Activation of signal transducer and activator of transcription 5 in human prostate cancer is associated with high histological grade.

We have recently identified signal transducer and activator of transcription 5 (Stat5) as a critical survival factor for prostate cancer cells. We now report that activation of Stat5 is associated with high histological grade of human prostate cancer. Specifically, immunohistochemical analysis demonstrated a strong positive correlation with activation of Stat5 and high Gleason score in 114 human prostate cancers. To investigate the mechanisms underlying constitutive activation of Stat5 in prostate cancer, a dominant-negative mutant of Janus kinase 2 (Jak2) was delivered by adenovirus to CWR22Rv cells. Dominant-negative-Jak2 effectively blocked the activation of Stat5 whereas wild-type Jak2 enhanced activation, indicating that Jak2 is the main kinase that phosphorylates Stat5 in human prostate cancer cells. A ligand-induced mechanism for activation of Stat5 in prostate cancer was suggested by the ability of prolactin (Prl) to stimulate activation of both Jak2 and Stat5 in CWR22Rv human prostate cancer cells and in CWR22Rv xenograft tumors. In addition, Prl restored constitutive activation of Stat5 in five of six human prostate cancer specimens in ex vivo long-term organ cultures. Finally, Prl protein was locally expressed in the epithelium of 54% of 80 human prostate cancer specimens with positive correlation with high Gleason scores and activation of Stat5. In conclusion, our data indicate that increased activation of Stat5 was associated with more biologically aggressive behavior of prostate cancer. The results further suggest that Jak2 is the principal Stat5 tyrosine kinase in human prostate cancer, possibly activated by autocrine/paracrine Prl.

Inhibition of transcription factor Stat5 induces cell death of human prostate cancer cells.

Identifying regulators of prostate cancer cell survival may lead to new therapeutic strategies for prostate cancer. We now report prevalent activation of transcription factor Stat5 in human prostate cancer and provide novel evidence that blocking activation of Stat5 in human prostate cancer cells leads to extensive cell death. Specifically, Stat5 was activated in 65% of human prostate cancer specimens examined based on nuclear location of tyrosine phosphorylated Stat5. Adenoviral gene delivery of a dominant-negative Stat5 mutant (DNStat5), but not wild-type Stat5, induced cell death of both the androgen-independent human prostate cancer cell line CWR22Rv and the androgen-sensitive LnCap cell line. Endogenous Stat5 was active in both CWR22Rv and LnCap cells. In contrast, only low levels of inactive Stat5 proteins were detected in the PC-3 cell line, which correlated with resistance to DNStat5-induced cell death. In CWR22Rv and LnCap cells, inhibition of Stat5 by expression of DNStat5 induced apoptotic cell death as judged from morphological changes, DNA fragmentation, and caspase-3 activation with evidence of a caspase-9-dependent mechanism. We propose that blocking Stat5 function may represent a novel therapeutic approach for prostate cancer.

PRL signal transduction in the epithelial compartment of rat prostate maintained as long-term organ cultures in vitro.

Using long-term organ cultures of rat prostate tissue explants, we previously demonstrated that PRL both stimulates proliferation and acts as an androgen-independent suppressor of apoptosis in prostate epithelial cells, leading to epithelial hyperplasia. In this work we delineate intracellular signaling molecules activated by PRL in prostate tissue to identify candidate signaling proteins that are responsible for maintaining survival and proliferation of prostate epithelium in androgen-deprived growth environment. We now show that signal transducer and activator of transcription-5a (Stat5a) and Stat5b become tyrosine phosphorylated in response to PRL stimulation in rat prostate using prostate organ culture as an experimental model. Stat5 was translocated to the nuclei of epithelial cells of prostate tissue as demonstrated by immunohistochemistry. Furthermore, EMSA showed PRL-inducible binding of Stat5a homodimers and Stat5a/5b heterodimers to the PRL response element of the beta-casein gene promoter. Signaling molecules Stat3, Stat1, MAPK, or protein kinase B, which can be activated by PRL in other target cells, were not activated by PRL in prostate tissue. Furthermore, we show that Stat5a and Stat5b are continuously phosphorylated in rat prostate in vivo, although they are expressed to varying degree in separate lobes of rat prostate. Collectively, our results suggest that PRL signaling in rat prostate tissue is primarily transduced via Stat5a and Stat5b. The Stat5 pathway represents one candidate signaling mechanism, used by PRL and possibly other growth factors and cytokines, that supports the viability of prostate epithelial cells during long-term androgen deprivation.