Recurrent point mutations in SPOP define a distinct molecular subclass of prostate cancer. Here, we describe a mouse model showing that mutant SPOP drives prostate tumorigenesis in vivo. Conditional expression of mutant SPOP in the prostate dramatically altered phenotypes in the setting of Pten loss, with early neoplastic lesions (high-grade prostatic intraepithelial neoplasia) with striking nuclear atypia and invasive, poorly differentiated carcinoma. In mouse prostate organoids, mutant SPOP drove increased proliferation and a transcriptional signature consistent with human prostate cancer. Using these models and human prostate cancer samples, we show that SPOP mutation activates both PI3K/mTOR and androgen receptor signaling, effectively uncoupling the normal negative feedback between these two pathways. Display omitted •Mutations in SPOP are driver events resulting in prostate tumorigenesis in the mouse•SPOP mutation activates PI3K/mTOR signaling through upregulation of SRC3 (NCOA3)•SPOP mutation maintains AR signaling against PI3K/mTOR-mediated negative feedback•Mutant SPOP upregulates a network of AR-associated transcription factors Blattner et al. develop a mouse model and use it to demonstrate that human SPOP mutation can drive prostate tumorigenesis through coordinate deregulation of both PI3K/mTOR and AR pathways. The study provides insights to both unique and common features of molecular subtypes of human prostate cancer.