Identification of hyper-rewired genomic stress non-oncogene addiction genes across 15 cancer types
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Identification of hyper-rewired genomic stress non-oncogene addiction genes across 15 cancer types. / Hjaltelin, Jessica Xin; Izarzugaza, Jose M G; Jensen, Lars Juhl; Russo, Francesco; Westergaard, David; Brunak, Søren.
In: npj Systems Biology and Applications, Vol. 5, 27, 2019.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - Identification of hyper-rewired genomic stress non-oncogene addiction genes across 15 cancer types
AU - Hjaltelin, Jessica Xin
AU - Izarzugaza, Jose M G
AU - Jensen, Lars Juhl
AU - Russo, Francesco
AU - Westergaard, David
AU - Brunak, Søren
PY - 2019
Y1 - 2019
N2 - Non-oncogene addiction (NOA) genes are essential for supporting the stress-burdened phenotype of tumours and thus vital for their survival. Although NOA genes are acknowledged to be potential drug targets, there has been no large-scale attempt to identify and characterise them as a group across cancer types. Here we provide the first method for the identification of conditional NOA genes and their rewired neighbours using a systems approach. Using copy number data and expression profiles from The Cancer Genome Atlas (TCGA) we performed comparative analyses between high and low genomic stress tumours for 15 cancer types. We identified 101 condition-specific differential coexpression modules, mapped to a high-confidence human interactome, comprising 133 candidate NOA rewiring hub genes. We observe that most modules lose coexpression in the high-stress state and that activated stress modules and hubs take part in homoeostasis maintenance processes such as chromosome segregation, oxireductase activity, mitotic checkpoint (PLK1 signalling), DNA replication initiation and synaptic signalling. We furthermore show that candidate NOA rewiring hubs are unique for each cancer type, but that their respective rewired neighbour genes largely are shared across cancer types.
AB - Non-oncogene addiction (NOA) genes are essential for supporting the stress-burdened phenotype of tumours and thus vital for their survival. Although NOA genes are acknowledged to be potential drug targets, there has been no large-scale attempt to identify and characterise them as a group across cancer types. Here we provide the first method for the identification of conditional NOA genes and their rewired neighbours using a systems approach. Using copy number data and expression profiles from The Cancer Genome Atlas (TCGA) we performed comparative analyses between high and low genomic stress tumours for 15 cancer types. We identified 101 condition-specific differential coexpression modules, mapped to a high-confidence human interactome, comprising 133 candidate NOA rewiring hub genes. We observe that most modules lose coexpression in the high-stress state and that activated stress modules and hubs take part in homoeostasis maintenance processes such as chromosome segregation, oxireductase activity, mitotic checkpoint (PLK1 signalling), DNA replication initiation and synaptic signalling. We furthermore show that candidate NOA rewiring hubs are unique for each cancer type, but that their respective rewired neighbour genes largely are shared across cancer types.
U2 - 10.1038/s41540-019-0104-5
DO - 10.1038/s41540-019-0104-5
M3 - Journal article
C2 - 31396397
VL - 5
JO - npj Systems Biology and Applications
JF - npj Systems Biology and Applications
SN - 2056-7189
M1 - 27
ER -
ID: 227083384