Abstract B19: Quantitative proteomics analysis identifies MUC1 as an effect sensor of EGFR inhibition

Introduction The epidermal growth factor receptor (EGFR) is often hyperactivated through overexpression or somatic mutation in multiple cancer types, driving tumor growth and survival. Targeted therapies against EGFR show clinical benefit, but resistance to these agents invariably develops. Thus, th...

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Published in:Molecular cancer therapeutics 2015-12, Vol.14 (12_Supplement_2), p.B19-B19
Main Authors: de Boer, Harmen R., Joosten, Esméé, Fusetti, Fabrizia, Fehrmann, Rudolf S.N., de Vries, Elisabeth G.E., van Vugt, Marcel A.T.M.
Format: Article
Language:English
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Summary:Introduction The epidermal growth factor receptor (EGFR) is often hyperactivated through overexpression or somatic mutation in multiple cancer types, driving tumor growth and survival. Targeted therapies against EGFR show clinical benefit, but resistance to these agents invariably develops. Thus, there is need for markers of effective treatment, termed ‘effect sensors’, to monitor the effective treatment with EGFR therapeutics during therapy. Therefore, we investigated the cellular rewiring at the proteomic level in response to EGFR inhibition, with the aim of identifying proteins that can be used as effect sensors. These effect sensors potentially constitute powerful targets for the development of tracers to monitor EGFR-directed therapies. Materials and Methods Human breast cancer cell lines were tested for cell viability in presence of the EGFR inhibitor erlotinib and sensitive cell lines (SKBR3, SUM149, and BT474) were identified. These cell lines were labeled with stable (SILAC) isotopes and subsequently control-treated or treated with erlotinib for 48 hours. Membranes were then isolated and analyzed with quantitative mass-spectrometry (MS). Results were validated in erlotinib-sensitive (SKBR3, SUM149, and BT474) and resistant breast cancer cell lines (MB-231 and BT549), as well as erlotinib-sensitive human non-small cell lung cancer (NSCLC) cell lines (H292 and HCC827). Results In total, 1,485 overlapping proteins were quantitatively determined in all cell lines, containing 256 plasma membrane proteins as determined using Gene Ontology. Of those, 8 proteins showed at least 1.5 fold up-regulation and were selected for validation. We found MUC1 to be significantly upregulated in response to erlotinib treatment. Upregulation of MUC1 was detected both at protein and mRNA levels in all erlotinib-sensitive breast cancer cell lines, but not in erlotinib-resistant cell lines. In addition, MUC1 levels were elevated upon erlotinib treatment in NSCLC cell lines H292 (EGFR-WT) and HCC827 (EGFR-exon-19 deletion). MUC1 upregulation was observed as early as 48 hours after treatment, and persisted until 14 days with continuous erlotinib treatment. Upregulation of MUC1 was also observed in response to other clinical EGFR inhibitors, including lapatinib and afatinib, as well as in response to the monoclonal EGFR-directed antibody cetuximab. Erlotinib-induced MUC1 expression was dependent on PI3K/AKT/mTOR signaling, since MUC1 expression was completely blocked when EGF
ISSN:1535-7163
1538-8514
DOI:10.1158/1535-7163.TARG-15-B19