Concomitant inactivation of the p53- and pRB- functional pathways predicts resistance to DNA damaging drugs in breast cancer in vivo
Permanent link
https://hdl.handle.net/10037/8598Date
2015-05-08Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Knappskog, Stian; Berge, Elisabet Ognedal; Chrisanthar, Ranjan; Geisler, Stephanie; Staalesen, Vidar; Leirvaag, Beryl; Yndestad, Synnøve; de Faveri, Elise Norheim; Karlsen, Bård Ove; Wedge, David C.; Akslen, Lars A.; Lilleng, Peer Kåre; Løkkevik, Erik; Lundgren, Steinar; Østenstad, Bjørn; Risberg, Terje; Mjaaland, Ingvil; Aas, Turid; Lønning, Per EysteinAbstract
Chemoresistance is the main obstacle to cancer cure. Contrasting studies focusing on single
gene mutations, we hypothesize chemoresistance to be due to inactivation of key pathways
affecting cellular mechanisms such as apoptosis, senescence, or DNA repair. In
support of this hypothesis, we have previously shown inactivation of either TP53 or its
key activators CHK2 and ATM to predict resistance to DNA damaging drugs in breast cancer
better than TP53 mutations alone. Further, we hypothesized that redundant pathway(s)
may compensate for loss of p53-pathway signaling and that these are inactivated as well
in resistant tumour cells. Here, we assessed genetic alterations of the retinoblastoma gene (RB1) and its key regulators: Cyclin D and E as well as their inhibitors p16 and p27. In
an exploratory cohort of 69 patients selected from two prospective studies treated with
either doxorubicin monotherapy or 5-FU and mitomycin for locally advanced breast cancers,
we found defects in the pRB-pathway to be associated with therapy resistance (pvalues
ranging from 0.001 to 0.094, depending on the cut-off value applied to p27 expression
levels). Although statistically weaker, we observed confirmatory associations in a validation
cohort from another prospective study (n ¼ 107 patients treated with neoadjuvant
epirubicin monotherapy; p-values ranging from 7.0 104 to 0.001 in the combined data
sets). Importantly, inactivation of the p53-and the pRB-pathways in concert predicted
resistance to therapy more strongly than each of the two pathways assessed individually
(exploratory cohort: p-values ranging from 3.9 106 to 7.5 103 depending on cut-off
values applied to ATM and p27 mRNA expression levels). Again, similar findings were
confirmed in the validation cohort, with p-values ranging from 6.0 107 to 6.5 105
in the combined data sets. Our findings strongly indicate that concomitant inactivation
of the p53- and pRB- pathways predict resistance towards anthracyclines and mitomycin
in breast cancer in vivo.
Description
Published version. Source at http://dx.doi.org/10.1016/j.molonc.2015.04.008.