Download Germ Layer Formation in Chick and Mouse Embryos

Early Development in Vertebrates:
Germ Layer Formation in Chick and Mouse Embryos
Top
View
Side View
Ventral
Top View
Posterior
Caudal
Tail
Sections : Vertical, Horizontal, Sagittal
Lateral / Distal / Peripheral
Dorsal
Medial / Proximal / Central
Geometry in Embryology
Lateral / Distal / Peripheral
Anterior
Rostral
Head
Advantages of using chick embryos in developmental studies
1. Year-round easy accessibility
2. Easy preparation of synchronized embryos in big quantities
3. Extensive manipulations are possible. (explant, injection & in ovo culture)
4. Human gene compatibility
5. Low cost
Blastodisc (Blastoderm)
5-6 layers of cells
linked together with
tight junctions
yolk
albumin
egg shell
Most Embryonic Body;
Active Cell Cleavage
Marginal Belt;
boundary;
important roles
in cell fate
specification
25mV membrane potential
pH 9.5
PMZ
pH 6.5
primary hypoblasts
all three
germ layers
local
thickening
of PMZ
Extraembryonic membrane
Linkage between endoderm & yolk sac
secondary hypoblasts : P  A extension
• posterior epiblast thickening
• epiblasts anterior to Koller’s sickle
• increase in cell height
• more globular shape
• higher motility
• ECM digestion
Primitive Streak
• epiblasts in PMZ region P  A extension
• increase in length, decrease in width
• ingression of the cells around the streak
(first ingressing epiblasts migrate down to basal
lamina to form future endoderm)
• simultaneous hypoblast extension underneath
Hensen’s Node
• primitive knot
• anterior thickening of
primitive streak
• ~ organizer in frog
Primitive Pit
• funnel shape
• major cell passing
gate to blastocoel
• 70% of area
pellucida
• extension to
future head
forming region
Primitive Groove
• depression within the streak
• open path to blastocoel
• ~ blastopore in frog
future
head
forming
region
anterior expansion of the
embryonic regions between
Hensen’s node and head process
midbrain
hindbrain
border
Once Hensen’s node hits
the head process…
posterior regression of Hensen’s
node and primitive streak
(i.e., shortening of primitive streak)
(PA)
(AP)
(AP)
(AP)
(PSM)
• Anterior-end passing cells migrate anteriorly to form foregut, head mesoderm, and notochord.
• Posterior-end passing cells migrate downward to form endodermal and mesodermal tissues.
• Order of Development : Anterior > Posterior, Medial > Lateral
• individual cell ingression, migration, EMT, and cell fate specification in chick and mouse embryos
• continuous invagination, migration, and cell fate specification in amphibians
gradual replacement of basal lamina
by future endoderm forming cells
Visualizing Ingressing and Migrating Cells during Early Development
Formation of Germ Layers
1. First group of cells passing through Hensen’s node
 forms pharyngeal endoderm of foregut (anterior migration & hypoblast displacement)
 confines hypoblasts in the anterior portion of area pellucida (germinal crescent);
precursors of the germ cells later migrating to the gonads through the blood vessel
2. Second group (between epiblasts and endoderms)
 head mesenchyme, prechordal plate mesoderm (anterior to notochord forming point)
(anterior migration, but short traveling to the ventral side)
 head process formation anterior to the Hensen’s node
3. Third group
 chordamesoderm  notochord forming cells (from Hensen’s node to rostral up to midbrain)
 hindbrain and trunk (from Hensen’s node to caudal to the end of streak)
4. Lateral portion of primitive streak ingression (for posterior organs)
Deep layer : mid-line hypoblast replacement  most endodermal origin organs
 extraembryonic membranes
Middle layer  mesodermal origin organs
Formation of Germ Layers (continued)
5. Mesodermal cell ingression continues.
Hensen’s node disappears
Primitive streak regression begins.
after generating 17 somites
Posterior movement of Hensen’s node
Posterior extension of notochord  cells ingressed through Hensen’s node (until 17 somites)
 cells ingressed through primitive streak (after 17 somites)
AP gradient in developmental maturity
anterior region --> already initiate organogenesis (i.e. brain & heart)
posterior region --> still active gastrulation
Formation of Germ Layers (continued)
midbrain level
initial HN level
before regression
HN position
during regression
Formation of Germ Layers (continued)
6. Finally, the remaining epiblast cells represent presumptive ectodermal cells.
Epiboly of the ectoderm : Ectodermal precursor cells continue to migrate and proliferate
to surround the yolk for about 4 days. Outer marginal cells of area opaca firmly attach
to vitelline envelope of the yolk via fibronectin interactions and these ECM-membrane
interactions provide locomotive forces for epiblast cells to wrap around the entire yolk.
Thus, after complete and successful gastrulation,
1) The yolk is surrounded by the ectoderms.
2) Hypoblasts are replaced by the endoderms.
3) Various mesoderms are appropriately positioned
between endoderm and ectoderm.
AP Axis (Asymmetry) Formation
due to Gravity Caused by Egg Rotation
heavy
light
Hensen’s Node Is the Chick “Organizer”
[hoxb1]
[otx2]
[otx2]
[hoxb1]
2O Hensen’s node
periphery
transplantation
Induction of a New Embryo by Transplantation of Hensen’s Node
Genes expressed in
PMZ  entire primitive streak Koller’s sickle  Hensen’s node
Vg1
Nodal
Chordin
Shh
During Early Gastrulation
Medial-Anterior Region  BMP
FGF from
Hensen’s Node
Precursor Cells
Lateral-Posterior Region  BMP
o
1
o
BMP Signaling
2
Chordin, Noggin, Nodal
(BMP antagonists)
from Hensen’s Node
Inhibition of BMP signaling is critical for early gastrulation
BMP (Bone Morphogenetic Protein) Pathway
Participating R-Smads
for each pathway
BMP : Smad 1, 5, 8
TGFb : Smad 2, 3
R-Smad
I-Smad
Noggin
Chordin
Gremlin
Folistatin
Nodal
BMP
Antagonists
Co-Smad
Generation of Mesodermal Cells from the Epiblast
Mesoderm
Epiblast
Mesoderm
Marker (-)
ERNI
Sox3
ERNI/Sox3
Brachyury
Tbx6L
Streak
FGF8
Cerberus
Hypoblasts
(No Cerberus)
Nodal
Hensen’s
Node
Retension of Neural Ectoderm in the Epiblast
FGF8
slower induction
than Brachyury/Tbx6L
SIP1
BMP
Signaling
Neural
Tissue
Formation
Churchill
Brachyury
Tbx6
positive cell
ingression
to form
mesoderm
ERNI/Sox3/Churchill/SIP1 positive cells  Neural Ectoderm
During Early Gastrulation
Anterior  Retinoic Acid
Posterior  Retinoic Acid
Retinoic Acid
Degrading
Enzyme
Retinoic Acid
Synthesizing
Enzyme
early
stage
embryo
posterior
marker
(Hoxb1)
Cerberus
Left-Right Asymmetry in Chick
RIGHT
LEFT
Ventral
View
Activin
Nodal
Cerberus
Shh
BMP4
BMP
Snail
Shh
Lefty-2
Nodal
FGF8
Dorsal
View
Lefty-2
Nodal
Pitx2
Pitx2
Snail
e.g. Heart, Spleen
Pitx2
e.g. Liver
Ventral
View
Difficulties in Studying Mammalian Embryos
1. Smallest eggs among animal kingdom
(100 um in diameter, 1/100 size to Xenopus egg)
2. Too fragile (manipulations almost impossible)
3. Material availability
4. Internal development
Key Features in Mammalian Embryogenesis
I. Rotational Cell Cleavage
Rotational
Cleavage
Multiple
One

Cells
Cell
Repeat
Meridonial
Cleavage
Meridonial
Cleavage
Meridonial
Cleavage
Equatorial
Cleavage
Meridonial …….
Cleavage
Equatorial …….
Cleavage
Meridonial …….
Cleavage
Equatorial …….
Cleavage
Key Features in Mammalian Embryogenesis
II. Compaction, ICM, Trophoblast & Blastocyst
2 cell stage
4 cell stage
uncompacted
8 cell stage
compacted
8 cell stage
compaction
compacted
16 cell stage
morula (embryo proper)
ICM + Trophoblast
(chorion)

Blastocyst
Key Features in Mammalian Embryogenesis
III. ICM vs. Trophoblast
Key Features in
Syncitio-Trophoblast
Mammalian Embryogenesis
Amniotic Ectoderm
IV. Blastocyst Penetration,
Imaginary Yolk Sac, &
Amniotic Cavity
Epiblast
Amniotic Structures
Imaginary
Yolk Sac
Uterine Tissue
Hypoblast
Uterine Epithelium
Extraembryonic
Endoderm
Extraembryonic
Mesoderm
Epiblast
Hypoblast
Uterus Lumen
Blastocoel
Trophoblast
Blastocyst
Key Features in Mammalian Embryogenesis
V. Gastrulation & Cell Migration from Bilaminar Germ Disc
Key Features in Mammalian Embryogenesis
VI. Chorionic Villi Circulation (Exchange)
• Small molecule (nutrients, O2) supply from mother to fetus via capillary vessel diffusion
• Fetus sends metabolic toxic wastes to maternal circulation system.
• BUT, no merge or fusion between maternal and zygotic blood vessels
Production of Chimeric Mice
Zona Pellucida : extracellular matrix of egg, essential for sperm binding,
prevent attachment of blastocyst to oviduct wall
(if fails, ectopic tubal pregnancy  hemorrhage)
AP Patterning by Hox Gene Expression
• 4 clusters of Hox gene per haploid set
• located on 4 different chromosomes
(mouse : Hox a to d, human : Hox A to D
• gene composition and relative location order
are conserved from fly to human
• Hox positive tissues
- anterior boundary of the hindbrain to tail
- tissues along the dorsal axis (neural tube,
neural crest, paraxial mesoderm, medial
surface ectoderm
• a given combination of Hox gene expression
dictates a specific level in the A-P axis
• anterior to posterior retinoic acid gradient
regulates Hox gene expression
• anterior Hox gene repression by RA
• RA-indep posterior Hox gene expression
• Hox gene mutation  more severe effects in
anterior patterning
• RA treatment alters Hox gene expression.
Experimental Confirmation of Hox Code Hypothesis
Hox10 K.O.  lumbar to thoracic
Hox11 K.O.  sacral to lumbar
more RA
anterior reduction
posterior expansion
less RA
anterior expansion
posterior reduction
Comparative Anatomy Supports Hox Code Hypothesis
# of vertebrae for each level
Chick
14
7
4
8
3
Mouse
7
13
6
4
6