Project description:While BRCA-related cancers respond well to double-strand break (DSB) inducing agents, resistance is a serious clinical problem. One mechanism of resistance is reversion of the BRCA1 mutation, suggesting that BRCA1 function is required for resistance. Here we show that secondary Brca1 mutations are not always necessary, since residual activity of the mutant BRCA1 protein can be sufficient for tumor cells to withstand treatment. Genomic profiling and RAD51 foci formation are currently seen as potential biomarkers to stratify patients for therapies targeting homologous recombination deficiency (HRD). However, we show that while mouse mammary tumors with different Brca1 mutations have identical genomic profiles, they respond considerably different to HRD targeted therapy. It may therefore be useful to stratify patients according to functional assays and the underlying BRCA1 mutation. We performed aCGH on mammary tumor DNA from KB1C61GP (n=20), littermate KB1P (n=18) and KP mice (n=19). Spleen DNA of the same animal was used as control material.

Project description:While BRCA-related cancers respond well to double-strand break (DSB) inducing agents, resistance is a serious clinical problem. One mechanism of resistance is reversion of the BRCA1 mutation, suggesting that BRCA1 function is required for resistance. Here we show that secondary Brca1 mutations are not always necessary, since residual activity of the mutant BRCA1 protein can be sufficient for tumor cells to withstand treatment. Genomic profiling and RAD51 foci formation are currently seen as potential biomarkers to stratify patients for therapies targeting homologous recombination deficiency (HRD). However, we show that while mouse mammary tumors with different Brca1 mutations have identical genomic profiles, they respond considerably different to HRD targeted therapy. It may therefore be useful to stratify patients according to functional assays and the underlying BRCA1 mutation. We performed aCGH on mammary tumor DNA from KB1(185stop)P (n=20), KB1(5382stop)P (n=20) and littermate KB1P (n=22). Spleen DNA of the same animal was used as control material.

Project description:CRISPR Cas9-based functional genomics screening is a powerful approach for identifying and characterizing novel oncology drug targets. Here, we elucidate the synthetic lethal mechanism of deubiquitinating enzyme USP1 in cancers with underlying DNA damage vulnerabilities, specifically BRCA1/2 mutant tumors and a subset of BRCA1/2 wild-type (WT) tumors. In sensitive cells, pharmacological inhibition of USP1 leads to decreased DNA synthesis concomitant with the induction of S-phase-specific DNA damage. Genome-wide CRISPR-Cas9 screens identified RAD18 and UBE2K, which promote PCNA mono- and polyubiquitination respectively, as downstream mediators of USP1 dependency. The accumulation of mono- and polyubiquitinated PCNA following USP1 inhibition was associated with a reduction in total PCNA protein levels. Ectopic expression of WT and ubiquitin-dead K164R PCNA reversed USP1 inhibitor sensitivity. Our results demonstrate, for the first time, that USP1 dependency hinges on the aberrant processing of mono- and polyubiquitinated PCNA. Moreover, this mechanism of USP1 dependency extends beyond BRCA1/2 mutant tumors to a novel subset of BRCA1/2 WT cancer enriched in ovarian and lung lineages. We further show PARP and USP1 inhibition are strongly synergistic in BRCA1/2 mutant cell lines and xenograft models. We postulate USP1 dependency unveils a previously uncharacterized vulnerability linked to post-translational modifications of PCNA. Taken together, USP1 inhibition may represent a unique therapeutic strategy for BRCA1/2 mutant tumors and a subset of BRCA1/2 WT tumors.

Project description:Homologous-recombination deficiency (HRD) is closely related to PARPi benefit in ovarian cancer (OC). The capacity of BRCA1 promoter methylation to predict prognosis and HRD status remains unclear. We aimed to correlate BRCA1 promoter methylation levels in patients with high-grade OC to HRD status and clinical behavior to assess its clinical relevance.

Project description:Although PARP inhibitors (PARPi) now form part of the standard-of-care for the treatment of homologous recombination defective cancers, de novo and acquired resistance limits their overall effectiveness. Previously, overexpression of the BRCA1-∆11q splice variant has been shown to cause PARPi resistance. How cancer cells achieve increased BRCA1-∆11q expression has remained unclear. Using isogenic cells with different BRCA1 mutations, we show that reduction in HUWE1 leads to increased levels of BRCA1-∆11q and PARPi resistance. This effect is specific to cells able to express BRCA1-∆11q (e.g. BRCA1 exon 11 mutant cells) and is not seen in BRCA1 mutants that cannot express BRCA1-∆11q, nor in BRCA2 mutant cells. As well as increasing levels of BRCA1-∆11q protein in exon 11 mutant cells, HUWE1 silencing also restores RAD51 nuclear foci and platinum salt resistance. HUWE1 catalytic domain mutations were also seen in a case of PARPi resistant, BRCA1 exon 11 mutant, high grade serous ovarian cancer. These results suggest how elevated levels of BRCA1-∆11q and PARPi resistance can be achieved, identify HUWE1 as a candidate biomarker of PARPi resistance for assessment in future clinical trials and illustrate how some PARPi resistance mechanisms may only operate in patients with particular BRCA1 mutations.

Project description:While BRCA-related cancers respond well to double-strand break (DSB) inducing agents, resistance is a serious clinical problem. One mechanism of resistance is reversion of the BRCA1 mutation, suggesting that BRCA1 function is required for resistance. Here we show that secondary Brca1 mutations are not always necessary, since residual activity of the mutant BRCA1 protein can be sufficient for tumor cells to withstand treatment. Genomic profiling and RAD51 foci formation are currently seen as potential biomarkers to stratify patients for therapies targeting homologous recombination deficiency (HRD). However, we show that while mouse mammary tumors with different Brca1 mutations have identical genomic profiles, they respond considerably different to HRD targeted therapy. It may therefore be useful to stratify patients according to functional assays and the underlying BRCA1 mutation.

Project description:While BRCA-related cancers respond well to double-strand break (DSB) inducing agents, resistance is a serious clinical problem. One mechanism of resistance is reversion of the BRCA1 mutation, suggesting that BRCA1 function is required for resistance. Here we show that secondary Brca1 mutations are not always necessary, since residual activity of the mutant BRCA1 protein can be sufficient for tumor cells to withstand treatment. Genomic profiling and RAD51 foci formation are currently seen as potential biomarkers to stratify patients for therapies targeting homologous recombination deficiency (HRD). However, we show that while mouse mammary tumors with different Brca1 mutations have identical genomic profiles, they respond considerably different to HRD targeted therapy. It may therefore be useful to stratify patients according to functional assays and the underlying BRCA1 mutation.

Project description:The poly (ADP-ribose) polymerases (PARPs) inhibitors are an exciting new class of agents that have shown efficacy in treating various cancers, especially these harboring BRCA1/2 mutations. The cancer associated BRCA1/2 mutations disrupt DNA double strand break (DSB) repair by homologous recombination (HR). PARP inhibitors (PARPi) have been applied to trigger synthetic lethality in BRCA1/2-mutated cancer cells by promoting accumulation of toxic DSBs. Unfortunately, PARP inhibitor (PARPi) resistance is common and develops through multiple mechanisms. Restoration of HR and/or stabilizing replication forks are two major mechanisms of PARPi resistance in BRCA1/2-mutated cells. To further understand the mechanisms of drug resistance to PARPi, we undertook an unbiased approach with a CRISPR-pooled library to screen new genes whose loss-of-function confers resistance to PARPi olaparib. We identified ZNF251, a transcription factor, and confirmed its loss-of-function led to the PARPi resistance in BRCA1-mutated breast and ovarian cancer lines. Elevated activities of both HR and non-homologous end joining (NHEJ) repair were detected in cancer cells harboring BRCA1 mutation and ZNF251 deletion (BRCA1mut+ZNF251del) and were associated with enhanced expression of RAD51 and Ku70/Ku80, respectively. Furthermore, we showed that DNA-PKcs inhibitor restored sensitivity of BRCA1mut+ZNF251del cells to PARPi. Taken together, our study identified a novel gene whose loss of function conferred resistance to PARPi, providing new insight into signaling pathways that contribute to acquired resistance in BRCA1-mutated breast and ovarian cancers.

Project description:BRCA1/2-deficient ovarian carcinoma (OC) has been shown to be particularly sensitive to PARP inhibitors (PARPis) and BRCA1/2 mutation status is currently used as a predictive biomarker for PARPi therapy. Despite eliciting major clinical benefit for the majority of patients, a significant proportion of BRCA1/2-deficient OC tumors do not respond to PARPis for reasons that are incompletely understood. Using an integrated chemical, phospho- and ADP-ribosylation proteomics approach, we sought to develop additional mechanism-based biomarker candidates for PARPi therapy in OC and identify new targets for combination therapy to overcome primary resistance. Chemical proteomics with PARPi baits in a BRCA1-isogenic OC cell line pair, as well as patient-derived BRCA1-profiecient and deficient tumor samples, and subsequent validation by co-immunoprecipitation showed differential PARP1 and PARP2 protein complex composition with Ku70 and Ku80 in PARPi-sensitive, BRCA1-deficient UWB1.289 (UWB) cells compared to PARPi-insensitive, BRCA1-reconstituted UWB1.289 (UWB+B) cells. Global phosphoproteomics and ADP-ribosylation proteomics furthermore revealed that rucaparib induced the cell cycle pathway and NHEJ pathway in UWB cells, but down-regulated ErbB signaling in UWB+B cells. In addition, we observed AKT PARylation and pro-survival AKT-mTOR signaling in UWB+B cells after PARPi treatment. Consistently, synergy of PARPis with DNAPK or AKT inhibitors was more pronounced in UWB+B cells identifying these pathways as actionable vulnerabilities. In conclusion, the combination of chemical proteomics, phosphoproteomics and ADP-ribosylation proteomics can identify differential PARP1/2 complexes and diverse, but actionable drug compensatory signaling in OC.

Project description:BRCA1/2-deficient ovarian carcinoma (OC) has been shown to be particularly sensitive to PARP inhibitors (PARPis) and BRCA1/2 mutation status is currently used as a predictive biomarker for PARPi therapy. Despite eliciting major clinical benefit for the majority of patients, a significant proportion of BRCA1/2-deficient OC tumors do not respond to PARPis for reasons that are incompletely understood. Using an integrated chemical, phospho- and ADP-ribosylation proteomics approach we sought to develop additional mechanism-based biomarker candidates for PARPi therapy in OC and identify new targets for combination therapy to overcome primary resistance. Chemical proteomics with PARPi baits in a BRCA1-isogenic OC cell line pair, as well as patient-derived BRCA1-profiecient and deficient tumor samples, and subsequent validation by co-immunoprecipitation showed differential PARP1 and PARP2 protein complex composition with Ku70 and Ku80 in PARPi-sensitive, BRCA1-deficient UWB1.289 (UWB) cells compared to PARPi-insensitive, BRCA1-reconstituted UWB1.289 (UWB+B) cells. Global phosphoproteomics and ADP-ribosylation proteomics furthermore revealed that rucaparib induced the cell cycle pathway and NHEJ pathway in UWB cells, but down-regulated ErbB signaling in UWB+B cells. In addition, we observed AKT PARylation and pro-survival AKT-mTOR signaling in UWB+B cells after PARPi treatment. Consistently, synergy of PARPis with DNAPK or AKT inhibitors was more pronounced in UWB+B cells identifying these pathways as actionable vulnerabilities. In conclusion, the combination of chemical proteomics, phosphoproteomics and ADP-ribosylation proteomics can identify differential PARP1/2 complexes and diverse, but actionable drug compensatory signaling in OC.