6533b7d0fe1ef96bd125a559

RESEARCH PRODUCT

Loss of PHD3 allows tumours to overcome hypoxic growth inhibition and sustain proliferation through EGFR

Higinio DopesoAmparo Acker-palmerAmparo Acker-palmerTill AckerGuido ReifenbergerMathias RitterMathias RitterClara L. EssmannPatrick H. MaxwellAlina FilatovaBoyan K. GarvalovAnne-theres HenzeÁNgel M. CuestaSascha SeidelPeter CarmelietFranziska FossFranziska Foss

subject

MaleColorectal cancerAngiogenesisProcollagen-Proline DioxygenaseGeneral Physics and AstronomyApoptosisGrowth inhibitoryBiologyArticleGeneral Biochemistry Genetics and Molecular BiologyHypoxia-Inducible Factor-Proline DioxygenasesGene Knockout Techniqueschemistry.chemical_compoundCell Line TumormedicineAnimalsHumansEgfr signalingHypoxiaCell ProliferationMice KnockoutMultidisciplinaryCell growthGeneral ChemistryHypoxia (medical)Hypoxia-Inducible Factor 1 alpha Subunitmedicine.diseaseMolecular biologyErbB ReceptorsOxygenchemistryApoptosisCancer researchFemalemedicine.symptomGrowth inhibitionGlioblastoma

description

Solid tumours are exposed to microenvironmental factors such as hypoxia that normally inhibit cell growth. However, tumour cells are capable of counteracting these signals through mechanisms that are largely unknown. Here we show that the prolyl hydroxylase PHD3 restrains tumour growth in response to microenvironmental cues through the control of EGFR. PHD3 silencing in human gliomas or genetic deletion in a murine high-grade astrocytoma model markedly promotes tumour growth and the ability of tumours to continue growing under unfavourable conditions. The growth-suppressive function of PHD3 is independent of the established PHD3 targets HIF and NF-κB and its hydroxylase activity. Instead, loss of PHD3 results in hyperphosphorylation of epidermal growth factor receptor (EGFR). Importantly, epigenetic/genetic silencing of PHD3 preferentially occurs in gliomas without EGFR amplification. Our findings reveal that PHD3 inactivation provides an alternative route of EGFR activation through which tumour cells sustain proliferative signalling even under conditions of limited oxygen availability.

yearjournalcountryeditionlanguage
2014-11-25Nature Communications
https://doi.org/10.1038/ncomms6582