Project description:Although inhibitors of the kinases CHK1, ATR and WEE1 are undergoing clinical testing, it remains unclear how these three classes of agents kill susceptible cells and whether they utilize the same cytotoxic mechanism. Here we observed that CHK1 inhibition induces apoptosis in a subset of acute leukemia cell lines, including TP53 null acute myeloid leukemia (AML) and BCR/ABL-positive acute lymphoid leukemia (ALL), in vitro and inhibits leukemic colony formation in clinical AML samples ex vivo. In further studies, CHK1 downregulation or CHK1 inhibitor treatment triggered signaling in sensitive human acute leukemia cell lines that involved CDK2 activation followed by AP1-dependent TNF transactivation, TNF production and engagement of a TNFR1- and BID-dependent apoptotic pathway. AML lines that were intrinsically CHK1 inhibitor resistant exhibited high CHK1 expression and were sensitized by CHK1 downregulation. Signaling through this same CDK2  AP1  TNF cytotoxic pathway was also initiated by ATR or WEE1 inhibitors in vitro and during CHK1 inhibitor treatment of AML xenografts in vivo. Collectively, these observations not only identify new contributors to antileukemic cell action of CHK1, ATR and WEE1 inhibitors, but also delineate a previously undescribed pathway leading from aberrant CDK2 activation to death ligand-induced killing that can potentially be exploited for acute leukemia treatment.

Project description:Immune checkpoint blockade (ICB) demonstrates durable clinical benefit only in a minority of renal cell carcinoma (RCC) patients. Identifying molecular features that determine response and developing approaches to enhance the response remain an urgent clinical need. Here we found that, in multiple RCC cell lines, targeting the ATR-CHK1 axis with pharmacological inhibitors increased cytosolic DNA accumulation, activated the cGAS-IRF3-dependent cytosolic DNA sensing pathway, and resulted in the inflammatory cytokine expression. SETD2 mutated RCC cell lines or tumor samples were associated with preferential ATR-CHK1 activation over ATM-CHK2 activation. SETD2 knockdown promoted the cytosolic DNA sensing pathway and conferred greater sensitivity in response to ATR-CHK1 inhibition. In murine Renca tumors, Setd2 knockdown and ATR inhibitor VE822 synergistically promoted cytosolic DNA sensing pathway, immune cell infiltration, and immune checkpoint protein expression. Setd2 deficient Renca tumors demonstrated greater vulnerability to ICB monotherapy or in combination with VE822 than Setd2 proficient tumors. SETD2 mutations were associated with a higher response rate and prolonged overall survival in ICB-treated RCC patients, but not in non-ICB-treated RCC patients. This study provides a mechanism-based guidance to develop more personalized combination therapy regimens for RCC patients with SETD2 mutations.

Project description:Excessive genomic instability coupled with abnormalities in DNA repair pathways induce high levels of “replication stress” when cancer cells propagate. Rather than hampering cancer cell proliferation, novel treatment strategies are turning their attention toward targeting cell cycle checkpoint kinases (such as ATR, CHK1, WEE1 and others) along the DNA damage response and replicative stress response pathways, thereby allowing unrepaired DNA damage to be carried forward towards mitotic catastrophe and apoptosis. The selective inhibitor of ATR kinase elimusertib (BAY 1895344), has demonstrated preclinical and clinical monotherapy activity; however, reliable predictive biomarkers of treatment benefit are still lacking. In this study, using gene expression profiling of 24 cell lines from different cancer types and in a panel of ovarian cancer cell lines, we found that nuclear-specific enrichment of checkpoint kinase 1 (CHK1) correlated with increased sensitivity to elimusertib. Using an advanced multispectral imaging system in subsequent cell line-derived xenograft specimens, we showed a trend between nuclear phosphorylated-CHK1 (pCHK1) staining and increased sensitivity to the ATR inhibitor elimusertib, indicating the potential value of pCHK1 expression as a predictive biomarker of ATR inhibitor sensitivity.

Project description:To characterize the downstream gene expression response following ATR inhibition, we performed RNA-Seq after treatment of CLB-BAR and CLB-GE neuroblastoma cells with 50 nM of the ATR inhibitor BAY 1895344 for 24h and 48h

Project description:Although Bcr-Abl kinase inhibitors have proven effective in the treatment of chronic myeloid leukemia (CML), they generally fail to completely eradicate Bcr-Abl+ leukemia cells. To identify genes whose inhibition sensitizes Bcr-Abl+ leukemias to killing by Bcr-Abl inhibitors, we performed an RNAi-based synthetic lethal screen with imatinib in CML cells. This screen identified numerous components of a Wnt/Ca2+/NFAT signaling pathway. Antagonism of this pathway led to impaired NFAT activity, decreased cytokine production and enhanced sensitivity to Bcr-Abl inhibition. Furthermore, NFAT inhibition with cyclosporin A facilitated leukemia cell elimination by the Bcr-Abl inhibitor dasatinib and markedly improved survival in a mouse model of Bcr-Abl+ acute lymphoblastic leukemia (ALL). Targeting this pathway in combination with Bcr-Abl inhibition could improve treatment of Bcr-Abl+ leukemias. We utilized a genome-wide shRNA library in combination with microarray analysis to screen for gene targets in chronic myeloid leukemia cells that cooperate with imatinib.

Project description:To understand the in vivo transcriptomic response to ATR inhibition, RNA-Seq was performed 3 days after treatment of a previously developed neuroblastoma mouse model (Alk-F1178S;Th-MYCN; see Borenas et al., EMBO J, 2021) with the ATR inhibitor ceralasertib.

Project description:To understand the in vivo transcriptomic response to ATR inhibition, RNA-Seq was performed after treatment of 2 previously developed neuroblastoma mouse models (Alk-F1178S;Th-MYCN and Rosa26_Alkal2;Th-MYCN; see Borenas et al., EMBO J, 2021) with the ATR inhibitor BAY 1895344.

Project description:AXL is a receptor tyrosine kinase that is often overexpressed in cancers. It contributes to pathophysiology in cancer progression and therapeutic resistance, making it an emerging therapeutic target. The first-in-class AXL inhibitor bemcentinib (R428/BGB324) has been granted fast track designation by the U.S. Food and Drug Administration (FDA) in STK11-mutated advanced metastatic non-small cell lung cancer and was also reported to show selective sensitivity towards ovarian cancers (OC) with a Mesenchymal molecular subtype. In this study, we further explored AXL’s role in mediating DNA damage responses by using OC as a disease model. AXL inhibition using R428 resulted in the increase of DNA damage with the concurrent upregulation of DNA damage response signalling molecules. Furthermore, AXL inhibition rendered cells more sensitive to the inhibition of ATR, a crucial mediator for replication stress. Combinatory use of AXL and ATR inhibitors showed additive effects in OC. Through SILAC co-immunoprecipitation mass spectrometry, we identified a novel binding partner of AXL, SAM68, whose loss in OC cells harboured phenotypes in DNA damage responses similar to AXL inhibition. In addition, AXL- and SAM68-deficiency or R428 treatment induced elevated levels of cholesterol and upregulated genes in the cholesterol biosynthesis pathway. There might be a novel protective role of cholesterol in shielding cancer cells against DNA damage induced by AXL inhibition or SMA68 deficiency.  

Project description:Although Bcr-Abl kinase inhibitors have proven effective in the treatment of chronic myeloid leukemia (CML), they generally fail to completely eradicate Bcr-Abl+ leukemia cells. To identify genes whose inhibition sensitizes Bcr-Abl+ leukemias to killing by Bcr-Abl inhibitors, we performed an RNAi-based synthetic lethal screen with imatinib in CML cells. This screen identified numerous components of a Wnt/Ca2+/NFAT signaling pathway. Antagonism of this pathway led to impaired NFAT activity, decreased cytokine production and enhanced sensitivity to Bcr-Abl inhibition. Furthermore, NFAT inhibition with cyclosporin A facilitated leukemia cell elimination by the Bcr-Abl inhibitor dasatinib and markedly improved survival in a mouse model of Bcr-Abl+ acute lymphoblastic leukemia (ALL). Targeting this pathway in combination with Bcr-Abl inhibition could improve treatment of Bcr-Abl+ leukemias.

Project description:High-risk neuroblastoma (NB) often involves amplification of the neural MYC (MYCN) oncogene as well as mutations in ALK. Currently, high-risk NB presents significant clinical challenges, and additional therapeutic options are needed. Oncogenes such as MYCN and ALK result in increased replication stress in cancer cells, offering one such therapeutically exploitable option. Here, we followed up on earlier phosphoproteomic analyses that identified ATR activity in ALK-driven NB cell lines. We tested several ATR inhibitors, identifying BAY 1895344 as the most potent inhibitor of NB cell growth and proliferation. Using RNA-Seq, proteomics and phosphoproteomics we characterized the response of NB cells and tumours to ATR inhibition, identifying key components of the DNA damage response (DDR) as well as ATRX, MYCN, E2F and DCK among other ATR targets in NB cells. ATR inhibition with BAY 1895344 also produced robust responses in mouse NB models. Remarkably, a 2 week protocol combining ATR and ALK inhibition led to complete regression of NB tumours in two independent NB genetically modified mouse tumour models. These results suggest that NB patients, particularly in high-risk groups with oncogene induced replication stress, may benefit from inhibition of ATR as therapeutic intervention.