Project description:Therapeutic resistance to DNA damage is a significant challenge in oncology. To gain insight into biological mechanisms that cause DNA damage resistance and to inform strategies for achieving synergy with therapeutic radiation, we performed parallel pooled genetic CRISPR-Cas9 screening for survival in high-risk head and neck squamous cell carcinoma (HNSCC) subtypes. Surprisingly, in addition to known mediators of radiotherapy response, including ATM, DNAPK, and NF-κB signaling, loss of JAK1 was identified as a driver of tumor cell radioresistance. Knockout of JAK1 in HNSCC increased cell survival by enhancing the DNA damage-dependent G2/M cell cycle arrest and delaying progression to radiation-induced mitotic catastrophe. In line with this finding, both JAK1 knockout and kinase inhibition with abrocitinib prevented subsequent formation of radiation-induced micronuclei. Loss of JAK1 function did not affect canonical CDK1 signaling but instead reduced activation of PLK1 and AURKA, two kinases with auxiliary roles in the regulation of G2 and M phase progression. Correspondingly, using both EdU labelling and live cell imaging techniques, JAK1 loss was found to cause prolonged metaphase, mitotic slippage, and progression to tetraploidy. Targeting the mitotic kinesin KIF18A with the small molecule sovilnesib exacerbated mitotic stress and enhanced the efficacy of radiation. These studies establish KIF18A inhibition as a strategy to counteract the protective G2/M cell cycle arrest induced by DNA damage and to thus enhance tumor cell sensitivity to radiation therapy.

Project description:Therapeutic resistance to DNA damage is a significant challenge in oncology. To gain insight into biological mechanisms that cause DNA damage resistance and to inform strategies for achieving synergy with therapeutic radiation, we performed parallel pooled genetic CRISPR-Cas9 screening for survival in high-risk head and neck squamous cell carcinoma (HNSCC) subtypes. Surprisingly, in addition to known mediators of radiotherapy response, including ATM, DNAPK, and NF-κB signaling, loss of JAK1 was identified as a driver of tumor cell radioresistance. Knockout of JAK1 in HNSCC increased cell survival by enhancing the DNA damage-dependent G2/M cell cycle arrest and delaying progression to radiation-induced mitotic catastrophe. In line with this finding, both JAK1 knockout and kinase inhibition with abrocitinib prevented subsequent formation of radiation-induced micronuclei. Loss of JAK1 function did not affect canonical CDK1 signaling but instead reduced activation of PLK1 and AURKA, two kinases with auxiliary roles in the regulation of G2 and M phase progression. Correspondingly, using both EdU labelling and live cell imaging techniques, JAK1 loss was found to cause prolonged metaphase, mitotic slippage, and progression to tetraploidy. Targeting the mitotic kinesin KIF18A with the small molecule sovilnesib exacerbated mitotic stress and enhanced the efficacy of radiation. These studies establish KIF18A inhibition as a strategy to counteract the protective G2/M cell cycle arrest induced by DNA damage and to thus enhance tumor cell sensitivity to radiation therapy.

Project description:Therapeutic resistance to DNA damage is a significant challenge in oncology. To gain insight into biological mechanisms that cause DNA damage resistance and to inform strategies for achieving synergy with therapeutic radiation, we performed parallel pooled genetic CRISPR-Cas9 screening for survival in high-risk head and neck squamous cell carcinoma (HNSCC) subtypes. Surprisingly, in addition to known mediators of radiotherapy response, including ATM, DNAPK, and NF-κB signaling, loss of JAK1 was identified as a driver of tumor cell radioresistance. Knockout of JAK1 in HNSCC increased cell survival by enhancing the DNA damage-dependent G2/M cell cycle arrest and delaying progression to radiation-induced mitotic catastrophe. In line with this finding, both JAK1 knockout and kinase inhibition with abrocitinib prevented subsequent formation of radiation-induced micronuclei. Loss of JAK1 function did not affect canonical CDK1 signaling but instead reduced activation of PLK1 and AURKA, two kinases with auxiliary roles in the regulation of G2 and M phase progression. Correspondingly, using both EdU labelling and live cell imaging techniques, JAK1 loss was found to cause prolonged metaphase, mitotic slippage, and progression to tetraploidy. Targeting the mitotic kinesin KIF18A with the small molecule sovilnesib exacerbated mitotic stress and enhanced the efficacy of radiation. These studies establish KIF18A inhibition as a strategy to counteract the protective G2/M cell cycle arrest induced by DNA damage and to thus enhance tumor cell sensitivity to radiation therapy.

Project description:Barr2017 - Dynamics of p21 in hTert-RPE1 cells This deteministic model reveals that a bistable switch created by Cdt2, promotes irreversible S-phase entry by keeping p21 levels low, prevents premature S-phase exit upon DNA damage This model is described in the article: DNA damage during S-phase mediates the proliferation-quiescence decision in the subsequent G1 via p21 expression. Barr AR, Cooper S, Heldt FS, Butera F, Stoy H, Mansfeld J, Novák B, Bakal C. Nat Commun 2017 Mar; 8: 14728 Abstract: Following DNA damage caused by exogenous sources, such as ionizing radiation, the tumour suppressor p53 mediates cell cycle arrest via expression of the CDK inhibitor, p21. However, the role of p21 in maintaining genomic stability in the absence of exogenous DNA-damaging agents is unclear. Here, using live single-cell measurements of p21 protein in proliferating cultures, we show that naturally occurring DNA damage incurred over S-phase causes p53-dependent accumulation of p21 during mother G2- and daughter G1-phases. High p21 levels mediate G1 arrest via CDK inhibition, yet lower levels have no impact on G1 progression, and the ubiquitin ligases CRL4Cdt2 and SCFSkp2 couple to degrade p21 prior to the G1/S transition. Mathematical modelling reveals that a bistable switch, created by CRL4Cdt2, promotes irreversible S-phase entry by keeping p21 levels low, preventing premature S-phase exit upon DNA damage. Thus, we characterize how p21 regulates the proliferation-quiescence decision to maintain genomic stability. This model is hosted on BioModels Database and identified by: BIOMD0000000660. To cite BioModels Database, please use: Chelliah V et al. BioModels: ten-year anniversary. Nucl. Acids Res. 2015, 43(Database issue):D542-8. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Radiotherapy is a key treatment for head and neck squamous cell carcinoma (HNSCC) especially in patients with human papilloma virus-negative (HPV-) HNSCC. Our studies identify polo-like kinase 1 (PLK1) as a promising target for HNSCC. PLK1 inhibition with onvansertib reduces cell viability and spheroid growth of HPV- HNSCC cells. PLK1 inhibition combined with radiation increases G2/M arrest, decreases colony formation of HPV- HNSCC cells, and reduces tumor growth in vivo. RNA-sequencing demonstrates radiation increases MMP10 expression but PLK1 inhibition reverses this effect in HPV- HNSCC cells. PLK1 inhibition also reduces MMP10 activity in HPV- HNSCC cells. These findings suggest that combining PLK1 inhibition with radiation may improve therapeutic response for HPV- HNSCC via MMP10, offering a novel approach to overcome radiation resistance.

Project description:Loss of JAK1 Function Causes G2/M Cell Cycle Defects Vulnerable to KIF18A Inhibition

Project description:The kinesin family member 18A (Kif18a) is an essential regulator of microtubule dynamics and chromosome alignment during mitosis. Laboratory mice with a loss of function mutation in Kif18a are are infertile due to mitotic arrest of germ cells, but this phenotype shows variable penetrance depending on genetic background. Kif18a is also necessary for mitotic progression of chromosomally unstable cancer cells, which exhibit mitotic arrest in the absence of KIF18A function. While it is clear that functional dependency on KIF18A varies by cell type and genetic context, the heritable factors that influence this dependency remain unknown. To address this, we took advantage of the variable penetrance observed in different mouse strain backgrounds to screen for genetic loci that modulate germ cell depletion in the absence of KIF18A. We found a significant association between the severity of germ cell depletion and a locus on Chr5 wherein anaphase promoting complex subunits 5 (Anapc5) and 7 (Anapc7) were the top candidate genes. We compared the expression of both genes at key timepoints in gondal development and found that both genes were differentially expressed in sensitive strain backgrounds when compared to resistant strain backgrounds. We also identify a novel retroviral insertion in Anapc7 that may in part explain the observed expression differences. In cell line models, we found that depletion of KIF18A induced mitotic arrest, which was partially rescued by co-depletion of APC7 and exacerbated by co-depletion of APC5. These findings suggest that differential expression and activity of Anapc5 and Anapc7 may influence sensitivity to KIF18A depletion in germ cells and CIN cells, with potential implications for optimizing antineoplastic therapies.

Project description:Defects in DNA damage responses may underlie genetic instability and malignant progression in melanoma. Cultures of normal human melanocytes (NHMs) and melanoma lines were analyzed to determine whether global patterns of gene expression could predict the efficacy of DNA damage cell cycle checkpoints that arrest growth and suppress genetic instability. NHMs displayed effective G1 and G2 checkpoint responses to ionizing radiation-induced DNA damage. A majority of melanoma cell lines (11/16) displayed significant quantitative defects in one or both checkpoints. Melanomas with B-RAF mutations as a class displayed a significant defect in DNA damage G2 checkpoint function. In contrast the epithelial-like subtype of melanomas with wildtype N-RAS and B-RAF alleles displayed an effective G2 checkpoint but a significant defect in G1 checkpoint function. RNA expression profiling revealed that melanoma lines with defects in the DNA damage G1 checkpoint displayed reduced expression of p53 transcriptional targets, such as CDKN1A and DDB2, and enhanced expression of proliferation-associated genes, such as CDC7 and GEMININ. A Bayesian analysis tool was more accurate than significance analysis of microarrays for predicting checkpoint function using a leave-one-out method. The results suggest that defects in DNA damage checkpoints may be recognized in melanomas through analysis of gene expression. Experiment Overall Design: Normal human melanocyte and melanoma cell lines w/wo mutations in B-raf or N-ras were treated with 1.5 Gy IR irridiartion for G1 and G2 checkpoint determination. RNA was isolated from exponentially growing cultures and applied for microarray hybridizaton with Agilent 44 K (G4112A) array.

Project description:Hypoxia promotes an aggressive tumor phenotype with increased genomic instability, partially due to downregulation of DNA repair pathways. However, in addition to DNA repair, genome stability is also controlled by cell cycle checkpoints. An important issue is therefore whether hypoxia also can alter the DNA damage cell cycle checkpoints. Here, we show that hypoxia (24h 0.2% O2) alters the expression of several G2 checkpoint regulators, as examined by microarray gene expression analysis and immunoblotting of U2OS cells. While some of the changes reflected hypoxia-induced inhibition of cell cycle progression, flow cytometric bar-coding analysis of individual cells showed that the levels of several G2 checkpoint regulators were reduced in G2 phase cells after hypoxic exposure, in particular cyclin B1. These effects were accompanied by decreased Cyclin dependent kinase (CDK) activity in G2 phase cells after hypoxia. Furthermore, cells pre-exposed to hypoxia showed a longer G2 checkpoint arrest upon treatment with ionizing radiation. Similar results were found following other hypoxic conditions (~0.03 % O2 20h and 0.2% O2 72h). These results demonstrate that the DNA damage G2 checkpoint can be altered as a consequence of hypoxia, and we propose that such alterations may influence the genome stability of hypoxic tumors. We measured gene expression changes in U2OS cells after treatment with 0.2% hypoxia for 24 hours. The data were used in the exploration of hyopxia induced alterations in the G2 checkpoint.

Project description:The DNA dependent pattern recognition receptor, cGAS mediates communication between genotoxic stress and the immune system. Mitotic chromosome missegregation is an established stimulator of cGAS activity, however, it is unclear if progression through mitosis is required for cancer cell intrinsic activation of immune mediated anti-tumor responses. Moreover, it is unknown if disruption of cell cycle checkpoints can restore responses in cancer cells that are recalcitrant to DNA damage induced inflammation. Here we demonstrate that prolonged cell cycle arrest at the G2-mitosis boundary from either CDK1 inhibition or excessive DNA damage prevents inflammatory stimulated gene expression and immune mediated destruction of tumors outside the field of irradiation. Remarkably, DNA damage induced inflammatory signaling is restored upon concomitant disruption of p53 and the G2 checkpoint, in a cGAS- and RIG-I- dependent manner. These findings link aberrant cell progression and p53 loss to an expanded spectrum of damage associated molecular pattern recognition and have implications for the design of rational approaches to augment anti-tumor immune responses.