Integrated clinical and genomic analysis identifies driver events and molecular evolution of colitis-associated cancers.
Walid K ChatilaHenry S WalchJaclyn F HechtmanSydney M MoyerValeria SgambatiDavid M FaleckAmitabh SrivastavaLaura TangJamal K BenhamidaDorina IsmailgeciCarl CamposFan WuQing ChangEfsevia VakianiElisa de StanchinaMartin R WeiserMaria WidmarRhonda K YantissManish A ShahAdam J BassZsofia K StadlerLior H KatzIngo K MellinghoffNilay S SethiNikolaus SchultzKaruna GaneshDavid P KelsenRona YaegerPublished in: Nature communications (2023)
Inflammation has long been recognized to contribute to cancer development, particularly across the gastrointestinal tract. Patients with inflammatory bowel disease have an increased risk for bowel cancers, and it has been posited that a field of genetic changes may underlie this risk. Here, we define the clinical features, genomic landscape, and germline alterations in 174 patients with colitis-associated cancers and sequenced 29 synchronous or isolated dysplasia. TP53 alterations, an early and highly recurrent event in colitis-associated cancers, occur in half of dysplasia, largely as convergent evolution of independent events. Wnt pathway alterations are infrequent, and our data suggest transcriptional rewiring away from Wnt. Sequencing of multiple dysplasia/cancer lesions from mouse models and patients demonstrates rare shared alterations between lesions. These findings suggest neoplastic bowel lesions developing in a background of inflammation experience lineage plasticity away from Wnt activation early during tumorigenesis and largely occur as genetically independent events.
Keyphrases
- papillary thyroid
- stem cells
- cell proliferation
- oxidative stress
- patients with inflammatory bowel disease
- end stage renal disease
- childhood cancer
- single cell
- squamous cell
- newly diagnosed
- chronic kidney disease
- genome wide
- ejection fraction
- ulcerative colitis
- mouse model
- gene expression
- copy number
- squamous cell carcinoma
- lymph node metastasis
- young adults
- transcription factor
- dna methylation
- single molecule