POT1 and Damage Response Malfunction Trigger Acquisition of Somatic Activating Mutations in the VEGF Pathway in Cardiac Angiosarcomas
Identificadores
Identificadores
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Visualización o descarga de ficheros
Fecha de publicación
2019Título de revista
JOURNAL OF THE AMERICAN HEART ASSOCIATION
Tipo de contenido
Artigo
DeCS
mutación | factores de transcripción | apoptosis | estudios de casos y controles | proteínas de unión al ADN | hemangiosarcoma | proteínas mutadas de ataxia telangiectasia | carcinogénesis | transducción de señales | neoplasias cardíacas | proteínas de unión a telómeros | inmunohistoquímica | receptor 2 de factores de crecimiento endotelial vascular | daño del ADN | proteína supresora de tumor p53 | humanos | puntos de comprobación del ciclo celularMeSH
Apoptosis | Vascular Endothelial Growth Factor Receptor-2 | Signal Transduction | Cell Cycle Checkpoints | Tumor Suppressor Protein p53 | DNA Damage | Hemangiosarcoma | Immunohistochemistry | Mutation | Telomere-Binding Proteins | DNA-Binding Proteins | Transcription Factors | Humans | Carcinogenesis | Ataxia Telangiectasia Mutated Proteins | Heart Neoplasms | Case-Control StudiesResumen
Background Mutations in the POT1 gene explain abnormally long telomeres and multiple tumors including cardiac angiosarcomas (CAS). However, the link between long telomeres and tumorigenesis is poorly understood. Methods and Results Here, we have studied the somatic landscape of 3 different angiosarcoma patients with mutations in the POT1 gene to further investigate this tumorigenesis process. In addition, the genetic landscape of 7 CAS patients without mutations in the POT1 gene has been studied. Patients with CAS and nonfunctional POT1 did not repress ATR (ataxia telangiectasia RAD3-related)-dependent DNA damage signaling and showed a constitutive increase of cell cycle arrest and somatic activating mutations in the VEGF (vascular endothelial growth factor)/angiogenesis pathway (KDR gene). The same observation was made in POT1 mutation carriers with tumors different from CAS and also in CAS patients without mutations in the POT1 gene but with mutations in other genes involved in DNA damage signaling. Conclusions Inhibition of POT1 function and damage-response malfunction activated DNA damage signaling and increased cell cycle arrest as well as interfered with apoptosis, which would permit acquisition of somatic mutations in the VEGF/angiogenesis pathway that drives tumor formation. Therapies based on the inhibition of damage signaling in asymptomatic carriers may diminish defects on cell cycle arrest and thus prevent the apoptosis deregulation that leads to the acquisition of driver mutations.