Characterisation of checkpoint kinase 1 and 2 in ovarian cancer

Francis, Kyle Evan

January 2016

CHEK1 inhibitors are currently in clinical trials for their ability to abrogate chemotherapy-induced CHEK1 activation and S phase arrest resulting in cancer cell apoptosis. No studies have yet identified ovarian cancers that could benefit from CHEK1-targeting therapy. I hypothesised that knowledge of CHEK1 and CHEK2 signalling in the DNA damage response can assist in identifying potential biomarkers for platinum responsiveness and CHEK-targeting therapy in ovarian cancer. In vitro studies investigated the CHEK1/2 inhibitor AZD7762 (AZD) and cisplatin (CP) in same patient-derived platinum-sensitive/resistant high-grade serous ovarian cancer cell lines (PEO1/PEO4 and PEO14/PEO23). Cytotoxicity assays confirmed higher CP IC50’s for PEO4 and PEO23 relative to PEO1 and PEO14 cell lines, respectively. AZD was more toxic to PEO1 cells and an additive effect of AZD with CP relative to CP alone was seen. A nontoxic AZD treatment to PEO4 cells sensitised the cells to CP when applied in combination. PEO14 and PEO23 cells had similar cytotoxicity profiles for combination treatments. BRDU DNA synthesis assays and cell cycle analysis revealed increased BRDU incorporation and accumulation in S phase when all cell lines were treated with CP. AZD treatment had a similar effect in PEO14 and PEO23 cells and increased the sub-G1 population, a marker of apoptotic DNA fragmentation, relative to control. Drug combination had no major effect on cell cycle distributions of both PEO14 and PEO23 cells relative to single agents but resulted in BRDU incorporation levels below CP and control levels for PEO14 cells. In PEO1 and PEO4 cells, AZD did not affect the cell cycle or DNA synthesis levels relative to control. Drug combination did not alter the cell cycle relative to CP treatment for PEO1 cells but decreased S phase and increased G2/M and sub-G1 populations in PEO4 cells. This was coupled with a decrease of CP-induced BRDU levels in PEO4 control levels. Apoptotic PARP cleavage/total PARP occurred early in CP treated PEO1 and PEO14 cells. A surrogate CHEK1/2 activity marker, p-CDC2 (Y15), decreased in all lines treated with AZD relative to control. Within PEO1 and PEO4 cells, greatest PARP cleavage was observed with combination treatment and coincided with high p-H2AX (S139), a DNA damage marker. p-CHEK1 (S317) and p-CHEK2 (T68), both ATR and ATM phosphorylation sites during DNA damage, increased for lone drug treatment and, to a greater extent, the combination drug treatments. PARP cleavage occurs across all treatments in PEO1 cells while it only occurs in the combination treatment for PEO4 cells. The latter coincides with a decrease in p-CHEK1 (S296) a CHEK1 autophosphorylation site, p-TP53 (S15), and p-BRCA1 (S1524), a homologous recombination marker, relative to the CP treated sample. In PEO14 and PEO23 cells, lone AZD and combination treatments had similar cleaved PARP/total PARP levels compared to the PEO14 CP treated cells. This was coupled with increased p-H2AX (S139), decreased CHEK1, and decreased CHEK2 autophosphorylation p-CHEK2 (S516). A human ovarian cancer xenograft model identified increases in p-H2AX (S139), CHEK1, p-CHEK1 (S317), p-CHEK2 (T68), and p-BRCA1 (S1524) in the carboplatin responsive cancers. In the paired pre- and post-chemotherapy human ovarian cancer samples, p-CHEK1 (S317) was elevated in post-chemotherapy responsive samples. In the first cohort, high p-CHEK1 (S317) was an independent poor overall survival biomarker and correlated with high p-H2AX (S139), MYC, p-CHEK1 (S296), p-CHEK2 (T68), p-CHEK2 (S516), and p-TP53 (S15). p-CHEK1 (S317) was associated with poor overall survival in serous ovarian cancers within the second pre-treatment ovarian cancer cohort. In conclusion, AZD can induce apoptosis in CP resistant cancer cells by synergising with CP to abrogate the S phase checkpoint, increase DNA damage, and inhibit CHEK1, and BRCA1 function. As a single agent, AZD can induce apoptosis by decreasing CHEK1 levels and CHEK2 activity. p- CHEK1 (S317) is a platinum responsive / poor prognostic biomarker.

Germline Mutations in CHEK1 and CHEK2 in Women with Ovarian, Peritoneal, or Fallopian Tube Cancer

Harrell, Maria Isabel

01 January 2015

Ovarian cancer is the deadliest gynecological malignancy affecting women. Diagnosis often occurs late due to non-specific symptoms, but if detected early, there is excellent chance for survival. One of the most important risk factors is family history. Up to 24% of cases are due to inherited loss-of-function mutations in genes involved in the DNA damage response. The theory underlying hereditary cancers is Knudson's two-hit theory of cancer causation, where two hits are necessary for cancer to occur in an individual: one in the germline and one in the tissue. The genes, CHEK1 and CHEK2, are modulators of the DNA damage response, and could be susceptible to a first hit. There is little to no evidence about whether loss-of-function mutations in either of these two genes can lead to ovarian cancer. Using a cohort of 587 ovarian cancer cases and 557 controls, this study sought to determine if CHEK1 and CHEK2 are associated with ovarian cancer. Applying Fisher's exact test to compare mutation rates and the t test to compare age at time of diagnosis, the alternative hypothesis about an association between disease and mutations in CHEK1 and CHEK2 was rejected, but an association between younger age at diagnosis in cases and mutations in either gene was confirmed. The association between age and mutations in either of these genes suggests that there is some influence of age on disease, but a clear association between development of disease and mutations cannot yet be established. This research has implications for social change: By recognizing the need to test earlier in women with mutations in CHEK1 and/or CHEK2, they will have a higher chance of survival and better health outcomes, not only for ovarian cancer but for related cancers as well.

CHEK1

CHEK2

genetic susceptibility

ovarian cancer

Epidemiology

Genetics