Your search keyword '"WEE1 kinase"' showing total 5 results

1. Repurposing clinically approved drugs as Wee1 checkpoint kinase inhibitors: an in silico investigation integrating molecular docking, ensemble QSAR modelling and molecular dynamics simulation.

Author

Olawale, Femi, Ogunyemi, Oludare, and Folorunso, Ibukun Mary

Subjects

*MOLECULAR dynamics, *MOLECULAR docking, *QSAR models, *KINASE inhibitors, *BINDING energy

Abstract

High levels of Wee1 expression have been seen in a variety of malignancies, including breast cancer, cervical cancer and leukaemia. Due to the positive link between cancer and Wee1 expression, the protein has become a particularly relevant therapeutic target in the fight against cancer. The current study aimed to identify potential Wee1 kinase inhibitors from FDA-approved drugs using in silico approach. The drug candidates were virtually screened in silico against Wee1 kinase using molecular docking. The binding free energy of the nine top-scoring compounds was determined, after which its bioactivity was predicted by three well-validated QSAR models. The molecular dynamics of FDA-approved drugs dasatinib and cangrelor with Wee1 kinase were studied for 100 ns. The results demonstrated that the top-scoring compounds identified as potential Wee1 inhibitors exhibited favourable binding energies (docking scores), and its stability with Wee1 was evident by the binding free energy calculation. The result of the AutoQSAR ensemble/consensus prediction showed that this set of compounds had satisfactory inhibitory attributes. The MD simulation showed stable complexes throughout the duration of the simulation. Based on the data obtained from this study, we recommend the top-scoring compounds for further preclinical investigation for its potential to inhibit Wee1 kinase in cancer. [ABSTRACT FROM AUTHOR]

Published

2022

2. Enhancing direct cytotoxicity and response to immune checkpoint blockade following ionizing radiation with Wee1 kinase inhibition.

Author

Patel, Priya, Sun, Lily, Robbins, Yvette, Clavijo, Paul E., Friedman, Jay, Silvin, Christopher, Van Waes, Carter, Cook, John, Mitchell, James, and Allen, Clint

Subjects

*IONIZING radiation, *GRANZYMES, *IMMUNE response, *CELL cycle, *CYTOTOXIC T cells

Abstract

Tumor cells activate the G2/M cell cycle checkpoint in response to ionizing radiation (IR) and effector immune cell-derived granzyme B to facilitate repair and survival. Wee1 kinase inhibition reverses the ability of tumor cells to pause at G2/M. Here, we hypothesized that AZD1775, a small molecule inhibitor of Wee1 kinase, could sensitize tumor cells to IR and T-lymphocyte killing and improve responses to combination IR and programmed death (PD)-axis immune checkpoint blockade (ICB). Multiple models of head and neck carcinoma, lung carcinoma and melanoma were used in vitro and in vivo to explore this hypothesis. AZD1775 reversed G2/M cell cycle checkpoint activation following IR, inducing cell death. Combination IR and AZD1775 induced accumulation of DNA damage in M-phase cells and was rescued with nucleoside supplementation, indicating mitotic catastrophe. Combination treatment enhanced control of syngeneic MOC1 tumors in vivo, and on-target effects of systemic AZD1775 could be localized with targeted IR. Combination treatment enhanced granzyme B-dependent T-lymphocyte killing through reversal of additive G2/M cell cycle block induced by IR and granzyme B. Combination IR and AZ1775-enhanced CD8+ cell-dependent MOC1 tumor growth control and rate of complete rejection of established tumors in the setting of PD-axis ICB. Functional assays demonstrated increased tumor antigen-specific immune responses in sorted T-lymphocytes. The combination of IR and AZD1775 not only lead to enhanced tumor-specific cytotoxicity, it also enhanced susceptibility to T-lymphocyte killing and responses to PD-axis ICB. These data provide the pre-clinical rationale for the combination of these therapies in the clinical trial setting. [ABSTRACT FROM AUTHOR]

Published

2019

3. p21 limits S phase DNA damage caused by the Wee1 inhibitor MK1775.

Author

Hauge, Sissel, Macurek, Libor, and Syljuåsen, Randi G.

Abstract

The Wee1 inhibitor MK1775 (AZD1775) is currently being tested in clinical trials for cancer treatment. Here, we show that the p53 target and CDK inhibitor p21 protects against MK1775-induced DNA damage during S-phase. Cancer and normal cells deficient for p21 (HCT116 p21-/-, RPE p21-/-, and U2OS transfected with p21 siRNA) showed higher induction of the DNA damage marker γH2AX in S-phase in response to MK1775 compared to the respective parental cells. Furthermore, upon MK1775 treatment the levels of phospho-DNA PKcs S2056 and phospho-RPA S4/S8 were higher in the p21 deficient cells, consistent with increased DNA breakage. Cell cycle analysis revealed that these effects were due to an S-phase function of p21, but MK1775-induced S-phase CDK activity was not altered as measured by CDK-dependent phosphorylations. In the p21 deficient cancer cells MK1775-induced cell death was also increased. Moreover, p21 deficiency sensitized to combined treatment of MK1775 and the CHK1-inhibitor AZD6772, and to the combination of MK1775 with ionizing radiation. These results show that p21 protects cancer cells against Wee1 inhibition and suggest that S-phase functions of p21 contribute to mediate such protection. As p21 can be epigenetically downregulated in human cancer, we propose that p21 levels may be considered during future applications of Wee1 inhibitors. [ABSTRACT FROM AUTHOR]

Published

2019

4. Inactivation of Pmc1 vacuolar Ca2+ ATPase causes G2 cell cycle delay in Hansenula polymorpha.

Author

Fokina, Anastasia V., Sokolov, Svyatoslav S., Kalebina, Tatyana S., Ter-avanesyan, Michael D., Agaphonov, Michael O., and Kang, Hyun A.

Published

2012

5. WEE1 kinase inhibition reverses G2/M cell cycle checkpoint activation to sensitize cancer cells to immunotherapy.

Author

Sun, Lillian, Moore, Ellen, Berman, Rose, Clavijo, Paul E., Friedman, Jay, Allen, Clint T., Saleh, Anthony, Chen, Zhong, Van Waes, Carter, and Davies, John

Subjects

*T cells, *CANCER, *CELL cycle, *KINASE inhibitors, *GRANZYMES, *APOPTOSIS, *ADENOCARCINOMA, *MELANOMA

Abstract

Intrinsic resistance to cytotoxic T-lymphocyte (CTL) killing limits responses to immune activating anti-cancer therapies. Here, we established that activation of the G2/M cell cycle checkpoint results in tumor cell cycle pause and protection from granzyme B-induced cell death. This was reversed with WEE1 kinase inhibition, leading to enhanced CTL killing of antigen-positive tumor cells. Similarly, but at a later time point, cell cycle pause following TNFα exposure was reversed with WEE1 kinase inhibition, leading to CTL transmembrane TNFα-dependent induction of apoptosis and necroptosis in bystander antigen-negative tumor cells. Results were reproducible in models of oral cavity carcinoma, melanoma and colon adenocarcinoma harboring variable Tp53 genomic alterations. WEE1 kinase inhibition sensitized tumors to PD-1 mAb immune checkpoint blockade in vivo, resulting in CD8+-dependent rejection of established tumors harboring antigen-positive or mixed antigen-positive and negative tumor cells. Together, these data describe activation of the G2/M cell cycle checkpoint in response to early and late CTL products as a mechanism of resistance to CTL killing, and provide pre-clinical rationale for the clinical combination of agents that inhibit cell cycle checkpoints and activate anti-tumor immunity. [ABSTRACT FROM AUTHOR]

Published

2018