Androgen receptor activity is essential for prostate cancer development and progression. While there are classically defined roles for the retinoblastoma (Rb) and p53 tumor suppressor pathways in maintenance of cell cycle control and the DNA damage response, recent studies have demonstrated a direct role of these two pathways in regulating AR expression and function. While the role of Pten deregulation in prostate cancer has provided much insight in to the mechanisms underlying prostate cancer initiation and progression, emerging roles for Rb and p53 are likely to further expand upon our understanding of tumor suppressor/nuclear receptor interaction. As disconnecting mitogenic signaling from AR-mediated gene transcription underlies the progression to castrate resistant prostate cancer (CRPC), functional inactivation of these two tumor suppressor pathways represents one mechanism through which AR protein levels can be upregulated and AR-mediated gene transcription can become aberrant. Importantly, recent advances in small molecule inhibitor design and discovery have led to the identification of agents capable of targeting these two prominent pathways and restoring the function of deregulated wild-type Rb and p53 protein. While such agents have undergone extensive study in many solid tumor types, the additional importance of Rb and p53 in restraining transcription of the AR gene within the prostate provides impetus for examining how loss of these two tumor suppressor proteins can facilitate transition of prostate cancers to CRPC. As will be reviewed in this article, restoration of Rb and p53 functions are not only important in regard to shortterm cell cycle regulation and response to genomic stresses, but likely have direct implications for deregulation of the AR locus.