1. Reproduction and Development
Chapters 46 and 47 Campbell 9th

2. Major vestibular (Bartholin’s) gland Labia minora Labia majora
Figure 46.10
Oviduct
Ovary
Uterus
(Urinary bladder)
(Pubic bone)
(Rectum)
Urethra
Cervix
Body
Vagina
Glans
Clitoris
Prepuce
Major vestibular (Bartholin’s) gland
Labia minora
Labia majora
Vaginal opening
Oviduct
Ovaries
Figure Reproductive anatomy of the human female.
Follicles
Corpus luteum
Uterus
Uterine wall
Endometrium
Cervix
Vagina

3. (Urinary bladder) Seminal vesicle (Urinary duct) (Rectum) (Pubic bone)
Figure 46.11b
(Urinary bladder)
Seminal vesicle
(Urinary duct)
(Rectum)
(Pubic bone)
Vas deferens
Erectile tissue
Ejaculatory duct
Prostate gland
Figure Reproductive anatomy of the human male.
Urethra
Penis
Bulbourethral gland
Vas deferens
Glans
Epididymis
Testis
Prepuce
Scrotum

4. Gametogenesis
Gametogenesis, the production of gametes, differs in male and female, reflecting the distinct structure and function of their gametes
Sperm are small and motile and must pass from male to female
Eggs are larger and carry out their function within the female
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5. Oogenesis, the development of a mature egg, is a prolonged process
Spermatogenesis, the development of sperm, is continuous and prolific (millions of sperm are produced per day; each sperm takes about 7 weeks to develop
Oogenesis, the development of a mature egg, is a prolonged process
Immature eggs form in the female embryo but do not complete their development until years or decades later
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6. Spermatogenesis differs from oogenesis in three ways
All four products of meiosis develop into sperm while only one of the four becomes an egg
Spermatogenesis occurs throughout adolescence and adulthood
Sperm are produced continuously without the prolonged interruptions in oogenesis
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7. Figure 46.12 Exploring: Human Gametogenesis
Figure 46.12a
Epididymis
Seminiferous tubule
Testis
Primordial germ cell in embryo
Cross section of seminiferous tubule
Mitotic divisions
Spermatogonial stem cell 2n
Mitotic divisions
Sertoli cell nucleus
Spermatogonium 2n
Mitotic divisions
Primary spermatocyte 2n
Meiosis I
Figure Exploring: Human Gametogenesis
Secondary spermatocyte n n
Meiosis II
Lumen of seminiferous tubule
Spermatids (two stages)
Early spermatid
Neck n n n n
Tail
Midpiece
Head
Differentiation (Sertoli cells provide nutrients)
Plasma membrane
Sperm cell n n
Acrosome n n
Nucleus
Mitochondria

8. Primordial germ cell in embryo Mitotic divisions
Figure 46.12ab
Primordial germ cell in embryo
Mitotic divisions
Spermatogonial stem cell 2n
Mitotic divisions
Spermatogonium 2n
Mitotic divisions
Primary spermatocyte 2n
Meiosis I
Secondary spermatocyte n n
Meiosis II
Figure Exploring: Human Gametogenesis
Early spermatid n n n n
Differentiation (Sertoli cells provide nutrients)
Sperm cell n n n n

9. Figure 46.12 Exploring: Human Gametogenesis
Figure 46.12b
Primary oocyte within follicle
Ovary
Growing follicle
Primordial germ cell
In embryo
Mitotic divisions 2n
Oogonium
Mitotic divisions
Primary oocyte (present at birth), arrested in prophase of meiosis I
Mature follicle 2n
Ruptured follicle
Completion of meiosis I and onset of meiosis II
First polar body n n
Secondary oocyte, arrested at metaphase of meiosis II
Ovulated secondary oocyte
Figure Exploring: Human Gametogenesis
Ovulation, sperm entry
Completion of meiosis II
Second polar body
Corpus luteum n
Fertilized egg n
Degenerating corpus luteum

10. Primary oocyte (present at birth), arrested in prophase of meiosis I
Figure 46.12bb
Primordial germ cell
In embryo
Mitotic divisions 2n
Oogonium
Mitotic divisions
Primary oocyte (present at birth), arrested in prophase of meiosis I 2n
Completion of meiosis I and onset of meiosis II
First polar body n n
Secondary oocyte, arrested at metaphase of meiosis II
Ovulation, sperm entry
Figure Exploring: Human Gametogenesis
Completion of meiosis II
Second polar body n
Fertilized egg n

11. Hormones of Female Reproduction
Stop Here and Do the Handout first

12. Concept 46.4: The interplay of tropic and sex hormones regulates mammalian reproduction
Human reproduction is coordinated by hormones from the hypothalamus, anterior pituitary, and gonads
Gonadotropin-releasing hormone (GnRH) is secreted by the hypothalamus and directs the release of FSH and LH from the anterior pituitary
FSH and LH regulate processes in the gonads and the production of sex hormones
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13. Hormonal Control of the Female Reproductive Cycles
In females, the secretion of hormones and the reproductive events they regulate are cyclic
Prior to ovulation, the endometrium thickens with blood vessels in preparation for embryo implantation
If an embryo does not implant in the endometrium, the endometrium is shed in a process called menstruation
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14. Degenerating corpus luteum
Figure 46.13
(a)
Control by hypothalamus
Inhibited by combination of estradiol and progesterone
Hypothalamus 
Stimulated by high levels of estradiol 1
GnRH 
Anterior pituitary
Inhibited by low levels of estradiol  2
FSH LH
(b)
Pituitary gonadotropins in blood 6 LH
FSH 3
FSH and LH stimulate follicle to grow
LH surge triggers ovulation
(c)
Ovarian cycle 7 8
Growing follicle
Corpus luteum
Degenerating corpus luteum
Maturing follicle
Follicular phase
Ovulation
Luteal phase
Estradiol secreted by growing follicle in increasing amounts
Progesterone and estradiol secreted by corpus luteum 4
(d)
Ovarian hormones in blood
Peak causes LH surge (see ) 5 6
Figure The reproductive cycle of the human female. 10
Estradiol 9
Progesterone
Estradiol level very low
Progesterone and estra- diol promote thickening of endometrium
(e)
Uterine (menstrual) cycle
Endometrium
Menstrual flow phase
Proliferative phase
Secretory phase
Days 5 10 14 15 20 25 28

15.  Hypothalamus GnRH   Anterior pituitary FSH LH Negative feedback
Figure 46.14 
Hypothalamus
GnRH  
Anterior pituitary
FSH LH
Negative feedback
Negative feedback
Sertoli cells
Leydig cells
Figure Hormonal control of the testes.
Inhibin
Spermatogenesis
Testosterone
Testis

16. Early Development
During its first 2 to 4 weeks, the embryo obtains nutrients directly from the endometrium
Meanwhile, the outer layer of the blastocyst, called the trophoblast, mingles with the endometrium and eventually forms the placenta
Blood from the embryo travels to the placenta through arteries of the umbilical cord and returns via the umbilical vein
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17. Maternal portion of placenta
Figure 46.16
Maternal arteries
Maternal veins
Placenta
Umbilical cord
Maternal portion of placenta
Chorionic villus, containing fetal capillaries
Fetal portion of placenta (chorion)
Maternal blood pool
Figure Placental circulation.
Uterus
Fetal arteriole
Fetal venule
Umbilical arteries
Umbilical cord
Umbilical vein

18. from fetus and mother’s posterior pituitary
Figure 46.18
Estradiol
Oxytocin 
from ovaries
from fetus and mother’s posterior pituitary
Activates oxytocin receptors on uterus
Stimulates uterus to contract
Positive feedback
Stimulates placenta to make 
Prostaglandins
Figure Positive feedback in labor.
Stimulate more contractions of uterus

19. Expulsion: delivery of the infant
Figure 46.19
Placenta
Umbilical cord
Uterus
Cervix 1
Dilation of the cervix 2
Expulsion: delivery of the infant
Figure The three stages of labor.
Uterus
Placenta (detaching)
Umbilical cord 3
Delivery of the placenta

20. The importance of cell-cell communication.
Development
The importance of cell-cell communication.

21. 8-cell stage (viewed from the animal pole)
Figure 47.7
Zygote
2-cell stage forming
Gray crescent
0.25 mm
8-cell stage (viewed from the animal pole)
4-cell stage forming
Animal pole
8-cell stage
Figure 47.7 Cleavage in a frog embryo.
0.25 mm
Blastula (at least 128 cells)
Vegetal pole
Blastocoel
Blastula (cross section)

22. In pairs write the following terms in order.
Gastrula
Morula
Blastula
Zygote

23. Terminology of Stages of Development
ZYGOTE
MORULA SOLID BALL
EMBRYO
BLASTULA (BLASTOCYST IN MAMMALS)
GASTRULA

24. Concept 47.2: Morphogenesis in animals involves specific changes in cell shape, position, and survival
After cleavage, the rate of cell division slows and the normal cell cycle is restored
Morphogenesis, the process by which cells occupy their appropriate locations, involves
Gastrulation, the movement of cells from the blastula surface to the interior of the embryo
Organogenesis, the formation of organs
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25. Gastrulation
Gastrulation rearranges the cells of a blastula into a three-layered embryo, called a gastrula
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26. Each germ layer contributes to specific structures in the adult animal
The three layers produced by gastrulation are called embryonic germ layers
The ectoderm forms the outer layer
The mesoderm partly fills the space between the endoderm and ectoderm
The endoderm lines the digestive tract
Each germ layer contributes to specific structures in the adult animal
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27. ECTODERM (outer layer of embryo)
Figure 47.8
ECTODERM (outer layer of embryo)
• Epidermis of skin and its derivatives (including sweat glands, hair follicles)
• Nervous and sensory systems
• Pituitary gland, adrenal medulla
• Jaws and teeth
• Germ cells
MESODERM (middle layer of embryo)
• Skeletal and muscular systems
• Circulatory and lymphatic systems
• Excretory and reproductive systems (except germ cells)
• Dermis of skin
• Adrenal cortex
Figure 47.8 Major derivatives of the three embryonic germ layers in vertebrates.
ENDODERM (inner layer of embryo)
• Epithelial lining of digestive tract and associated organs (liver, pancreas)
• Epithelial lining of respiratory, excretory, and reproductive tracts and ducts
• Thymus, thyroid, and parathyroid glands

29. MEMBRANES
The four extraembryonic membranes that form around the embryo arise from the amniotic egg
The chorion functions in gas exchange
The amnion encloses the amniotic fluid
The yolk sac encloses the yolk
The allantois disposes of waste products and contributes to gas exchange
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30. Organogenesis
During organogenesis, various regions of the germ layers develop into rudimentary organs
Early in vertebrate organogenesis, the notochord forms from mesoderm, and the neural plate forms from ectoderm
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31. Figure 47.13
Neural folds
Eye
Somites
Tail bud
Neural fold
Neural plate
SEM
1 mm
1 mm
Neural tube
Neural crest cells
Neural fold
Neural plate
Notochord
Neural crest cells
Coelom
Notochord
Ectoderm
Somite
Figure Neurulation in a frog embryo.
Mesoderm
Outer layer of ectoderm
Archenteron (digestive cavity)
Endoderm
Neural crest cells
(c) Somites
Archenteron
(a) Neural plate formation
Neural tube
(b) Neural tube formation

32. The neural plate soon curves inward, forming the neural tube
The neural tube will become the central nervous system (brain and spinal cord)
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33. Mesoderm lateral to the notochord forms blocks called somites
Neural crest cells develop along the neural tube of vertebrates and form various parts of the embryo (nerves, parts of teeth, skull bones, and so on)
Mesoderm lateral to the notochord forms blocks called somites
Lateral to the somites, the mesoderm splits to form the coelom (body cavity)
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34. Archenteron (digestive cavity)
Figure 47.13c
Eye
Somites
Tail bud
SEM
1 mm
Neural tube
Neural crest cells
Notochord
Coelom
Figure Neurulation in a frog embryo.
Somite
Archenteron (digestive cavity)
(c) Somites

35. The embryonic cells in a limb bud respond to positional information indicating location along three axes
Proximal-distal axis
Anterior-posterior axis
Dorsal-ventral axis
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36. (b) Wing of chick embryo
Figure 47.24b 2
Digits 3 4
Anterior
Ventral
Figure Vertebrate limb development.
Proximal
Distal
Dorsal
Posterior
(b) Wing of chick embryo

37. EXPERIMENT Anterior New ZPA Donor limb bud Host limb bud ZPA Posterior
Figure 47.25
EXPERIMENT
Anterior
New ZPA
Donor limb bud
Host limb bud
ZPA
Posterior
RESULTS 4
Figure Inquiry: What role does the zone of polarizing activity (ZPA) play in limb pattern formation in vertebrates? 3
What role does the zone of polarizing activity (ZPA) play in limb pattern formation in vertebrates? 2 2 3 4

38. Cell Fate Determination
Sonic hedgehog is an inductive signal for limb development
Hox genes also play roles during limb pattern formation
Read Cell Fate Determination and Pattern Formation
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39. Cilia and Cell Fate
Ciliary function is essential for proper specification of cell fate in the human embryo
Motile cilia play roles in left-right specification
Monocilia (nonmotile cilia) play roles in normal kidney development
Almost every cell has one that acts as a transporter and an antenna to receive info from other cells
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40. Figure 47.26 Kartogener’s Syndrome
Lungs
Heart
Liver
Spleen
Stomach
Figure Situs inversus, a reversal of normal left-right asymmetry in the chest and abdomen.
Large intestine
Normal location of internal organs
Location in situs inversus

41. Figure 46.12 Exploring: Human Gametogenesis
Figure 46.12a
Epididymis
Seminiferous tubule
Testis
Primordial germ cell in embryo
Cross section of seminiferous tubule
Mitotic divisions
Spermatogonial stem cell 2n
Mitotic divisions
Sertoli cell nucleus
Spermatogonium 2n
Mitotic divisions
Primary spermatocyte 2n
Meiosis I
Figure Exploring: Human Gametogenesis
Secondary spermatocyte n n
Meiosis II
Lumen of seminiferous tubule
Spermatids (two stages)
Early spermatid
Neck n n n n
Tail
Midpiece
Head
Differentiation (Sertoli cells provide nutrients)
Plasma membrane
Sperm cell n n
Acrosome n n
Nucleus
Mitochondria

42. Figure 46.12 Exploring: Human Gametogenesis
Figure 46.12b
Primary oocyte within follicle
Ovary
Growing follicle
Primordial germ cell
In embryo
Mitotic divisions 2n
Oogonium
Mitotic divisions
Primary oocyte (present at birth), arrested in prophase of meiosis I
Mature follicle 2n
Ruptured follicle
Completion of meiosis I and onset of meiosis II
First polar body n n
Secondary oocyte, arrested at metaphase of meiosis II
Ovulated secondary oocyte
Figure Exploring: Human Gametogenesis
Ovulation, sperm entry
Completion of meiosis II
Second polar body
Corpus luteum n
Fertilized egg n
Degenerating corpus luteum