The histone variant H3.3 marks active chromatin by replacing the conventional histone H3.1. In this study, we investigate the detailed mechanism of H3.3 replication-independent deposition. We found that the death domainassociated protein DAXX and the chromatin remodeling factor ATRX (a-thalassemia/mental retardation syndrome protein) are specifically associated with the H3.3 deposition machinery. Bacterially expressed DAXX has a marked binding preference for H3.3 and assists the deposition of (H3.3-H4) 2 tetramers on naked DNA, thus showing that DAXX is a H3.3 histone chaperone. In DAXX-depleted cells, a fraction of H3.3 was found associated with the replication-dependent machinery of deposition, suggesting that cells adapt to the depletion. The reintroduced DAXX in these cells colocalizes with H3.3 into the promyelocytic leukemia protein (PML) bodies. Moreover, DAXX associates with pericentric DNA repeats, and modulates the transcription from these repeats through assembly of H3.3 nucleosomes. These findings establish a new link between the PML bodies and the regulation of pericentric DNA repeat chromatin structure. Taken together, our data demonstrate that DAXX functions as a bona fide histone chaperone involved in the replication-independent deposition of H3.3.[Keywords: Histone variant; H3.3; histone chaperone; PML-NBs] Supplemental material is available at http://www.genesdev.org.
The phenotype of the human genetic disorder Cockayne syndrome (CS) is not only due to DNA repair defect but also (and perhaps essentially) to a severe transcription initiation defect. After UV irradiation, even undamaged genes are not transcribed in CSB cells. Indeed, neither RNA pol II nor the associated basal transcription factors are recruited to the promoters of the housekeeping genes, around of which histone H4 acetylation is also deficient. Transfection of CSB restores the recruitment process of RNA pol II. On the contrary, the p53-responsive genes do not require CSB and are transcribed in both wild-type and CSB cells upon DNA damage. Altogether, our data highlight the pivotal role of CSB in initiating the transcriptional program of certain genes after UV irradiation, and also may explain some of the complex traits of CS patients.
Excluding 53BP1 from chromatin is required to attenuate the DNA damage response during mitosis, yet the functional relevance and regulation of this exclusion is unclear. Here we show that 53BP1 is phosphorylated during mitosis on two residues, T1609 and S1618, located in its well-conserved ubiquitination-dependent recruitment (UDR) motif. Phosphorylating these sites blocks the interaction of the UDR motif with mononuclesomes containing ubiquitinated histone H2A and impedes binding of 53BP1 to mitotic chromatin. Ectopic recruitment of 53BP1- T1609A/S1618A to mitotic DNA lesions was associated with significant mitotic defects that could be reversed by inhibiting non-homologous end joining. We also reveal that protein phosphatase complex, PP4C/R3β dephosphorylates T1609 and S1618 to allow the recruitment of 53BP1 to chromatin in G1 phase. Our results identify key sites of 53BP1 phosphorylation during mitosis, identify the counteracting phosphatase complex that restores the potential for DDR during interphase, and establish the physiological importance of this regulation.
SUMMARY53BP1 is a multi-functional double-strand break (DSB) repair protein that is essential for class switch recombination in B lymphocytes and for sensitizing BRCA1-deficient tumors to PARP inhibitors. Central to all 53BP1 activities is its recruitment to DSBs via the interaction of the tandem Tudor domain with dimethylated lysine 20 of histone H4 (H4K20me2). Here we identify an uncharacterized protein, TIRR (Tudor Interacting Repair Regulator) that directly binds the tandem Tudor domain and masks its H4K20me2 binding motif. Upon DNA damage, ATM phosphorylates 53BP1 and recruits RIF1 to dissociate the 53BP1-TIRR complex. However, overexpression of TIRR impedes 53BP1 function by blocking its localization to DSBs. Depletion of TIRR destabilizes 53BP1 in the nuclear soluble fraction and also alters the DSB-induced protein complex centering 53BP1. These findings identify TIRR as a new factor that influences DSB †
Limited DNA end resection is the key to impaired homologous recombination (HR) in BRCA1mutant cells. Here through a loss-of-function CRISPR screen we identify DYNLL1 as an inhibitor of DNA end resection. Loss of DYNLL1 allows DNA end resection and restores HR in BRCA1mutant cells, thereby inducing resistance to platinum drugs and poly(ADP-ribose) polymerase
p53 regulates the transcription of a number of genes among which are dierent redox-related genes. It has been proposed that these genes can induce a cellular oxidative stress leading to p53-dependent apoptosis (Polyak et al., 1997). MnSOD, the product of superoxide dismutase 2 (SOD2) gene, is one of the major cellular defences against oxidative stress. We demonstrate here that p53 is able to repress SOD2 gene expression and that this repression takes place at promoter level. We show the importance of this regulation for the p53 function, by demonstrating that an overexpression of MnSOD decreases p53-mediated induction of apoptosis. Moreover, we demonstrate that MnSOD overexpression decreases p53-gene expression at the promoter level. These ®ndings raise the hypothesis that p53 and SOD2 genes are mutually regulated leading to the modulation of various cellular processes including apoptosis. Oncogene (2001) 20, 430 ± 439.
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