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Journal of Andrology, Vol. 27, No. 4, July/August 2006
Copyright © American Society of Andrology

Reducing Estrogen Synthesis in Developing Boars Increases Testis Size and Total Sperm Production

ALAN J. CONLEY

From the ^* Department of Animal Science and the Department of Population Health & Reproduction, School of Veterinary Medicine, University of California, Davis, California.

Correspondence to: Dr Janet F. Roser, Department of Animal Science, University of California, One Shields Ave, Davis, CA 95616 (e-mail: jfroser{at}ucdavis.edu).

Received for publication November 23, 2005; accepted for publication March 3, 2006.

	Abstract

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The abundant production of testicular estrogens and the presence of both ESR1 and ESR2 within boar testes are consistent with a role for estrogen in testicular development and/or function in this species. This study was aimed at determining the role of endogenous estrogen in the regulation of testicular development and function, including the effects on testis weight, histology, sperm production (detergent-resistant spermatid numbers), Sertoli cell numbers, and Leydig cell volume in the boar. Twenty-eight littermate pairs of boars were assigned to groups as follows: 1 boar from each pair was assigned to the control group (vehicle) and the other was assigned to treatment and received 0.1 mg/kg body weight of an aromatase enzyme inhibitor (letrozole) orally each week beginning at 1 week of age until castration at 2, 3, 4, 5, 6, 7, or 8 months of age. Testes were weighed and testicular parenchyma was recovered for determination of histology and detergent-resistant spermatid numbers, and for determination of Sertoli cell number and Leydig cell volume by staining for GATA-4 and 17- hydroxylase/17-20 lyase respectively. Testes of aromatase-inhibited boars initially exhibited delayed lumen formation, lower testicular weight, fewer detergentresistant spermatids, and fewer Sertoli cells, but by 7 to 8 months, these boars had recovered and had larger testes, more detergentresistant spermatids per testis, and more Sertoli cells. Total Leydig cell volume increased in proportion to testis size. Reducing endogenous estrogen is consistent with a delay in testicular maturation/puberty that allows for a longer window for the proliferation of Sertoli cells and maturation of Leydig cells, resulting in larger testes and higher spermatid production.

     Key words: Aromatase inhibition, Sertoli cell, Leydig cell

Although estrogen is now generally accepted as an essential component for normal testicular development and function in several species, how it does so is not clear. Estrogen secreted by the testes can influence gonadotropic feedback. Alternatively, synthesis by Leydig cells can have local, more direct testicular effects. Moreover, species differ widely in their capacity for estrogen synthesis. Testicular estrogen synthesis in boars is much higher than in males of most other species (Velle, 1966; Claus and Hoffman, 1980). The presence of estrogen receptors on germ cells, Leydig cells, and Sertoli cells at different stages of development (Rago et al, 2004; Mutembei et al, 2005) in the boar is consistent with a paracrine/autocrine role of estrogen in testicular development in this species. Estrogen synthesis is catalyzed by the enzyme aromatase, which is expressed in Leydig cells of this as of most species (Conley and Hinshelwood, 2001; Weng et al, 2005). Importantly, previous studies in our laboratory indicate that inhibiting estrogen synthesis by using an aromatase inhibitor does not alter gonadotropin secretion in boars (At-Taras et al, 2006), providing an unusual opportunity to investigate local effects of estrogen on testicular function. Therefore, the objective of this study was to investigate the effects of inhibiting endogenous estrogen synthesis on testicular development, including testis weight, histology, sperm production (detergent-resistant spermatid number), Sertoli cell number, and Leydig cell volume in the boar.

	Materials and Methods

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Animals

Twenty-eight littermate pairs of boars (n = 56 total) were treated orally with either vehicle (corn oil) or with a nonsteroidal aromatase inhibitor (0.1 mg/kg body weight [BW] letrozole [4-4'-(1H-1,2,3-triazol-1-yl-methylene)-bis-benzonitrile], CGS 20267; Ciba-Geigy, Basel, Switzerland) once a week starting at 1 week of age until castration at 2, 3, 4, 5, 6, 7, or 8 months of age. The dose of letrozole administered (0.1 mg/kg [BW]) was selected following experiments that were consistent with this dose as the lowest dose that effectively reduced estradiol concentrations. This study was conducted in accordance with the Guide for the Care and Use of Agricultural Animals in Agricultural Research and Teaching and approved by the Animal Use and Care Advisory Committee at the University of California at Davis. Boars are from established lines developed from Durocs, Hampshires, Yorkshires, and Pietrains provided by PIC USA (a division of Sygen International, Franklin, Ky). They were housed at the UC Davis Swine Facility. Four littermate pairs (1 treated and 1 control from each pair) were castrated at each age. BW was not affected by treatment. Testes from each animal were weighed and pieces of testicular parenchyma were removed avoiding mediastinum and tunica albuginea. One piece of testicular parenchyma was collected from boars castrated at 5–8 months of age and processed for determination of detergent-resistant spermatids. Another piece was weighed and its volume recorded before it was fixed in 4% paraformaldehyde for histology and determination of Sertoli cell numbers and Leydig cell volume.

Determination of Detergent-Resistant Spermatids

One gram of testicular parenchyma from each boar was macerated in 10 mL of sterile, aqueous 0.9% NaCl/0.05% Triton X-100 at room temperature for 3 minutes using a Wheaton Potter-Elvehjem tissue grinder with PTFE pestle (Fisher Scientific, Pittsburgh, Pa) as previously described (Amann and Almquist, 1961; Amann and Lambiase, 1969). The homogenate was poured into a 50-mL sterile tube and the glass tube was rinsed with 10 mL of 0.9% NaCl/0.05% Triton X-100 (total volume of 20 mL). Homogenates were stored at 4°C and the number of detergent-resistant spermatids per gram of testis tissue, a measure of sperm production, was determined the next day using a hemacytometer (3 counts within 10% for each sample). Preliminary experiments had evaluated 1, 2, 3, and 4 minutes of homogenization; 3 minutes gave equivalent values to 4 minutes but higher values than 1 or 2 minutes, presumably because shorter intervals did not completely free spermatids from tissue.

Histology

     Tissue Fixation and Preparation— Tissue was placed in 4% paraformaldehyde for 24 hours at 4°C and then transferred to 0.1 M phosphate-buffered saline (PBS) at 4°C for 24 hours. Tissue was then dehydrated in a step-wise fashion through ethanol (30%, 50%, and 70%, respectively, each for 24 hours at 4°C). After 24 hours or more in 70% ethanol, tissue was processed (dehydration in ethanol and infiltration through xylene and paraffin) in a VIP machine (Tissue Tek VIP; Miles Scientific, Naperville, Ill). Tissue was embedded in paraffin using a tissue embedding consol system (Sakura Finetek USA, Inc, Torrance, Calif) and sectioned at 5 µm for hematoxylin and eosin staining, at 5 µm for 17- hydroxylase/17–20 lyase cytochrome P450 (P450c17) immunostaining, and at 25 µm for identifying and enumerating Sertoli cells by immunocytochemical staining of GATA-4 within Sertoli cell nuclei.

Immunocytochemistry

     GATA-4— Immunolocalization of the transcription factor GATA-4 was performed as previously described (McCoard et al, 2001) using the Vectastain Elite ABC kit (Vector Laboratories, Burlingame, Calif) with slight modifications. Thick sections (25 µm) were deparaffinized, rehydrated, and incubated in a sodium citrate buffer (antigen unmasking solution, H-3300; Vector Laboratories) for 15 minutes, followed by blocking of endogenous peroxidase activity in 3% hydrogen peroxide in methanol for 10 minutes. Sections were washed 3 times (5 minutes each time) in 50 mM Tris buffer with 1.5% NaCl pH 7.6 (TB) prior to blocking with 1% normal rabbit serum (Vector Laboratories) for 20 minutes at room temperature (RT). Sections were incubated in primary antibody (polyclonal goat anti-mouse, GATA-4 sc-1237, 1:200 dilution in TB; Santa Cruz Biotechnologies, Santa Cruz, Calif) at RT for 2 hours, washed in TB 3 times, and incubated with biotinylated rabbit anti-goat secondary antibody. Sections were washed again 3 times in TB prior to incubation with an avidin-biotin-peroxidase complex (ABC; Vector Laboratories) at RT for an additional 40 minutes. NovaRed (Vector Laboratories) was used to visualize immunoreactivity prior to washing in tap water, dehydrating in CitriSolv (Fisher Health Care, Houston, Tex), and sealing with Coversafe mounting media (American MasterTech Scientific, Inc, Lodi, Calif).

     P450c17— Immunolocalization of P450c17 to identify Leydig cells was performed as previously described (Conley et al, 1995) with slight modifications. Briefly, sections were deparaffinized and rehydrated before quenching endogenous peroxidase activity with 0.3% hydrogen peroxide in methanol. Sections were washed and then incubated in heated (approximately 200°F for 10 minutes) sodium citrate buffer (antigen unmasking solution), cooled and washed again in PBS (50 mM phosphate, 150 mM NaCl, pH 7.6). Sections were incubated in blocking serum for 20 minutes, then in a rabbit polyclonal antibody raised against P450c17 (1:1000, courtesy of Dr Anita Payne, Stanford University, Stanford, Calif) or normal rabbit serum (1:1000, control sections) overnight, after which they were washed for 5 minutes in PBS and incubated in biotinylated secondary antibody (goat anti-rabbit immunoglobulin G) for 30 minutes. Sections were washed again in PBS (5 minutes) before incubating in an ABC (Vector Laboratories) at RT for 30 minutes and washed again. 3-amino-9-ethylcarbazole (AEC; Vector Laboratories) was used as the peroxidase substrate to visualize antibody labeling.

Sertoli Cell Counting

An Olympus BH2 microscope with a computer-controlled stage (Olympus, Melville, NY), microcater (Heidenhain MT12), digital camera and stereology software (CAST; Copenhagen, Denmark) were used to visualize GATA-4 stained sections and count Sertoli cell nuclei. Adjustments were not made for shrinkage because this was determined to be consistent among tissue sections. Fields were chosen randomly by the software, and at least 200 cells were counted for each animal. Number density of Sertoli cells were calculated using the optical dissector method (Petersen and Pakkenberg, 2000). Average number of Sertoli cells per counting frame was divided by the area of the counting frame and the dissector height of the optical dissector (Howard and Reed, 1998). Final Sertoli cell number per testis was determined by multiplying the resulting number by testis weight because volume measurements of testicular tissue indicated a density of 1 g/cm³.

Determination of Leydig Cell Volume

Determination of Leydig cell volume was based on the percentage of area stained with P450c17 compared with total testicular area. Sections were projected onto a computer screen from an Olympus BH2 microscope using a QICAM monochrome camera (QIMAGING 3; Burnaby, Canada). NIH Scion Image software (version Beta 4.0.2; Scion Corporation, Frederick, Md) was used to make the necessary measurements. Six to 8 fields were measured for each animal at a final magnification of 300x. Percentage of the area stained with P450c17 was then multiplied by testis weight (it having been determined that 1 cm³ = 1 g tissue) to get final testicular Leydig cell volume.

Data Analysis

Testicular weight was analyzed using 2-way ANOVA (Proc GLM; SAS Statistical Software, SAS Institute Inc, Cary, NC) with treatment and age as the main effects. Significant treatment by age effects were noted using the LSMEANS procedure (SAS Statistical Software). Detergent-resistant spermatid number, Sertoli cell number, and Leydig cell volume were analyzed by 1-way ANOVA with treatment as the main effect, each age separately, to fulfill homogeneity of variance criteria. Data are presented as least square means ± pooled SEM.

View larger version (17K): [in this window] [in a new window]   Figure 1. Total testicular weight (g) in control and letrozole-treated boars at 2 through 8 months of age (least square means ± pooled SEM). Asterisks indicate differences between control and treated boars at each age. *P .05. **P .005.

	Results

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View larger version (149K): [in this window] [in a new window]   Figure 2. Hematoxylin and eosin stained testis sections from 4- and 5-month-old control and letrozole-treated boars. Lumen (L) development is delayed in testes from treated boars compared with testes from control boars. Scale bars = 50 µm.

View larger version (21K): [in this window] [in a new window]   Figure 3. (A) Spermatid production per gram of testis (106). (B) Spermatid production per testis (109) in boars ages 5 to 8 months. Values are means from 4 boars and error bars represent SEM. Asterisks indicate differences between control and treated boars at each age. *P .05. **P .01.

Letrozole treatment had additional effects on somatic cells in both tubular and interstitial compartments. The number of Sertoli cells ranged from an average of 2.86 x 10⁹ and 3.18 x 10⁹, respectively, for control and treated boars at 2 months to 2.33 x 10¹⁰ and 2.78 x 10¹⁰ for control and treated animals, respectively, at 8 months (P < .05). Sertoli cell numbers in aromatase-inhibited boars were increased an average of 137% over control numbers at all ages except 4 months, when Sertoli cells in aromatase-inhibited boars were only 78% of Sertoli cells in control littermates (P < .05; Figure 4). Leydig cell volume as a percentage of total testicular volume, although initially lower in treated boars at 2 months (P < .05), was not different between aromatase-inhibited and control animals at 5 or 8 months of age (Figure 5). Therefore, with the increase in testis size in aromatase-inhibited boars, there was a consequent 48% increase in total Leydig cell volume above control values at 8 months (115.6 ± 21.4 cm³ vs 60.6 ± 21.4 cm³ in treated and control boars, respectively; P < .05).

View larger version (19K): [in this window] [in a new window]   Figure 4. Sertoli cell numbers in testes of letrozole-treated boars ages 2–8 months as a percentage of Sertoli cell numbers in control littermates (%). Asterisks indicate significant differences in Sertoli cell number percentage. *P < .05. Four-month-old treated boars had fewer Sertoli cells relative to control littermates than 3- and 5-month-old treated animals.

View larger version (15K): [in this window] [in a new window]   Figure 5. Leydig cell volume as a percentage of total testicular volume in control and letrozole-treated boars at 2, 5, and 8 months of age. Asterisks indicate significant differences in Leydig cell volume relative to total testicular volume between control and treated boars within a particular age. *P < .05. Percentage volume occupied by Leydig cells was initially lower (2 months) but had recovered at 5 and 8 months.

	Discussion

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In addition to the development of viable and fertile sperm (Franca and Cardoso, 1998), testicular development and maturation is marked by the development and maturation of the somatic cells (Lunstra et al, 1986, 2003; Franca et al, 2000; McCoard et al, 2001). Leydig cells are the major cellular site of steroidogenic enzyme expression (Conley et al, 1996; Kaminski et al, 1997; Weng et al, 2005), producing both testosterone and estradiol (Raeside and Renaud, 1983; Setchell et al, 1983; Saez et al, 1989). Sertoli cells are the "nurse" cells for developing germ cells, providing factors essential for spermatogenesis (Sylvester and Griswold, 1994). They are the major determinants of testis size (Gondos and Berndtson, 1993; Lunstra et al, 2003), and both testis size and Sertoli cell number are correlated with total sperm production (Chubb, 1992; Okwun et al, 1996; Ford et al, 1997). Sertoli cell proliferation in the pig apparently takes place primarily during the late prenatal and early postnatal period (Putra and Blackshaw, 1985; Kosco et al, 1987; McCoard et al, 2001; Lunstra et al, 2003). Hemicastration studies have indicated that compensatory Sertoli cell proliferation in boars is possible only prior to the onset of puberty (Putra and Blackshaw, 1985; Kosco et al, 1989a). Data from the present study show that the increase in testis size was associated with increased Sertoli cell numbers in reduced estrogen boars above controls, an increase that was apparent as early as 2 months of age. The increment in Sertoli cell numbers with letrozole was sustained through all ages with the exception of the 4-month time point. Rather than representing a decrease in Sertoli cell numbers in the treated boars, the reversal of this trend at 4 months likely reflects a peri-pubertal increase in Sertoli cell numbers in control animals that preceded a delayed increase in Sertoli cell proliferation in treated animals by approximately 1 month. Because initiation of tubular lumen development also occurred later in aromatase-inhibited boars (5 months) compared with control littermates (4 months), there may similarly be a delay in testicular (Sertoli cell) maturation resulting in delayed initiation of puberty. Evidence from Piau pigs shows a biphasic pattern of Sertoli cell proliferation with the second phase occurring just prior to puberty (between 3 and 4 months in these pigs; Franca et al, 2000), consistent with the peri-pubertal increase in Sertoli cell numbers observed in our control animals. Both the timing of the increase in Sertoli cell numbers and the age at tubular lumen formation in letrozole-treated boars suggest that testis development and puberty were delayed by the local inhibition of estrogen synthesis.

Whether estrogen affects Sertoli cell proliferation directly or indirectly is unclear at this time and subject to speculation. However, it is noteworthy that some mitogenic factors, including fibroblast growth factor, epidermal growth factor, and somatomedin, induce porcine Sertoli cell proliferation in vitro (Jaillard et al, 1987), and their production may be regulated by estrogen (Artagaveytia et al, 1997; Smith et al, 2002). In the rat, thyroid hormone appears to be a regulator of Sertoli cell proliferation, growth, and differentiation, as evidenced with neonatal hypothyroidism, which causes delayed puberty and an increase in Sertoli cell number (De Franca et al, 1995). Higher neonatal triiodothyronine concentrations were related to fewer Sertoli cells and earlier onset of puberty in Meishan boars (McCoard et al, 2003), and estrogens are believed to cause an increase in thyroid stimulating hormone production and secretion by pituitary cells in culture in at least 1 species (ovine; Miller et al, 1977). Additionally, an allele of the thyroid-binding globulin gene on the porcine X chromosome that alters the bioavailability of thyroxine (Schussler, 2000) is also associated with variation in testis size (Nonneman et al, 2005). However, 2 independent studies have shown that induction of hypothyroidism in pigs has no effect on testis development (Tarn et al, 1998; Klobucar et al, 2003). Thus far no evidence exists for the direct effect of estrogen on Sertoli cell proliferation in the boar, although this has been documented in the dogfish shark (Betka and Callard, 1998), in which estrogen inhibits DNA synthesis in germ cell–Sertoli cell units within the testes. Further investigation of the mechanisms of action of estrogen on Sertoli cell proliferation is warranted.

Interestingly, the relative percentage Leydig cell volume in testes of aromatase-inhibited boars was conserved, matching the relative volume in testes of control littermate boars. Not only were larger testes in previous studies associated with more Sertoli cells and longer tubules (Kosco et al, 1989a; Lunstra et al, 2003), but there was a noticeable increase in the volume and number of Leydig cells (Lunstra et al, 2003) as well. The present study is consistent with a proportional increase in Leydig cell volume with testis size. Compensatory growth of the remaining testis in hemicastrated boars induced a 250% increase in Leydig cell mass relative to body mass as compared with intact boars (Kosco et al, 1989b). An increase in absolute Leydig cell volume in aromatase-inhibited, reduced-estrogen boars is indicative of increased steroidogenic capacity, because studies have shown a direct correlation between Leydig cell volume and steroidogenic capacity in the boar (Lunstra et al, 1986). In the dog, decreasing estrogen synthesis resulted in hypertrophy of Leydig cells (Walters et al, 1988; Junker Walker and Nogues, 1994), as did immunizing against estradiol in rams (Schanbacher et al, 1987); this effect was likely because of increased luteinizing hormone (LH) tropic drive (Schanbacher et al, 1987; Juniewicz et al, 1988). Unlike the dog and the ram, the boar did not have elevated LH following aromatase enzyme inhibition, and hence it is likely that the increase in total Leydig cell volume observed in 8-month-old boars was caused by reduced estrogen synthesis, whereas the initial reduction at 2 months may be attributed to the delay in testicular maturation in aromatase-inhibited boars.

This study was aimed at determining the role of endogenous estrogens on testicular growth and development in the domestic boar. Although the effect of estrogen on testicular development and function has been studied in several species, we are not aware of any previous studies in the boar that have investigated the role of endogenous estrogen on the development of the somatic cells within the testis that ultimately contribute to testicular size and sperm production. Interestingly, reducing endogenous estrogens caused a delay in the apparent onset of puberty but an ultimate increase in testis size, Sertoli cell number, and total spermatid production per animal without affecting relative Leydig cell volume. These findings suggest that estrogen is an important Sertoli cell maturation factor regulating testicular development in the domestic boar.

	Acknowledgments

 
We would like to thank Kent Parker, Animal Science Swine Facility Manager, for the care and maintenance of the boars as well as for assistance with handling the animals. Thanks also to the faculty and staff at the UC Davis School of Veterinary Science for castrating boars. We would like to acknowledge the help of Dr Tom Famula, Professor of Animal Science, for assistance with statistical analysis. We would like to extend our sincere appreciation to Chris Pearl for his instrumental role in the treatment and handling of animals and tissue. Thanks to Matt Rooney for his assistance in handling and treatment of animals.

	Footnotes

 
Supported by National Reseach Initiative competitive grant 2002-35203-12606 from the USDA Cooperative State Research, Education and Extension Service.

DOI: 10.2164/jandrol.05195

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