GRK2 Enforces Androgen Receptor Dependence in the Prostate and Prostate Tumors

Overview

Journal Oncogene

Specialties Molecular Biology
Oncology

Date 2020 Jan 22

PMID 31959897

Authors

Adam J Adler

Payal Mittal

Adam T Hagymasi

Antoine Menoret

Chen Shen

Federica Agliano

Kyle T Wright

James J Grady

Chia-Ling Kuo

Enrique Ballesteros

Kevin P Claffey

Anthony T Vella

Affiliations

Soon will be listed here.

Abstract

Metastatic tumors that have become resistant to androgen deprivation therapy represent the major challenge in treating prostate cancer. Although these recurrent tumors typically remain dependent on the androgen receptor (AR), non-AR-driven tumors that also emerge are particularly deadly and becoming more prevalent. Here, we present a new genetically engineered mouse model for non-AR-driven prostate cancer that centers on a negative regulator of G protein-coupled receptors that is downregulated in aggressive human prostate tumors. Thus, prostate-specific expression of a dominant-negative G protein-coupled receptor kinase 2 (GRK2-DN) transgene diminishes AR and AR target gene expression in the prostate, and confers resistance to castration-induced involution. Further, the GRK2-DN transgene dramatically accelerates oncogene-initiated prostate tumorigenesis by increasing primary tumor size, potentiating visceral organ metastasis, suppressing AR, and inducing neuroendocrine marker mRNAs. In summary, GRK2 enforces AR-dependence in the prostate, and the loss of GRK2 function in prostate tumors accelerates disease progression toward the deadliest stage.

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