Chromatin compartmentalization regulates the response to DNA damage.

The DNA damage response is essential to safeguard genome integrity. Although the contribution of chromatin in DNA repair has been investigated1,2, the contribution of chromosome folding to these processes remains unclear3. Here we report that, after the production of double-stranded breaks (DSBs) in mammalian cells, ATM drives the formation of a new chromatin compartment (D compartment) through the clustering of damaged topologically associating domains, decorated with γH2AX and 53BP1. This compartment forms by a mechanism that is consistent with polymer-polymer phase separation rather than liquid-liquid phase separation. The D compartment arises mostly in G1 phase, is independent of cohesin and is enhanced after pharmacological inhibition of DNA-dependent protein kinase (DNA-PK) or R-loop accumulation. Importantly, R-loop-enriched DNA-damage-responsive genes physically localize to the D compartment, and this contributes to their optimal activation, providing a function for DSB clustering in the DNA damage response. However, DSB-induced chromosome reorganization comes at the expense of an increased rate of translocations, also observed in cancer genomes. Overall, we characterize how DSB-induced compartmentalization orchestrates the DNA damage response and highlight the critical impact of chromosome architecture in genomic instability.

Senataxin resolves RNA:DNA hybrids forming at DNA double-strand breaks to prevent translocations.

Ataxia with oculomotor apraxia 2 (AOA-2) and amyotrophic lateral sclerosis (ALS4) are neurological disorders caused by mutations in the gene encoding for senataxin (SETX), a putative RNA:DNA helicase involved in transcription and in the maintenance of genome integrity. Here, using ChIP followed by high throughput sequencing (ChIP-seq), we report that senataxin is recruited at DNA double-strand breaks (DSBs) when they occur in transcriptionally active loci. Genome-wide mapping unveiled that RNA:DNA hybrids accumulate on DSB-flanking chromatin but display a narrow, DSB-induced, depletion near DNA ends coinciding with senataxin binding. Although neither required for resection nor for timely repair of DSBs, senataxin was found to promote Rad51 recruitment, to minimize illegitimate rejoining of distant DNA ends and to sustain cell viability following DSB production in active genes. Our data suggest that senataxin functions at DSBs in order to limit translocations and ensure cell viability, providing new insights on AOA2/ALS4 neuropathies.

Physical interaction between the histone acetyl transferase Tip60 and the DNA double-strand breaks sensor MRN complex.

Chromatin modifications and chromatin-modifying enzymes are believed to play a major role in the process of DNA repair. The histone acetyl transferase Tip60 is physically recruited to DNA DSBs (double-strand breaks) where it mediates histone acetylation. In the present study, we show, using a reporter system in mammalian cells, that Tip60 expression is required for homology-driven repair, strongly suggesting that Tip60 participates in DNA DSB repair through homologous recombination. Moreover, Tip60 depletion inhibits the formation of Rad50 foci following ionizing radiation, indicating that Tip60 expression is necessary for the recruitment of the DNA damage sensor MRN (Mre11-Rad50-Nbs1) complex to DNA DSBs. Moreover, we found that endogenous Tip60 physically interacts with endogenous MRN proteins in a complex which is distinct from the classical Tip60 complex. Taken together, our results describe a physical link between a DNA damage sensor and a histone-modifying enzyme, and provide important new insights into the role and mechanism of action of Tip60 in the process of DNA DSB repair.

Human DNA polymerase eta is required for common fragile site stability during unperturbed DNA replication.

Human DNA polymerase eta (Pol eta) modulates susceptibility to skin cancer by promoting translesion DNA synthesis (TLS) past sunlight-induced cyclobutane pyrimidine dimers. Despite its well-established role in TLS synthesis, the role of Pol eta in maintaining genome stability in the absence of external DNA damage has not been well explored. We show here that short hairpin RNA-mediated depletion of Pol eta from undamaged human cells affects cell cycle progression and the rate of cell proliferation and results in increased spontaneous chromosome breaks and common fragile site expression with the activation of ATM-mediated DNA damage checkpoint signaling. These phenotypes were also observed in association with modified replication factory dynamics during S phase. In contrast to that seen in Pol eta-depleted cells, none of these cellular or karyotypic defects were observed in cells depleted for Pol iota, the closest relative of Pol eta. Our results identify a new role for Pol eta in maintaining genomic stability during unperturbed S phase and challenge the idea that the sole functional role of Pol eta in human cells is in TLS DNA damage tolerance and/or repair pathways following exogenous DNA damage.

Role of TLS DNA polymerases eta and kappa in processing naturally occurring structured DNA in human cells.

Accurate DNA replication during S-phase is fundamental to maintain genome integrity. During this critical process, replication forks frequently encounter obstacles that impede their progression. While the regulatory pathways which act in response to exogenous replication stress are beginning to emerge, the mechanisms by which fork integrity is maintained at naturally occurring endogenous replication-impeding sequences remains obscure. Notably, little is known about how cells replicate through special chromosomal regions containing structured non-B DNA, for example, G4 quartets, known to hamper fork progression or trigger chromosomal rearrangements. Here, we have investigated the role in this process of the human translesion synthesis (TLS) DNA polymerases of the Y-family (pol eta, pol iota, and pol kappa), specialized enzymes known to synthesize DNA through DNA damage. We show that depletion by RNA interference of expression of the genes for Pol eta or Pol kappa, but not Pol iota, sensitizes U2OS cells treated with the G4-tetraplex interactive compound telomestatin and triggers double-strand breaks in HeLa cells harboring multiple copies of a G-rich sequence from the promoter region of the human c-MYC gene, chromosomally integrated as a transgene. Moreover, we found that downregulation of Pol kappa only raises the level of DSB in HeLa cells containing either one of two breakage hotspot structured DNA sequences in the chromosome, the major break region (Mbr) of BCL-2 gene and the GA rich region from the far right-hand end of the genome of the Kaposi Sarcoma associated Herpesvirus. These data suggest that naturally occurring DNA structures are physiological substrates of both pol eta and pol kappa. We discuss these data in the light of their downregulation in human cancers.

Distinct roles of chromatin-associated proteins MDC1 and 53BP1 in mammalian double-strand break repair.

Phosphorylated histone H2AX ("gamma-H2AX") recruits MDC1, 53BP1, and BRCA1 to chromatin near a double-strand break (DSB) and facilitates efficient repair of the break. It is unclear to what extent gamma-H2AX-associated proteins act in concert and to what extent their functions within gamma-H2AX chromatin are distinct. We addressed this question by comparing the mechanisms of action of MDC1 and 53BP1 in DSB repair (DSBR). We find that MDC1 functions primarily in homologous recombination/sister chromatid recombination, in a manner strictly dependent upon its ability to interact with gamma-H2AX but, unexpectedly, not requiring recruitment of 53BP1 or BRCA1 to gamma-H2AX chromatin. In contrast, 53BP1 functions in XRCC4-dependent nonhomologous end-joining, likely mediated by its interaction with dimethylated lysine 20 of histone H4 but, surprisingly, independent of H2AX. These results suggest a specialized adaptation of the "histone code" in which distinct histone tail-protein interactions promote engagement of distinct DSBR pathways.

Molecular analysis of sister chromatid recombination in mammalian cells.

Sister chromatid recombination (SCR) is a potentially error-free pathway for the repair of double-strand breaks arising during replication and is thought to be important for the prevention of genomic instability and cancer. Analysis of sister chromatid recombination at a molecular level has been limited by the difficulty of selecting specifically for these events. To overcome this, we have developed a novel "nested intron" reporter that allows the positive selection in mammalian cells of "long tract" gene conversion events arising between sister chromatids. We show that these events arise spontaneously in cycling cells and are strongly induced by a site-specific double-strand break (DSB) caused by the restriction endonuclease, I-SceI. Notably, some I-SceI-induced sister chromatid recombination events entailed multiple rounds of gene amplification within the reporter, with the generation of a concatemer of amplified gene segments. Thus, there is an intimate relationship between sister chromatid recombination control and certain types of gene amplification. Dysregulated sister chromatid recombination may contribute to cancer progression, in part, by promoting gene amplification.

Control of sister chromatid recombination by histone H2AX.

Histone H2AX has a role in suppressing genomic instability and cancer. However, the mechanisms by which it performs these functions are poorly understood. After DNA breakage, H2AX is phosphorylated on serine 139 in chromatin near the break. We show here that H2AX serine 139 enforces efficient homologous recombinational repair of a chromosomal double-strand break (DSB) by using the sister chromatid as a template. BRCA1, Rad51, and CHK2 contribute to recombinational repair, in part independently of H2AX. H2AX(-/-) cells show increased use of single-strand annealing, an error-prone deletional mechanism of DSB repair. Therefore, the chromatin response around a chromosomal DSB, in which H2AX serine 139 phosphorylation plays a central role, "shapes" the repair process in favor of potentially error-free interchromatid homologous recombination at the expense of error-prone repair. H2AX phosphorylation may help set up a favorable disposition between sister chromatids.

DNA polymerase beta overexpression stimulates the Rad51-dependent homologous recombination in mammalian cells.

Overexpression of DNA polymerase beta (polbeta), an error-prone DNA repair enzyme, has been shown to result in mutagenesis, aneuploidy and tumorigenesis. To further investigate the molecular basis leading to cancer-associated genetic changes, we examined whether the DNA polbeta could affect homologous recombination (HR). Using mammalian cells carrying an intrachromosomal recombination marker we showed that the DNA polbeta overexpression increased the HR mostly by enhancing gene conversion. Concomitantly, we observed the generation of DNA strand breaks as well as a DNA polbeta-dependent formation of Rad51 foci. The stimulation of HR was abolished by the coexpression of a dominant negative form of Rad51, suggesting that the Rad51 was involved in the increased HR events. The expression of different DNA polbeta mutants lacking polymerase activity did not result in HR stimulation, indicating that the DNA synthesis activity of DNA polbeta was related to this phenotype. These results provide new insights into the molecular mechanisms of the genetic instability observed in DNA polbeta overexpressing tumour cells.

BRCA1 and BRCA2 in hereditary breast cancer.

The hereditary breast and ovarian cancer susceptibility genes, BRCA1 and BRCA2, have established roles in genome integrity maintenance and in the control of homologous recombination. Recent work has produced valuable insights into the mechanisms of action of the gene products. This review summarizes some of these advances, and attempts to place them in the context of known functions of the genes.

Distinct BRCA1 rearrangements involving the BRCA1 pseudogene suggest the existence of a recombination hot spot.

The 5' end of the breast and ovarian cancer-susceptibility gene BRCA1 has previously been shown to lie within a duplicated region of chromosome band 17q21. The duplicated region contains BRCA1 exons 1A, 1B, and 2 and their surrounding introns; as a result, a BRCA1 pseudogene (PsiBRCA1) lies upstream of BRCA1. However, the sequence of this segment remained essentially unknown. We needed this information to investigate at the nucleotide level the germline deletions comprising BRCA1 exons 1A, 1B, and 2, which we had previously identified in two families with breast and ovarian cancer. We have analyzed the recently deposited nucleotide sequence of the 1.0-Mb region upstream of BRCA1. We found that 14 blocks of homology between the tandemly repeated copies (cumulative length = 11.5 kb) show similarity of 77%-92%. Gaps between blocks result from insertion or deletion, usually of repetitive elements. BRCA1 exon 1A and PsiBRCA1 exon 1A are 44.5 kb apart. In the two families with breast and ovarian cancer mentioned above, distinct homologous recombination events occurred between intron 2 of BRCA1 and intron 2 of PsiBRCA1, leading to 37-kb deletions. Breakpoint junctions were found to be located at close but distinct sites within segments that are 98% identical. The mutant alleles lack the BRCA1 promoter and harbor a chimeric gene consisting of PsiBRCA1 exons 1A, 1B, and 2, which lacks the initiation codon, fused to BRCA1 exons 3-24. Thus, we report a new mutational mechanism for the BRCA1 gene. The presence of a large region homologous to BRCA1 on the same chromosome appears to constitute a hot spot for recombination.