Synergistic effects of H3 and H4 nucleosome tails on structure and dynamics of a lesion-containing DNA: Binding of a displaced lesion partner base to the H3 tail for GG-NER recognition

Local Alteration of Ionic Strength in a Nucleosome Core Particle and Its Effect on N7-Methyl-2'-deoxyguanosine Depurination

Positively charged N-terminal histone tails play important roles in maintaining the nucleosome (and chromatin) structure and function. Charge alteration, including those imposed by post-translational modifications, impacts chromatin dynamics, protein binding, and the fate of DNA damage. There is evidence that N-terminal histone tails affect the local ionic environment within a nucleosome core particle (NCP), but this phenomenon is not well understood. Determining the modulation of the local ionic environment within an NCP by histone tails could help uncover the underlying mechanisms of their functions and effects. Utilizing bottom-up syntheses of NCPs containing wild-type or mutated histones and a fluorescent probe that is sensitive to the local ionic environment, we show that interaction with positively charged N-terminal tails increases the local ionic strength near nucleosomal DNA. The effect is diminished by replacing positively charged residues with neutral ones or deleting a tail in its entirety. Replacing the fluorescent probe with the major DNA methylation product, N7-methyl-2'-deoxyguanosine (MdG), revealed changes in the depurination rate constant varying inversely with local ionic strength. These data indicate that the MdG hydrolysis rates depend on and also inform on local ionic strength in an NCP. Overall, histone tail charge contributes to the complexity of the NCP structure and function by modulating the local ionic strength.

Molecular dynamics simulations reveal how H3K56 acetylation impacts nucleosome structure to promote DNA exposure for lesion sensing

The first order of DNA packaging is the nucleosome with the DNA wrapped around the histone octamer. This leaves the nucleosomal DNA with access restrictions, which impose a significant barrier to repair of damaged DNA. The efficiency of DNA repair has been related to nucleosome structure and chromatin status, which is modulated in part by post-translational modifications (PTMs) of histones. Numerous studies have suggested a role for acetylation of lysine at position 56 of the H3 histone (H3K56ac) in various DNA transactions, including the response to DNA damage and its association with human cancer. Biophysical studies have revealed that H3K56ac increases DNA accessibility by facilitating spontaneous and transient unwrapping motions of the DNA ends. However, how this acetylation mark modulates nucleosome structure and dynamics to promote accessibility to the damaged DNA for repair factors and other proteins is still poorly understood. Here, we utilize approximately 5-6 microseconds of atomistic molecular dynamics simulations to delineate the impact of H3K56 acetylation on the nucleosome structure and dynamics, and to elucidate how these nucleosome properties are further impacted when a bulky benzo[a]pyrene-derived DNA lesion is placed near the acetylation site. Our findings reveal that H3K56ac alone induces considerable disturbance to the histone-DNA/histone-histone interactions, and amplifies the distortions imposed by the presence of the lesion. Our work highlights the important role of H3K56 acetylation in response to DNA damage and depicts how access to DNA lesions by the repair machinery can be facilitated within the nucleosome via a key acetylation event.

A Dynamic View of the Interaction of Histone Tails with Clustered Abasic Sites in a Nucleosome Core Particle

Apurinic/apyrimidinic sites are the most common forms of DNA damage under physiological conditions, yet their structural and dynamical behavior within nucleosome core particles has just begun to be investigated and is dramatically different from that of abasic sites in B-DNA. Clusters of two or more abasic sites are repaired even less efficiently and hence constitute hot spots of high mutagenicity notably due to enhanced double-strand break formation. On the basis of an X-ray structure of a 146 bp DNA wrapped onto a histone core, we investigate the structural behavior of two bistranded abasic sites positioned at mutational hot spots during microsecond-range molecular dynamics simulations. Our simulations allow us to probe interactions of histone tails at clustered abasic site locations, with a definitive assignment of the key residues involved in the NCP-catalyzed formation of DNA-protein cross-linking in line with recent experimental findings, and pave the way for a systematic assessment of the response of histone tails to DNA lesions.

Nucleosome Core Particles Lacking H2B or H3 Tails Are Altered Structurally and Have Differential Base Excision Repair Fingerprints

A recently discovered post-translational modification of histone proteins is the irreversible proteolytic clipping of the histone N-terminal tail domains. This modification is involved in the regulation of various biological processes, including the DNA damage response. In this work, we used chemical footprinting to characterize the structural alterations to nucleosome core particles (NCPs) that result from a lack of a histone H2B or H3 tail. We also examine the influence of these histone tails on excision of the mutagenic lesion 1,N⁶-ethenoadenine (εA) by the repair enzyme alkyladenine DNA glycosylase. We found that the absence of the H2B or H3 tail results in altered DNA periodicity relative to that of native NCPs. We correlated these structural alterations to εA excision by utilizing a global analysis of 21 εA sites in NCPs and unincorporated duplex DNA. In comparison to native NCPs, there is enhanced excision of εA in tailless H2B NCPs in regions that undergo DNA unwrapping. This enhanced excision is not observed for tailless H3 NCPs; rather, excision is inhibited in more static areas of the NCP not prone to unwrapping. Our results support in vivo observations of alkylation damage profiles and the potential role of tail clipping as a mechanism for overcoming physical obstructions caused by packaging in NCPs but also reveal the potential inhibition of repair by tail clipping in some locations. Taken together, these results further our understanding of how base excision repair can be facilitated or diminished by histone tail removal and contribute to our understanding of the underlying mechanism that leads to mutational hot spots.

Breaths, Twists, and Turns of Atomistic Nucleosomes

Gene regulation programs establish cellular identity and rely on dynamic changes in the structural packaging of genomic DNA. The DNA is packaged in chromatin, which is formed from arrays of nucleosomes displaying different degree of compaction and different lengths of inter-nucleosomal linker DNA. The nucleosome represents the repetitive unit of chromatin and is formed by wrapping 145-147 basepairs of DNA around an octamer of histone proteins. Each of the four histones is present twice and has a structured core and intrinsically disordered terminal tails. Chromatin dynamics are triggered by inter- and intra-nucleosome motions that are controlled by the DNA sequence, the interactions between the histone core and the DNA, and the conformations, positions, and DNA interactions of the histone tails. Understanding chromatin dynamics requires studying all these features at the highest possible resolution. For this, molecular dynamics simulations can be used as a powerful complement or alternative to experimental approaches, from which it is often very challenging to characterize the structural features and atomic interactions controlling nucleosome motions. Molecular dynamics simulations can be performed at different resolutions, by coarse graining the molecular system with varying levels of details. Here we review the successes and the remaining challenges of the application of atomic resolution simulations to study the structure and dynamics of nucleosomes and their complexes with interacting partners.

Comparison of the Base Excision and Direct Reversal Repair Pathways for Correcting 1,N6-Ethenoadenine in Strongly Positioned Nucleosome Core Particles

1,N⁶-ethenoadenine (εA) is a mutagenic lesion and biomarker observed in numerous cancerous tissues. Two pathways are responsible for its repair: base excision repair (BER) and direct reversal repair (DRR). Alkyladenine DNA glycosylase (AAG) is the primary enzyme that excises εA in BER, generating stable intermediates that are processed by downstream enzymes. For DRR, the Fe(II)/α-ketoglutarate-dependent ALKBH2 enzyme repairs εA by direct conversion of εA to A. While the molecular mechanism of each enzyme is well understood on unpackaged duplex DNA, less is known about their actions on packaged DNA. The nucleosome core particle (NCP) forms the minimal packaging unit of DNA in eukaryotic organisms and is composed of 145–147 base pairs wrapped around a core of eight histone proteins. In this work, we investigated the activity of AAG and ALKBH2 on εA lesions globally distributed at positions throughout a strongly positioned NCP. Overall, we examined the repair of εA at 23 unique locations in packaged DNA. We observed a strong correlation between rotational positioning of εA and AAG activity but not ALKBH2 activity. ALKBH2 was more effective than AAG at repairing occluded εA lesions, but only AAG was capable of full repair of any εA in the NCP. However, notable exceptions to these trends were observed, highlighting the complexity of the NCP as a substrate for DNA repair. Modeling of binding of the repair enzymes to NCPs revealed that some of these observations can be explained by steric interference caused by DNA packaging. Specifically, interactions between ALKBH2 and the histone proteins obstruct binding to DNA, which leads to diminished activity. Taken together, these results support in vivo observations of alkylation damage profiles and contribute to our understanding of mutational hotspots.

A chromatin scaffold for DNA damage recognition: how histone methyltransferases prime nucleosomes for repair of ultraviolet light-induced lesions

The excision of mutagenic DNA adducts by the nucleotide excision repair (NER) pathway is essential for genome stability, which is key to avoiding genetic diseases, premature aging, cancer and neurologic disorders. Due to the need to process an extraordinarily high damage density embedded in the nucleosome landscape of chromatin, NER activity provides a unique functional caliper to understand how histone modifiers modulate DNA damage responses. At least three distinct lysine methyltransferases (KMTs) targeting histones have been shown to facilitate the detection of ultraviolet (UV) light-induced DNA lesions in the difficult to access DNA wrapped around histones in nucleosomes. By methylating core histones, these KMTs generate docking sites for DNA damage recognition factors before the chromatin structure is ultimately relaxed and the offending lesions are effectively excised. In view of their function in priming nucleosomes for DNA repair, mutations of genes coding for these KMTs are expected to cause the accumulation of DNA damage promoting cancer and other chronic diseases. Research on the question of how KMTs modulate DNA repair might pave the way to the development of pharmacologic agents for novel therapeutic strategies.

Variable impact of conformationally distinct DNA lesions on nucleosome structure and dynamics: Implications for nucleotide excision repair

The packaging of DNA in nucleosomes presents a barrier for biological transactions including replication, transcription and repair. However, despite years of research, how the DNA is freed from the histone proteins and thereby allows the molecular machines to access the DNA remains poorly understood. We are interested in global genomic nucleotide excision repair (GG-NER). It is established that the histones are obstacles to this process, and DNA lesions are repaired less efficiently in nucleosomes than in free DNA. In the present study, we utilized molecular dynamics simulations to elucidate the nature of the distortions and dynamics imposed in the nucleosome by a set of three structually different lesions that vary in GG-NER efficiencies in free DNA, and in nucleosomes [Shafirovich, Geacintov, et. al, 2019]. Two of these are bulky lesions derived from metabolic activation of the environmental carcinogen benzo[a]pyrene, the 10R (+)-cis-anti-B[a]P-N²-dG and the stereoisomeric 10S (+)-trans-anti-B[a]P-N²-dG, which respectively adopt base-displaced/intercalated and minor groove-aligned conformations in DNA. The third is a non-bulky lesion, the 5'R-8-cyclo-2'-deoxyguanosine cross-link, produced by reactive oxygen and nitrogen species; cyclopurine lesions are highly mutagenic. These adducts are placed near the dyad axis, and rotationally with the lesion-containing strand facing towards or away from the histones. While each lesion has distinct conformational characteristics that are retained in the nucleosome, a spectrum of structural and dynamic disturbances, from slight to substantial, are displayed that depend on the lesion's structure and position in the nucleosome. We hypothesize that these intrinsic structural and dynamic distinctions provide different signals to initiate the cascade of chromatin-opening processes, including acetylation and other post translational modifications, remodeling by ATP-dependent complexes and spontaneous unwrapping that regulate the rate of access to the lesion; this may translate ultimately into varying GG-NER efficiencies, including repair resistance when signals for access are too weak.

Rotational and translational positions determine the structural and dynamic impact of a single ribonucleotide incorporated in the nucleosome

Ribonucleotides misincorporated by replicative DNA polymerases are by far the most common DNA lesion. The presence of ribonucleotides in DNA is associated with genome instability, causing replication stress, chromosome fragility, gross chromosomal rearrangements, and other mutagenic events. Furthermore, nucleosome and chromatin assembly as well as nucleosome positioning are affected by the presence of ribonucleotides. Notably, nucleosome formation is significantly reduced by a single ribonucleotide. Single ribonucleotides are primarily removed from DNA by the ribonucleotide excision repair (RER) pathway via the RNase H2 enzyme, which incises the DNA backbone on the 5'-side of the ribonucleotide. While the structural implications of a single ribonucleotide in free duplex DNA have been well studied, how a single ribonucleotide embedded in nucleosomal DNA impacts nucleosome structure and dynamics, and the possible consequent impact on RER, have not been explored. We have carried out 3.5 μs molecular dynamics simulations of a single ribonucleotide incorporated at various translational and rotational positions in a nucleosome core particle. We find that the presence of the 2'-OH group on the ribose impacts the local conformation and dynamics of both the ribonucleotide and nearby DNA nucleotides as well as their interactions with histones; the nature of these disturbances depends on the rotational and translational setting, including whether the ribose faces toward or away from the histones. The ribonucleotide's preferred C3'-endo pucker is stabilized by interactions with the histones, and furthermore the ribonucleotide can cause dynamic local duplex disturbance involving an abnormal C3'-endo population of the adjacent deoxyribose pucker, minor groove opening, ruptured Watson-Crick pairing, and duplex unwinding that are governed by translation-dependent histone-nucleotide interactions. Possible effects of these disturbances on RER are considered.