Role of histone tails in structural stability of the nucleosome

Histone tails play an important role in nucleosome structure and dynamics. Here we investigate the effect of truncation of histone tails H3, H4, H2A and H2B on nucleosome structure with 100 ns all-atom molecular dynamics simulations. Tail domains of H3 and H2B show propensity of α-helics formation during the intact nucleosome simulation. On truncation of H4 or H2B tails no structural change occurs in histones. However, H3 or H2A tail truncation results in structural alterations in the histone core domain, and in both the cases the structural change occurs in the H2Aα3 domain. We also find that the contacts between the histone H2A C terminal docking domain and surrounding residues are destabilized upon H3 tail truncation. The relation between the present observations and corresponding experiments is discussed.     

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.     

Role of histone tails in the conformation and interactions of nucleosome core particles

The goal of this work was to test the role of the histone tails in the emergence of attractive interactions between nucleosomes above a critical salt concentration that corresponds to the complete tail extension outside the nucleosome [Mangenot, S., et al (2002) Biophys. J. 82, 345-356; Mangenot, S., et al (2002) Eur. Phys. J. E 7, 221-231]. Small angle X-ray scattering experiments were performed in parallel with intact and trypsin tail-deleted nucleosomes with 146 +/- 3 bp DNA. We varied the monovalent salt concentration from 10 to 300 monovalent salt concentration and followed the evolution of (i) the second virial coefficient that characterizes the interactions between particles and (ii) the conformation of the particle. The attractive interactions do not emerge in the absence of the tails, which validates the proposed hypothesis.     

Use of selectively trypsinized nucleosome core particles to analyze the role of the histone "tails" in the stabilization of the nucleosome

Using immobilized trypsin and an appropriate fractionation procedure, we have been able to prepare, for the first time, nucleosome core particles containing selectively trypsinized histone domains. The particles thus obtained: [(H3T-H4T)2-2(H2AT-H2BT)].DNA; [(H3-H4)2-2(H2AT-H2BT)].DNA; [H3T-H4T)2-2(H2A-H2B)].DNA (where T means trypsinized), together with the non-trypsinized controls have been characterized using the following techniques: analytical ultracentrifugation, circular dichroism, thermal denaturation and DNAse I digestion. The major aim of this study was to analyze the role of the amino-terminal regions (the histone "tails") on the stability of the nucleosome in solution. The data obtained from this analysis clearly show that stability of the nucleosome core particle to dissociation (below a salt concentration of 0.7 M-NaCl) is not affected by the presence or the absence of any of the N-terminal regions of the histones. Furthermore, these histone regions make very little contribution, if any, to the conformational transition that nucleosomes undergo in this range of salt concentrations. They play, however, a very important role in determining the thermal stability of the particle, as reflected in the dramatic alterations exhibited by the melting profiles upon selective removal of these tails by trypsinization. The melting data can be explained by a simple hypothesis that ascribes interaction of H2A/H2B and H3/H4 tails to particular regions of the nucleosomal DNA.     

Influence of DNA topology and histone tails in nucleosome organization on pBR322 DNA.

Recently, we have found that the assembly of nucleosomes reconstituted on negatively supercoiled DNA is cooperative. In the present paper the role of DNA topology and of histone tails in nucleosome assembly was explored. Reconstituted minichromosomes on relaxed DNA at different histone/DNA ratios (R) were assayed by topological analysis and electron microscopy visualization. Both methods show a linear relationship between average nucleosome number (N) and R. This suggests that in the case of relaxed DNA, cooperative internucleosomal interactions are small or absent. The influence of histone tails in nucleosome assembly was studied on minichromosomes reconstituted with trypsinized histone octamer on negatively supercoiled DNA by topological analysis. The topoisomers distribution, after trypsinization, dramatically changes, indicating that nucleosome-nucleosome interactions are remarkably decreased. These results show that, in chromatin folding, in addition to the well known role of histone H1, the interactions between histone octamer tails and DNA are also of importance.     

DNA sequence-dependent contributions of core histone tails to nucleosome stability: differential effects of acetylation and proteolytic tail removal

Modulation of nucleosome stability in chromatin plays an important role in eukaryotic gene expression. The core histone N-terminal tail domains are believed to modulate the stability of wrapping nucleosomal DNA and the stability of the chromatin filament. We analyzed the contribution of the tail domains to the stability of nucleosomes containing selected DNA sequences that are intrinsically straight, curved, flexible, or inflexible. We find that the presence of the histone tail domains stabilizes nucleosomes containing DNA sequences that are intrinsically straight or curved. However, the tails do not significantly contribute to the free energy of nucleosome formation with flexible DNA. Interestingly, hyperacetylation of the core histone tail domains does not recapitulate the effect of tail removal by limited proteolysis with regard to nucleosome stability. We find that acetylation of the tails has the same minor effect on nucleosome stability for all the selected DNA sequences. A comparison of histone partitioning between long donor chromatin, acceptor DNA, and free histones in solution shows that the core histone tails mediate internucleosomal interactions within an H1-depleted chromatin fiber amounting to an average free energy of about 1 kcal/mol. Thus, such interactions would be significant with regard to the free energies of sequence-dependent nucleosome positioning. Last, we analyzed the contribution of the H2A/H2B dimers to nucleosome stability. We find that the intact nucleosome is stabilized by 900 cal/mol by the presence of the dimers regardless of sequence. The biological implications of these observations are discussed.     

Regulated nucleosome mobility and the histone code

Post-translational modifications of the histone tails are correlated with distinct chromatin states that regulate access to DNA. Recent proteomic analyses have revealed several new modifications in the globular nucleosome core, many of which lie at the histone-DNA interface. We interpret these modifications in light of previously published data and propose a new and testable model for how cells implement the histone code by modulating nucleosome dynamics.     

Enzymic acetylation of nucleosome histone.

Rat liver chromatin prepared from purified nuclei catalyzed the acetylation of histones in nucleosomes at the same level as that of nuclei. The activity of histone acetyltransferase in chromatin was destroyed by heat treatment at 65 degrees C for 5 min. Histones in exogenously added nucleosomes also served as substrate for the enzyme. The sites of acetylation in the nucleosomes appeared to be in the trypsin-digestable N-terminal regions of histones H4, H3, and H2A, as has been reported in an in vivo system.     

Regulation of histone synthesis and nucleosome assembly

Histone deposition onto nascent DNA is the first step in the process of chromatin assembly during DNA replication. The process of nucleosome assembly represents a daunting task for S-phase cells, partly because cells need to rapidly package nascent DNA into nucleosomes while avoiding the generation of excess histones. Consequently, cells have evolved a number of nucleosome assembly factors and regulatory mechanisms that collectively function to coordinate the rates of histone and DNA synthesis during both normal cell cycle progression and in response to conditions that interfere with DNA replication.     

Acetylation increases access of remodelling complexes to their nucleosome targets to enhance initiation of V(D)J recombination

Targeted chromatin remodelling is essential for many nuclear processes, including the regulation of V(D)J recombination. ATP-dependent nucleosome remodelling complexes are important players in this process whose activity must be tightly regulated. We show here that histone acetylation regulates nucleosome remodelling complex activity to boost RAG cutting during the initiation of V(D)J recombination. RAG cutting requires nucleosome mobilization from recombination signal sequences. Histone acetylation does not stimulate nucleosome mobilization per se by CHRAC, ACF or their catalytic subunit, ISWI. Instead, we find the more open structure of acetylated chromatin regulates the ability of nucleosome remodelling complexes to access their nucleosome templates. We also find that bromodomain/acetylated histone tail interactions can contribute to this targeting at limited concentrations of remodelling complex. We therefore propose that the changes in higher order chromatin structure associated with histone acetylation contribute to the correct targeting of nucleosome remodelling complexes and this is a novel way in which histone acetylation can modulate remodelling complex activity.     

Differential dissociation of histone tails from core chromatin

The dissociation of the trypsin-sensitive basic tails of the core histones in core chromatin has been followed as a function of [NaCl] using proton NMR spectroscopy. The tails dissociate in a highly cooperative all or none manner over the salt concentration range 0.2-0.6 M, that is, below the salt concentration required to dissociate the complete molecule. Assuming that each basic tail dissociates independently, the total number of salt linkages involved in binding the tails to DNA is 103. This equals the number of basic side chains in the tails of an octamer. The standard free energy of dissociation, delta G degree, in 1 M NaCl at 297 K is 3.6 kcal/mol. Temperature had no effect on the extent of dissociation up to 45 degrees C. However, between 45 and 65 degrees C, where the premelting transition in the core chromatin occurs, the tails dissociated completely. Dissociation of the tails was associated with a conformational transition in the DNA consistent with loss of supercoiling. From this, and the results of a previous study, it can be shown that the structured, trypsin-resistant domain of each core histone octamer makes 100 salt linkages to DNA. Thus, in 10 mM salt, each core octamer makes a total of 203 salt linkages to DNA.     

PARP1 ADP-ribosylates lysine residues of the core histone tails

The chromatin-associated enzyme PARP1 has previously been suggested to ADP-ribosylate histones, but the specific ADP-ribose acceptor sites have remained enigmatic. Here, we show that PARP1 covalently ADP-ribosylates the amino-terminal histone tails of all core histones. Using biochemical tools and novel electron transfer dissociation mass spectrometric protocols, we identify for the first time K13 of H2A, K30 of H2B, K27 and K37 of H3, as well as K16 of H4 as ADP-ribose acceptor sites. Multiple explicit water molecular dynamics simulations of the H4 tail peptide into the catalytic cleft of PARP1 indicate that two stable intermolecular salt bridges hold the peptide in an orientation that allows K16 ADP-ribosylation. Consistent with a functional cross-talk between ADP-ribosylation and other histone tail modifications, acetylation of H4K16 inhibits ADP-ribosylation by PARP1. Taken together, our computational and experimental results provide strong evidence that PARP1 modifies important regulatory lysines of the core histone tails.     

Complicated tails: histone modifications and the DNA damage response

In recent years, several ATP-dependent chromatin-remodeling complexes and covalent histone modifications have been implicated in the response to double-stranded DNA breaks (DSBs). When a DSB occurs, cells must identify the DSB, activate the DNA damage checkpoint, and repair the break. Chromatin modification appears to be important but not essential for each of these processes, yet its precise mechanistic roles are only beginning to come into focus. Here, we discuss the role of chromatin in signaling by the DNA damage checkpoint pathway.     

Base excision repair in nucleosomes lacking histone tails

Recently, we developed an in vitro system using human uracil DNA glycosylase (UDG), AP endonuclease (APE), DNA polymerase beta (pol beta) and rotationally positioned DNA containing a single uracil associated with a 'designed' nucleosome, to test short-patch base excision repair (BER) in chromatin. We found that UDG and APE carry out their catalytic activities with reduced efficiency on nucleosome substrates, showing a distinction between uracil facing 'out' or 'in' from the histone surface, while DNA polymerase beta (pol beta) is completely inhibited by nucleosome formation. In this report, we tested the inhibition of BER enzymes by the N-terminal 'tails' of core histones that take part in both inter- and intra-nucleosome interactions, and contain sites of post-translational modifications. Histone tails were removed by limited trypsin digestion of 'donor' nucleosome core particles and histone octamers were exchanged onto a nucleosome-positioning DNA sequence containing a single G:U mismatch. The data indicate that UDG and APE activities are not significantly enhanced with tailless nucleosomes, and the distinction between rotational settings of uracil on the histone surface is unaffected. More importantly, the inhibition of pol beta activity is not relieved by removal of the histone tails, even though these tails interact with DNA in the G:U mismatch region. Finally, inclusion of X-ray cross complement group protein 1 (XRCC1) or Werner syndrome protein (WRN) had no effect on the BER reactions. Thus, additional activities may be required in cells for efficient BER of at least some structural domains in chromatin.