Project description:Oncogenic YAP sensitizes cells to CHK1 inhibition via CDK4/6 driven G1 acceleration

Project description:A long-term goal in cancer research has been to inhibit the cell cycle in tumour cells without causing toxicity in proliferative healthy tissues. The best evidence that this is achievable is provided by CDK4/6 inhibitors, which arrest the cell cycle in G1, are well-tolerated in patients, and are effective in treating ER+/HER2- breast cancer. CDK4/6 inhibitors are effective because they arrest tumour cells more efficiently than some healthy cell types and, in addition, they affect the tumour microenvironment to enhance anti-tumour immunity. We demonstrate here another reason to explain their efficacy. Tumour cells are specifically vulnerable to CDK4/6 inhibition because during the G1 arrest, oncogenic signals drive toxic cell overgrowth. This overgrowth causes permanent cell cycle withdrawal by either preventing progression from G1 or by inducing replication stress and genotoxic damage during the subsequent S-phase and mitosis. Inhibiting or reverting oncogenic signals that converge onto mTOR can rescue this excessive growth, DNA damage and cell cycle exit in cancer cells. Conversely, inducing oncogenic signals in non-transformed cells can drive these toxic phenotypes and sensitize cells to CDK4/6 inhibition. Together, this demonstrates how oncogenic signals that have evolved to stimulate constitutive tumour growth and proliferation driven subverted to cause toxic cell growth and irreversible cell cycle exit when proliferation is halted in G1.

Project description:CDK4/6 inhibitors arrest the cell cycle in G1-phase. They are licenced to treat breast cancer and are also undergoing clinical trials against a range of other tumour types. To facilitate these efforts, it is important to understand why a temporary cell cycle arrest in G1 causes long-lasting effects on tumour growth. Here we demonstrate that a prolonged G1-arrest following CDK4/6 inhibition downregulates replisome components and impairs origin licencing. This causes a failure in DNA replication after release from that arrest, resulting in a p53-dependent withdrawal from the cell cycle. If p53 is absent, then cells bypass the G2-checkpoint and undergo a catastrophic mitosis resulting in excessive DNA damage. These data therefore link CDK4/6 inhibition to genotoxic stress; a phenotype that is shared by most other broad-spectrum anti-cancer drugs. This provides a rationale to predict responsive tumour types and effective combination therapies, as demonstrated by the fact that chemotherapeutics that cause replication stress also induce sensitivity to CDK4/6 inhibition.

Project description:Cell size and the cell cycle are intrinsically coupled and abnormal increases in cell size are associated with senescence and permanent cell cycle arrest. The mechanism by which overgrowth primes cells to withdraw from the cell cycle remains unknown. We investigate this here using CDK4/6 inhibitors that arrest cell cycle progression during G0/G1 and are used in the clinic to treat ER+/HER2- metastatic breast cancer. We demonstrate that CDK4/6 inhibition promotes cellular overgrowth during G0/G1, causing p38MAPK-p53-p21-dependent cell cycle withdrawal. We find that cell cycle withdrawal is triggered by two waves of p21 induction. First, overgrowth during a long-term G0/G1 arrest induces an osmotic stress response. This stress response produces the first wave of p21 induction. Second, when CDK4/6 inhibitors are removed, a fraction of cells escape long term G0/G1 arrest and enter S-phase where overgrowth-driven replication stress results in a second wave of p21 induction that causes cell cycle withdrawal from G2, or the subsequent G1. We propose a model whereby both waves of p21 induction contribute to promote permanent cell cycle arrest. This model could explain why cellular hypertrophy is associated with senescence and why CDK4/6 inhibitors have long-lasting effects in patients.

Project description:Disease frameshift mutations of calreticulin (CALR) are the second most prevalent driver mutations in essential thrombocythemia (ET) and primary myelofibrosis (PMF). To identify potential targeted therapies for CALR mutated myeloproliferative neoplasms, we aimed to search for small molecule drugs that selectively inhibit the growth of CALR mutated cells using high-throughput drug screening. We investigated 89,172 compounds using isogenic cell lines and identified several hits targeting the ATR-CHK1 pathway. The selective inhibitory effect of these candidate compounds was validated in a co-culture assay of CALR mutated and wild type cells. Of the tested hit compounds, CHK1 inhibitors potently depleted CALR mutated cells, allowing CALR wild type cell dominance in the co-culture over time. Neither CALR deficient cells nor JAK2V617F mutated cells showed hypersensitivity to the drug treatment, suggesting that the vulnerability to ATR-CHK1 inhibition is specifically caused by the oncogenic activation by the mutant CALR. CHK1 inhibitors induced replication stress in CALR mutated cells revealed by elevated pan-nuclear staining for γH2AX and hyperphosphorylation of RPA2. They also promoted S-phase cell cycle arrest and blocked the completion of DNA replication in CALR mutated cells. Transcriptomic and phosphoproteomic analyses revealed a replication stress signature caused by the oncogenic CALR mutation, suggesting an intrinsic vulnerability of these cells to CHK1 perturbation. This study indicates that ATR-CHK1 pathway is a potential therapeutic target in CALR mutated hematopoietic cells.

Project description:YAP knockdown in HUVEC elicits proliferation and cell cycle preogression defects. YAP deficient cells caused arrest in G1 and defects in S-phase entry. The microarray analysis was conducted to identify potential YAP targets that are involved in HUVEC cell cycle regulation

Project description:By selective and reversible inhibition of CDK4/CDK6, we have developed a strategy to both inhibit proliferation and enhance cytotoxic killing of cancer cells. Induction of prolonged early-G1 arrest (pG1) by CDK4/CDK6 inhibition halts gene expression in early-G1 and prevents expression of genes programmed for other cell cycle phases. S-phase synchronization upon removal of the early-G1 block (pG1-S) fails to completely restore scheduled gene expression. Consequently, coordinate loss of IRF4 and gain of Bim and Noxa expression sensitize myeloma tumor cells to bortezomib-induced apoptosis in pG1 and more profoundly in pG1-S in vitro. Induction of pG1 and pG1-S by CDK4/CDK6 inhibition augments tumor-specific bortezomib killing in myeloma xenografts. Inhibition of CDK4/CDK6 in combination therapy thus represents a novel mechanism-based cancer therapy. PD 0332991 (PD) is the only known specific and reversible CDK4/CDK6 inhibitor. Gene expression was measured in myeloma MM1.S cells treated with PD (0.25 uM) in triplicate for 12, 24 or 36 h, or in cells released from G1, induced by 24hPD, for 4 or 18 h.

Project description:YAP knockdown in HUVEC elicits proliferation and cell cycle preogression defects. YAP deficient cells caused arrest in G1 and defects in S-phase entry. The microarray analysis was conducted to identify potential YAP targets that are involved in HUVEC cell cycle regulation mRNA samples were collected from siRNA treated HUVECs 30 hour after transfection. Four biological replicates were used for each condition: control (RISC-free) and knockdown (siYAP#1 and siYAP#2)

Project description:The purpose of this clinical study is to establish the safety profile, determine the maximum tolerated dose (MTD) and recommend a Phase 2 dose and schedule of SRA737; and to evaluate the efficacy of SRA737 in prospectively-selected subjects with genetically-defined tumors that harbor genomic alterations linked to increased replication stress and that are hypothesized to be more sensitive to checkpoint kinase 1 (Chk1) inhibition via synthetic lethality. Specific cancer indications that frequently harbor these genetic mutations will be studied.

Project description:By selective and reversible inhibition of CDK4/CDK6, we have developed a strategy to both inhibit proliferation and enhance cytotoxic killing of cancer cells. Induction of prolonged early-G1 arrest (pG1) by CDK4/CDK6 inhibition halts gene expression in early-G1 and prevents expression of genes programmed for other cell cycle phases. S-phase synchronization upon removal of the early-G1 block (pG1-S) fails to completely restore scheduled gene expression. Consequently, coordinate loss of IRF4 and gain of Bim and Noxa expression sensitize myeloma tumor cells to bortezomib-induced apoptosis in pG1 and more profoundly in pG1-S in vitro. Induction of pG1 and pG1-S by CDK4/CDK6 inhibition augments tumor-specific bortezomib killing in myeloma xenografts. Inhibition of CDK4/CDK6 in combination therapy thus represents a novel mechanism-based cancer therapy.