Abstract 3490
Background
Cellular signal transduction research identified 10-15 signaling pathways responsible for driving tumor growth. Defining pathway activity in tumor tissue is necessary to optimize targeted therapy choice. Verhaegh et al (Cancer Research 2014) used a Bayesian network approach to model transcriptional programs of signaling pathways. These pathway models use mRNA expression levels of validated direct pathway target genes to infer a probability of pathway activity in individual patient samples. Here, initial results of the AR model are presented.
Methods
28 bona fide AR target genes were selected and a Bayesian network model for the AR pathway was built and calibrated. The model uses target genes mRNA levels (Affymetrix HG-U133Plus2.0 array) as input to infer probability of AR pathway activity. Evaluation was done using multiple public datasets from clinical studies. The model was also adapted for qPCR data as input, using a subset of most informative target genes.
Results
Biological validation on androgen stimulated LNCaP cultures showed expected AR activity (GSE7868), which was inhibited by the anti-androgen bicalutamide (GSE7708). In cell line xenograft models (GSE21887, GSE33316, GSE966), AR was active in the presence of androgen and inactive in castrated mice. In prostate hyperplasia and 90% of primary prostate cancer (PCa) samples (GSE17951, GSE28403, GSE32982, GSE3325, GSE45016) AR was active; in contrast, AR was inactive in 30-50% of castration resistant or metastatic samples. AR was active in primary PCa samples, but not in samples taken 3 days after surgical castration (GSE32982). In other cancer types AR was mostly inactive, except for a subset of Her2 subtype Breast Cancer (BCa), Luminal BCa (EM-TAB-365, GSE12276, GSE17097, GSE21653), and meningioma samples (GSE16581, GSE9438). Translation to qPCR-RNA measurement as input was successful, underscoring the portability of our approach to other measurement platforms
Conclusions
Our biologically validated computational AR model enables assessing functional AR pathway activity in individual patient tissue samples, based on mRNA microarray or qPCR input from respectively FF or FFPE material. Other pathway models and clinical validation studies are in progress.
Clinical trial identification
Legal entity responsible for the study
Philips Research
Funding
None
Disclosure
A. van Brussel, M.A. Inda, E. Den Biezen, D. van Strijp, J. Wrobel, H. van Ooijen, R. Hoffmann, W. Verhaegh, A. van de Stolpe: Employee of Philips Research.