subfraction of the intracellular SV40 chromatin followed by the fixation of DNA linking number by a topoisomerase activity. Based on the linking number change and the known unwinding angle of ellipticine, the intercalation density was calculated as one ellipticine molecule per 10-20 bp in the Ih DNA. This result suggests the existence of different populations of intracellular SV40 chromatin with respect to the accessibility to ellipticine intercalation.

The Ku complex is modulated in response to viral infection and other cellular changes

The complex of Ku with DNA is demonstrated to have multiple forms as assayed by gel retardation analysis. In CV1 cells this variation of complex can be modulated in response to viral infection with SV40. By Western blot analysis, a correlation can be made between modification of the complex formed on DNA in response to viral infection with variation of the 85 kDa subunit of Ku. Modification of the 85 kDa subunit can also be seen when cells are exposed to various extracellular stimuli including variation in serum levels, PMA and CaPO4.

Half-lives of different sized mRNAs for the PKA subunit RI alpha are regulated differently in response to inhibition of transcription and translation

The RI alpha mRNA level is induced 3-5 times by FSH or cAMP analogs in primary cultures of rat Sertoli cells. In rat tissues, the RI alpha gene gives rise to three different mRNAs of different size: 3.2, 2.9 and 1.7 kb. In the present study we report that the 1.7 kb transcript has a shorter half-life than the two other mRNAs. In cells which had been pre-stimulated with a cAMP analog, inhibition of transcription stabilizes the two larger, but not the smaller sized RI alpha mRNA. However, in contrast, inhibition of protein synthesis stabilizes all the RI alpha mRNAs. Thus, degradation of various mRNAs coding for the same protein reveals different dependencies on transcription and translation.

Inhibitors of RNA and protein synthesis stabilize messenger RNA for the RII beta subunit of protein kinase A in different cellular compartments

Messenger RNA for RII beta is transiently induced (greater than 50-fold) by cAMP analogs in primary cultures of rat Sertoli cells. The induction is dependent on protein synthesis. We have previously shown that mRNA for RII beta is stabilized by cAMP, as well as inhibitors of transcription and translation. This indicated that rapid degradation of RII beta mRNA involved a protein with a rapid turnover and its corresponding mRNA. The two RNA synthesis inhibitors used in the present study stabilized both nuclear and cytoplasmic RII beta mRNA, whereas inhibition of protein synthesis stabilized RII beta mRNA in the cytoplasm only. These results indicate that only cytoplasmic degradation of RII beta mRNA is dependent on a protein with high turnover. In contrast, nuclear degradation appears to be dependent on an RNA with a short half-life, not involving protein synthesis.

HMG proteins 14 and 17 become cross-linked to the globular domain of histone H3 near the nucleosome core particle dyad

HMG proteins were derivatized with the photoactivatable cross-linker N-succinimidyl 3-((4-azidophenyl)dithio)propionate and then allowed to associate with nucleosome core particles. Following photolysis, peptide mapping of the principal dimeric adducts was carried out. Cross-linking occurred primarily from a central location in the HMGs to a central location in H3. The positions of these cross-links, considered along with other data from the literature, show that HMG proteins 14 and 17 make important contacts to H3 near the front face of the nucleosome. This raises the possibility that HMGs 14 and 17 participate in the reported conformational transition which exposes the H3 sulfhydryls of active nucleosomes.

Transcribed chromatin

In eukaryotes, DNA that is transcribed is packaged first into nucleosomes and then into chromatin fibres. How does transcription proceed through chromatin? Studies of transcription through nucleosomes in vitro suggest that the intracellular environment may provide factors which alleviate the inhibitory effect that nucleosomes have on transcription, possibly via positive supercoiling induced by the migrating polymerase. Stable changes in nucleosome structure have been correlated with transcriptionally active chromatin, but the precise mechanism by which RNA polymerase transcribes through nucleosomal DNA remains unknown.