Project description:A subset of cancer cells are intrinsically sensitive to inhibitors targeting PARG, the poly(ADP-ribose) glycohydrolase that degrades PAR chains. Sensitivity is accompanied by persistent DNA replication stress, and can be induced by inhibition of TIMELESS, a replisome accelerator. However, the nature of the oncogenic vulnerability responsible for intrinsic sensitivity remains undetermined. To understand PARG activity dependency, we analyzed Timeless model systems and intrinsically sensitive ovarian cancer cells. We show that nucleoside supplementation rescues all phenotypes associated with PARG inhibitor sensitivity, including replisome speed and fork-restart ability, S-phase completion and mitotic entry, proliferation dynamics and clonogenic potential, in both a TIMELESShaploinsufficient model and intrinsically sensitive cells. Importantly nucleoside supplementation restores PARG inhibitor resistance without reverting PAR chain accumulation, indicating that sensitivity correlates with PAR chain intolerance. We show that inhibition of thymidylate synthase, an enzyme required for dNTP homeostasis, induces PARG-dependency, and, using label-free, quantitative proteomics, we show that PKMYT1, a negative regulator of CDK1, is overexpressed in PARG inhibitor-sensitive cells. Together, these observations suggest that PARG inhibitor sensitivity reflects an inability to control replisome speed and/or maintain helicase-polymerase coupling in response to nucleotide imbalances, in turn applying selective pressure on mitotic entry controls to maintain genome integrity.

Project description:PARG inhibitor sensitivity correlates with accumulation of single strand DNA gaps in preclinical models of ovarian cancer

Project description:Deficiencies in the BRCA1 tumor suppressor gene are the main cause of hereditary breast and ovarian cancer. BRCA1 is involved in the Homologous Recombination DNA repair pathway, and, together with BARD1, forms a heterodimer with ubiquitin E3 activity. The relevance of the BRCA1/BARD1 ubiquitin E3 activity for tumor suppression and DNA repair remains controversial and most efforts aimed to identify BRCA1/BARD1 ubiquitination substrates rely on indirect evidence. Here, we observed that the BRCA1/BARD1 ubiquitin E3 activity was not required for Homologous Recombination or resistance to Olaparib. Using TULIP2 methodology, which enables the direct identification of E3-specific ubiquitination substrates, we identified substrates for BRCA1/BARD1. PCNA is ubiquitinated by BRCA1/BARD1 in unperturbed conditions independently of RAD18, avoiding the formation of ssDNA gaps during DNA replication and promoting replication fork stability upon replication stress, solving the controversy about the function of BRCA1/BARD1 E3 activity in Homologous Recombination.

Project description:To identify origins of replication in Lachancea waltii by mapping regions of ssDNA that are enriched in S phase. L. waltii cells are grown in the presence of hydroxyurea, which slows replication forks and causes the accumulation of ssDNA at the replication fork.

Project description:Lesions on DNA can uncouple DNA synthesis from helicase unwinding, generating stretches of unreplicated single stranded DNA (ssDNA) behind the replication fork. These ssDNA gaps need to be filled in to complete DNA duplication and thereby avoid the generation of DNA double-stranded breaks (DSBs), a major source of genomic instability. Gap filling repair involves either translesion DNA synthesis (TLS) or template switching (TS) to bypass the lesion. At the heart of these processes, ubiquitylated PCNA recruits many proteins that dictate pathway choice, but the enzymes regulating PCNA ubiquitylation in vertebrates remain poorly defined. Here we report that the E3 ubiquitin ligase RFWD3 promotes non-specific ubiquitylation of proteins on ssDNA, to enhance protein accumulation and stimulate gap filling repair. The absence of RFWD3 leads to a profound defect in recruitment of key repair and signaling factors to damaged chromatin, including ubiquitin and proteins known to ubiquitylate and interact with ubiquitylated PCNA. As a result, PCNA ubiquitylation is severely inhibited without RFWD3, and TLS across different DNA lesions drastically impaired. We propose that RFWD3 is an essential coordinator of the response to ssDNA gaps, where it triggers wide spread ubiquitylation to drive recruitment of effectors of PCNA ubiquitylation and DNA damage bypass.

Project description:Lesions on DNA can uncouple DNA synthesis from helicase unwinding, generating stretches of unreplicated single stranded DNA (ssDNA) behind the replication fork. These ssDNA gaps need to be filled in to complete DNA duplication and thereby avoid the generation of DNA double-stranded breaks (DSBs), a major source of genomic instability. Gap filling repair involves either translesion DNA synthesis (TLS) or template switching (TS) to bypass the lesion. At the heart of these processes, ubiquitylated PCNA recruits many proteins that dictate pathway choice, but the enzymes regulating PCNA ubiquitylation in vertebrates remain poorly defined. Here we report that the E3 ubiquitin ligase RFWD3 promotes non-specific ubiquitylation of proteins on ssDNA, to enhance protein accumulation and stimulate gap filling repair. The absence of RFWD3 leads to a profound defect in recruitment of key repair and signaling factors to damaged chromatin, including ubiquitin and proteins known to ubiquitylate and interact with ubiquitylated PCNA. As a result, PCNA ubiquitylation is severely inhibited without RFWD3, and TLS across different DNA lesions drastically impaired. We propose that RFWD3 is an essential coordinator of the response to ssDNA gaps, where it triggers non-specific ubiquitylation to drive recruitment of effectors of PCNA ubiquitylation and DNA damage bypass.

Project description:ADP-ribosylation (ADPr) signaling plays a crucial role in the DNA damage response. Inhibitors against the main enzyme catalyzing ADPr after DNA damage – PARP1 – are used as targeted therapies against breast cancers with BRCA1/2 mutations. However, development of resistance to PARP inhibitors (PARPi) is a major obstacle in treating patients. To better understand the role of ADPr in PARPi sensitivity, we used Liquid Chromatography-Mass Spectrometry (LC-MS) for systems level analysis of the ADP-ribosylome in six breast cancer cell lines with different PARPi sensitivities. We identified 1632 sites on 777 proteins, primarily on serine residues, with a high site overlap of DNA damage-related proteins across all cell lines, demonstrating high conservation in ADPr signaling after DNA damage. We furthermore observed site-specific differences in ADPr intensities in PARPi-sensitive BRCA mutants, and unique ADPr sites in PARPi-resistant BRCA mutant cells, which we notably show to have low PARG levels and longer PARP1 ADPr chains.

Project description:We previously demonstrated that inactivation of the replication checkpoint via a mec1 mutation led to chromosome breakage at replication forks initiated from virtually all origins of replication, after transient exposure to hydroxyurea (HU), an inhibitor of ribonucleotide reductase. Furthermore, we have shown that chromosomes break at replication forks that have suffered single-stranded DNA (ssDNA) formation. Here we sought to determine whether all replication forks containing ssDNA gaps have equal probability of producing double strand breaks (DSBs) when cells attempt to recover from HU exposure. We devised a new methodology, Break-Seq, that combines our previously described DSB labeling with NextGen sequencing to map chromosome breaks with improved sensitivity and resolution. We show that DSBs preferentially occur at genes transcriptionally induced by HU. Notably, different subsets of the HU-induced genes produced DSBs in MEC1 and mec1 cells as replication forks traversed greater distance in MEC1 cells than in mec1 cells during the recovery from HU. Specifically, while MEC1 cells exhibited chromosome breakage at stress-response transcription factors, mec1 cells predominantly suffered chromosome breakage at transporter genes, many of which are the substrates of the said transcription factors. We propose that HU-induced chromosome fragility arises at higher frequency near HU-induced genes as a result of destabilized replication forks encountering transcription factor binding and/or the act of transcription. Our model provides an explanation for a long-standing problem in chromosome biology: why different replication inhibitors produce different spectra of chromosome breakage? We propose that different inhibitors elicit different transcription responses as well as destabilize replication forks, and, when the two processes collide, ssDNA at the replication fork suffers further strand breakage, causing DSBs.

Project description:We previously demonstrated that inactivation of the replication checkpoint via a mec1 mutation led to chromosome breakage at replication forks initiated from virtually all origins of replication, after transient exposure to hydroxyurea (HU), an inhibitor of ribonucleotide reductase. Furthermore, we have shown that chromosomes break at replication forks that have suffered single-stranded DNA (ssDNA) formation. Here we sought to determine whether all replication forks containing ssDNA gaps have equal probability of producing double strand breaks (DSBs) when cells attempt to recover from HU exposure. We devised a new methodology, Break-Seq, that combines our previously described DSB labeling with NextGen sequencing to map chromosome breaks with improved sensitivity and resolution. We show that DSBs preferentially occur at genes transcriptionally induced by HU. Notably, different subsets of the HU-induced genes produced DSBs in MEC1 and mec1 cells as replication forks traversed greater distance in MEC1 cells than in mec1 cells during the recovery from HU. Specifically, while MEC1 cells exhibited chromosome breakage at stress-response transcription factors, mec1 cells predominantly suffered chromosome breakage at transporter genes, many of which are the substrates of the said transcription factors. We propose that HU-induced chromosome fragility arises at higher frequency near HU-induced genes as a result of destabilized replication forks encountering transcription factor binding and/or the act of transcription. Our model provides an explanation for a long-standing problem in chromosome biology: why different replication inhibitors produce different spectra of chromosome breakage? We propose that different inhibitors elicit different transcription responses as well as destabilize replication forks, and, when the two processes collide, ssDNA at the replication fork suffers further strand breakage, causing DSBs.

Project description:The response to Poly (ADP-ribose) polymerase inhibitors (PARPi) is dictated by homologous recombination (HR) DNA repair mechanisms and the abundance of lesions that trap PARP enzymes on chromatin. It remains unclear, however, if the established role of PARP in promoting chromatin accessibility impacts viability in these settings. Using a CRISPR based screen, we identify the PAR-binding Snf2-like ATPase, ALC1 as a key determinant of PARPi toxicity in HR-deficient cells. ALC1 loss reduced viability of BRCA mutant cells and enhanced their sensitivity to PARPi by up to 250-fold, while overcoming several known resistance mechanisms. ALC1 loss was not epistatic to other repair pathways that execute the PARPi response. Instead, ALC1 deficiency reduced chromatin accessibility concomitant with a decrease in the association of repair factors. This resulted in an accumulation of replication associated DNA damage and a reliance on HR. These findings establish PAR-dependent chromatin remodeling as a mechanistically distinct aspect of PARPi responses, implicating ALC1 inhibition as a new approach to overcome therapeutic resistance in HR-deficient cancers.