Anatomy and embryology of male and female reproductive systems


Embryology of the male and female reproductive systems

Embryonic sexual differentiation is a very delicate process ( Fig. 1.1 ) that starts with the genotypic determination at the time of fertilization (i.e., XY or XX) and then concludes in a manner that depends on how the gametes influence the phenotype (i.e., culminating in final pubertal and brain development events). It is worth noting that most information—especially information pertaining to genetics—have been derived from mouse models since studies on human tissues are few in number and also since it has been pointed out that the developmental stages and global gene expression of both species are comparable [i.e., few exceptions exist like how SOX2 (sex-determining region Y-box 2) and SOX17 are two different transcription factors utilized by the primordial germ cells (PGCs) of the mouse and human species, respectively]. Sex determination has long been thought to have a predetermined default path toward a final female phenotype in the absence of the influence of the male pathway steering factors; however, recent data indicate that not only does the alternative sex development pathway need continuous active repression during the embryonic life but also that it might need to remain actively repressed for life. Table 1.1 outlines the possible genetic errors that can disrupt such a delicate process at different stages.

Fig. 1.1, Sexual differentiation timetable and the genetic determinants needed for the development of primordial gonads and tracts. Sexual differentiation timetable (A) and the genetic determinants needed for the development of primordial gonads and tracts (B). Dax1 , dosage-sensitive sex reversal, adrenal hypoplasia critical region, on chromosome X, gene 1; Emx2 , empty spiracles homeobox 2; Gata4 , GATA-binding protein 4; Lhx1 or 9 , homeobox protein Lim-1 or 9; Pax2 or 8 , paired box 2 or 8; Sf1 , steroidogenic factor-1; Wnt4 , wingless-type MMTV integration site member 4; Wt1 , Wilms’ tumor 1.

Table 1.1
Genetic factors with possible roles in sexual determination or differentiation.
Reproduced with permission from Arboleda VA, Quigley CA, Vilain E. Chapter 118—Genetic basis of gonadal and genital development. In: Jameson JL, De Groot LJ, de Kretser DM, et al., eds. Endocrinology: Adult and Pediatric . 7th ed. Philadelphia: Elsevier Saunders; 2016:2051–2085.e7 [Table 118-1].
Gene name or pseudonyms Human gene locus Protein name Protein type Genetic or cellular targets of factors Action of factors Effects of overexpression or underexpression of gene
Factors involved in both ovary and testis sex determinations
SF1*
NR5A1
FTZF1
Ad4BP
9q33 SF1 Orphan nuclear receptor/zinc finger transcription factor WT1, SRY, SOX9, DAX1, GNRHR, LHβ, ACTHR, AMH, AMHR, STAR, CYP11A1, CYP21A2, CYP11B1, OXT, and others Activates transcription of many genes in the development of gonads, adrenal glands; regulates steroidogenesis; synergizes with WT1; antagonizes; DAXi. Dose-dependent activity. KO mice (XX and XY): no gonads or adrenals; retained Müllerian structures; abnormal hypothalamus. Haploinsufficient mice: reduced but not absent adrenal function
Homozygous human mutation: 46,XY sex reversal and adrenal hypoplasia
Heterozygous human mutation: 46,XX normal ovary, partial adrenal insufficiency
WT1* 11p13 WT1 Zinc finger transcription factor; tumor repressor DAX1, AMH, SRY, IGF2I, IGF1R, PDGFA, PAX2 Represses transcription; activates transcription of SRY; dose-dependent effects XY homozygous deletion of WT1 + KTS isoform: male-to-female sex reversal; XY homozygous deletion of WT1 + KTS isoform: streak gonads in XX and XY. Human Denys–Drash syndrome: gonadal dysgenesis, congenital nephropathy, Wilms’ tumor
GATA4* 8p23.1-p22 GATA4 Zinc finger transcription factor “GATA” DNA motif; AMH; genes encoding steroidogenic enzymes Expressed early in both ovary and testis; interacts with FOG2 KO mice: embryonic lethal, no gonadal phenotype reported. Most human mutations cause isolated cardiac defects. Rare cases are reported with both cardiac defects and 46,XY gonadal dysgenesis
CBX2* 17q25.3 CBX2 Transcription repressor Possibly SRY Mediates changes in chromatin structure KO mice (XX or XY) have retarded development of gonadal ridges; XY mice have male-to-female sex reversal. Compound heterozygous mutations cause 46,XY gonadal dysgenesis
Factors involved in testis sex determination
SRY* Yp11.3 SRY HMG-box-containing transcription factor SF1, SOX9, CYP19A1, AMH Bends DNA; may antagonize SOX3 XX mice expressing transgenic Sry, female-to-male sex reversal. Human SRY mutations: 46,XY sex reversal, gonadal dysgenesis
Translocation of SRY to X chromosome: 46,XX female-to-male sex reversal or ovotesticular disorder of sex development
SOX9* 17q24-q25 SOX9 HMG-box-containing transcription factor of SRY family Supporting cells of gonadal primordium; WNT4, FGF9 Simulates differentiation of Sertoli cells; dosage-sensitive effects Odsex mice: derepression of Sox9 expression in XX gonads → testis development; Human mutation: 46,XY sex reversal; gene duplication or deletion in coding and/or noncoding regions results in 46,XX or 46,XY DSD
ATRX*
XH2
Xq13.1–q21.1 ATRX Helicase; transcription factor Widespread expression early in mouse embryogenesis, more restricted expression later Gene regulation at interphase and chromosomal segregation at mitosis Human mutations: α-thalassemia, mental retardation, genital anomalies → male-to-female sex reversal in 46,XY
DHH* 12q13.1 DHH Signaling molecule Expressed only in testis Involved in interactions between Sertoli cells and germ cells. May regulate mitosis and meiosis in male germ cells Strain-specific effects: XY null mice have defective Leydig cell development and are feminized. Human mutations cause 46,XY gonadal dysgenesis with peripheral neuropathy
FGF9 13q11–q12 FGF9 Growth factor SOX9 Promotes Sertoli cell differentiation and germ cell survival KO mice: XY sex reversal
LHCGR* 2p21 LH/CG receptor G-protein-coupled, seven-transmembrane-peptide hormone receptor Not applicable Transduces LH signal to activate G → cAMP. Required for Leydig cell testosterone production Human mutation: Leydig cell hypoplasia → male hypovirilization; mouse: normal sex differentiation
Males and females infertile
STAR* 8p11.2 STAR Mitochondrial transport protein Not applicable Transports cholesterol to inner mitochondrial membrane Human mutation: congenital lipoid adrenal hyperplasia; 46,XY undervirilization
SRD5A2* 2p23 5α-Reductase 2 Mitochondrial enzyme Not applicable Converts testosterone → DHT 5α-Reductase deficiency; 46,XY undervirilization
AR* Xq11.2–q12 AR Ligand-dependent nuclear receptor AMHR, CYP19 Regulates transcription XY mice: undervirilization of internal and external genitalia; 46,XY human mutation: androgen insensitivity syndrome
AMH* 19p13.3 AMH Glycoprotein homodimer of TGF-β family Mesenchymal and epithelial cells of Müllerian ducts Ligand for AMHR; stimulates apoptosis of Müllerian duct 46,XY human mutation: Persistent Müllerian duct syndrome
AMHR2* 12q13 Type II AMH receptor (AMHR2) Transmembrane serine/threonine kinase receptor Mesenchymal and epithelial cells of Müllerian ducts Receptor for AMH; stimulates apoptosis of Müllerian duct Persistent Müllerian duct syndrome
Factors involved in ovary/female sex determination
RSPO1* 1p34 RSPO1 Thrombospondin-like secreted activator of β-catenin WNT4, CTNNB1 Expressed in testis, ovary, adrenals, thyroid, trachea, kidney, skin
Controls expression of CTNNB1 (gene for β-catenin) in developing ovary
Mouse: XX null show partial female-to-male sex reversal, with the development of seminiferous tubules; Human: 46,XY sex reversal and palmoplantar keratosis
WNT4* 1p36.23–p35.1 WNT4 Cysteine-rich signaling molecule/secreted growth factor Mesonephric mesenchyme Directs initial Müllerian duct formation in both sexes; “antitestis” factor in ovarian development XX and XY null mice: Müllerian duct agenesis. Overexpression in XY: male-to-female sex reversal. Human 46,XY: duplication of WNT4 associated with male-to-female sex reversal
FOXL2* 3q23 FOXL2 Transcription factor Not reported Expressed predominantly in ovary; earliest known marker of ovarian differentiation in mammals Goat: deletion associated with XX sex reversal. Human mutation: 46,XX gonadal dysgenesis
HOXA13* 7p15–p14 HOXA13 Homeodomain transcription factor FGF8, BMP7 Involved in epithelial–mesenchymal interactions required for morphogenesis of terminal gut and urogenital tract, including Müllerian structures Mouse: XX null have hypoplasia of cervix and vagina. 46,XX human mutation: hand–foot–genital syndrome with uterine malformation
Factors with possible roles in either or both sexes
DAX1*
NR0B1
AHCH
Xp21.3–p21.2 DAX1
NROB1
Orphan nuclear receptor transcription factor RAR, RXR, STAR, CYP17A1, HSD3B2 Represses SF1 transcription; antagonizes SF1; regulates testis cord organization. Presents premature cell differentiation
Dose-dependent effects
Strain-specific defects in XY mice: overexpression → testis maldevelopment and sex reversal; homozygous deletion → adrenal hypoplasia, normal testes. Human mutations: adrenal hypoplasia congenita, hypothalamic hypogonadism
WNT7A 3p25 WNT7A Signaling molecule Mesenchymal and epithelial cells of Müllerian ducts XY: involved in Müllerian duct regression; XX: stimulates the development of Müllerian duct Male mice with homozygous deficiency of Wnt7a have retained Müllerian ducts; female Wnt7a-deficient mice have defective, though not absent, development of oviducts and uterus
DMRT1/2* 9p24.3 DMRT1
DMRT2
DM-domain transcription factors Expressed only in genital ridge
Dose-dependent effect on postnatal testis development
XY null mice have normal prenatal testis development but abnormal postnatal testis differentiation. Human monosomy 9p: 46,XY testis maldevelopment; 46,XX primary hypogonadism
KO , knockout; NR , not reported. *Means the gene has reported mutations in humans. Many genes listed have mutations that were reported only in mice.

Germ cell specification

Three weeks after fertilization, from the proximal epiblast-derived mesodermal portion located near the extraembryonic endoderm—at the posterior part of the primitive streak—arises a group of cells (i.e., at least six in number) that display unique qualities from their surrounding tissues (i.e., larger size, clearer cytoplasm, and fewer organelles) and will later carry on their role as the PGCs. This process has been termed “specification” and is influenced by a number of factors—that belong to the transforming growth factor-β ( TGF-β ) superfamily—produced by extraembryonic ectoderm although the cascade response of the cells depends on the expression of other factors like the wingless-type MMTV integration site member 3 ( WNT3 ) (i.e., in this case to specifically respond to the bone morphogenetic proteins ( BMP ) of the TGF-β family). Genes like PR-domain containing-1 (i.e., Prdm1 or Blimp1 as previously called), Prdm14 , and transcription factor AP-2 gamma ( Tfap2c ) are downstream activation targets that should be properly expressed for a successful specification to take place since—for example— Prdm1 prevents the expression of genes that can pull the germ cell toward the somatic cell-line development. Rodriguez and colleagues provide an excellent discussion of growth factor and genes related to sex differentiation and development that can be found in their published work.

Germ cell migration and the concurrent genital ridge development ( Fig. 1.2 )

For the next 1–2 weeks post specification, PGCs acquire changes in their morphology (i.e., pseudopodia) in order to carry out active amoeboid movement and successfully migrate to the hindgut and then to the genital ridge (i.e., and into the developing sex cords). Their path goes through the dorsal mesentery and the journey seems to require the influence of various genes (i.e., homeobox protein Lim-1 ( LHX1 or Lim1 ) for proper hindgut localization and WNT family member 5A ( WNT5A ) for the PGCs to receive a proper migration cue; the mutation of the latter can partly explain findings in Robinow syndrome), the action of ligand/receptor pathways (i.e., stromal cell-derived factor 1 (Sdf1 or C–X–C motif chemokine 12 (CXCL12)/CXC receptor 4 (CXCR4) pathway), an optimum collagen-I deposition in the extracellular matrix (i.e., induced by TGF-β through the activin receptor-like kinase 5 (alk5)), and the help of autonomic nerve fibers migrating along with them to the same destination.

Fig. 1.2, Gonadal embryogenesis and anatomical relationships. Gonadal embryology (A) and the anatomical relationships during embryogenesis (B).

The development of the genital ridge commences and proceeds in conjunction with the migration. The urogenital ridge arises as a dorsal body wall thickening that harbors populations from both the primitive mesoderm and the coelomic epithelium (viz., adrenogenital primordium). The central portion—the mesonephros—of the urogenital ridge gives rise to the gonadal ridge along its ventromedial surface—which starts bulging after germ cells infiltrate it to form the primordial indifferent gonad by the end of the 5th week of intrauterine life. Certain gene mutations can affect the development of genital ridge (i.e., and consequently risk the lack of the development of the gonads themselves in addition to some malfunctions in the adrenal and renal systems) and they include Wilms’ tumor 1 ( Wt1 ), steroidogenic factor-1 ( SF1 ), Lhx1 , Lhx9 , empty spiracles homeobox 2 ( Emx2 ), and GATA-binding protein 4 ( GATA4 ).

The indifferent stage, the bipotential gonad, and the gonadal differentiation

Sustainment of the morphological development of the gonads requires the presence and the influence of germ cells only in the case of the ovary (i.e., normal testicular development continues in their absence) ; however, both the cortex and the medulla of the indifferent gonads change according to the genotype of the fetus (i.e., cortex develop and medulla regresses in the case of the XX genotype and the medullary sex cords proliferate toward seminiferous tubules formation in the case of the XY genotype). Interestingly, PGCs differentiate into male or female gametes according to the cellular environment they are placed in. For instance, female genotypic PGCs become spermatogonia when they are placed in gonads with testicular somatic cell environment (i.e., of Sertoli cell lineage) while those migrating to aberrant locations give rise to oogonia—that degenerate afterward—irrespective of their sexual genotype (i.e., though rarely they form teratomas in certain locations as the mediastinum). Assumptions about the sexual identity of the gonad grow stronger as intrauterine life progresses over the weeks depending on a number of clues—which when working toward an assumption of the presence of an ovary—that include the following: lack of testicular development beyond the 7th week; the presence of oogonial meiosis around the time of the 8th week; and visualization of primordial follicles by the 16th week.

Gonadal differentiation seems to rely on intricate genetic interactions between multiple upstream and downstream factors ( Fig. 1.3 ), many of which are yet to be fully elucidated. The long-held belief that the female differentiation pathway is the default one in the absence of male factors’ influences has recently started to be challenged. Consequently, for example, and in the case of female gonad determination and the hypotheses behind it, two possibilities are now entertained for the directions factor takes to achieve the determination: repression of somatic testis-inducing genes in addition to the activation of ovary stimulating ones as one possibility; downregulation of the same male genes while removing the repression on ovary stimulating ones as an alternate possibility. It is worthy of note that no definite hypothetical model has been adopted yet even when the knowledge about possible factors keeps-on expanding.

Fig. 1.3, Hypothetical models of gonadal determination. Hypothetical model of signal balance during initial sex determination in the undifferentiated gonad (A), testis determination (B), and ovary determination (C). Arrows denote stimulatory actions while blunt-ended pointers in (B) denote inhibitory actions.

At about the 7th week and under the influence of the autosomal gene SRY (sex-determining region Y)-box 9 ( SOX9 ) (i.e., which gets inhibited mainly by β-catenin or catenin beta-1 gene ( CTNNB1 ) in the case of ovary determination pathway and is upregulated by the SRY gene), Sertoli cells differentiate, proliferate, and surround the arriving PGCs to form primitive sex cords while protecting the PGCs from entering meiosis prematurely (i.e., protection is vital for commitment to spermatogenesis and is mediated by degrading retinoic acid—and possibly other products—by the cytochrome p450 enzyme (Cyp26b1); mitotic arrest continues until puberty). Sertoli cells promote differentiation of peritubular myoid cells and—by the 8th week—Leydig cells (i.e., both arising from primitive interstitial cells) by secreting anti-Müllerian hormone (AMH) as a paracrine factor. SRY and other factors (i.e., transmembrane ligand ephrin-B2) influence to proper vascularization of the testes—which is characterized by early distinct arterial specification and is necessary for further transportation of testicular hormones. From the second trimester thereafter, Sertoli cells double in number fortnightly (i.e., coupled by a parallel increase in numbers of germ and Leydig cells) resulting in a rapid increase in testicular sizes. It is evident that Y-chromosome genes are necessary to maintain spermatogenesis while having extra X-chromosomes (i.e., as is the case with Klinefelter’s syndrome) can result in compromised testicular development and size.

An alternate developmental path is generally followed in the case of the ovary and differs from that of the testis in the following points:

  • Failure of migration of PGCs results in a degenerated fibrous streak being formed (i.e., Turner syndrome). After their successful arrival and infiltration of the secondary cortical sex cords, the medulla starts to regress and the ovaries start to become distinguishable by the 6–8th weeks. PGCs undergo vigorous mitotic duplication during that time (i.e., reaching 600,000 in number as oogonia by the 8th week); subsequently, meiosis (i.e., which is facilitated by the action of retinoic acid and possibly nonretinoic acid factors), oogonial atresia, and the ongoing mitosis regulate their number until they reach a peak of at least 6 million cells by mid-gestation—at the time of formation of the first primordial follicle and breakdown of oocyte cell nests—and then decline afterward (i.e., cells entering meiosis freeze their progress at the meiosis-I phase by the 17th week to resume meiosis later in puberty). By the 7th month, mitosis is terminated and oogonial atresia is replaced by follicular atresia which withers their number to only 700,000 primordial follicles at birth (i.e., and 300,000 by the time of puberty). Fig. 1.4 provides more details about oogenesis throughout the intrauterine period.

    Fig. 1.4, Intrauterine fetal oogenesis timeline.

  • Pregranulosa cells lack SRY expression that allows SOX9 to be antagonized properly and—thus—the commitment to granulosa cell lineage can occur under the influence of the WNT4/β-catenin pathway.

  • The forkhead box 2 ( Foxl2 ) gene maintains such differentiation by continuous suppression of SOX9 .

  • Nuclear receptor subfamily 0 group B member 1 ( NR0B1 ) gene (formerly called dosage-sensitive sex reversal, adrenal hypoplasia critical region, on chromosome X, gene 1 ( DAX1 )) is a dosage-sensitive gene that needs two copies to antagonize SOX9 and SF1 . Conversely, as suggested by its formal name, the absence of NR0B1 gene (i.e., low dose) can potentially result in testicular dysgenesis.

  • Theca cells are the Leydig cells’ female counterparts and developed from the interstitial cells under the influence of WNT4 and Foxl2 genes and in the absence of the effect of high levels of testosterone.

  • Vascularization of the ovary follows the classic angiogenic route rather than recruiting endothelial cells by breaking down mesonephric vessels.

Gonadal relocation and descent ( Fig. 1.5 )

Testicular migration—and descent—begins around the 12th week of intrauterine life, goes through two major phases (viz., transabdominal and inguinoscrotal phases), and ends with the successful intra-scrotal positioning by the 32nd gestational week. In addition to the increase in the intraabdominal pressure and the passive change in position that occurs as a result of elongation of the trunk and enlargement of the pelvis (i.e., both phenomena are common to both sexes), the descent is aided in males by the secretory products of Leydig cells (including testosterone and insulin-like factor 3 (Insl3) and anti-Müllerian hormone (AMH)) that result—first—in the simultaneous regression of the craniosuspensory ligament and differentiation of the gubernaculum (i.e., to develop muscular tissue) and then the contraction of the latter to guide the testes through the inguinal canal (i.e., that contracts around the spermatic cord afterward preventing inguinal hernia) and into the scrotum—a process that the genitofemoral nerve is hypothesized to mediate through the action of calcitonin gene-related peptide (CGRP). Mutations in the INSL3 gene or its receptor gene (viz., relaxin/insulin-like family peptide receptor 2 [ RXFP2 ], aka leucine-rich repeat-containing G protein-coupled receptor 8 [ LGR8 ] or G protein-coupled receptor affecting testis descent [ GREAT ]), deficient Insl3 production, or fetal androgen insufficiency/resistance are associated with cryptorchidism in humans.

Fig. 1.5, Fetal testicular descent. Figure outlines testicular descent steps during the intrauterine life. (A) During the 2nd gestational month. (B) During the 3rd month. (C) During the 7th month. (D) At term.

In females, the craniosuspensory ligament remains intact (i.e., which later gives rise to the ovarian suspensory ligament) while the gubernaculum remains undifferentiated (i.e., which later gives rise to the round ligament of the ovary [superior part] and that of the uterus [inferior part] which is anchored to both labia majora). Therefore, the ovaries only undergo a caudal shift to become positioned lateral to the kidneys.

Sexual duct differentiation ( Fig. 1.6 )

At week 4 of gestation, the indifferent stage of sexual duct differentiation begins as the mesonephric duct (aka Wolffian duct) forms from the lateral nephrotomes (i.e., intermediate mesoderm segments), followed 2 weeks later by the emergence of the paramesonephric duct (aka Müllerian duct) as an invagination of the urogenital ridge’s surface epithelium. After another 2 weeks, the testosterone secreted by the Leydig cells induces the differentiation of the Wolffian ducts into the epididymides (cranial segment), vasa deferentia, and seminal vesicles (lower segment) over the succeeding 4 weeks (i.e., dihydrotestosterone (DHT) does not influence the process as evident from the lack of 5α-reductase 2 enzyme expression in Wolffian ducts during differentiation). A simultaneous process of defeminization takes place where the Müllerian ducts regress under the effect of the AMH to completely disappear by the 11th week (i.e., AMH—or Müllerian inhibitory substance (MIS)—produced by Sertoli cells and the mechanism is mainly an apoptotic one). Both hormones might be primarily acting in a paracrine manner since unilateral testicular absence leads to ipsilateral persistence of the Müllerian structures and residual development of Wolffian ones ; inactivating mutations of AMH gene or AMH type II receptor defects can also negatively impact the functions of AMH (i.e., persistent Müllerian duct syndrome (PMDS) while overexpression in females leads to blind vagina and the absence of oviducts. Conversely in normal 46,XX females, the absence of the AMH allows the Müllerian ducts to continue their differentiation into fallopian tubes (cranial portions), uterus, cervix, and the upper third of the vagina (i.e., the lower portion originates from the urogenital sinus) while the absence of the testosterone prevents the differentiation of the Wolffian ducts (i.e., thus only nonfunctioning remnants can persist).

Fig. 1.6, Embryologic sexual duct differentiation. Indifferent internal genitalia ( top ). Female differentiation ( bottom left ). Male differentiation ( bottom right ). Dotted lines represent obliterated structures.

Some genetic defects can potentially result in the complete absence of reproductive tracts including the null mutation of Emx2 , Lim-1 , and paired box 2 ( Pax2 ) genes; WNT4 and WNT7A mutations are accompanied with the masculinization of reproductive tracts in females in the case of the former and with Müllerian regression failure in males (causing obstructive sterility)—and Müllerian defective differentiation in females—in the case of the latter. Homeobox-containing genes ( HOX ) are very important in the specification of various male and female tract parts and are expressed from top downward with increasing numbering (i.e., Hoxd10–13 or its Hoxa paralogues) such that mutations of—for example— Hoxa10 leads to the transformation of the cranial uterine part into a fallopian tube in females and ductus deferens to epididymis in males. In humans, HOXA13 mutation leads to the hand–foot–genital syndrome (aka Guttmacher syndrome) where there are Müllerian defects in females and hypospadias in males (i.e., in addition to limb abnormalities).

External genitalia and other accessory glands differentiation

The external genitalia of both sexes develop indifferently until the 8th week of gestation (i.e., the start of testosterone secretion); before then, an initial elevation called the genital tubercle is formed—at the cloacal membrane’s cranial end and possibly guided by fibroblast growth factor 8 ( Fgf8 ) gene—by the 4th week (i.e., primordial penis or clitoris), and then the urethral (medial) and labioscrotal (lateral) folds (i.e., primordial labia minora/penile foreskin and labia majora/scrotum, respectively) flank the urogenital groove by the 6th week and the indifferent stage appears largely hormonal-independent.

The presence of DHT (i.e., converted by the action of 5α-reductase enzyme on testosterone) and its action on androgen receptor (AR) in the target tissues (i.e., external genitalia and some accessory glands like the prostate) is the deciding factor for masculinization of them (i.e., in the case of deficiency of DHT—or in the case of resistance like in androgen insensitivity syndrome—the external genitalia develop down the female pathway). By the 12th week of gestation, those going down the path of masculinization complete the process of male sexual differentiation of the external genitalia (i.e., genital tubercle elongation as penis, urethral folds ventral fusion as penile urethra, and labioscrotal folds midline fusion as scrotum) and the prostate (i.e., develops from the urogenital sinus after the vesicovaginal septum formation is inhibited)—penile enlargement, however, continues further in the third trimester (i.e., which seems quite incomplete in cases of fetal hypopituitarism—or luteinizing hormone receptor β (LHβ) mutations—since the androgen production is less dependent on the maternal chorionic gonadotropin (CG) stimulation in the third trimester) and the whole penile enlargement appears to be under the regulation of HOX , FGF , and Sonic hedgehog ( Shh ) genes. In the absence of proper androgen stimulation (i.e., female, androgen deficiency, or androgen resistance), the external genitalia continue down the female pathway and also complete the differentiation by the 12th week as follows: genital tubercle slightly enlarges as clitoris, urogenital sinus remains open, vesicovaginal septum forms, urethral folds become labia minora, and labioscrotal folds become labia majora (i.e., minor labial fusions lead to the formation of mons pubis (anteriorly) and posterior commissure (posteriorly)). Urethral and urogenital sinus outgrowths produce urethral/para-urethral glands and great vestibular glands, respectively. Table 1.2 illustrates homologous parts of the urogenital system of both genders.

Table 1.2
homologous parts of the urogenital system of both genders.
Reproduced with permission from Carlson BM. Chapter 16: Urogenital system. Part II: development of the body systems. In: Carlson BM, ed. Human Embryology and Developmental Biology . 5th ed. Philadelphia: Elsevier Saunders; 2014:376–407 [Table 16.2].
Indifferent structure Male derivative Female derivative
Genital ridge Testis Ovary
Primordial germ cells Spermatozoa Ova
Sex cords Seminiferous tubules (Sertoli cells) Follicular (granulosa) cells
Mesonephric tubules Efferent ductules Oöphoron
Paradidymis Paroöphoron
Mesonephric (Wolffian) ducts Appendix of epididymis Appendix of ovary
Epididymal duct Gartner’s duct
Ductus deferens
Ejaculatory duct
Seminal vesicles
Mesonephric ligaments Gubernaculum testis Round ligament of ovary
Round ligament of uterus
Paramesonephric (Müllerian) ducts Appendix of testis Uterine tubes
Prostate utricle Uterus
Upper vagina
Definitive urogenital sinus (lower part) Penile urethra Lower vagina
Bulbourethral glands Vaginal vestibule
Early urogenital sinus (upper part) Urinary bladder Urinary bladder
Prostatic urethra Urethra
Prostate gland Glands of Skene
Genital tubercle Penis Clitoris
Genital folds Floor of penile urethra Labia minora
Genital swellings Scrotum Labia majora

Anatomy of the male reproductive system

The male reproductive system is anatomically divided into internal and external genitalia. The internal genitalia include the gonads (testes), the spermatic cords, and the accessory organs and glands while the external genitalia constitute a penis and a scrotum.

The role of the male genital system ensures the production of enough viable male gametes, their successful transportation, and the regulated secretion of male sex hormones in a manner that leads to acceptable sexual desire and potency.

Testes and spermatogenesis

The male gonads (testes) are the most important component of the male reproductive system since it is the sole source of the gametes and the main source of male sex hormone (testosterone). As per the currently available literature, each testis is an oval-shaped firm organ with measurements ranging from 3.7 to 5.1 cm in terms of length, 2 to 3.1 cm in terms of width, and 3 to 5.2 cm in the anteroposterior diameter; measurements determined clinically are useful for estimating volume (i.e., by incorporating them in equations) and can be used as cutoffs to help diagnose certain syndromes (i.e., < 3.5 cm longest diameter Klinefelter’s syndrome ). Additionally, each normally possesses a weight that ranges from 12 to 26 g and a volume that ranges from 14.8 to 28 mL (i.e., clinically or a US measured range of 10–17 mL ).

For spermatogenesis to proceed properly, the temperature of the testes has to be held at a level 3–4°C lower than the cores and this is normally facilitated by several factors: their position in the scrotum outside the body (i.e., which is continuously corrected by the cremasteric muscle according to testicular and scrotal temperatures), the special characteristics of the scrotal skin (see later), and the pampiniform venous plexus maintained countercurrent exchange mechanism (i.e., by surrounding the testicular artery with their colder blood). Conditions that increase such temperature result in impaired spermatogenesis (i.e., cryptorchidism and frequent hot baths; the latter can cause a temporary effect with a recovery of at least 3 months).

The testes usually lie obliquely suspended by the spermatic cords in the scrotum and buried inside three layers of coverings (i.e., ordered from outside inward): a peritoneum-like tunica vaginalis (i.e., covering all but the testicular posterior aspect; it’s the extension of the processus vaginalis whose incomplete closure predisposes to indirect inguinal hernia and hydroceles), the fibrous tunica albuginea, (i.e., which creates the mediastinum testis) and the vascular tunica vasculosa (i.e., which is in-line with all surfaces of the testis and tunica albuginea’s septations going into it). Fig. 1.7 provides an illustration of the testes and their surrounding relationships.

Fig. 1.7, Cross-sectional illustration of the testis and its surrounding structures.

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