TY - JOUR
T1 - Patient-specific cancer genes contribute to recurrently perturbed pathways and establish therapeutic vulnerabilities in esophageal adenocarcinoma
AU - Oesophageal Cancer Clinical and Molecular Stratification (OCCAMS) Consortium
AU - Mourikis, Thanos P.
AU - Benedetti, Lorena
AU - Foxall, Elizabeth
AU - Temelkovski, Damjan
AU - Nulsen, Joel
AU - Perner, Juliane
AU - Cereda, Matteo
AU - Lagergren, Jesper
AU - Howell, Michael
AU - Yau, Christopher
AU - Fitzgerald, Rebecca C.
AU - Scaffidi, Paola
AU - Noorani, Ayesha
AU - Edwards, Paul A.W.
AU - Elliott, Rachael Fels
AU - Grehan, Nicola
AU - Nutzinger, Barbara
AU - Hughes, Caitriona
AU - Fidziukiewicz, Elwira
AU - Bornschein, Jan
AU - MacRae, Shona
AU - Crawte, Jason
AU - Northrop, Alex
AU - Contino, Gianmarco
AU - Li, Xiaodun
AU - de la Rue, Rachel
AU - Katz-Summercorn, Annalise
AU - Abbas, Sujath
AU - Loureda, Daniel
AU - O’Donovan, Maria
AU - Miremadi, Ahmad
AU - Malhotra, Shalini
AU - Tripathi, Monika
AU - Tavaré, Simon
AU - Lynch, Andy G.
AU - Eldridge, Matthew
AU - Secrier, Maria
AU - Bower, Lawrence
AU - Devonshire, Ginny
AU - Jammula, Sriganesh
AU - Davies, Jim
AU - Crichton, Charles
AU - Carroll, Nick
AU - Safranek, Peter
AU - Hindmarsh, Andrew
AU - Sujendran, Vijayendran
AU - Hayes, Stephen J.
AU - Ang, Yeng
AU - Sharrocks, Andrew
AU - Walker, Robert C.
PY - 2019/12
Y1 - 2019/12
N2 - The identification of cancer-promoting genetic alterations is challenging particularly in highly unstable and heterogeneous cancers, such as esophageal adenocarcinoma (EAC). Here we describe a machine learning algorithm to identify cancer genes in individual patients considering all types of damaging alterations simultaneously. Analysing 261 EACs from the OCCAMS Consortium, we discover helper genes that, alongside well-known drivers, promote cancer. We confirm the robustness of our approach in 107 additional EACs. Unlike recurrent alterations of known drivers, these cancer helper genes are rare or patient-specific. However, they converge towards perturbations of well-known cancer processes. Recurrence of the same process perturbations, rather than individual genes, divides EACs into six clusters differing in their molecular and clinical features. Experimentally mimicking the alterations of predicted helper genes in cancer and pre-cancer cells validates their contribution to disease progression, while reverting their alterations reveals EAC acquired dependencies that can be exploited in therapy.
AB - The identification of cancer-promoting genetic alterations is challenging particularly in highly unstable and heterogeneous cancers, such as esophageal adenocarcinoma (EAC). Here we describe a machine learning algorithm to identify cancer genes in individual patients considering all types of damaging alterations simultaneously. Analysing 261 EACs from the OCCAMS Consortium, we discover helper genes that, alongside well-known drivers, promote cancer. We confirm the robustness of our approach in 107 additional EACs. Unlike recurrent alterations of known drivers, these cancer helper genes are rare or patient-specific. However, they converge towards perturbations of well-known cancer processes. Recurrence of the same process perturbations, rather than individual genes, divides EACs into six clusters differing in their molecular and clinical features. Experimentally mimicking the alterations of predicted helper genes in cancer and pre-cancer cells validates their contribution to disease progression, while reverting their alterations reveals EAC acquired dependencies that can be exploited in therapy.
UR - http://www.scopus.com/inward/record.url?scp=85069459995&partnerID=8YFLogxK
U2 - 10.1038/s41467-019-10898-3
DO - 10.1038/s41467-019-10898-3
M3 - Article
C2 - 31308377
AN - SCOPUS:85069459995
SN - 2041-1723
VL - 10
JO - Nature Communications
JF - Nature Communications
IS - 1
M1 - 3101
ER -
