Project description:PARP inhibitors (PARPi) present a remarkable advance in the treatment of patients with homologous recombination (HR)-deficient tumors but resistance remains a challenge1-5. While most research has focused on the downstream consequences of PARPi exposure to tackle resistance, the immediate impact of PARP inhibition on the chromatin environment and its contribution to PARPi toxicity remains elusive. Here, we show that PARP inhibition induces histone release from the chromatin. This presents a vulnerability of PARPi-resistant cancer cells, which are addicted to histone homeostasis mechanisms to sustain elevated DNA replication rates and survival. Through functional genetic screens, we identified NASP as a key factor in maintaining the stability of evicted histones via its TPR motifs. NASP loss renders tumor cells hypersensitive to PARPi treatment in vitro and in vivo, impairs replication fork progression and elevates levels of replication-associated DNA damage. Moreover, NASP acts together with the INO80 complex and the chaperoning activity of PARP1 to ensure efficient histone turnover and prevent the accumulation of lethal DNA damage following PARPi exposure. Collectively, our work reports on histone eviction as an immediate cellular response to PARPi treatment and provides a promising avenue for targeting histone supply pathways to overcome PARPi resistance.

Project description:Background: PARP inhibitors (PARPi) kill cancer cells by stalling DNA replication and preventing DNA repair, resulting in a critical accumulation of DNA damage. Resistance to PARPi is a growing clinical problem in the treatment of high grade serous ovarian carcinoma (HGSOC). Acetylation of histone H3 lysine 14 (H3K14ac) and associated histone acetyltransferases (HATs) have known functions in DNA repair and replication, but their expression and activities have not been examined in the context of PARPi-resistant HGSOC. Results: Using mass spectrometry profiling of histone modifications, we observed altered H3K14ac enrichment in PARPi-resistant HGSOC cells relative to isogenic PARPi-sensitive lines. By RT-qPCR and RNA-Seq, we also observed altered expression of numerous HATs in PARPi-resistant HGSOC cells and a PARPi-resistant PDX model. Knockdown of HATs only modestly altered PARPi response, although knockdown and inhibition of PCAF significantly increased resistance. Pharmacologic inhibition of HBO1 severely depleted H3K14ac but did not affect PARPi response. However, knockdown and inhibition of BRPF3, which is known to interact in a complex with HBO1, did reduce PARPi resistance. Conclusions: This study demonstrates that severe depletion of H3K14ac does not affect PARPi response in HGSOC. Our data suggest that bromodomain functions of HAT proteins such as PCAF, or accessory proteins such as BRPF3, may play a greater role in PARPi response than acetyltransferase functions.

Project description:PARP inhibitors (PARPi) resistance is not well understood in prostate cancer (PC). The aim of the study was to identify new resistance mechanisms in PC by developing acquired olaparib-resistance PC cell lines.

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: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.

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.

Project description:Chemical modifications of RNAs have emerged as a new layer of epigenetic gene regulation. N6-methyladenosine (m6A) is the most abundant chemical modification of messenger RNA (mRNA). The m6A modification affects RNA fate and functions such as RNA stability. Despite the high initial response rates to PARP inhibitors in BRCA1/2-mutated epithelial ovarian cancers (EOC), PARP inhibitor (PARPi) resistance remains a major challenge. The role of m6A modification in PARPi resistance has not previously been explored. Here we show that m6A modification of FZD10 mRNA contributes to PARPi resistance by upregulating the Wnt/-catenin pathway in BRCA-mutated EOC cells. Global m6A profile reveals a significant increase in m6A modification in FZD10 mRNA. This correlates with an increase in FZD10 mRNA stability and an upregulation of the Wnt/-catenin pathway in PARPi resistant cells. FZD10 knockdown or inhibition of the Wnt/-catenin sensitizes the resistant cells to PARPi. Mechanistically, downregulation of m6A demethylases FTO and ALKBH5 is sufficient to increase FZD10 mRNA m6A modification and reduce PARPi sensitivity, which correlates with an increase in homologous recombination activity. Moreover, PAPRi and Wnt/-catenin inhibitor showed synergistic suppression of growth of PAPRi resistant cells both in vitro and in vivo in a xenograft ovarian cancer mouse model. Our results show that m6A contributes to PAPRi resistance in BRCA-deficient EOC cells by upregulating the Wnt/-catenin pathway through stabilizing FZD10. They also suggest that inhibition of Wnt/-catenin pathway represents a potential strategy to overcome PARPi resistance.

Project description:Metastatic melanoma is either intrinsically resistant or rapidly acquires resistance to targeted drugs such as MAPK inhibitors (MAPKi). Here, using a drug screen targeting chromatin regulators in patient-derived 3D melanoma cell cultures, we discovered that PARP inhibitors are capable of restoring MAPKi sensitivity. This synergy was found to be independent of DNA damage repair pathways and was effective both in vitro and in vivo in patients-derived xenografts. Strikingly, through integrated transcriptomic, proteomic and epigenomic analysis, we discovered that PARPi induces lysosomal autophagy which was accompanied by enhanced mitochondrial lipid metabolism that, ultimately, increased antigen presentation and sensitivity to T-cell cytotoxicity. Moreover, we also found that PARP inhibitors regulated EMT-like phenotype switching by dampening the mesenchymal phenotype via transcriptomic and epigenetic rearrangements. This, in turn, redirected melanoma cells towards a proliferative and, thus, MAPKi-sensitive state. Our study provides a scientific rational for treating patients with PARPi in combination with MAPKi to annihilate acquired therapy resistance.

Project description:PARP inhibitor (PARPi)-resistant BRCA mutant (BRCAm) high-grade serous ovarian cancer (HGSOC) represents a new clinical challenge with unmet therapeutic needs. Quantitative high-throughput drug combination screen identifies that ATR inhibitor (ATRi) and AKT inhibitor (AKTi) combination is a rational treatment strategy for both PARPi-sensitive and PARPi-resistant BRCAm HGSOC by inducing DNA damage and R-loop-mediated replication stress (RS). Mechanistically, the kinase domain of AKT1 directly interacts with DHX9, thus facilitating recruitment of DHX9 to R-loops. AKTi increases ATRi-induced R-loop-mediated RS by mitigating recruitment of DHX9 to R-loops. Moreover, DHX9 is upregulated in tumors from PARPi-resistant BRCAm HGSOC patients and high co-expression of DHX9 and AKT1 correlates with worse survival. Our study reveals a previously unknown interaction between AKT1 and DHX9 in R-loop resolution and novel mechanisms of action of AKTi and ATRi combination. Our data also provide a rationale for the clinical development of ATRi and AKTi combination for BRCAm HGSOC irrespective of PARPi resistance status and a potential biomarker to predict the response of combination therapy.

Project description:PARP inhibitors (PARPi) prevent cancer cell growth by inducing synthetic lethality with DNA repair defects (e.g., in BRCA1/2 mutant cells). We have identified an alternate pathway for PARPi-mediated growth control in BRCA1/2-intact breast cancer cells involving rDNA transcription and ribosome biogenesis. PARP-1 binds to snoRNAs, which stimulate PARP-1 catalytic activity in the nucleolus independent of DNA damage. Activated PARP-1 ADP-ribosylates DDX21, an RNA helicase that localizes to nucleoli and promotes rDNA transcription when ADP-ribosylated. Treatment with PARPi or mutation of the ADP-ribosylation sites reduce DDX21 nucleolar localization, rDNA transcription, ribosome biogenesis, protein translation, and cell growth. The salient features of this pathway are evident in xenografts in mice and human breast cancer patient samples. Elevated levels of PARP-1 and nucleolar DDX21 are associated with cancer-related outcomes. Our studies provide a mechanistic rationale for efficacy of PARPi in cancer cells lacking defects in DNA repair whose growth is inhibited by PARPi.