The transcriptional histone acetyltransferase cofactor TRRAP associates with the MRN repair complex and plays a role in DNA double-strand break repair

Histone H3 tails containing dimethylated lysine and adjacent phosphorylated serine modifications adopt a specific conformation during mitosis and meiosis

Condensation of chromatin, mediated in part by posttranslational modifications of histones, is essential for cell division during mitosis. Histone H3 tails are dimethylated on lysine (Kme2) and become phosphorylated on serine (Sp) residues during mitosis. We have explored the possibility that these double modifications are involved in the establishment of H3 tail conformations during the cell cycle. Here we describe a specific chromatin conformation occurring at Kme2 and adjacently phosphorylated S of H3 tails upon formation of a hydrogen bond. This conformation appears exclusively between early prophase and early anaphase of the mitosis, when chromatin condensation is highest. Moreover, we observed that the conformed H3Kme2Sp tail is present at the diplotene and metaphase stages in spermatocytes and oocytes. Our data together with results obtained by cryoelectron microscopy suggest that the conformation of Kme2Sp-modified H3 tails changes during mitosis and meiosis. This is supported by biostructural modeling of a modified histone H3 tail bound by an antibody, indicating that Kme2Sp-modified H3 tails can adopt at least two different conformations. Thus, the H3K9me2S10p and the H3K27me2S28p sites are involved in the acquisition of specific chromatin conformations during chromatin condensation for cell division.

Transcriptional activation of histone genes requires NPAT-dependent recruitment of TRRAP-Tip60 complex to histone promoters during the G1/S phase transition

Transcriptional activation of histone subtypes is coordinately regulated and tightly coupled with the onset of DNA replication during S-phase entry. The underlying molecular mechanisms for such coordination and coupling are not well understood. The cyclin E-Cdk2 substrate NPAT has been shown to play an essential role in the transcriptional activation of histone genes at the G(1)/S-phase transition. Here, we show that NPAT interacts with components of the Tip60 histone acetyltransferase complex through a novel amino acid motif, which is functionally conserved in E2F and adenovirus E1A proteins. In addition, we demonstrate that transformation/transactivation domain-associated protein (TRRAP) and Tip60, two components of the Tip60 complex, associate with histone gene promoters at the G(1)/S-phase boundary in an NPAT-dependent manner. In correlation with the association of the TRRAP-Tip60 complex, histone H4 acetylation at histone gene promoters increases at the G(1)/S-phase transition, and this increase involves NPAT function. Suppression of TRRAP or Tip60 expression by RNA interference inhibits histone gene activation. Thus, our data support a model in which NPAT recruits the TRRAP-Tip60 complex to histone gene promoters to coordinate the transcriptional activation of multiple histone genes during the G(1)/S-phase transition.

DNA damage-dependent acetylation and ubiquitination of H2AX enhances chromatin dynamics

Chromatin reorganization plays an important role in DNA repair, apoptosis, and cell cycle checkpoints. Among proteins involved in chromatin reorganization, TIP60 histone acetyltransferase has been shown to play a role in DNA repair and apoptosis. However, how TIP60 regulates chromatin reorganization in the response of human cells to DNA damage is largely unknown. Here, we show that ionizing irradiation induces TIP60 acetylation of histone H2AX, a variant form of H2A known to be phosphorylated following DNA damage. Furthermore, TIP60 regulates the ubiquitination of H2AX via the ubiquitin-conjugating enzyme UBC13, which is induced by DNA damage. This ubiquitination of H2AX requires its prior acetylation. We also demonstrate that acetylation-dependent ubiquitination by the TIP60-UBC13 complex leads to the release of H2AX from damaged chromatin. We conclude that the sequential acetylation and ubiquitination of H2AX by TIP60-UBC13 promote enhanced histone dynamics, which in turn stimulate a DNA damage response.

Orchestration of chromatin-based processes: mind the TRRAP

Chromatin modifications at core histones including acetylation, methylation, phosphorylation and ubiquitination play an important role in diverse biological processes. Acetylation of specific lysine residues within the N terminus tails of core histones is arguably the most studied histone modification; however, its precise roles in different cellular processes and how it is disrupted in human diseases remain poorly understood. In the last decade, a number of histone acetyltransferases (HATs) enzymes responsible for histone acetylation, has been identified and functional studies have begun to unravel their biological functions. The activity of many HATs is dependent on HAT complexes, the multiprotein assemblies that contain one HAT catalytic subunit, adapter proteins, several other molecules of unknown function and a large protein called TRansformation/tRanscription domain-Associated Protein (TRRAP). As a common component of many HAT complexes, TRRAP appears to be responsible for the recruitment of these complexes to chromatin during transcription, replication and DNA repair. Recent studies have shed new light on the role of TRRAP in HAT complexes as well as mechanisms by which it mediates diverse cellular processes. Thus, TRRAP appears to be responsible for a concerted and context-dependent recruitment of HATs and coordination of distinct chromatin-based processes, suggesting that its deregulation may contribute to diseases. In this review, we summarize recent developments in our understanding of the function of TRRAP and TRRAP-containing HAT complexes in normal cellular processes and speculate on the mechanism underlying abnormal events that may lead to human diseases such as cancer.

Mre11 mediates gene regulation in yeast spore development

Mre11, together with Rad50 and Xrs2/NBS, plays pivotal roles in homologous recombination, repair of DNA double strand breaks (DSBs), activation of damage-induced checkpoint, and telomere maintenance. Here we demonstrate that the absence of Mre11 in yeast causes specific effects on regulation of a class of meiotic genes for spore development. Using DNA microarray assays to analyze yeast mutants defective for meiotic DSB formation, we revealed that the meiotic expression profile in the mre11Delta cells was generally unaffected when compared to the one in the wild-type strain, although the activation of about 90 meiotic genes were severely and specifically impaired in early meiosis. These defects were confirmed by northern and lacZ reporter gene assays. Interestingly, a substantial portion of the severely affected genes includes genes responsible for spore wall biogenesis, the defects of which may account for the fragile spore wall phenotype of the mre11Delta strain. The transcriptional deficiency was not observed in other DSB mutants such as rad50Delta, xrs2Delta, spo11Delta, and spo11Y135F, suggesting the transcriptional defect in mre11Delta is due to neither lack of meiotic DSB formation, nor disintegrity of Mre11-Rad50-Xrs2 complex. In addition, the deficiency of mre11Delta in gene activation was not alleviated by the deletion of RAD24. Therefore, it is unlikely that DNA damage checkpoint activation by mre11Delta caused transcriptional deficiency. We also found that a C-terminus DNA binding domain truncation mutant (mre11DeltaC49), which has meiosis-specific defects, exhibited transcriptional defects as observed in mre11Delta, whereas an N-terminal phosphoesterase mutant (mre11D16A) does not. Taken together, we propose that Mre11 is involved in the regulation of a specific class of genes during spore development through its C-terminus domain.

Tip60-dependent acetylation of p53 modulates the decision between cell-cycle arrest and apoptosis

Upon DNA damage and other types of stress, p53 induces either cell-cycle arrest or apoptosis depending on the cellular context. However, the molecular mechanisms that govern the choice between cell-cycle arrest and apoptosis are not well understood. Here, we show that Tip60 is required for both cell growth arrest and apoptosis mediated by p53 and also induces its acetylation specifically at lysine 120 (K120) within the DNA-binding domain. Interestingly, this modification is crucial for p53-dependent apoptosis but is dispensable for its mediated growth arrest. K120 is a recurrent site for p53 mutation in human cancer, and the corresponding acetylation-defective tumor mutant (K120R) abrogates p53-mediated apoptosis, but not growth arrest. Thus, our study demonstrates that Tip60-dependent acetylation of p53 at K120 modulates the decision between cell-cycle arrest and apoptosis, and it reveals that the DNA-binding core domain is an important target for p53 regulation by posttranslational modifications.

TopBP1 contains a transcriptional activation domain suppressed by two adjacent BRCT domains

TopBP1 has eight BRCT [BRCA1 (breast-cancer susceptibility gene 1) C-terminus] domains and is involved in initiating DNA replication, and DNA damage checkpoint signalling and repair. Several BRCT-domain-containing proteins involved in mediating DNA repair have transcriptional regulatory domains, and as demonstrated for BRCA1 these regulatory domains are important in mediating the functions of these proteins. These transcriptional regulatory processes involve modification of chromatin, and recent evidence has clearly demonstrated that the ability to modify chromatin plays an important role in regulating DNA damage signalling and repair. Here we report the identification of a TopBP1 transcriptional activation domain that is rich in hydrophobic residues, interspersed with acidic amino acids, characteristics that are typical of transcriptional activation domains identified previously. Two adjacent repressor domains encoded by BRCT2 and BRCT5 silence this activator and experiments suggest that these repressors actively recruit repressor complexes. Both the activator and BRCT2 repressor domains function in yeast. The present study identifies several chromatin modification domains encoded by TopBP1, and the implications of these findings are discussed in the context of the DNA damage response and the understanding of TopBP1 function.

Tip60 in DNA damage response and growth control: many tricks in one HAT

The Tip60 histone acetyltransferase is part of an evolutionarily conserved multisubunit complex, NuA4, which is recruited by many transcription factors to their target promoters, where it is thought to participate in histone acetylation and transcriptional activation. These transcription factors include tumor promoters and also tumor suppressors, such as p53, which links Tip60 to DNA damage responses. Tip60 also has transcription-independent roles in DNA damage responses. First, independently from NuA4, Tip60 binds the kinases ataxia-telangiectasia mutated (ATM) and DNA-dependent protein kinase catalytic subunit (DNA-PKcs) and participates in their activation by DNA double-strand breaks. Second, NuA4 is recruited to the chromatin surrounding the breaks and, through a series of chromatin modifications, contributes to the dynamics of DNA repair. These molecular activities might endow Tip60 with multiple and potentially antagonistic biological functions.

A novel function of DNA repair molecule Nbs1 in terminal differentiation of the lens fibre cells and cataractogenesis

The Nbs1 protein, hypomorphic mutant in Nijmegen breakage syndrome (NBS), is a component of the Mre11/Rad50/Nbs1 (M/R/N) complex that acts as a DNA double-strand break sensor and functions in cell cycle checkpoint in response to DNA damage and DNA repair. Here we report that targeted disruption of murine NBS1 gene (Nbn) in the lens alters the M/R/N complex nuclear localization and results in microphthalmia in mice due to reduced proliferation of the lens epithelial cells. Unexpectedly, all Nbn-deficient lenses develop cataracts at an early age due to altered lens fibre cell differentiation, including disruption of normal lens epithelial and fibre cell architecture and incomplete denucleation of fibre cells, and these changes are independent of the p53 pathway. In addition, Nbn-deficient lenses show dysregulated transcription of various crystallins. Thus, this study implicates a novel function of Nbs1 in terminal differentiation of the lens fibre cells and in cataractogenesis.

Following the path of the virus: the exploitation of host DNA repair mechanisms by retroviruses

Numerous host cellular cofactors are involved in the life cycle of retroviruses. Importantly, DNA repair machinery of infected cells is activated by retroviruses and retroviral vectors during the process of integration and host cell DNA repair proteins are employed to create a fully integrated provirus. The full delineation of these repair mechanisms that are triggered by retroviruses also has implications outside of the field of retrovirology. It will undoubtedly be of interest to developers of gene therapy and will also further facilitate our understanding of DNA repair and cancer. This review gives a brief summary of the accomplishments in the field of DNA repair and retroviral integration and the opportunities that this area of science provides with regards to the elucidation of repair mechanisms, in the context of retroviral infection.