Conditional Expression of the Androgen Receptor Increases Susceptibility of Bladder Cancer in Mice

Bladder cancer represents a significant human tumor burden, accounting for about 7.7% and 2.4% of all cancer cases in males and females, respectively. While men have a higher risk of developing bladder cancer, women tend to present at a later stage of disease and with more aggressive tumors. Previous studies have suggested a promotional role of androgen signaling in enhancing bladder cancer development. To directly assess the role of androgens in bladder tumorigenesis, we have developed a novel transgenic mouse strain, R26hARLoxP/+:Upk3aGCE/+, in which the human AR transgene is conditionally expressed in bladder urothelium. Intriguingly, both male and female R26hARLoxP/+:Upk3aGCE/+ mice display a higher incidence of urothelial cell carcinoma (UCC) than the age and sex matched control littermates in response to the carcinogen, N-butyl-N-(4-hydroxybutyl) nitrosamine (BBN). We detect expression of the human AR transgene in CK5-positive and p63-positive basal cells in bladder urothelium. Further analyses of UCC tissues from R26hARLoxP/+:Upk3aGCE/+ mice showed that the majority of tumor cells are of urothelial basal cell origin. Positive immunostaining of transgenic AR protein was observed in the majority of tumor cells of the transgenic mice, providing a link between transgenic AR expression and oncogenic transformation. We observed an increase in Ki67 positive cells within the UCC lesions of transgenic AR mice. Manipulating endogenous androgen levels by castration and androgen supplementation directly affected bladder tumor development in male and female R26hARLoxP/+:Upk3aGCE/+ mice, respectively. Taken together, our data demonstrate for the first time that conditional activation of transgenic AR expression in bladder urothelium enhances carciongen-induced bladder tumor formation in mice. This new AR transgenic mouse line mimics certain features of human bladder cancer and can be used to study bladder tumorigenesis and for drug development.


Introduction
Bladder cancer represents a significant human tumor burden, with more than 70,000 new cases of bladder cancer diagnosed in the nation annually, resulting in approximately 16,000 deaths [1]. It accounts for about 7.7% and 2.4% of all cancer cases in males and females, respectively [1]. However, the mortality rates of male and female patients are approximately 20.4% and 25.4%, respectively [2]. The above evidence suggests that men have a higher risk of bladder cancer, whereas women tend to have more aggressive tumors. Currently, the molecular mechanisms underlying these gender differences in bladder tumorigenesis are unclear.
Androgen signaling plays a promotional role in prostate cancer growth, and thus, androgen ablation therapy is an effective treatment for patients with naïve prostate cancer [3]. Emerging evidence has also implicated an important role of androgen signaling in bladder tumorigenesis [4][5][6][7]. Expression of the androgen receptor (AR) has been detected in both murine as well as human bladder urothelium and submucosa [7,8]. Previous studies have suggested that androgen signaling may directly or indirectly enhance bladder cancer development [7]. Decreased bladder tumor incidence has been observed in an Ar knockout mouse model (ARKO) [5,7]. However, it appears that there is no significant correlation between tumor grades and AR expression levels in clinical patient samples [8,9] A carcinogen-induced mouse model system has been frequently used to investigate the development of urothelial cell carcinoma (UCC). Mice exposed to N-butyl-N-(4-hydroxybutyl) nitrosamine (BBN) develop a spectrum of bladder pathologies, including muscle-invasive carcinomas, non-invasive carcinoma, squamous cell carcinomas, and hyperplasia [10,11]. Interestingly, in this mouse model, a clear sexual dimorphism in bladder carcinogenesis has been observed [7,10]. The incidence of bladder cancer in male mice was about two times greater than in female mice [7]. Moreover, neither male nor female ARKO mice developed bladder carcinoma after 12-weeks of exposure to BBN [7]. Similar to the full-body Ar knockout mice, male mice with conditional deletion of Ar in bladder urothelium by uroplakin II (UPII) promoter driven Cre were less susceptible to BBN-induced bladder carcinoma development [5]. Additionally, decreased bladder urothelium cellular proliferation was observed in both fullbody and urothelial-specific Ar knockout mice [5,7]. These studies implicate a promotional role for androgen signaling in the oncogenic transformation of bladder urothelium.
To directly assess the biological role of androgen signaling in bladder tumorigenesis, we recently generated a conditional AR transgenic mouse line, R26hAR LoxP , in which a human AR transgene was specifically targeted into the ROSA26 locus, R26hAR LoxP/+ [16,17]. The AR transgene in this mouse model can be constitutively expressed in a tissue specific manner through the activation of Cre recombinase [18]. We intercrossed the R26hAR LoxP/+ and Upk3a GCE/+ mice in order to target inducible expression of the AR transgene to the bladder urothelium. Both male and female R26hAR LoxP/+ :Upk3a GCE/+ mice showed increased susceptibility to BBN-induced urothelial cell carcinoma (UCC) development after conditional expression of the AR transgene. Expression of both cytokeratin 5 (CK5) and p63, cellular markers of basal cells in the bladder urothelium, is detected in tumor cells of UCC lesions. Manipulating endogenous androgen levels by castration and androgen supplementation directly affected bladder tumor development in male and female R26hAR LoxP/+ :Upk3a GCE/+ mice, respectively. Taken together, our data demonstrate for the first time that conditional activation of transgenic AR expression in bladder urothelium enhances carcinogen-induced bladder tumor formation in mice.

Mouse Experiments
The R26hAR-floxed mice were generated as previously described [18]. To generate the conditional AR transgenic mice, we intercrossed R26hAR loxP/wt mice with the Upk3a GCE/+ strain (JAX stock: 015855). For genotyping, mouse tail tips were isolated between age 2-3 weeks and incubated in lysis buffer (Cat# 102-T, VIAGEN Biotech, LA, CA) overnight at 55°C. Samples were briefly spun down and genomic DNA was dissolved in TE buffer. Three primers that can distinguish the wild type from the AR target allele were used for genomic PCR amplification. The forward primer, 5'-CTCTGCTGCCTCCTGGCTTCT-3', was used for both wild type and targeted alleles, and the reverse primer for the wild type allele was 5'-CGAGGCGGATCA CAAGCAATA-3', and for targeted allele was 5'-TCAATGGGCGGGGGTCGTT-3'. PCR fragments for genotyping were amplified at 94°C for 5 min, then 94°C for 20 sec, 64°C for 30 sec, and 72°C for 25 sec for 30 cycles, then 72°C for 2 min. To assess recombination, the forward primer 5'-TTCGGCTTCTGGCGTGTGAC-3' and the reverse primer 5'-GCTGTGATGA TGCGGTAGTC-3' were used in genomic PCR reactions. PCR fragments were amplified at 95°C for 5 min, then 95°C for 45 sec, 63°C for 50 sec, and 72°C for 2 min for 40 cycles, then 72°C for 5 min.
For castration experiments and testosterone pellet insertion, both R26hAR LoxP/+ :Upk3a GCE/+ mice and their control littermates were anesthetized by IP injection with Ketamine and Xylazine. To castrate male mice, both testicles and epididymides were removed through a scrotal approach. The distal end of the spermatic cord was ligated with silk suture as described previously [19]. For pellet insertion, female mice were anesthetized as described above. The testosterone pellet was inserted subcutaneously in the back at the nape of the neck. All animal experiments performed in this study were approved by the Administrative Panel on Laboratory Animal Care at Stanford University.

Tamoxifen Injection and BBN Treatment
Both 5-week-old R26hAR LoxP/+ :Upk3a GCE/+ mice and their control littermates were administrated tamoxifen in corn oil, approximately 5 mg / 25 g body weight, by IP injection five times within a three week period. Following the last injection, at 8 weeks of age, mice were given tap water containing 0.1% of N-butyl-N-(4-hydroxybutyl) nitrosamine (BBN) ad libitum (TCI America, Portland, OR) for 12 weeks, and then normal water for one week prior to analyses. The mice were sacrificed and urinary bladders and other abnormal tissues were collected and preserved in 10% neutral buffered formalin. Mouse tissues were embedded in paraffin, sectioned, and stained with hematoxylin and eosin (H&E). At least three individual slides from each mouse were prepared and assessed for pathologic abnormalities.

Statistical Analyses
We presented the data as the mean ±SD. We made comparisons between groups using a twosided Student's t test. P<0.05 and P<0.01 were considered significant.

Expression of Upk3a in Mouse Bladder Urothelium
The Upk3a GCE/+ , transgenic mice were generated by inserting a tamoxifen-inducible Cre recombinase (CreERT2) and eGFP fusion gene under the control of the mouse Upk3a promoter. As reported previously, Upk3a GCE/+ mice appear phenotypically normal without any abnormalities [15]. To identify Upk3a expression cells, we generated Rosa26-mT/mG (R26RmT/mG):Upk3a GCE/+ mice by intercrossing R26RmT/mG [20] and Upk3a GCE/+ mouse strains ( Fig 1A). In this mouse model, tamoxifen (TM)-induced Cre activity can switch membrane-bound tdTomato (mT) to membrane-bound green fluorescent protein (mGFP) expression through recombination of the floxed reporter loci in targeted cells. We administrated one dose of tamoxifen (TM) or vehicle control to 6-week old R26RmT/mG:Upk3a GCE/+ mice and analyzed them two weeks post injection ( Fig 1B). We observed specific expression of mGFP expression in the bladder urothelium of TM-induced R26RmT/mG:Upk3a GCE/+ mice, but not in uninduced controls (Fig 1C-1D'). It has been suggested that adult rodent bladder urothelium consists of three separate populations of cells: umbrella, intermediate, and basal cells. Umbrella cells, also known as superficial cells, line the bladder lumen and highly express uroplakins and CK8, but not p63 or CK5 [10]. Intermediate cells reside underneath the umbrella cells and express both uroplakins and p63, but not CK5. Basal cells lie adjacent to the lamina propria and surrounding muscle tissues and express CK5 and p63 [21][22][23]. Using coimmunofluorescence assays, we further characterized the cellular identity of mGFP expression cells in the bladder urothelium with Ck5, Ck8, and p63 antibodies (Fig 1E-1G"). We observed the expression of Ck5 (Fig 1E"), p63 (Fig 1F"), and CK8 (Fig 1G") overlaid with mGFP staining suggesting that most of the cells in bladder urothelium are targeted by Upk3a GCE/+ mice [21].

Conditional Expression of the AR Transgene in Mouse Bladder Urothelium
Although the potential effect of the Ar has been assessed previously using a tissue-specific Ar knockout mouse model driven by UPII-Cre model [5], AR-mediated oncogenic transformation in bladder tumorigenesis remains unclear. To directly address the promotional role of the AR in bladder cancer initiation and progression, we generated R26hAR LoxP/+ :Upk3a GCE/+ mice ( Fig  2A). As demonstrated in R26RmT/mG:Upk3a GCE/+ mice, expression of transgenic AR protein can be induced in bladder urothelium after TM administration. We administered TM to R26hAR LoxP/+ :Upk3a GCE/+ and R26hAR LoxP/+ controls starting at 5 weeks of age (Fig 2B). Using genomic PCR approaches, we confirmed the activity of CreER in bladder tissues, resulting in a 300 bp PCR fragment corresponding to the deletion of the LSL cassette through loxP/Cre recombination in bladder tissues of R26hAR LoxP/+ :Upk3a GCE/+ mice with TM induction, but not in those of R26hAR LoxP/+ mice at 8 weeks of age ( Fig 2C). We confirmed transgenic AR protein expression through immunohistochemistry with either an antibody (441, Santa Cruz, sc-7305) specific for transgenic human AR protein, hAR, or an antibody (N-20, Santa Cruz, sc-816) against both human and mouse AR proteins, m&hAR. Using these two different antibodies allowed us to distinguish transgenic human AR from endogenous mouse Ar in mouse bladder tissues. Nuclear AR staining with the m&hAR antibody is detected in the bladder urothelium of both R26hAR LoxP/+ :Upk3a GCE/+ (Fig 2F and 2F') and R26hAR LoxP control mice (Fig 2D and 2D'), though the intensity of the former is stronger than the latter. As expected, positive nuclear staining with the human AR specific antibody, hAR, was only observed in bladder urothelial tissues isolated from R26hAR LoxP/+ :Upk3a GCE/+ mice (Fig 2E and 2E'). These data indicate that expression of the AR transgene in bladder urothelium is a result of the LoxP/ Cre recombination through TM-activated Cre transgene driven by the Upk3a promoter.
Using immunofluorescent approaches, we further confirmed expression of transgenic AR protein in bladder urothelium through TM-induced LoxP/Cre recombination in R26hAR LoxP/+ : Upk3a GCE/+ mice ( Fig 2J' and 2K'), but not in R26hAR LoxP/+ only control mice (Fig 2H' and 2I'). In line with our observation in R26RmT/mG:Upk3a GCE/+ mice, we observed a clear overlay of transgenic AR expression with both CK5 and p63 expression in urothelial cells of R26hAR LoxP/+ :Upk3a GCE/+ mice ( Fig 2J" and 2K"), suggesting that transgenic AR expression is present in basal and intermediate cell populations in bladder urothelium [21].

Conditional Expression of Transgenic AR in Mouse Bladder Urothelium Enhances Susceptibility to Carcinogen-Induced Tumor Formation
N-butyl-N-(4-hydroxybutyl) nitrosamine (BBN) is a well-established carcinogen that has been frequently used in rodents to induce urinary bladder cancer [24], which bears significant histopathological and molecular similarities to the human disease [25]. Therefore, we assessed whether transgenic AR expression in bladder urothelium changes the susceptibility to BBNinduced tumorigenesis. Both R26hAR LoxP/+ :Upk3a GCE/+ and R26hAR LoxP/+ mice were administrated TM at 5 weeks of age, and were then treated with 0.1% BBN in their drinking water starting at 8 weeks of age, for 12 weeks. Mice were sacrificed 1 week after ending BBN treatment (Fig 3A). Gross and histological analyses showed a spectrum of pathological changes in bladder urothelium, which included hyperplasia, carcinoma in situ, non-invasive urothelial cell carcinoma, and invasive urothelial cell carcinoma (Fig 3B-3E'). Interestingly, eight out of twelve male R26hAR LoxP/+ :Upk3a GCE/+ mice developed invasive urothelial cell carcinoma (67%), bearing the most severe tumor phenotypes in comparison to mice of other genotypes (Fig 3F). In contrast, only three of thirteen age matched male R26hAR LoxP/+ control littermates developed invasive urothelial cell carcinoma (23%). Furthermore, five out of thirteen female  Fig 2A) with bladder urothelium tissue samples of R26AR LoxP/+ Upk3a GCE/+ and R26AR LoxP/+ mice. The AR trangene allele was detected in the samples of both R26AR LoxP/+ Upk3a GCE/+ and R26AR LoxP/+ mice (black arrow), but TM induced recombination on the AR transgene allele was only observed in R26AR LoxP/+ Upk3a GCE/+ mice (white arrow). (D-F') Immunohistochemical staining of the bladder urothelium of TM injected R26AR LoxP/+ mice using either the R26hAR LoxP/+ :Upk3a GCE/+ mice also developed invasive urothelial cell carcinomas (39%) while no age-matched female R26hAR LoxP/+ control littermates developed either non-invasive or invasive urothelial cell carcinomas (Fig 3F). These data demonstrate that conditional expression of transgenic AR in bladder urothelium cells enhances susceptibility to oncogenic antibody that is reactive to both mouse and human AR protein (m&hAR), or the antibody that is reactive to only human AR (hAR) (n = 9). (F-G') Immunohistochemical staining of the bladder urothelium with the two different AR antibodies as described above using the samples of TM-injected R26AR LoxP/+ Upk3a GCE/+ mice (n = 12). (H-K") Single channel and merged immunofluorescent images of bladder tissues of TM-injected R26AR LoxP/+ and R26AR LoxP/+ Upk3a GCE/+ mice stained with antibodies against CK5 p63, and the human AR (in red) (n = 6). doi:10.1371/journal.pone.0148851.g002

BBN-Induced Urothelial Cell Carcinomas in R26hAR LoxP/+ :Upk3a GCE/+ Are Urothelial Intermediate and Basal Cell Origin
It has been shown that BBN induced the development of bladder urothelial cell carcinoma in mice [6,22]. To further define the origin of bladder tumors in the R26hAR LoxP/+ :Upk3a GCE/+ mice, we performed immunohistochemical analyses to examine a series of cellular markers in tumor tissues. As shown in Fig 4A-4D', tumor cells showed positive immunostaining with the human AR antibody (Fig 4A and 4A'), suggesting a link between transgenic AR expression and BBN-induced oncogenic transformation. Tumor cells showed strong positive staining for CK5 (Fig 4B and 4B'), which is a hallmark of pathologies arising from the basal cells [22]. Slight staining of CK8 was also observed in tumor cells (Fig 4C and 4C'). Most tumor cells were also reactive to p63 antibody (Fig 4D and 4D'). Using co-immunofluorescent approaches, we further characterized the cellular identity of tumor cells. Nuclear staining of transgenic AR overlaid uniformly with cytoplasmic membrane staining of CK5 in tumor cells of R26hAR LoxP/+ : Upk3a GCE/+ mice (Fig 4F-4F"). Additionally, most CK5 positive tumor cells isolated from both R26hAR LoxP/+ :Upk3a GCE/+ and R26hAR LoxP/+ mice were also reactive to p63 antibodies ( Fig 4G-4H"). Taken together, these data suggest that the origin of BBN-induced bladder urothelial cell carcinoma is mainly derived from basal cells in R26hAR LoxP/+ :Upk3a GCE/+ mice and R26hAR LoxP/+ controls.

Transgenic AR Expression Promotes Tumor Cell Proliferation in the
Bladder of R26hAR LoxP/+ :Upk3a GCE/+ Mice A promotional role of AR in cellular proliferation has been previously demonstrated in the prostate [26][27][28]. We investigated the potential effect of transgenic AR expression in promoting cellular proliferation in bladders of BBN-treated R26hAR LoxP/+ :Upk3a GCE/+ mice. We performed immunohistochemistry to stain bladder tissue slides with Ki67 antibody from both male and female R26hAR LoxP/+ :Upk3a GCE/+ and R26hAR LoxP/+ mice (Fig 4I-4L). Ki67 immunostaining was quantified by counting a total of 1000 bladder urothelial cells from five highpower fields in each sample. Three mice in each sex and genotype were analyzed, representative data is shown (Fig 4I-4L). The proliferative index in the male R26hAR LoxP/+ :Upk3a GCE/+ group was approximately one-fold greater than in male R26hAR LoxP/+ control mice, and female R26hAR LoxP/+ and R26hAR LoxP/+ :Upk3a GCE/+ mice (Fig 4M). These results implicate a promotional role of transgenic AR expression in cellular proliferation of BBN-induced bladder urothelial tumors.
Androgens Play a Dominant Role in Increasing the Susceptibility to BBN Induced Urothelial Carcinoma Development in R26hAR LoxP/+ : Upk3a GCE/+ Mice In this study, we observed the highest incidence of BBN-induced invasive urothelial cell carcinomas in male R26hAR LoxP/+ :Upk3a GCE/+ mice compared to other sex and genotype mice. In addition, tumor cells from R26hAR LoxP/+ :Upk3a GCE/+ mice appeared to be more proliferative than those from other groups of mice. The AR is a member of the steroid hormone receptor superfamily [29], and its activity is regulated through androgens in general. To further characterize the role of the androgen axis in R26hAR LoxP/+ :Upk3a GCE/+ mice, we manipulated androgen levels by either castrating male mice or supplementing female mice with androgen pellets. We then assessed BBN-induced bladder tumorigenesis in the above mice ( Fig 5A). Intriguingly, castrated male R26hAR LoxP/+ control mice only developed bladder urothelial hyperplasia ( Fig  5B). However, 2 out of 5 (40%) castrated R26hAR LoxP/+ :Upk3a GCE/+ mice developed urothelial carcinomas. As we previously observed, intact male R26hAR LoxP/+ :Upk3a GCE/+ mice showed the highest incidence of urothelial cell carcinomas among the various groups of mice in this study (Fig 5B).
In this set of experiments, we examined cellular proliferation using Ki67 immunohistochemistry with samples isolated from different genotype, treatment, and gender groups. As shown in Fig 5C, we observed higher Ki67 staining from samples isolated from intact R26hAR LoxP/+ :Upk3a GCE/+ mice than those from castrated counterparts. There was no significant difference in Ki67 staining between intact and castrated R26hAR LoxP/+ male mice, as well as female R26hAR LoxP/+ :Upk3a GCE/+ mice that either received or did not receive androgen pellet insertion. Interestingly, tumor cells in the female R26hAR LoxP/+ mice without pellet supplement showed higher Ki67 staining than tumor cells from the mice with pellets (Fig 5C), which implies that other signaling pathways may also be involved in regulating tumor cell proliferation in BBN-induced bladder urothelial tumors in this group of mice.

Discussion
In this study, we directly address a long-unanswered question regarding the biological role of androgen signaling in bladder tumorigenesis. Using R26RmT/mG:Upk3a GCE/+ reporter mouse line, we detected the activity of the Upk3a promoter in the bladder urothelium of mice. We then generated the R26hAR LoxP/+ :Upk3a GCE/+ mouse strain to directly assess the role of conditional expression of the AR in the basal and intermediate cells in bladder urothelium by BBNinduced bladder tumorigenesis. The data generated from this study provide the first line of evidence that demonstrates a promotional role of transgenic AR expression in enhancing the susceptibility to BBN-induced bladder urothelial carcinomas in mice.
Sexual dimorphism has been observed among human bladder cancer patients. Therefore, a potential role for androgen signaling as a contributing factor to the pathogenesis of bladder cancer has long been speculated. Initial studies examining AR expression in tissue lysates prepared from bladder tumor biopsies detected high levels of AR expression in both male and female patients when compared to samples from normal bladder urothelium [30]. Similar observations were also reported in bladder patient samples by using immunohistochemical approaches [8,9,31]. Earlier studies also showed decreased bladder tumor incidence in the Ar knockout mouse models, suggesting a protective role of AR deletion [5,7]. However, previous studies have not directly assessed the promotional role of the AR in bladder tumorigenesis using biologically relevant and appropriate in vivo systems. In this study, we addressed the biological significance and consequences of transgenic AR expression in bladder urothelial tumorigenesis using a new and unique mouse model, R26hAR LoxP/+ :Upk3a GCE/+ mice. We observed that conditional expression of the AR in bladder urothelium significantly enhances BBNinduced bladder cancer development in both male and female mice. These data suggest that dysregulation of AR activation may directly contribute to the sexual dimorphism observed in human bladder cancer development. In addition, our R26hAR LoxP/+ :Upk3a GCE/+ mouse model appears to be a unique and innovative tool that can be used to characterize the molecular mechanisms underlying AR action in bladder tumorigenesis.

Roles of Androgen Signaling in Bladder Tumorigenesis
Given the fact that the AR is a steroid hormone receptor and its activation is mainly through androgen signaling, we carefully characterized the effect of androgen axis in R26hAR LoxP/+ : Upk3a GCE/+ mice. Decreasing androgen levels by castration showed an inhibitory effect of BBN-induced tumor progression from bladder urothelial hyperplasia to urothelial carcinomas in both male R26hAR LoxP/+ :Upk3a GCE/+ mice and age-and sex-matched R26hAR LoxP/+ control littermates. Moreover, conditional expression of transgenic AR in female R26hAR LoxP/+ : Upk3a GCE/+ mice increased the incidence of BBN-induced bladder urothelial carcinomas compared to female R26hAR LoxP/+ control littermates. Keeping consistent to this line of evidence, androgen-supplemented female R26hAR LoxP/+ :Upk3a GCE/+ mice demonstrated the highest incidence of BBN-induced urothelial carcinoma compared to both untreated counterparts and female R26hAR LoxP/+ control littermates. Our data from this series of experiments suggest that androgen signaling enhances the susceptibility to BBN-induced bladder tumorigenesis in both genders.
The AR is a ligand-dependent transcription factor that upon binding to androgens can translocate to the nucleus, bind to androgen-responsive elements in DNA and activate transcription [32]. Transcriptional downstream target genes of the AR have been well investigated, particularly in male reproductive organs including the prostate. However, the downstream targets of AR in the bladder have not been well characterized. Interestingly, recent studies have shown increased Wnt/β-catenin signaling in response to AR activation in several bladder cancer cell lines [33,34]. In a mouse model expressing stabilized β-catenin, a three-fold decrease in bladder tumor incident was observed in castrated male mice in comparison to intact counterparts, implicating a link between the oncogenic effects of Wnt/β-catenin signaling and the androgen axis [34]. In this study, we examined the expression and cellular localization of βcatenin in bladder tissues of R26hAR LoxP/+ :Upk3a GCE/+ and R26hAR LoxP/+ mice. However, we did not observe any significant difference in β-catenin expression and cellular distribution between urothelial carcinoma cells in different mice genotypes (S1 Fig). We also examined the activity of Wnt/β-catenin signaling by examining the levels of the β-catenin downstream target, c-Myc, but also did not observe any significant differences between the tumor samples isolated from AR transgenic mice and controls (S1 Fig). It has also been suggested that CD24 was a downstream target of androgen signaling in bladder tissues, and may play a role in bladder tumorigenesis [35]. In the same study, it has been shown that deletion of CD24 reduced BBNinduced bladder carcinogenesis, and that tumor reduction effect was more striking in male than in female mice [35]. CD24 expression and related activity have also been correlated with decreased tumor growth and metastasis in both xenograft and transgenic knockout mouse models of bladder cancer [35,36]. However, we failed to detect CD24 expression in bladder tissue samples isolated from both R26hAR LoxP/+ :Upk3a GCE/+ and R26hAR LoxP/+ mice by using a variety of experimental approaches (data not shown). Currently, we do not know the reasons for the discrepancies between our results and previous reports. Given that the molecular mechanisms for controlling CD24 expression and activity remain elusive, more in-depth experiments using our current new mouse model are necessary to determine the regulatory role of androgen signaling in CD24 expression.
The pioneering work that depletion of androgens resulted in significant tumor regression in prostate cancer patients by Charles Huggins and Clarence Hodges demonstrated a key role of androgen-signaling in human prostate cancer [3]. The promoting role of androgen signaling through the AR in stimulating prostatic tumor cell growth has been well studied in human prostate cancer. However, it is still unclear whether androgen signaling can enhance or promote oncogenic transformation during the course of tumor initiation and progression in other tissues and organs. In this study, we used the BBN-induced urinary bladder carcinoma model to assess the potential role of androgen signaling in bladder tumorigenesis. We demonstrate a promotional role of androgen signaling in enhancing the susceptibility of BBN-induced bladder tumorigenesis. Using different experimental approaches to manipulate endogenous androgen levels, we have shown that the effect of transgenic AR expression in bladder urothelial cells is mediated through androgens in both male and female mice. Moreover, we observed that transgenic AR expression increases cellular proliferation. Given the nature of our study using the BBN-induced bladder tumor model, our findings also suggest that other factors may play a dominant role in inducing bladder tumor initiation and progression. Therefore, future studies using R26hAR LoxP/+ :Upk3a GCE/+ mice combined with other relevant mouse models may explore the collaborative effects between androgen signaling and other signaling pathways in bladder tumor initiation and progression.