GASTRULATION
most characteristic event occurring the 3rd week
Begins with the formation of primitive streak (PS) on the surface
of the epiblast: cephalic end, primitive node, surrounding
primitive pit
Cells migrate inwards towards the PS this is called Invagination,
controlled by Fibroblast Growth Factor 8 (FGF8)
FGF8 then Controls cell specification into the mesoderm by
regulating BRACHYURY (T) expression.
Cells invaginated and displace hypoblast creat endoderm
Between epiblast and endoderm (that was produced previously)
form mesoderm
Cells remaining in epiblast form ectoderm. The epiblast cells
continous to move laterally, cranially and caudally. Those
epiblast cells that moves cranially are formed into two:
Precordial plate which will be the induction of forebrain
Oropharyngeal membrane, the future opening of oral cavity
Epiblast gives rise to all 3 germ layers in the embryo, ectoderm,
mesoderm, and endoderm (deepest). All these layers form all of
the tissues and organs during organogenesis
The Primary villi, small capillaries, villous capillaries and the
connecting stalk (chorionic plate) supply the embryo with
nutrients and oxygen
Remember that the tropoblast will be the future placenta and
this placenta will produce oxygen and nutrients to the embryo.
In the cephalic direction, they pass on each side of the
prechordal plate. Later, the prechordal píate will be important
for induction of the forebrain
FORMATION OF NOTOCHORD
Prenotochordal cells invaginate in primitive node and the
epiblast cells are invaginating moving lateral wise, they are at
the cranial region, are your prechordal plate. As they continue
to move lateral wise upon reaching the middle, they will form two
layers. It will be the notochondral plate. As the two layers reach
the central region, it will now becomes a single layer. It will form
the notochord because the endoderm will now be detached. So
it now only form a single layer and that will become the definitive
chord, future neural tube and future axial skeleton
- The notochord and prenotochordal cells extend cranially to
the prechordal plate (an area just caudal to the
oropharyngeal membrane) and caudally to the primitive pit.
At the point where the pit forms an indentation in the
epiblast, the neuromeric canal temporarily connects the
amniotic and yolk sac cavities.
- The cloacal membrane is formed at the caudal end of the
embryonic disc. When the cloacal membrane appears, the
posterior wall of the yolk sac forms a small diverticulum that
extends in the connecting stalk. This diverticulum, the
allantoenteric diverticulum, or allantois, appears around
the 16th day of development.
ESTABLISHMENT OF BODY AXES
Anterior- posterior AP cranio caudal, dorso-ventral DV, left-right
LR occurs early in embryogenesis, initiated during morula stage
AP axis forms the anterior visceral endoderm (AVE) at the
cranial end of the endoderm which will become the head region
Mesoderm will ventralize to contribute to kidneys in the
presence of FGF8, bone morphogenetic protein 4 (BMP4),
transforming growth factor (TGF B)
Node is the organizer
Nodal in involved in intiating and maintaining the primitive streak
Laterally (L-R sidedness) – primitive streak appears, FGF8
secreted, nodal expression restricted to L side. Abnormal
expression includes laterality defects: situs inversus, dextro
cardia
Lateral defects – if the nodal expressions are abnormally
expressed
Dextro cardia – if the organ that should be on the left but is
located on the right, eg. heart
Situs inversus - if the organ is positioned in a reverse manner
such as in a mirror image arrangement. For example, the organ
that is supposedly on the right but is placed on the left and one
that is placed on the left is placed on the right.
FATE ESTABLISHED DURING GASTRULATION
- Paraxial Mesoderm are those migrating at the lateral
edges of the node and from the cranial end of the streak
- Intermediate Mesoderm are cells migrating through the
mid streak region
- Lateral Plate Mesoderm forms those migrating through the
more caudal part of the streak.
- Cells migrating through the caudal most part of the streak
contribute to extraembryonic mesoderm
GROWTH OF EMBRYONIC DISC
- initially flat and almost round, gradually becomes
elongated, with a broad cephalic and a narrow caudal end.
Growth and elongation of the cephalic part of the disc are
caused by a continuous migration of cells from the primitive
streak region in a cephalic direction. At that stage, the
primitive streak shows regressive changes, rap- idly
shrinks, and soon disappears.
- That the primitive streak at the caudal end of the disc
continues to supply new cells until the end of the fourth
week has an important bearing on development of the
embryo.
- Thus, gastrulation, or formation of the germ layers,
continues in caudal segments while cranial structures are
differentiating, causing the embryo to develop
cephalocaudally.
I.PERIOD OF ORGANOGENESIS
formation of tissues and organs
3 germs layers, ectoderm, mesoderm, and endoderm, gives rise
to a number of specific tissues and organs
Ectoderm germ layer (everything that is in contact with the
outside world) e.g. CNS, PNS, sensory epithelium of era, nose,
eye, skin, hair, nails, pituitary, mammary, and sweat glands
Mesoderm germ layer (tissues that support the body) e.g
somitomeres, myotome (muscle tissue), sclerotome (cartilage,
bone), dermatome (skin)
Endoderm germ layer (organs withing the body) e.g. GIT, RT,
UB, thyroid, parathyroid, liver, pancreas, tympanic cavity,
auditory tube
Induction of the neural plate caused by the upregulation of
Fibroblast Growth factor (FGF), inhibition of the activities of
Bone Morphogenetic Protein 4 (BMP4), Transforming growth
factor B (TGF B)
Formation of neural tube from neural plate (NEURULATION)
occurs by lengthening of neural plate (cranial to caudal) and
body axis, lateral edges elevate to form NEURAL FOLDS and
the depressed mid region form NEURAL GROOVE
Neural fold approach each other in midline where they fuse and
form the cervical region that proceeds cranially and caudally.
Neural tube is formed
Anterior cranial neuropore closes at day 25
Posterior caudal neuropore closes at day 28
Neurulation complete with its narrow caudal portion/ spinal cord
and broader cephalic portion/ brain vesicles
- MOLECULAR REGULATION OF NEURAL INDUCTION
- Neurulation is the process whereby the neural píate forms
the neural tube.
- NEURAL CREST. As the neural folds elevate and fuse,
cells at the lateral border or crest of the neuroectoderm
begin to dissociate from their neighbors.
The ectodermal germ layer gives rise to organs and structures that
maintain contact with the outside world:
- The central nervous system
- The peripheral nervous system
- The sensory epithelium of the ear, nose, and eye
- The epidermis, including the hair and nails
- The subcutaneous glands
- The mammary glands
- The pituitary gland
- Enamel of the teeth
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