Human DNA ligase I efficiently seals nicks in nucleosomes

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.

Phosphorylation of linker histones by DNA-dependent protein kinase is required for DNA ligase IV-dependent ligation in the presence of histone H1

DNA nonhomologous end-joining in vivo requires the DNA-dependent protein kinase (DNA-PK) and DNA ligase IV/XRCC4 (LX) complexes. Here, we have examined the impact of histone octamers and linker histone H1 on DNA end-joining in vitro. Packing of the DNA substrate into dinucleosomes does not significantly inhibit ligation by LX. However, LX ligation activity is substantially reduced by the incorporation of linker histones. This inhibition is independent of the presence of core histone octamers and cannot be restored by addition of Ku alone but can be partially rescued by DNA-PK. The kinase activity of DNA-PK is essential for the recovery of end-joining. DNA-PK efficiently phosphorylates histone H1. Phosphorylated histone H1 has a reduced affinity for DNA and a decreased capacity to inhibit end-joining. Our findings raise the possibility that DNA-PK may act as a linker histone kinase by phosphorylating linker histones in the vicinity of a DNA break and coupling localized histone H1 release from DNA ends, with the recruitment of LX to carry out double-stranded ligation. Thus, by using histone H1-bound DNA as a template, we have reconstituted the end-joining step of DNA nonhomologous end-joining in vitro with a requirement for DNA-PK.

The core histone N-terminal tail domains negatively regulate binding of transcription factor IIIA to a nucleosome containing a 5S RNA gene via a novel mechanism

Reconstitution of a DNA fragment containing a 5S RNA gene from Xenopus borealis into a nucleosome greatly restricts binding of the primary 5S transcription factor, TFIIIA. Consistent with transcription experiments using reconstituted templates, removal of the histone tail domains stimulates TFIIIA binding to the 5S nucleosome greater than 100-fold. However, we show that tail removal increases the probability of 5S DNA unwrapping from the core histone surface by only approximately fivefold. Moreover, using site-specific histone-to-DNA cross-linking, we show that TFIIIA binding neither induces nor requires nucleosome movement. Binding studies with COOH-terminal deletion mutants of TFIIIA and 5S nucleosomes reconstituted with native and tailless core histones indicate that the core histone tail domains play a direct role in restricting the binding of TFIIIA. Deletion of only the COOH-terminal transcription activation domain dramatically stimulates TFIIIA binding to the native nucleosome, while further C-terminal deletions or removal of the tail domains does not lead to further increases in TFIIIA binding. We conclude that the unmodified core histone tail domains directly negatively influence TFIIIA binding to the nucleosome in a manner that requires the C-terminal transcription activation domain of TFIIIA. Our data suggest an additional mechanism by which the core histone tail domains regulate the binding of trans-acting factors in chromatin.

Repair and Genetic Consequences of Endogenous DNA Base Damage in Mammalian Cells

Living organisms dependent on water and oxygen for their existence face the major challenge of faithfully maintaining their genetic material under a constant attack from spontaneous hydrolysis and active oxygen species and from other intracellular metabolites that can modify DNA bases. Repair of endogenous DNA base damage by the ubiquitous base-excision repair pathway largely accounts for the significant turnover of DNA even in nonreplicating cells, and must be sufficiently accurate and efficient to preserve genome stability compatible with long-term cellular viability. The size of the mammalian genome has necessitated an increased complexity of repair and diversification of key enzymes, as revealed by gene knock-out mouse models. The genetic instability characteristic of cancer cells may be due, in part, to mutations in genes whose products normally function to ensure DNA integrity.

The histone octamer is invisible when NF-kappaB binds to the nucleosome

The transcription factor NF-kappaB is involved in the transcriptional control of more than 150 genes, but the way it acts at the level of nucleosomal templates is not known. Here we report on a study examining the interaction of NF-kappaB p50 with its DNA recognition sequence in a positioned nucleosome. We demonstrate that NF-kappaB p50 was able to bind to the nucleosome with an apparent association constant close to that for free DNA. In agreement with this, the affinity of NF-kappaB p50 binding does not depend on the localization of its recognition sequence relative to the nucleosome dyad axis. In addition, the binding of NF-kappaB p50 does not induce eviction of histones and does not perturb the overall structure of the nucleosome. The NF-kappaB p50-nucleosome complex exhibits, however, local structural alterations within the NF-kappaB p50 recognition site. Importantly, these alterations were very similar to those found in the NF-kappaB p50-DNA complex. Our data suggest that NF-kappaB p50 can accommodate the distorted, bent DNA within the nucleosome. This peculiar property of NF-kappaB p50 might have evolved to meet the requirements for its function as a central switch for stress responses.

Structural features of transcription factor IIIA bound to a nucleosome in solution

Assembly of a DNA fragment containing a Xenopus borealis somatic-type 5S RNA gene into a nucleosome greatly restricts binding of the 5S gene-specific transcription factor IIIA (TFIIIA) to the 5S internal promoter. However, TFIIIA binds with high affinity to 5S nucleosomes lacking the N-terminal tail domains of the core histones or to nucleosomes in which these domains are hyperacetylated. The degree to which tail acetylation or removal improves TFIIIA binding cannot be simply explained by a commensurate change in the general accessibility of nucleosomal DNA. In order to investigate the molecular basis of how TFIIIA binds to the nucleosome and to ascertain if binding involves all nine zinc fingers and/or displacement of histone-DNA interactions, we examined the TFIIIA-nucleosome complex by hydroxyl radical footprinting and site-directed protein-DNA cross-linking. Our data reveal that the first six fingers of TFIIIA bind and displace approximately 20 bp of histone-DNA interactions at the periphery of the nucleosome, while binding of fingers 7 to 9 appears to overlap with histone-DNA interactions. Molecular modeling based on these results and the crystal structures of a nucleosome core and a TFIIIA-DNA cocomplex yields a precise picture of the ternary complex and a potentially important intermediate in the transition from naïve chromatin structure to productive polymerase III transcription complex.

Nucleosome sliding induced by the xMi-2 complex does not occur exclusively via a simple twist-diffusion mechanism

ATP-dependent chromatin remodeling complexes can induce the translocation (sliding) of nucleosomes in cis along DNA, but the mechanism by which sliding occurs is not well defined. We previously presented evidence that sliding induced by the human SWI/SNF complex does not occur solely via a proposed "twist-diffusion" mechanism whereby the DNA rotates about its helical axis without displacement from the surface of the nucleosome (Aoyagi, S., and Hayes, J. J. (2002) Mol. Cell. Biol. 22, 7484-7490). Here we examined whether the Xenopus Mi-2 nucleosome remodeling complex induces nucleosome sliding via a twist-diffusion mechanism with nucleosomes assembled onto DNA templates containing branched DNA structures expected to sterically hinder rotation of the DNA helix on the nucleosome surface. We find that the branched DNA-containing nucleosomes undergo xMi-2-catalyzed sliding at a rate and extent identical to that of nucleosomes assembled on native DNA fragments. These results indicate that both the hSWI/SNF and xMi-2 complexes induce nucleosome sliding via a mechanism(s) other than simple twist diffusion and are consistent with models in which the DNA largely maintains its rotational orientation with respect to the histone surface.

Suppressed catalytic activity of base excision repair enzymes on rotationally positioned uracil in nucleosomes

The majority of DNA in eukaryotic cells exists in the highly condensed structural hierarchy of chromatin, which presents a challenge to DNA repair enzymes in that recognition, incision, and restoration of the original sequence at most sites must take place within these structural constraints. To test base excision repair (BER) activities on chromatin substrates, an in vitro system was developed that uses human uracil DNA glycosylase (UDG), apyrimidinic/apurinic endonuclease (APE), and DNA polymerase beta (pol beta) on homogeneously damaged, rotationally positioned DNA in nucleosomes. We find that UDG and APE carry out their combined catalytic activities with reduced efficiency on nucleosome substrates ( approximately 10% of that on naked DNA). Furthermore, these enzymes distinguish between two different rotational settings of the lesion on the histone surface, showing a 2- to 3-fold difference in activity between uracil facing "toward" and "away from" the histones. However, UDG and APE will digest such substrates to completion in a concentration-dependent manner. Conversely, the synthesis activity of pol beta is inhibited completely by nucleosome substrates and is independent of enzyme concentration. These results suggest that the first two steps of BER, UDG and APE, may occur "unassisted" in chromatin, whereas downstream factors in this pathway (i.e., pol beta) may require nucleosome remodeling for efficient DNA BER in at least some regions of chromatin in eukaryotic cells.

Xenopus transcription factor IIIA and the 5S nucleosome: development of a useful in vitro system

5S RNA genes in Xenopus are regulated during development via a complex interplay between assembly of repressive chromatin structures and productive transcription complexes. Interestingly, 5S genes have been found to harbor powerful nucleosome positioning elements and therefore have become an important model system for reconstitution of eukaryotic genes into nucleosomes in vitro. Moreover, the structure of the primary factor initiating transcription of 5S DNA, transcription factor IIIA, has been extensively characterized. This has allowed for numerous studies of the effect of nucleosome assembly and histone modifications on the DNA binding activity of a transcription factor in vitro. For example, linker histones bind 5S nucleosomes and repress TFIIIA binding in vitro in a similar manner to that observed in vivo. In addition, TFIIIA binding to nucleosomes assembled with 5S DNA is stimulated by acetylation or removal of the core histone tail domains. Here we review the development of the Xenopus 5S in vitro system and discuss recent results highlighting new aspects of transcription factor - nucleosome interactions,

Structure and dynamic behavior of nucleosomes

Genetic studies have identified residues in the structured regions of the histones that are critically involved in the formation of heterochromatin. Any investigation of the events that regulate access to the chromatin substrate must take into account the dynamic nature of the nucleosome, and the regulated inter-conversion between various levels of chromatin higher-order structure.

Evidence for DNA translocation by the ISWI chromatin-remodeling enzyme

The ISWI proteins form the catalytic core of a subset of ATP-dependent chromatin-remodeling activities. Here, we studied the interaction of the ISWI protein with nucleosomal substrates. We found that the ability of nucleic acids to bind and stimulate the ATPase activity of ISWI depends on length. We also found that ISWI is able to displace triplex-forming oligonucleotides efficiently when they are introduced at sites close to a nucleosome but successively less efficiently 30 to 60 bp from its edge. The ability of ISWI to direct triplex displacement was specifically impeded by the introduction of 5- or 10-bp gaps in the 3'-5' strand between the triplex and the nucleosome. In combination, these observations suggest that ISWI is a 3'-5'-strand-specific, ATP-dependent DNA translocase that may be capable of forcing DNA over the surface of nucleosomes.

Crystal structures of nucleosome core particles in complex with minor groove DNA-binding ligands

We determined the crystal structures of three nucleosome core particles in complex with site-specific DNA-binding ligands, the pyrrole-imidazole polyamides. While the structure of the histone octamer and its interaction with the DNA remain unaffected by ligand binding, nucleosomal DNA undergoes significant structural changes at the ligand-binding sites and in adjacent regions to accommodate the ligands. Our findings suggest that twist diffusion occurs over long distances through tightly bound nucleosomal DNA. This may be relevant to the mechanism of ATP-dependent and spontaneous nucleosome translocation, and to the effect of bound factors on nucleosome dynamics.

Histone H3 and the histone acetyltransferase Hat1p contribute to DNA double-strand break repair

The modification of newly synthesized histones H3 and H4 by type B histone acetyltransferases has been proposed to play a role in the process of chromatin assembly. The type B histone acetyltransferase Hat1p and specific lysine residues in the histone H3 NH(2)-terminal tail (primarily lysine 14) are redundantly required for telomeric silencing. As many gene products, including other factors involved in chromatin assembly, have been found to participate in both telomeric silencing and DNA damage repair, we tested whether mutations in HAT1 and the histone H3 tail were also sensitive to DNA-damaging agents. Indeed, mutations both in specific lysine residues in the histone H3 tail and in HAT1 resulted in sensitivity to methyl methanesulfonate. The DNA damage sensitivity of the histone H3 and HAT1 mutants was specific for DNA double-strand breaks, as these mutants were sensitive to the induction of an exogenous restriction endonuclease, EcoRI, but not to UV irradiation. While histone H3 mutations had minor effects on nonhomologous end joining, the primary defect in the histone H3 and HAT1 mutants was in the recombinational repair of DNA double-strand breaks. Epistasis analysis indicates that the histone H3 and HAT1 mutants may influence DNA double-strand break repair through Asf1p-dependent chromatin assembly.

hSWI/SNF-catalyzed nucleosome sliding does not occur solely via a twist-diffusion mechanism

Nucleosome remodeling by the hSWI/SNF complex and other chromatin remodeling complexes can cause translocation (sliding) of the histone octamer in cis along DNA. Structural and biochemical evidence suggest that sliding involves a DNA twist-diffusion process whereby the DNA rotates about the helical axis without major displacement from the surface of the nucleosome and that this process may be driven by torsional stress within the DNA. We report that hSWI/SNF efficiently catalyzes sliding of nucleosomes containing branched DNAs as steric blocks to twist-diffusion and a nick to allow dissipation of torsional stress within the nucleosome. These results suggest that SWI/SNF-catalyzed nucleosome sliding does not occur exclusively via a simple twist-diffusion mechanism and support models in which the DNA maintains its rotational orientation to and is at least partially separated from the histone surface during nucleosome translocation.

DNA base excision repair of uracil residues in reconstituted nucleosome core particles

The human base excision repair machinery must locate and repair DNA base damage present in chromatin, of which the nucleosome core particle is the basic repeating unit. Here, we have utilized fragments of the Lytechinus variegatus 5S rRNA gene containing site-specific U:A base pairs to investigate the base excision repair pathway in reconstituted nucleosome core particles in vitro. The human uracil-DNA glycosylases, UNG2 and SMUG1, were able to remove uracil from nucleosomes. Efficiency of uracil excision from nucleosomes was reduced 3- to 9-fold when compared with naked DNA, and was essentially uniform along the length of the DNA substrate irrespective of rotational position on the core particle. Furthermore, we demonstrate that the excision repair pathway of an abasic site can be reconstituted on core particles using the known repair enzymes, AP-endonuclease 1, DNA polymerase beta and DNA ligase III. Thus, base excision repair can proceed in nucleosome core particles in vitro, but the repair efficiency is limited by the reduced activity of the uracil-DNA glycosylases and DNA polymerase beta on nucleosome cores.

Flap endonuclease 1 efficiently cleaves base excision repair and DNA replication intermediates assembled into nucleosomes

Flap Endonuclease 1 (FEN1) plays important roles both in DNA replication and in base excision repair (BER). However, in both processes FEN1 substrates are likely to be assembled into chromatin. In order to examine how FEN1 is able to work within chromatin, we prepared model nucleosome substrates containing FEN1-cleavable DNA flaps. We find that human FEN1 binds and cleaves such substrates with efficiencies similar to that displayed with naked DNA. Moreover, we demonstrate that both FEN1 and human DNA ligase I can operate successively on DNA within the same nucleosome. These results suggest that some BER steps may not require nucleosome remodeling in vivo and that FEN 1 activity during Okazaki fragment processing can occur on nucleosomal substrates.

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

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

Chromatin structure and dynamics: state-of-the-art

A meeting entitled "Chromatin Structure and Dynamics: State-of-the-Art" organized by Jordanka Zlatanova and Sanford Leuba was held at the NIH from May 8-10, 2002. It was a timely meeting and addressed our current understanding of chromatin structure, dynamics, and function.

Nucleosome remodeling by the human SWI/SNF complex requires transient global disruption of histone-DNA interactions

We utilized a site-specific cross-linking technique to investigate the mechanism of nucleosome remodeling by hSWI/SNF. We found that a single cross-link between H2B and DNA virtually eliminates the accumulation of stably remodeled species as measured by restriction enzyme accessibility assays. However, cross-linking the histone octamer to nucleosomal DNA does not inhibit remodeling as monitored by DNase I digestion assays. Importantly, we found that the restriction enzyme-accessible species can be efficiently cross-linked after remodeling and that the accessible state does not require continued ATP hydrolysis. These results imply that the generation of stable remodeled states requires at least transient disruption of histone-DNA interactions throughout the nucleosome, while hSWI/SNF-catalyzed disruption of just local histone-DNA interactions yields less-stable remodeled states that still display an altered DNase I cleavage pattern. The implications of these results for models of the mechanism of SWI/SNF-catalyzed nucleosome remodeling are discussed.

Nucleotide excision repair and chromatin remodeling

The organization of DNA within eukaryotic cell nuclei poses special problems and opportunities for the cell. For example, assembly of DNA into chromatin is thought to be a principle mechanism by which adventitious general transcription is repressed. However, access to genomic DNA for events such as DNA repair must be facilitated by energy-intensive processes that either directly alter chromatin structure or impart post-translational modifications, leading to increased DNA accessibility. The assembly of DNA into chromatin affects both the incidence of damage to DNA and repair of that damage. Correction of most damage to DNA caused by UV irradiation occurs via the nucleotide excision repair (NER) process. NER requires extensive involvement of large multiprotein complexes with relatively large stretches of DNA. Here, we review recent evidence suggesting that at least some steps of NER require ATP-dependent chromatin remodeling activities while perhaps others do not.

When repair meets chromatin. First in series on chromatin dynamics

In eukaryotic cells, the inheritance of both the DNA sequence and its organization into chromatin is critical to maintain genome stability. This maintenance is challenged by DNA damage. To fully understand how the cell can tolerate genotoxic stress, it is necessary to integrate knowledge of the nature of DNA damage, its detection and its repair within the chromatin environment of a eukaryotic nucleus. The multiplicity of the DNA damage and repair processes, as well as the complex nature of chromatin, have made this issue difficult to tackle. Recent progress in each of these areas enables us to address, both at a molecular and a cellular level, the importance of inter-relationships between them. In this review we revisit the 'access, repair, restore' model, which was proposed to explain how the conserved process of nucleotide excision repair operates within chromatin. Recent studies have identified factors potentially involved in this process and permit refinement of the basic model. Drawing on this model, the chromatin alterations likely to be required during other processes of DNA damage repair, particularly double-strand break repair, are discussed and recently identified candidates that might perform such alterations are highlighted.

Preferential interaction of the core histone tail domains with linker DNA

Within chromatin, the core histone tail domains play critical roles in regulating the structure and accessibility of nucleosomal DNA within the chromatin fiber. Thus, many nuclear processes are facilitated by concomitant posttranslational modification of these domains. However, elucidation of the mechanisms by which the tails mediate such processes awaits definition of tail interactions within chromatin. In this study we have investigated the primary DNA target of the majority of the tails in mononucleosomes. The results clearly show that the tails bind preferentially to "linker" DNA, outside of the DNA encompassed by the nucleosome core. These results have important implications for models of tail function within the chromatin fiber and for in vitro structural and functional studies using nucleosome core particles.

Nucleosomes and the chromatin fiber

During the past year and a half, significant progress has been made in understanding the structure and dynamics of nucleosomes and the chromatin fiber, the mechanism of action of the core histone amino termini, the structure and function of histone variants, and the function of linker histones in the chromatin fiber.