Treatment with sodium butyrate inhibits the complete condensation of interphase chromatin

Live-cell three-dimensional single-molecule tracking reveals modulation of enhancer dynamics by NuRD

To understand how the nucleosome remodeling and deacetylase (NuRD) complex regulates enhancers and enhancer-promoter interactions, we have developed an approach to segment and extract key biophysical parameters from live-cell three-dimensional single-molecule trajectories. Unexpectedly, this has revealed that NuRD binds to chromatin for minutes, decompacts chromatin structure and increases enhancer dynamics. We also uncovered a rare fast-diffusing state of enhancers and found that NuRD restricts the time spent in this state. Hi-C and Cut&Run experiments revealed that NuRD modulates enhancer-promoter interactions in active chromatin, allowing them to contact each other over longer distances. Furthermore, NuRD leads to a marked redistribution of CTCF and, in particular, cohesin. We propose that NuRD promotes a decondensed chromatin environment, where enhancers and promoters can contact each other over longer distances, and where the resetting of enhancer-promoter interactions brought about by the fast decondensed chromatin motions is reduced, leading to more stable, long-lived enhancer-promoter relationships.

Epigenetic regulation of nuclear lamina-associated heterochromatin by HAT1 and the acetylation of newly synthesized histones

A central component of the epigenome is the pattern of histone post-translational modifications that play a critical role in the formation of specific chromatin states. Following DNA replication, nascent chromatin is a 1:1 mixture of parental and newly synthesized histones and the transfer of modification patterns from parental histones to new histones is a fundamental step in epigenetic inheritance. Here we report that loss of HAT1, which acetylates lysines 5 and 12 of newly synthesized histone H4 during replication-coupled chromatin assembly, results in the loss of accessibility of large domains of heterochromatin, termed HAT1-dependent Accessibility Domains (HADs). HADs are mega base-scale domains that comprise ∼10% of the mouse genome. HAT1 globally represses H3 K9 me3 levels and HADs correspond to the regions of the genome that display HAT1-dependent increases in H3 K9me3 peak density. HADs display a high degree of overlap with a subset of Lamin-Associated Domains (LADs). HAT1 is required to maintain nuclear structure and integrity. These results indicate that HAT1 and the acetylation of newly synthesized histones may be critical regulators of the epigenetic inheritance of heterochromatin and suggest a new mechanism for the epigenetic regulation of nuclear lamina-heterochromatin interactions.

Interactions With Histone H3 & Tools to Study Them

Histones are an integral part of chromatin and thereby influence its structure, dynamics, and functions. The effects of histone variants, posttranslational modifications, and binding proteins is therefore of great interest. From the moment that they are deposited on chromatin, nucleosomal histones undergo dynamic changes in function of the cell cycle, and as DNA is transcribed and replicated. In the process, histones are not only modified and bound by various proteins, but also shuffled, evicted, or replaced. Technologies and tools to study such dynamic events continue to evolve and better our understanding of chromatin and of histone proteins proper. Here, we provide an overview of H3.1 and H3.3 histone dynamics throughout the cell cycle, while highlighting some of the tools used to study their protein–protein interactions. We specifically discuss how histones are chaperoned, modified, and bound by various proteins at different stages of the cell cycle. Established and select emerging technologies that furthered (or have a high potential of furthering) our understanding of the dynamic histone–protein interactions are emphasized. This includes experimental tools to investigate spatiotemporal changes on chromatin, the role of histone chaperones, histone posttranslational modifications, and histone-binding effector proteins.

Sodium butyrate induces genotoxic stress in function of photoperiod variations and differentially modulates the expression of genes involved in chromatin modification and DNA repair in Petunia hybrida seedlings

Sodium butyrate applied to Petunia hybrida seeds under a long-day photoperiod has a negative impact (reduced seedling length, decreased production of photosynthetic pigments, and accumulation of DNA damage) on early seedling development, whereas its administration under dark/light conditions (complete dark conditions for 5 days followed by exposure to long-day photoperiod for 5 days) bypasses some of the adverse effects. Genotoxic stress impairs plant development. To circumvent DNA damage, plants activate DNA repair pathways in concert with chromatin dynamics. These are essential during seed germination and seedling establishment, and may be influenced by photoperiod variations. To assess this interplay, an experimental design was developed in Petunia hybrida, a relevant horticultural crop and model species. Seeds were treated with different doses of sodium butyrate (NaB, 1 mM and 5 mM) as a stress agent applied under different light/dark conditions throughout a time period of 10 days. Phenotypic (germination percentage and speed, seedling length, and photosynthetic pigments) and molecular (DNA damage and gene expression profiles) analyses were performed to monitor the response to the imposed conditions. Seed germination was not affected by the treatments. Seedling development was hampered by increasing NaB concentrations applied under a long-day photoperiod (L) as reflected by the decreased seedling length accompanied by increased DNA damage. When seedlings were grown under dark conditions for 5 days and then exposed to long-day photoperiod for the remaining 5 days (D/L), the damaging effects of NaB were circumvented. NaB exposure under L conditions resulted in enhanced expression of HAT/HDAC (HISTONE ACETYLTRANSFERASES/HISTONE DEACTEYLASES) genes along with repression of genes involved in DNA repair. Differently, under D/L conditions, the expression of DNA repair genes was increased by NaB treatment and this was associated with lower levels of DNA damage. The observed DNA damage and gene expression profiles suggest the involvement of chromatin modification- and DNA repair-associated pathways in response to NaB and dark/light exposure during seedling development.

Histone epigenetic marks in heterochromatin and euchromatin of the Chagas' disease vector, Triatoma infestans

Triatoma infestans, a vector of Chagas' disease, shows several particular cell biology characteristics, including the presence of conspicuous heterochromatic bodies (chromocenters) where DNA methylation has not been previously detected. Whether histone modifications contribute to the condensed state of these bodies has not yet been studied. Here, we investigated epigenetic modifications of histones H3 and H4 and presence of the non-histone heterochromatin protein (HP1-α) in the chromocenters and euchromatin of T. infestans cell nuclei, using immunocytochemistry. The effect of different concentrations of the histone deacetylase inhibitors valproic acid (VPA) and sodium butyrate (NaBt) on chromocenter condensation was visually examined; in VPA-treated specimens, this effect was also analyzed by image analysis. Trimethylated H3K9 signals, which were revealed in chromocenter and non-chromocenter areas, were strongest in chromocenters, whereas selected acetylated histone marks and mono- and dimethylated H3K9 and H4K20 signals were detected only in euchromatin. Weak trimethylated H4K20 signals and variable distribution of HP1-α were detected in chromocenters of part of the cellular population analyzed. Although specific VPA and NaBt treatment conditions affected the heterochromatin condensation pattern, they did not induce a decrease in survival and molting rates of the T. infestans nymphs. The VPA-induced chromatin remodeling was not accompanied by induction of H3K9 acetylation in chromocenters. Present findings regarding histone modifications and effects following VPA or NaBt treatments did not yet solve the question of which factors are responsible for maintenance of the condensed state of chromocenters in T. infestans. A possibility requiring further investigation remains on histone methylation marks and/or non-histone proteins.

Assembling chromatin: the long and winding road

It has been over 35 years since the acceptance of the "chromatin subunit" hypothesis, and the recognition that nucleosomes are the fundamental repeating units of chromatin fibers. Major subjects of inquiry in the intervening years have included the steps involved in chromatin assembly, and the chaperones that escort histones to DNA. The following commentary offers an historical perspective on inquiries into the processes by which nucleosomes are assembled on replicating and nonreplicating chromatin. This article is part of a Special Issue entitled: Histone chaperones and Chromatin assembly.

Nano-scale analyses of the chromatin decompaction induced by histone acetylation

The acetylation of histone tails is a key factor in the maintenance of chromatin dynamics and cellular homeostasis. The hallmark of active chromatin is the hyper-acetylation of histones, which appears to result in a more open chromatin structure. Although short nucleosomal arrays have been studied, the structural dynamics of relatively long acetylated chromatin remain unclear. We have analyzed in detail the structure of long hyper-acetylated chromatin fibers using atomic force microscopy (AFM). Hyper-acetylated chromatin fibers isolated from nuclei that had been treated with Trichostatin A (TSA), an inhibitor of histone deacetylase, were found to be thinner than those from untreated nuclei. The acetylated chromatin fibers were more easily spread out of nuclei by high-salt treatment, implying that hyper-acetylation facilitates the release of chromatin fibers from compact heterochromatin regions. Chromatin fibers reconstituted in vitro from core histones and linker histone H1 became thinner upon acetylation. AFM imaging indicated that the gyration radius of the nucleosomal fiber increased after acetylation and that the hyper-acetylated nucleosomes did not aggregate at high salt concentrations, in contrast to the behavior of non-acetylated nucleosomal arrays, suggesting that acetylation increases long-range repulsions between nucleosomes. Based on these data, we considered a simple coarse grained model, which underlines the effect of remaining electric charges inside the chromatin fiber.

Core histone hyperacetylation impacts cooperative behavior and high-affinity binding of histone H1 to chromatin

Linker histones stabilize higher order chromatin structures and limit access to proteins involved in DNA-dependent processes. Core histone acetylation is thought to modulate H1 binding. In the current study, we employed kinetic modeling of H1 recovery curves obtained during fluorescence recovery after photobleaching (FRAP) experiments to determine the impact of core histone acetylation on the different variants of H1. Following brief treatments with histone deacetylase inhibitor, most variants showed no change in H1 dynamics. A change in mobility was detected only when longer treatments were used to induce high levels of histone acetylation. This hyperacetylation imparted marked changes in the dynamics of low-affinity H1 population, while conferring variant-specific changes in the mobility of H1 molecules that were strongly bound. Both the C-terminal domain (CTD) and globular domain were responsible for this differential response to TSA. Furthermore, we found that neither the CTD nor the globular domain, by themselves, undergoes a change in kinetics following hyperacetylation. This led us to conclude that hyperacetylation of core histones affects the cooperative nature of low-affinity H1 binding, with some variants undergoing a predicted decrease of almost 2 orders of magnitude.

Studying histone modifications and their genomic functions by employing chromatin immunoprecipitation and immunoblotting

Histones are one of the most abundant and highly conserved proteins in eukaryotes. Apart from serving as structural entities for orderly compaction of genomes, they play an instrumental role in the regulation of many important biological processes involving DNA such as transcription, DNA repair, and the cell cycle. Histone modifications have been implicated in maintaining the transcriptionally poised state of important genesin embryonic stem cells. Histone modifications are believed to be responsible for compartmentalization of chromatin into active and inactive domains. Hence, the tools and techniques required for studying these proteins are of utmost importance to biologists. This chapter provides a brief review of the posttranslational modifications of the N-terminal tails of histones and their biological roles, followed by step-by-step protocols for the most common techniques employed to study them. Here, we describe chromatin immunoprecipitation (ChIP) for studying the genomic functions of the most widely studied histone modifications, namely, histone H3 lysine 9 acetylation and histone H3 lysine 9 trimethylation that are typically associated with transcriptional activation and repression, respectively. Special emphasis has been given on the method of preparation of sonicated chromatin prior to immunoprecipitation since this single step affects the success of ChIP greatly and is often poorly described in published protocols. Protocol for histone isolation by acid-extraction and detection by Coomassie staining has also been described. We also describe the protocol for immunoblot analysis of histones using antibodies against key histone modifications. This chapter will serve as a useful resource in the study of histones and their posttranslational modifications.

The H4 tail domain participates in intra- and internucleosome interactions with protein and DNA during folding and oligomerization of nucleosome arrays

The condensation of nucleosome arrays into higher-order secondary and tertiary chromatin structures likely involves long-range internucleosomal interactions mediated by the core histone tail domains. We have characterized interarray interactions mediated by the H4 tail domain, known to play a predominant role in the formation of such structures. We find that the N-terminal end of the H4 tail mediates interarray contacts with DNA during self-association of oligonucleosome arrays similar to that found previously for the H3 tail domain. However, a site near the histone fold domain of H4 participates in a distinct set of interactions, contacting both DNA and H2A in condensed structures. Moreover, we also find that H4-H2A interactions occur via an intra- as well as an internucleosomal fashion, supporting an additional intranucleosomal function for the tail. Interestingly, acetylation of the H4 tail has little effect on interarray interactions by itself but overrides the strong stimulation of interarray interactions induced by linker histones. Our results indicate that the H4 tail facilitates secondary and tertiary chromatin structure formation via a complex array of potentially exclusive interactions that are distinct from those of the H3 tail domain.

Small molecules affecting transcription in Friedreich ataxia

This review concerns the development of small molecule therapeutics for the inherited neurodegenerative disease Friedreich ataxia (FRDA). FRDA is caused by transcriptional repression of the nuclear FXN gene, encoding the essential mitochondrial protein frataxin and accompanying loss of frataxin protein. Frataxin insufficiency leads to mitochrondrial dysfunction and progressive neurodegeneration, along with scoliosis, diabetes and cardiomyopathy. Individuals with FRDA generally die in early adulthood from the associated heart disease, the most common cause of death in FRDA. While antioxidants and iron chelators have shown promise in ameliorating the symptoms of the disease, there is no effective therapy for FRDA that addresses the cause of the disease, the loss of frataxin protein. Gene therapy and protein replacement strategies for FRDA are promising approaches; however, current technology is not sufficiently advanced to envisage treatments for FRDA coming from these approaches in the near future. Since the FXN mutation in FRDA, expanded GAA.TTC triplets in an intron, does not alter the amino acid sequence of frataxin protein, gene reactivation would be of therapeutic benefit. Thus, a number of laboratories have focused on small molecule activators of FXN gene expression as potential therapeutics, and this review summarizes the current status of these efforts, as well as the molecular basis for gene silencing in FRDA.

Functions of site-specific histone acetylation and deacetylation

Histone acetylation regulates many cellular processes, and specific acetylation marks, either singly or in combination, produce distinct outcomes. For example, the acetylation pattern on newly synthesized histones is important for their assembly into nucleosomes by histone chaperones. Additionally, the degree of chromatin compaction and folding may be regulated by acetylation of histone H4 at lysine 16. Histone acetylation also regulates the formation of heterochromatin; deacetylation of H4 lysine 16 is important for spreading of heterochromatin components, whereas acetylation of this site serves as a barrier to this spreading. Finally, histone acetylation is critical for gene transcription, but recent results suggest that deacetylation of certain sites also plays an important role. There are many histone acetyltransferases (HATs) and deacetylases, with differing preferences for the various histone proteins and for specific sites on individual histones. Determining how these enzymes create distinct acetylation patterns and regulate the functional outcome is an important challenge.

Class I histone deacetylase Thd1p promotes global chromatin condensation in Tetrahymena thermophila

Class I histone deacetylases (HDACs) regulate DNA-templated processes such as transcription. They act both at specific loci and more generally across global chromatin, contributing to acetylation patterns that may underlie large-scale chromatin dynamics. Although hypoacetylation is correlated with highly condensed chromatin, little is known about the contribution of individual HDACs to chromatin condensation mechanisms. Using the ciliated protozoan Tetrahymena thermophila, we investigated the role of a specific class I HDAC, Tauhd1p, in the reversible condensation of global chromatin. In this system, the normal physiological response to cell starvation includes the widespread condensation of the macronuclear chromatin and general repression of gene transcription. We show that the chromatin in Thd1p-deficient cells failed to condense during starvation. The condensation failure correlated with aberrant hyperphosphorylation of histone H1 and the overexpression of CDC2, encoding the major histone H1 kinase. Changes in the rate of acetate turnover on core histones and in the distribution of acetylated lysines 9 and 23/27 on histone H3 isoforms that were found to correlate with normal chromatin condensation were absent from Thd1p mutant cells. These results point to a role for a class I HDAC in the formation of reversible higher-order chromatin structures and global genome compaction through mechanisms involving the regulation of H1 phosphorylation and core histone acetylation/deacetylation kinetics.

The H3 tail domain participates in multiple interactions during folding and self-association of nucleosome arrays

The core histone tail domains play a central role in chromatin structure and epigenetic processes controlling gene expression. Although little is known regarding the molecular details of tail interactions, it is likely that they participate in both short-range and long-range interactions between nucleosomes. Previously, we demonstrated that the H3 tail domain participates in internucleosome interactions during MgCl(2)-dependent condensation of model nucleosome arrays. However, these studies did not distinguish whether these internucleosome interactions represented short-range intra-array or longer-range interarray interactions. To better understand the complex interactions of the H3 tail domain during chromatin condensation, we have developed a new site-directed cross-linking method to identify and quantify interarray interactions mediated by histone tail domains. Interarray cross-linking was undetectable under salt conditions that induced only local folding, but was detected concomitant with salt-dependent interarray oligomerization at higher MgCl(2) concentrations. Interestingly, lysine-to-glutamine mutations in the H3 tail domain to mimic acetylation resulted in little or no reduction in interarray cross-linking. In contrast, binding of a linker histone caused a much greater enhancement of interarray interactions for unmodified H3 tails compared to "acetylated" H3 tails. Collectively these results indicate that H3 tail domain performs multiple functions during chromatin condensation via distinct molecular interactions that can be differentially regulated by acetylation or binding of linker histones.

Histone deacetylase inhibitors reverse gene silencing in Friedreich's ataxia

Expansion of GAA x TTC triplets within an intron in FXN (the gene encoding frataxin) leads to transcription silencing, forming the molecular basis for the neurodegenerative disease Friedreich's ataxia. Gene silencing at expanded FXN alleles is accompanied by hypoacetylation of histones H3 and H4 and trimethylation of histone H3 at Lys9, observations that are consistent with a heterochromatin-mediated repression mechanism. We describe the synthesis and characterization of a class of histone deacetylase (HDAC) inhibitors that reverse FXN silencing in primary lymphocytes from individuals with Friedreich's ataxia. We show that these molecules directly affect the histones associated with FXN, increasing acetylation at particular lysine residues on histones H3 and H4 (H3K14, H4K5 and H4K12). This class of HDAC inhibitors may yield therapeutics for Friedreich's ataxia.

Histone dynamics during transcription: exchange of H2A/H2B dimers and H3/H4 tetramers during pol II elongation

Chromatin within eukaryotic cell nuclei accommodates many complex activities that require at least partial disassembly and reassembly of nucleosomes. This disassembly/reassembly is thought to be somewhat localized when associated with processes such as site-specific DNA repair but likely occurs over extended regions during processive processes such as DNA replication or transcription. Here we review data addressing the effect of transcription elongation on nucleosome disassembly/reassembly, specifically focusing on the issue of transcription-dependent exchange of H2A/H2B dimers and H3/H4 tetramers. We suggest a model whereby passage of a polymerase through a nucleosome induces displacement of H2A/H2B dimers with a much higher probability than displacement of H3/H4 tetramers such that the extent of tetramer replacement is relatively low and proportional to polymerase density on any particular gene.

Trichostatin A-induced histone acetylation causes decondensation of interphase chromatin

The effect of trichostatin A (TSA)-induced histone acetylation on the interphase chromatin structure was visualized in vivo with a HeLa cell line stably expressing histone H2A, which was fused to enhanced yellow fluorescent protein. The globally increased histone acetylation caused a reversible decondensation of dense chromatin regions and led to a more homogeneous distribution. These structural changes were quantified by image correlation spectroscopy and by spatially resolved scaling analysis. The image analysis revealed that a chromatin reorganization on a length scale from 200 nm to >1 microm was induced consistent with the opening of condensed chromatin domains containing several Mb of DNA. The observed conformation changes could be assigned to the folding of chromatin during G1 phase by characterizing the effect of TSA on cell cycle progression and developing a protocol that allowed the identification of G1 phase cells on microscope coverslips. An analysis by flow cytometry showed that the addition of TSA led to a significant arrest of cells in S phase and induced apoptosis. The concentration dependence of both processes was studied.

Chromatin organization in the mammalian nucleus

Mammalian cells package their DNA into chromatin and arrange it in the nucleus as chromosomes. In interphase cells chromosomes are organized in a radial distribution with the most gene-dense chromosomes toward the center of the nucleus. Gene transcription, replication, and repair are influenced by the underlying chromatin architecture, which in turn is affected by the formation of chromosome territories. This arrangement in the nucleus presumably facilitates cellular functions to occur in an efficient and ordered fashion and exploring the link between transcription and nuclear organization will be an exciting area of further research.

A porphobilinogen deaminase (PBGD) Ran-binding protein interaction is implicated in nuclear trafficking of PBGD in differentiating glioma cells

Porphobilinogen deaminase (PBGD) is a rate-limiting enzyme of the heme biosynthesis pathway, whose level is elevated in various human tumors. PBGD was observed in both nuclear and cytoplasmic fractions of C6 glioma cells by immunostaining. During mitosis, chromatids were intensely stained for PBGD in comparison to the interphase chromatin. Using the yeast two-hybrid system, we identified RanBPM, the nuclear Ran-binding protein, as an interacting partner of PBGD. During butyrate-induced differentiation of C6, both nuclear and cytoplasmic PBGD levels declined as did Ran protein and its nucleotide exchange factor RCC1. N,N'-hexamethylene bis-acetamide-dependent differentiation resulted in an increase of the cytoplasmic PBGD, whereas nuclear PBGD, Ran protein and RCC1 remained unchanged. mRNA levels of PBGD remained unchanged during stimulation with both butyrate and N,N'-hexamethylene bis-acetamide. The enzymatic activity of PBGD and protoporphyrin IX synthesis in C6 cells were dependent on the differentiation induction agent. We conclude that PBGD possibly has a nuclear role in addition to its cytosolic enzymatic activity required for heme synthesis, which is related to cell transformation and differentiation.

Chemoprevention of Tumors: The Role of RAR-Beta

Chemoprevention can be defined as the use of specific natural or synthetic chemical agents to reverse, suppress, or prevent carcinogenic progression to invasive cancer. The knowledge of carcinogenic mechanisms provides the scientific rationale for chemoprevention. Epithelial carcinogenesis proceeds through multiple discernible stages of molecular and cellular alterations. Understanding of the multistep nature of carcinogenesis has evolved through highly controlled animal carcinogenesis studies, and these studies have identified three distinct phases: initiation, promotion and progression. Animal model studies have provided evidence that the development of cancer involves many different factors, including alterations in the structures and functions of different genes. Transitions between successive stages can be enhanced or inhibited in the laboratory by different types of agents, such activities providing the fundamental basis for chemoprevention.

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.

Linker histone function in chromatin: Dual mechanisms of action

Aspects pertaining to linker histone structure and function are discussed, including the extent to which these proteins are essential, their ability to regulate specific gene expression, and recent structural data that provides a potential molecular basis for understanding how linker histones can have both repressive and stimulatory effects on genomic functions in vivo.Key words: chromatin, linker histone, higher-order folding.

The core histone N termini function independently of linker histones during chromatin condensation

The relationships between the core histone N termini and linker histones during chromatin assembly and salt-dependent chromatin condensation were investigated using defined chromatin model systems reconstituted from tandemly repeated 5 S rDNA, histone H5, and either native "intact" core histone octamers or "tailless" histone octamers lacking their N-terminal domains. Nuclease digestion and sedimentation studies indicate that H5 binding and the resulting constraint of entering and exiting nucleosomal DNA occur to the same extent in both tailless and intact chromatin arrays. However, despite possessing a normal chromatosomal structure, tailless chromatin arrays can neither condense into extensively folded structures nor cooperatively oligomerize in MgCl(2). Tailless nucleosomal arrays lacking linker histones also are unable to either fold extensively or oligomerize, demonstrating that the core histone N termini perform the same functions during salt-dependent condensation regardless of whether linker histones are components of the array. Our results further indicate that disruption of core histone N termini function in vitro allows a linker histone-containing chromatin fiber to exist in a decondensed state under conditions that normally would promote extensive fiber condensation. These findings have key implications for both the mechanism of chromatin condensation, and the regulation of genomic function by chromatin.

Review: chromatin structural features and targets that regulate transcription

The nucleosome and chromatin fiber provide the common structural framework for transcriptional control in eukaryotes. The folding of DNA within these structures can both promote and impede transcription dependent on structural context. Importantly, neither the nucleosome nor the chromatin fiber is a static structure. Histone dissociation, histone modification, nucleosome mobility, and assorted allosteric transitions contribute to transcriptional control. Chromatin remodeling is associated with gene activation and repression. Energy-dependent processes mediate the assembly of both activating and repressive proteins into the nucleosomal infrastructure. Recent progress allows the structural consequences of these processes to be visualized at the chromosomal level. DNA and RNA polymerase, SWI/SNF complexes, histone deacetylases, and acetyltransferases are targeted by gene-specific regulators to mediate these structural transitions. The mistargeting of these enzymes contributes to human developmental abnormalities and tumorigenesis. These observations illuminate the roles of chromatin and chromosomal structural biology in human disease.

Thyroid hormone receptor, v-ErbA, and chromatin

The thyroid hormone receptor and the highly related viral oncoprotein v-erbA are found exclusively in the nucleus as stable constituents of chromatin. Unlike most transcriptional regulators, the thyroid hormone receptor binds with comparable affinity to naked and nucleosomal DNA. In vitro reconstitution experiments and in vivo genomic footprinting have delineated the chromatin structural features that facilitate association with the receptor. Chromatin bound thyroid hormone receptor and v-erbA generate Dnase I hypersensitive sites independent of ligand. The unliganded thyroid hormone receptor and v-erbA associate with a corepressor complex containing NCoR, SIN3, and histone deacetylase. The enzymatic activity of the deacetylase and a chromatin environment are essential for the dominant repression of transcription by both the unliganded thyroid hormone receptor and v-erbA. In the presence of ligand, the thyroid hormone receptor undergoes a conformational change that weakens interactions with the corepressor complex while facilitating the recruitment of transcriptional coactivators such as p300 and PCAF possessing histone acetyltransferase activity. The ligand-bound thyroid hormone receptor directs chromatin disruption events in addition to histone acetylation. Thus, the thyroid hormone receptor and v-erbA make very effective use of their stable association with chromatin and their capacity to alter the chromatin environment as a major component of the transcription regulation process. This system provides an exceptionally useful paradigm for investigating the structural and functional consequences of targeted chromatin modification.

Role of histone acetylation in the assembly and modulation of chromatin structures

The acetylation of the core histone N-terminal "tail" domains is now recognized as a highly conserved mechanism for regulating chromatin functional states. The following article examines possible roles of acetylation in two critically important cellular processes: replication-coupled nucleosome assembly, and reversible transitions in chromatin higher order structure. After a description of the acetylation of newly synthesized histones, and of the likely acetyltransferases involved, an overview of histone octamer assembly is presented. Our current understanding of the factors thought to assemble chromatin in vivo is then described. Genetic and biochemical investigations of the function the histone tails, and their acetylation, in nucleosome assembly are detailed, followed by an analysis of the importance of histone deacetylation in the maturation of newly replicated chromatin. In the final section the involvement of the histone tail domains in chromatin higher order structures is addressed, along with the role of histone acetylation in chromatin folding. Suggestions for future research are offered in the concluding remarks.

Relationships between chromatin organization and DNA methylation in determining gene expression

Chromatin is the natural substrate for the control of gene expression. Chromatin contains DNA, the transcriptional machinery and structural proteins such as histones. Recent advances demonstrate that transcriptional activity of a gene is largely controlled by the packaging of the template within chromatin. The covalent modification of chromatin provides an attractive mechanism for establishing and maintaining stable states of gene activity. DNA methylation and histone acetylation alter the nucleosomal infrastructure to repress or activate transcription. These covalent modifications have causal roles in both promoter-specific events and the global control of chromosomal activity. DNA methylation and histone acetylation have a major impact in both oncogenic transformation and normal development.

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.

Disruption of higher-order folding by core histone acetylation dramatically enhances transcription of nucleosomal arrays by RNA polymerase III

We have examined the effects of core histone acetylation on the transcriptional activity and higher-order folding of defined 12-mer nucleosomal arrays. Purified HeLa core histone octamers containing an average of 2, 6, or 12 acetates per octamer (8, 23, or 46% maximal site occupancy, respectively) were assembled onto a DNA template consisting of 12 tandem repeats of a 208-bp Lytechinus 5S rRNA gene fragment. Reconstituted nucleosomal arrays were transcribed in a Xenopus oocyte nuclear extract and analyzed by analytical hydrodynamic and electrophoretic approaches to determine the extent of array compaction. Results indicated that in buffer containing 5 mM free Mg2+ and 50 mM KCl, high levels of acetylation (12 acetates/octamer) completely inhibited higher-order folding and concurrently led to a 15-fold enhancement of transcription by RNA polymerase III. The molecular mechanisms underlying the acetylation effects on chromatin condensation were investigated by analyzing the ability of differentially acetylated nucleosomal arrays to fold and oligomerize. In MgCl2-containing buffer the folding of 12-mer nucleosomal arrays containing an average of two or six acetates per histone octamer was indistinguishable, while a level of 12 acetates per octamer completely disrupted the ability of nucleosomal arrays to form higher-order folded structures at all ionic conditions tested. In contrast, there was a linear relationship between the extent of histone octamer acetylation and the extent of disruption of Mg2+-dependent oligomerization. These results have yielded new insight into the molecular basis of acetylation effects on both transcription and higher-order compaction of nucleosomal arrays.

Agonistic properties of alniditan, sumatriptan and dihydroergotamine on human 5-HT1B and 5-HT1D receptors expressed in various mammalian cell lines

1. Alniditan, a novel migraine abortive agent, is a potent 5-HT1B/5-HT1D receptor agonist of nM affinity. We compared the agonistic properties of alniditan, sumatriptan and dihydroergotamine on the cloned human 5-HT1B receptor expressed at 200 fmol mg(-1) protein (Bmax) in non-induced L929sA cells, at 740 fmol mg(-1) protein in HEK 293 and at 2300 fmol mg(-1) protein in mIFNbeta-induced L929sA cells, and on the human cloned 5-HT1D receptor expressed in C6 glioma cells (Bmax 780 fmol mg(-1) protein). 2. Sodium butyrate treatment increased the expression level of human (h)5-HT1B receptors in HEK 293 cells and h5-HT1D receptors in C6 glioma cells approximately 3 fold, the binding affinities of [3H]-5-HT and [3H]-alniditan were unaffected. 3. Agonistic properties were evaluated based on inhibition of cyclic AMP accumulation in the cells after stimulation of adenylyl cyclase by forskolin or isoproterenol. Alniditan, sumatriptan and dihydroergotamine were full agonists at the hS-HT1B receptor (IC50 values were 1.7, 20 and 2 nM, respectively in HEK 293 cells) and hS-HT1D receptors (IC50 values of 1.3, 2.6 and 2.2 nM, respectively). At the h5-HT1B receptor the agonist potency of the compounds slightly increased with higher receptor density. The opposite was seen for antagonists (ocaperidone, risperidone and ritanserin). 4. This comparative study demonstrated that alniditan was 10 times more potent than sumatriptan at the h5-HT1B receptor, and twice as potent at the h5-HT1D receptor. Dihydroergotamine was more potent an agonist at the h5-HT1B receptor when expressed at high and low level in L929sA cells (but not in HEK 293 cells), and was less potent at the hS-HT1D receptor.

The nuclear matrix and the regulation of chromatin organization and function

Nuclear DNA is organized into loop domains, with the base of the loop being bound to the nuclear matrix. Loops with transcriptionally active and/or potentially active genes have a DNase I-sensitive chromatin structure, while repressed chromatin loops have a condensed configuration that is essentially invisible to the transcription machinery. Core histone acetylation and torsional stress appear to be responsible for the generation and/or maintenance of the open potentially active chromatin loops. The transcriptionally active region of the loop makes several dynamic attachments with the nuclear matrix and is associated with core histones that are dynamically acetylated. Histone acetyltransferase and deacetylase, which catalyze this rapid acetylation and deacetylation, are bound to the nuclear matrix. Several transcription factors are components of the nuclear matrix. Histone acetyltransferase, deacetylase, and transcription factors may contribute to the dynamic attachment of the active chromatin domains with the nuclear matrix at sites of ongoing transcription.

Modulatory effect of sodium butyrate on AluI-induced chromosomal aberrations in CHO cells

Exponentially growing CHO cells exposed to millimolar concentrations of sodium butyrate (SB) for 24 h were treated with AluI using two methods of cell poration, i.e., electroporation and streptolysin O (SLO). Under both conditions, SB was found to induce a 2-4-fold increase in AluI-induced chromosomal aberrations. When cells in monolayer were treated with AluI/SLO, lower concentrations of SB (2.5 mM) and AluI (1-4 U/ml) were required to produce a similar effect as that observed for electroporated cells, demonstrating the differential sensitivity of the two methods. Furthermore, in AluI/SLO-treated cells, a higher percentage of cells was found to show increased frequencies of aberrations per cell, compared to AluI/electroporated cells. The mechanism by which SB modulates the cell response to AluI treatment might involve changes in chromatin configuration thereby increasing the accessibility of AluI to different parts of chromatin.

Parental nucleosomes segregated to newly replicated chromatin are underacetylated relative to those assembled de novo

Antibodies specific for acetylated histone H4 were used to examine the acetylation state of parental histones that segregate to newly replicated DNA. To generate newly replicated chromatin containing only segregated parental nucleosomes, isolated nuclei were labeled with [3H]TTP in vitro; alternatively, whole cells were labeled with [3H]thymidine in the presence of cycloheximide. Soluble chromatin was prepared by micrococcal nuclease digestion, and subjected to immunoprecipitation with "penta" antibodies (Lin et al., 1989). In sharp contrast to nucleosomes containing newly synthesized, diacetylated H4 (Perry et al., 1993), chromatin replicated in vitro was only marginally susceptible to immunoprecipitation. Control experiments established that bona fide acetylated chromatin was selectively immunoprecipitated by the same techniques and that segregated nucleosomes were not disassembled during treatment with "penta" antibodies. When replication was coupled to an in vitro histone acetylation system, the enrichment for segregated nucleosomes in the immunopellet increased approximately 3-fold, demonstrating that changes in the acetylation state of segregated histones can be detected immunologically and that parental histones on new DNA are accessible to acetyltransferases during, or immediately after, DNA replication. In vivo pulse-chase experiments, performed in the presence of cycloheximide, confirmed these results. Uptake experiments further established that concurrent histone acetylation did not alter the rate of DNA synthesis in vitro. Our results provide evidence that replication-competent chromatin is not obligatorily acetylated, and indicate that the acetylation status of segregated histones may be maintained during chromatin replication. The possible significance of this, with respect to the regulation of chromatin higher order structures during DNA replication, and the propagation of transcriptionally active vs inactive chromatin structures, is discussed.

Analysis of nucleosome assembly and histone exchange using antibodies specific for acetylated H4

Using antibodies that specifically recognize the acetylated forms of histone H4, we show that it is possible to immunoprecipitate newly assembled (acetylated) nucleosomes. Newly replicated HeLa cell chromatin was labeled for 5-30 min with [3H]thymidine in the presence of sodium butyrate (thus inhibiting the deacetylation of newly deposited H4); bulk chromatin DNA was labeled for 24 h with [14C]thymidine. When soluble nucleosomes were incubated with immobilized antibodies, a comparison of the bound and unbound fractions showed up to a 65-fold enrichment for new chromatin DNA in the immunoprecipitate (bound), relative to the supernatant (unbound). No enrichment for new DNA was observed when preimmune control serum was used in a similar fashion. The enrichment for new DNA in the immunopellet was paralleled by a similar enrichment for all four newly synthesized histones. Acetylation was required for antibody recognition: When chromatin was replicated in the absence of butyrate (permitting histone deacetylation and chromatin maturation), equally low levels of new and old chromatin were immunoprecipitated, and no enrichment for new DNA was observed. Competition experiments confirmed these results. Analyses of histone deposition during the inhibition of DNA replication established that acetylated chromatin is the preferential target for H2A/H2B exchange. These experiments provide evidence for the highly selective assembly of newly synthesized H3, H2A, and H2B with acetylated H4, and for the involvement of histone acetylation in dynamic chromatin remodeling. In addition, immunoprecipitations of radiolabeled cytosolic extracts identified a possible somatic chromatin preassembly complex, containing newly synthesized H3 and new (acetylated) H4.

Changes in cell cycle and chromatin distribution in C6 glioma cells treated by dibutyryl cyclic AMP

C6 glioma cells in culture were treated with 1 mM dibutyryl cyclic AMP (Db-cAMP) for 5, 8, 24 and 72 h. The cells were labelled with [3H]-thymidine before either the end, or the beginning, of the Db-cAMP treatment. The cell cycle passage was monitored by the simultaneous determination of DNA content and DNA synthesis in propidium iodide stained autoradiograms. The data revealed an early (t less than or equal to 3-8 h) and moderate inhibitory effect of Db-cAMP on all phases of the cell cycle except mitosis; some cells (2%) were completely blocked in the S phase. Later (8 less than t less than 24-72 h), the cycling of a substantial part of the population became inhibited in G1 phase. Microdensitometric texture analysis of Feulgen-stained nuclei, performed 24 h after administration of Db-cAMP, showed a higher inhomogeneity of the DNA distribution in cell nuclei, caused by the condensation of a part of the chromatin. This may reflect either changes in genome expression taking part in the process of cAMP induced differentiation or transit of some cells into quiescent G0 or S0 phases.

Histone acetylation reduces H1-mediated nucleosome interactions during chromatin assembly

During chromatin replication and nucleosome assembly, newly synthesized histone H4 is acetylated before it is deposited onto DNA, then deacetylated as assembly proceeds. In a previous study (Perry and Annunziato, Nucleic Acids Res. 17, 4275 [1989]) it was shown that when replication occurs in the presence of sodium butyrate (thereby inhibiting histone deacetylation), nascent chromatin fails to mature fully and instead remains preferentially sensitive to DNaseI, more soluble in magnesium, and depleted of histone H1 (relative to mature chromatin). In the following report the relationships between chromatin replication, histone acetylation, and H1-mediated nucleosome aggregation were further investigated. Chromatin was replicated in the presence or absence of sodium butyrate; isolated nucleosomes were stripped of linker histone, reconstituted with H1, and treated to produce Mg(2+)-soluble and Mg(2+)-insoluble chromatin fractions. Following the removal of H1, all solubility differences between chromatin replicated in sodium butyrate for 30 min (bu-chromatin) and control chromatin were lost. Reconstitution with H1 completely restored the preferential Mg(2+)-solubility of bu-chromatin, demonstrating that a reduced capacity for aggregation/condensation is an inherent feature of acetylated nascent nucleosomes; however, titration with excess H1 caused the solubility differences to be lost again. Moreover, when the core histone N-terminal "tails" (the sites of acetylation) were removed by trypsinization prior to reconstitution, H1 was unable to reestablish the altered solubility of chromatin replicated in butyrate. Thus, the core histone "tails," and the acetylation thereof, not only modulate H1-mediated nucleosome interactions in vitro, but also strongly influence the ability of H1 to differentiate between new and old nucleosomes. The data suggest a possible mechanism for the control of H1 deposition and/or chromatin folding during nucleosome assembly.

Proteolytic removal of core histone amino termini and dephosphorylation of histone H1 correlate with the formation of condensed chromatin and transcriptional silencing during Tetrahymena macronuclear development

During the sexual cycle in Tetrahymena, the germ-line micronucleus gives rise to new macro- and micronuclei, whereas the former somatic macronucleus ceases transcription, becomes highly condensed, and is eventually eliminated from the cell. With polyclonal antibodies specific for acetylated forms of histone H4, immunofluorescent analyses have demonstrated that transcriptionally active macronuclei stain positively at all stages of the life cycle except during conjugation, when parental macronuclei become inactive and are eliminated from the cell. In this report using affinity-purified antibodies to either the acetylated or unacetylated amino-terminal domain of H4, immunofluorescent analyses suggest that the acetylated amino-terminal tails of H4 are proteolytically removed in "old" macronuclei during this period. This suggestion was further confirmed by biochemical analysis of purified old macronuclei that revealed several polypeptides with molecular mass 1-2 kD less than that of intact core histones. These species, which are unique to old macronuclei, are not newly synthesized and fail to stain with either acetylated or unacetylated H4 antibodies. Microsequence analysis clearly shows that these polypeptides are proteolytically processed forms of core histones whose amino-terminal "tails" (varying from 13 to 21 residues) have been removed. During the same developmental period, histone H1 is dephosphorylated rapidly and completely in old macronuclei. These results strongly suggest that the developmentally regulated proteolysis of core histones and dephosphorylation of histone H1 participate in a novel pathway leading to the formation of highly condensed chromatin and transcriptional silencing during Tetrahymena macronuclear development.

Yeast histone H4 N-terminal sequence is required for promoter activation in vivo

To search for histone domains that may regulate transcription in vivo, we made deletions and amino acid substitutions in the histone N-termini of S. cerevisiae. Histone H4 N-terminal residues 4-23, which include the extremely conserved, reversibly acetylated lysines (at positions 5, 8, 12, and 16), were found to encompass a region required for the activation of the GAL1 promoter. Deletions in the H4 N-terminus reduce GAL1 activation 20-fold. This effect is specific to histone H4 in that large deletions in the N-termini of H2A, H2B, and H3 do not similarly decrease induction. Activation of the PHO5 promoter is reduced approximately 4- to 5-fold by these H4 deletions. Mutations in histone H4 acetylation sites and surrounding residues can cause comparable and, in some cases, even greater effects on induction of these two promoters. We postulate that the H4 N-terminus may interact with a component of the transcription initiation complex, allowing nucleosome unfolding and subsequent initiation.

Histone hyperacetylation does not alter the positioning or stability of phased nucleosomes on the mouse mammary tumor virus long terminal repeat

Activation of mouse mammary tumor virus transcription by the hormone-bound glucocorticoid receptor results in disruption of a nucleosome that is specifically positioned on the promoter. Limited treatment of cells with the histone deacetylase inhibitor sodium butyrate prevents receptor-dependent promoter activation and nucleosome disruption [Bresnick, E. H., John, S., Berard, D. S., LeFebvre, P., & Hager, G. L. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 3977-3981]. On the basis of this observation, we undertook a series of experiments to compare the structure of normal and hyperacetylated mouse mammary tumor virus chromatin. Although butyrate prevents hormone-induced restriction enzyme cutting specifically in the B nucleosome region, chromatin containing hyperacetylated histones does not differ from normal chromatin in general sensitivity to restriction enzymes. Indirect end-labeling analysis of micrococcal nuclease digested chromatin reveals that nucleosomes are identically phased on the mouse mammary tumor virus long terminal repeat in normal and hyperacetylated chromatin. A synthetic DNA fragment spanning the B nucleosome region was reconstituted into a monosome by using core particles containing normal or hyperacetylated histones. Analysis of the structure of reconstituted monosomes by nondenaturing polyacrylamide gel electrophoresis, salt stability, thermal stability, restriction enzyme accessibility, and exonuclease III or DNase I footprinting reveals no effect of histone hyperacetylation on monosome structure. These observations suggest that histone hyperacetylation does not induce a major change in the structure of mouse mammary tumor virus chromatin, such as nucleosome unfolding.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleosomes: regulators of transcription

Histones and nucleosomes are involved in the folding of DNA in the eukaryotic cell. Recent evidence suggests that they are also involved in a multistep process of DNA unfolding and gene regulation.

Histone hyperacetylation can induce unfolding of the nucleosome core particle

A direct correlation exists between the level of histone H4 hyperacetylation induced by sodium butyrate and the extent to which nucleosomes lose their compact shape and become elongated (62.0% of the particles have a length/width ratio over 1.6; overall mean in the length/width ratio = 1.83 +/- 0.48) when bound to electron microscope specimen grids at low ionic strength (1mM EDTA, 10mM Tris, pH 8.0). A marked proportion of elongated core particles is also observed in the naturally occurring hyperacetylated chicken testis chromatin undergoing spermatogenesis when analyzed at low ionic strength (36.8% of the particles have a length/width ratio over 1.6). Core particles of elongated shape (length/width ratio over 1.6) generated under low ionic strength conditions are absent in the hypoacetylated chicken erythrocyte chromatin and represent only 2.3% of the untreated Hela S3 cell core particles containing a low proportion of hyperacetylated histones. The marked differences between control and hyperacetylated core particles are absent if the particles are bound to the carbon support film in the presence of 0.2 M NaCl, 6mM MgCl2 and 10mM Tris pH 8.0, conditions known to stabilize nucleosomes. A survey of the published work on histone hyperacetylation together with the present results indicate that histone hyperacetylation does not produce any marked disruption of the core particle 'per se', but that it decreases intranucleosomal stabilizing forces as judged by the lowered stability of the hyperacetylated core particle under conditions of shearing stress such as cationic competition by the carbon support film of the EM grid for DNA binding.

Influence of histone acetylation on the solubility, H1 content and DNase I sensitivity of newly assembled chromatin

In a previous report [Annunziato, A.T. and Seale, R.L. (1983) J. Biol. Chem. 258:12675] a novel intermediate in chromatin assembly was described (detected by labeling new DNA in the presence of the deacetylase inhibitor sodium butyrate), which retained approximately 50% of the heightened sensitivity of newly replicated chromatin to DNaseI. It is now reported that nucleosomes replicated in butyrate are considerably more soluble in the presence of magnesium, relative to chromatin replicated under control conditions, and that this heightened magnesium-solubility is reflected in a concomitant increase in the preferential solubility of nucleosomes containing newly synthesized core histones. This differential solubility was accompanied by a 5- to 6-fold depletion of histone H1, and was completely abolished by the selective removal of H1 from isolated nuclei. The removal of H1 also markedly reduced the preferential DNaseI sensitivity of chromatin replicated in butyrate. Further, when mononucleosomes of control and (acetylated) nascent chromatin were compared, no differences in DNaseI sensitivity were detected. These results provide evidence that the interactions between newly assembled nucleosomes and histone H1 are altered when histone deacetylation is inhibited during chromatin replication, and suggest a mechanism for the control of H1 deposition during nucleosome assembly in vivo.

A model of chromatin-dependent DNA replication sequences based on the decondensation units hypothesis

A model of chromatin-dependent DNA replication sequences was developed on the previously reported "decondensation units" hypothesis and its kinetic properties were examined by way of calculating various numerical indices using a Monte Carlo procedure. The model has much in common with the previous one but a fundamental difference is that the unit is assumed to consist of linearly arranged H-, D-, A- and S-zones each containing genes of different functional categories which are called H-, D-, A- and S-genes, respectively. The units are decondensed by the action of D-factors, i.e. decondensation factors, from H-zone to the end of S-zone and the genes in decondensed regions release signals to produce housekeeping enzymes, D-factors, A-factors and S-factors. These products are stored and at the same time degraded. A-factors activate replication origins in the decondensed regions and S-factors induce DNA synthesis at the activated origins. Replicated DNA is recondensed and gene activities are shut down in the recondensed chromatin. The factors are produced under the control of chromosome cycle and in turn affect chromosomes. Thus, dual control mechanism operates as Mazia and Prescott have argued. Biochemical and cytogenetic basis of this model was reviewed briefly and some results of simulation presented which include DNA synthesis rate vs. DNA content relationships. An outstanding characteristic of the model is the constancy of cellular state in A-subphase located in the late G1.