Chapter 46 Animal
Reproduction
Lecture Outline
Overview: Doubling Up for
Sexual Reproduction
Concept 46.1 Both asexual and sexual reproduction occur in
the animal kingdom
·
Asexual reproduction involves the formation of
individuals whose genes come from a single parent.
°
There
is no fusion of sperm and egg.
·
Sexual reproduction is the formation of
offspring by the fusion of haploid gametes
to form a diploid zygote.
°
The
female gamete, the unfertilized egg,
or ovum, is usually large and
nonmotile.
°
The
male gamete is the sperm, which is
usually small and motile.
°
Sexual
reproduction increases genetic variation among offspring by generating unique
combinations of genes inherited from two parents.
Diverse mechanisms of asexual reproduction
enable animals to produce identical offspring rapidly.
·
Many
invertebrates can reproduce asexually by fission,
in which a parent separates into two or more approximately equal-sized
individuals.
°
Budding is also common among
invertebrates. This is a form of asexual reproduction in which new individuals
split off from existing ones.
°
In
fragmentation, the body breaks into
several pieces, some or all of which develop into complete adults.
§
Reproducing
in this way requires regeneration of
lost body parts.
§
Many
animals can also replace new appendages by regeneration.
·
Asexual
reproduction has a number of advantages.
°
It
allows isolated animals to reproduce without needing to find a mate.
°
It
can create numerous offspring in a short period of time.
°
In
stable environments, it allows for the perpetuation of successful genotypes.
Reproductive
cycles and patterns vary extensively among mammals.
·
Most
animals exhibit cycles in reproductive activity, usually related to changing
seasons.
°
This
allows animals to conserve resources and reproduce when more energy is
available and when environmental conditions favor the survival of offspring.
·
Reproductive
cycles are controlled by a combination of environmental and hormonal cues.
°
Environmental
cues may include seasonal temperature, rainfall, day length, and lunar cycles.
·
Animals
may reproduce exclusively asexually or sexually or they may alternate between
the two modes, depending on environmental conditions.
°
Daphnia reproduce by
parthenogenesis under favorable conditions and sexually during times of
environmental stress.
·
Parthenogenesis is the process by which
an unfertilized egg develops without being fertilized.
°
Parthenogenesis
plays a role in the social organization of some bees, wasps, and ants.
§
Male
honeybees (drones) are haploid, and female honeybees (queens and workers) are
diploid.
°
Several
genera of fishes, amphibians, and lizards reproduce by a form of
parthenogenesis that produces diploid “zygotes.”
§
Fifteen
species of whiptail lizards reproduce exclusively by parthenogenesis.
§
There
are no males in this species, but the lizards imitate courtship and mating
behavior typical of sexual species of the same genus.
·
Sexual
reproduction presents a problem for sessile or burrowing animals or parasites
that may have difficulty encountering a member of the opposite sex.
°
One
solution is hermaphroditism, in
which one individual functions as both a male and a female.
§
Some
hermaphrodites can self-fertilize, but most mate with another member of the
same species.
à
In
such matings, each individual receives and donates sperm.
à
This
results in twice as many offspring as would be produced if only one set of eggs
were fertilized.
°
In
sequential hermaphroditism, an
individual reverses its sex during its lifetime.
§
In
some species, the sequential hermaphrodite is female first.
§
In
other species, the sequential hermaphrodite is male first.
Concept 46.2 Fertilization depends on mechanisms
that help sperm meet eggs of the same species
·
The
mechanisms of fertilization, the
union of sperm and egg, play an important part in sexual reproduction.
°
In
external fertilization, eggs are
released by the female into a wet environment, where they are fertilized by the
male.
°
In
species with internal fertilization,
sperm are deposited in or near the female reproductive tract, and fertilization
occurs within the tract.
·
A
moist habitat is almost always required for external fertilization, both to
prevent gametes from drying out and to allow the sperm to swim to the eggs.
·
In
species with external fertilization, timing is crucial to ensure that mature
sperm encounter ripe eggs.
°
Environmental
cues such as temperature or day length may cause gamete release by the whole
population.
°
Individuals
may engage in courtship behavior that leads to fertilization of the eggs of one
female by one male.
·
Internal
fertilization is an adaptation to terrestrial life that enables sperm to reach
an egg in a dry environment.
°
Internal
fertilization requires sophisticated reproductive systems, including copulatory
organs that deliver sperm and receptacles for their storage and transport to
ripe eggs.
·
Mating
animals may use pheromones, chemical
signals released by one organism that influence the behavior or physiology of
other individuals of the same species.
°
Pheromones
are small, volatile, or water-soluble molecules that disperse into the
environment.
°
Like
hormones, pheromones are active in minute amounts.
°
Many
pheromones act as male attractants.
·
All
species produce more offspring than can survive to reproduce.
·
Internal
fertilization usually involves the production of fewer zygotes than does
external fertilization.
°
However,
the survival rate is higher for internal fertilization.
°
Major
types of protection include tough eggshells, development of the embryo within
the reproductive tract of the mother, and parental care of the eggs and offspring.
·
Marsupial
mammals retain their embryos for only a short period in the uterus.
°
The
embryos crawl out and complete fetal development attached to a mammary gland in
the mother’s pouch.
·
The
embryos of eutherian mammals develop entirely within the uterus, nourished
through the placenta.
·
Parental
care of offspring can occur regardless of whether fertilization is external or
internal.
Reproductive systems produce gametes and make
them available to gametes of the opposite sex.
·
The
least complex reproductive systems lack gonads,
the organs that produce gametes in most animals.
°
Polychaete
worms lack gonads. Eggs and sperm develop from undifferentiated cells lining
the coelom.
°
As
the gametes mature, they are released from the body wall and fill the coelom.
°
In
some species, the body splits open to release the gametes, killing the parent.
·
Some
reproductive systems, such as those of parasitic flatworms, are very complex.
·
Most
insects have separate sexes with complex reproductive systems.
°
In
many species, the female reproductive system includes a spermatheca, a sac in which sperm may be stored for a year or more.
·
The
basic plan of all vertebrate reproductive systems is very similar.
°
However,
there are variations.
§
In
many nonmammalian vertebrates, the digestive, excretory, and reproductive
systems share a common opening to the outside, the cloaca.
§
Mammals
have separate openings for the digestive and reproductive systems.
à
Female
mammals also have separate openings for the excretory and reproductive systems.
§
The
uterus of most vertebrates is partly or completely divided into two chambers.
§
Male
reproductive systems differ mainly in copulatory organs.
à
Many
mammalian vertebrates do not have a well-developed penis and simply turn the
cloaca inside out to ejaculate.
Concept 46.3 Reproductive organs produce and transport gametes:
focus on humans
Human reproduction involves intricate anatomy
and complex behavior.
·
The
reproductive anatomy of the human female includes external and internal
reproductive structures.
°
External
reproductive structures consist of two sets of labia surrounding the clitoris
and vaginal opening.
°
Internal
reproductive organs consist of a pair of gonads and a system of ducts and
chambers.
§
The
role of the ducts and chambers is to conduct the gametes and house the embryo
and fetus.
·
The
ovaries, the female gonads, lie in
the abdominal cavity, attached to the uterus by a mesentery.
°
Each
ovary is enclosed in a tough protective capsule and contains many follicles.
°
Each
follicle consists of one egg cell
surrounded by one or more layers of follicle cells.
§
A
woman is born with about 400,000 follicles.
à
Only
several hundred of these will release eggs during a female’s reproductive
years.
§
Follicles
produce the primary female sex hormones, estrogens.
·
Usually
one follicle matures and releases its egg during each menstrual cycle in the
process of ovulation.
°
After
ovulation, the remaining follicular tissue develops into the corpus luteum.
°
The
corpus luteum secretes additional estrogens and progesterone, hormones that
help maintain the uterine lining during pregnancy.
°
If
pregnancy does not occur, the corpus luteum disintegrates and a new follicle
matures during the next cycle.
·
At
ovulation, the egg is released into the abdominal cavity near the opening of
the oviduct.
°
The
cilia-lined funnel-like opening of the oviduct draws in the egg.
°
Cilia
convey the egg through the oviduct to the uterus.
°
The
highly vascularized inner lining of the uterus is called the endometrium.
°
The
neck of the uterus, the cervix,
opens into the vagina.
°
The
vagina is a thin-walled chamber that
forms the birth canal and is the repository for sperm during copulation.
°
It
opens to the outside at the vulva,
the collective term for the external female genitalia.
·
The
vaginal opening is partially covered by a thin sheet of tissue called the hymen.
°
The
vaginal and urethral openings are located within a recess called the vestibule.
§
The
vestibule is surrounded by a pair of slender folds called the labia minora.
§
The
labia majora enclose and protect the
labia minora and vestibule.
§
The
clitoris is found at the front edge
of the vestibule.
·
During
sexual arousal, the clitoris, vagina, and labia engorge with blood and enlarge.
°
During
sexual arousal, Bartholin’s glands
secrete mucus into the vestibule, providing lubrication and facilitating
intercourse.
·
Mammary glands are present in both males
and females but normally function only in females.
°
They
are not a component of the human reproductive system but are important to
mammalian reproduction.
°
Within
the glands, small sacs of epithelial tissue secrete milk, which drains into a
series of ducts opening at the nipple.
°
Adipose
tissue forms the main mass of the mammary gland of a nonlactating mammal.
·
The
low estrogen level in males prevents the development of the sensory apparatus
and fat deposits, so that male breasts remain small, with nipples unconnected
to the ducts.
·
The
male’s external reproductive organs consist of the scrotum and penis.
·
The
internal reproductive organs consist of gonads that produce sperm and hormones,
accessory glands that secrete products essential to sperm movement, and ducts
to carry the sperm and glandular secretions.
°
The
male gonads, or testes, consist of
highly coiled tubes surrounded by layers of connective tissue.
°
The
tubes are seminiferous tubules, where
sperm are produced.
°
Leydig cells scattered between the
seminiferous tubules produce testosterone and other androgens.
°
The
scrotum, a fold in the body wall,
holds the testes outside the body cavity at a temperature about 2°C below that
of the abdomen.
§
This
keeps testicular temperature cooler than that in the body cavity.
°
The
testes develop in the body cavity and descend into the scrotum just before
birth.
·
From
the seminiferous tubules of the testes, the sperm pass through the coiled
tubules of the epididymis.
°
As
they pass through this duct, sperm become motile and gain the ability to
fertilize an egg.
·
Ejaculation propels sperm from the
epididymis to the vas deferens.
°
The
vas deferens run from the scrotum
and behind the urinary bladder.
°
Each
vas deferens joins with a duct from the seminal vesicle to form an ejaculatory duct.
°
The
ejaculatory ducts open into the urethra.
°
The
urethra drains both the excretory and reproductive systems.
·
Accessory
sex glands add secretions to semen.
°
A
pair of seminal vesicles contributes
about 60% of total semen volume.
§
Seminal
fluid is thick, yellowish, and alkaline.
§
It
contains mucus, fructose, a coagulating enzyme, ascorbic acid, and
prostaglandins.
·
The
prostate gland secretes directly
into the urethra.
°
Prostatic
fluid is thin and milky.
°
This
fluid contains anticoagulant enzymes and citrate.
·
Prostate
problems are common in males older than 40.
°
Benign
prostate enlargement occurs in virtually all males older than 70.
°
Prostate
cancer is one of the most common cancers in men.
·
The
bulbourethral glands are a pair of
small glands along the urethra below the prostate.
°
Prior
to ejaculation, they secrete clear mucus that neutralizes any acidic urine
remaining in the urethra.
°
Bulbourethral
fluid also carries some sperm released before ejaculation.
°
This
is one of the reasons the withdrawal method of birth control has a high failure
rate.
·
A
male usually ejaculates about 2–5 mL of semen, with each milliliter containing
about 50–130 million sperm.
·
Once
in the female reproductive tract, prostaglandins in semen thin the mucus at the
opening of the uterus and stimulate uterine contractions that help move the
semen.
°
When
ejaculated, semen coagulates, making it easier for uterine contractions to move
it along.
§
Anticoagulants
then liquefy the semen, and the sperm begin swimming.
°
The
alkalinity of semen helps neutralize the acidic environment of the vagina,
protecting the sperm and increasing their motility.
·
The
human penis is composed of three
layers of spongy erectile tissue.
°
During
sexual arousal, the erectile tissue fills with blood from arteries.
§
The
resultant increased pressure seals off the veins that drain the penis, causing
it to engorge with blood.
à
The
engorgement of the penis with blood causes an erection, which is essential for
the insertion of the penis into the vagina.
·
The
penis of some mammals possesses a baculum,
a bone that helps stiffen the penis.
·
Temporary
impotence can result from the consumption of alcohol or other drugs, and from
emotional problems.
·
Irreversible
impotence due to nervous system or circulatory problems can be treated with
drugs and penile implant devices.
°
The
oral drug Viagra acts by promoting the action of nitric oxide, enhancing
relaxation of smooth muscles in the blood vessels of the penis.
§
This
allows blood to enter the erectile tissue and sustain an erection.
·
The
main shaft of the penis is covered by relatively thick skin.
°
The
sensitive head, or glans penis, is
covered by thinner skin.
°
The
glans is covered by the foreskin, or prepuce,
which may be removed by circumcision.
°
There
is no verifiable health benefit to circumcision, which arose from religious
tradition.
Human sexual response is very complex.
·
Human
arousal involves a variety of psychological and physical factors.
·
Human
sexual response is characterized by a common physiological pattern.
°
Two
types of physiological reaction predominate in both sexes:
1. Vasocongestion, filling of tissue with blood, is caused by
increased blood flow.
2. Myotonia is increased muscle tension.
à
Both
smooth and skeletal muscle may show sustained or rhythmic contractions.
·
The
sexual response can be divided into four phases: excitement, plateau, orgasm,
and resolution.
·
Excitement
prepares the vagina and penis for coitus.
°
Vasocongestion
is evident in the erection of the penis and clitoris; the enlargement of the
testes, labia, and breasts; and vaginal lubrication.
°
Myotonia
may result in nipple erection or tension in the arms and legs.
·
In
the plateau phase, these responses continue.
°
Stimulation
by the autonomic nervous system increases breathing and heart rate.
°
In
females, plateau includes vasocongestion of the outer third of the vagina,
expansion of the inner two-thirds of the vagina, and elevation of the uterus to
form a depression that receives sperm at the back of the vagina.
·
Orgasm is the shortest phase of
the sexual response cycle.
°
It
is characterized by rhythmic, involuntary contractions of the reproductive
structures in both sexes.
°
In
male orgasm, emission is the contraction of the glands and ducts of the
reproductive tract, which forces semen into the urethra.
°
Ejaculation
occurs with the contraction of the urethra and expulsion of semen.
°
In
female orgasm, the uterus and outer vagina contract.
·
Resolution
completes the cycle and reverses the responses of earlier stages.
°
Vasocongested
organs return to their normal sizes and colors; muscles relax.
Concept 46.4 In humans and other
mammals, a complex interplay of hormones regulates gametogenesis
Spermatogenesis and oogenesis both involve
meiosis but differ in three significant ways.
·
Gametogenesis is based on meiosis.
·
Spermatogenesis is the production of
mature sperm cells from spermatogonia.
°
Spermatogenesis
is a continuous and prolific process in the adult male.
°
Each
ejaculation contains 100–650 million sperm.
·
Spermatogenesis
occurs in seminiferous tubules.
°
Primordial
germ cells of the embryonic testes differentiate into spermatogonia, the stem
cells that give rise to sperm.
°
As
spermatogonia differentiate into spermatocytes and then into spermatids,
meiosis reduces the chromosome number from diploid to haploid.
°
As
spermatogenesis progresses, the developing sperm cells move from the wall to
the lumen of a seminiferous tubule and then to the epididymis, where they
become motile.
·
The
structure of sperm fits its function.
°
A
head containing the haploid nucleus is tipped with an acrosome, which contains enzymes that help the sperm penetrate to
the egg.
°
Behind
the head are a large number of mitochondria (or a single large one) that
provide ATP to power the flagellum.
·
Oogenesis is the production of ova
from oogonia.
°
Oogenesis
differs from spermatogenesis in three major ways.
1. At birth an ovary may
contain all of the primary oocytes
it will ever have.
§
However,
in 2004, researchers reported that multiplying oogonia exist in the ovaries of
adult mice.
à
Researchers
are looking for similar cells in human ovaries.
§
Sperm
are produced from spermatogonia throughout a man’s life.
2. Unequal cytokinesis during
meiosis results in the formation of a single large secondary oocyte and three small polar bodies.
§
The
secondary oocyte becomes the ovum, while the polar bodies degenerate.
§
In
spermatogenesis, all four products of meiosis become mature sperm.
3. Oogenesis has long
“resting” periods.
°
Spermatogenesis
produces mature sperm from spermatogonia in an uninterrupted sequence.
·
Oogenesis
begins in the female embryo with differentiation of primordial germ cells into oogonia, ovary-specific stem cells.
°
An
oogonium multiplies by mitosis and begins meiosis, but the process stops at
prophase I.
°
The
primary oocytes remain quiescent
within small follicles until puberty.
°
Beginning
at puberty, follicle-stimulating hormone (FSH) stimulates a follicle to grow
and induces its primary oocyte to complete meiosis I and start meiosis II.
§
It
is arrested at metaphase II as a secondary oocyte.
°
The
secondary oocyte is released when
the follicle breaks open at ovulation.
°
Meiosis
is completed when a sperm penetrates the oocyte.
§
Oogenesis
is completed, producing an ovum.
°
The
haploid nuclei of the sperm and ovum fuse in fertilization.
°
The
ruptured follicle develops into the corpus luteum.
§
If
the released oocyte is not fertilized, the corpus luteum degenerates.
·
In
females, the secretion of hormones and the reproductive events they regulate
are cyclic.
°
Hormonal
control of the female cycle is complex.
·
Humans
and many other primates have menstrual
cycles.
°
If
pregnancy does not occur, the endometrium is shed through the cervix and vagina
in menstruation.
·
Other
mammals have estrous cycles.
°
If
pregnancy does not occur, the uterus reabsorbs the endometrium.
°
Estrous
cycles are associated with more pronounced behavioral cycles than are menstrual
cycles.
§
The
period of sexual activity, estrus,
is the only time the condition of the vagina permits mating.
§
Human
females may be sexually receptive throughout their menstrual cycle.
·
The
term menstrual cycle refers specifically to the changes that occur in the
uterus, and is also called the uterine
cycle.
°
It
is caused by cyclic events that occur in the ovaries, the ovarian cycle.
·
The
cycle begins with the release from the hypothalamus of GnRH or
gonadotropin-releasing hormone, which stimulates the pituitary to secrete small
amounts of FSH and LH.
°
FSH
stimulates follicle growth, aided by LH, or luteinizing hormone, and the cells
of the growing follicles start to make estrogen.
·
There
is a slow rise in estrogen secreted during the follicular phase, the part of the ovarian cycle in which follicles
are growing and oocytes maturing.
·
The
low level of estrogen inhibits secretion of the pituitary hormones, keeping FSH
and LH levels low.
°
The
levels of FSH and LH shoot up when the secretion of estrogen by the growing
follicle rises sharply.
§
The
high concentration of estrogen stimulates the secretion of gonadotropins by
acting on the hypothalamus to increase its output of GnRH.
§
This
stimulates the secretion of FSH and LH.
§
LH
secretion is especially high, because the high concentration of estrogen
increases the sensitivity of LH-releasing cells in the pituitary to GnRH.
§
LH
induces the final maturation of the follicle and ovulation.
§
The
follicle and adjacent wall of the ovary rupture, releasing the secondary
oocyte.
·
Following
ovulation, during the luteal phase
of the ovarian cycle, LH stimulates the transformation of the follicle into the
corpus luteum, a glandular structure.
·
Under
the continued stimulation by LH during this phase, the corpus luteum secretes
progesterone and estrogen.
°
As
the levels of these hormones rise, they exert negative feedback on the
hypothalamus and pituitary, inhibiting the secretion of LH and FSH.
·
Near
the end of the luteal phase, the corpus luteum disintegrates, causing
concentrations of estrogen and progesterone to decline.
°
The
pituitary and hypothalamus are liberated from the inhibitory effects of these
hormones.
°
The
pituitary begins to secrete enough FSH to stimulate the growth of new follicles
in the ovary, initiating the next ovarian cycle.
·
The
follicular phase of the ovarian cycle is coordinated with the proliferative phase of the menstrual
cycle.
°
Secretion
of estrogens during the follicular phase stimulates endometrial thickening.
°
The
estrogen and progesterone of the luteal phase stimulate development and
maintenance of the endometrium, including the enlargement of arteries and the
growth of endometrial glands.
§
The
glands secrete a nutrient fluid that can sustain an early embryo before it
implants in the uterine lining.
§
Thus,
the luteal phase of the ovarian cycle is coordinated with the secretory phase of the uterine cycle.
·
The
rapid drop in ovarian hormones as the corpus luteum disintegrates causes spasms
in the uterine lining, depriving it of blood.
·
The
upper two-thirds of the endometrium disintegrates, resulting in menstruation,
or the menstrual flow phase of the
uterine cycle, and the beginning of a new cycle.
·
During
menstruation, new ovarian follicles begin to grow.
°
Estrogen
is also responsible for female secondary sex characteristics, including
deposition of fat in the breasts and hips, increased water retention, and
stimulation of breast development.
°
It
also influences sexual behavior.
·
Menopause, the cessation of ovarian
and menstrual cycles, usually occurs between ages 46 and 54.
°
During
these years, the ovaries lose their responsiveness to FSH and LH, and menopause
results from a decline in estrogen production by the ovary.
·
Menopause
is an unusual phenomenon.
°
In
most species, females and males retain their reproductive capacity throughout
life.
·
There
might be an evolutionary explanation for menopause.
°
One
hypothesis proposes that cessation of reproduction allowed a woman to provide
better care for her children and grandchildren, increasing the survival of
individuals bearing her genes and increasing her fitness.
The principle sex hormones in the male are the
androgens.
·
The
male sex hormones, androgens, are steroid hormones produced mainly by the
Leydig cells of the testes, interstitial cells near the seminiferous tubules.
·
Testosterone,
the most important male androgen, and other androgens are responsible for the
primary and secondary male sex characteristics.
°
Primary
sex characteristics are associated with the development of the vas deferens and
other ducts, development of the external reproductive structures, and sperm
production.
°
Secondary
sex characteristics are features not directly related to the reproductive
system, including deepening of the voice, distribution of facial and pubic
hair, and muscle growth.
·
Androgens
also affect behavior.
°
In
addition to specific sexual behaviors and sex drive, androgens increase general
aggressiveness.
°
They
are responsible for vocal behavior, like singing in birds and calling by frogs.
·
Hormones
from the anterior pituitary and hypothalamus control androgen secretion and
sperm production by the testes.
Concept 46.5 In humans and other placental
mammals, an embryo grows into a newborn in the mother’s uterus
·
In
placental mammals, pregnancy or gestation is the condition of carrying
one or more embryos.
°
A
human pregnancy averages 266 days.
°
Many
rodents have gestation periods of 21 days. Cows have a gestation of 27 days,
and elephant gestation lasts 600 days.
·
Fertilization
or conception occurs in the oviduct.
°
Twenty-four
hours later, cleavage begins.
°
Three
to four days after fertilization, the embryo reaches the uterus as a ball of
cells.
°
By
one week past fertilization, the blastocyst
forms as a sphere of cells containing a cavity.
°
After
a few more days, the blastocyst implants in the endometrium.
·
The
embryo secretes hormones to signal its presence and control the mother’s
reproductive system.
°
Human chorionic
gonadotropin (HCG)
acts like pituitary LH to maintain secretion of progesterone and estrogens by
the corpus luteum for the first few weeks of pregnancy.
°
Some
HCG is excreted in the urine, where it is detected by pregnancy tests.
·
Human
gestation is divided into three trimesters
of three months each.
°
For
the first 2–4 weeks of development, the embryo obtains nutrients from the
endometrium.
°
The
outer layer of the blastocyst, called the trophoblast
invades the endometrium, eventually helping to form the placenta.
§
The
placenta allows diffusion of material between maternal and embryonic circulations,
providing nutrients, exchanging respiratory gases, and disposing of metabolic
wastes for the embryo.
°
Blood
from the embryo travels to the placenta and returns via the umbilical vein.
°
Organogenesis occurs during the first
trimester.
§
By
the end of week four, the heart is beating.
§
By
the end of week eight, all the major structures of the adult are present in
rudimentary form.
§
The
rapidity of development makes this a time when the embryo is especially
sensitive to environmental insults such as radiation or drugs.
°
High
levels of progesterone initiate changes in the maternal reproductive system.
§
These
include increased mucus in the cervix to form a protective plug, growth of the
maternal part of the placenta, enlargement of the uterus, and cessation of
ovarian and menstrual cycling.
§
The
breasts enlarge rapidly and may be very tender.
·
During
the second trimester, the fetus grows rapidly to 30 cm and is very active.
°
The
mother may feel movements during the early part of the second trimester.
°
Hormonal
levels stabilize as HCG declines, the corpus luteum deteriorates, and the
placenta takes over the secretion of progesterone, which maintains the
pregnancy.
·
During
the third trimester, the fetus grows rapidly to about 3–4 kg in weight and 50
cm in length.
°
Fetal
activity may decrease as the fetus fills the space available to it.
°
Maternal
abdominal organs become compressed and displaced, leading to frequent
urination, digestive blockages, and back strain.
·
A
complex interplay of local regulators (prostaglandins) and hormones (estrogen
and oxytocin) induces and regulates labor.
·
The
mechanism that triggers labor is not
fully understood.
°
In
one possible model, high levels of estrogen induce the formation of oxytocin
receptors on the uterus.
°
Oxytocin,
produced by the fetus and the mother’s posterior pituitary, stimulates powerful
contractions by the smooth muscles of the uterus.
°
Oxytocin
also stimulates the placenta to secrete prostaglandins, which enhance the
contractions.
°
The
physical and emotional stress associated with the contractions stimulate the
release of more oxytocin and prostaglandins, a positive feedback system that
underlies the process of labor.
·
Birth,
or parturition, is brought about by
strong, rhythmic uterine contractions.
°
The
process of labor has three stages.
§
The
first stage is the opening up and thinning of the cervix, ending in complete
dilation.
§
The
second stage is the expulsion of the baby as a result of strong uterine
contractions.
§
The
third stage is the expulsion of the placenta.
·
Lactation is unique to mammals.
°
After
birth, decreasing levels of progesterone free the anterior pituitary from
negative feedback and allow prolactin secretion.
°
Prolactin
stimulates milk production 2–3 days after birth.
°
The
release of milk from the mammary glands is controlled by oxytocin.
·
Reproductive
immunologists are working to understand why mammalian mothers do not reject the
embryo as a foreign body, despite its paternal antigens.
°
The
trophoblast may inhibit a maternal immune response against the embryo by
releasing signal molecules with immunosuppressive effects.
§
These
include HCG, a variety of protein “factors,” a prostaglandin, several
interleukins, and an interferon.
§
Some
combination of these substances may interfere with immune rejection by acting
on the mother’s T lymphocytes.
°
A
different hypothesis suggests that the trophoblast and later the placenta
secrete an enzyme that rapidly breaks down local supplies of tryptophan, an
amino acid necessary for T cell survival and function.
§
This
enzyme is essential for maintaining pregnancy in mice.
°
Another
possibility is the absence of certain histocompatibility antigens on placenta
cells and the secretion of a hormone that induces synthesis of a “death
activator” protein (FasL) on placental cells.
§
Activated
T cells have a complementary “death receptor” (Fas), and the binding of FasL to
Fas causes the T cells to self-destruct by apoptosis.
°
Contraception can be achieved in
several ways.
§
Some
methods prevent the release of mature secondary oocytes and sperm from gonads,
others prevent fertilization by keeping sperm and egg apart, and still others
prevent implantation of an embryo.
°
Fertilization
can be prevented by abstinence from sexual intercourse or by any of several
barriers that keep sperm and egg apart.
§
Temporary
abstinence is called the rhythm method
of birth control.
à
This
means of natural family planning
depends on refraining from intercourse when conception is most likely.
§
Ovulation
can be detected by noting changes in cervical mucus and body temperature during
the menstrual cycle.
§
Natural
family planning brings a pregnancy rate of 10–20%.
°
As
a method of preventing fertilization, coitus interruptus, or withdrawal
(removal of the penis from the vagina before ejaculation), is unreliable.
§
Sperm
may be present in secretions that precede ejaculation.
·
The
several barrier methods of
contraception that block sperm from meeting the egg have pregnancy rates of
less than 10%.
°
The
condom used by the male is a thin
latex or natural membrane sheath that fits over the penis to collect the semen.
°
The
diaphragm is a dome-shaped rubber
cap that fits into the upper portion of the vagina before intercourse.
°
Both
methods are more effective when used in conjunction with a spermicide.
·
Birth control pills are chemical
contraceptives with a pregnancy rate of less than 1%.
°
The
most commonly used birth control pills are a combination of a synthetic
estrogen and progestin (progesterone-like hormone).
°
This
combination acts by negative feedback to stop the release of GnRH by the
hypothalamus and, thus, of FSH and LH by the pituitary.
§
The
prevention of LH release prevents ovulation.
§
As
a backup mechanism, the inhibition of FSH secretion by the low dose of estrogen
in the pills prevents follicles from developing.
°
A
second type of birth control pill, the minipill, contains only progestin.
°
It
does not effectively block ovulation, and it is not as effective a
contraceptive as the combination pill.
§
The
minipill prevents fertilization mainly by causing thickening of a woman’s
cervical mucus so it blocks sperm from entering the uterus.
§
It
also causes changes in the endometrium that interfere with implantation.
°
Combination
pills carry a slightly elevated risk of abnormal blood clotting, high blood
pressure, heart attack, and stroke.
§
However,
they decrease the risk of ovarian and endometrial cancers.
°
Sterilization
is the permanent prevention of gamete release.
§
Tubal ligation in women involves
cauterization or ligation of a section of the oviducts to prevent the eggs from
traveling into the uterus.
§
Vasectomy in men is the cutting of
each vas deferens to prevent sperm from entering the urethra.
°
Abortion is the termination of a
pregnancy.
§
Spontaneous
abortion or miscarriage occurs in as many of one-third of all pregnancies.
§
In
addition, 1.5 million American women choose abortions performed by physicians
each year.
§
A
drug called mifepristone, or RU-486, enables a woman to terminate pregnancy
nonsurgically within the first seven weeks.
à
An
analogue of progesterone, RU-486 blocks progesterone reception in the uterus,
preventing progesterone from maintaining pregnancy.
à
It
is taken with a small amount of prostaglandin to induce uterine contractions.
Modern technology offers solutions for some
reproductive problems.
·
It
is now possible to diagnose many genetic and congenital abnormalities while the
fetus is in the uterus.
·
Amniocentesis
and chorionic villus sampling are invasive techniques in which amniotic fluid
or fetal cells are obtained for genetic analysis.
·
Commonly
used noninvasive techniques use ultrasound imaging to detect fetal conditions.
°
A
newer noninvasive method uses the fact that maternal blood contains fetal blood
cells that can be tested.
°
A
maternal blood sample yields fetal cells that can be identified by specific
antibodies and tested for genetic disorders.
·
Reproductive
technology can help with infertility treatments.
°
Hormone
therapy can increase sperm and egg production.
°
Surgery
can correct blocked oviducts.
·
Many
infertile couples use assisted reproductive technology (ART).
°
These
procedures involve surgical removal of secondary oocytes from a woman’s body,
fertilizing them, and returning them to the woman’s body.
§
With
in
vitro fertilization, the most common ART procedure, the oocytes are
mixed with sperm in culture dishes and inserted in the woman’s uterus at the
eight-cell stage or beyond.
§
In
ZIFT (zygote intrafallopian transfer), eggs are also fertilized in vitro, but zygotes are transferred
immediately to the woman’s fallopian tubes.
§
In
GIFT (gamete intrafallopian transfer), the eggs are not fertilized in vitro.
à
Instead,
the eggs and sperm are placed in the woman’s oviducts in the hope that
fertilization will occur there.
·
These
techniques are performed throughout the world and have resulted in thousands of
children.