Mutually exclusive and co-occurring genetic alterations in bladder tumorigenesis
Taxon: Mammal | Human
Process: Cancer | Signalling | Cell fate decision
Submitter: Claudine Chaouiya
Supporting paper: Remy, Elisabeth and Rebouissou, Sandra and Chaouiya, Claudine and Zinovyev, Andrei and Radvanyi, François and Calzone, Laurence (2015). A Modeling Approach to Explain Mutually Exclusive and Co-Occurring Genetic Alterations in Bladder Tumorigenesis. Cancer Research. 10.1158/0008-5472.can-15-0602
| Model file(s) | Description(s) |
|---|---|
| Bladder_Model.zginml | GINsim model |
| Bladder_Model.sbml | SBMLqual model |
Summary:
Relationships between genetic alterations, such as co-occurrence or mutual
exclusivity, are often observed in cancer, where their understanding may
provide new insights into etiology and clinical management. In this study, we
combined statistical analyses and computational modelling to explain patterns
of genetic alterations seen in 178 patients with bladder tumours (either
muscle-invasive or non-muscle-invasive). A statistical analysis on frequently
altered genes identified pair associations including co-occurrence or mutual
exclusivity. Focusing on genetic alterations of protein-coding genes involved
in growth factor receptor signalling, cell cycle and apoptosis entry, we
complemented this analysis with a literature search to focus on nine pairs of
genetic alterations of our dataset, with subsequent verification in three
other datasets available publically. To understand the reasons and contexts of
these patterns of associations while accounting for the dynamics of associated
signalling pathways, we built a logical model. This model was validated first
on published mutant mice data, then used to study patterns and to draw
conclusions on counter-intuitive observations, allowing one to formulate
predictions about conditions where combining genetic alterations benefits
tumorigenesis. For example, while CDKN2A homozygous deletions occur in a
context of FGFR3 activating mutations, our model suggests that additional
PIK3CA mutation or p21CIP deletion would greatly favour invasiveness. Further,
the model sheds light on the temporal orders of gene alterations, for example,
showing how mutual exclusivity of FGFR3 and TP53 mutations is interpretable if
FGFR3 is mutated first. Overall, our work shows how to predict combinations of
the major gene alterations leading to invasiveness.