Affinity chromatographic purification of nucleosomes containing transcriptionally active DNA sequences

Influence of core histone acetylation on SV40 minichromosome replication in vitro

We have used the SV40 in vitro replication system to analyze the replication efficiencies of SV40 minichromosomes associated with normal or hyperacetylated histones. We found that elongation of replication occurs with higher efficiency in hyperacetylated minichromosomes in comparison with normal minichromosomes. Our results indicate that the movement of the replication machinery through nucleosomal DNA is facilitated by charge neutralization due to acetylation of the histone tails.

Turnover of histone acetyl groups during sea urchin early development is not required for histone, heat shock and actin gene transcription

Histone acetylation is an extremely complex, reversible and specific process. In order to evaluate the importance of this modification for gene expression during sea urchin development, acetyl group turnover of histone lysine residues was blocked by sodium butyrate. The continuous presence of 15 Mm sodium butyrate in the incubation medium from the onset of development blocked gastrulation and resulted in chromatin containing hyperacetylated histone molecules in amounts usually not found in nature. At the mesenchyme blastula stage, the expression of the early histone genes was shut off and the expression of the late genes was switched on both in control and sodium butyrate-treated embryos. Investigation of the early histone gene chromatin structure in butyrate-treated embryos revealed a random distribution of nucleosomes when the genes were transcriptionally active as compared to regular nucleosomal packaging when genes were inactive. These changes in chromatin structure during development mimicked the chromatin structural transition of the early histone genes in control embryos. In addition, the ability of heat shock genes to be induced at elevated temperature and repressed at normal temperature was unaffected in butyrate treatment of embryos. Finally, the developmental profiles of the cytoskeletal CyIIIa actin gene expression in control and butyrate-treated embryos were very similar. The data presented suggest that turnover of histone acetyl groups and the overall level of histone acetylation are not determining factors in the up and down regulation of a number of genes during early development of sea urchin.

Effects of histone acetylation on chromatin structure

The effect of histone acetylation was monitored on CHO chromatin structure, following the addition of 7 mM Na-butyrate to the cell culture medium. The properties of both control and hyperacetylated chromatins and nuclei were investigated by circular dichroism, ethidium bromide intercalation, differential scanning calorimetry, and affinity chromatography. Our results are compatible with modest but significant alterations in the various levels of chromatin organization, as a result of the charge neutralization of some lysine residues within the N-terminal region of the histonic octamer. Namely, large statistically significant differences do exist in the heat capacity thermograms of native nuclei, where unfolding into single nucleofilament of the highly packed native chromatin superfiber appears associated with acetylation; at the same time CD, EB, and affinity chromatography point to modest but consistent differences in the compactness of isolated nucleosomes and polynucleosomes.

Isolation of chromatin fragments released by apoptotic cells

A two-step procedure for isolation of chromatin fragments released from apoptotic cells is described. The first step includes extraction of the chromatin fragments by a hypotonic treatment of isolated nuclei. The second step provides stabilization of the extracted chromatin fragments and their collection by a high-speed centrifugation. The procedure ensures not only a complete extraction and collection of the chromatin fragments but also intactness of their components. A number of control experiments confirmed this statement: they showed that the percentage of recovered fragmented DNA does not exceed 10% from the total DNA of apoptotic cells and that it is specific in both nature and chromosomal localization; the experiments reveal, moreover, that the protein components of the fragments including the well known histone and non-histone species possess also ability to support in in vitro conditions their specific phosphorylation. Developed for recovery of chromatin fragments from mouse erythroleukemia cells, spontaneously entering apoptosis, the procedure is practically applicable for all eukaryotic cell systems sharing programmable death.

HDA1 and HDA3 are components of a yeast histone deacetylase (HDA) complex

Histone acetylation is maintained through the action of histone acetyltransferases and deacetylases and has been correlated with increased gene activity. To investigate the functional role of these enzymes in the regulation of transcription, we have purified from Saccharomyces cerevisiae two histone deacetylase activities, HDA and HDB, with molecular masses of approximately 350 and 600 kDa, respectively. In vitro, the HDA activity deacetylates all four core histones, has a preference for histone H3, and is strongly inhibited by trichostatin A (a specific inhibitor of histone deacetylases). HDB is considerably less sensitive to trichostatin A. We report the extensive purification of the HDA activity and the identification of peptides (p75, p73, p72, and p71) whose presence correlates with deacetylase activity on native polyacrylamide gels. An antibody to p75 immunoprecipitates peptides with molecular masses similar to those in the 350-kDa complex. Additionally, antibodies to p75 and p71 specifically precipitate histone deacetylase activity and co-immunoprecipitate each other. Gene disruptions of p75 (HDA1) or p71 (HDA3) cause the loss of the 350-kDa (but not the 600-kDa) activity from our chromatography profiles. These data argue strongly that HDA1 and HDA3 are subunits of the HDA complex, which is structurally distinct from the second, HDB complex.

Spontaneous apoptosis in mouse F4N-S erythroleukemia cells induces a nonrandom fragmentation of DNA

This study characterizes the fragmented DNA of mouse erythroleukemia (MEL) cells spontaneously entering apoptosis. Fragmented DNA was isolated by introducing a novel procedure that ensured a complete extraction of the characteristic oligonucleosomal ladder. As the results show, less than 10% of DNA of apoptotic cells is fragmented in this form. The main conclusion from experiments to characterize the nature of fragmented DNA is that spontaneous apoptosis induces a nonrandom cleavage of genomic DNA. The Southern analysis performed with total apoptotic DNA revealed that it is strongly enriched in interspersed repetitive sequences. In situ hybridizations with such DNA showed further than in interphase nuclei these sequences flock together and form clusters spread throughout the whole nuclear area whereas in mitotic chromosomes they are located predominantly at their pericentromeric/peritelomeric ends. Partial cloning and sequencing reinforces the notion that the apoptotic DNA is representative for a heterochromatinic portion of the mouse genome. Support for such an unexpected conclusion is coming also from experiments indicating that this DNA is heavily methylated and poorly transcribed.

Biochemical characterization of mouse brain necdin

Necdin is a protein encoded by neural differentiation-specific mRNA derived from embryonal carcinoma cells (P19). Necdin of mouse brain was characterized by Western blotting and silver-staining analysis by using affinity purified antibodies to 17 synthetic peptides of deduced C-terminal amino acids. Necdin exhibits a molecular mass of 51 kDa on SDS/PAGE, and is localized in the S1 and S2 nucleosomal fractions. Sonicated necdin is found in all fractions of Sephacryl S-300 gel filtration chromatography, with a peak at 700 kDa. Necdin is released on microsomal nuclease digestion, which is essential for electrophoretic migration on acetic acid/urea/Triton gels, suggesting that it could be a DNA-binding protein. Nucleosomal necdin shows two peaks at approx. 10 S and approx. 20 S on sucrose gradient centrifugation in the presence of 0.6 M NaCl, and a single peak in the presence of 2.0 M NaCl. Necdin forms a huge complex through chemical cross-linking with glutaraldehyde or dimethyl sulphate. The silver-staining intensity of the 51 kDa band corresponds to the decrease in the immuno-staining in a reagent concentration-dependent manner. Necdin binds tightly to a double-stranded DNA affinity chromatography column, and can be eluted from it with 2.0 M NaCl after washing with 0.6 M NaCl (approx. 100 ng per ml of gel). This purified necdin exhibits of pI of 9.1 on isoelectric focusing. The nucleosomal necdin complex (>200 kDa) was adsorbed on an organomercurial agarose affinity chromatography column and was eluted with 10 mM DTT, revealing that necdin is possibly involved in the transactive nucleosomal complex. These data show that necdin is a nuclear basic DNA-binding protein that associates with other molecules to regulate transcriptionally active genes and nuclear function.

Identification of a gene encoding a yeast histone H4 acetyltransferase

A collection of yeast temperature-sensitive mutants was screened by an enzymatic assay to find a mutant defective in the acetylation of histone H4. The assay used a fractionated cell extract and measured acetylation of a peptide corresponding to amino acids 1-28 of H4. There are at least two activities in this fraction that acetylate the peptide. A mutation, hat1-1, that eliminates one of the activities was identified and mapped to a locus near the centromere of chromosome XVI. The HAT1 gene was cloned and found to encode a protein of 374 amino acids. Analysis of the peptide used in the assay demonstrated that the HAT1 enzyme acetylates lysine 12 of histone H4. hat1 mutants have no obvious growth defects or phenotypes other than the enzyme defect itself. The HAT1 protein expressed in Escherichia coli gave histone acetyltransferase activity in vitro, demonstrating that HAT1 is the structural gene for the enzyme.

An activity gel assay detects a single, catalytically active histone acetyltransferase subunit in Tetrahymena macronuclei

Macronuclei of the ciliated protozoan Tetrahymena thermophila possess a histone acetyltransferase activity closely associated with transcription-related histone acetylation. Nothing definitive is known concerning the polypeptide composition of this activity in Tetrahymena or any comparable activity from any cellular source. An acetyltransferase activity gel assay was developed which identifies a catalytically active subunit of this enzyme in Tetrahymena. This activity gel assay detects a single polypeptide of 55 kDa (p55) in crude macronuclear extracts, as well as in column-purified fractions, which incorporates [3H]acetate from [3H]acetyl-CoA into core histone substrates polymerized directly into SDS polyacrylamide gels. p55 copurifies precisely with acetyltransferase activity through all chromatographic steps examined, including reverse-phase HPLC. Gel-filtration chromatography of this activity indicates a molecular mass of 220 kDa, suggesting that the native enzyme may consist of four identical subunits of 55 kDa. Furthermore, p55 is tightly associated with di- and greater polynucleosomes and therefore may be defined as a component of histone acetyltransferase type A--i.e., chromatin associated.

Trichostatin A and trapoxin: novel chemical probes for the role of histone acetylation in chromatin structure and function

Reversible acetylation at the epsilon-amino group of lysines located at the conserved domain of core histones is supposed to play an important role in the regulation of chromatin structure and its transcriptional activity. One promising strategy for analyzing the precise function of histone acetylation is to block the activities of acetylating or deacetylating enzymes by specific inhibitors. Recently, two microbial metabolites, trichostatin A and trapoxin, were found to be potent inhibitors of histone deacetylases. Trichostatin A reversibly inhibits the mammalian histone deacetylase, whereas trapoxin causes inhibition through irreversible binding to the enzyme. The histone deacetylase from a trichostatin A-resistant cell line is resistant to trichostatin A, indicating that the enzyme is the primary target. Both of the agents induce a variety of biological responses of cells such as induction of differentiation and cell cycle arrest. Trichostatin A and trapoxin are useful in analyzing the role of histone acetylation in chromatin structure and function as well as in determining the genes whose activities are regulated by histone acetylation.

Interphase chromosomes of Friend-S cells are attached to the matrix structures through the centromeric/telomeric regions

DNA of the attachment sites of Friend erythroleukemia cells, isolated according to the conventional procedure, represents short, nuclease-resistant fragments with sizes below 400 bp, belonging to the class of mouse satellite. A number of experiments have indicated that their unusual resistance is due to complexing with RNA. By various approaches, it was confirmed that similar fragments might be recovered from total DNA following extensive digestion with DNase I. In situ hybridizations revealed further that at mitosis the sequences of the attachment sites are located at the centromeric/telomeric regions of the chromosomes, while at interphase they are redistributed into 9-13 well-defined clusters spread throughout the entire nuclear area. Parallel biochemical and electronmicroscopic studies have clarified, moreover, that the all three compartments of the matrix harbor such sequences. Thus, it appears that the attachment sites described function only at interphase, anchoring the both ends of each interphase chromosome to the matrix structures.

Histone acetylation and gene induction in human cells

An antibody recognising acetylated core histones was used to immunoprecipitate chromatin fragments from proliferating human K562 cells and from cells induced to differentiate with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA). The DNA of the acetylated chromatin was probed with sequences of platelet derived growth factor B chain (PDGF-B), a gene which is induced to strong expression upon differentiation. A high level of acetylation was observed before gene induction and no change seen following induction. This implies that core histone acetylation is an essential precondition for transcription.

Dynamics of interaction of RNA polymerase II with nucleosomes. II. During read-through and elongation

The sulfhydryl-specific fluorescence probe 1,5-IAEDANS (5-(2-((iodoacetyl)amino)ethyl)amino-naphthalene-1-sulfonic acid) was attached to the single cysteine of H3, and reconstituted fluorescent mononucleosomes were used as the template for in vitro transcription by the yeast RNA polymerase II (pol II). DNase I digestion analysis revealed that transcription of nucleosomes by pol II resulted in an overall loosening of the structure. Monitoring the transcription event by steady-state fluorescence analysis showed that nucleosomes only partially open during transcription. This opening is transient in nature, and nucleosomes close back as soon as the pol II falls off the template. Thus, using the technique of fluorescence spectroscopy, partial opening of nucleosome structure could be differentiated from complete dissociation into free DNA and histone octamer, a distinction that may not be possible by techniques like gel electrophoresis. Time-resolved fluorescence emission spectroscopy suggested that during read-through of the template by the pol II, histone octamers do not fall off the DNA. Only minor conformational changes within the histone octamer take place to accommodate the transcribing polymerase.

Selective use of H4 acetylation sites in the yeast Saccharomyces cerevisiae

The acetylation of specific lysine residues in the histone H4 may play a role in regulating various genes in the yeast Saccharomyces cerevisiae [Grunstein (1990) Annu. Rev. Cell Biol. 6, 643-678]. The detailed consideration of this possibility has been hampered by the lack of information on the frequency with which different H4 lysine residues are acetylated in yeast. In this paper, we use Western blotting from acid/urea/Triton gels and immunostaining with antisera specific for H4 molecules acetylated at particular lysine residues to show that 70-80% of H4 molecules in S. cerevisiae contain one or more acetylated lysines, and that lysines-5, -8, -12 and -16 are acetylated in an ordered, non-random fashion. The monoacetylated isoform (H4Ac1) is acetylated predominantly at lysine-16 (rarely at lysine-12), H4Ac2 is acetylated at lysine-16 and at either lysine-12 or at -8, while lysine-5 is acetylated frequently only in H4Ac3 and in H4Ac4.

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.

Histone deacetylase. A key enzyme for the binding of regulatory proteins to chromatin

Core histones can be modified by reversible, posttranslational acetylation of specific lysine residues within the N-terminal protein domains. The dynamic equilibrium of acetylation is maintained by two enzyme activities, histone acetyltransferase and histone deacetylase. Recent data on histone deacetylases and on anionic motifs in chromatin- or DNA-binding regulatory proteins (e.g. transcription factors, nuclear proto-oncogenes) are summarized and united into a hypothesis which attributes a key function to histone deacetylation for the binding of regulatory proteins to chromatin by a transient, specific local increase of the positive charge in the N-terminal domains of nucleosomal core histones. According to our model, the rapid deacetylation of distinct lysines in especially H2A and H2B would facilitate the association of anionic protein domains of regulatory proteins to specific nucleosomes. Therefore histone deacetylation (histone deacetylases) may represent a unique regulatory mechanism in the early steps of gene activation, in contrast to the more structural role of histone acetylation (histone acetyltransferases) for nucleosomal transitions during the actual transcription process.

Accumulation of multiacetylated forms of histones by trichostatin A and its developmental consequences in early starfish embryos

External application of 10 rig/ml (R)-trichostatin A (TSA), a potent and specific inhibitor of mammalian histone deacetylase, to the embryo of the starfish Asterina pectinifera inhibited development during the early gastrula stage before formation of mesenchyme cells. The TSA-sensitive period was limited to the mid-blastula stage before hatching. The pulse-chase experiment clearly demonstrated that TSA induced an accumulation of acetylated histone species in blastulae through inhibition of historic deacetylation. Similar blockage of development at the early gastrula stage was observed with n-butyrate, which has been known as a weak inhibitor of historic deacetylase. These results suggest an intimate role for historic acetylation-deacetylation equilibria in starfish development.

Elevation of large-T antigen production by sodium butyrate treatment of SV40-transformed WI-38 fibroblasts

The effects of sodium butyrate on simian virus 40 early gene expression were determined in SV40-transformed human embryonic lung fibroblasts (SVWI-38). Northern blot analysis and nuclear run-off transcription studies revealed that treatment of cells with millimolar concentrations of sodium butyrate (2.5 to 10 mM) resulted in increased levels of SV40 early gene transcripts, with a concomitant increase in their corresponding proteins (large-T and small-t antigens). Although sodium butyrate treatment enhanced the expression of the early genes, it was associated with a reduction in cell growth and total protein synthesis, as measured by cell number and incorporation of 3H-leucine into macromolecules, respectively. Immunoprecipitation of 35S-labelled cellular proteins with anti-p53 and anti-T antibodies revealed that the level of the cellular protein, p53, declined markedly in the presence of sodium butyrate. Furthermore, in control cells only 30% of the p53 was complexed with large-T antigen, whereas in butyrate-treated cells all the p53 was complexed with large-T antigen. The increased early gene expression was not due to altered methylation patterns, gene amplification, or rearrangement of the integrated SV40 genome. Sodium butyrate treatment did, however, result in the appearance of a new nuclear protein which bound specifically to a SV40 promoter fragment containing large-T antigen binding sites I and II.

Histone H4 isoforms acetylated at specific lysine residues define individual chromosomes and chromatin domains in Drosophila polytene nuclei

Histone H4 isoforms acetylated at lysines 5, 8, 12, or 16 have been shown, by indirect immunofluorescence with site-specific antisera, to have distinct patterns of distribution in interphase, polytene chromosomes from Drosophila larvae. H4 molecules acetylated at lysines 5 or 8 are distributed in overlapping, but nonidentical, islands throughout the euchromatic chromosome arms. beta-Heterochromatin in the chromocenter is depleted in these isoforms, but relatively enriched in H4 acetylated at lysine 12. H4 acetylated at lysine 16 is found at numerous sites along the transcriptionally hyperactive X chromosome in male larvae, but not in male autosomes or any chromosome in female cells. These findings support the hypothesis that H4 molecules acetylated at particular sites mediate unique and specific effects on chromatin function.

Histone acetylation and globin gene switching

An affinity-purified antibody that recognises the epitope epsilon-acetyl lysine has been used to fractionate chicken erythrocyte mononucleosomes obtained from 5 and 15 day embryos. The antibody bound chromatin was enriched in multiply acetylated forms of the core histones H3, H4 and H2B, but not in ubiquitinated H2A. The DNA of these modified nucleosomes was probed with genomic sequences from the embryonic beta rho gene (active at 5 days) and from the adult beta A gene (active at 15 days). Both genes were found to be highly enriched in the acetylated nucleosomes fractionated from both 5 day and from 15 day erythrocytes. We conclude that globin switching is not linked to a change in acetylation status of the genes and that a 'poised' gene carries histones acetylated to a similar level as a transcriptionally active gene. Core histone acetylation is not therefore a direct consequence of the transcriptional process and might operate at the level of the globin locus as a general enabling step for transcription.

Relationship of histone acetylation to DNA topology and transcription

An autonomously replicating plasmid constructed from bovine papiloma virus (BPV) and pBR322 was stably maintained as a nuclear episome in a mouse cell culture. Addition to a cell culture of sodium butyrate (5 mM) induced an increase in plasmid DNA supercoiling of 3-5 turns, an increase in acetylation of cellular histones, and a decrease in plasmid transcription by 2- to 4-fold. After withdrawal of butyrate, DNA supercoiling began to fluctuate in a wave-like manner with an amplitude of up to 3 turns and a period of 3-4 h. These waves gradually faded by 24 h. The transcription of the plasmid and acetylation of cellular histones also oscillated with the same period. The wave-like alterations were not correlated with the cell cycle, for there was no resumption of DNA replication after butyrate withdrawal for at least 24 h. In vitro chemical acetylation of histones with acetyl adenylate also led to an increase in the superhelical density of plasmid DNA. The parallel changes in transcription, histone acetylation, and DNA supercoiling in vivo may indicate a functional innerconnection. Also, the observed in vivo variation in the level of DNA supercoiling directly indicates the possibility of its natural regulation in eukaryotic cells.

High rotational mobility of DNA in animal cells and its modulation by histone acetylation

DNA rotational mobility in a bovine papilloma virus (BPV)-based minichromosome, autonomously replicating in mouse cells, was studied using topoisomer analysis in temperature shift experiments. It was found that in live cells the average number of topological turns increased by six in the course of temperature shift through a range of 37 degrees C. This comprised approximately 85% of the total potential mobility of naked plasmid DNA. DNA rotation in isolated nuclei was found to be 3.5-4.0 turns per 37 degrees C in 100 mM NaCl - much higher than in all experiments with animal cells reported thus far. In low salt mobility was considerably lowered. Attempts to extract minichromosomes from nuclei allowed isolation of no more than 10% of minichromosomal DNA, with could indicate a very high proportion of transcriptionally active minichromosomes in the intracellular population. Growing cells in the presence of sodium butyrate resulted not only in an increase in the level of plasmid superhelicity and a decrease of its transcription (as we report in the accompanying publication) but also reduced rotational mobility of plasmid DNA threefold (from 6 to 2 turns per 37 degrees C). The decrease in DNA rotational mobility after butyrate treatment was also partially manifested in isolated nuclei (especially at lower ionic strength). To check whether histone acetylation is directly responsible for DNA immobilization, we performed in vitro acetylation of histones using acetyl adenylate. This resulted in severe DNA immobilization in experiments using both up and down temperature shifts.

High-mobility group and other nonhistone substrates for nuclear histone N-acetyltransferase

A variety of nonhistone proteins and polyamines has been studied for their substrate activity for nuclear histone N-acetyltransferase. Nonhistone chromatin high-mobility group (HMG) proteins are found to be as good a substrate for the enzyme as histones. The enzyme also acetylates spermidine and spermine. However, protamine, bovine serum albumin, and ubiquitin are not substrates. Chymotryptic peptides of histone and HMGs retained about 64% of the substrate activity, but trypsin treatment reduced the substrate activity by more than 85%. Both N-acetyltransferase activities for HMGs and histones are copurified through salt extraction, polyethylene glycol fractionation, and chromatography on DEAE-cellulose, phosphocellulose columns, and a HPLC anionic-exchange column. The highly purified nuclear histone acetyltransferase shows similar optimal pH and ping-pong kinetics for both HMGs and histones. The Km for HMG is 0.25 mg/ml. HMGs are able to accept the acetyl group from isolated acetyl-enzyme intermediate. Denatured gel analysis shows that HMG 1 and HMG 2 are the major proteins acetylated. High salt concentrations, mononucleotides, and DNA, which inhibit histone substrate activity of the enzyme, also inhibit HMG substrate activity. These observations suggest that there is a major nuclear N-acetyltransferase which is responsible for the acetylation of both histones and HMGs and perhaps also of spermine and spermidine. Thus the regulation of the structure and function of chromatin through postsynthetic acetylation can be achieved by a single nuclear N-acetyltransferase.

Inhibition of 5S RNA transcription in vitro by nucleosome cores with low or high levels of histone acetylation

Nucleosomes exert strong inhibitory effects on gene transcription in vitro and in vivo. Since most DNA is packaged in nucleosomes, there must exist mechanisms to alleviate this inhibition during gene activation. Nucleosomes could be destabilized by histone acetylation which is strongly correlated with gene expression. We have compared the effects of nucleosomes cores with low or high levels of histone acetylation on 5S RNA transcription with Xenopus nuclear extracts in vitro. Little or no difference was observed over a range of 1 to 15 nucleosome cores per plasmid template. This result suggests that nucleosomal DNA is not more accessible to transcription factors and to the transcription machinery in acetylated nucleosomes.

Histone contributions to the structure of DNA in the nucleosome

We describe the application of the hydroxyl radical footprinting technique to examine the contribution of the core histone tails and of histones H3 and H4 to the structure of DNA in the nucleosome. We first establish that, as was previously determined for a nucleosome containing a unique sequence of DNA, mixed-sequence nucleosomes contain two distinct regions of DNA structure. The central three turns of DNA in the nucleosome have a helical periodicity of approximately 10.7 base pairs per turn, while flanking regions have a periodicity of approximately 10.0 base pairs per turn. Removal of the histone tails does not change the hydroxyl radical cleavage pattern in either mixed- or unique-sequence nucleosome samples. A tetramer of histones H3 and H4, (H3/H4)2, organizes the central 120 base pairs of DNA identically to that found in the nucleosome. Moreover, "tailless" octamers and the (H3/H4)2 tetramer recognize the same nucleosome positioning signals as the intact octamer.

Polarized light scattering of nucleosomes and polynucleosomes--in situ and in vitro studies

Nucleosomes, chromatin and nuclei, extracted from rat hepatocytes, are studied by a new "in house" experimental configuration which measures circular intensity differential scattering (CIDS) and other elements of the polarized light scattering matrix. The Mueller matrix elements, S14 and S34, that are related to the geometric parameters of the superhelical arrangement of polynucleosomes point to the existence of a quaternary structure at low ionic strength for chromatin prepared by the cold-water method, which is lost by shearing, and is not found in the soluble chromatin prepared through the nuclease method. Only salt addition to a final concentration of 5 mM MgCl2, 150 mM NaCl and 10 mM Tris HCl (pH 7) yields a sizeable (S14 + S34) signal in the latter chromatin, which is however still different from the corresponding signal of native nuclei and of "cold-water" chromatin. Comfortingly, the (S14 + S34) signal from isolated nucleosomes is consistently very low (nearly zero) as predicted by multiple dipole simulation within the framework of classical electrodynamics. Results are discussed in terms of the topological constraints present in the native long chromatin fiber, which are lost after limited nuclease digestion and after shearing.

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.

Affinity isolation of active murine erythroleukemia cell chromatin: uniform distribution of ubiquitinated histone H2A between active and inactive fractions

This laboratory recently reported the development of a biotin-cellulose/streptavidin affinity chromatography method based on the DNase I sensitivity of active chromatin to isolate a DNA fraction from murine erythroleukemia (MEL) cells that is more than 15-fold enriched in active genes (Dawson et al.: Journal of Biological Chemistry 264:12830-12837, 1989). We now report the extension of this technique to isolate and characterize chromatin that is enriched in active genes. In this approach, DNA in nuclei isolated from MEL cells was nicked with DNase I at a concentration that does not digest the active beta-globin gene, followed by repair of the nicks with a cleavable biotinylated nucleotide analog, 5-[(N-biotin-amido)hexanoamido-ethyl-1,3'-dithiopropionyl-3- aminoallyl]-2'- deoxyuridine 5'-triphosphate (Bio-19-SS-dUTP), during a nick-translation reaction. After shearing and sonication of the nuclei to solubilize chromatin, chromatin fragments containing biotin were separated from non-biotinylated fragments by sequential binding to streptavidin and biotin cellulose. The bound complex contained approximately 10% of the bulk DNA. Reduction of the disulfide bond in the biotinylated nucleotide eluted approximately one-half of the affinity isolated chromatin. Hybridization analysis of DNA revealed that whereas inactive albumin sequences were equally distributed among the chromatin fractions, virtually all of the active beta-globin sequences were associated with chromatin fragments which had bound to the affinity complex. Western blot assessment for ubiquitinate histones revealed that ubiquitinated histone H2A (uH2A) was uniformly distributed among active (bound) and inactive (unbound) chromatin fractions.

Rapid histone H3 phosphorylation in response to growth factors, phorbol esters, okadaic acid, and protein synthesis inhibitors

When quiescent cells are stimulated with growth factors, phorbol esters, okadaic acid, or protein synthesis inhibitors, the early-response genes, which include c-fos and c-jun, are rapidly induced. The earliest growth factor- and phorbol ester-stimulated nuclear signaling events concomitant with proto-oncogene induction are the rapid phosphorylation of two chromatin-associated proteins, pp33 and pp15. We show here that the tumor promoter okadaic acid, which inhibits protein phosphatases 1 and 2A, and the protein synthesis inhibitors anisomycin and cycloheximide also stimulate pp33 and pp15 phosphorylation. Using transcriptional inhibitors, we show that this response is not a consequence of early gene induction. By peptide mapping and microsequencing, chromatin-associated pp15 is identified as histone H3. Upon stimulation, histone H3 is rapidly phosphorylated on serine residues within its highly charged, basic N-terminal domain. Thus, these diverse agents elicit a common early nuclear signal modulating nucleosomal structure or function, potentially contributing to conformational regulation of proto-oncogene induction.

Two new photoaffinity polyamines appear to alter the helical twist of DNA in nucleosome core particles

Two new photoaffinity derivatives of polyamines have been synthesized by the reaction of spermine or spermidine with methyl 4-azidobenzimidate. The new compounds were purified chromatographically and characterized by several methods including proton magnetic resonance spectroscopy. The spermine derivative is N1-ABA-spermine [(azidobenzamidino)spermine], and the spermidine derivative is a mixture of N1- and N8-ABA-spermidine. ABA-spermine stabilizes nucleosome core particles in thermal denaturation experiments, with similar but not identical effects when compared with the parent polyamine, spermine. In circular dichroism experiments, ABA-spermine was capable of producing a B----Z transition in poly(dG-m5dC) at a concentration of 30 microM, compared with 5 microM required to produce the same effect with spermine. On the other hand, ANB-spermine [(azidonitrobenzoyl)spermine; Morgan, J. E., Calkins, C. C., & Matthews, H. R. (1989) Biochemistry 28, 5095-5106] stabilized the B form of poly(dG-br5dC). ABA-spermine is a potent inhibitor of ornithine decarboxylase from Escherichia coli, giving 50% inhibition at 0.12 mM, while ANB-spermine is a modest inhibitor, comparable to spermine or spermidine. Under conditions of nitrogen-limited growth, yeast take up ABA-spermine and ABA-spermidine at approximately one-third to half the rate of spermidine or spermine. In contrast, ANB-spermine was not significantly taken up. The photoaffinity polyamines were used to photoaffinity label the DNA in nucleosome core particles, and the sites of labeling were determined by exonuclease protection. All photoaffinity reagents showed both nonspecific labeling and specific sites of higher occupancy. However, the positions of the sites varied: the ANB-spermine sites confirmed those previously reported (Morgan et al., 1989); the ABA-spermine and ABA-spermidine sites were spaced at 9.8 bp intervals from the 3' end of each DNA strand. This observation, together with the effect of spermine on the circular dichroism of DNA in nucleosome core particles, implies that polyamines alter the helical twist of DNA in nucleosome core particles. The ABA-polyamines are offered as general-purpose photoaffinity polyamine reagents.

Nucleoprotein hybridization: a method for isolating active and inactive genes as chromatin

The developmentally regulated sea urchin early histone gene repeat (SUEHGR) from Strongylocentrotus purpuratus was isolated as chromatin by nucleoprotein hybridization. This technique is a novel method to isolate specific sequences as chromatin. Because the purification scheme is based only on the gene sequence and is independent of other physical properties such as protein composition and transcriptional activity, we were able to isolate the same gene in different functional states. Gene size chromatin fragments were solubilized by restriction endonuclease digestion of cell nuclei. Using T7 gene 6 exonuclease, the 3'termini of the fragments were exposed and then hybridized in solution to a biotinylated oligonucleotide complementary to one end of the SUEHGR fragment. The hybrids were bound to an Avidin D matrix. DTT cleavage of the biotin linker yielded a chromatin fraction greater than 700 fold enriched in SUEHGR. Overall yields were between 2% and 15%. The purity of the isolated material was independently measured to be greater than 80%. The homogeneous native structure of the inactive genes was preserved as shown by electron microscopy and micrococcal nuclease digestion of the purified SUEHGR. Minor heterogeneity was observed for the purified active genes by micrococcal nuclease digestion but the main features of the active chromatin were preserved during isolation. This isolation offers the first opportunity to study the structure of an RNA polymerase II gene at different stages of the cell cycle and development.

Regulation of nuclear histone acetyltransferase by nucleic acids, histone.DNA complex, and chromatin

Nuclear histone acetyltransferase is found to be inhibited by various nucleic acids and components. Of the adenosine phosphates, the order of inhibitory potency is ATP greater than ADP greater than AMP. Among the nucleoside triphosphates, GTP seems to be the best inhibitor, followed by ATP, CTP, and UTP. Deoxymononucleotides have the same order of inhibition potential as their ribonucleotide counterparts, with inhibition constants in the low millimolar range. Oligonucleotides and polynucleotides are much better inhibitors than mononucleotides. The inhibition constants of the DNA molecules are size dependent. Molecules larger than 40 base pairs have inhibition constants less than 18 micrograms/ml, whereas molecules with decreasing numbers of base pairs have increasing magnitudes of inhibition constants. However, acetyltransferase has a lower affinity for free DNA molecules than for DNA.histone complexes as revealed by its interaction with DNA-Sepharose and histone.DNA-Sepharose columns. Furthermore, native chromatin depleted of endogenous histone acetyltransferase activity shows no inhibitory effect on the enzyme. Yet heated chromatin not only loses substrate activity but also becomes an inhibitor for the enzyme. Since unmodified sea urchin sperm chromatin has been shown to be a potent acetyltransferase inhibitor, it seems possible that DNA.histone complexes may be the true inhibitory species and that the conformational states of such complexes may serve as a regulatory mechanism in the control of the enzyme activity.

Dynamically acetylated histones of chicken erythrocytes are selectively methylated

The relationship between histone acetylation and methylation in chicken immature erythrocytes was investigated. Previous studies have shown that transcriptionally active/competent gene-enriched chromatin fragments are enriched in newly methylated histones H3 and H4. Moreover, newly methylated histone H4 is hyperacetylated. Here, we show that dynamically acetylated histone H4 is selectively engaged in ongoing methylation. While sodium butyrate (an inhibitor of histone deacetylase) does not inhibit ongoing histone methylation, it does affect the acetylation state of newly methylated histone H4 when chicken immature erythrocytes are incubated in its presence or absence. Only one rate of acetylation of labelled newly methylated unacetylated histone H4 with a t1/2 of 8 min is observed. Previous studies have shown that the solubility of transcriptionally active/competent gene chromatin fragments in 0.15 M-NaCl is dependent upon the level of acetylated histone species, with induction of hyperacetylation increasing the solubility of this gene chromatin. Here, we show that the low salt solubility of chromatin fragments associated with newly methylated histones H3 and H4 is also dependent upon the level of acetylated histones. These results provide further support for the hypothesis that histones participating in ongoing methylation are associated with transcriptionally active/competent chromatin and suggest that the processes of histone H4 methylation and dynamic acetylation are partially coupled in terminally differentiated erythrocytes.

Factors affecting nucleosome structure in transcriptionally active chromatin. Histone acetylation, nascent RNA and inhibitors of RNA synthesis

The nucleosomes of transcriptionally active genes can be separated from those of inactive genes by affinity chromatography on organomercury-agarose (Hg-agarose) columns. The basis for this separation is the difference in accessibility of the sulfhydryl groups of histone H3 and certain non-histone proteins in active and inactive chromatin. A new procedure distinguishing between different modes of binding of transcriptionally active nucleosomes to the Hg-agarose column has been applied to study several factors which might influence the binding reaction. Nucleosomes that bind to the column because of salt-labile associations with SH-reactive non-histone proteins, such as the high-mobility-group proteins, HMG-1 and HMG-2, were released by adding 0.5 M NaCl to the eluting buffer. The remaining nucleosomes, in which reactive histone H3 thiol groups can bind covalently to the organomercury, were then displaced from the column by 10 mM dithiothreitol. Both Hg-agarose-bound fractions contain the transcriptionally active DNA sequences of the cell, but inactive nucleosomes, such as those containing alpha-globin DNA, pass through the column. The histones of both Hg-agarose-bound fractions have significantly higher levels of acetylation than do histones of the unbound fraction, but the content of tri- and tetra-acetylated H3 and H4 is significantly higher in the nucleosomes with reactive H3 thiols. The rate of turnover of histone N-acetyl groups is also far greater in the Hg-agarose-bound nucleosomes than in the unbound nucleosomes. Although the overall levels of histone acetylation can be increased significantly by incubating HeLa cells in the presence of the deacetylase inhibitor, 5 mM sodium butyrate, this treatment has little if any effect on the total number of nucleosomes retained on the Hg-agarose column. However, the ability of Hg-agarose chromatography to detect localized changes in chromatin structure is evidenced by an 11-fold increase in the Hg-agarose binding of nucleosomes containing the DNA of the butyrate-inducible alkaline phosphatase gene, compared to the Hg-agarose-bound nucleosomes of control cells. Although nascent RNA chains are present in the Hg-agarose-bound nucleosomes released by dithiothreitol, binding of the SH-reactive nucleosomes to the Hg-agarose column is not dependent on the presence of proteins associated with nascent RNA chains, since binding does not decrease following removal of the nascent transcripts by ribonuclease treatment.(ABSTRACT TRUNCATED AT 400 WORDS)

Patterns of histone acetylation

The N-terminal domains of all four core histones are subject to reversible acetylation at certain lysine residues. This modification has been functionally linked to transcription, histone deposition at replication and to histone removal during spermatogenesis. To increase understanding of the significance of this modification we have studied the specificity of site utilisation in the monoacetyl, diacetyl and triacetyl forms of histones H3, H4 and H2B (histone H2A has only a single modification site), using pig thymus and HeLa cells as the source of histones. The HeLa histones were extracted from cells grown both with and without butyrate treatment. It is found that for histone H3 there is a fairly strict order of site occupancy: Lys14, followed by Lys23, followed by Lys18 in both pig and HeLa histones. Since the order and specificity is the same when butyrate is added to the HeLa cell cultures, we conclude that addition of the fatty acid does not scramble the specificity of site utilisation, but merely allows more of the natural forms of modified histone to accumulate. For histone H4, the monoacetyl form is exclusively modified at Lys16, but further addition of acetyl groups is less specific and progresses through sites 12, 8 and 5 in an N-terminal direction. Similar results were obtained for H4 from both pig thymus and butyrate-treated HeLa cells. Histone H2B could be studied in detail only from butyrate-treated HeLa cells and a much lower level of site specificity was found: sites 12 and 15 were preferred to the more N- and C-terminal sites at Lys5 and Lys20. The data reinforces the view that lysine acetylation in core histones is a very specific phenomenon that plays several functionally distinct roles. The high degree of site specificity makes it unlikely that the structural effects of acetylation are mediated merely by a generalised reduction of charge in the histone N-terminal domains.