Reproductive Systems PDF

Summary

This document discusses the male and female reproductive systems, including their organs, functions, and processes like spermatogenesis. It also details the supporting structures and functions of the male reproductive system and mentions the specialized branches of medicine concerned with these systems, such as gynecology and andrology.

Full Transcript

The Reproductive
Systems
The reproductive systems and homeostasis
The male and female reproductive organs work together to produce offspring. In addition, the
female reproductive organs contribute to sustaining the growth of embryos and fetuses.

Sexual reproduction is the process by which organisms produce offspring by making germ cells called gametes (GAM-ēts ⫽
spouses). After the male gamete (sperm cell) unites with the female gamete (secondary oocyte)—an event called fertilization
ˉ -shun)—the resulting cell contains one set of chromosomes from each parent. Males and females have
(fer⬘-til-i-ZA
anatomically distinct reproductive organs that are adapted for producing gametes, facilitating fertilization, and, in females,
sustaining the growth of the embryo and fetus.

The male and female reproductive organs can be grouped by function. The gonads—testes in males and ovaries in females—
produce gametes and secrete sex hormones. Various ducts then store and transport the gametes, and accessory sex glands
produce substances that protect the gametes and facilitate their movement. Finally, supporting structures, such as the penis in
males and the uterus in females, assist the delivery of gametes, and the uterus is also the site for the growth of the embryo and
during
fetus du pregnancy.
uring pregn

ynecolog (gı̄-ne-KOL-oˉ-jē; gyneco- ⫽ woman; -logy ⫽ study of) is the
Gynecology
G
specialized branch of medicine concerned with the diagnosis and
special
treatment of diseases of the female reproductive system. As noted in
treat
Chapter 26, urology (uˉ-ROL-oˉ-jē) is the study of the urinary system.
Ch
Urologists also diagnose and treat diseases and disorders of the
U
male reproductive system. The branch of medicine that deals with
male disorders, especially infertility and sexual dysfunction, is
called andrology (an-DROL-oˉ-jē; andro- ⫽ masculine).
m
sco
ew /N
ide
ldw
or
W
n

io
ct
n ne
o
kC
Stoc
s ge
BAO-
Ima
Did you ever wonder how breast augmentation
D
and breast reduction are performed

1041
1042 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

28.1 Male Reproductive System Scrotum
OBJECTIVES
The scrotum (SKRŌ-tum ⫽ bag), the supporting structure for
Describe the location, structure, and functions of the the testes, consists of loose skin and underlying subcutaneous
organs of the male reproductive system. layer that hangs from the root (attached portion) of the penis
Discuss the process of spermatogenesis in the testes. (Figure 28.1a). Externally, the scrotum looks like a single
pouch of skin separated into lateral portions by a median ridge
The organs of the male reproductive system include the testes, called the raphe (RAˉ-fē ⫽ seam). Internally, the scrotal sep-
a system of ducts (epididymis, ductus deferens, ejaculatory tum divides the scrotum into two sacs, each containing a single
ducts, and urethra), accessory sex glands (seminal vesicles, testis (Figure 28.2). The septum is made up of a subcutaneous
prostate, and bulbourethral glands), and several supporting layer and muscle tissue called the dartos muscle (DAR-toˉs ⫽
structures, including the scrotum and the penis (Figure 28.1). skinned), which is composed of bundles of smooth muscle fibers.
The testes (male gonads) produce sperm and secrete hormones. The dartos muscle is also found in the subcutaneous layer of the
The duct system transports and stores sperm, assists in their scrotum. Associated with each testis in the scrotum is the cre-
maturation, and conveys them to the exterior. Semen contains master muscle (krē-MAS-ter ⫽ suspender), a series of small
sperm plus the secretions provided by the accessory sex glands. bands of skeletal muscle that descend as an extension of the
The supporting structures have various functions. The penis de- internal oblique muscle through the spermatic cord to surround
livers sperm into the female reproductive tract and the scrotum the testes.
supports the testes.

FUN CTI ON S OF THE MA LE RE PRO DU CTIVE SYSTEM
Figure 28.1 Male organs of reproduction and surrounding structures.
1. The testes produce sperm and the male sex hormone testosterone.
Reproductive organs are adapted for producing new individuals 2. The ducts transport, store, and assist in maturation of sperm.
and passing on genetic material from one generation to the next. 3. The accessory sex glands secrete most of the liquid portion of semen.
4. The penis contains the urethra, a passageway for ejaculation of
semen and excretion of urine.

Sagittal
plane

Sacrum Peritoneum

Seminal vesicle Urinary bladder
Vesicorectal pouch
Ductus (vas) deferens
Coccyx
Suspensory ligament
Rectum of penis
Ampulla of ductus
Pubic symphysis
(vas) deferens
Ejaculatory duct Prostate
Prostatic urethra
Deep muscles of perineum
Intermediate
urethra Bulbourethral (Cowper’s)
gland
Anus
Corpus cavernosum penis
Spongy urethra
Body of penis
Root of penis Corpus spongiosum penis
Corona
Epididymis
Glans penis
Prepuce (foreskin)
External urethral orifice
Testis
Scrotum

(a) Sagittal section
 28.1 MALE REPRODUCTIVE SYSTEM 1043
SUPERIOR

Seminal vesicle Urinary bladder
(opened)
Ductus (vas)
deferens
Prostatic urethra
Prostate
Ejaculatory duct
Pubic symphysis
Rectum
Corpus
cavernosum penis
Intermediate
urethra Corpus
spongiosum penis
Root of penis Body of penis
Bulbospongiosus
muscle
Testis
Spongy urethra Corona
Glans penis

POSTERIOR ANTERIOR
(b) Sagittal section

What are the groups of reproductive organs in males, and what are the functions of each group?

The location of the scrotum and the contraction of its muscle Testes
fibers regulate the temperature of the testes. Normal sperm produc-
tion requires a temperature about 2–3⬚C below core body tempera- The testes (TES-tēz ⫽ witness), or testicles, are paired oval
ture. This lowered temperature is maintained within the scrotum glands in the scrotum measuring about 5 cm (2 in.) long and 2.5
because it is outside the pelvic cavity. In response to cold tempera- cm (1 in.) in diameter (Figure 28.3). Each testis (singular) has a
tures, the cremaster and dartos muscles contract. Contraction of the mass of 10–15 grams. The testes develop near the kidneys, in the
cremaster muscles moves the testes closer to the body, where they posterior portion of the abdomen, and they usually begin their
can absorb body heat. Contraction of the dartos muscle causes the descent into the scrotum through the inguinal canals (passage-
scrotum to become tight (wrinkled in appearance), which reduces ways in the lower anterior abdominal wall; see Figure 28.2) dur-
heat loss. Exposure to warmth reverses these actions. ing the latter half of the seventh month of fetal development.

Figure 28.2 The scrotum, the
supporting structure for the testes. Internal oblique muscle
Aponeurosis of external Spermatic cord
The scrotum consists of loose oblique muscle (cut) Superficial
skin and an underlying Fundiform ligament of penis inguinal ring
subcutaneous layer and Suspensory ligament of penis Cremaster muscle
supports the testes.
Transverse section of penis: Ductus (vas) deferens
Corpora cavernosa penis
Autonomic nerve
Spongy urethra
Testicular artery
Corpus spongiosum penis
Lymphatic vessel

28
SCROTAL SEPTUM Pampiniform plexus
of testicular veins
Cremaster muscle C H A P T E R
Epididymis
Tunica albuginea
of testis
External spermatic fascia Tunica vaginalis
(peritoneum)
DARTOS MUSCLE Internal spermatic fascia
Skin of SCROTUM RAPHE

Which muscles help regulate
the temperature of the testes? Anterior view of scrotum and testes and transverse section of penis
1044 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

Figure 28.3 Internal and external anatomy of a testis.
The testes are the male gonads, which produce haploid
l id sperm.

Sagittal Spermatic cord
plane

Blood vessels
and nerves

Ductus (vas) deferens

Head of epididymis

Efferent duct

SEMINIFEROUS TUBULE
Body of epididymis
STRAIGHT TUBULE
Rete testis TUNICA VAGINALIS
TUNICA ALBUGINEA
Ductus epididymis

LOBULE

SEPTUM
Tail of epididymis

(a) Sagittal section of testis showing seminiferous tubules

SUPERIOR

Spermatic cord

RETE TESTIS SEMINIFEROUS
Head of TUBULES
Body of epididymis
epididymis TUNICA
VAGINALIS
TESTIS
TESTIS

TUNICA TUNICA
Tail of ALBUGINEA
VAGINALIS
epididymis

POSTERIOR ANTERIOR

(b) Lateral view of testis and associated structures (c) Sagittal section

What tissue layers cover and protect the testes?
 28.1 MALE REPRODUCTIVE SYSTEM 1045
A serous membrane called the tunica vaginalis (TOO-ni-ka
vaj-i-NAL-is; tunica ⫽ sheath), which is derived from the perito- CLINICAL CONNECTION | Cryptorchidism
neum and forms during the descent of the testes, partially covers The condition in which the testes do not descend into the
the testes. A collection of serous fluid in the tunica vaginalis is scrotum is called cryptorchidism (krip-TOR-ki-dizm; crypt-
called a hydrocele (HĪ -droˉ-sēl; hydro- ⫽ water; -kele ⫽ hernia). ⫽ hidden; -orchid ⫽ testis); it occurs in about 3% of full-
It may be caused by injury to the testes or inflammation of the term infants and about 30% of premature infants. Untreated bi-
epididymis. Usually, no treatment is required. Internal to the tu- lateral cryptorchidism results in sterility because the cells involved
nica vaginalis the testis is surrounded by is a white fibrous capsule in the initial stages of spermatogenesis are destroyed by the higher
composed of dense irregular connective tissue, the tunica albu- temperature of the pelvic cavity. The chance of testicular cancer is
30–50 times greater in cryptorchid testes. The testes of about 80%
ginea (al⬘-buˉ-JIN-ē-a; albu- ⫽ white); it extends inward, form-
of boys with cryptorchidism will descend spontaneously during the
ing septa that divide the testis into a series of internal compart-
first year of life. When the testes remain undescended, the condi-
ments called lobules. Each of the 200–300 lobules contains one tion can be corrected surgically, ideally before 18 months of
to three tightly coiled tubules, the seminiferous tubules (sem⬘-i- age.
NIF-er-us; semin- ⫽ seed; -fer- ⫽ to carry), where sperm are
produced. The process by which the seminiferous tubules of the
testes produce sperm is called spermatogenesis (sper⬘-ma-toˉ-
JEN-e-sis; genesis ⫽ to be born).
The seminiferous tubules contain two types of cells: sper- cells and the release of sperm into the lumen of the seminiferous
matogenic cells (sper⬘-ma-toˉ-JEN-ik), the sperm-forming cells, tubule. They also produce fluid for sperm transport, secrete the
and sustentacular cells (sus⬘-ten-TAK-uˉ-lar) or Sertoli cells hormone inhibin, and regulate the effects of testosterone and
(ser-TŌ-lē), which have several functions in supporting sper- FSH (follicle-stimulating hormone).
matogenesis (Figure 28.4). Stem cells called spermatogonia In the spaces between adjacent seminiferous tubules are clus-
(sper⬘-ma-toˉ-GŌ-nē-a; -gonia ⫽ offspring; singular is sper- ters of cells called interstitial cells or Leydig cells (LĪ-dig) (Fig-
matogonium) develop from primordial germ cells (prı̄-MŌR- ure 28.4). These cells secrete testosterone, the most prevalent an-
dē-al ⫽ primitive or early form) that arise from the yolk sac and drogen. An androgen is a hormone that promotes the development
enter the testes during the fifth week of development. In the of masculine characteristics. Testosterone also promotes a man’s
embryonic testes, the primordial germ cells differentiate into libido (sexual drive).
spermatogonia, which remain dormant during childhood and ac-
tively begin producing sperm at puberty. Toward the lumen of Spermatogenesis
the seminiferous tubule are layers of progressively more ma- Before you read this section, please review the topic of reproduc-
ture cells. In order of advancing maturity, these are primary tive cell division in Chapter 3 in Section 3.7. Pay particular atten-
spermatocytes, secondary spermatocytes, spermatids, and sperm tion to Figures 3.33 and 3.34.
cells. After a sperm cell, or spermatozoon (sper⬘-ma-toˉ- In humans, spermatogenesis takes 65–75 days. It begins
ZŌ-on; zoon ⫽ life), has formed, it is released into the lumen of with the spermatogonia, which contain the diploid (2n) number
the seminiferous tubule. (The plural terms are sperm and sper- of chromosomes (Figure 28.5). Spermatogonia are types of
matozoa.) stem cells; when they undergo mitosis, some spermatogonia re-
Embedded among the spermatogenic cells in the seminifer- main near the basement membrane of the seminiferous tubule
ous tubules are large sustentacular cells or Sertoli cells, which in an undifferentiated state to serve as a reservoir of cells for
extend from the basement membrane to the lumen of the tubule. future cell division and subsequent sperm production. The rest
Internal to the basement membrane and spermatogonia, tight of the spermatogonia lose contact with the basement mem-
junctions join neighboring sustentacular cells to one another. brane, squeeze through the tight junctions of the blood–testis
These junctions form an obstruction known as the blood–testis barrier, undergo developmental changes, and differentiate into
barrier because substances must first pass through the susten- primary spermatocytes (SPER-ma-toˉ-sı̄tz⬘). Primary sper-
tacular cells before they can reach the developing sperm. By matocytes, like spermatogonia, are diploid (2n); that is, they
isolating the developing gametes from the blood, the blood–tes- have 46 chromosomes.
tis barrier prevents an immune response against the spermato- Shortly after it forms, each primary spermatocyte replicates

28
genic cell’s surface antigens, which are recognized as “foreign” its DNA and then meiosis begins (Figure 28.5). In meiosis I,
by the immune system. The blood–testis barrier does not in- homologous pairs of chromosomes line up at the metaphase
clude spermatogonia. plate, and crossing-over occurs. Then, the meiotic spindle C H A P T E R
Sustentacular cells support and protect developing spermato- pulls one (duplicated) chromosome of each pair to an opposite
genic cells in several ways. They nourish spermatocytes, sperma- pole of the dividing cell. The two cells formed by meiosis I
tids, and sperm; phagocytize excess spermatid cytoplasm as de- are called secondary spermatocytes. Each secondary sper-
velopment proceeds; and control movements of spermatogenic matocyte has 23 chromosomes, the haploid number (n). Each
1046 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

Figure 28.4 Microscopic
anatomy of the seminiferous tubules Interstitial cell
and stages of sperm production Blood capillary
(spermatogenesis). Arrows indicate the
SPERMATOGENIC CELLS:
progression of spermatogenic cells from Basement membrane
Spermatogonium (2n)
least mature to most mature. The (n) and (stem cell)
(2n) refer to haploid and diploid numbers of
chromosomes, respectively. Sustentacular cell Primary spermatocyte (2n)
nucleus
Spermatogenesis occurs in the Blood–testis barrier
seminiferous tubules of the testes. (tight junction) Secondary spermatocyte (n)

Spermatid (n)

Sperm cell or
spermatozoon (n)
Lumen of
seminiferous
tubule

Which cells secrete testosterone? Transverse section of part of seminiferous tubule

chromosome within a secondary spermatocyte, however, is Figure 28.5 Events in spermatogenesis. Diploid cells (2n)
made up of two chromatids (two copies of the DNA) still at- have 46 chromosomes; haploid cells (n) have 23 chromosomes.
tached by a centromere. No replication of DNA occurs in the
secondary spermatocytes. Spermiogenesis involves the maturation of spermatids
In meiosis II, the chromosomes line up in single file along the into sperm.
metaphase plate, and the two chromatids of each chromosome Basement membrane
separate. The four haploid cells resulting from meiosis II are of seminiferous tubule
Some spermatogonia remain
called spermatids (SPER-ma-tids). A single primary spermato- Superficial as precursor stem cells
cyte therefore produces four spermatids via two rounds of cell SPERMATOGONIUM
2n
division (meiosis I and meiosis II). 2n
Mitosis
A unique process occurs during spermatogenesis. As sper-
Some spermatogonia
matogenic cells proliferate, they fail to complete cytoplasmic pushed away from 2n
separation (cytokinesis). The cells remain in contact via cyto- basement membrane
plasmic bridges through their entire development (see Fig- Differentiation
ures 28.4 and 28.5). This pattern of development most likely PRIMARY SPERMATOCYTE
accounts for the synchronized production of sperm in any given
DNA replication,
area of the seminiferous tubule. It may also have survival value 2n tetrad formation,
in that half of the sperm contain an X chromosome and half and crossing-over
Meiosis I
contain a Y chromosome. The larger X chromosome may carry MEIOSIS
genes needed for spermatogenesis that are lacking on the SECONDARY SPERMATOCYTES
Each
smaller Y chromosome. n n chromosome
has two
The final stage of spermatogenesis, spermiogenesis (sper⬘- Meiosis II chromatids
mē-oˉ-JEN-e-sis), is the development of haploid spermatids
Cytoplasmic SPERMATIDS
into sperm. No cell division occurs in spermiogenesis; each
bridge
spermatid becomes a single sperm cell. During this process, n n n n
spherical spermatids transform into elongated, slender sperm.
An acrosome (described shortly) forms atop the nucleus, which SPERMIOGENESIS SPERMATOZOA
condenses and elongates, a flagellum develops, and mitochondria
Deep n n n n
multiply. Sustentacular cells dispose of the excess cytoplasm
that sloughs off. Finally, sperm are released from their connec-
tions to sustentacular cells, an event known as spermiation
(sper⬘-mē-Aˉ -shun). Sperm then enter the lumen of the
seminiferous tubule. Fluid secreted by sustentacular cells What is the outcome
of meiosis I? Lumen of seminiferous tubule
 28.1 MALE REPRODUCTIVE SYSTEM 1047
pushes sperm along their way, toward the ducts of the testes. most sperm do not survive more than 48 hours within the fe-
At this point, sperm are not yet able to swim. male reproductive tract.

Sperm Hormonal Control of Testicular Function
Each day about 300 million sperm complete the process of Although the initiating factors are unknown, at puberty certain
spermatogenesis. A sperm is about 60 ␮m long and contains hypothalamic neurosecretory cells increase their secretion of
several structures that are highly adapted for reaching and pen- gonadotropin-releasing hormone (GnRH) (goˉ⬘-nad-oˉ-TRŌ-
etrating a secondary oocyte (Figure 28.6). The major parts of a pin). This hormone in turn stimulates gonadotrophs in the ante-
sperm are the head and the tail. The flattened, pointed head of rior pituitary to increase their secretion of the two gonadotropins,
the sperm is about 4–5 ␮m long. It contains a nucleus with 23 highly luteinizing hormone (LH) (LOO-tē-in⬘-ı̄z-ing) and follicle-
condensed chromosomes. Covering the anterior two-thirds of stimulating hormone (FSH). Figure 28.7 shows the hormones
the nucleus is the acrosome (AK-roˉ-soˉm; acro- ⫽ atop; -some and negative feedback loops that control secretion of testoster-
⫽ body), a caplike vesicle filled with enzymes that help a sperm one and spermatogenesis.
to penetrate a secondary oocyte to bring about fertilization. LH stimulates interstitial cells, which are located between
Among the enzymes are hyaluronidase and proteases. The tail seminiferous tubules, to secrete the hormone testosterone (tes-
of a sperm is subdivided into four parts: neck, middle piece, TOS-te-roˉn). This steroid hormone is synthesized from choles-
principal piece, and end piece. The neck is the constricted re- terol in the testes and is the principal androgen. It is lipid-soluble
gion just behind the head that contains centrioles. The centri- and readily diffuses out of interstitial cells into the interstitial fluid
oles form the microtubules that comprise the remainder of the and then into blood. Via negative feedback, testosterone suppresses
tail. The middle piece contains mitochondria arranged in a secretion of LH by anterior pituitary gonadotrophs and suppresses
spiral, which provide the energy (ATP) for locomotion of sperm secretion of GnRH by hypothalamic neurosecretory cells. In some
to the site of fertilization and for sperm metabolism. The prin- target cells, such as those in the external genitals and prostate,
cipal piece is the longest portion of the tail, and the end piece the enzyme 5 alpha-reductase converts testosterone to another
is the terminal, tapering portion of the tail. Once ejaculated, androgen called dihydrotestosterone (DHT) (dı̄-hı̄⬘-droˉ-tes-
TOS-ter-oˉn).
FSH acts indirectly to stimulate spermatogenesis (Figure 28.7).
FSH and testosterone act synergistically on the sustentacular
cells to stimulate secretion of androgen-binding protein
Figure 28.6 Parts of a sperm cell.
(ABP) into the lumen of the seminiferous tubules and into the
About 300 million sperm mature each day. interstitial fluid around the spermatogenic cells. ABP binds to
testosterone, keeping its concentration high. Testosterone stim-
ulates the final steps of spermatogenesis in the seminiferous
tubules. Once the degree of spermatogenesis required for male
Acrosome reproductive functions has been achieved, sustentacular cells
HEAD release inhibin, a protein hormone named for its role in inhibit-
Nucleus ing FSH secretion by the anterior pituitary (Figure 28.7). If
Neck spermatogenesis is proceeding too slowly, less inhibin is re-
leased, which permits more FSH secretion and an increased rate
of spermatogenesis.
Mitochondria
Testosterone and dihydrotestosterone both bind to the same
Middle piece
androgen receptors, which are found within the nuclei of target
cells. The hormone–receptor complex regulates gene expression,
turning some genes on and others off. Because of these changes,
the androgens produce several effects:
TAIL Prenatal development. Before birth, testosterone stimulates
Principal
the male pattern of development of reproductive system ducts

28
piece
and the descent of the testes. Dihydrotestosterone stimulates
development of the external genitals (described in Section C H A P T E R
28.5). Testosterone also is converted in the brain to estrogens
(feminizing hormones), which may play a role in the develop-
ment of certain regions of the brain in males.
End piece Development of male sexual characteristics. At puberty,
testosterone and dihydrotestosterone bring about develop-
ment and enlargement of the male sex organs and the devel-
opment of masculine secondary sexual characteristics. Sec-
What are the functions of each part of a sperm cell? ondary sex characteristics are traits that distinguish males
1048 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

Figure 28.7 Hormonal control of spermatogenesis and and enlargement of the larynx and consequent deepening of
actions of testosterone and dihydrotestosterone (DHT). In the voice.
response to stimulation by FSH and testosterone, sustentacular Development of sexual function. Androgens contribute to
cells secrete androgen-binding protein (ABP). Dashed red lines male sexual behavior and spermatogenesis and to sex drive (li-
indicate negative feedback inhibition. bido) in both males and females. Recall that the adrenal cortex
is the main source of androgens in females.
Release of FSH is stimulated by GnRH and inhibited by
inhibin; release of LH is stimulated by GnRH and Stimulation of anabolism. Androgens are anabolic hormones;
inhibited by testosterone. that is, they stimulate protein synthesis. This effect is obvious
in the heavier muscle and bone mass of most men as compared
Hypothalamus to women.
GnRH
A negative feedback system regulates testosterone production
(Figure 28.8). When testosterone concentration in the blood in-
Testosterone decreases creases to a certain level, it inhibits the release of GnRH by cells
release of GnRH and LH
in the hypothalamus. As a result, there is less GnRH in the portal
Anterior pituitary blood that flows from the hypothalamus to the anterior pituitary.
Inhibin decreases Gonadotrophs in the anterior pituitary then release less LH, so
Gonadotroph
release of FSH the concentration of LH in systemic blood falls. With less stimu-
lation by LH, the interstitial cells in the testes secrete less testos-
Together with terone, and there is a return to homeostasis. If the testosterone
testosterone, LH stimulates concentration in the blood falls too low, however, GnRH is again
FSH stimulates FSH LH
testosterone released by the hypothalamus and stimulates secretion of LH by
spermatogenesis secretion
the anterior pituitary. LH in turn stimulates testosterone produc-
Testosterone tion by the testes.
Inhibin
CHECKPOINT
Testosterone 1. Describe the function of the scrotum in protecting the
ABP testes from temperature fluctuations.
2. Describe the internal structure of a testis. Where are
sperm cells produced? What are the functions of
Spermatogenic
cells sustentacular cells and interstitial (Leydig) cells?
Sustentacular cells Interstitial 3. Describe the principal events of spermatogenesis.
secrete androgen- Dihydro- cells secrete 4. Which part of a sperm cell contains enzymes that help
binding protein testosterone testosterone
(DHT) the sperm cell fertilize a secondary oocyte?
(ABP)
5. What are the roles of FSH, LH, testosterone, and inhibin
in the male reproductive system? How is secretion of
these hormones controlled?
Male pattern of development (before birth)
Enlargement of male sex organs Reproductive System Ducts in Males
and expression of male secondary
sex characteristics (starting at puberty) Ducts of the Testis
Anabolism (protein synthesis)
Pressure generated by the fluid secreted by sustentacular cells
pushes sperm and fluid along the lumen of seminiferous tubules
Key:
and then into a series of very short ducts called straight tubules
LH FSH Testosterone
(see Figure 28.3a). The straight tubules lead to a network of ducts
LH receptor FSH receptor Androgen
receptor in the testis called the rete testis (RĒ-tē ⫽ network). From the
rete testis, sperm move into a series of coiled efferent ducts (EF-
Which cells secrete inhibin? er-ent) in the epididymis that empty into a single tube called the
ductus epididymis.

and females but do not have a direct role in reproduction. Epididymis
These include muscular and skeletal growth that results in The epididymis (ep⬘-i-DID-i-mis; epi- ⫽ above or over; -didymis
wide shoulders and narrow hips; facial and chest hair (within ⫽ testis) is a comma-shaped organ about 4 cm (1.5 in.) long
hereditary limits) and more hair on other parts of the body; that lies along the posterior border of each testis (see Fig-
thickening of the skin; increased sebaceous (oil) gland secretion; ure 28.3a). The plural is epididymides (ep⬘-i-di-DIM-i-dēz).
 28.1 MALE REPRODUCTIVE SYSTEM 1049
Figure 28.8 Negative feedback control of blood level of Each epididymis consists mostly of the tightly coiled ductus
testosterone. epididymis. The efferent ducts from the testis join the ductus
epididymis at the larger, superior portion of the epididymis
Gonadotrophs of the anterior pituitary produce called the head. The body is the narrow midportion of the epi-
luteinizing hormone (LH). didymis, and the tail is the smaller, inferior portion. At its distal
end, the tail of the epididymis continues as the ductus (vas)
deferens (discussed shortly).
STIMULUS
The ductus epididymis would measure about 6 m (20 ft) in
length if it were uncoiled. It is lined with pseudostratified colum-
nar epithelium and encircled by layers of smooth muscle. The
Disrupts homeostasis free surfaces of the columnar cells contain stereocilia (ster⬘-ē-oˉ-
by increasing
SIL-ē-a), which despite their name are long, branching microvilli
(not cilia) that increase the surface area for the reabsorption of
CONTROLLED CONDITION degenerated sperm. Connective tissue around the muscle layer at-
Blood level of testosterone taches the loops of the ductus epididymis and carries blood ves-
sels and nerves.
Functionally, the epididymis is the site of sperm matura-
tion, the process by which sperm acquire motility and the abil-
RECEPTORS ity to fertilize an ovum. This occurs over a period of about
Cells in 14 days. The epididymis also helps propel sperm into the ductus
hypothalamus (vas) deferens during sexual arousal by peristaltic contraction
that secrete
GnRH – of its smooth muscle. In addition, the epididymis stores sperm,
which remain viable here for up to several months. Any stored
sperm that are not ejaculated by that time are eventually
Input Decreased GnRH reabsorbed.
in portal blood
Ductus Deferens
CONTROL CENTER Within the tail of the epididymis, the ductus epididymis be-
Anterior Return to comes less convoluted, and its diameter increases. Beyond this
pituitary homeostasis when point, the duct is known as the ductus deferens or vas deferens
gonadotrophs response brings
blood level of (DEF-er-enz) (see Figure 28.3a). The ductus deferens, which is
testosterone back about 45 cm (18 in.) long, ascends along the posterior border of
to normal the epididymis through the spermatic cord and then enters the
Output Decreased LH pelvic cavity. There it loops over the ureter and passes over the side
in systemic blood
and down the posterior surface of the urinary bladder (see Fig-
ure 28.1a). The dilated terminal portion of the ductus deferens is
EFFECTORS
the ampulla (am-PUL-la ⫽ little jar; see Figure 28.9). The
Interstitial mucosa of the ductus deferens consists of pseudostratified colum-
(Leydig)
cells in nar epithelium and lamina propria (areolar connective tissue).
testes The muscularis is composed of three layers of smooth muscle;
the inner and outer layers are longitudinal, and the middle layer
Secrete less is circular.
testosterone Functionally, the ductus deferens conveys sperm during
sexual arousal from the epididymis toward the urethra by peri-
RESPONSE
staltic contractions of its muscular coat. Like the epididymis,
Decrease in blood
the ductus deferens also can store sperm for several months.

28
level of testosterone Any stored sperm that are not ejaculated by that time are even-
tually reabsorbed.
C H A P T E R
Spermatic Cord
Which hormones inhibit secretion of FSH and LH by the The spermatic cord is a supporting structure of the male repro-
anterior pituitary? ductive system that ascends out of the scrotum (see Figure 28.2).
It consists of the ductus (vas) deferens as it ascends through the
scrotum, the testicular artery, veins that drain the testes and carry
testosterone into circulation (the pampiniform plexus), autonomic
1050 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

nerves, lymphatic vessels, and the cremaster muscle. The sper- (see Figure 28.2), a somewhat triangular opening in the aponeu-
matic cord and ilioinguinal nerve pass through the inguinal canal rosis of the external oblique muscle. In females, the round liga-
(ING-gwi-nal ⫽ groin), an oblique passageway in the anterior ment of the uterus and ilioinguinal nerve pass through the ingui-
abdominal wall just superior and parallel to the medial half of the nal canal.
inguinal ligament. The canal, which is about 4–5 cm (about 2 in.) The term varicocele (VAR-i-koˉ-sēl; varico- ⫽ varicose; -kele
long, originates at the deep (abdominal) inguinal ring, a slitlike ⫽ hernia) refers to a swelling in the scrotum due to a dilation of
opening in the aponeurosis of the transversus abdominis muscle; the veins that drain the testes. It is usually more apparent when
the canal ends at the superficial (subcutaneous) inguinal ring the person is standing and typically does not require treatment.

FUN CTI ON S OF ACCE SSORY SE X G L AN D SECRETIO NS
Figure 28.9 Locations of several accessory reproductivee
1. The seminal vesicles secrete an enzymes that break down clotting
organs in males. The prostate, urethra, and penis have been alkaline, viscous fluid that helps proteins from the seminal
sectioned to show internal details. neutralize acid in the female vesicles.
reproductive tract, provides 3. The bulbourethral glands
The male urethra has three subdivisions: the prostatic, fructose for ATP production by secrete an alkaline fluid that
membranous, and spongy (penile) urethra. sperm, contributes to sperm neutralizes the acidic
motility and viability, and helps environment of the urethra and
semen coagulate after mucus that lubricates the lining
ejaculation. of the urethra and the tip of
2. The prostate secretes a milky, the penis during sexual
slightly acidic fluid that contains intercourse.

RIGHT DUCTUS
(VAS) DEFERENS

View

Left ureter
Urinary bladder

Hip bone
(cut)

AMPULLA OF DUCTUS
PROSTATE (VAS) DEFERENS
SEMINAL VESICLE

PROSTATIC
URETHRA
SEMINAL VESICLE
DUCT
INTERMEDIATE EJACULATORY
(MEMBRANOUS) DUCT
URETHRA

Deep muscles of perineum
CRUS OF PENIS
BULBOURETHRAL
(COWPER’S) GLAND
BULB OF PENIS

CORPORA CAVERNOSA
CORPUS SPONGIOSUM PENIS
PENIS
SPONGY URETHRA

(a) Posterior view of male accessory organs of reproduction
 28.1 MALE REPRODUCTIVE SYSTEM 1051

Urinary bladder

Left ureter
Hip bone
Pelvic diaphragm

RIGHT DUCTUS
(VAS) DEFERENS

Obturator internus SEMINAL VESICLE
muscle AMPULLA OF DUCTUS
(VAS) DEFERENS

PROSTATE

Deep muscles of perineum

Bulbospongiosus muscle

(b) Posterior view of male accessory organs of reproduction

What accessory sex gland contributes the majority of the seminal fluid?

Ejaculatory Ducts 8. Give the locations of the three subdivisions of the male
Each ejaculatory duct (ē-JAK-uˉ-la-toˉr-ē; ejacul- ⫽ to expel) is urethra.
about 2 cm (1 in.) long and is formed by the union of the duct from 9. Trace the course of sperm through the system of ducts
from the seminiferous tubules to the urethra.
the seminal vesicle and the ampulla of the ductus (vas) deferens
10. List the structures within the spermatic cord.
(Figure 28.9). The short ejaculatory ducts form just superior to the
base (superior portion) of the prostate and pass inferiorly and an-
teriorly through the prostate. They terminate in the prostatic ure- Accessory Sex Glands
thra, where they eject sperm and seminal vesicle secretions just
before the release of semen from the urethra to the exterior. The ducts of the male reproductive system store and transport
sperm cells, but the accessory sex glands secrete most of the liq-
Urethra uid portion of semen. The accessory sex glands include the sem-
In males, the urethra (uˉ-RĒ-thra) is the shared terminal duct of the inal vesicles, the prostate, and the bulbourethral glands.
reproductive and urinary systems; it serves as a passageway for
both semen and urine. About 20 cm (8 in.) long, it passes through Seminal Vesicles
the prostate, the deep muscles of the perineum, and the penis, and The paired seminal vesicles (VES-i-kuls) or seminal glands
is subdivided into three parts (see Figures 28.1 and 26.22). The are convoluted pouchlike structures, about 5 cm (2 in.) in
prostatic urethra (pros-TAT-ik) is 2–3 cm (1 in.) long and passes length, lying posterior to the base of the urinary bladder and
through the prostate. As this duct continues inferiorly, it passes anterior to the rectum (Figure 28.9). Through the seminal vesi-
through the deep muscles of the perineum, where it is known as the cle ducts they secrete an alkaline, viscous fluid that contains
intermediate (membranous) urethra (MEM-bra-nus). The inter- fructose (a monosaccharide sugar), prostaglandins, and clotting
mediate urethra is about 1 cm (0.5 in.) in length. As this duct passes proteins that are different from those in blood. The alkaline na-

28
through the corpus spongiosum of the penis, it is known as the ture of the seminal fluid helps to neutralize the acidic environ-
spongy urethra, which is about 15–20 cm (6–8 in.) long. The ment of the male urethra and female reproductive tract that other- C H A P T E R
spongy urethra ends at the external urethral orifice. The histol- wise would inactivate and kill sperm. The fructose is used for
ogy of the male urethra may be reviewed in Section 26.8. ATP production by sperm. Prostaglandins contribute to sperm
CHECKPOINT motility and viability and may stimulate smooth muscle con-
6. Which ducts transport sperm within the testes? tractions within the female reproductive tract. The clotting
7. Describe the location, structure, and functions of the proteins help semen coagulate after ejaculation. Fluid secreted
ductus epididymis, ductus (vas) deferens, and ejaculatory by the seminal vesicles normally constitutes about 60% of the
duct. volume of semen.
1052 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

Prostate provides sperm with a transportation medium, nutrients, and
The prostate (PROS-taˉt; prostata ⫽ one who stands before) is a protection from the hostile acidic environment of the male’s ure-
single, doughnut-shaped gland about the size of a golf ball. It thra and the female’s vagina.
measures about 4 cm (1.6 in.) from side to side, about 3 cm (1.2 in.) Once ejaculated, liquid semen coagulates within 5 minutes
from top to bottom, and about 2 cm (0.8 in.) from front to back. It due to the presence of clotting proteins from the seminal vesi-
is inferior to the urinary bladder and surrounds the prostatic ure- cles. The functional role of semen coagulation is not known,
thra (Figure 28.9). The prostate slowly increases in size from but the proteins involved are different from those that cause
birth to puberty. It then expands rapidly until about age 30, after blood coagulation. After about 10 to 20 minutes, semen reliq-
which time its size typically remains stable until about age 45, uefies because prostate-specific antigen (PSA) and other pro-
when further enlargement may occur. teolytic enzymes produced by the prostate break down the
The prostate secretes a milky, slightly acidic fluid (pH about clot. Abnormal or delayed liquefaction of clotted semen may
6.5) that contains several substances. (1) Citric acid in prostatic cause complete or partial immobilization of sperm, thereby in-
fluid is used by sperm for ATP production via the Krebs cycle. hibiting their movement through the cervix of the uterus. After
(2) Several proteolytic enzymes, such as prostate-specific antigen passing through the uterus and uterine tube, the sperm are af-
(PSA), pepsinogen, lysozyme, amylase, and hyaluronidase, even- fected by secretions of the uterine tube in a process called ca-
tually break down the clotting proteins from the seminal vesicles. pacitation (see Section 28.2). The presence of blood in semen
(3) The function of the acid phosphatase secreted by the prostate is called hemospermia (hē-moˉ-SPER-mē-a; hemo- ⫽ blood;
is unknown. (4) Seminalplasmin in prostatic fluid is an antibiotic -sperma ⫽ seed). In most cases, it is caused by inflammation
that can destroy bacteria. Seminalplasmin may help decrease the of the blood vessels lining the seminal vesicles; it is usually
number of naturally occurring bacteria in semen and in the lower treated with antibiotics.
female reproductive tract. Secretions of the prostate enter the
prostatic urethra through many prostatic ducts. Prostatic secre- Penis
tions make up about 25% of the volume of semen and contribute The penis (⫽ tail) contains the urethra and is a passageway for
to sperm motility and viability. the ejaculation of semen and the excretion of urine (Figure 28.10).
It is cylindrical in shape and consists of a body, glans penis, and a
Bulbourethral Glands root. The body of the penis is composed of three cylindrical
The paired bulbourethral glands (bul⬘-boˉ-uˉ-RĒ-thral), or Cow- masses of tissue, each surrounded by fibrous tissue called the tu-
per’s glands (KOW-pers), are about the size of peas. They are nica albuginea (Figure 28.10). The two dorsolateral masses are
located inferior to the prostate on either side of the membranous called the corpora cavernosa penis (corpora ⫽ main bodies;
urethra within the deep muscles of the perineum, and their ducts cavernosa ⫽ hollow). The smaller midventral mass, the corpus
open into the spongy urethra (Figure 28.9). During sexual arousal, spongiosum penis, contains the spongy urethra and keeps it open
the bulbourethral glands secrete an alkaline fluid into the urethra during ejaculation. Skin and a subcutaneous layer enclose all
that protects the passing sperm by neutralizing acids from urine in three masses, which consist of erectile tissue. Erectile tissue is
the urethra. They also secrete mucus that lubricates the end of the composed of numerous blood sinuses (vascular spaces) lined by
penis and the lining of the urethra, decreasing the number of endothelial cells and surrounded by smooth muscle and elastic
sperm damaged during ejaculation. Some males release a drop or connective tissue.
two of this mucus upon sexual arousal and erection. The fluid The distal end of the corpus spongiosum penis is a slightly
does not contain sperm cells. enlarged, acorn-shaped region called the glans penis; its mar-
gin is the corona (koˉ-RŌ-na). The distal urethra enlarges
within the glans penis and forms a terminal slitlike opening,
Semen the external urethral orifice. Covering the glans in an uncir-
Semen (⫽ seed) is a mixture of sperm and seminal fluid, a liquid cumcised penis is the loosely fitting prepuce (PRĒ-poos), or
that consists of the secretions of the seminiferous tubules, seminal foreskin.
vesicles, prostate, and bulbourethral glands. The volume of semen The root of the penis is the attached portion (proximal por-
in a typical ejaculation is 2.5–5 milliliters (mL), with 50–150 mil- tion). It consists of the bulb of the penis, the expanded poste-
lion sperm per mL. When the number falls below 20 million/mL, rior continuation of the base of the corpus spongiosum penis,
the male is likely to be infertile. A very large number of sperm is and the crura of the penis (KROO-ra; singular is crus ⫽ resem-
required for successful fertilization because only a tiny fraction bling a leg), the two separated and tapered portions of the cor-
ever reaches the secondary oocyte. pora cavernosa penis. The bulb of the penis is attached to the
Despite the slight acidity of prostatic fluid, semen has a slightly inferior surface of the deep muscles of the perineum and is
alkaline pH of 7.2–7.7 due to the higher pH and larger volume of enclosed by the bulbospongiosus muscle, a muscle that aids
fluid from the seminal vesicles. The prostatic secretion gives se- ejaculation. Each crus of the penis bends laterally away from
men a milky appearance, and fluids from the seminal vesicles and the bulb of the penis to attach to the ischial and inferior pubic
bulbourethral glands give it a sticky consistency. Seminal fluid rami and is surrounded by the ischiocavernosus muscle (see
 28.1 MALE REPRODUCTIVE SYSTEM 1053
Figure 28.10 Internal structure of the penis. The inset in (b) shows details of the skin and fasciae.
The penis contains the urethra, a common pathway for semen and urine.

Urinary bladder
Internal urethral orifice
Prostatic urethra Prostate
Orifice of ejaculatory duct
Bulbourethral (Cowper’s) gland
Intermediate urethra
Deep muscles of perineum ROOT OF PENIS:
Bulb of penis
Crus of penis
Skin
Deep
dorsal Superficial dorsal
vein vein
BODY OF PENIS:
Corpora cavernosa penis Dorsal Subcutaneous layer
artery
Fascia
Corpus spongiosum penis

DORSAL
Corpora cavernosa
penis

Spongy urethra Tunica albuginea of
corpora cavernosa
Deep artery of penis

Corona Corpus spongiosum
penis
GLANS PENIS
Spongy urethra
Prepuce VENTRAL Tunica albuginea of
(foreskin)
corpus spongiosum
External urethral orifice penis

(a) Frontal section (b) Transverse section

CLINICAL CONNECTION | Superficial dorsal vein
Circumcision Deep dorsal vein
Skin
Circumcision (⫽ to cut around) is a Dorsal artery
Subcutaneous
surgical procedure in which part of or layer Corpora cavernosa penis
the entire prepuce is removed. It is usually Tunica albuginea of corpora
performed several days after birth, and is cavernosa penis
done for social, cultural, religious, and (more Deep artery of penis
rarely) medical reasons. Although most
health-care professionals find no medical jus-
tification for circumcision, some feel that it

28
has benefits, such as a lower risk of urinary Spongy urethra
tract infections, protection against penile
Corpus spongiosum penis C H A P T E R
cancer, and possibly a lower risk for sexually
transmitted diseases. Indeed, studies in sev- Tunica albuginea of corpus
eral African villages have found lower rates spongiosum penis
of HIV infection among circumcised men.
(c) Transverse section

Which tissue masses form the erectile tissue in the penis, and why do they become rigid during sexual arousal?
1054 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

Figure 11.13). The weight of the penis is supported by two
ligaments that are continuous with the fascia of the penis. (1) CLINICAL CONNECTION | Premature Ejaculation
The fundiform ligament (FUN-di-form) arises from the infe- A premature ejaculation is ejaculation that occurs too early,
rior part of the linea alba. (2) The suspensory ligament of the for example, during foreplay or on or shortly after penetra-
penis arises from the pubic symphysis. tion. It is usually caused by anxiety, other psychological
Upon sexual stimulation (visual, tactile, auditory, olfactory, or causes, or an unusually sensitive foreskin or glans penis. For most
imagined), parasympathetic fibers from the sacral portion of the males, premature ejaculation can be overcome by various techniques
spinal cord initiate and maintain an erection, the enlargement and (such as squeezing the penis between the glans penis and shaft as
stiffening of the penis. The parasympathetic fibers produce and re- ejaculation approaches), behavioral therapy, or medication.
lease nitric oxide (NO). The NO causes smooth muscle in the walls
of arterioles supplying erectile tissue to relax, which allows these
blood vessels to dilate. This in turn causes large amounts of blood CHECKPOINT
to enter the erectile tissue of the penis. NO also causes the smooth 11. Briefly explain the locations and functions of the
muscle within the erectile tissue to relax, resulting in widening of seminal vesicles, the prostate, and the bulbourethral
the blood sinuses. The combination of increased blood flow and (Cowper’s) glands.
12. What is semen? What is its function?
widening of the blood sinuses results in an erection. Expansion of
13. Explain the physiological processes involved in erection
the blood sinuses also compresses the veins that drain the penis; the
and ejaculation.
slowing of blood outflow helps to maintain the erection.
The term priapism (PRĪ -a-pizm) refers to a persistent and
usually painful erection of the penis that does not involve sexual
desire or excitement. The condition may last up to several hours 28.2 Female Reproductive
and is accompanied by pain and tenderness. It results from ab-
normalities of blood vessels and nerves, usually in response to
System
medication used to produce erections in males who otherwise OBJECTIVES
cannot attain them. Other causes include a spinal cord disorder, Describe the location, structure, and functions of the
leukemia, sickle-cell disease, or a pelvic tumor. organs of the female reproductive system.
Ejaculation (ē-jak-uˉ-LAˉ-shun; ejectus- ⫽ to throw out), the Discuss the process of oogenesis in the ovaries.
powerful release of semen from the urethra to the exterior, is a The organs of the female reproductive system (Figure 28.11)
sympathetic reflex coordinated by the lumbar portion of the spi- include the ovaries (female gonads); the uterine (fallopian) tubes,
nal cord. As part of the reflex, the smooth muscle sphincter at or oviducts; the uterus; the vagina; and external organs, which
the base of the urinary bladder closes, preventing urine from be- are collectively called the vulva, or pudendum. The mammary
ing expelled during ejaculation, and semen from entering the glands are considered part of both the integumentary system and
urinary bladder. Even before ejaculation occurs, peristaltic con- the female reproductive system.
tractions in the epididymis, ductus (vas) deferens, seminal vesi-
cles, ejaculatory ducts, and prostate propel semen into the penile
portion of the urethra (spongy urethra). Typically, this leads to Ovaries
emission (ē-MISH-un), the discharge of a small volume of se- The ovaries (⫽ egg receptacles), which are the female gonads, are
men before ejaculation. Emission may also occur during sleep paired glands that resemble unshelled almonds in size and shape;
(nocturnal emission). The musculature of the penis (bulbospon- they are homologous to the testes. (Here homologous means that
giosus, ischiocavernosus, and superficial transverse perineal two organs have the same embryonic origin.) The ovaries produce
muscles), which is supplied by the pudendal nerve, also con- (1) gametes, secondary oocytes that develop into mature ova (eggs)
tracts at ejaculation (see Figure 11.13). after fertilization, and (2) hormones, including progesterone and
Once sexual stimulation of the penis has ended, the arterioles estrogens (the female sex hormones), inhibin, and relaxin.
supplying the erectile tissue of the penis constrict and the smooth The ovaries, one on either side of the uterus, descend to the
muscle within erectile tissue contracts, making the blood sinuses brim of the superior portion of the pelvic cavity during the third
smaller. This relieves pressure on the veins supplying the penis month of development. A series of ligaments holds them in posi-
and allows the blood to drain through them. Consequently, the tion (Figure 28.12). The broad ligament of the uterus, which is a
penis returns to its flaccid (relaxed) state. fold of the parietal peritoneum, attaches to the ovaries by a double-
 28.2 FEMALE REPRODUCTIVE SYSTEM 1055
layered fold of peritoneum called the mesovarium (mez⬘-oˉ-VAˉ- people believed that it did. We have since learned that the cells
rē-um). The ovarian ligament anchors the ovaries to the uterus, that produce ova arise from the yolk sac and migrate to the
and the suspensory ligament attaches them to the pelvic wall. ovaries during embryonic development.
Each ovary contains a hilum (HĪ-lum), the point of entrance and The tunica albuginea is a whitish capsule of dense irregular
exit for blood vessels and nerves along which the mesovarium is connective tissue located immediately deep to the germinal
attached. epithelium.
The ovarian cortex is a region just deep to the tunica albu-
Histology of the Ovary ginea. It consists of ovarian follicles (described shortly) sur-
Each ovary consists of the following parts (Figure 28.13): rounded by dense irregular connective tissue that contains
The germinal epithelium (germen ⫽ sprout or bud) is a layer collagen fibers and fibroblast-like cells called stromal cells.
of simple epithelium (low cuboidal or squamous) that covers The ovarian medulla is deep to the ovarian cortex. The bor-
the surface of the ovary. We now know that the term germinal der between the cortex and medulla is indistinct, but the me-
epithelium in humans is not accurate because this layer does dulla consists of more loosely arranged connective tissue and
not give rise to ova; the name came about because, at one time, contains blood vessels, lymphatic vessels, and nerves.

FUN CTI ON S OF THE FE M AL E RE PRO DU CTIVE SYSTEM
Figure 28.11 Female organs of reproduction and
1. The ovaries produce secondary development of the fetus during
surrounding structures. oocytes and hormones, including pregnancy, and labor.
progesterone and estrogens 4. The vagina receives the penis
The organs of reproduction in females include the (female sex hormones), inhibin, during sexual intercourse and is
ovaries, uterine (fallopian) tubes, uterus, vagina, vulva, and relaxin. a passageway for childbirth.
and mammary glands. 2. The uterine tubes transport a 5. The mammary glands synthesize,
secondary oocyte to the uterus secrete, and eject milk for
and normally are the sites where nourishment of the newborn.
fertilization occurs.
3. The uterus is the site of implanta-
tion of a fertilized ovum,

Sagittal
plane Uterine tube

Fimbriae

Sacrum Ovary

Uterus
Uterosacral ligament
Round ligament
Posterior fornix of vagina of uterus

Rectouterine pouch
Cervix
Vesicouterine pouch Urinary bladder

Coccyx Pubic symphysis

Rectum Mons pubis

Clitoris

28
Vagina Urethra

Labium majus C H A P T E R
Anus

External urethral orifice

Labium minus

(a) Sagittal section
F I G U R E 28. 11 CONTINUES
1056 CHAPTER 28 THE REPRODUCTIVE SYSTEMS

F I G U R E 28.11 CONTINUED Fimbriae
Ovary

Uterine tube

Fundus of uterus
Body of uterus

Rectouterine pouch

Cervix of uterus
Vesicouterine pouch Urinary bladder

Vagina Pubic symphysis

Rectum Mons pubis
Urethra
Clitoris

Labium minus

Labium majus

(b) Sagittal section

Which structures in males are homologous to the ovaries, the clitoris, the paraurethral glands, and the greater vestibular glands?

Figure 28.12 Relative positions of the ovaries, the uterus, and the ligaments that support them.
Ligaments holding the ovaries in position are the mesovarium, the ovarian ligament, and the suspensory ligament.

ANTERIOR

Rectus abdominis
muscle

Urinary bladder
View
Uterus
Transverse
plane
Round ligament

Ovarian ligament
Uterine (fallopian) tube Mesovarium
Ovary Cecum
Rectouterine pouch
Broad ligament

Suspensory ligament Vermiform appendix

Ureter Cardinal ligament
Ileum
Uterosacral ligament
Sigmoid colon

Common iliac artery

POSTERIOR

Superior view of transverse section

To which structures do the mesovarium, ovarian ligament, and suspensory ligament anchor the ovary?
 28.2 FEMALE REPRODUCTIVE SYSTEM 1057
Figure 28.13 Histology of the ovary. The arrows indicate the sequence of developmental stages that occur as part of the
maturation of an ovum during the ovarian cycle.

The ovaries are the female gonads; they produce haploid oocytes.

Primordial Secondary Germinal
follicle f