Differential regulation of protooncogene c-myc expression in rat ventral prostate after castration

To evaluate the possibility that the protooncogene c-myc plays a role in ventral prostate, the effects of castration have been investigated at a beginning of a period by Northern blot hybridization and the levels of c-myc mRNA were also compared with mRNA of androgen-regulated genes, C1 and TRPM-2. Levels of c-myc mRNA in ventral prostate increased with maximal stimulation reached at 6 hours (early induction) and 48 hours (late induction) after castration, respectively. The level of C1 mRNA did not change and TRPM-2 was not detected at early induction of c-myc mRNA after castration. The level of early induction of c-myc mRNA after castration was increased in ventral prostate treated with cycloheximide, but it was almost reduced by actinomycin-D pretreatment. Administration of androgen at the time of castration prevented early induction of c-myc mRNA. These results suggest that protooncogene c-myc is differentially regulated in ventral prostate after castration.     

Simultaneous activation of heat shock protein (hsp 70) and nucleolin genes during in vivo and in vitro prereplicative stages of rat hepatocytes.

Rapidly growing cells usually have high levels of ribosome biogenesis. The sequential expression of protooncogenes during the transition of quiescent hepatocytes to the replicative stage was assumed to be followed by activation of cellular genes related to cell growth such as ribosome biosynthesis. First, the expression of major nucleolar protein (nucleolin or C23) and major heat-shock protein (hsp 70) genes was examined during rat liver regeneration. hsp 70 may function in cell growth and has a characteristic nucleolar location after heat shock. Both nucleolin and hsp 70 mRNA began to increase simultaneously after peaks of c-fos and c-myc, showed a peak 6 h after partial hepatectomy, and declined to the control levels around 20 h. That is, the peaks of nucleolin and hsp 70 mRNA precede the peak of ribosome formation (12-20 h) and DNA replication (24 h). Second, the behavior of nucleolin and hsp 70 mRNA was examined in primary cultured hepatocytes during their G0-G1 transition. Although the amounts of c-myc mRNA reached a plateau around 20 h after the initiation of culture and remained at these levels, DNA synthesis has never been found to start without the addition of EGF and insulin to this system. Both nucleolin and hsp 70 mRNA began to increase at around 20 h (prereplicative stage) and simultaneously decreased in inverse proportion to DNA synthesis induced by these growth factors. Thus, it is possible that the simultaneous enhancement of nucleolin and hsp 70 genes as described above is not merely coincidental, but is important biologically during the transition of quiescent hepatocytes to proliferative cells.     

Androgen repression of the production of a 29-kilodalton protein and its mRNA in the rat ventral prostate

The regression of the ventral prostate, after a rat is deprived of androgens by castration, is accompanied by a marked decrease in the prostate's ability to synthesize RNA and major proteins. Surprisingly, in vitro translation of prostate RNA, isolated from rats 2 days after castration, detects four proteins with Mr of approximately 29,000, 37,000, 46,000, and 49,000 whose message levels increased 4- to 12-fold compared to results from normal rats. According to cDNA dot hybridization analysis, the increase after castration in the level of the 29-kDa protein-mRNA (per unit amount of DNA) was reversed within 6 h by androgen treatment of castrated rats. In contrast, the level of a mRNA in male rat liver, which hybridized to a cloned probe for the prostate 29-kDa protein-mRNA was reduced by castration and increased by androgen treatment. During an in vitro incubation, the ventral prostates of normal rats were much less efficient than the prostates of rats castrated 2 days earlier in synthesizing a 29-kDa protein. Despite the fact that androgenic manipulation of rats induced very rapid and significant changes in the production of the 29-kDa protein and in the level of its mRNA, the cellular level of this protein in the prostate, as determined by radioimmunoassay, was maintained at near normal values throughout the 2-week experimental period. Thus, the prostate appears to have a mechanism, based on androgen repression of certain genes, to maintain the cellular levels of the 29-kDa protein and possibly other structurally or functionally important proteins during both the periods of androgen-dependent growth and the castration-induced regression. The loss of such a regulatory mechanism may result in androgen-independent abnormal prostate growth.     

Oxidative stress signalling in the apoptosis of Jurkat T-lymphocytes

Within the first 24 h after castration of an adult male rat, the vascular system of the ventral prostate gland undergoes a degenerative process that drastically reduces blood flow to the tissue. Since the vascular degeneration precedes the loss of the prostatic epithelium (by apoptosis), we have proposed that the onset of epithelial cell apoptosis in this tissue is caused by an ischemic/hypoxic environment resulting from the loss of blood flow. In order to further evaluate the extent to which ischemia/hypoxia might be a factor in apoptosis of the prostate epithelium after castration, we analyzed for biomarkers of cellular hypoxia in rat ventral prostates during the first 3 days following castration. Ventral prostate tissues removed from hypoxyprobe-1-treated adult male rats (uncastrated controls; surgically castrated for 24, 48 or 72 h, or sham-castrated for equivalent times) were directly analyzed for evidence of hypoxia by in situ immunohistochemical evaluation of hypoxyprobe-1 adduct formation in the prostate cells. Protein extracts from these tissues were also tested for expression of the 120 kDa hypoxia-inducible factor-1-alpha (HIF-1-alpha) protein as well as for expression of mitogen-activated protein kinase (MAPK) and c-Jun N-terminal kinase (JNK) proteins using a Western blot assay. The tyrosine phosphorylation status of the latter signaling molecules was also evaluated by Western blotting using anti-tyrosine phosphate antibodies. Our results showed that epithelial cells of the rat ventral prostate stained positively for hypoxyprobe-1 adducts at all times after castration, whereas cells in control tissues were unstained by this procedure. In addition, the prostatic expression of HIF-1-alpha protein was increased approximately 20-fold at 48 h after castration compared to control tissues. Finally, although prostatic MAPK and JNK protein expression was unaltered during the early period after castration, phosphorylation of the JUN kinase protein was significantly elevated, indicating that this stress-activated cellular signaling pathway becomes more active subsequent to castration. These results support our proposal that early castration-induced degeneration and constriction of the vascular system of the rat ventral prostate gland leads to reduced oxygenation of prostatic epithelial cells and the activation of hypoxic cellular signaling in these cells through upregulation of HIF-1-alpha expression and stimulation of the JUN kinase signaling pathway.     

Androgen regulation of FLICE-like inhibitory protein gene expression in the rat prostate

In hope of eventually identifying defects in human prostatic neoplasias that render them insensitive to anti-androgen therapy, we have examined the regulation of components of ligand-induced cell death pathways during castration-induced regression of the prostate. Rat prostates were obtained after surgical castration with or without subsequent androgen replacement. The mRNA levels of genes encoding components of the apoptotic pathway were measured from individual prostates. Whole prostates 1-10 days after castration did not show a significant change in mRNA levels encoding either Fas or FasL, which some studies suggest are necessary for regression to occur. However, the mRNA encoding a catalytically inactive cysteinyl aspartate-specific protease (caspase) analog, FLICE-like inhibitor protein (FLIP), decreases during the first day following castration. In the most apoptotically responsive ventral lobe of the rat prostate, the reduction in FLIP mRNA levels is evident within 12 h of castration. The mRNA levels of the principal target of FLIP inhibition, caspase-8, do not change during the period preceding the onset of detectable DNA fragmentation. Androgen administration to castrated rats reverses prostate regression, and restores FLIP mRNA to normal levels. By acting as an inhibitor of caspase-8, FLIP may protect prostatic epithelium from apoptosis. Androgen withdrawal, by reducing FLIP mRNA levels, might leave the cells vulnerable to as yet unidentified cell death signals.     

Autologous down-regulation of androgen receptor messenger ribonucleic acid

Autoregulation of androgen receptor (AR) mRNA was investigated using Northern blot analysis with AR cDNA fragments as probes. The amount of AR mRNA increased 2- to 10-fold with androgen withdrawal and decreased below control levels after androgen stimulation in rat ventral prostate, coagulating gland, epididymis, seminal vesicle, kidney, and brain, and in a human prostate cancer cell line, LNCaP. In rat ventral prostate, AR mRNA increased 2- to 3-fold within 24 h after castration and remained elevated for 4 days. Treatment with testosterone propionate beginning 24 h after castration reduced ventral prostate AR mRNA 4-fold within 8 h of androgen replacement. Administration of estradiol 24 h after castration had no significant effect on prostatic AR mRNA. Androgens, including testosterone and the synthetic androgen methyltrienolone (R1881), or the antiandrogen cyproterone acetate down-regulated AR mRNA in vitro in LNCaP cells, whereas estradiol was without effect. Administration of testosterone propionate to rats with androgen insensitivity did not decrease AR mRNA. Down-regulation of AR mRNA by androgen is therefore a receptor-mediated process which occurs in vivo in rat tissues that differ in androgen responsiveness and in cultured human prostate cells.     

TNF-alpha-related apoptosis-inducing ligand decoy receptor DcR2 is targeted by androgen action in the rat ventral prostate

The apoptotic cell death process in the prostate is known to be under the control of androgens. Tumor necrosis factor-alpha (TNF-alpha)-related apoptosis-inducing ligand (TRAIL) is a member of the TNF-alpha family of cytokines, known to induce apoptosis upon binding to its death domain-containing receptors, DR4/TRAIL-R1 and DR5/TRAIL-R2. Two additional TRAIL receptors, DcR1/TRAIL-R3 and DcR2/TRAIL-R4, lack functional death domains and act as decoy receptors for TRAIL. In this study, we examined whether TRAIL and cellular receptors expression was targeted by androgens during the apoptotic cell death process in the hormone sensitive ventral prostate. The role of androgens was investigated using two sets of experiment. (1) Androgen deprivation associated with an apoptotic process resulted in a decrease in DcR2 mRNA and protein expression in the ventral prostate 3 days after castration. Testosterone administration to castrated adult rats prevented the decrease in DcR2 mRNA and protein levels in the ventral prostate. In contrast, DcR2 expression was modified, neither in the dorsolateral nor in the anterior prostate following castration. No changes were observed in DR4, DR5, DcR1, and TRAIL mRNA and protein levels in prostate after castration. (2) A specific decrease in DcR2 expression was observed in the ventral prostate after treatment of rats with the anti-androgen flutamide. Together, the present results suggest that testosterone specifically controls DcR2 expression in the adult rat ventral prostate. Androgen withdrawal, by reducing DcR2 expression, might leave the cells vulnerable to cell death signals generated by TRAIL via its functional receptors.     

Urethral glands of the male mouse contain secretory component and immunoglobulin A plasma cells and are targets of testosterone.

The occurrence and possible functions of mucosal immunity in the male urogenital tract have not been extensively investigated. In this study we used immunolabeling to localize secretory component (SC) and immunoglobulin (Ig) A in the urogenital tract of the male mouse. SC was located in the ventral prostate, while SC and IgA plasma cells were both detected in the urethral glands in the pelvic and bulbous portions of the urethra. SC and IgA were not observed elsewhere in the urogenital tract. We also examined the ventral prostate and urethral glands of sham-castrated, oil-treated castrated, and testosterone-treated castrated mice. There was a striking reduction in the size of the ventral prostate and urethral glands in oil-treated castrates compared to the other two groups, based on gross and histological morphology. Morphometric analysis showed that the cell and nuclear sizes of the urethral gland acinar cells were reduced after castration and restored to normal size by testosterone treatment. Androgen receptors (AR) were localized in the nuclei of urethral gland cells by immunocytochemistry using anti-AR antibodies. Labeling of SC and IgA plasma cells was similar in the urethral glands and ventral prostates of sham- and testosterone-treated castrates, but was reduced or absent at these sites in oil-treated castrates. These studies show that the ventral prostate and urethral glands may be sites for secretory immunity in the male murine urogenital tract, and that the urethral glands are targets for testosterone.     

Intravesicular Fas localization in epithelial cells of castrated rat prostate glands

Androgenic steroids regulate the development and size of mammalian prostate epithelial cells. To evaluate the relationship between Fas-Fas ligand system and apoptosis in prostate epithelial cells of the castrated rats, we have examined immunocytochemical localization of Fas antigen in the castrated rat prostate glands at a series of different times. We used a rabbit polyclonal anti-Fas antibody with a streptavidin-biotin method and confocal laser scanning method or an immunogold method. Fas immunolocalization was examined in ventral lobes of prostate glands taken from intact or castrated adult male Wistar rats on day 1, 2, 3, 4 and 5 by light or electron microscopy. At a light microscopic level, the castrated prostate epithelial cells showed mostly Fas immunolocalization in their apical parts of cytoplasm on day 2 after the castration. In addition, their extent of the Fas expression was expanded throughout the cytoplasm in proportion to the androgen ablation periods, and later the Fas expression was detected at luminar or basolateral sides of the epithelial cells. Both immunogold labeling with ultrathin sections and immunoperoxidase technique with cryostat sections demonstrated that Fas was localized mainly in secretory granules of the castrated prostate epithelial cells and some parts of their cell membranes at later stages. Our immunocytochemical findings showed that Fas expression was time-dependently induced in most of the prostatic epithelial cells after castration of rats. The rate of Fas-expressing epithelial cells was too high and inconsistent with the previously reported rate of TUNEL-positive ones. The membrane-associated Fas may have little effect on the apoptosis in the present case, bacause a lot of soluble Fas was secreted from the prostatic epithelial cells. A further study is needed to clarify some significance of the secretory Fas in the prostatic epithelium after the rat castration.