chapter 47 animal development. from eggs to organisms
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Chapter 47 Animal Development
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From eggs to organisms
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Figure 47.1 A “homunculus” inside the head of a human sperm
Preformation: a series of successively smaller embryos within embryos
Epigenesis: the form of animal emerges gradually from a formless eggs( Aristotle)
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Fertilization activate the egg and brings together the nuclei of sperm and eggs
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1. The Acrosomal reaction
release of enzyme from acrosomal vesicle
elongation of acrosomal process and penetration
through jelly coat
binding of acrosomal process to specific
receptors on eggs
fusion of sperm and egg plasma causes influx of
sodium and membrane depolarization
fast block to polyspermy
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2. The Cortical reaction
release of Ca+2 from the site of sperm entry
2nd messenger ( IP and DAG) induced by Ca+2
release opens Ca+2 channel on egg's’s ER
cortical granule release content into periventilline
layer
formation of fertilization envelope) slow block to
poly spermy
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Figure 47.2 The acrosomal and cortical reactions during sea urchin fertilization
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Figure 47.3 A wave of Ca2+ release during the cortical reaction
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3. Activation of eggs
DAG activate H+ channel , causes pH change
and induce metabolic rate
fusion of sperm and egg nucleus
DNA synthesis begin
cell division begins in 90 minutes
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Figure 47.4 Timeline for the fertilization of sea urchin eggs
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Fertilization of mammals
1. Migration of sperm through follicle cells
2. Binding induces acrosomal reaction
3. Binding of sperm cells to ZP3 receptor in coat of
zona pellucida
4. Nucleus of both eggs and sperm did not fuse until the 1st division of the zygote
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Figure 47.5 Fertilization in mammals
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Cleavage partitions the zygote into many smaller cells
Three stages after fertilization
1. Cell division 細胞分裂期
cell undergo S and M phase of cell cycle but skip
G1 and G2 phase
partition cytoplasm of zygote into many smaller
cells called blastomere ( distribution of different
cytoplasmic content in the different regions)
polarity defined by substances that are
heterogeneously distributed in the cytoplasm of
the eggs
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Figure 47.6 Cleavage in an echinoderm (sea urchin) embryo
45-90 min after fertilization
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Figure 47.7 The establishment of the body axes and the first cleavage plane in an amphibian
(More concentrate yolk)
灰月區
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Figure 47.8x Cleavage in a frog embryo
Animal pole
Vegetal pole
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2. Gastrulation 原腸期
rearrangement of cells of blastula
transformation of blastula into three layer embryonic germ layer
ectoderm: nervous system and outer layer of skin
endoderm: digestive tract and associated organs
mesoderm: dermis, kidney, hearts, muscles…
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Figure 47.9 Sea urchin gastrulation (Layer 1)
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Figure 47.9 Sea urchin gastrulation (Layer 2)
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Figure 47.9 Sea urchin gastrulation (Layer 3)
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Figure 47.10 Gastrulation in a frog embryo
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Table 47.1 Derivatives of the Three Embryonic Germ Layers in Vertebrates
外胚層
內胚層
中胚層
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3. Organogenesis 器官形成
folds, splits and dense clustering( condensation)
of cells
notochord ( dorsal mesoderm)neuroplate(
dorsal ectoderm)
somite ( mesoderm) backbone of animals axial
skeleton
morphogenesis and differentiation continue to
refine organs as they formed
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Figure 47.11 Organogenesis in a frog embryo
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Amniote embryos develop in a fluid filled sac with shell or uterus
Amniotes: within the shells or uterus, embryos
surrounded by fluid within a sac formed by
membrane called amnion
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Avian development
meroblastic cleavage : cell division occurs only in
a small yolk-free cytoplasm atop of the large mass
of yolk
The tissue layer out side the embryo develop into
four extra embryonic membrane( yolk sac, amnion,
chorion, and allantois)
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Figure 47.12 Cleavage, gastrulation, and early organogenesis in a chick embryo
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Figure 47.13 Organogenesis in a chick embryo
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Figure 47.14 The development of extra embryonic membranes in a chick
(Waste storage)
( filled with amnionic fluid for protection)
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Figure 47.15 Early development of a human embryo and its extraembryonic membranes
7 days, 100 cells
implantation
Development of extraembryonic membrane
Inward movement of epiblast starts the gatrulation
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The cellular and molecular basis of morphogenesis and differentiation in Animals
Morphogenesis: cell movement , shape and position
change of developing cells
invagination and evagination
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Figure 47.16 Change in cellular shape during morphogenesis
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Figure 47.17 Convergent extension of a sheet of cells
Convergent extension:
cells of tissue layer rearrange to become narrower
and longer
Possible guide by ECM( Ecm act as a track to guide
the movement of the cells)
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Figure 47.18 The extracellular matrix and cell migration
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Figure 47.19 The role of a cadherin in frog blastula formation
CAM: cell adhesion molecule
cadhesrin
Experimental: inject with antisense cadhedrin
control
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The developmental fate of cells depends on the cytoplasmic determinants and cell-cell induction
1. The heterogeneous distribution of cytoplasmic
determinants in the unfertilized eggs lead to
regional differentiation in the early embryo
2. Induction, interaction among the embryo cells
themselves induces gene experssion
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Figure 47.20 Fate maps for two chordates
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Figure 47.21 Experimental demonstration of the importance of cytoplasmic determinants in amphibians
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Figure 47.22 The “organizer” of Spemann and Mangold
Primary organizer of embryo
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BMP-4( bone morphogenic proteins)
Locate at ventral side of gastrula
Organizer produce proteins to inhibit the BMP-4
activity
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Figure 47.23 Organizer regions in vertebrate limb development
AER
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AER( Apical Ectodermal Ridge)
required for proximal-distal axis and patterning of
this axis
EGF: epidermal growth factor is responsible for the
growth signal
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ZPA (Zone of Polarizing Area)
Responsible for pattern formation along anterior-
posterior axis
secret sonic hedgehog, which is important for the
growth of limb bud growth
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Figure 47.24 The experimental manipulation of positional information
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Figure 47.6x Sea urchin development, from single cell to larva
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Figure 47.8d Cross section of a frog blastula
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