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Review: Ontology and endocrinology of the reproductive system of bulls from fetus to maturity

Published online by Cambridge University Press:  19 March 2018

M. McGowan*
Affiliation:
School of Veterinary Science, The University of Queensland, Gatton Campus, Gatton, QLD 4343, Australia
M. K. Holland
Affiliation:
School of Veterinary Science, The University of Queensland, Gatton Campus, Gatton, QLD 4343, Australia
G. Boe-Hansen
Affiliation:
School of Veterinary Science, The University of Queensland, Gatton Campus, Gatton, QLD 4343, Australia
*

Abstract

This review focuses on current understanding of prenatal, prepubertal and post-pubertal development of the male reproductive system of cattle. The critical developmental events occur during the first 3 to 4 months of gestation and the first ~6 to 9 months after birth. The Wilms Tumor-1 and SRY proteins play critical roles in early development and differentiation of the fetal testis, which in turn drives gestational development of the entire male reproductive system. The hypothalamic–pituitary–gonadal axis matures earlier in the bovine fetus than other domestic species with descent of the testes into the scrotum occurring around the 4th month of gestation. An array of congenital abnormalities affecting the reproductive system of bulls has been reported and most are considered to be heritable, although the mode of inheritance in most cases has not been fully defined. Early postnatal detection of most of these abnormalities is problematic as clinical signs are generally not expressed until after puberty. Development of genomic markers for these abnormalities would enable early culling of affected calves in seedstock herds. The postnatal early sustained increase in lutenising hormone secretion cues the rapid growth of the testes in the bull calf leading to the onset of puberty. There is good evidence that both genetic and environmental factors, in particular postnatal nutrition, control or influence development and maturation of the reproductive system. For example, in Bos taurus genotypes which have had sustained genetic selection pressure applied for fertility, and where young bulls are managed on a moderate to high plane of nutrition puberty typically occurs at 8 to 12 months of age. However, in many Bos indicus genotypes where there has been little selection pressure for fertility and where young bulls are reared on a low plane of nutrition, puberty typically occurs between 15 to 17 months. Our understanding of the control and expression of sexual behavior in bulls is limited, particularly in B. indicus genotypes.

Type
Review Article
Copyright
© The Animal Consortium 2018 

Implications

A good understanding of prenatal and postnatal development of the reproductive system of bulls and the factors affecting it’s development provides the basis for ‘best practice’ recommendations on the management of pregnant seedstock dams and management of young bulls through to them either, becoming herd sires or semen donors. Both prenatal and postnatal development of the reproductive system is controlled by interactions between genetic and environmental factors. Some disturbances in development may be diagnosed before puberty but some such as unilateral testicular hypoplasia and premature spiral deviation of the penis may not manifest until months to several years after bulls reach puberty.

Introduction

To optimize the management of young bulls and to understand the pathogenesis of subfertility or infertility in young and older bulls knowledge of the sequence and broad timing of developmental and physiological changes in the reproductive system that occur from conception to sexual maturity is required. Disturbances in either prenatal and or postnatal development of the reproductive system of males are associated with varying degrees of subfertility or infertility. Furthermore, it is important to consider development of the reproductive system as part of development of the whole male animal, not in isolation. For example, it is well recognized that at the same time critical peripubertal changes are occurring in development of the testes important maturational changes are occurring in articular cartilage, and disturbances in the latter can predispose to degenerative joint disease which in turn may be associated with reduced libido, mating ability and/or semen quality (Persson et al., Reference Persson, Söderquist and Ekman2007). This review will focus on current understanding of prenatal, prepubertal and post-pubertal development of the reproductive system of bulls and highlight some of the key factors affecting this development

Prenatal development of the reproductive system

Period of the embryo through to day 100 of gestation

The chromosomal sex of the embryo is determined at fertilization by the sex chromosome carried by the fertilizing spermatozoon. Immediately following fertilization (review: Avella et al., Reference Avella, Xiong and Dean2013) the embryo remains transcriptionally silent until the 8 to 16 cell stage (Graf et al., Reference Graf, Krebs, Heininen-Brown, Zakhartchenko, Blum and Wolf2014). By the blastocyst stage, when differentiation begins with formation of the inner cell mass (ICM) and the trophectoderm (Reijo Pera and Prezzoto, Reference Reijo Pera and Prezzoto2016), differences in genes expressed can be detected between male and female embryos (Heras et al., Reference Heras, De Cininck, Van Poucke, Goossens, Bogado Pascottini, Van Nieuwerburgh, Deforce, De Sutter, Leroy, Gutierrez-Adan, Peelman and Van Soom2016). At about the time the embryo hatches through the zona pellucida a second phase of differentiation which involves both the ICM and trophectoderm occurs. Cells of the ICM facing the blastocoel flatten and elongate and form the hypoblast whilst the remaining ICM cells become the epiblast. From the epiblast three somatic germ layers develop, the ectoderm, endoderm and mesoderm, and these can be detected before appositional attachment of the conceptus to the endometrium. These layers give rise to different organ systems. With respect to the male reproductive system the hypothalamus, pituitary gland and penis are derived from the ectoderm, and the gonads, epididymis, ductus deferens and urinary system are derived from the mesoderm.

At the time the embryo differentiates into the three somatic germ layers most cells lose their pluripotency except for the primordial germ cells which are derived from the inner lining of the yolk sac. These cells migrate either passively or by amoeboid movement, in response to as yet unidentified molecular cues, into the genital or gonadal ridge to form the indifferent gonad. The understanding of these processes in the bovine lags behind that in smaller mammals (Tarbashevich and Raz, Reference Tarbashevich and Raz2010), but the expectation is the processes will be similar.

Primordial germ cells are recognized as large cells which stain positive for alkaline phosphatase and the well-known marker of pluripotency octamer-binding transcription factor 4. Primordial germ cells which do not populate the genital ridge degenerate. Rapid population of the genital ridge occurs because of the high rate of mitotic division shown by these cells, probably in response to Steel Factor and the cytokine Leukaemia Inhibitory Factor (Gu et al., Reference Gu, Runyan, Shoemaker, Surani and Wylie2009). By day 25 in the bovine fetus there are 1 to 2000 primordial germ cells in the genital ridge.

The indifferent gonad is located on the inner surface of the dorsal body wall medial to the embryonic kidneys. It is first seen at about days 28 to 29 when the fetus has a crown-rump length of 9 to 10 mm. It remains morphologically indifferent for several weeks. There are three cell types in the genital ridge: local mesenchymal cells, cells derived from the coelomic epithelium and cells from the regressing mesonephric tubules that invade the presumptive gonadal tissue (Hyttel et al., Reference Hyttel, Sinowatz, Vejlsted and Betteridge2009). Some of the genes important in this process have been identified from their high levels of expression in the developing gonad. The earliest acting gene is Wilms tumor-1 (WT-1). The WT-1protein is a zinc finger transcription factor produced by the Sertoli cells, and is essential for the development of the kidneys and gonads. In the developing gonad it plays a crucial role in testis cord assembly and maintenance. The WT-1 protein also regulates development of the fetal Leydig cells, interstitial progenitor cell lineages and peritubular myoid cell development through Notch signalling, thus facilitating fetal testis compartmentation (Wen et al., Reference Wen, Wang, Tang, Cheng and Liu2016). The gene Lim1 encodes a homeobox transcription factor which plays a major role in development of the kidney, but is also important in gonad development because in its absence the gonads do not develop (Davies and Fisher, Reference Davies and Fisher2002). Steroid factor 1 (SF1) is a nuclear receptor and acts as a regulator of multiple genes (Kohler and Achermann, Reference Kohler and Achermann2010). It is highly expressed in the early indifferent gonad but its role there is unclear. SF1 is also highly expressed in steroidogenic cells of the adrenal cortex and gonads, as well as in neurons of the ventromedial nucleus of the hypothalamus (Kohler and Achermann, Reference Kohler and Achermann2010). The gonad ceases being indifferent when cords of epithelial cells from the mesonephric tubules and regressing glomerular capsule penetrate the mesenchyme of the genital ridge and form the primitive sex chords.

Differentiation of the fetal testis occurs in response to the sex-determining region on the Y chromosome (i.e. the SRY gene). The SRY protein is a member of the SRY related high mobility group box (Sox) transcription factor family. Expression of SRY begins at day 37 and peaks at day 39 in the bovine fetus (Ross et al, Reference Ross, Bowles, Hope, Lehnert and Koopman2009). The bovine protein encoded by SRY is composed of 229 amino acids (Soleymani et al., Reference Soleymani, Hafezian, Mianji, Mansouri, Chaharaein, Tjehmiri, Shanrifi Tabar and Mostafie2017) and is very similar in size to murine SRY. In both species the encoded protein is a member of the high mobility group (HMG) of proteins. The SRY gene regulates a number of other genes which collectively drive differentiation of the indifferent gonad to become a testis. The gene Sox9 is the direct target for SRY. Expression of Sox9 leads to differentiation of the foetal Sertoli cells (Gonen et al, Reference Gonen, Quinn, O’Neill, Koopman and Lovell-Badge2017) which orchestrate testicular morphogenesis. Sox9 controls a conserved genetic program that involves most of the sex-determining genes. In the fetal testes Sox9 modulates both transcription, and also directly or indirectly differential splicing of its target genes, through binding to genomic regions with sequence motifs that are conserved among mammals and are called Sertoli cell signatures. Sertoli cell signatures display precise organization of binding motifs for the Sertoli cell reprogramming factors Sox9, Gata4 and DMRT1. Recently, a new factor, tripartite motif containing factor 28 which can interact with Sox9 in the fetal testes, was identified by Rahmoun et al. (Reference Rahmoun, Lavery, Laurent-Chaballier, Bellora, Phillip, Symon, Pailhoux, Cammas, Chung, Bageri-Fam, Murphy, Bardwell, Zarkower, Boizet-Bonhoure, Clair, Harley and Poulat2017).

Commencement of differentiation of the male bovine gonad occurs at days 41 to 42 of gestation, preceded by several days with the first detection of SRY. Initially each testicular cord is lumenless with undifferentiated Sertoli cells around the periphery. They are shaped like a horseshoe with tiny strands connecting the ends which at days 60 to 70 of gestation begin to develop into the rete testis. Also at this time, in the mesenchyme between the testicular chords, the first generation of fetal Leydig cells begin to differentiate. These fetal Leydig cells originate in the mesonephros. Interestingly, these cells degenerate postnatally and are replaced by adult Leydig cells, which differentiate only after birth (O’Shaughnessy and Fowler Reference O’Shaughnessy and Fowler2014). It is clear that SRY and the cascade of genetic events it initiates collectively drive the formation of the testes and through this, ultimately development of the entire male reproductive system.

Vigier et al. (Reference Vigier, Prépin and Jost1976) describe the key events in development of the male bovine reproductive tract, commencing with masculinization of the external genitalia around day 47 of gestation, driven by testosterone and androstenedione secretion from the newly differentiated fetal Leydig cells. By day 60 the scrotum is well differentiated. Regression of the paramesonephric ducts starts from day 50 (Vigier et al., Reference Vigier, Prépin and Jost1976) and is completed by day 80. The masculinization of the internal genitalia occurs in two distinct phases. In the first phase (days 56 to 58) the early buds of the seminal vesicles and prostate appear, and the bulbourethral gland begins to develop. In the second phase (beyond day 70) branching of the seminal vesicles begins, differentiation of the epididymis begins, and stabilization of the mesonephric ducts occurs (Vigier et al., Reference Vigier, Prépin and Jost1976). At the end of the first trimester the major components of the bovine male reproductive system are all present but not yet fully developed. However, the epididymis only begins to form at day 110 (Alkafafy and Sinowatz, Reference Alkafafy and Sinowatz2012).

The highly complex series of events which occur in differentiation and development of the male reproductive system are underpinned by the program of regulated gene expression described above. However, epigenetic mechanisms are also likely to influence many aspects of development of the male reproductive tract. Although a cell’s transcriptional machinery, provides the basis for its differentiation and development, epigenetic marks on its DNA may alter components of this machinery (Rojas-Garcia et al., Reference Rojas-Garcia, Recabarren, Sir-Petermann, Rey, Palma and Carrasco2013). These epigenetic marks are subject to both environmental and developmental perturbations which can subsequently impact on early embryonic development (Farin et al., Reference Farin, Piedrahita and Farin2006) or gametogenesis (Mochizuki et al., Reference Mochizuki, Tachibana, Saitou, Tokitake and Matsui2012). Although there is extensive research on the impact of in-utero nutrition of the dam and fetus on development and function of the male reproductive system in sheep there has been only a few studies conducted in cattle. Sullivan et al. (Reference Sullivan, Micke, Greer and Perry2010) reported that when tropically adapted heifers were fed a ration formulated to provide an average of 2.4×the recommended energy and protein requirements for the first and second trimester their male calves at 5 months of age had smaller testes and lower serum concentrations of testosterone compared with the calves from heifers fed an average of 1.9× and 0.7× the recommended energy and protein requirements. In-vitro manipulation and culture of gametes and embryos have also been shown to affect the normal epigenome of the subsequent fetus or offspring (Ventura-Junca et al., Reference Ventura-Junca, Irarrazaval, Rolle, Gutierrez, Moreno and Santos2015; Anckaert and Fair, Reference Anckaert and Fair2017; Canovas et al., Reference Canovas, Ross, Kelsey and Coy2017). However, it is important to note that with respect to the development of the reproductive system of the bull there are no confirmed reports that the use of assisted reproductive technologies has contributed to abnormal development.

Period from day 100 of gestation through to birth

During this period final development of the internal and external genitalia is completed including descent of the testes into the scrotum. The hypothalamic–pituitary–gonadal (HPG) axis continues to mature and the fetal Leydig cells secrete androgens, testosterone and dihydrotestosterone (DHT), which act to stabilize the mesonephric ducts and to masculinize the external genitalia, and insulin-like peptide 3 (Insl3) which acts with testosterone to induce testicular descent.

Testosterone regulates three main aspects of male phenotypic development, directly or through DHT: the genital tubercle develops into the penis; the urogenital sinus forms the urethra, the prostate gland and the bulbourethral glands; and the mesonephric duct is converted into the epididymis, vas deferens, ampulla and seminal vesicles. When considering the pathogenesis of developmental and congenital abnormalities of the male reproductive tract it is important to understand that both testicular descent and the formation of the internal and external genitalia involve multistep developmental processes influenced by many factors, including specific genetic factors (Klonisch et al., Reference Klonisch, Fowler and Hombach-Klonisch2004), and environmental factors. In humans increased incidence of abnormalities such as delayed preputial separation, hypospadias, cryptorchidism and reduced semen quality (WHO, 2012) have been speculated to be associated with in-utero exposure to endocrine-disrupting compounds, however the impact of these compounds on development of the reproductive system of bulls has not been determined. In sheep there is experimental evidence demonstrating that the reproductive axis of male lambs born to DES and testosterone treated pregnant ewes is adversely affected with subsequent reduced testicular development and semen quality in mature rams (Recabarren et al., Reference Recabarren, Rojas-Garcia, Recabarren, Alfaro, Smith, Padmanabhan and Sir-Peterman2008; Rojas-Garcia et al., Reference Rojas-Garcia, Recabarren, Sir-Petermann, Rey, Palma and Carrasco2013).

Congenital disorders of development of the reproductive tract in the bull are well described, particularly disorders related to testicular development and descent, and for structures originating from the mesonephric ducts and genital tubercle (Barth, Reference Barth2013). Many of the described congenital disorders are considered to be heritable, however neither the causal mutation(s) nor the molecular etiology of these phenotypes have been definitively identified. However, ongoing advances in genomics are likely to significantly improve our understanding of the underlying cause of these abnormalities (Han and Peñagaricano, Reference Han and Peñagaricano2016).

By 100 to 120 days of gestation, the testes of the bovine fetus have passed through the inguinal canal and entered the scrotum, which is derived from the urogenital folds. This is early in comparison with other domestic species and is preceded by an earlier maturing HPG axis in this species. There are two critical phases in descent of the testes, the transabdominal and inguinoscrotal phase. These phases are essential to move the testes into the scrotum (Klonisch et al., Reference Klonisch, Fowler and Hombach-Klonisch2004). In the bovine, testicular descent begins relative early in gestation with the transabdominal phase beginning around days 80 to 90 and the inguinoscrotal phase around day 112. Insl3 produced by the fetal Leydig cells mediates transabdominal descent, and secreted androgens mediate the inguinoscrotal descent. Both Insl3 and testosterone are necessary for normal development and reorganization of the gubernaculum during the inguinoscrotal descent. In cattle plasma concentrations of Insl3 and testosterone at 4 to 8 months of gestation have been shown to be significantly higher in dam’s carrying a male fetus compared with a female fetus. In the bovine fetus plasma testosterone peaks at day 125. Measurement of these hormones have been used for mid-gestation determination of the sex of the fetus (Kibushi et al., Reference Kibushi, Kawate, Kaminogo, Hannan, Weerakoon, Sakase, Fukushima, Seyama, Inaba and Tamada2016).

The descent of the testes into the scrotal sac is a complex multifactorial process, and a variety of environmental and genetic factors have been shown to affect the process. Although mutations in the Insl3 gene or LGR8/GREAT, acting as ligand and receptor respectively, have been found to be associated with cryptorchidism in humans (Foresta and Ferlin, Reference Foresta and Ferlin2004), similar mutations have not been identified in cattle. In cattle the prevalence of cryptorchidism has been reported to be 0.17% (St.Jean et al., Reference St.Jean, Gaughan and Constable1992) with left-sided retention occurring twice as frequently as right-sided retention. Interestingly in the bull inguinal hernia occurs most frequently on the left side (Foster Reference Foster2016). There may be a heritable predisposition to cryptorchidism in some breeds such as Polled Herefords and Shorthorns (St.Jean et al., Reference St.Jean, Gaughan and Constable1992).

Differentiation of the external genitalia commences around day 60 in the bovine fetus under the influence of DHT. The glans penis originates from the apex of the genital tuberculum and a cord of epithelia cells moves into the genital tubercles to fuse with the urethral groove. The cord forms the distal part of the penile urethra (Hyttel et al., Reference Hyttel, Sinowatz, Vejlsted and Betteridge2009). Hypospadias is an abnormal opening of the urethra due to failure or incomplete closure of the embryonic urethral groove. It is often considered a mild form of psedo-hermaphrodism reported to result from an inadequate response of the distal urethral fold to DHT. In cattle, the reported prevalence of hypospadias is very low, around 0.3% (Saunders and Ladds Reference Saunders and Ladds1978), and in some cases is accompanied by other abnormalities of the reproductive tract such as penile aplasia and cryptorchidism. Familial clustering has been reported (Kumi-Diaka and Osori, Reference Kumi-Diaka and Osori1979) indicating a potential genetic etiology.

A number of congenital penile anomalies have been described in the bull including hypoplasia of the penis, diphallus and premature spiral deviation of the penis (Walker, Reference Walker1964; Foster, Reference Foster2016). In bulls penile hypoplasia is often described as congenital short penis, and in some cases may be due to congenital shortening of the retractor penis muscle. This results is penile protrusion being restricted to <25 cm from the penile tip to preputial orifice (Gilbert, Reference Gilbert1989). Barth (Reference Barth2013) estimates the annual incidence of this abnormality to be 0.0002%, and cases have been diagnosed in both Bos taurus and Bos indicus genotypes (Gilbert, Reference Gilbert1989). Also described in bulls is partial or complete absence of the sigmoid flexure of the penis (Foster, Reference Foster2016). Premature spiral deviation of the penis is the most commonly diagnosed penile deviation and in most cases is thought to be due to abnormal development of the dorsal apical ligament of the penis predisposing to progressive post-pubertal degeneration of the ligament (Ashdown, Reference Ashdown and Pearson2006). It has been reported in most breeds and there is a higher prevalence in polled than horned bulls (Ashdown and Pearson, Reference Ashdown and Pearson1973), however this is unlikely to be linked to the polled gene. The observed prevalence of premature spiral deviation of the penis in a population of British breed bulls was 16% for polled bulls compared with 1% in horned bulls (Blockey and Taylor, Reference Blockey and Taylor1984). In a later study (Norman et al., Reference Norman, Bertram and McGowan2008) involving both B. taurus and B. indicus genotypes, approximately twice as many cases of premature spiral deviation of the penis were observed in polled-breed bulls (13.5%) than in horned-breed bulls (5.6%). Although Blockey and Taylor (Reference Blockey and Taylor1984) concluded from their pedigree analysis that the condition was likely to be heritable, Norman et al. (Reference Norman, Bertram and McGowan2008) concluded that it was not associated with the polled gene per se. The major problem with this abnormality is that expression is often delayed until bulls are 3 to 6 years of age and it can only be conclusively diagnosed by observing a bull attempting to serve multiple times (Norman et al., Reference Norman, Bertram and McGowan2008).

Another common abnormality of the penis and prepuce is persistent frenulum which results when there is incomplete breakdown of the preputial attachment to the glans penis around the time of puberty. Throughout gestation the penis is attached to the penile prepuce by a lamella of ectodermal cells and a frenulum of connective tissue. The preputial cavity subsequently develops as the ectodermal lamella keratinizes and splits into two epithelial surfaces. This keratinization commences at the tip of the penis in the calf shortly after birth (around 4 weeks), but protrusion of the penis does not occur until just before puberty. Studies have indicated that keratinization of the ectodermal lamella is controlled by androgens, which may be the case during both fetal and prepubertal development (Ashdown, Reference Ashdown1960). The reported prevalence in both B. taurus and B. indicus genotypes is 0.5%, however the author (M. M.) has frequently observed 2% to 4% affected bulls in large groups of 1- to 2-year-old bulls. It is considered a heritable abnormality but the mode of inheritance has not been determined (Barth, Reference Barth2013).

Differentiation of the seminal vesicles commences around days 56 to 58 as small out-growths of the posterior mesonephric ducts and after day 70 these simple diverticula become branched and grow rapidly. On day 110 the seminal vesicles are ~7 mm in length and at the same time the epididymis, begins to form when the mesonephric duct lengthens and coils forming the three distinct epididymal regions (caput, corpus and cauda) (Alkafafy and Sinowatz, Reference Alkafafy and Sinowatz2012). Hypoplasia of the epididymis and/or the accessory sex glands has been described in bulls (Williams et al., Reference Williams, Revell, Scholes, Courtenay and Smith2010; Foster, Reference Foster2016). Segmental aplasia or hypoplasia of the mesonephric duct is a sporadically reported defect. The condition is characterized by partial or complete absence of structures derived from the mesonephric duct, including the epididymis, ductus deferens, ampullae and seminal vesicles (Foster Reference Foster2016). Both uni- and bilateral aplasia of the mesonephric duct has been described in the bull (Saunders and Ladds, Reference Saunders and Ladds1978; Campero et al., Reference Campero, Bagshaw and Ladds1989). These abnormalities are considered to be heritable but the mode of inheritance is poorly understood (Saunders and Ladds, Reference Saunders and Ladds1978). A pedigree analysis of 18 Simmental bulls with segmental aplasia of the epididymis indicated an autosomal recessive mechanism as the mode of inheritance (Konig et al., Reference Konig, Weber and Kupferschmied1972). Spermatic granuloma of the head of the epididymis is related to failure of one or more of the efferent ductules to join with the head of the epididymis (Foster, Reference Foster2016). This condition will in most cases only become apparent after puberty. The prostate and bulbourethral glands arise from endodermal epithelial buds from the middle or pelvic part of the urogenital sinus. Congenital abnormalities of the prostate gland and bulbourethral glands are very uncommon in the bull (Campero et al., Reference Campero, Bagshaw and Ladds1989; Foster, Reference Foster2016).

In cattle, most heifers born as co-twins with males exhibit the intersexual syndrome commonly known as freemartinism. The effects on the male born co-twin to a freemartin is however less evident. Chimerism is readily detected in the male, but the effects on the reproductive system have been much debated (Long, Reference Long1979). Spermatogonial chimerism was demonstrated in three bulls born as freemartins (Rejduch et al., Reference Rejduch, Słota and Gustavsson2000). In this study a low number of spermatogonia (10%) were shown to be carrying XX chromosomes, which could affect the sex ratio of offspring sired by these bulls. The fertility of bulls born as a co-twin to a freemartin varies with some being normally fertile whilst others are subfertile or infertile due to reduced percentages of motile and morphologically normal sperm (Padula, Reference Padula2005)). In a study of 22 bulls born co-twin to freemartins, and with evidence of chimerism, a higher proportion (58%) of co-twin bulls were culled because of poor fertility than normal controls (5%; Dunn et al., Reference Dunn, McEntee, Hall, Johnson and Stone1979). However, Long (Reference Long1979) did not detect any difference in fertility between chimeric and non-chimeric bulls.

Postnatal development of the reproductive system

Rawlings et al. (Reference Rawlings, Evans, Chandolia and Bagu2008) have provided an excellent review of studies describing postnatal development of the reproductive system of bulls. However, it should be noted that most of the reported studies involved B. taurus breed cattle managed on a moderate to high plane of nutrition from birth to sexual maturation (average daily live weight gain of ~1 kg/day). This contrasts with the situation commonly encountered in tropical rangelands where B. indicus genotypes predominate, and very marked seasonal variation in rainfall restricts postnatal average daily live weight gain to only 0.3 to 0.4 kg/day. The primary impact of low prepubertal growth rate is delayed onset in puberty and slower rate of testicular development. Age guidelines for the occurrence of critical events such as puberty should always be interpreted with body weight (BW) and growth rate data. McGowan et al. (Reference McGowan, Muller, Lisle, Fordyce, Holroyd and Doogan2012) demonstrated that testicular development (as defined by measurement of scrotal circumference) in a population of young tropically adapted bulls was better described when weight rather than age was used in a standard non-linear model.

Using Rawlings et al. (Reference Rawlings, Evans, Chandolia and Bagu2008) review of development of the reproductive system of the bull three periods of development should be considered, prepubertal, peripubertal and post pubertal.

Prepubertal development

This is the period from birth through to the onset of rapid increase in testicular size at ~6 months of age. At birth the testes of the bull calf are fully descended and are primarily composed of lumenless chords of primordial germ cells, fetal Leydig cells and undifferentiated Sertoli cells (Wrobel, Reference Wrobel1990; Rawlings et al., Reference Rawlings, Evans, Chandolia and Bagu2008). The penis is firmly attached to the prepuce and although present the accessory sex glands are essentially non-functional. Interestingly, the seminal vesicular glands begin to rapidly increase in size several months after birth (Chandolia et al., Reference Chandolia, Honaramooz, Omeke, Pierson, Beard and Rawlings1997) well before the period of rapid growth of the testes.

However, commencing about a month after birth the fetal Leydig cells degenerate and numbers of adult Leydig cells and undifferentiated Sertoli cells begin to increase rapidly (Sinowatz and Amselgruber, Reference Sinowatz and Amselgruber1986; Wrobel Reference Wrobel1990). This critical growth and differentiation of cells begins around the time of the early sustained postnatal increase in lutenising hormone (LH) secretion which is driven by an increase in the frequency of pulses of GnRH (Rawlings et al., Reference Rawlings, Evans, Chandolia and Bagu2008). Although serum concentrations of LH remain elevated for several months serum concentrations of testosterone are low (Evans et al., Reference Evans, Pierson, Garcia, McDougall, Hrudka and Rawlings1996). Rawlings et al. (Reference Rawlings, Evans, Chandolia and Bagu2008) concluded that the duration of increased LH secretion is controlled by negative enhanced feedback suppression of gonadotropin secretion by testes-derived androgens and oestradiol, but changes in central opiodergic tone may also play a role in regulating GnRH secretion. Both serum concentrations of follicle stimulating hormone (FSH) and inhibin are also high during the prepubertal period but decline around the time of onset of rapid growth of the testes (Miyamoto et al., Reference Miyamoto, Umezu, Ishii, Furusawa, Masaki, Hasegawa and Ohta1989; Evans et al., Reference Evans, Pierson, Garcia, McDougall, Hrudka and Rawlings1996). Although the role of the prepubertal increase in LH in cueing the onset of puberty is clear the role of FSH is unclear. Evans et al. (Reference Evans, Davies, Nasser, Bowman and Rawlings1995) found no differences in the prepubertal FSH concentrations of calves which had a mean difference in onset of puberty of 6 weeks. However, there is some evidence (Bagu et al., Reference Bagu, Madgwick, Duggavathi, Bartlewski, Barrett, Huchkowsky, Cook and Rawlings2004) that FSH secretion is a key driver of prepubertal proliferation of Sertoli cells, which in turn is a critical determinant of daily sperm production in the bull (Berndtson et al., Reference Berndtson, Igboeli and Parker1987). The role of inhibin in regulating the pattern of secretion of FSH is unclear (Rawlings et al., Reference Rawlings, Evans, Chandolia and Bagu2008).

Pre-spermatogonia begin to proliferate and some spermatogonia appear about a month after birth with primary spermatocytes appearing at about 5 months of age (Curtis and Amann, Reference Curtis and Amann1981). However, spermatogenesis only really begins to progress rapidly at the end of the early postnatal increase in LH secretion, and as serum concentrations of FSH and inhibin decrease markedly (Rawling et al., Reference Rawlings, Evans, Chandolia and Bagu2008).

The magnitude of LH secretion between 1 to 5 months after birth in bull calves directly affects the pattern of growth and differentiation of the testes and thus age of onset of puberty. Evans et al. (Reference Evans, Davies, Nasser, Bowman and Rawlings1995) demonstrated that the prepubertal increase in LH secretion was greater in bull calves that had an early onset of puberty compared with those that had a later onset. This difference maybe under significant genetic control as evidenced by the moderate heritability (0.3 to 0.5) of GnRH induced LH secretion at 4 months of age in B. indicus (Brahman) and B. indicus cross bull calves (Corbet et al., Reference Corbet, Burns, Johnston, Wolcott, Corbet, Venus, Li, McGowan and Holroyd2013). The high heritability (0.7) of serum concentrations of inhibin at 4 months of age in both genotypes in this study requires further investigation to determine its significance.

There has been considerable interest not only in the AI industry, but also amongst seedstock producers selling yearling bulls, in developing to advance the onset of puberty. Feeding high energy and protein diets to young beef and dairy calves to achieve average daily weight gains (ADG) of ~1.4 to 1.5 kg/day through to 16 months of age has been shown to significantly reduce age of onset of puberty, increase paired testes weight and increase total daily sperm production without any adverse effects on semen quality (Brito et al., Reference Brito, Barth, Rawlings, Wilde, Crews, Mir and Kastelic2007; Dance et al., Reference Dance, Thundathil, Blondin and Kastelic2016). These impacts are driven by enhanced secretion of GnRH and LH during the period of early postnatal increase in LH, and are directly influenced by increased concentrations of circulating insulin and in particular IGF-1. Although there is a strong association between increased plane of nutrition and increased concentrations of IGF-1, it is also important to recognize that IGF-1 secretion is under significant genetic control as reported by Corbet et al. (Reference Corbet, Burns, Johnston, Wolcott, Corbet, Venus, Li, McGowan and Holroyd2013). Thus, the response to nutritional manipulation is likely to be significantly influenced by genetics, and may explain why Harstine et al. (Reference Harstine, Maquivar, Helser, Utt, Premanandan, DeJarnette and Day2015) observed that Holstein bull calves which managed to achieve ADG of 1.5 kg/day did not have an earlier onset of puberty than those fed to grow at 0.75 kg/day, despite significant differences in testes size.

Peripubertal development

This is the period encompassing the rapid almost linear growth of the testes and epididymides, including establishment of a lumen in each seminiferous tubule (Evans et al., Reference Evans, Pierson, Garcia, McDougall, Hrudka and Rawlings1996), through to puberty. It is interesting to note that Wolf et al. (Reference Wolf, Almquist and Hale1965) observed that protrusion of the penis with complete separation from the prepuce precedes the onset of puberty by ~1.5 months. The continuing rapid increase in adult Leydig cells (Wrobel, Reference Wrobel1990) and low frequency pulses of LH, result in a rapid increase in serum concentrations of testosterone which drives this rapid growth of the testes (Rawlings et al., Reference Rawlings, Evans, Chandolia and Bagu2008) and spermatogenesis. However, the trajectory of growth of the testes between about 6 to 12 months varies considerably between bulls which adversely affects the accuracy of selection of bulls at an early age which will have small testes at 18 to 24 months of age (Barth, Reference Barth2013). Spermatogenesis is also supported by the differentiation of Sertoli cells which occurs between about the 4th and 10th month after birth (Abdel-Raouf, Reference Abdel-Raouf1960; Curtis and Amann, Reference Curtis and Amann1981). Primary then secondary spermatocytes are detected between the 5th and 8th month after birth, and between the 8th and 10th month mature spermatozoa are present in the lumen of the seminiferous tubules (Curtis and Amann, Reference Curtis and Amann1981; Evans et al., Reference Evans, Pierson, Garcia, McDougall, Hrudka and Rawlings1996). Also during this period the seminal vesicular glands become functional with amounts of fructose and citric acid increasing markedly after about the 5th to 6th month (Abdel-Raouf, Reference Abdel-Raouf1960).

Wolf et al. (Reference Wolf, Almquist and Hale1965) has defined puberty in the bull as the age at which an ejaculate containing a minimum of 50×106 total sperm with at least 10% showing progressive motility is first collected. These authors have also proposed that a scrotal circumference (SC) of ≥28 cm is indicative that a bull has reached puberty. However, in bulls managed on a low plane of nutrition post weaning a more appropriate SC threshold is ≥26 cm. In a study of tropically adapted bulls (Chase et al., Reference Chase, Chenoweth, Larsen, Hammond, Olson, West and Johnson2001) mean SC when an ejaculate containing 50×106 sperm was collected varied by only 1 cm (27 to 28 cm) between genotypes and between years, but mean age and BW when this was achieved varied by ~2months and 100 kg, respectively. Furthermore, mean SC when spermatozoa were first detected in an ejaculate were 2 to 3 cm less than mean SC at puberty using Wolf et al. (Reference Wolf, Almquist and Hale1965) definition. Overall, for breeds of cattle which have had sustained genetic selection pressure applied for fertility and where young bulls are managed on a moderate to high plane of nutrition (i.e. have achieved ADG since birth of ~1 kg/day), puberty typically occurs at 8 to 12 months of age (Barth, Reference Barth2013). However, for breeds where there has been little selection pressure for fertility, for example many B. indicus genotypes, and particularly where these young bulls are reared on a low plane of nutrition, puberty typically occurs between 15 and 17 months and there is large variation among individual bulls in timing of onset of puberty (Holroyd et al., Reference Holroyd, Bertram, Doogan, Fordyce, Petherick and Turner2005).

Post-pubertal development

This is the period during which maturation of spermatogenesis is completed, testicular growth begins to plateau and bulls develop normal sexual behavior. Also maturational changes in the accessory sex glands and their secretions occur, and it is also likely that the profile of seminal plasma proteins changes during this period. In this period the majority (about 70%) of bulls transition from being markedly subfertile to attaining normal fertility. This is primarily because the ejaculates of pubertal bulls contain a high proportion of morphologically abnormal sperm and sexual behavior is a ‘learned’ phenomena. The interval from onset of puberty to when bulls are producing an ejaculate containing at least 70% normal sperm has been estimated to be 3 to 4 months in B. taurus breed bulls (Lunstra and Echternkamp, Reference Lunstra and Echternkamp1982) but varies considerably between bulls. Analysis of the findings of beef bull breeding soundness examination in Western Canada have demonstrated that whilst only 45% of 12 month old bulls produced an ejaculate containing >70% normal sperm this had increased to 75% for 14 months old bulls (Barth, Reference Barth2013). Holroyd et al. (Reference Holroyd, Bertram, Doogan, Fordyce, Petherick and Turner2005) reported that the mean percent normal sperm for B. indicus bulls (Brahman) aged 14 months was 42%, and this increased to 67% when they reached 16 months of age. Also during the post-pubertal period Price and Wallach (Reference Price and Wallach1991) and Holroyd et al. (Reference Holroyd, Bertram, Doogan, Fordyce, Petherick and Turner2005) both observed marked increase in the expression of normal sexual behavior by bulls exposed to either restrained or unrestrained female cattle in a yard test.

Conclusions

Despite significant advances in our understanding of the genetic control of prenatal and postnatal development of the male reproductive system, the genomic basis for many suspected heritable abnormalities has not been determined. This is important because for many of the abnormalities of the reproductive system of bulls clinical signs are only expressed after puberty (e.g. unilateral testicular hypoplasia), they may spontaneously resolve (e.g. rupture of a persistent frenulum during first mating), or they can only be detected by observing the bull attempting to serve repeatedly (e.g. premature spiral deviation of the penis). Furthermore, in contrast to sheep, in cattle we still have only a limited understanding of the impact of environmental factors on both in-utero and longer term development and function. Finally, the major area of deficiency in our understanding of development of the reproductive system of the bulls is development and endocrine control of sexual behavior

Acknowledgments

The authors thank the many beef and dairy farmers around the world who have supported their research.

Declaration of interest

The authors declare that there is no conflict of interest in this review.

Ethics statement

No original data are presented in this review and hence no ethics approval was sought or required.

Software and data repository resources

No software or data were deposited anywhere as part of this review.

References

Abdel-Raouf, M 1960. The postnatal development of the reproductive organs in bulls with special reference to puberty. (Including growth of the hypophysis and the adrenals). Acta Endocrinology 34 (suppl. 49), 1109.Google Scholar
Alkafafy, M and Sinowatz, F 2012. Prenatal development of the bovine epididymis: light microscopical, glycochemical and immunohistochemical studies. Acta Histochemica 114, 682694.CrossRefGoogle Scholar
Anckaert, E and Fair, T 2017. DNA methylation reprogramming during oogenesis and interference by reproductive technologies: studies in the mouse and bovine models. Reproduction Fertility and Development 27, 739754.Google Scholar
Ashdown, RR 1960. The adherence between the free end of the bovine penis and its sheath. Journal of Anatomy 94, 198204.191.Google ScholarPubMed
Ashdown, RR 2006. Functional, developmental and clinical anatomy of the bovine penis and prepuce. CAB Reviews: Perspectives in Agriculture, Veterinary Science, Nutrition and Natural Resources 21, 129.Google Scholar
Ashdown, RR and Pearson, H 1973. Studies on ‘Corkscrew Penis’ in the bull. Veterinary Record 93, 3035.CrossRefGoogle ScholarPubMed
Avella, MA, Xiong, B and Dean, J 2013. The molecular basis of gamete recognition in mice and humans. Molecular Human Reproduction 19, 279289.CrossRefGoogle ScholarPubMed
Bagu, ET, Madgwick, S, Duggavathi, R, Bartlewski, PM, Barrett, DM, Huchkowsky, S, Cook, SJ and Rawlings, NC 2004. Effects of treatment with LH or FSH from 4 to 8 weeks of age on the attainment of puberty in bull calves. Theriogenology 62, 861873.CrossRefGoogle ScholarPubMed
Barth, AD 2013. Bull breeding soundness, 3rd edition. Western Canadian Association of Bovine Practitioners, Saskatoon, Canada. pp. 108131.Google Scholar
Berndtson, WE, Igboeli, G and Parker, WG 1987. The numbers of Sertoli cells in mature Holstein bulls and their relationship to quantitative aspects of spermatogenesis. Biology. Reproduction 37, 6067.CrossRefGoogle Scholar
Blockey, MA and Taylor, EG 1984. Observations on spiral deviation of the penis in beef bulls. Australian Veterinary Journal 61, 141145.Google Scholar
Brito, LFC, Barth, AD, Rawlings, NC, Wilde, RE, Crews, DH, Mir, PS and Kastelic, J 2007. Effect of nutrition during calfhood and peripubertal period on serum metabolic hormones, gonadotropins and testosterone concentrations, and on sexual development in bulls. Domestic Animal Endocrinology 33, 118.CrossRefGoogle ScholarPubMed
Campero, CM, Bagshaw, PA and Ladds, PW 1989. Lesions of presumed congenital origin in the accessory sex glands of bulls. Australian Veterinary Journal 66, 8185.Google Scholar
Canovas, S, Ross, PJ, Kelsey, G and Coy, P 2017. DNA methylation in embryo development: epigenetic impact of ART. Bioessays 39. https://doi.org/10.1002/bies.201700106.Google Scholar
Chandolia, RK, Honaramooz, A, Omeke, BC, Pierson, R, Beard, AP and Rawlings, NC 1997. Assessment of development of the testes and accessory glands by ultrasonography in bull calves and associated endocrine changes. Theriogenology 48, 119132.Google Scholar
Chase, CC, Chenoweth, PJ, Larsen, RE, Hammond, AC, Olson, TA, West, RL and Johnson, DD 2001. Growth, puberty and carcass characteristics of Brahman-, Senepol-, and Tuli-sired F1 Angus bulls. Journal Animal Science 79, 20062015.CrossRefGoogle ScholarPubMed
Corbet, NJ, Burns, BM, Johnston, DJ, Wolcott, ML, Corbet, DH, Venus, BK, Li, Y, McGowan, MR and Holroyd, RG 2013. Male traits and herd reproductive capability in tropical beef cattle. 2. Genetic parameters of bull traits. Animal Production Science 53, 101113.Google Scholar
Curtis, S and Amann, R 1981. Testicular development and establishment of spermatogenesis in Holstein bulls. Journal Animal Science 53, 16451647.Google Scholar
Davies, JA and Fisher, CE 2002. Genes and proteins in renal development. Experimental Nephrology 10, 102113.CrossRefGoogle ScholarPubMed
Dance, A, Thundathil, J, Blondin, P and Kastelic, J 2016. Enhanced early-life nutrition of Holstein bulls increases sperm production potential without decreasing postpubertal semen quality. Theriogenology 86, 687694.Google Scholar
Dunn, HO, McEntee, K, Hall, CE, Johnson, RH and Stone, WH 1979. Cytogenetic and reproductive studies of bulls born co-twin with freemartins. Journal of Reproduction and Fertility 57, 2130.Google Scholar
Evans, A-CO, Davies, FJ, Nasser, LF, Bowman, P and Rawlings, NC 1995. Differences in early patterns of gonadotrophin secretion between early and late maturing bulls, and changes in semen characteristics at puberty. Theriogenology 43, 569578.Google Scholar
Evans, A-CO, Pierson, RA, Garcia, A, McDougall, LM, Hrudka, F and Rawlings, NC 1996. Changes in circulating hormone concentrations, testes histology and testes ultrasonography during sexual maturation in beef bulls. Theriogenology 46, 345357.Google Scholar
Farin, PW, Piedrahita, JA and Farin, CE 2006. Errors in the development of fetuses and placentas from in vitro produced bovine embryos. Theriogenology 65, 178191. Endocrinology 254–255, 109–119.CrossRefGoogle ScholarPubMed
Foresta, C and Ferlin, A 2004. Role of INSL3 and LGR8 in cryptorchidism and testicular functions. Reproductive Biomedicine Online 9, 294298.Google Scholar
Foster, RA 2016. Chapter 5 – male genital system A2. In Jubb, Kennedy & Palmer’s Pathology of Domestic Animals, volume 3, 6th edition (ed. MG Maxie), pp. 465510.e461. W.B. Saunders, Ontario, Canada.Google Scholar
Gilbert, RO 1989. The diagnosis of short penis as a cause of impotentia coeundi in bulls. Theriogenology 32, 805815.Google Scholar
Gonen, N, Quinn, A, O’Neill, HC, Koopman, P and Lovell-Badge, R 2017. Normal levels of Sox9 expression in the developing mouse testis depend on the TES/TESCO enhancer, but this does not act alone. PLoS Genetics 13. https://doi.org/10.1371/journal.pgen.1006520.Google Scholar
Graf, A, Krebs, S, Heininen-Brown, M, Zakhartchenko, V, Blum, H and Wolf, E 2014. Genome activation in bovine embryos: review of the literature and new insights from RNA sequencing experiments. Animal Reproduction Science 149, 4658.Google Scholar
Gu, Y, Runyan, C, Shoemaker, A, Surani, A and Wylie, C 2009. Steel factor controls primordial factor survival and motility from the time of their specification in the allantois and provides a continuous niche throughout their migration. Development 136, 12951303.CrossRefGoogle ScholarPubMed
Han, Y and Peñagaricano, F 2016. Unravelling the genomic architecture of bull fertility in Holstein cattle. BMC Genetics 17, 143154.Google Scholar
Harstine, BR, Maquivar, M, Helser, LA, Utt, MD, Premanandan, C, DeJarnette, JM and Day, ML 2015. Effects of dietary energy on sexual maturation and sperm production in Holstein bulls. Journal of Animal Science 93, 27592766.Google Scholar
Heras, S, De Cininck, DJ, Van Poucke, M, Goossens, K, Bogado Pascottini, O, Van Nieuwerburgh, F, Deforce, D, De Sutter, P, Leroy, JL, Gutierrez-Adan, A, Peelman, L and Van Soom, A 2016. Suboptimal culture conditions induce more deviations in gene expression in male than female bovine blastocysts. BMC Genomics 17, 72121.Google Scholar
Holroyd, RG, Bertram, JD, Doogan, VJ, Fordyce, G, Petherick, JC and Turner, LB 2005. NAP3.117 Delivery of adequate normal sperm to site of fertilisation. Meat Livestock Australia, Sydney, Australia.Google Scholar
Hyttel, P, Sinowatz, F, Vejlsted, M and Betteridge, K 2009. Essentials of domestic animal embryology. Saunders Elsevier, Edinburgh, UK.Google Scholar
Kibushi, M, Kawate, N, Kaminogo, Y, Hannan, MA, Weerakoon, WWPN, Sakase, M, Fukushima, M, Seyama, T, Inaba, T and Tamada, H 2016. Fetal gender prediction based on maternal plasma testosterone and insulin-like peptide 3 concentrations at mid-gestation and late gestation in cattle. Theriogenology 86, 17641773.Google Scholar
Klonisch, T, Fowler, PA and Hombach-Klonisch, S 2004. Molecular and genetic regulation of testis descent and external genitalia development. Developmental Biology 270, 118.Google Scholar
Kohler, B and Achermann, JC 2010. Update – steroidogenic factor 1. Minerva Endocrinology 35, 7386.Google Scholar
Konig, H, Weber, W and Kupferschmied, H 1972. Epididymal aplasia in bulls and boars. Demonstration of 18 cases with recessive inheritance in the Simmentaler spotted breed. b. Occurrence of abnormalities in one boar and 3 offspring. Schweizer Archiv Fur Tierheilkunde 114, 7382.Google Scholar
Kumi-Diaka, J and Osori, DIK 1979. Perineal hypospadias in two related bull calves, a case report. Theriogenology 11, 163164.Google Scholar
Long, SE 1979. The fertility of bulls born twin to freemartins: a review. Veterinary Record 104, 211213.Google Scholar
Lunstra, D and Echternkamp, S 1982. Puberty in beef bulls: acrosome morphology and semen quality in bulls of different breeds. Journal Animal Science 55, 638648.Google Scholar
Mochizuki, K, Tachibana, M, Saitou, M, Tokitake, Y and Matsui, Y 2012. Implication of DNA demethylation and bivalent histone modification for selective gene regulation in mouse primordial germ cells. PLoS One 7, e46036.Google Scholar
Miyamoto, A, Umezu, M, Ishii, S, Furusawa, T, Masaki, J, Hasegawa, Y and Ohta, M 1989. Serum inhibin, FSH, LH and testosterone levels and testicular inhibin content in beef bulls from birth to puberty. Animal Reproduction Science 20, 165178.Google Scholar
McGowan, M, Muller, T, Lisle, A, Fordyce, G, Holroyd, R and Doogan, V 2012. Recommended minimum scrotal circumference for tropically-adapted beef bulls in northern Australia. Reproduction in Domestic Animals 47 (suppl. 4), 5191902.Google Scholar
Norman, S, Bertram, J and McGowan, M 2008. B.AWW.0187 Prevalence of selected abnormalities in polled and horned bulls which affect breeding soundness. Meat Livestock Australia, Sydney, Australia.Google Scholar
O’Shaughnessy, PJ and Fowler, PA 2014. Development of the human fetal testis. Annales d’Endocrinologie 75, 4853.Google Scholar
Padula, AM 2005. The freemartin syndrome: an update. Animal Reproduction Science 87, 93109.Google Scholar
Persson, Y, Söderquist, L and Ekman, S 2007. Joint disorder; a contributory cause to reproductive failure in beef bulls? Acta Veterinaria Scandinavica 49, 3138.Google Scholar
Price, EO and Wallach, SJR 1991. Development of sexual and aggressive behaviours in Hereford bulls. Journal Animal Science 69, 10191027.CrossRefGoogle ScholarPubMed
Rahmoun, M, Lavery, R, Laurent-Chaballier, S, Bellora, N, Phillip, GK, Symon, A, Pailhoux, E, Cammas, F, Chung, J, Bageri-Fam, S, Murphy, M, Bardwell, V, Zarkower, D, Boizet-Bonhoure, B, Clair, P, Harley, VR and Poulat, F 2017. In the mammalian foetal testis, Sox9 regulates expression of its target genes by binding to genomic regions with conserved signatures. Nucleic Acid Research 45, 71917211.Google Scholar
Rawlings, N, Evans, ACO, Chandolia, RK and Bagu, ET 2008. Sexual maturation in the bull. Reproduction Domestic Animals 43 (suppl. 2), 295301.CrossRefGoogle ScholarPubMed
Reijo Pera, RA and Prezzoto, L 2016. Species specific variation among mammals. Current Topics Developmental Biology 120, 401420.Google Scholar
Rejduch, B, Słota, E and Gustavsson, I 2000. 60,XY/60,XX chimerism in the germ cell line of mature bulls born in heterosexual twinning. Theriogenology 54, 621627.Google Scholar
Recabarren, SE, Rojas-Garcia, PP, Recabarren, MP, Alfaro, VH, Smith, R, Padmanabhan, V and Sir-Peterman, T 2008. Prenatal testosterone excess reduces sperm count and motility. Endocrinology 149, 64446448.Google Scholar
Rojas-Garcia, PP, Recabarren, MP, Sir-Petermann, T, Rey, R, Palma, S, Carrasco, A et al 2013. Altered testicular development as a consequence of increase number of Sertoli cell in male lambs exposed prenatally to excess testosterone. Endocrine 43, 705713.CrossRefGoogle ScholarPubMed
Ross, DGF, Bowles, J, Hope, M, Lehnert, SL and Koopman, P 2009. Profiles of gonadal gene expression in the developing bovine embryo. Sexual Development 3, 273283.Google Scholar
Saunders, PJ and Ladds, PW 1978. Congenital and developmental anomalies of the genitalia of slaughtered bulls. Australian Veterinary Journal 54, 1013.Google Scholar
Soleymani, B, Hafezian, SH, Mianji, GR, Mansouri, K, Chaharaein, B, Tjehmiri, A, Shanrifi Tabar, M and Mostafie, A 2017. Bovine sex determining region Y: cloning, optimised expression and purification. Animal Biotechnology 28, 4452.Google Scholar
Sinowatz, F and Amselgruber, W 1986. Postnatal development of bovine Sertoli cells. Anatomy and Embryology 174, 413423.Google Scholar
St.Jean, G, Gaughan, EM and Constable, PD 1992. Cryptorchidism in North American cattle: breed predisposition and clinical findings. Theriogenology 38, 951958.Google Scholar
Sullivan, TM, Micke, GC, Greer, RM and Perry, VE 2010. Dietary manipulation of Bos indicus x heifers during gestation affects the prepubertal reproductive development of their bull calves. Animal Reproduction Science 118, 163170.Google Scholar
Tarbashevich, K and Raz, E 2010. The nuts and bolts of germ-cell migration. Current Opinion in Cell Biology 22, 715721.Google Scholar
Ventura-Junca, P, Irarrazaval, I, Rolle, AJ, Gutierrez, JI, Moreno, RD and Santos, MJ 2015. In vitro fertilization in mammals: epigenetic and developmental alterations. Scientific and bioethical implications for IVF in humans. Biological Research 18, 4868.Google Scholar
Vigier, B, Prépin, J and Jost, A 1976. Chronology of development of the genital tract of the calf fetus. Archives Danatomie Microscopique et de Morphologie Experimentale 65, 77101.Google ScholarPubMed
Walker, DF 1964. Deviations of the bovine penis. Journal American Veterinary Medical Association 145, 677682.Google Scholar
Wen, Q, Wang, Y, Tang, J, Cheng, CY and Liu, YX 2016. Sertoli cell WT-1 regulates peritubular myoid cell and fetal Leydig cell differentiation during fetal testis development. PLoS One 30, 11.Google Scholar
Williams, HJ, Revell, SG, Scholes, SF, Courtenay, AE and Smith, RF 2010. Clinical, ultrasonographic and pathological findings in a bull with segmental aplasia of the mesonephric duct. Reproduction in Domestic Animals 45, e212e216.Google Scholar
Wolf, F, Almquist, J and Hale, E 1965. Prepuberal behavior and puberal characteristics of beef bulls on high nutrient allowance. Journal Animal Science 24, 761765.Google Scholar
World Health Organization 2012. Possible developmental early effects of endocrine disrupters on child health. WHO Document Production Services, Geneva, Switzerland.Google Scholar
Wrobel, K 1990. The postnatal development of the bovine Leydig cell population. Reproduction Domestic Animals 25, 5160.Google Scholar