1. Chapter 47
Animal Development

2. Overview: A Body-Building Plan
It is difficult to imagine that each of us began life as a single cell called a zygote
A human embryo at about 6–8 weeks after conception shows development of distinctive features

3. Fig. 47-1
Figure 47.1 How did this complex embryo form from a single cell?
1 mm

4. The question of how a zygote becomes an animal has been asked for centuries
As recently as the 18th century, the prevailing theory was called preformation
Preformation is the idea that the egg or sperm contains a miniature infant, or “homunculus,” which becomes larger during development

5. Fig. 47-2
Figure 47.2 A “homunculus” inside the head of a human sperm

6. Development is determined by the zygote’s genome and molecules in the egg called cytoplasmic determinants
Cell differentiation is the specialization of cells in structure and function
Morphogenesis is the process by which an animal takes shape

7. Model organisms are species that are representative of a larger group and easily studied, for example, Drosophila and Caenorhabditis elegans
Classic embryological studies have focused on the sea urchin, frog, chick, and the nematode C. elegans

8. Concept 47.1: After fertilization, embryonic development proceeds through cleavage, gastrulation, and organogenesis
Important events regulating development occur during fertilization and the three stages that build the animal’s body
Cleavage: cell division creates a hollow ball of cells called a blastula
Gastrulation: cells are rearranged into a three-layered gastrula
Organogenesis: the three layers interact and move to give rise to organs

9. Fertilization
Fertilization brings the haploid nuclei of sperm and egg together, forming a diploid zygote
The sperm’s contact with the egg’s surface initiates metabolic reactions in the egg that trigger the onset of embryonic development

10. The Acrosomal Reaction
The acrosomal reaction is triggered when the sperm meets the egg
The acrosome at the tip of the sperm releases hydrolytic enzymes that digest material surrounding the egg

11. Fig
Basal body (centriole)
Sperm head
Figure 47.3 The acrosomal and cortical reactions during sea urchin fertilization
For the Cell Biology Video Cortical Granule Fusion Following Egg Fertilization, go to Animation and Video Files.
Acrosome
Jelly coat
Vitelline layer
Sperm-binding receptors
Egg plasma membrane

12. Fig
Basal body (centriole)
Sperm head
Figure 47.3 The acrosomal and cortical reactions during sea urchin fertilization
Acrosome
Hydrolytic enzymes
Jelly coat
Vitelline layer
Sperm-binding receptors
Egg plasma membrane

13. Fig
Sperm nucleus
Acrosomal process
Basal body (centriole)
Actin filament
Sperm head
Figure 47.3 The acrosomal and cortical reactions during sea urchin fertilization
Acrosome
Hydrolytic enzymes
Jelly coat
Vitelline layer
Sperm-binding receptors
Egg plasma membrane

14. Fig
Sperm plasma membrane
Sperm nucleus
Acrosomal process
Basal body (centriole)
Actin filament
Sperm head
Fused plasma membranes
Figure 47.3 The acrosomal and cortical reactions during sea urchin fertilization
Acrosome
Hydrolytic enzymes
Jelly coat
Vitelline layer
Sperm-binding receptors
Egg plasma membrane

15. Fig
Sperm plasma membrane
Sperm nucleus
Fertilization envelope
Acrosomal process
Basal body (centriole)
Actin filament
Sperm head
Cortical granule
Fused plasma membranes
Figure 47.3 The acrosomal and cortical reactions during sea urchin fertilization
Perivitelline space
Acrosome
Hydrolytic enzymes
Jelly coat
Vitelline layer
Sperm-binding receptors
Egg plasma membrane
EGG CYTOPLASM

16. Gamete contact and/or fusion depolarizes the egg cell membrane and sets up a fast block to polyspermy

17. The Cortical Reaction
Fusion of egg and sperm also initiates the cortical reaction
This reaction induces a rise in Ca2+ that stimulates cortical granules to release their contents outside the egg
These changes cause formation of a fertilization envelope that functions as a slow block to polyspermy

18. Fig. 47-4
EXPERIMENT
10 sec after fertilization
25 sec
35 sec
1 min
500 µm
RESULTS
1 sec before fertilization
10 sec after fertilization
20 sec
30 sec
500 µm
Figure 47.4 Is the distribution of Ca2+ in an egg correlated with formation of the fertilization envelope?
For the Cell Biology Video Calcium Release Following Egg Fertilization, go to Animation and Video Files.
For the Cell Biology Video Calcium Wave Propagation in Fish Eggs, go to Animation and Video Files.
CONCLUSION
Point of sperm nucleus entry
Spreading wave of Ca2+
Fertilization envelope

19. 10 sec after fertilization 25 sec 35 sec 1 min 500 µm
Fig. 47-4a
EXPERIMENT
Figure 47.4 Is the distribution of Ca2+ in an egg correlated with formation of the fertilization envelope?
10 sec after fertilization
25 sec
35 sec
1 min
500 µm

20. 1 sec before fertilization 10 sec after fertilization 20 sec 30 sec
Fig. 47-4b
RESULTS
1 sec before fertilization
Figure 47.4 Is the distribution of Ca2+ in an egg correlated with formation of the fertilization envelope?
10 sec after fertilization
20 sec
30 sec
500 µm

21. CONCLUSION Point of sperm nucleus entry Spreading wave of Ca2+
Fig. 47-4c
CONCLUSION
Point of sperm nucleus entry
Spreading wave of Ca2+
Fertilization envelope
Figure 47.4 Is the distribution of Ca2+ in an egg correlated with formation of the fertilization envelope?

22. Activation of the Egg
The sharp rise in Ca2+ in the egg’s cytosol increases the rates of cellular respiration and protein synthesis by the egg cell
With these rapid changes in metabolism, the egg is said to be activated
The sperm nucleus merges with the egg nucleus and cell division begins

23. Fertilization in Mammals
Fertilization in mammals and other terrestrial animals is internal
In mammalian fertilization, the cortical reaction modifies the zona pellucida, the extracellular matrix of the egg, as a slow block to polyspermy

24. Zona pellucida Follicle cell Sperm nucleus Cortical granules
Fig. 47-5
Zona pellucida
Follicle cell
Figure 47.5 Fertilization in mammals
Sperm nucleus
Cortical granules
Sperm basal body

25. In mammals the first cell division occurs 12–36 hours after sperm binding
The diploid nucleus forms after this first division of the zygote

26. Cleavage
Fertilization is followed by cleavage, a period of rapid cell division without growth
Cleavage partitions the cytoplasm of one large cell into many smaller cells called blastomeres
The blastula is a ball of cells with a fluid-filled cavity called a blastocoel

27. (a) Fertilized egg (b) Four-cell stage (c) Early blastula
Fig. 47-6
(a) Fertilized egg
Figure 47.6 Cleavage in an echinoderm embryo
(b) Four-cell stage
(c) Early blastula
(d) Later blastula

28. (a) Fertilized egg Fig. 47-6a
Figure 47.6 Cleavage in an echinoderm embryo
(a) Fertilized egg

29. (b) Four-cell stage Fig. 47-6b
Figure 47.6 Cleavage in an echinoderm embryo
(b) Four-cell stage

30. (c) Early blastula Fig. 47-6c
Figure 47.6 Cleavage in an echinoderm embryo
(c) Early blastula

31. (d) Later blastula Fig. 47-6d
Figure 47.6 Cleavage in an echinoderm embryo
(d) Later blastula

32. The eggs and zygotes of many animals, except mammals, have a definite polarity
The polarity is defined by distribution of yolk (stored nutrients)
The vegetal pole has more yolk; the animal pole has less yolk

33. The three body axes are established by the egg’s polarity and by a cortical rotation following binding of the sperm
Cortical rotation exposes a gray crescent opposite to the point of sperm entry

34. (a) The three axes of the fully developed embryo
Fig. 47-7
Dorsal
Right
Anterior
Posterior
Left
Ventral
(a) The three axes of the fully developed embryo
Animal pole
Pigmented cortex
First cleavage
Animal hemisphere
Point of sperm nucleus entry
Figure 47.7 The body axes and their establishment in an amphibian
Future dorsal side
Vegetal hemisphere
Gray crescent
Vegetal pole
(b) Establishing the axes

35. (a) The three axes of the fully developed embryo
Fig. 47-7a
Dorsal
Right
Anterior
Posterior
Left
Ventral
Figure 47.7 The body axes and their establishment in an amphibian
(a) The three axes of the fully developed embryo

36. (b) Establishing the axes
Fig. 47-7b-1
Animal pole
Animal hemisphere
Vegetal hemisphere
Figure 47.7 The body axes and their establishment in an amphibian
Vegetal pole
(b) Establishing the axes

37. Point of sperm nucleus entry
Fig. 47-7b-2
Pigmented cortex
Point of sperm nucleus entry
Future dorsal side
Gray crescent
Figure 47.7 The body axes and their establishment in an amphibian
(b) Establishing the axes

38. (b) Establishing the axes
Fig. 47-7b-3
First cleavage
Figure 47.7 The body axes and their establishment in an amphibian
(b) Establishing the axes

39. Point of sperm nucleus entry Animal hemisphere
Fig. 47-7b-4
Animal pole
First cleavage
Pigmented cortex
Point of sperm nucleus entry
Animal hemisphere
Future dorsal side
Vegetal hemisphere
Gray crescent
Vegetal pole
Figure 47.7 The body axes and their establishment in an amphibian
(b) Establishing the axes

40. Cleavage planes usually follow a pattern that is relative to the zygote’s animal and vegetal poles

41. Zygote Fig. 47-8-1 Figure 47.8 Cleavage in a frog embryo
For the Cell Biology Video Cleavage of a Fertilized Egg, go to Animation and Video Files.

42. Fig
2-cell stage forming
Figure 47.8 Cleavage in a frog embryo

43. Fig
4-cell stage forming
Figure 47.8 Cleavage in a frog embryo

44. Animal pole 8-cell stage Vegetal pole Fig. 47-8-4
Figure 47.8 Cleavage in a frog embryo

45. Blastula (cross section)
Fig
Blastocoel
Blastula (cross section)
Figure 47.8 Cleavage in a frog embryo

46. Blastula (cross section)
Fig
0.25 mm
0.25 mm
Animal pole
Blastocoel
Figure 47.8 Cleavage in a frog embryo
Vegetal pole
Zygote
2-cell stage forming
4-cell stage forming
8-cell stage
Blastula (cross section)

47. Cell division is slowed by yolk
Holoblastic cleavage, complete division of the egg, occurs in species whose eggs have little or moderate amounts of yolk, such as sea urchins and frogs

48. Meroblastic cleavage, incomplete division of the egg, occurs in species with yolk-rich eggs, such as reptiles and birds

49. Gastrulation
Gastrulation rearranges the cells of a blastula into a three-layered embryo, called a gastrula, which has a primitive gut

50. Video: Sea Urchin Embryonic Development
The three layers produced by gastrulation are called embryonic germ layers
The ectoderm forms the outer layer
The endoderm lines the digestive tract
The mesoderm partly fills the space between the endoderm and ectoderm
Video: Sea Urchin Embryonic Development

51. Gastrulation in the sea urchin embryo
The blastula consists of a single layer of cells surrounding the blastocoel
Mesenchyme cells migrate from the vegetal pole into the blastocoel
The vegetal plate forms from the remaining cells of the vegetal pole and buckles inward through invagination

52. Gastrulation in the sea urchin embryo
The newly formed cavity is called the archenteron
This opens through the blastopore, which will become the anus

53. Future ectoderm Future mesoderm Future endoderm Animal pole Blastocoel
Fig
Future ectoderm
Future mesoderm
Future endoderm
Animal pole
Blastocoel
Mesenchyme cells
Figure 47.9 Gastrulation in a sea urchin embryo
Vegetal plate
Vegetal pole

54. Future ectoderm Future mesoderm Future endoderm Fig. 47-9-2
Figure 47.9 Gastrulation in a sea urchin embryo

55. Filopodia pulling archenteron tip
Fig
Future ectoderm
Future mesoderm
Future endoderm
Filopodia pulling archenteron tip
Figure 47.9 Gastrulation in a sea urchin embryo
Archenteron

56. Future ectoderm Future mesoderm Future endoderm Blastocoel Archenteron
Fig
Future ectoderm
Future mesoderm
Future endoderm
Blastocoel
Figure 47.9 Gastrulation in a sea urchin embryo
Archenteron
Blastopore

57. Mesenchyme (mesoderm forms future skeleton)
Fig
Future ectoderm
Future mesoderm
Future endoderm
Ectoderm
Mouth
Figure 47.9 Gastrulation in a sea urchin embryo
Mesenchyme (mesoderm forms future skeleton)
Digestive tube (endoderm)
Anus (from blastopore)

58. Figure 47.9 Gastrulation in a sea urchin embryo
Key
Future ectoderm
Future mesoderm
Future endoderm
Archenteron
Blastocoel
Filopodia pulling archenteron tip
Animal pole
Blastocoel
Archenteron
Blastocoel
Blastopore
Mesenchyme cells
Ectoderm
Vegetal plate
Vegetal pole
Mouth
Figure 47.9 Gastrulation in a sea urchin embryo
Mesenchyme cells
Mesenchyme (mesoderm forms future skeleton)
Digestive tube (endoderm)
Blastopore
50 µm
Anus (from blastopore)

59. Gastrulation in the frog
The frog blastula is many cell layers thick
Cells of the dorsal lip originate in the gray crescent and invaginate to create the archenteron
Cells continue to move from the embryo surface into the embryo by involution
These cells become the endoderm and mesoderm

60. Gastrulation in the frog
The blastopore encircles a yolk plug when gastrulation is completed
The surface of the embryo is now ectoderm, the innermost layer is endoderm, and the middle layer is mesoderm

61. Fig
SURFACE VIEW
CROSS SECTION
Animal pole
Blastocoel
Dorsal lip of blasto- pore
Dorsal lip of blastopore
Key
Blastopore
Future ectoderm
Figure Gastrulation in a frog embryo
Early gastrula
Future mesoderm
Vegetal pole
Future endoderm

62. Fig
SURFACE VIEW
CROSS SECTION
Blastocoel shrinking
Archenteron
Key
Future ectoderm
Figure Gastrulation in a frog embryo
Future mesoderm
Future endoderm

63. Fig
SURFACE VIEW
CROSS SECTION
Ectoderm
Mesoderm
Blastocoel remnant
Endoderm
Archenteron
Key
Blastopore
Future ectoderm
Figure Gastrulation in a frog embryo
Late gastrula
Future mesoderm
Blastopore
Yolk plug
Future endoderm

64. Figure 47.10 Gastrulation in a frog embryo
SURFACE VIEW
CROSS SECTION
Animal pole
Blastocoel
Dorsal lip of blasto- pore
Dorsal lip of blastopore
Blastopore
Early gastrula
Vegetal pole
Blastocoel shrinking
Archenteron
Figure Gastrulation in a frog embryo
Ectoderm
Mesoderm
Blastocoel remnant
Endoderm
Archenteron
Key
Blastopore
Future ectoderm
Future mesoderm
Late gastrula
Blastopore
Yolk plug
Future endoderm

65. Gastrulation in the chick
The embryo forms from a blastoderm and sits on top of a large yolk mass
During gastrulation, the upper layer of the blastoderm (epiblast) moves toward the midline of the blastoderm and then into the embryo toward the yolk

66. The midline thickens and is called the primitive streak
The movement of different epiblast cells gives rise to the endoderm, mesoderm, and ectoderm

67. Migrating cells (mesoderm) Hypoblast
Fig
Dorsal
Fertilized egg
Primitive streak
Anterior
Embryo
Left
Right
Yolk
Posterior
Ventral
Primitive streak
Epiblast
Future ectoderm
Figure Gastrulation in a chick embryo
Blastocoel
Endoderm
Migrating cells (mesoderm)
Hypoblast
YOLK

68. Organogenesis
During organogenesis, various regions of the germ layers develop into rudimentary organs
The frog is used as a model for organogenesis

69. Early in vertebrate organogenesis, the notochord forms from mesoderm, and the neural plate forms from ectoderm

70. Figure 47.12 Early organogenesis in a frog embryo
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
Somite
Notochord
Ectoderm
Figure Early organogenesis in a frog embryo
Archenteron (digestive cavity)
Mesoderm
Outer layer of ectoderm
Endoderm
Neural crest cells
(c) Somites
Archenteron
(a) Neural plate formation
Neural tube
(b) Neural tube formation

71. (a) Neural plate formation
Fig a
Neural fold
Neural plate
1 mm
Neural folds
Notochord
Ectoderm
Mesoderm
Figure 47.12a Early organogenesis in a frog embryo
Endoderm
Archenteron
(a) Neural plate formation

72. Video: Frog Embryo Development
The neural plate soon curves inward, forming the neural tube
The neural tube will become the central nervous system (brain and spinal cord)
Video: Frog Embryo Development

73. (b) Neural tube formation
Fig b-1
Neural fold
Neural plate
Figure 47.12b Early organogenesis in a frog embryo
(b) Neural tube formation

74. (b) Neural tube formation
Fig b-2
Figure 47.12b Early organogenesis in a frog embryo
(b) Neural tube formation

75. (b) Neural tube formation
Fig b-3
Neural crest cells
Figure 47.12b Early organogenesis in a frog embryo
(b) Neural tube formation

76. Outer layer of ectoderm
Fig b-4
Outer layer of ectoderm
Neural crest cells
Neural tube
Figure 47.12b Early organogenesis in a frog embryo
(b) Neural tube formation

77. 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

78. Archenteron (digestive cavity)
Fig c
Neural tube
Neural crest cells
Eye
Somites
Tail bud
Notochord
Coelom
Somite
Archenteron (digestive cavity)
Figure 47.12c Early organogenesis in a frog embryo
SEM
1 mm
(c) Somites

79. Organogenesis in the chick is quite similar to that in the frog

80. These layers form extraembryonic membranes
Fig
Eye
Neural tube
Notochord
Forebrain
Somite
Coelom
Heart
Archenteron
Endoderm
Lateral fold
Mesoderm
Blood vessels
Ectoderm
Somites
Yolk stalk
Yolk sac
These layers form extraembryonic membranes
Figure Organogenesis in a chick embryo
Neural tube
YOLK
(a) Early organogenesis
(b) Late organogenesis

81. These layers form extraembryonic membranes
Fig a
Neural tube
Notochord
Somite
Coelom
Archenteron
Endoderm
Lateral fold
Mesoderm
Ectoderm
Yolk stalk
Figure Organogenesis in a chick embryo
Yolk sac
These layers form extraembryonic membranes
YOLK
(a) Early organogenesis

82. (b) Late organogenesis
Fig b
Eye
Forebrain
Heart
Blood vessels
Somites
Figure Organogenesis in a chick embryo
Neural tube
(b) Late organogenesis

83. The mechanisms of organogenesis in invertebrates are similar, but the body plan is very different

84. Reproductive system (except germ cells)
Fig
ECTODERM
MESODERM
ENDODERM
Epidermis of skin and its derivatives (including sweat glands, hair follicles) Epithelial lining of mouth and anus Cornea and lens of eye Nervous system Sensory receptors in epidermis Adrenal medulla Tooth enamel Epithelium of pineal and pituitary glands
Notochord Skeletal system Muscular system Muscular layer of stomach and intestine Excretory system Circulatory and lymphatic systems
Reproductive system (except germ cells)
Dermis of skin Lining of body cavity Adrenal cortex
Epithelial lining of digestive tract Epithelial lining of respiratory system Lining of urethra, urinary bladder, and reproductive system Liver Pancreas Thymus Thyroid and parathyroid glands
Figure Adult derivatives of the three embryonic germ layers in vertebrates

85. Developmental Adaptations of Amniotes
Embryos of birds, other reptiles, and mammals develop in a fluid-filled sac in a shell or the uterus
Organisms with these adaptations are called amniotes

86. During amniote development, four extraembryonic membranes form around the embryo:
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

87. Amniotic cavity with amniotic
Fig
Amnion
Allantois
Embryo
Amniotic cavity with amniotic
fluid
Albumen
Shell
Figure Extraembryonic membranes in birds and other reptiles
Yolk (nutrients)
Chorion
Yolk sac

88. Mammalian Development
The eggs of placental mammals
Are small and store few nutrients
Exhibit holoblastic cleavage
Show no obvious polarity
Gastrulation and organogenesis resemble the processes in birds and other reptiles
Early cleavage is relatively slow in humans and other mammals

89. At completion of cleavage, the blastocyst forms
A group of cells called the inner cell mass develops into the embryo and forms the extraembryonic membranes
The trophoblast, the outer epithelium of the blastocyst, initiates implantation in the uterus, and the inner cell mass of the blastocyst forms a flat disk of cells
As implantation is completed, gastrulation begins

90. Endometrial epithelium (uterine lining)
Fig
Endometrial epithelium (uterine lining)
Uterus
Inner cell mass
Trophoblast
Figure Four stages in early embryonic development of a human
Blastocoel

91. Epiblast Expanding region of trophoblast Maternal blood vessel
Fig
Expanding region of trophoblast
Maternal blood vessel
Epiblast
Hypoblast
Figure Four stages in early embryonic development of a human
Trophoblast

92. The epiblast cells invaginate through a primitive streak to form mesoderm and endoderm
The placenta is formed from the trophoblast, mesodermal cells from the epiblast, and adjacent endometrial tissue
The placenta allows for the exchange of materials between the mother and embryo
By the end of gastrulation, the embryonic germ layers have formed

93. Epiblast Expanding region of trophoblast Amniotic cavity Hypoblast
Fig
Expanding region of trophoblast
Amniotic cavity
Epiblast
Hypoblast
Yolk sac (from hypoblast)
Figure Four stages in early embryonic development of a human
Extraembryonic mesoderm cells (from epiblast)
Chorion (from trophoblast)

94. Ectoderm Endoderm Amnion Chorion Mesoderm Yolk sac
Fig
Amnion
Chorion
Ectoderm
Mesoderm
Endoderm
Yolk sac
Figure Four stages in early embryonic development of a human
Extraembryonic mesoderm
Atlantois

95. Figure 47.16 Four stages in early embryonic development of a human
Endometrial epithelium (uterine lining)
Expanding region of trophoblast
Maternal blood vessel
Uterus
Inner cell mass
Epiblast
Trophoblast
Hypoblast
Blastocoel
Trophoblast
Expanding region of trophoblast
Amnion
Amniotic cavity
Chorion
Ectoderm
Epiblast
Mesoderm
Figure Four stages in early embryonic development of a human
Hypoblast
Endoderm
Yolk sac (from hypoblast)
Yolk sac
Extraembryonic mesoderm cells (from epiblast)
Extraembryonic mesoderm
Chorion (from trophoblast)
Allantois

96. The extraembryonic membranes in mammals are homologous to those of birds and other reptiles and develop in a similar way

97. Concept 47.2: Morphogenesis in animals involves specific changes in cell shape, position, and adhesion
Morphogenesis is a major aspect of development in plants and animals
Only in animals does it involve the movement of cells

98. The Cytoskeleton, Cell Motility, and Convergent Extension
Changes in cell shape usually involve reorganization of the cytoskeleton
Microtubules and microfilaments affect formation of the neural tube

99. Fig
Ectoderm
Figure Change in cell shape during morphogenesis

100. Neural plate Microtubules Fig. 47-17-2
Figure Change in cell shape during morphogenesis

101. Fig
Actin filaments
Figure Change in cell shape during morphogenesis

102. Fig
Figure Change in cell shape during morphogenesis

103. Fig
Neural tube
Figure Change in cell shape during morphogenesis

104. Ectoderm Neural plate Microtubules Actin filaments Neural tube
Fig
Ectoderm
Neural plate
Microtubules
Actin filaments
Figure Change in cell shape during morphogenesis
Neural tube

105. The cytoskeleton also drives cell migration, or cell crawling, the active movement of cells
In gastrulation, tissue invagination is caused by changes in cell shape and migration
Cell crawling is involved in convergent extension, a morphogenetic movement in which cells of a tissue become narrower and longer

106. Convergence Extension Fig. 47-18
Figure Convergent extension of a sheet of cells
For the Cell Biology Video Lamellipodia in Cell Migration, go to Animation and Video Files.

107. Role of Cell Adhesion Molecules and the Extracellular Matrix
Cell adhesion molecules located on cell surfaces contribute to cell migration and stable tissue structure
One class of cell-to-cell adhesion molecule is the cadherins, which are important in formation of the frog blastula

108. Embryo without EP cadherin
Fig
RESULTS
0.25 mm
0.25 mm
Figure Is cadherin required for development of the blastula?
For the Cell Biology Video E-cadherin Expression, go to Animation and Video Files.
Control embryo
Embryo without EP cadherin

109. Fibers of the extracellular matrix may function as tracks, directing migrating cells along routes
Several kinds of glycoproteins, including fibronectin, promote cell migration by providing molecular anchorage for moving cells

110. RESULTS Experiment 1 Control Matrix blocked Experiment 2 Control
Fig
RESULTS
Experiment 1
Control
Matrix blocked
Experiment 2
Figure Is an organized fibronectin matrix required for convergent extension?
Control
Matrix blocked

111. RESULTS Experiment 1 Control Matrix blocked Fig. 47-20-1
Figure Is an organized fibronectin matrix required for convergent extension?
Control
Matrix blocked

112. RESULTS Experiment 2 Control Matrix blocked Fig. 47-20-2
Figure Is an organized fibronectin matrix required for convergent extension?
Control
Matrix blocked

113. Concept 47.3: The developmental fate of cells depends on their history and on inductive signals
Cells in a multicellular organism share the same genome
Differences in cell types is the result of differentiation, the expression of different genes

114. Two general principles underlie differentiation:
During early cleavage divisions, embryonic cells must become different from one another
If the egg’s cytoplasm is heterogenous, dividing cells vary in the cytoplasmic determinants they contain

115. After cell asymmetries are set up, interactions among embryonic cells influence their fate, usually causing changes in gene expression
This mechanism is called induction, and is mediated by diffusible chemicals or cell-cell interactions

116. Fate Mapping
Fate maps are general territorial diagrams of embryonic development
Classic studies using frogs indicated that cell lineage in germ layers is traceable to blastula cells

117. Blastomeres injected with dye
Fig
Epidermis
Epidermis
Central nervous system
64-cell embryos
Notochord
Blastomeres injected with dye
Mesoderm
Endoderm
Blastula
Neural tube stage (transverse section)
Larvae
Figure Fate mapping for two chordates
(a) Fate map of a frog embryo
(b) Cell lineage analysis in a tunicate

118. Central nervous system Epidermis
Fig a
Epidermis
Central nervous system
Epidermis
Notochord
Mesoderm
Endoderm
Figure 47.21a Fate mapping for two chordates
Blastula
Neural tube stage (transverse section)
(a) Fate map of a frog embryo

119. Techniques in later studies marked an individual blastomere during cleavage and followed it through development

120. Blastomeres injected with dye
Fig b
64-cell embryos
Blastomeres injected with dye
Figure 47.21b Fate mapping for two chordates
Larvae
(b) Cell lineage analysis in a tunicate

121. Time after fertilization (hours)
Fig
Zygote
First cell division
Nervous system, outer skin,
muscula- ture
Muscula- ture, gonads
Outer skin, nervous system
Germ line (future gametes)
Time after fertilization (hours)
Musculature 10
Hatching
Intestine
Intestine
Figure Cell lineage in Caenorhabditis elegans
Mouth
Anus
Eggs
Vulva
ANTERIOR
POSTERIOR
1.2 mm

122. Establishing Cellular Asymmetries
To understand how embryonic cells acquire their fates, think about how basic axes of the embryo are established

123. The Axes of the Basic Body Plan
In nonamniotic vertebrates, basic instructions for establishing the body axes are set down early during oogenesis, or fertilization
In amniotes, local environmental differences play the major role in establishing initial differences between cells and the body axes

124. Restriction of the Developmental Potential of Cells
In many species that have cytoplasmic determinants, only the zygote is totipotent
That is, only the zygote can develop into all the cell types in the adult

125. Unevenly distributed cytoplasmic determinants in the egg cell help establish the body axes
These determinants set up differences in blastomeres resulting from cleavage

126. Experimental egg (side view)
Fig a
EXPERIMENT
Control egg (dorsal view)
Experimental egg (side view)
Gray crescent
Gray crescent
Thread
Figure How does distribution of the gray crescent affect the development potential of the first two daughter cells?

127. Experimental egg (side view)
Fig b
EXPERIMENT
Control egg (dorsal view)
Experimental egg (side view)
Gray crescent
Gray crescent
Thread
Figure How does distribution of the gray crescent affect the development potential of the first two daughter cells?
RESULTS
Normal
Belly piece
Normal

128. As embryonic development proceeds, potency of cells becomes more limited

129. Cell Fate Determination and Pattern Formation by Inductive Signals
After embryonic cell division creates cells that differ from each other, the cells begin to influence each other’s fates by induction

130. The “Organizer” of Spemann and Mangold
Based on their famous experiment, Hans Spemann and Hilde Mangold concluded that the blastopore’s dorsal lip is an organizer of the embryo
The Spemann organizer initiates inductions that result in formation of the notochord, neural tube, and other organs

131. Dorsal lip of blastopore Primary embryo
Fig
EXPERIMENT
RESULTS
Dorsal lip of blastopore
Primary embryo
Secondary (induced) embryo
Pigmented gastrula (donor embryo)
Nonpigmented gastrula (recipient embryo)
Primary structures: Neural tube
Notochord
Figure Can the dorsal lip of the blastopore induce cells in another part of the amphibian embryo to change their developmental fate?
Secondary structures: Notochord (pigmented cells)
Neural tube (mostly nonpigmented cells)

132. Dorsal lip of blastopore
Fig a
EXPERIMENT
Dorsal lip of blastopore
Pigmented gastrula (donor embryo)
Figure Can the dorsal lip of the blastopore induce cells in another part of the amphibian embryo to change their developmental fate?
Nonpigmented gastrula (recipient embryo)

133. RESULTS Primary embryo Secondary (induced) embryo
Fig b
RESULTS
Primary embryo
Secondary (induced) embryo
Primary structures: Neural tube
Figure Can the dorsal lip of the blastopore induce cells in another part of the amphibian embryo to change their developmental fate?
Notochord
Secondary structures: Notochord (pigmented cells)
Neural tube (mostly nonpigmented cells)

134. Formation of the Vertebrate Limb
Inductive signals play a major role in pattern formation, development of spatial organization
The molecular cues that control pattern formation are called positional information
This information tells a cell where it is with respect to the body axes
It determines how the cell and its descendents respond to future molecular signals

135. The wings and legs of chicks, like all vertebrate limbs, begin as bumps of tissue called limb buds

136. Figure 47.25 Vertebrate limb development
Anterior
Limb bud
AER
ZPA
Limb buds
Posterior
50 µm
Apical ectodermal ridge (AER)
(a) Organizer regions 2
Figure Vertebrate limb development
Digits 3 4
Anterior
Ventral
Proximal
Distal
Dorsal
Posterior
(b) Wing of chick embryo

137. Apical ectodermal ridge (AER)
Fig a
Anterior
Limb bud
AER
ZPA
Limb buds
Posterior
50 µm
Apical ectodermal ridge (AER)
Figure 47.25a Vertebrate limb development
(a) Organizer regions

138. 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

139. (b) Wing of chick embryo
Fig b 2
Digits 3 4
Anterior
Ventral
Proximal
Distal
Figure 47.25b Vertebrate limb development
Dorsal
Posterior
(b) Wing of chick embryo

140. One limb-bud organizer region is the apical ectodermal ridge (AER)
The AER is thickened ectoderm at the bud’s tip
The second region is the zone of polarizing activity (ZPA)
The ZPA is mesodermal tissue under the ectoderm where the posterior side of the bud is attached to the body

141. Tissue transplantation experiments support the hypothesis that the ZPA produces an inductive signal that conveys positional information indicating “posterior”

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

143. EXPERIMENT Anterior New ZPA Donor limb bud Host limb bud ZPA Posterior
Fig a
EXPERIMENT
Anterior
New ZPA
Donor limb bud
Host limb bud
Figure What role does the zone of polarizing activity (ZPA) play in limb pattern formation in vertebrates?
ZPA
Posterior

144. Fig b
RESULTS 4 3 2 2
Figure What role does the zone of polarizing activity (ZPA) play in limb pattern formation in vertebrates? 3 4

145. Signal molecules produced by inducing cells influence gene expression in cells receiving them
Signal molecules lead to differentiation and the development of particular structures
Hox genes also play roles during limb pattern formation

146. Fig
Figure Human polysyndactyly due to a homozygous mutation in a Hox gene

147. Cortical granule release (cortical reaction)
Fig. 47-UN1
Sperm-egg fusion and depolarization of egg membrane (fast block to polyspermy)
Cortical granule release (cortical reaction)
Formation of fertilization envelope (slow block to polyspermy)

148. 2-cell stage forming Animal pole 8-cell stage Vegetal pole Blastocoel
Fig. 47-UN2
2-cell stage forming
Animal pole
8-cell stage
Vegetal pole
Blastocoel
Blastula

149. Fig. 47-UN3

150. Fig. 47-UN4
Neural tube
Neural tube
Notochord
Notochord
Coelom
Coelom

151. Fig. 47-UN5
Species:
Stage:

152. Fig. 47-UN6

153. You should now be able to:
Describe the acrosomal reaction
Describe the cortical reaction
Distinguish among meroblastic cleavage and holoblastic cleavage
Compare the formation of a blastula and gastrulation in a sea urchin, a frog, and a chick
List and explain the functions of the extraembryonic membranes

154. Describe the process of convergent extension
Describe the role of the extracellular matrix in embryonic development
Describe two general principles that integrate our knowledge of the genetic and cellular mechanisms underlying differentiation
Explain the significance of Spemann’s organizer in amphibian development

155. Explain pattern formation in a developing chick limb, including the roles of the apical ectodermal ridge and the zone of polarizing activity