DNA修复的表观遗传学调控

表观遗传学信息的改变是导致人类肿瘤形成的重要因素之一．基因组的稳定性经常会受到DNA损伤的威胁．然而,高度致密的染色质结构却极大地妨碍了DNA修复的进行．因此,真核生物细胞中必须有一个精确的机制来克服染色质这一天然的屏障．其中,组蛋白的共价修饰和ATP-依赖的染色质重塑通过改变染色质的结构,对DNA修复进程起着关键的调控作用．介绍了DNA修复过程中,发生在表观遗传学方面的主要调控过程,特别阐述了在DNA双链断裂损伤应答和修复过程中,组蛋白修饰和染色质重塑方面最新的研究进展,并对今后的发展方向进行了讨论．     

Histone Acetyltransferase 1 Promotes Homologous Recombination in DNA Repair by Facilitating Histone Turnover

Faithful repair of DNA double-strand breaks is vital to the maintenance of genome integrity and proper cell functions. Histone modifications, such as reversible acetylation, phosphorylation, methylation, and ubiquitination, which collectively contribute to the establishment of distinct chromatin states, play important roles in the recruitment of repair factors to the sites of double-strand breaks. Here we report that histone acetyltransferase 1 (HAT1), a classical B type histone acetyltransferase responsible for acetylating the N-terminal tail of newly synthesized histone H4 in the cytoplasm, is a key regulator of DNA repair by homologous recombination in the nucleus. We found that HAT1 is required for the incorporation of H4K5/K12-acetylated H3.3 at sites of double-strand breaks through its HIRA-dependent histone turnover activity. Incorporated histones with specific chemical modifications facilitate subsequent recruitment of RAD51, a key repair factor in mammalian cells, to promote efficient homologous recombination. Significantly, depletion of HAT1 sensitized cells to DNA damage compromised the global chromatin structure, inhibited cell proliferation, and induced cell apoptosis. Our experiments uncovered a role for HAT1 in DNA repair in higher eukaryotic organisms and provide a mechanistic insight into the regulation of histone dynamics by HAT1.     

Chromatin modulation and the DNA damage response

The ability to sense and respond appropriately to genetic lesions is vitally important to maintain the integrity of the genome. Emerging evidence indicates that various modulations to chromatin structure are centrally important to many aspects of the DNA damage response (DDR). Here, we discuss recently described roles for specific post-translational covalent modifications to histone proteins, as well as ATP-dependent chromatin remodelling, in DNA damage signalling and repair of DNA double strand breaks.     

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.     

Preserving genome integrity and function: the DNA damage response and histone modifications

Modulation of chromatin templates in response to cellular cues, including DNA damage, relies heavily on the post-translation modification of histones. Numerous types of histone modifications including phosphorylation, methylation, acetylation, and ubiquitylation occur on specific histone residues in response to DNA damage. These histone marks regulate both the structure and function of chromatin, allowing for the transition between chromatin states that function in undamaged condition to those that occur in the presence of DNA damage. Histone modifications play well-recognized roles in sensing, processing, and repairing damaged DNA to ensure the integrity of genetic information and cellular homeostasis. This review highlights our current understanding of histone modifications as they relate to DNA damage responses (DDRs) and their involvement in genome maintenance, including the potential targeting of histone modification regulators in cancer, a disease that exhibits both epigenetic dysregulation and intrinsic DNA damage.     

H2AX: tailoring histone H2A for chromatin-dependent genomic integrity.

During the last decade, chromatin research has been focusing on the role of histone variability as a modulator of chromatin structure and function. Histone variability can be the result of either post-translational modifications or intrinsic variation at the primary structure level: histone variants. In this review, we center our attention on one of the most extensively characterized of such histone variants in recent years, histone H2AX. The molecular phylogeny of this variant seems to have run in parallel with that of the major canonical somatic H2A1 in eukaryotes. Functionally, H2AX appears to be mainly associated with maintaining the genome integrity by participating in the repair of the double-stranded DNA breaks exogenously introduced by environmental damage (ionizing radiation, chemicals) or in the process of homologous recombination during meiosis. At the structural level, these processes involve the phosphorylation of serine at the SQE motif, which is present at the very end of the C-terminal domain of H2AX, and possibly other PTMs, some of which have recently started to be defined. We discuss a model to account for how these H2AX PTMs in conjunction with chromatin remodeling complexes (such as INO80 and SWRI) can modify chromatin structure (remodeling) to support the DNA unraveling ultimately required for DNA repair.     

Histone marks: repairing DNA breaks within the context of chromatin

Inherited or acquired defects in detecting, signalling or repairing DNA damage are associated with various human pathologies, including immunodeficiencies, neurodegenerative diseases and various forms of cancer. Nuclear DNA is packaged into chromatin and therefore the true in vivo substrate of damaged DNA occurs within the context of chromatin. Our work aims to decipher the mechanisms by which cells detect DNA damage and signal its presence to the DNA-repair and cell-cycle machineries. In particular, much of our work has focused on DNA DSBs (double-strand breaks) that are generated by ionizing radiation and radiomimetic chemicals, and which can also arise when the DNA replication apparatus encounters other DNA lesions. In the present review, we describe some of our recent work, as well as the work of other laboratories, that has identified new chromatin proteins that mediate DSB responses, control SDB processing or modulate chromatin structure at DNA-damage sites. We also aim to survey several recent advances in the field that have contributed to our understanding of how particular histone modifications and involved in DNA repair. It is our hope that by understanding the role of chromatin and its modifications in promoting DNA repair and genome stability, this knowledge will provide opportunities for developing novel classes of drugs to treat human diseases, including cancer.