Shaping chromatin for repair

To counteract the adverse effects of various DNA lesions, cells have evolved an array of diverse repair pathways to restore DNA structure and to coordinate repair with cell cycle regulation. Chromatin changes are an integral part of the DNA damage response, particularly with regard to the types of repair that involve assembly of large multiprotein complexes such as those involved in double strand break (DSB) repair and nucleotide excision repair (NER). A number of phosphorylation, acetylation, methylation, ubiquitylation and chromatin remodeling events modulate chromatin structure at the lesion site. These changes demarcate chromatin neighboring the lesion, afford accessibility and binding surfaces to repair factors and provide on-the-spot means to coordinate repair and damage signaling. Thus, the hierarchical assembly of repair factors at a double strand break is mostly due to their regulated interactions with posttranslational modifications of histones. A large number of chromatin remodelers are required at different stages of DSB repair and NER. Remodelers physically interact with proteins involved in repair processes, suggesting that chromatin remodeling is a requisite for repair factors to access the damaged site. Together, recent findings define the roles of histone post-translational modifications and chromatin remodeling in the DNA damage response and underscore possible differences in the requirements for these events in relation to the chromatin context.     

Accessing DNA damage in chromatin: Preparing the chromatin landscape for base excision repair

DNA damage in chromatin comes in many forms, including single base lesions that induce base excision repair (BER). We and others have shown that the structural location of DNA lesions within nucleosomes greatly influences their accessibility to repair enzymes. Indeed, a difference in the location of uracil as small as one-half turn of the DNA backbone on the histone surface can result in a 10-fold difference in the time course of its removal in vitro. In addition, the cell has evolved several interdependent processes capable of enhancing the accessibility of excision repair enzymes to DNA lesions in nucleosomes, including post-translational modification of histones, ATP-dependent chromatin remodeling and interchange of histone variants in nucleosomes. In this review, we focus on different factors that affect accessibility of BER enzymes to nucleosomal DNA.     

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.     

Chromatin Dynamics during DNA Repair Revealed by Pair Correlation Analysis of Molecular Flow in the Nucleus

Chromatin dynamics modulate DNA repair factor accessibility throughout the DNA damage response. The spatiotemporal scale upon which these dynamics occur render them invisible to live cell imaging. Here we present a believed novel assay to monitor the in vivo structural rearrangements of chromatin during DNA repair. By pair correlation analysis of EGFP molecular flow into chromatin before and after damage, this assay measures millisecond variations in chromatin compaction with submicron resolution. Combined with laser microirradiation we employ this assay to monitor the real-time accessibility of DNA at the damage site. We find from comparison of EGFP molecular flow with a molecule that has an affinity toward double-strand breaks (Ku-EGFP) that DNA damage induces a transient decrease in chromatin compaction at the damage site and an increase in compaction to adjacent regions, which together facilitate DNA repair factor recruitment to the lesion with high spatiotemporal control.     

Chromatin remodeling and the maintenance of genome integrity

DNA damage of any type is threatening for a cell. If lesions are left unrepaired, genomic instability can arise, faithful transmission of genetic information is greatly compromised eventually leading the cell to undergo apoptosis or carcinogenesis. In order to access/detect and repair these damages, repair factors must circumvent the natural repressive barrier of chromatin. This review will present recent progress showing the intricate link between chromatin, its remodeling and the DNA repair process. Several studies demonstrated that one of the first events following specific types of DNA damage is the phosphorylation of histone H2A. This mark or the damage itself are responsible for the association of chromatin-modifying complexes near damaged DNA. These complexes are able to change the chromatin structure around the wounded DNA in order to allow the repair machinery to gain access and repair the lesion. Chromatin modifiers include ATP-dependent remodelers such as SWI/SNF and Rad54 as well as histone acetyltransferases (HATs) like SAGA/NuA4-related complexes and p300/CBP, which have been shown to facilitate DNA accessibility and repair in different pathways leading to the maintenance of genome integrity.     

染色质结构之美——染色质可及性

染色质可及性(chromatin accessibility)作为一种衡量染色质结合因子与染色质DNA结合能力高低的染色质属性,是评价染色质结构稳态的重要指标之一,在多种细胞核进程中扮演重要角色,包括基因转录调控以及DNA损伤修复等。该属性的异常调控与多种疾病的发生发展密切相关,包括肿瘤以及神经退行性疾病等。对于该属性探究已经成为生命科学与疾病领域的热点。伴随越来越多的新技术应运而生,例如染色质构象捕获技术、高通量测序技术以及两种技术的结合等。随着技术的进步,多种参与调控染色质可及性的因素被发现和总结,包括核小体占位、组蛋白修饰以及非编码RNA等。多项大规模的染色质组学数据绘制了多种疾病的染色质可及性图谱,为揭示疾病的发生发展与染色质可及性之间的关系提供了数据支持。同时,随着单细胞染色质可及性测序技术的发展,实现了对细胞类型染色质层面的划分,弥补了单纯依赖基因表达划分细胞类型的不足。本文将从染色质的组成与可及性、影响染色质可及性的因素、染色质可及性的检测方法,以及染色质可及性与癌症的关系等方面简要阐述染色质可及性的研究进展。     

Current role of mammalian sirtuins in DNA repair

Cellular DNA is constantly challenged by damage-inducing factors derived from exogenous or endogenous sources. Thus, to protect against DNA damage, cells have evolved complex and finely regulated mechanisms collectively known as DNA-damage response (DDR). However, DNA repair in eukaryotes does not occur merely in naked DNA but also within a highly organized and compacted chromatin environment, which ultimately participates in regulating DDR pathways. Thus, remodelling of the chromatin surrounding areas containing damaged DNA is required to allow access to the DNA repair machinery, as well as post-translational modifications in many repair factors to recruit and activate them at the damaged site. Notably, proteins such as sirtuins, which are NAD+-dependent deacetylases, have evolved to modulate multiple repair pathways through deacetylation of some repair factors, influencing chromatin accessibility or indirectly modulating cell cycle and preventing oxidative stress. In this way, the purpose of this review is to summarize the recent knowledge that links sirtuins with DNA repair, with a particular emphasis on the molecular mechanisms associated with coordination and regulation of this vital process.     

Light and dark in chromatin repair: repair of UV-induced DNA lesions by photolyase and nucleotide excision repair

Nucleotide excision repair (NER) and DNA repair by photolyase in the presence of light (photoreactivation) are the major pathways to remove UV-induced DNA lesions from the genome, thereby preventing mutagenesis and cell death. Photoreactivation was found in many prokaryotic and eukaryotic organisms, but not in mammals, while NER seems to be universally distributed. Since packaging of eukaryotic DNA in nucleosomes and higher order chromatin structures affects DNA structure and accessibility, damage formation and repair are coupled intimately to structural and dynamic properties of chromatin. Here, I review recent progress in the study of repair of chromatin and transcribed genes. Photoreactivation and NER are discussed as examples of how an individual enzyme and a complex repair pathway, respectively, access DNA lesions in chromatin and how these two repair processes fulfil complementary roles in removal of UV lesions. These repair pathways provide insight into the structural and dynamic properties of chromatin and suggest how other DNA repair processes could work in chromatin.     

Detection of bulky DNA lesions: DDB2 at the interface of chromatin and DNA repair in eukaryotes

Bulky DNA damage is corrected by the nucleotide excision repair (NER) pathway. Although the core biochemical mechanism of NER is understood, details including lesion recognition and repair in the context of chromatin remain to be elucidated. As more data become available, the complexity of lesion recognition in chromatin is becoming clear. This review will discuss current knowledge of DNA damage recognition in the context of chromatin, with a focus on the roles of chromatin remodeling and the specific lesion recognition protein DDB2 (DNA damage-binding protein 2) in chromatin repair. Additionally, we propose a model that ubiquitination-mediated DDB2 dissociation from chromatin, not its degradation, is important for GG-NER progression.     

Histone tails: Directing the chromatin response to DNA damage

Considerable energetic investment is devoted to altering large stretches of chromatin adjacent to DNA double strand breaks (DSBs). Immediately ensuing DSB formation, a myriad of histone modifications are elicited to create a platform for inducible and modular assembly of DNA repair protein complexes in the vicinity of the DNA lesion. This complex signaling network is critical to repair DNA damage and communicate with cellular processes that occur in cis and in trans to the genomic lesion. Failure to properly execute DNA damage inducible chromatin changes is associated with developmental abnormalities, immunodeficiency, and malignancy in humans and in genetically engineered mouse models. This review will discuss current knowledge of DNA damage responsive histone changes that occur in mammalian cells, highlighting their involvement in the maintenance of genome integrity.