Nucleosome linking number change controlled by acetylation of histones H3 and H4

High levels of acetylation of lysines in the amino-terminal domains of all four core histones, H2A, H2B, H3, and H4, have been shown to reduce the linking number change per nucleosome core particle in reconstituted minichromosomes (Norton, V. G., Imai, B. S., Yau, P., and Bradbury, E. M. (1989) Cell 57, 449-457). Because there is evidence to suggest that the acetylations of H3 and H4 have functions that are distinct from those of H2A and H2B, we have determined the nucleosome core particle linking number change in minichromosomes containing fully acetylated H3 and H4 and very low levels of acetylation in H2A and H2B. This linking number change was -0.81 +/- 0.05, in close agreement with the linking number change for hyperacetylated nucleosome core particles which contain high levels of acetylation in all four core histones (approximately 70% of full acetylation in H3 and H4). Therefore, high levels of acetylation of H3 and H4 alone are responsible for the reduction in the linking number change per nucleosome core particle.     

A chromatin core particle obtained by selective cleavage of histones by clostripain.

Rat liver chromatin core particles digested with clostripain yield a structurally well-defined nucleoprotein particle with an octameric core made up of fragmented histone species (designated H'2A, H'2B, H'3 and H'4, respectively) after selective loss of a sequence segment located in the N-terminal region of each core histone. Sequential Edman degradation and carboxypeptidase digestion unambiguously establish that histones H2A, H2B, H3 and H4 are selectively cleaved at the carboxyl side of Arg 11, Lys 20, Arg 26 and Arg 19 respectively and that the C-terminal sequences remain unaffected. Despite the loss of the highly basic N-terminal regions, including approximately 17% of the total amino acids, the characteristic structural organization of the nucleosome core particle appears to be fully retained in the proteolyzed core particle, as judged by physicochemical and biochemical evidence. Binding of spermidine to native and proteolyzed core particles shows that DNA accessibility differs markedly in both structures. As expected the proteolyzed particle, which has lost all the in vivo acetylation sites, is not enzymatically acetylated, in contrast to the native particle. However, proteolyzed histones act as substrates of the acetyltransferase in the absence of DNA, as a consequence of the occurrence of potential acetylation sites in the core histones thus rendered accessible. The possible role of the histone N-terminal regions on chromatin structure and function is discussed in the light of the present observations with the new core particle obtained by clostripain proteolysis.     

Influence of histone tails and H4 tail acetylations on nucleosome-nucleosome interactions

Nucleosome–nucleosome interaction plays a fundamental role in chromatin folding and self-association. The cation-induced condensation of nucleosome core particles (NCPs) displays properties similar to those of chromatin fibers, with important contributions from the N-terminal histone tails. We study the self-association induced by addition of cations [Mg²⁺, Ca²⁺, cobalt(III)hexammine³⁺, spermidine³⁺ and spermine⁴⁺] for NCPs reconstituted with wild-type unmodified histones and with globular tailless histones and for NCPs with the H4 histone tail having lysine (K) acetylations or lysine-to-glutamine mutations at positions K5, K8, K12 and K16. In addition, the histone construct with the single H4K16 acetylation was investigated. Acetylated histones were prepared by a semisynthetic native chemical ligation method. The aggregation behavior of NCPs shows a general cation-dependent behavior similar to that of the self-association of nucleosome arrays. Unlike nucleosome array self-association, NCP aggregation is sensitive to position and nature of the H4 tail modification. The tetra-acetylation in the H4 tail significantly weakens the nucleosome–nucleosome interaction, while the H4 K → Q tetra-mutation displays a more modest effect. The single H4K16 acetylation also weakens the self-association of NCPs, which reflects the specific role of H4K16 in the nucleosome–nucleosome stacking. Tailless NCPs can aggregate in the presence of oligocations, which indicates that attraction also occurs by tail-independent nucleosome–nucleosome stacking and DNA–DNA attraction in the presence of cations. The experimental data were compared with the results of coarse-grained computer modeling for NCP solutions with explicit presence of mobile ions.     

Chemical acetylation, trypsinolysis and stability of nucleosomes

Gel electrophoretic analysis of the histone chemical acetylation in the nucleosome core particles with acetic andydride revealed availability of about 14 lysine residues of histone H2A, 15-21 of H2B, 8-11--H3 and 6-9--H4. Moderately lysine-rich histones H2A and H2B were found to be more susceptible to acetylation than arginine-rich H3 and H4. Chemical acetylation enhanced the rate of trypsin digestion in acetylated nucleosomes as evidenced by gel electrophoresis of histone fragments. A more pronounced trypsin digestion was evident at acetylation of only 3-5 histone amino groups per nucleosome. However, even heavily acetylated nucleosomes yielded in familiar trypsin limit digest pattern of histone fragments thus indicating persistence of histone octamer. Nucleosomes which were trace acetylated (up to 3-5 histone amino groups neutralized per nucleosome) and treated with trypsin to remove highly charged terminal histone regions revealed remarkable unfolding and partial dissociation when analyzed by gel electrophoresis. The same trace acetylated nucleosomes did not show such destabilization prior to trypsin digestion.     

Acetylation of histone H3 lysine 56 regulates replication-coupled nucleosome assembly

Chromatin assembly factor 1 (CAF-1) and Rtt106 participate in the deposition of newly synthesized histones onto replicating DNA to form nucleosomes. This process is critical for the maintenance of genome stability and inheritance of functionally specialized chromatin structures in proliferating cells. However, the molecular functions of the acetylation of newly synthesized histones in this DNA replication-coupled nucleosome assembly pathway remain enigmatic. Here we show that histone H3 acetylated at lysine 56 (H3K56Ac) is incorporated onto replicating DNA and, by increasing the binding affinity of CAF-1 and Rtt106 for histone H3, H3K56Ac enhances the ability of these histone chaperones to assemble DNA into nucleosomes. Genetic analysis indicates that H3K56Ac acts in a nonredundant manner with the acetylation of the N-terminal residues of H3 and H4 in nucleosome assembly. These results reveal a mechanism by which H3K56Ac regulates replication-coupled nucleosome assembly mediated by CAF-1 and Rtt106.     

The effects of histone H4 tail acetylations on cation-induced chromatin folding and self-association

Understanding the molecular mechanisms behind regulation of chromatin folding through covalent modifications of the histone N-terminal tails is hampered by a lack of accessible chromatin containing precisely modified histones. We study the internal folding and intermolecular self-association of a chromatin system consisting of saturated 12-mer nucleosome arrays containing various combinations of completely acetylated lysines at positions 5, 8, 12 and 16 of histone H4, induced by the cations Na(+), K(+), Mg(2+), Ca(2+), cobalt-hexammine(3+), spermidine(3+) and spermine(4+). Histones were prepared using a novel semi-synthetic approach with native chemical ligation. Acetylation of H4-K16, but not its glutamine mutation, drastically reduces cation-induced folding of the array. Neither acetylations nor mutations of all the sites K5, K8 and K12 can induce a similar degree of array unfolding. The ubiquitous K(+), (as well as Rb(+) and Cs(+)) showed an unfolding effect on unmodified arrays almost similar to that of H4-K16 acetylation. We propose that K(+) (and Rb(+)/Cs(+)) binding to a site on the H2B histone (R96-L99) disrupts H4K16 ε-amino group binding to this specific site, thereby deranging H4 tail-mediated nucleosome-nucleosome stacking and that a similar mechanism operates in the case of H4-K16 acetylation. Inter-array self-association follows electrostatic behavior and is largely insensitive to the position or nature of the H4 tail charge modification.     

Histones H1 and H4 of surface-spread meiotic chromosomes

The chromatin conformation of somatic and meiotic chromosomes is, at least in part, a function of electrostatic nucleosome interactions that are mediated by transient acetylation of the histone H4 N-terminal domain and phosphorylation of histone H1. The distribution of those histones in the chromatin of meiotic chromosomes is reported here. Antibodies to testis-specific histone 1, H1t, detect H1t in the chromatin of mouse meiotic prophase chromosomes only after synapsis and synaptonemal complex (SC) assembly is completed and before core separation is initiated. The H1t protein is evenly distributed over euchromatin, heterochromatin and the SC. Antibodies to acetylated lysine residues 5, 12 or 16 of histone H4, indicate that the euchromatin is more acetylated than the centromeric heterochromatin. The pattern is most pronounced for acetylated residue 5 and least for 16. Antibodies to phosphorylated H1 epitopes do not react with chromatin but, instead, recognize the chromosome cores and SCs. Possibly these are not phosphorylated histone H1 epitopes, but SC proteins with similar potentially phosphorylatable sequences such as KTPTK of the synaptic protein Syn1.     

Histone H3 Lysine 56 Acetylation: A New Twist in the Chromosome Cycle

Several recent reports have identified lysine 56 (K56) as a novel site of acetylation in yeast histone H3. K56 acetylation is predicted to disrupt some of the histone-DNA interactions at the entry and exit points of the nucleosome core particle. This modification occurs in virtually all the newly synthesised histones that are deposited into chromatin during S-phase. Cells with mutations that block K56 acetylation show increased genome instability and hypersensitivity to genotoxic agents that interfere with replication. Removal of K56 acetylation takes place in the G2/M phase of the cell cycle and is dependent upon Hst3 and Hst4, two proteins that are related to the NAD+-dependent histone deacetylase Sir2. In response to DNA damage checkpoint activation during S-phase, expression of Hst3/Hst4 is delayed to extend the window of opportunity in which K56 acetylation can act in the DNA damage response. The high abundance of histone H3 K56 acetylation, its regulation and strategic location in the nucleosome core particle raise a number of fascinating issues that we discuss here.     

Characterization of histone H2A and H2B variants and their post-translational modifications by mass spectrometry

The nucleosome, the fundamental structural unit of chromatin, contains an octamer of core histones H3, H4, H2A, and H2B. Incorporation of histone variants alters the functional properties of chromatin. To understand the global dynamics of chromatin structure and function, analysis of histone variants incorporated into the nucleosome and their covalent modifications is required. Here we report the first global mass spectrometric analysis of histone H2A and H2B variants derived from Jurkat cells. A combination of mass spectrometric techniques, HPLC separations, and enzymatic digestions using endoproteinase Glu-C, endoproteinase Arg-C, and trypsin were used to identify histone H2A and H2B subtypes and their modifications. We identified nine histone H2A and 11 histone H2B subtypes, among them proteins that only had been postulated at the gene level. The two main H2A variants, H2AO and H2AC, as well as H2AL were either acetylated at Lys-5 or phosphorylated at Ser-1. For the replacement histone H2AZ, acetylation at Lys-4 and Lys-7 was found. The main histone H2B variant, H2BA, was acetylated at Lys-12, -15, and -20. The analysis of core histone subtypes with their modifications provides a first step toward an understanding of the functional significance of the diversity of histone structures.     

Dynamics of histone H3 acetylation in the nucleosome core during mouse pre-implantation development

In mammals, the time period that follows fertilization is characterized by extensive chromatin remodeling, which enables epigenetic reprogramming of the gametes. Major changes in chromatin structure persist until the time of implantation, when the embryo develops into a blastocyst, which comprises the inner cell mass and the trophectoderm. Changes in DNA methylation, histone variant incorporation, and covalent modifications of the histones tails have been intensively studied during pre-implantation development. However, modifications within the core of the nucleosomes have not been systematically analyzed. Here, we report the first characterization and temporal analysis of 3 key acetylated residues in the core of the histone H3: H3K64ac, H3K122ac, and H3K56ac, all located at structurally important positions close to the DNA. We found that all 3 acetylations occur during pre-implantation development, but with different temporal kinetics. Globally, H3K64ac and H3K56ac were detected throughout cleavage stages, while H3K122ac was only weakly detectable during this time. Our work contributes to the understanding of the contribution of histone modifications in the core of the nucleosome to the “marking” of the newly established embryonic chromatin and unveils new modification pathways potentially involved in epigenetic reprogramming.     

Structure of chromatin containing extensively acetylated H3 and H4

I have grown HeLa cells in 5 mM sodium n-butyrate leading to extensive in vivo histone acetylation, and have characterized the structure of chromatin containing the modified histones. Nuclear DNA in butyrate-treated cells is digested 5-10 fold more rapidly by DNAase I than the DNA of control cells. Staphylococcal nuclease degrades the two nuclear samples to acid-soluble material with identical rates; this nuclease, however, does excise nucleosomes with extensively acetylated histones from the nucleoprotein chain preferentially. The physical properties of unsheared chromatin and isolated core particles from control and butyrate-treated cells are closely similar, as are the rates of digestion of core particles from the two cell preparations by DNAase I. Determination of the relative susceptibilities of cleavage sites for DNAase I demonstrates that the site 60 bases from the ends of the DNA resistant in control cells, becomes susceptible to the nuclease in core particles containing acetylated histones. Similarly, the 5' terminal phosphate at the end of DNA in core prticles is removed by staphylococcal nuclease 2-3 fold faster in particles containing acetylated histones than in particles from control cells.     

Dynamics of histone acetylation in Saccharomyces cerevisiae

Rates of turnover for the posttranslational acetylation of core histones were measured in logarithmically growing yeast cells by radioactive acetate labeling to near steady-state conditions. On average, acetylation half-lives were approximately 15 min for histone H4, 10 min for histone H3, 4 min for histone H2B, and 5 min for histone H2A. These rates were much faster than the several hours that have previously been reported for the rate of general histone acetylation and deacetylation in yeast. The current estimates are in line with changes in histone acetylation detected directly at specific chromatin locations and the speed of changes in gene expression that can be observed. These results emphasize that histone acetylation within chromatin is subject to constant flux. Detailed analysis revealed that the turnover rates for acetylation of histone H3 are the same from mono- through penta-acetylated forms. A large fraction of acetylated histone H3, including possibly all tetra- and penta-acetylated forms, appears subject to acetylation turnover. In contrast, the rate of acetylation turnover for mono- and di-acetylated forms of histones H4 and H2B, and the fraction subject to acetylation turnover, was lower than for multi-acetylated forms of these histones. This difference may reflect the difference in location of these histones within the nucleosome, a difference in the spectrum of histone-specific acetylating and deacetylating enzymes, and a difference in the role of acetylation in different histones.     

Distinct acetylation of <Emphasis Type="Italic">Trypanosoma cruzi</Emphasis> histone H4 during cell cycle,parasite differentiation,and after DNA damage

Histones of trypanosomes are quite divergent when compared to histones of most eukaryotes. Nevertheless, the histone H4 of Trypanosoma cruzi, the protozoan that causes Chagas’ disease, is acetylated in the N terminus at lysines 4, 10, and 14. Here, we investigated the cellular distribution of histone H4 containing each one of these posttranslational modifications by using specific antibodies. Histone H4 acetylated at lysine 4 (H4-K4ac) is found in the entire nuclear space preferentially at dense chromatin regions, excluding the nucleolus of replicating epimastigote forms of the parasite. In contrast, histone H4 acetylated either at K10 or K14 is found at dispersed foci all over the nuclei and at the interface between dense and nondense chromatin areas as observed by ultrastructural immunocytochemistry. The level of acetylation at K4 decreases in nonreplicating forms of the parasites when compared to K10 and K14 acetylations. Antibodies recognizing the K14 acetylation strongly labeled cells at G2 and M stages of the cell cycle. Besides that, hydroxyurea synchronized parasites show an increased acetylation at K4, K10, and K14 after S phase. Moreover, we do not observed specific colocalization of K4 modifications with the major sites of RNA polymerase II. Upon γ-irradiation that stops parasite replication until the DNA is repaired, dense chromatin disappears and K4 acetylation decreases, while K10 and K14 acetylation increase. These results indicate that each lysine acetylation has a different role in T. cruzi. While K4 acetylation occurs preferentially in proliferating situations and accumulates in packed chromatin, K10 and K14 acetylations have a particular distribution probably at the boundaries between packed and unpacked chromatin. Sheila Cristina Nardelli and Julia Pinheiro Chagas da Cunha contributed equally to this work.     

Histone H4 K16Q mutation, an acetylation mimic, causes structural disorder of its N-terminal basic patch in the nucleosome

Histone tails and their posttranslational modifications play important roles in regulating the structure and dynamics of chromatin. For histone H4, the basic patch K(16)R(17)H(18)R(19) in the N-terminal tail modulates chromatin compaction and nucleosome sliding catalyzed by ATP-dependent ISWI chromatin remodeling enzymes while acetylation of H4 K16 affects both functions. The structural basis for the effects of this acetylation is unknown. Here, we investigated the conformation of histone tails in the nucleosome by solution NMR. We found that backbone amides of the N-terminal tails of histones H2A, H2B, and H3 are largely observable due to their conformational disorder. However, only residues 1-15 in H4 can be detected, indicating that residues 16-22 in the tails of both H4 histones fold onto the nucleosome core. Surprisingly, we found that K16Q mutation in H4, a mimic of K16 acetylation, leads to a structural disorder of the basic patch. Thus, our study suggests that the folded structure of the H4 basic patch in the nucleosome is important for chromatin compaction and nucleosome remodeling by ISWI enzymes while K16 acetylation affects both functions by causing structural disorder of the basic patch K(16)R(17)H(18)R(19).