Demasculinization and feminization of male gonads by atrazine: consistent effects across vertebrate classes.

Atrazine is the most commonly detected pesticide contaminant of ground water, surface water, and precipitation. Atrazine is also an endocrine disruptor that, among other effects, alters male reproductive tissues when animals are exposed during development. Here, we apply the nine so-called "Hill criteria" (Strength, Consistency, Specificity, Temporality, Biological Gradient, Plausibility, Coherence, Experiment, and Analogy) for establishing cause-effect relationships to examine the evidence for atrazine as an endocrine disruptor that demasculinizes and feminizes the gonads of male vertebrates. We present experimental evidence that the effects of atrazine on male development are consistent across all vertebrate classes examined and we present a state of the art summary of the mechanisms by which atrazine acts as an endocrine disruptor to produce these effects. Atrazine demasculinizes male gonads producing testicular lesions associated with reduced germ cell numbers in teleost fish, amphibians, reptiles, and mammals, and induces partial and/or complete feminization in fish, amphibians, and reptiles. These effects are strong (statistically significant), consistent across vertebrate classes, and specific. Reductions in androgen levels and the induction of estrogen synthesis - demonstrated in fish, amphibians, reptiles, and mammals - represent plausible and coherent mechanisms that explain these effects. Biological gradients are observed in several of the cited studies, although threshold doses and patterns vary among species. Given that the effects on the male gonads described in all of these experimental studies occurred only after atrazine exposure, temporality is also met here. Thus the case for atrazine as an endocrine disruptor that demasculinizes and feminizes male vertebrates meets all nine of the "Hill criteria".

Estradiol upregulates activating transcription factor 3, a candidate gene in the etiology of hypospadias.

Hypospadias is a penile developmental abnormality that may partly result from in utero exposure to estrogenic compounds. Expression of activating transcription factor 3 (ATF3) is elevated in human foreskin tissue from hypospadic patients, and in utero exposure to ethinyl estradiol (17-EE) causes ATF3 upregulation in a hypospadias mouse model. We investigated the effects of in vitro exposure to EE on ATF3 expression and promoter activity in human foreskin fibroblasts using immunocytochemistry, quantitative polymerase chain reaction (PCR), western blot, and the luciferase activity assay. Immunocytochemistry showed peak positive staining at 2 hours after 0.5 to 3 hours of EE treatment (0.1 microM). Western blot showed significantly increased ATF3 protein expression (P = 0.006) after EE exposure. ATF3 mRNA, as evaluated using reverse transcriptase PCR and TaqMan real-time PCR, also increased (P = 0.146). In addition, the luciferase activity assay showed that ATF3 promoter activity was significantly enhanced after 1 hour of EE exposure (P < 0.0001). Thus, EE upregulates ATF3 expression in fibroblasts in vitro, consistent with our previous results with human tissue and in vivo mouse models. ATF3 is involved in the TGF-beta epithelial-mesenchymal signaling pathway, and its involvement in hypospadias suggests that ATF3 plays a role in development of this anomaly as a result of exposure to estrogenic compounds. Its potential involvement in other manifestations of developmental endocrine disruption is worth investigating.

Endocrine disruptors and hypospadias: role of genistein and the fungicide vinclozolin.

OBJECTIVES: The phytoestrogen (plant estrogen) genistein, present in soy products, is of interest because in utero exposure to genistein can cause hypospadias in our mouse model and maternal consumption of soy is prevalent in human populations. Another compound of interest is the fungicide vinclozolin, which also causes hypospadias in the mouse and rat and can occur concurrently with genistein in the diet as a residue on exposed foods. A study in the United Kingdom found no relationship between a maternal organic vegetarian diet and hypospadias frequency, but women who consumed nonorganic vegetarian diets had a greater percentage of sons with hypospadias. Because nonorganic diets can include residues of pesticides such as vinclozolin, we sought to assess the interaction of realistic daily exposures to genistein and vinclozolin and their effects on the incidence of hypospadias. METHODS: Pregnant mice were fed a soy-free diet and orally gavaged from gestational days 13 to 17 with 0.17 mg/kg/day of genistein, 10 mg/kg/day of vinclozolin, or genistein and vinclozolin together at the same doses, all in 100 microL of corn oil. The controls received the corn oil vehicle. The male fetuses were examined at gestational day 19 for hypospadias, both macroscopically and histologically. RESULTS: We identified no hypospadias in the corn oil group. The incidence of hypospadias was 25% with genistein alone, 42% with vinclozolin alone, and 41% with genistein and vinclozolin together. CONCLUSIONS: These findings support the idea that exposure to these compounds during gestation could contribute to the development of hypospadias.

In utero exposure to benzophenone-2 causes hypospadias through an estrogen receptor dependent mechanism.

PURPOSE: Additives such as benzophenone-2 are commonly used in cosmetic products and food container plastics to filter out ultraviolet light. In pregnant women exposure may result in transplacental transfer of benzophenone-2 to fetuses. Benzophenone-2 is estrogenic in vitro and in the rat uterotropic assay. Estradiol causes hypospadias in mice and estrogen-like compounds are also postulated to cause hypospadias. We determined whether hypospadias would develop in male mice exposed to benzophenone-2 in utero and whether this outcome depended on estrogen receptor pathways. MATERIALS AND METHODS: Timed pregnant C57BL/6 mice were administered benzophenone-2 (6.25 mg) or control vehicle by oral gavage from gestational days 12 through 17 and they were sacrificed on day 18. Fetuses were weighed and sexed, anogenital distance was measured and genital tubercles were harvested for paraffin sections or quantitative reverse transcriptase-polymerase chain reaction analysis of genes purportedly involved in genital tubercle development. RESULTS: Eight of 57 benzophenone-2 treated male fetuses (14%) whose genital tubercles were examined histologically had hypospadias (p = 0.0064). Co-administration of benzophenone-2 with the estrogen receptor antagonist EM-800 resulted in normal genital tubercles, ie no hypospadias, in 26 of 26 mice. Likewise no EM-800 or control treated male genital tubercles showed hypospadias. Benzophenone-2 treated male mice had no changes in body mass adjusted anogenital distance relative to controls. Reverse transcriptase-polymerase chain reaction revealed that genital tubercles of benzophenone-2 treated male mice expressed higher levels of estrogen receptor-beta relative to male controls (p = 0.04). CONCLUSIONS: These findings suggest that benzophenone-2 may cause hypospadias via signaling through the estrogen receptor. Further study of human benzophenone-2 exposure and its effects is needed to support this hypothesis.

Estrogen receptor-alpha and beta are differentially distributed, expressed and activated in the fetal genital tubercle.

PURPOSE: We examined the ontogenic and sex specific expression of estrogen receptor-alpha and beta in mouse genital tubercles and assessed the effects of in utero estrogen exposure on these parameters. MATERIALS AND METHODS: Expression of the 2 genes was detected in mouse genital tubercles from fetuses collected on gestational days 12, 14, 16 and 18, and from newborns using immunohistochemistry and quantitative polymerase chain reaction. Pregnant dams were exposed to ethinyl estradiol or corn oil as the control. RESULTS: Estrogen receptor-alpha and beta proteins first appeared on gestational days 12 and 14, respectively. The 2 proteins were expressed in the urethral plate and mesenchyma. Staining intensity was more prominent in the mesenchyma for estrogen receptor-alpha and in the urethral plate for estrogen receptor-beta. Female genital tubercles expressed more estrogen receptor-alpha than male genital tubercles (p <0.01), while estrogen receptor-alpha expression increased gradually in the 2 sexes until birth. Estrogen receptor-beta expression did not differ between males and females, and it showed no notable variation during fetal life. Ethinyl estradiol led to a 2.1 and 3.8-fold increase in estrogen receptor-alpha expression in females and in males with hypospadias (p = 0.002 and 0.04, respectively). Estrogen receptor-beta expression did not change in response to ethinyl estradiol. CONCLUSIONS: This study provides in vivo evidence that estrogen receptor-alpha expression in the genital tubercles of each sex increases until parturition but estrogen receptor-beta expression does not, implying genital tubercle sensitivity to estrogen increases during fetal life. Exogenous administration of estrogens results in a response of increased expression of estrogen receptor-alpha but not of estrogen receptor-beta. These differential findings for estrogen receptor-alpha and beta imply that the 2 receptors may have different roles in normal or anomalous genital tubercle development.

Urothelial sonic hedgehog signaling plays an important role in bladder smooth muscle formation.

During bladder development, primitive mesenchyme differentiates into smooth muscle (SM) under the influence of urothelium. The gene(s) responsible for this process have not been elucidated. We propose that the Sonic hedgehog (Shh) signaling pathway is critical in bladder SM formation. Herein, we examine the role of the Shh-signaling pathway during SM differentiation in the embryonic mouse bladder. Genes in the Shh pathway and SM expression in mouse embryonic (E) bladders (E12.5, 13.5, and 14.5) were examined by immunohistochemistry (IHC), in situ hybridization, and reverse transcription polymerase chain reaction (RT-PCR). To examine the effects of disrupting Shh signaling, bladder tissues were isolated at E12.5 and E14.5, that is, before and after bladder SM induction. The embryonic bladders were cultured on membranes floating on medium with and without 10 muM of cyclopamine, an Shh inhibitor. After 3 days, SM expression was examined by assessing the following: SM alpha-actin (SMAA), SM gamma-actin (SMGA), SM-myosin heavy chain (SM-MHC), Patched, GLI1, bone morphogenic protein 4 (BMP4), and proliferating cell nuclear antigen (PCNA) by IHC and RT-PCR. SM-related genes and proteins were not expressed in E12.5 mouse embryonic bladder before SM differentiation, but were expressed by E13.5 when SM differentiation was initiated. Shh was expressed in the urothelium in E12.5 bladders. Shh-related gene expression at E12.5 was significantly higher than at E14.5. In cyclopamine-exposed cultures of E12.5 tissue, SMAA, SMGA, GLI1, and BMP4 gene expression was significantly decreased compared with controls, but PCNA gene expression did not change. In cyclopamine-exposed E14.5 cultures, SMGA and SM-MHC gene expression did not change compared with controls. Using an in vitro embryonic bladder culture model, we were able to define the kinetics of SM- and Shh-related gene expression. Cyclopamine inhibited detrusor SM actin induction, but did not inhibit SM-MHC induction. SMAA and SMGA genes appear to be induced by Shh-signaling pathways, but the SM-MHC gene is not. Based on Shh expression by urothelium and the effects of Shh inhibition on bladder SM induction, we hypothesize that urothelial-derived Shh orchestrates induction of SM in the fetal mouse bladder.

Candidate genes and their response to environmental agents in the etiology of hypospadias.

The molecular events that lead to isolated hypospadias remain largely unknown, and the etiology of this common congenital anomaly seems to be multifactorial. We have explored the response of several candidate genes to environmental agents that cause hypospadias in a mouse model. Here, we provide an overview of current findings in relation to candidate genes and their response to environmental agents, including the results of genomic analyses of both mouse and human tissues. In addition to steroid-hormone receptors, one gene of specific interest is activating transcription factor 3 (ATF3). We hypothesize a potential mechanism of action for ATF3 and other identified genes, including TGF-B.

Up-regulation of estrogen responsive genes in hypospadias: microarray analysis.

PURPOSE: An unexplained increase in the incidence of hypospadias has been reported, and yet to our knowledge the molecular events and their regulation leading to hypospadias remain unknown, although environmental compounds capable of endocrine activity are suspected. We screened on a global scale abnormalities in gene expression in human hypospadiac tissue compared to those in nonhypospadiac tissue. Additionally, microarray analysis of tissue from a pair of fraternal twins, including 1 with and 1 without hypospadias, served as a control for genetic variability. We hypothesized that gene expression would differ between hypospadiac vs nonhypospadiac tissue and fraternal twin data would show patterns similar to those of group data on hypospadiac and nonhypospadiac tissue. MATERIALS AND METHODS: Microarray analysis was performed on tissue from patients with and without hypospadias, and from a pair of fraternal twins, including 1 with and 1 without hypospadias. Analysis incorporated the expression of 22,000 genes. RESULTS: We found significant differences in gene expression, specifically with a group of genes, including CYR61, CTGF, ATF3 and GADD45beta, known to be responsive to estrogen or to interact with estrogen receptor. CONCLUSIONS: Our findings provide support for the hypothesis that endocrine active environmental compounds may contribute to the development of hypospadias. Additionally, regulation of these genes may have a role in formation of the urethra.

Embryonic exposure to low-dose 17beta-estradiol decreases fetal mass sex specifically in male mice and does not cause hypospadias.

BACKGROUND: Endocrine-disrupting compounds are synthetic and natural compounds in the environment that can alter endocrine-governed developmental processes. Among these are the natural estrogens genistein, a plant isoflavone, and 17beta-estradiol (E2), which is present in dietary animal products, such as eggs and meat. In addition, natural and synthetic steroids are administered to beef cattle to promote growth, and low levels of the estrogens can persist in the beef. Most previous work using E2 has involved injection; however, oral administration results in a different suite of hormone products following first-pass metabolism in the liver. METHODS: Low doses of E2 were administered orally to pregnant dams to determine embryonic effects. As end points of effects, we examined whether embryonic exposure produced hypospadias, an endocrine-linked abnormality of the male genitalia, and we assessed fetal mass. RESULTS: Male fetuses from the two highest dosage groups were significantly smaller than their control male counterparts, and males from the highest dosage group were also significantly smaller than control females. Control males were significantly larger than all females, and there was no difference in mass among control and treated females. Additionally, the E2 dose was inversely correlated with mass overall. No effect of these doses of E2 on hypospadias was seen. CONCLUSIONS: These results indicate a sex-specific fetal effect of low-dose, orally administered E2, which appears to exert androgen-inhibiting effects on mass in males.

Ontogeny of androgen receptor and disruption of its mRNA expression by exogenous estrogens during morphogenesis of the genital tubercle.

PURPOSE: The ontogeny of androgen receptor expression in male and female mouse genital tubercles, and the effects of in utero ethinyl estradiol exposure on androgen receptor mRNA expression in the hypospadias model were studied. MATERIALS AND METHODS: Androgen receptor mRNA expression was measured in mouse genital tubercles from fetuses and pups collected on gestational days 12, 14, 16 and 18, and from newborns using immunohistochemistry and real-time quantitative polymerase chain reaction. Pregnant dams were exposed to ethinyl estradiol or corn oil as controls from gestational days 12 to 17. Genital tubercles of gestational day 19 fetuses were then examined by further quantitative polymerase chain reaction analysis after identification of the seam area using a dissecting microscope to diagnose hypospadias in males. RESULTS: Androgen receptor protein was detected in genital tubercles by gestational day 14. Androgen receptor mRNA expression increased gradually in each sex during normal development. However, female genital tubercles expressed a higher level of androgen receptor mRNA throughout development compared to male genital tubercles (p <0.0001). In utero ethinyl estradiol exposure led to a 5.4 and 4.5-fold increase in androgen receptor mRNA in the genital tubercles of female and male embryos (p = 0.004 and 0.001, respectively). Hypospadiac male genital tubercles showed increased androgen receptor mRNA expression compared to control males (p = 0.006). Levels in hypospadiac males did not differ from those in control females but they were less than those in ethinyl estradiol treated females (p >0.05 and 0.01, respectively). CONCLUSIONS: Androgen receptor protein is expressed abundantly in male and female genital tubercles. Androgen receptor mRNA levels are higher in female than in male genital tubercles through development and they increase in response to in utero ethinyl estradiol exposure with ethinyl estradiol treated females having the highest levels of expression, followed by ethinyl estradiol treated hypospadiac males. We infer that higher estrogen in genital tubercles results in a physiological response of increased androgen receptor mRNA expression. We found no direct association between changes in androgen receptor mRNA expression and the presence or absence of hypospadias in males, suggesting that alterations in the expression of proteins other than or in addition to androgen receptor result in anomalous urethral development. This finding supports the idea that the etiology of hypospadias is multifactorial in origin.

Gene expression profiles in mouse urethral development.

OBJECTIVE: To analyse the gene expression profiles of the mouse genital tubercle (GT) during urethral tube development at embryonic (E) days E14, E15, E16 and E17, as the aetiology of hypospadias, one of the most common congenital anomalies, remains unknown. MATERIALS AND METHODS: During GT development the urethral folds fuse to form an epithelial seam; subsequently, the epithelial seam disappears, resulting in the normal tubular urethra. Abnormalities in urethral seam formation and remodelling might explain hypospadias, and elucidating the molecular developmental mechanisms underlying normal penile development might provide the basis for understanding hypospadias. Total RNA was isolated from the genital tubercle at embryonic days E14, E15, E16, and E17. Together with reference RNA, sample RNA was labelled with Cy-3 and Cy-5 respectively and hybridized to a 16 000-mouse gene array that included the Incyte GEM2.1 and NIA 7k sets. Candidate genes were analysed by immunohistochemistry and real-time polymerase chain reaction. RESULTS: Using cDNA microarrays, we identified the up-regulation of genes involved in the transforming growth factor (TGF)-beta and Wnt-Frizzled pathways, and of thrombospondin (TSP) 4, a member of a cell-migration molecule family, all candidates for involvement in urethral tube formation. Immunohistochemistry showed TGFbeta1, TGFbeta receptor III, and Frizzled1 were expressed exclusively in E14-E17 urethral epithelium. TSP4 was expressed in the mesenchymal basal layer underlying E17 GT skin epidermis. CONCLUSIONS: Many signalling pathways are involved in late GT development, and cell migration molecules might have an important role in urethral tube formation.

Steroid receptors and mammalian penile development: an unexpected role for progesterone receptor?

PURPOSE: We investigated the role of steroid receptors in normal and abnormal genital tubercle development in males and females. We hypothesized that progesterone receptor expression might be involved in abnormal development in both sexes. MATERIALS AND METHODS: We examined the effects of medroxyprogesterone acetate on steroid receptor mRNA expression and assessed the involvement of androgen receptor in the action of medroxyprogesterone acetate on genital tubercle development using androgen receptor deficient (Tfm) mice. RESULTS: Quantitative reverse transcriptase polymerase chain reaction and morphological results demonstrated a pattern of virilized females and feminized males in medroxyprogesterone acetate exposed embryos. Progesterone receptor was the only steroid receptor examined that did not differ between medroxyprogesterone acetate treated males and vehicle treated females. At the morphological level in utero exposure to medroxyprogesterone acetate from gestational days 12 to 17 feminized male genital tubercles, producing a more proximal urethral opening. Female fetuses exposed for the same period exhibited virilized genitalia, with a more distal urethral opening. We also exposed Tfm mice to medroxyprogesterone acetate to assess the role of androgen receptor in the activity of medroxyprogesterone acetate. These medroxyprogesterone acetate exposed mice did not differ morphologically from vehicle treated Tfm mice, indicating that medroxyprogesterone acetate requires androgen receptor to elicit genital tubercle abnormalities. CONCLUSIONS: The increase of progesterone receptor mRNA expression in males and the decrease in females as a result of exposure to medroxyprogesterone acetate, which also causes urethral abnormalities in both sexes, suggests a previously unidentified role for progesterone receptor, possibly interacting with androgen receptor, in anomalous genital tubercle development.

Activating transcription factor 3 is estrogen-responsive in utero and upregulated during sexual differentiation.

BACKGROUND/AIMS: Synthetic estrogens induce hypospadias, an anomaly of genital tubercle/urethral development. Activating transcription factor 3 (ATF3), which is estrogen-responsive in vitro, is upregulated in hypospadiac human tissue. We used a mouse model of steroid-dependent genital tubercle development to elucidate the ontogeny of ATF3 expression and the developmental response of ATF3 in vivo to estrogen exposure. METHODS: We used quantitative RT-PCR to assess ontogenic expression of ATF3 and its response to estrogen treatment in utero. Immunohistochemistry was used to localize the protein. RESULTS: Quantitative RT-PCR showed that ATF3 mRNA is upregulated in all estrogen-exposed fetal genital tubercles compared to controls (p = 0.024), including specifically in males exposed in utero (p = 0.049). Additionally, its expression increases significantly during the period of sexual differentiation in both sexes and significantly correlates with female development (p = 0.004), a phenomenon that appears to be attributable to higher levels at birth in females. The protein localizes in the nucleus, as expected. CONCLUSIONS: ATF3 is estrogen-responsive in vivo. The response of ATF3 to estrogenic stimulation in utero at an earlier stage may contribute to urethral abnormalities observed in estrogen-exposed male fetuses, although it is likely not the only gene involved, which supports the general understanding that hypospadias is subject to multifactorial influences. ATF3 may therefore be an appropriate gene for further investigations in an endocrine context.

Embryonic exposure to the fungicide vinclozolin causes virilization of females and alteration of progesterone receptor expression in vivo: an experimental study in mice.

BACKGROUND: Vinclozolin is a fungicide that has been reported to have anti-androgenic effects in rats. We have found that in utero exposure to natural or synthetic progesterones can induce hypospadias in mice, and that the synthetic progesterone medroxyprogesterone acetate (MPA) feminizes male and virilizes female genital tubercles. In the current work, we selected a relatively low dose of vinclozolin to examine its in utero effects on the development of the genital tubercle, both at the morphological and molecular levels. METHODS: We gave pregnant dams vinclozolin by oral gavage from gestational days 13 through 17. We assessed the fetal genital tubercles from exposed fetuses at E19 to determine location of the urethral opening. After determination of gonadal sex, either genital tubercles were harvested for mRNA quantitation, or urethras were injected with a plastic resin for casting. We analyzed quantified mRNA levels between treated and untreated animals for mRNA levels of estrogen receptors alpha and beta, progesterone receptor, and androgen receptor using nonparametric tests or ANOVA. To determine effects on urethral length (males have long urethras compared to females), we measured the lengths of the casts and performed ANOVA analysis on these data. RESULTS: Our morphological results indicated that vinclozolin has morphological effects similar to those of MPA, feminizing males (hypospadias) and masculinizing females (longer urethras). Because these results reflected our MPA results, we investigated the effects of in utero vinclozolin exposure on the mRNA expression levels of androgen, estrogen alpha and beta, and progesterone receptors. At the molecular level, vinclozolin down-regulated estrogen receptor alpha mRNA in females and up-regulated progesterone receptor mRNA. Vinclozolin-exposed males exhibited up-regulated estrogen receptor alpha and progesterone receptor mRNA, effects we have also seen with exposure to the synthetic estrogen, ethinyl estradiol. CONCLUSION: The results suggest that vinclozolin virilizes females and directly or indirectly affects progesterone receptor expression. It also affects estrogen receptor expression in a sex-based manner. We found no in vivo effect of vinclozolin on androgen receptor expression. We propose that vinclozolin, which has been designated an anti-androgen, may also exert its effects by involving additional steroid-signaling pathways.

The effects of coal tar based pavement sealer on amphibian development and metamorphosis.

Coal tar based pavement sealers are applied regularly to parking lots and contain significant levels of polycyclic aromatic hydrocarbons (PAHs). Recently a connection between elevated levels of PAHs in streams and storm water runoff from parking lots has been identified. We tested the hypothesis that coal tar based pavement sealers could alter the survival, growth, and development of amphibians using a model species, Xenopus laevis. Ten fertilized individuals were placed singly into containers containing one of four treatment groups: control, low, medium, and high (respective nominal concentrations 0, 3, 30, and 300 ppm TPAH). All of the individuals in the high exposure group died by the sixth day of exposure. By day 14 there were significant patterns of stunted growth (p<0.0001) and slower development (p=0.006) in the medium and high exposure groups relative to the control and low treatment groups. When the experiment ended on day 52 the control and low-dose individuals had achieved more advanced developmental stages than the medium group (p=0.0007). These data indicate that these commonly used coal tar based pavement sealers may potentially affect the amphibian taxa living in areas that receive storm water runoff.

Serum response factor, its cofactors, and epithelial-mesenchymal signaling in urinary bladder smooth muscle formation.

Little is known about the mechanism of bladder smooth muscle differentiation. We hypothesize that epithelial-mesenchymal signaling induces the expression of smooth muscle proteins in bladder mesenchyme resulting in smooth muscle differentiation. We confirmed that smooth muscle differentiation in the mouse urinary bladder occurs first at gestational day 14 (E14) based upon immunohistochemical localization of smooth muscle alpha-actin (SMAA). To investigate murine bladder smooth muscle differentiation and epithlelial-mesenchymal signaling in the developing bladder, we analyzed gene expression profiles of intact embryonic murine bladders and separated epithelial and mesenchymal components at embryonic days E13, E14, E15, E16, and postnatal day 1 (P1). Using cDNA microarray, we identified regulators of vascular smooth muscle differentiation in bladder mesenchyme, including serum response factor (SRF) and its cofactors, ELK1 and SRF accessory protein (SAP)1, as well as two SRF-associated pathways, angiotension receptor II and transforming growth factor- beta2. Immunohistochemistry showed diffuse expression of SRF in the bladder at E12 with localization of expression to the peripheral mesenchyme at E13 and E14. Our results suggest that bladder smooth muscle differentiation may share a similar gene expression program as occurs during vascular smooth muscle differentiation. The unique structure of the urinary bladder makes it an ideal model for studies of smooth muscle differentiation and epithelial-mesenchymal signaling.