Lee Zou

Replication protein A-mediated recruitment and activation of Rad17 complexes

The human Rad17–Rfc2-5 and Rad9–Rad1–Hus1 complexes play crucial roles in the activation of the ATR-mediated DNA damage and DNA replication stress response pathways. In response to DNA damage, Rad9 is recruited to chromatin in a Rad17-dependent manner in human cells. However, the DNA structures recognized by the Rad17–Rfc2-5 complex during the damage response have not been defined. Here, we show that replication protein A (RPA) stimulates the binding of the Rad17–Rfc2-5 complex to single-stranded DNA (ssDNA), primed ssDNA, and a gapped DNA structure. Furthermore, RPA facilitates the recruitment of the Rad9–Rad1–Hus1 complex by the Rad17–Rfc2-5 complex to primed and gapped DNA structures in vitro. These findings suggest that RPA-coated ssDNA is an important part of the structures recognized by the Rad17–Rfc2-5 complex. Unlike replication factor C (RFC), which uses the 3′ primer/template junction to recruit proliferating cell nuclear antigen (PCNA), the Rad17–Rfc2-5 complex can use both the 5′ and the 3′ primer/template junctions to recruit the Rad9–Rad1–Hus1 complex, and it shows a preference for gapped DNA structures. These results explain how the Rad17–Rfc2-5 complex senses DNA damage and DNA replication stress to initiate checkpoint signaling.

Checking on the fork: the DNA-replication stress-response pathway

To ensure the fidelity of DNA replication, cells activate a stress-response pathway when DNA replication is perturbed. This pathway regulates not only progress through the cell cycle but also transcription, apoptosis, DNA repair/recombination and DNA replication itself. Mounting evidence has suggested that this pathway is important for the maintenance of genomic integrity. Here, we discuss recent findings about how this pathway is activated by replication stress and how it regulates the DNA-replication machinery to alleviate the stress.

DNA damage sensing by the ATM and ATR kinases.

In eukaryotic cells, maintenance of genomic stability relies on the coordinated action of a network of cellular processes, including DNA replication, DNA repair, cell-cycle progression, and others. The DNA damage response (DDR) signaling pathway orchestrated by the ATM and ATR kinases is the central regulator of this network in response to DNA damage. Both ATM and ATR are activated by DNA damage and DNA replication stress, but their DNA-damage specificities are distinct and their functions are not redundant. Furthermore, ATM and ATR often work together to signal DNA damage and regulate downstream processes. Here, we will discuss the recent findings and current models of how ATM and ATR sense DNA damage, how they are activated by DNA damage, and how they function in concert to regulate the DDR.

Single-Stranded DNA Orchestrates an ATM-to-ATR Switch at DNA Breaks

ATM and ATR are two master checkpoint kinases activated by double-stranded DNA breaks (DSBs). ATM is critical for the initial response and the subsequent ATR activation. Here we show that ATR activation is coupled with loss of ATM activation, an unexpected ATM-to-ATR switch during the biphasic DSB response. ATM is activated by DSBs with blunt ends or short single-stranded overhangs (SSOs). Surprisingly, the activation of ATM in the presence of SSOs, like that of ATR, relies on single- and double-stranded DNA junctions. In a length-dependent manner, SSOs attenuate ATM activation and potentiate ATR activation through a swap of DNA-damage sensors. Progressive resection of DSBs directly promotes the ATM-to-ATR switch in vitro. In cells, the ATM-to-ATR switch is driven by both ATM and the nucleases participating in DSB resection. Thus, single-stranded DNA orchestrates ATM and ATR to function in an orderly and reciprocal manner in two distinct phases of DSB response.

Regulation of homologous recombination by RNF20-dependent H2B ubiquitination.

The E3 ubiquitin ligase RNF20 regulates chromatin structure by monoubiquitinating histone H2B in transcription. Here, we show that RNF20 is localized to double-stranded DNA breaks (DSBs) independently of H2AX and is required for the DSB-induced H2B ubiquitination. In addition, RNF20 is required for the methylation of H3K4 at DSBs and the recruitment of the chromatin-remodeling factor SNF2h. Depletion of RNF20, depletion of SNF2h, or expression of the H2B mutant lacking the ubiquitination site (K120R) compromises resection of DNA ends and recruitment of RAD51 and BRCA1. Consequently, cells lacking RNF20 or SNF2h and cells expressing H2B K120R exhibit pronounced defects in homologous recombination repair (HRR) and enhanced sensitivity to radiation. Finally, the function of RNF20 in HRR can be partially bypassed by forced chromatin relaxation. Thus, the RNF20-mediated H2B ubiquitination at DSBs plays a critical role in HRR through chromatin remodeling.

TERRA and hnRNPA1 orchestrate an RPA-to-POT1 switch on telomeric single-stranded DNA

Maintenance of telomeres requires both DNA replication and telomere ‘capping’ by shelterin. These two processes use two single-stranded DNA (ssDNA)-binding proteins, replication protein A (RPA) and protection of telomeres 1 (POT1). Although RPA and POT1 each have a critical role at telomeres, how they function in concert is not clear. POT1 ablation leads to activation of the ataxia telangiectasia and Rad3-related (ATR) checkpoint kinase at telomeres, suggesting that POT1 antagonizes RPA binding to telomeric ssDNA. Unexpectedly, we found that purified POT1 and its functional partner TPP1 are unable to prevent RPA binding to telomeric ssDNA efficiently. In cell extracts, we identified a novel activity that specifically displaces RPA, but not POT1, from telomeric ssDNA. Using purified protein, here we show that the heterogeneous nuclear ribonucleoprotein A1 (hnRNPA1) recapitulates the RPA displacing activity. The RPA displacing activity is inhibited by the telomeric repeat-containing RNA (TERRA) in early S phase, but is then unleashed in late S phase when TERRA levels decline at telomeres. Interestingly, TERRA also promotes POT1 binding to telomeric ssDNA by removing hnRNPA1, suggesting that the re-accumulation of TERRA after S phase helps to complete the RPA-to-POT1 switch on telomeric ssDNA. Together, our data suggest that hnRNPA1, TERRA and POT1 act in concert to displace RPA from telomeric ssDNA after DNA replication, and promote telomere capping to preserve genomic integrity.

Alternative Lengthening of Telomeres Renders Cancer Cells Hypersensitive to ATR Inhibitors

Cancers alternative means to an end To stay alive and proliferating, tumor cells must maintain their telomeres: the DNA sequences at the ends of chromosomes. The majority accomplish this by activating the enzyme telomerase. However, certain tumor types favor a different mechanism called alternative lengthening of telomeres (ALT), which involves DNA recombination. Flynn et al. delineated the molecular events that occur at the telomeres of ALT-proficient tumor cells by studying the function of a protein that is altered by mutation in these tumors. The analysis revealed a specific protein kinase that is essential for ALT, which could in principle be targeted to halt tumor growth. Science, this issue p. 273 A potential therapeutic strategy is identified for tumor cells that maintain their telomeres by an unusual mechanism. Cancer cells rely on telomerase or the alternative lengthening of telomeres (ALT) pathway to overcome replicative mortality. ALT is mediated by recombination and is prevalent in a subset of human cancers, yet whether it can be exploited therapeutically remains unknown. Loss of the chromatin-remodeling protein ATRX associates with ALT in cancers. Here, we show that ATRX loss compromises cell-cycle regulation of the telomeric noncoding RNA TERRA and leads to persistent association of replication protein A (RPA) with telomeres after DNA replication, creating a recombinogenic nucleoprotein structure. Inhibition of the protein kinase ATR, a critical regulator of recombination recruited by RPA, disrupts ALT and triggers chromosome fragmentation and apoptosis in ALT cells. The cell death induced by ATR inhibitors is highly selective for cancer cells that rely on ALT, suggesting that such inhibitors may be useful for treatment of ALT-positive cancers.

ATR: a master conductor of cellular responses to DNA replication stress.

The integrity of the genome is constantly challenged by intrinsic and extrinsic genotoxic stresses that damage DNA. The cellular responses to DNA damage are orchestrated by DNA damage signaling pathways, also known as DNA damage checkpoints. These signaling pathways play crucial roles in detecting DNA damage, regulating DNA repair and coordinating DNA repair with other cellular processes. In vertebrates, the ATM- and Rad3-related (ATR) kinase plays a key role in the response to a broad spectrum of DNA damage and DNA replication stress. Here, we will discuss the recent findings on how ATR is activated by DNA damage and how it protects the genome against interference with DNA replication.

CRL4Cdt2-Mediated Destruction of the Histone Methyltransferase Set8 Prevents Premature Chromatin Compaction in S Phase

The proper coordination between DNA replication and mitosis during cell-cycle progression is crucial for genomic stability. During G2 and mitosis, Set8 catalyzes monomethylation of histone H4 on lysine 20 (H4K20me1), which promotes chromatin compaction. Set8 levels decline in S phase, but why and how this occurs is unclear. Here, we show that Set8 is targeted for proteolysis in S phase and in response to DNA damage by the E3 ubiquitin ligase, CRL4(Cdt2). Set8 ubiquitylation occurs on chromatin and is coupled to DNA replication via a specific degron in Set8 that binds PCNA. Inactivation of CRL4(Cdt2) leads to Set8 stabilization and aberrant H4K20me1 accumulation in replicating cells. Transient S phase expression of a Set8 mutant lacking the degron promotes premature H4K20me1 accumulation and chromatin compaction, and triggers a checkpoint-mediated G2 arrest. Thus, CRL4(Cdt2)-dependent destruction of Set8 in S phase preserves genome stability by preventing aberrant chromatin compaction during DNA synthesis.

ATR Autophosphorylation as a Molecular Switch for Checkpoint Activation

The ataxia telangiectasia-mutated and Rad3-related (ATR) kinase is a master checkpoint regulator safeguarding the genome. Upon DNA damage, the ATR-ATRIP complex is recruited to sites of DNA damage by RPA-coated single-stranded DNA and activated by an elusive process. Here, we show that ATR is transformed into a hyperphosphorylated state after DNA damage, and that a single autophosphorylation event at Thr 1989 is crucial for ATR activation. Phosphorylation of Thr 1989 relies on RPA, ATRIP, and ATR kinase activity, but unexpectedly not on the ATR stimulator TopBP1. Recruitment of ATR-ATRIP to RPA-ssDNA leads to congregation of ATR-ATRIP complexes and promotes Thr 1989 phosphorylation in trans. Phosphorylated Thr 1989 is directly recognized by TopBP1 via the BRCT domains 7 and 8, enabling TopBP1 to engage ATR-ATRIP, to stimulate the ATR kinase, and to facilitate ATR substrate recognition. Thus, ATR autophosphorylation on RPA-ssDNA is a molecular switch to launch robust checkpoint response.