TY - JOUR
T1 - A modular master regulator landscape controls cancer transcriptional identity
AU - Paull, Evan O.
AU - Aytes, Alvaro
AU - Jones, Sunny J.
AU - Subramaniam, Prem S.
AU - Giorgi, Federico M.
AU - Douglass, Eugene F.
AU - Tagore, Somnath
AU - Chu, Brennan
AU - Vasciaveo, Alessandro
AU - Zheng, Siyuan
AU - Verhaak, Roel
AU - Abate-Shen, Cory
AU - Alvarez, Mariano J.
AU - Califano, Andrea
N1 - Publisher Copyright:
© 2020 Elsevier Inc.
PY - 2021/1/21
Y1 - 2021/1/21
N2 - Despite considerable efforts, the mechanisms linking genomic alterations to the transcriptional identity of cancer cells remain elusive. Integrative genomic analysis, using a network-based approach, identified 407 master regulator (MR) proteins responsible for canalizing the genetics of individual samples from 20 cohorts in The Cancer Genome Atlas (TCGA) into 112 transcriptionally distinct tumor subtypes. MR proteins could be further organized into 24 pan-cancer, master regulator block modules (MRBs), each regulating key cancer hallmarks and predictive of patient outcome in multiple cohorts. Of all somatic alterations detected in each individual sample, >50% were predicted to induce aberrant MR activity, yielding insight into mechanisms linking tumor genetics and transcriptional identity and establishing non-oncogene dependencies. Genetic and pharmacological validation assays confirmed the predicted effect of upstream mutations and MR activity on downstream cellular identity and phenotype. Thus, co-analysis of mutational and gene expression profiles identified elusive subtypes and provided testable hypothesis for mechanisms mediating the effect of genetic alterations. A network-based integrative genomic analysis of 20 The Cancer Genome Atlas cohorts characterizes conserved master regulator blocks underlying cancer hallmarks across different tumor types, providing insights into the connection between genetic alterations and tumor transcriptional identity.
AB - Despite considerable efforts, the mechanisms linking genomic alterations to the transcriptional identity of cancer cells remain elusive. Integrative genomic analysis, using a network-based approach, identified 407 master regulator (MR) proteins responsible for canalizing the genetics of individual samples from 20 cohorts in The Cancer Genome Atlas (TCGA) into 112 transcriptionally distinct tumor subtypes. MR proteins could be further organized into 24 pan-cancer, master regulator block modules (MRBs), each regulating key cancer hallmarks and predictive of patient outcome in multiple cohorts. Of all somatic alterations detected in each individual sample, >50% were predicted to induce aberrant MR activity, yielding insight into mechanisms linking tumor genetics and transcriptional identity and establishing non-oncogene dependencies. Genetic and pharmacological validation assays confirmed the predicted effect of upstream mutations and MR activity on downstream cellular identity and phenotype. Thus, co-analysis of mutational and gene expression profiles identified elusive subtypes and provided testable hypothesis for mechanisms mediating the effect of genetic alterations. A network-based integrative genomic analysis of 20 The Cancer Genome Atlas cohorts characterizes conserved master regulator blocks underlying cancer hallmarks across different tumor types, providing insights into the connection between genetic alterations and tumor transcriptional identity.
KW - cancer genetics
KW - cancer systems biology
KW - genomic alteration
KW - integrative genomics
KW - multiomics
KW - network analysis
KW - pan-cancer analysis
KW - transcriptional regulation
UR - http://www.scopus.com/inward/record.url?scp=85099592542&partnerID=8YFLogxK
U2 - 10.1016/j.cell.2020.11.045
DO - 10.1016/j.cell.2020.11.045
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C2 - 33434495
AN - SCOPUS:85099592542
SN - 0092-8674
VL - 184
SP - 334-351.e20
JO - Cell
JF - Cell
IS - 2
ER -