Tumor specimens were collected from 54 prostate cancer patients at the time of a local recurrence following therapy failure. In 26 cases, paired primary tumor specimens from the same patients prior to therapy were also available. Fifteen (28%) of the recurrent therapy-resistant tumors, but none of the untreated primary tumors, contained AR gene amplification as determined by fluorescence in situ hybridization. According to single-stranded conformation polymorphism analysis, the AR gene was wild type in all but one of the 13 AR amplified cases studied. In one tumor, a presumed mutation in the hormone-binding domain at codon 674 leading to a Gly --> Ala substitution was found, but functional studies indicated that this mutation did not change the transactivational properties of the receptor. AR amplification was associated with a substantially increased level of mRNA expression of the gene by in situ hybridization. Clinicopathological correlations indicated that AR amplification was most likely to occur in tumors that had initially responded well to endocrine therapy and whose response duration was more than 12 months. Tumors that recurred earlier or those that showed no initial therapy response did not contain AR amplification. The median survival time after recurrence was two times longer for patients with AR amplification in comparison to those with no amplification (P = 0.03, Willcoxon-Breslow test).
In conclusion, failure of conventional androgen deprivation therapy in prostate cancer may be caused by a clonal expansion of tumor cells that are able to continue androgen-dependent growth despite of the low concentrations of serum androgens. Amplification and the increased expression of a wild-type AR gene may play a key role in this process.
Pasi Koivisto, Juha Kononen, Christian Palmberg, et al. Cancer Res 1997;57:314-319.
Pasi Koivisto1, Juha Kononen1, Christian Palmberg2, Teuvo Tammela2, Eija Hyytinen1, Jorma Isola1, Jan Trapman3, Kitty Cleutjens3, Arjan Noordzij3,4, Tapio Visakorpi1,5, Olli-P. Kallioniemi1,5
1. Laboratory of Cancer Genetics, Institute of Medical Technology. University of Tampere, Tampere University Hospital, Tampere, Finland
2. Instittue of Medical Tech, University of Tampere, Division of Urology, Tampere University Hospital, Tampere, Finland
3. Departments of Pathology, Erasmus University, Rotterdam, The Netherlands
4. Department of Urology, Erasmus University, Rotterdam, The Netherlands
5. Laboratory of Cancer Genetics, National Center for Human Genome Research, NIH, Bethesda, Maryland