Prostate cancer antigen 3 (PCA3) is the most specific prostate cancer biomarker but its function remains unknown. Here we identify PRUNE2, a target protein-coding gene variant, which harbors the PCA3 locus, thereby classifying PCA3 as an antisense intronic long noncoding (lnc)RNA. We show that PCA3 controls PRUNE2 levels via a unique regulatory mechanism involving formation of a PRUNE2/PCA3 double-stranded RNA that undergoes adenosine deaminase acting on RNA (ADAR)-dependent adenosine-to-inosine RNA editing. PRUNE2 expression or silencing in prostate cancer cells decreased and increased cell proliferation, respectively. Moreover, PRUNE2 and PCA3 elicited opposite effects on tumor growth in immunodeficient tumor-bearing mice. Coregulation and RNA editing of PRUNE2 and PCA3 were confirmed in human prostate cancer specimens, supporting the medical relevance of our findings. These results establish PCA3 as a dominant-negative oncogene and PRUNE2 as an unrecognized tumor suppressor gene in human prostate cancer, and their regulatory axis represents a unique molecular target for diagnostic and therapeutic intervention.S everal lines of evidence demonstrate that long noncoding RNAs (lncRNAs) are functional in carcinogenesis through regulatory mechanisms such as promoter looping, alternative splicing, antisense gene silencing, transcriptional regulation, and DNA repair, thus potentially serving as tumor markers. A few lncRNA species have emerged as potential prostate cancer biomarkers such as prostate cancer gene expression marker-1 (PCGEM1) and prostate cancer noncoding RNA1 (PRNCR1), which enhance androgen receptor (AR)-dependent gene activation, and prostate cancer-associated ncRNA transcript-1 (PCAT1), which silences BRCA2 via posttranscriptional homologous recombination (1). Notably, the most specific biomarker in human prostate cancer identified to date is an lncRNA, prostate cancer antigen 3 (PCA3, also known as PCA3 DD3 or DD3 PCA3 ), which is up-regulated in human prostate cancer (2). Since its discovery more than 15 y ago, PCA3 has been extensively investigated (3) and has been approved for clinical applications to aid the diagnosis of prostate cancer in both the European Union and the United States. Paradoxically-despite its striking clinical specificity-the inherent cellular role of the lncRNA PCA3 in human prostate cancer, if any, remains completely unknown (1). Here we report a unique biological function for PCA3. Within a single functional genetic unit, we show that PCA3 is an antisense intronic lncRNA that down-regulates an as yet unrecognized tumor suppressor gene, a human homolog of the Drosophila prune gene, PRUNE2, through a process that involves RNA editing mediated by a supramolecular complex containing adenosine deaminase acting on RNA (ADAR) family members. We propose a working model in which PCA3 acts as a dominant-negative oncogene in prostate cancer and show consistent results in therapeutic preclinical models and in patient-derived human samples. Therefore, the molecular interaction of PRUNE2...
