CIIT Centers for Health Research, Research Triangle Park, North Carolina 27709
1 To whom correspondence should be addressed at WIL Research Laboratories, 1407 George Road, Ashland, OH 44805. Fax: (419) 289-3650. E-mail: cbowman{at}wilresearch.com.
Received March 3, 2005; accepted April 8, 2005
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ABSTRACT |
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Key Words: antiandrogen; male reproductive development; phthalate; di(n-butyl); Wolffian duct; epididymis; insulin-like growth factor.
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INTRODUCTION |
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Di(n-butyl) phthalate (DBP), one of many phthalate esters, is primarily used as a plasticizer and solvent and is widely distributed as an environmental contaminant (IPCS, 1997). Adverse effects on male reproductive development have been observed in animals exposed pre- and postnatally to DBP, in the absence of maternal toxicity (Mylchreest et al., 1998
; NTP, 1991
; Wine et al., 1997
). Male rats, exposed to DBP only during late gestation, exhibited similar adverse effects to those observed in previous studies of longer duration, including malformed epididymides, vasa deferentia, seminal vesicles, and prostates in addition to hypospadias, cryptorchidism, decreased anogenital distance, and increased nipple retention (Barlow and Foster, 2003
; Gray et al., 1999
; Mylchreest et al., 1999
, 2000
). Malformations of the epididymis are one of the most sensitive and consistent lesions in adult male rats associated with prenatal DBP exposure, with an overall pup incidence of 40 to 50% (82 to 89% litter incidence) at 500 mg/kg/day when administered daily from GD 12 to 21 (Mylchreest et al., 1999
, 2000
). DBP-exposed epididymides are characterized by decreased coiling of the epididymis and an increased amount of intervening fibrous connective tissue stroma. Neither DBP nor its monoester metabolite bind to the androgen receptor (AR) (Foster et al., 2001
); however, DBP exposure during gestation reduces fetal testicular testosterone levels (Mylchreest et al., 2002
; Shultz et al., 2001
). This decrease in fetal testicular testosterone following prenatal DBP exposure (500 mg/kg/day) is a result of decreased fetal testicular mRNA and protein expression of several proteins required for cholesterol transport and steroidogenesis (Thompson et al., 2004
). Lehmann et al. (2004)
has demonstrated through dose-response studies that fetal testosterone and testicular expression of several proteins required for cholesterol transport and steroidogenesis are decreased significantly following in utero DBP exposure as low as 50 mg/kg/day. This decrease in fetal testicular testosterone following DBP exposure is the likely primary mode of action responsible for altered WD differentiation that results in epididymal malformations observed in adult rats (Mylchreest et al., 2002
). GD 19 and 21 are sensitive time points for evaluation of WD development because ductal coiling has not yet started on GD 19, but by GD 21 the WD is highly coiled and differentiated in controls, but following exposure to 500 mg/kg/day of DBP, lack of coiling is observed by GD 21 (Barlow and Foster, 2003
). In utero exposure to the androgen receptor antagonist linuron induces a similar abnormal phenotype of the WD, but fetal testicular testosterone levels do not appear to be altered (McIntyre et al., 2002
). The decreased coiling of the WD induced by linuron has been examined at the molecular level, and some critical developmental pathways have been identified (Turner et al., 2003
) that may begin to explain the malformations of the epididymis in adult rats following prenatal exposure to this androgen receptor antagonist (McIntyre et al., 2002
).
The epididymal malformations induced by prenatal DBP exposure represent an experimental model to improve understanding of the mechanisms responsible for androgen-dependent development of the male reproductive tract. Knowledge of the mechanisms involved in the induction of epididymal malformations could ultimately be useful in determining the relative risk to human health from prenatal exposure to DBP. The objective of the present study was to identify gene expression changes associated with the abnormal differentiation of the upper WD in DBP-exposed rat fetuses. Pregnant rats were treated with DBP (500 mg/kg/day) from GD 12 to GD 19 or 21, since this has been shown in previous studies to maximize the incidence of epididymal abnormalities (Barlow and Foster, 2003). Microarrays and real-time reverse transcription polymerase chain reaction (RT-PCR) were utilized to identify candidate genes altered by DBP exposure during WD stabilization and differentiation. In addition, insulin-like growth factor 1 receptor (IGF1R) and AR protein were evaluated by immunohistochemistry to identify corresponding changes in the localization and/or intensity of protein expression on GD 19 in an effort to further characterize the effects of DBP on paracrine and androgen signaling during development in a cell-specific manner.
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MATERIAL AND METHODS |
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Treatment.
Sperm-positive rats from each treatment block were gavaged daily (08000900) from GD 12 to 19 or 21 with either corn oil vehicle (Sigma Chemical Company, St. Louis, MO) or di(n-butyl) phthalate (99.8%, Aldrich Chemical Company, Milwaukee, WI) in corn oil at 500 mg/kg/day at a volume of 1 ml/kg/day. Dams were examined daily for clinical signs of toxicity. Dam body weights were recorded daily during dosing.
Study design.
The study was performed using three separate blocks of animals. Dams from all blocks were euthanized by carbon dioxide asphyxiation and exsanguination followed by removal of the fetuses by cesarean section. The developing WD and fetal testes were removed from all male fetuses and examined using a dissecting microscope with transillumination, and the gross morphology of the tissues was recorded. Two blocks of animals were euthanized on GD 19. One block consisted of six dams dosed with corn oil and seven dams with 500 mg/kg/day DBP, and the second block consisted of four corn oil-exposed and four DBP-exposed dams. The tissues collected from the first block of animals were snap-frozen in liquid nitrogen immediately after dissection and used for molecular analyses. Tissues collected from the second block of animals were fixed in neutral-buffered formalin for 12 h and subsequently processed for immunohistochemistry. A third block of dams was euthanized on GD 21 and consisted of six dams dosed with corn oil and seven dams with 500 mg/kg/day DBP. The tissues collected from the third block of animals were immediately frozen in liquid nitrogen for subsequent molecular analyses.
cDNA microarrays.
Wolffian ducts were pooled from three to four fetuses within the same litter to obtain sufficient RNA for the molecular analyses (each pool was considered a sample). For GD 21 fetuses, only WD with similar ductal morphology was pooled. Total RNA was isolated from WD on GD 19 and 21 using STAT-60TM (Tel-Test, Inc., Friendswood, TX). Total RNA was DNase-treated with RNase-free DNase (Roche, Indianapolis, IN) at 37°C for 30 min in the presence of RNasin (Applied Biosystems, Foster City, CA). Reverse-transcription (RT) reactions were performed using 3.5 µg of total RNA, 32P-dATP, and Superscript-II MMLV reverse transcriptase (Gibco-BRL, Gaithersburg, MD) for 60 min at 50°C. Following purification with ProbeQuantTM G-50 MicroColumns (Amersham Biosciences, Piscataway, NJ), probes were added to each Clontech (Palo Alto, CA) Atlas Rat Toxicology 1.2 cDNA expression array (1,185 genes). Hybridization and washing were performed according to manufacturer's instructions. Arrays were placed on a phosphor screen for 12 days, and images collected using a PhosphorImagerTM SI (Molecular Dynamics, Amersham Biosciences Corp., Piscataway, NJ). These images were imported into AtlasImage software (Clontech) for data collection. Arrays were analyzed by AtlasImage 2.01 and GeneSpring 4.2 (Silicon Genetics, Redwood, CA). Array analysis was performed on four to seven pooled samples (representing at least three individual litters) per treatment group conducted with three or four arrays per treatment group per hybridization.
Real-time RT-PCR.
Real-time RT-PCR using the GeneAmp® 5700 Sequence Detection System (Applied Biosystems) was performed to analyze changes in gene expression. DNase-treated total RNA (1 µg) from each tissue pool (described previously) was aliquoted in quadruplicate for RT, with one aliquot receiving no enzyme. RT was performed using the TaqMan® RT reagents (Applied Biosystems) and manufacturer's instructions. The quality of the RT reactions was confirmed by PCR of each triplicate RT compared to the no-enzyme control for each RNA sample using glyceraldehyde-3-phosphate dehydrogenase (GAPDH) primers and manufacturer's protocols (Applied Biosystems) for PCR. For GAPDH RT samples, the PCRs were performed using SYBR® Green PCR Master Mix (Applied Biosystems) according to the manufacturer's instructions using a reaction volume of 25 µl. Sequences of the rat-specific primer sets used are listed in Table 1. The primer sets with asterisks have been described previously (Turner et al., 2003). New primer sets were designed by Primer Express 2.0 software (Applied Biosystems). For each primer set, the production of a single PCR product was confirmed using gel electrophoresis, and primer efficiency was determined according to the manufacturer's protocols (Applied Biosystems). Real-time RT-PCR analyses were performed in triplicate on four to ten pooled samples (representing three to seven individual litters) per treatment group. PCR reactions for specific mRNAs of interest were performed in parallel with reactions using GAPDH specific primers to allow for standardization across samples for cDNA input. Relative quantitation of gene expression for samples from DBP-exposed fetuses compared to controls was performed according to User Bulletin #2 (Applied Biosystems).
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Statistical analysis.
Statistical analyses were conducted using JMP (version 4.0.4, SAS Institute, Cary, NC), and p < 0.05 was considered statistically significant. For analyses of dam body weight, the number of fetuses was used as a covariant in the analysis of covariance (ANCOVA) used to test for significance of treatment effects. The Fisher's exact test was used to determine whether the incidence of decreased coiling of the WDs was significantly different between groups. Statistical analysis of the real-time RT-PCR data was performed on the relative gene expression data as described in User Bulletin #2 (Applied Biosystems). The data represented in the figures reflects relative gene expression in comparison to controls and does not represent mRNA abundance. Significant differences between control and treated were determined by performing a t-test.
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RESULTS |
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Effects of DBP on Wolffian Duct Morphology During Late Gestation
In general, WDs dissected from GD 19 DBP-exposed fetuses compared to control fetuses were slightly smaller in size (underdeveloped), the ducts themselves were more fragile, and the adipose tissue surrounding the duct had a gelatinous appearance. As shown in Figures 1A and 1B, the changes in WD morphology from DBP-exposed GD 19 fetuses were very subtle; as such no quantitation of these changes was performed. By GD 21, WDs from control fetuses were markedly coiled, whereas WD from fetuses exposed to DBP exhibited less coiling (Figs. 1C and 1D). The WD from DBP-exposed fetuses on GD 21 exhibited variably decreased coiling, from complete lack of coiling (Fig. 1D) to decreased coiling of only the caput or cauda regions (not shown). Since there was no detectable pattern as to which fetuses exhibited no coiling or regions of decreased coiling, all of these variations were classified as decreased coiling (Fig. 2). On GD 21, 89% of fetuses (100% of litters) showed decreased coiling following exposure to DBP (Fig. 2), whereas on GD 19 no coiling of the WD was observed in any fetus. The macroscopic pathology of the differentiating WD following DBP exposure in the present study is consistent with that described previously by Barlow and Foster (2003). Consistent with the lack of coiling in the WDs from DBP-exposed fetuses, the GD 21 WD sections showed an overall decrease in the number of ductal cross-sections (Fig. 1F) in comparison with the controls (Fig. 1E). Since macroscopic changes in WD morphology were observed on GD 21, it is possible that the proportion of ductal epithelial cells to the surrounding mesenchyme may be altered relative to controls. Thus, the increases in mRNA expression on GD 21 described below may reflect alterations in cell numbers. Unfortunately, the differentiating rat WD would be extremely difficult to evaluate using standard morphometry techniques due to its extremely small size and frailty. As such, quantification of cellular ratios was not attempted in the present study.
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Effect of DBP Exposure on mRNA Expression of Members of the Insulin-Like Growth Factor Gene Family and Epidermal Growth Factor Receptor
Daily exposure to DBP from GD 12 to 19 or 21 increased mRNA expression of different members of the insulin-like growth factor (IGF) family in the developing WD (Fig. 3). Real-time RT-PCR analysis indicated that mRNAs for IGF1, IGF2, IGF1 receptor (IGF1R), and IGF binding protein 5 (IGFBP5) were up-regulated following DBP exposure. Specifically, IGF1 mRNA expression was increased 1.82- and 2.37-fold (p < 0.05) with DBP on GD 19 and 21, respectively (Fig. 3). Both IGF2 and IGF1R mRNAs were significantly increased on GD 19 (1.95- and 1.93-fold, respectively) with DBP. There was a 1.6-fold increase (p < 0.05) in IGFBP5 mRNA on GD 21, but no change on GD 19. Epidermal growth factor receptor (EGFR) mRNA was unchanged on GD 19 and GD 21.
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DISCUSSION |
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Proposed Model of Altered Wolffian Duct Differentiation
Based on the results of these studies, we propose the following model for increased paracrine signaling in the developing WD (Fig. 9). This model suggests a coherent molecular response between the mesenchyme, extracellular matrix, and epithelia that is secondary to the decrease in fetal testicular testosterone and ultimately results in the altered phenotype following in utero DBP exposure. Specifically, prenatal DBP exposure (and the subsequent decrease in fetal testicular testosterone) during WD development appears to increase paracrine signaling of growth factors (e.g., IGFs) and other developmentally conserved pathways (e.g., BMP4) followed by increased proteinase activity (MMPs), which may induce altered morphogenesis of the extracellular matrix (e.g., collagen and fibronectin) ultimately resulting in the abnormal WD phenotype observed on GD 21. In addition to the above changes, AR protein appears to be decreased in the ductal epithelia on GD 19 (present study) and 21 (Mylchreest et al., 2002), coincident with decreased levels of fetal testicular testosterone. Both mRNA and protein data from the current study suggest that the IGF pathway is up-regulated in the WD with DBP exposure. We speculate this may be due to one of two reasons. The increased IGF signaling may be a compensatory response to decreased testosterone, or the IGF system may be a functional repressor normally leading to WD regression in females, but in normal males is repressed by testosterone; therefore decreased testosterone may result in an increase in IGF signaling in DBP-exposed fetuses in comparison to the controls. There is evidence suggesting that another growth factor (transforming growth factor betaTGFß) is a functional repressor (Roy et al., 1999
) that is normally down-regulated by androgens (Kyprianou and Isaacs, 1989
) but can inhibit androgen-induced growth and ductal morphogenesis (Cunha et al., 1992
). This growth factor was not evaluated in the current study.
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During normal fetal development in the male rat, AR is initially expressed in the mesenchymal cells surrounding the WD, with subsequent induction of expression within the epithelial cells by GD 18 (Bentvelsen et al., 1995; Cooke et al., 1991
; Majdic et al., 1995
; You and Sar, 1998
). DBP induces its antiandrogenic effects upstream of the AR, by decreasing testosterone biosynthesis (Mylchreest et al., 2002
; Shultz et al., 2001
; Thompson et al., 2004
). However, it was important to evaluate the expression and localization of the AR in WD from DBP-exposed fetuses, since circulating testosterone levels are lower than controls. There is some evidence that AR transcriptional activity may be enhanced by low levels of androgens (Orio et al., 2002
). In the present study, AR mRNA expression appeared to be slightly increased on GD 19, but was unchanged on GD 21 in the WD from DBP-exposed fetuses. However, interpretation of the GD 21 mRNA data is complicated by potential changes in the proportions of epithelial to mesenchymal cells. Consequently, overall GD 21 AR mRNA expression in the WD may not change if the number of mesenchymal cells increased in parallel with a decrease in the number of ductal epithelial cells. AR expression was further evaluated on GD 19 using immunohistochemistry. Epithelial cell AR protein expression was variably decreased on GD 19 (Fig. 8), but there was no apparent change in mesenchymal AR protein expression. The apparent disconcordance between increased AR mRNA and variably decreased epithelial AR protein on GD 19 may be explained by small sample size, variability, a posttranscriptional event precluding increased protein synthesis, or by increased protein turnover. The decrease in ductal epithelial AR protein expression is consistent with previous data demonstrating a decrease in ductal epithelial AR protein in WD from DBP-exposed fetuses on GD 21 (Mylchreest et al., 2002
). A decrease in AR protein in the epithelia of the developing WD has also been shown with the AR-antagonists linuron (Turner et al., 2003
) and flutamide (Bentvelsen et al., 1995
; Mylchreest et al., 2002
).
The bone morphogenetic protein (BMP) and fibroblast growth factor (FGF) families, together with their receptors, are highly conserved signaling pathways of great importance in development (Gerhart, 1999; Hogan, 1999
, Jung et al., 1998
). In the present study, BMP4 mRNA expression was increased in the WD from GD 19 DBP-exposed fetuses and is consistent with reports that BMP4 is considered a negative growth factor, inhibiting epithelial cell proliferation (Hogan, 1999
; Lamm et al., 2001
). In contrast, decreases in BMPs and BMP-receptors were observed in developing WDs on GD 21 and epididymides on PND 7 from linuron-exposed fetuses (Turner et al., 2003
). In DBP-exposed fetuses, FGF10 mRNA expression was unaltered in WDs on GD 19, but increased on GD 21. BMP4 and FGF10 are expressed in the mesenchyme of developing organs and together regulate branching morphogenesis (Thomson and Cunha, 1999
; Weaver et al., 2000
). BMP4 is though to act as a negative growth factor, by inhibiting epithelial cell proliferation and bud formation (Hogan, 1999
; Lamm et al., 2001
), whereas FGF10 promotes budding (Weaver et al., 2000
). In addition BMP4 is expressed in the mesenchyme surrounding the developing WD and appears to play a role in the development of the mouse external genitalia (Miyazaki et al., 2000
). It is difficult to know if the alterations in BMP4 and FGF10 expression represent changes in their respective signaling pathways, because it was not possible to quantify all the relevant receptors. However, the fact that BMP4 and FGF10 are growth factors that are known to act in a paracrine fashion between the mesenchyme and epithelia in many developing organs suggests that they could be involved in regulating epithelial cell proliferation in WDs and thus ductal coiling.
Both Notch2 and Dlk are members of highly conserved developmental signaling pathways that regulate cell-to-cell communication during tissue morphogenesis (Artavanis-Tsakonas et al., 1999; Gerhart, 1999
). Therefore it is not surprising that these signaling pathways may be disrupted in developing WD from DBP-exposed fetuses. Down regulation of Dlk has been associated with cellular differentiation (Laborda, 2000
). Thus, the increased Dlk mRNA expression observed in the current study following DBP exposure might suggest a lack of cell maturation (mesenchyme-epithelia transition or epithelial proliferation). This is consistent with an increase in Dlk mRNA expression observed in GD 21 WDs from linuron-exposed fetuses that exhibited decreased ductal coiling (Turner et al., 2003
).
MMPs are a family of extracellular proteinases that regulate many developmental processes, including branching morphogenesis, extracellular matrix degradation, growth factor release, and cleavage of cell adhesion molecules (Seiki, 2002; Vu and Werb, 2000
). The family of MMPs also has their own family of inhibitors, the TIMPs. The overall balance of active MMPs and TIMPs (thought to be primarily regulated at the level of transcription) dictates specific proteinase activity and function (Basbaum and Werb, 1996
; Talhouk et al., 1992
; Werb, 1997
). MMP2 specifically is considered one of the first target genes downstream of paracrine signaling during normal Mullerian ductal epithelial regression in the male rat (Roberts et al., 2002
). In the developing WD, we propose that paracrine signals may be altered to induce MMP activity, thus preventing WD differentiation as a consequence of prenatal DBP exposure (Fig. 9).
In general, the ECM environment consists of soluble factors (growth factors and MMPs) interacting with matrix components (collagen and fibronectin) and the cell surface receptors (integrins, growth factor receptors, and MMPs) to regulate tissue morphogenesis and differentiation during development (Adams and Watt, 1993; Basbaum and Werb, 1996
; Jones et al., 1993
; Luke and Coffey, 1994
; Sakurai, 2003
; Slater, 1996
; Sternlicht and Werb, 2001
; Streuli, 1999
; Werb, 1997
; Werb et al., 1996
). For example, MMP proteolysis of IGFBPs results in increased IGF activity, and IGFBPs bound to the ECM serve as a reservoir of IGF1 and 2 (Fowlkes et al., 1999
). IGF1 and IGF1R can regulate MMP2 and MMP14 synthesis (Zhang and Brodt, 2003
). Interestingly, fibronectin increases MMP activity and epithelial cell loss in hormone withdrawal-induced mammary gland involution (Schedin et al., 2000
). Signals from both integrins and growth factor receptors are thought to be necessary for the G1 to S-phase transition and cell proliferation (Danen and Yamada, 2001
). Synergy between these receptors results from binding of ECM ligands and growth factors that act on different components of the same signaling pathways involved with normal morphogenesis (Miyamoto et al., 1998
; Werb, 1997
). In addition, recent data demonstrates that MGP (a calcification inhibitor in bone) may also regulate BMPs (Zebboudj et al., 2002
).
In summary, prenatal DBP exposure (and subsequent decrease in fetal testicular testosterone) appears to alter the mesenchyme-epithelial signaling of growth factors (e.g., IGFs) and other developmentally conserved pathways (e.g., BMP4), followed by changes in the macroscopic and microscopic morphology on GD 21 (Fig. 9). Although the mRNA and immunohistochemical data support this hypothesis, further study is necessary to validate this proposed model. Based on the current DBP study and the linuron-induced changes in the WD (Turner et al., 2003) there are distinct differences in the molecular and hormonal mechanisms responsible for the similar epididymal malformation observed in adult animals following in utero exposure to antiandrogens. We believe this effect on WD differentiation by DBP is likely a consequence of decreased fetal testicular testosterone, but direct effects of DBP on the developing WD independent of testosterone are possible. This study identifies candidate genes involved with paracrine signaling during rat WD differentiation not previously reported. In addition, a model has been proposed for the DBP-induced changes observed in the developing WD. The present study builds on previous work within our laboratory to understand the various modes of action underlying the sensitivity of male reproductive tract development to environmental antiandrogens. Future studies should further evaluate the IGF pathway and its relationship to testosterone-regulated development of the reproductive tract.
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NOTES |
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3 Present address: Sanofi-Aventis, Bridgewater, NJ 08807.
4 Present address: National Institute of Environmental Health Sciences, Research Triangle Park, NC 27709.
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ACKNOWLEDGMENTS |
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