Project description:An effective long-term inhibition of multiple DNA repair signals is required to design a novel and effective therapeutic for glioblastoma (GBM), a highly DNA repair ‘addicted’ cancer. AsiDNA, a double-strand DNA break (DSB) mimetic, is an innovative approach that shuts down the entire DNA repair system in cancer cells by sequestering DSB repair factors. We showed that inhibition of class I histone deacetylases (HDACs) dislodges repair factors from sites of DNA damage. We therefore tested whether AsiDNA and pan HDAC inhibitor Belinostat combination can impart a chromatin-based long-term DNA damage and impair DNA repair in GBM cells. We performed mass spectrometry with chromatin isolated from AsiDNA and Belinostat and found that Belinostat reduces histone H1.2 levels. To this end, we assessed whether AsiDNA and Belinostat alter histone H1.2 occupancy genome-wide. In order to understand the long-term effects of AsiDNA on DNA repair, we treated U87 cells with AsiDNA for 6 days followed by 6 days recovery from the drug. We used this protocol to create long-term AsiDNA treated cells (LTAU87) according to the clinical trial protocol. We performed NicE-seq with LTAU87 cells and MTU87 (mock treated U87; control) in the presence or absence of belinostat treatment in order to address whether they alter the global chromatin structure.

Project description:An effective long-term inhibition of multiple DNA repair signals is required to design a novel and effective therapeutic for glioblastoma (GBM), a highly DNA repair ‘addicted’ cancer. AsiDNA, a double-strand DNA break (DSB) mimetic, is an innovative approach that shuts down the entire DNA repair system in cancer cells by sequestering DSB repair factors. We showed that inhibition of class I histone deacetylases (HDACs) dislodges repair factors from sites of DNA damage. We therefore tested whether AsiDNA and pan HDAC inhibitor Belinostat combination can impart a chromatin-based long-term DNA damage and impair DNA repair in GBM cells. We performed mass spectrometry with chromatin isolated from AsiDNA and Belinostat and found that Belinostat reduces histone H1.2 levels. To this end, we assessed whether AsiDNA and Belinostat alter histone H1.2 occupancy genome-wide. In order to understand the long-term effects of AsiDNA on DNA repair, we treated U87 cells with AsiDNA for 6 days followed by 6 days recovery from the drug. We used this protocol to create long-term AsiDNA treated cells (LTAU87) according to the clinical trial protocol. We performed H1.2 ChIP-Seq with LTAU87 cells and MTU87 (mock treated U87; control) in the presence and absence of belinostat in order to address whether they alter the global chromatin structure.

Project description:An effective long-term inhibition of multiple DNA repair signals is required to design a novel and effective therapeutic for glioblastoma (GBM), a highly DNA repair ‘addicted’ cancer. AsiDNA, a double-strand DNA break (DSB) mimetic, is an innovative approach that shuts down the entire DNA repair system in cancer cells by sequestering DSB repair factors. We showed that inhibition of class I histone deacetylases (HDACs) dislodges repair factors from sites of DNA damage. We therefore tested whether AsiDNA and pan HDAC inhibitor Belinostat combination can impart a chromatin-based long-term DNA damage and impair DNA repair in GBM cells. In order to understand the long-term effects of AsiDNA on DNA repair, we treated U87 cells with AsiDNA for 6 days followed by 6 days recovery from the drug. We used this protocol to create long-term AsiDNA treated cells (LTAU87) according to the clinical trial protocol. We performed RNA-Seq with LTAU87 cells and MTU87 (mock treated U87; control) in the presence and absence of belinostat.

Project description:In this study, a population of knockout cells was generated using the GeCKO v2 sgRNA library. The population of knockout cells was treated with the PARP inhibitor olaparib for 14 days. Over this time, knockout cells that were sensitive to olaparib treatment would die and a population of knockout cells that was resistant to olaparib treatment remained. Cells from olaparib and DMSO conditions and the sgRNA cassette in the knockout cells was amplified and sequenced to identify synthetic lethal or suppressor interactions with olaparib treatment.

Project description:Exploring non-genetic evolution of cell states during cancer treatments has become attainable by recent advances in lineage-tracing methods. However, transcriptional changes that drive cells into resistant fates may be subtle, necessitating high resolution analysis. We developed ReSisTrace that uses shared transcriptomic features of synchronized sister cells to predict the states that prime treatment resistance. We applied ReSisTrace in ovarian cancer cells to dissect primed resistance against olaparib, carboplatin or natural killer (NK) cells, and  discovered a novel connection between DNA repair deficiency and susceptibility to NK cells. Furthermore, we identified small molecules driving cells to sensitive states prior to treatment. In summary, ReSisTrace resolves pre-existing transcriptional features of treatment vulnerability, facilitating both molecular patient stratification for personalized treatments and discovery of synergistic pre-sensitizing therapies.

Project description:Acquisition of resistance to the PARP inhibitor, Olaparib, constitutes a major challenge for the treatment of advanced prostate cancer. The purpose of this study was to identify molecular targets responsible for the development of acquired Olaparib resistance in advanced prostate cancer. Towards this goal, next-generation sequencing (NGS)-based gene expression profiling (RNA-Sequencing; RNA-Seq) was performed on castration-sensitive prostate cancer (CSPC)/Olaparib-sensitive LNCaP cells, castration-sensitive prostate cancer (CSPC)/Olaparib-resistant LN-OlapR cells, castration-resistant prostate cancer (CSPC)/Olaparib-sensitive C4-2B cells, and castration-resistant prostate cancer (CSPC)/Olaparib-resistant 2B-OlapR cells.

Project description:Analysis of enzalutamide- and/or olaparib-responsive gene expression in prostate cancer cells. The hypothesis tested in the present study was that enzalutamide influences the expression of genes that are involved in important bioprocesses in prostate cance rcells, including DNA damage response genes and this effect may synergize with poly(ADP-ribose) polymerase inhibitor olaparib in cytotoxicity to prstate cancer cells. prostate cancer cells were pretreated with enzalutamide or vehicle control DMSO for 24 h, followed by treatment with enzalutamide, olaparib, enzalutamide+olaparib, or vehicle control DMSO for 48 h. Gene expression in enzalutamide+olaparib-treated cells was compared with taht in vehicle control- and single agent-treated cells.

Project description:Cancer cells exhibit dramatic differences in gene expression at the single-cell level which can predict whether they become resistant to treatment. Treatment perpetuates this heterogeneity, resulting in a diversity of cell states among resistant clones. However, it remains unclear whether these differences lead to distinct responses when another treatment is applied or the same treatment is continued. In this study, we combined single-cell RNA-sequencing with barcoding to track resistant clones through prolonged and sequential treatments. We found that cells within the same clone have similar gene expression states after multiple rounds of treatment. Moreover, we demonstrated that individual clones have distinct and differing fates, including growth, survival, or death, when subjected to a second treatment or when the first treatment is continued. By identifying gene expression states that predict clone survival, this work provides a foundation for selecting optimal therapies that target the most aggressive resistant clones within a tumor.

Project description:Background: Poly (ADP-ribose) polymerase inhibitors (PARPi) prevent single-stranded DNA repair. Olaparib is a PARPi approved for the treatment of BRCA mutant ovarian and breast carcinoma. Emerging clinical data suggest a benefit of combining olaparib with immunotherapy in prostate cancer patients both with and without somatic BRCA mutations. Methods: We examined if olaparib, when combined with IgG1 antibody-dependent cellular cytotoxicity (ADCC)-mediating monoclonal antibodies (mAbs) cetuximab (anti-EGFR), or avelumab (anti-PD-L1), would increase tumor cell sensitivity to killing by natural killer (NK) cells independently of BRCA status or mAb target upregulation. BRCA mutant and BRCA wildtype (WT) prostate carcinoma cell lines were pretreated with olaparib and then exposed to NK cells in the presence or absence of cetuximab or avelumab. Results: NK-mediated killing was significantly increased in both cell lines and was further increased using the ADCC-mediating mAbs. Pre-exposure of NK cells to recombinant IL-15/IL-15RA further increased the lysis of olaparib treated tumor cells. In addition, olaparib treated tumor cells were killed to a significantly greater degree by engineered high-affinity NK cells (haNK). We show here for the first time that (a) olaparib significantly increased tumor cell sensitivity to NK killing and ADCC in both BRCA WT and BRCA mutant prostate carcinoma cells, independent of PD-L1 or EGFR modulation; (b) mechanistically, treatment with olaparib upregulated death receptor TRAIL-R2, and (c) olaparib significantly enhanced NK killing of additional tumor types, including breast, non-small cell lung carcinoma, and chordoma. Conclusions: These studies support the combined use of NK- and ADCC-mediating agents with correctly timed PARP inhibition.

Project description:Sequencing of olaparib-resistant PEO1 derivatives (C4, C5, C10 and C18) and parental PEO1 (P1 and P2) cells was performed in order to determine mechanisms of acquired resistance in the resistant cell lines. PEO1 parental cell lines were authenticated prior to sequencing. PEO1 parental were confirmed to be BRCA2-mutated (5139C>G). Olaparib PEO1 resistant cells were generated through a step-wise escalation of olaparib (10nM to 8uM olaparib). In olaparib resistant lines an increase canonical Wnt signaling and loss of of non-canonical Wnt signaling was observed.