Your search keyword '"van Liere, Elsbeth A."' showing total 2 results

1. Oncogenic RAS sensitizes cells to drug-induced replication stress via transcriptional silencing of P53

Author

Segeren, Hendrika A., van Liere, Elsbeth A., Riemers, Frank M., de Bruin, Alain, and Westendorp, Bart

Abstract

Cancer cells often experience high basal levels of DNA replication stress (RS), for example due to hyperactivation of oncoproteins like MYC or RAS. Therefore, cancer cells are considered to be sensitive to drugs that exacerbate the level of RS or block the intra S-phase checkpoint. Consequently, RS-inducing drugs including ATR and CHK1 inhibitors are used or evaluated as anti-cancer therapies. However, drug resistance and lack of biomarkers predicting therapeutic efficacy limit efficient use. This raises the question what determines sensitivity of individual cancer cells to RS. Here, we report that oncogenic RAS does not only enhance the sensitivity to ATR/CHK1 inhibitors by directly causing RS. Instead, we observed that HRASG12Vdampens the activation of the P53-dependent transcriptional response to drug-induced RS, which in turn confers sensitivity to RS. We demonstrate that inducible expression of HRASG12Vsensitized cells to ATR and CHK1 inhibitors. Using RNA-sequencing of FACS-sorted cells we discovered that P53 signaling is the sole transcriptional response to RS. However, oncogenic RAS attenuates the transcription of P53 and TGF-β pathway components which consequently dampens P53 target gene expression. Accordingly, live cell imaging showed that HRASG12Vexacerbates RS in S/G2-phase, which could be rescued by stabilization of P53. Thus, our results demonstrate that transcriptional control of P53 target genes is the prime determinant in the response to ATR/CHK1 inhibitors and show that hyperactivation of the MAPK pathway impedes this response. Our findings suggest that the level of oncogenic MAPK signaling could predict sensitivity to intra-S-phase checkpoint inhibition in cancers with intact P53.

Published

2022

2. Excessive E2F Transcription in Single Cancer Cells Precludes Transient Cell-Cycle Exit after DNA Damage

Author

Segeren, Hendrika A., van Rijnberk, Lotte M., Moreno, Eva, Riemers, Frank M., van Liere, Elsbeth A., Yuan, Ruixue, Wubbolts, Richard, de Bruin, Alain, and Westendorp, Bart

Abstract

E2F transcription factors control the expression of cell-cycle genes. Cancers often demonstrate enhanced E2F target gene expression, which can be explained by increased percentages of replicating cells. However, we demonstrate in human cancer biopsy specimens that individual neoplastic cells display abnormally high levels of E2F-dependent transcription. To mimic this situation, we delete the atypical E2F repressors (E2F7/8) or overexpress the E2F3 activator in untransformed cells. Cells with elevated E2F activity during S/G2 phase fail to exit the cell cycle after DNA damage and undergo mitosis. In contrast, wild-type cells complete S phase and then exit the cell cycle by activating the APC/CCdh1via repression of the E2F target Emi1. Many arrested wild-type cells eventually inactivate APC/CCdh1to execute a second round of DNA replication and mitosis, thereby becoming tetraploid. Cells with elevated E2F transcription fail to exit the cell cycle after DNA damage, which potentially causes genomic instability, promotes malignant progression, and reduces drug sensitivity.

Published

2020