Embryo Midterms PDF - Saint Louis University

Summary

These notes from Saint Louis University cover the third week of embryonic development, focusing on gastrulation, formation of the trilaminar germ disc, notochord development, and the establishment of body axes. It also discusses topics like clinical correlations and associated birth defects. These notes are from a lecture on October 9, 2024.

Full Transcript

EMBRYOLOGY SAINT LOUIS UNIVERSITY

M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

OUTLINE o Ectoderm: epidermis, central and peripheral
nervous system, eyes and internal ears, neural
I. GASTRULATION: FORMATION OF GERM LAYERS........... 1
crest cells, and many connective tissues of the
A. Gastrulation................................................ 1 head
II. TERMINOLOGIES.............................................. 1 o Mesoderm: all skeletal muscles, blood cells,
III. FORMATION OF NOTOCHORD.............................. 1 lining of blood vessels, all visceral smooth
IV. ESTABLISHMENT OF BODY AXES............................. 2 muscular coats
A. The Anterioposterior Axes.............................. 3 o Endoderm: source of the epithelial linings of the
respiratory and alimentary (digestive) tracts,
B. Dorsoventral Axes....................................... 3
including the glands opening into the
C. Dorsal Mesoderm Formation.......................... 3 gastrointestinal tract and glandular cells of
D. The Left-Right Sidedness (Laterality)................. 3 associated organs such as the liver and
V. FATE MAP ESTABLISHED DURING GASTRULATION......... 4 pancreas
VI. GROWTH OF EMBRYONIC DISC............................. 4
VII. FURTHER DEVELOPMENT OF THE TROPHOBLAST........... 5
VIII. CLINICAL CORRELATIONS.................................... 6
A. Conjoined Twins......................................... 6
B. Teratogenesis Associated with Gastrulation........ 6
C. Tumors Associated with Gastrulation................. 6
D. Birth Defects Associated with Laterality............. 6
IX. SUMMARY...................................................... 7
X. SUPPLEMENTAL VIDEO........................................ 8 Figure 2. Representative view of germ disc at the end of the
XI. Checkpoint!.................................................. 9 second week of development
XII. REFERENCES................................................... 10 II. TERMINOLOGIES
 Priminitive node
I. GASTRULATION: FORMATION OF GERM LAYERS o Cephalic end of the streak
o Consists of a slightly elevated area surrounding
A. GASTRULATION
the small primitive pit
 Process whereby the bilaminar disc undergoes
 Invagination
reorganization to form a trilaminar disc
o Inward movement when the cells of the epiblast
 Establishes all three primary germ layers from the epiblast
migrates towards the primitive streak
(ectoderm, mesoderm, and endoderm) in the embryo,
 Fibroblast Growth Factor 8 (FGF8)
these will later form all of the tissues and organs
o Synthesized by the primitive streak cells
 Begins with the primitive streak formation on the surface of
o Controls cell migration and specification
the epiblast
o Down regulates E-cadherin
o Epiblast: source of all germ layers and these
▪ Protein that binds the epiblast cells
germ layers gives rise to all tissues and organs of
together
the embryo
o Controls cell specification into the mesoderm by
regulating BRACHYURY (T) expression.

III. FORMATION OF THE NOTOCHORD
 Prenotochordal cells
o Invaginates in the primitive node and move
forward cranially in the middle until they reach
the prechordal plate
 Implantation site at the end of the 2nd week ▪ Prechordal plate
 The most characteristic even occurring during the third - Forms between the tip of the
week of gestation notochord and the
oropharyngeal membrane
o Consists of a small
region tightly
adherent ectoderm
and endoderm
cells that represents
the future opening
of the oral cavity
- Derived from some of the first
cells that migrate through the
node in the midline and
Figure 1. Implantation site at the end of the 2nd week move in a cephalic direction
 Is the beginning of morphogenesis and is the most
significant event occurring during the third week. During this
week, the embryo is referred to as a gastrula
 This process is what established the three germ layer in the
embryo

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 EMBRYOLOGY SAINT LOUIS UNIVERSITY

M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

Figure 3. Primitive streak of embryo

▪ Become intercalated in the hypoblast
so that for a short time, the midline of
the embryo consists of two cell layer
that form the notochordal plate
- Notochordal plate will now Figure 4. A. Sagittal section of 17-day embryo. B. Cross section
form the definitive notochord through region of notochordal plate. C. Definitive
 Definitive notochord notochord.
o Underlies the neural tube and is a signaling
center for inducing the axial skeleton  Notochord
1. The cranial end forms first o Functions as a primary inductor
2. Caudal regions are added as the o It stimulates the development of the primitive
primitive streak assumes a more vertebral column
caudal position. o In induces the overlying ectoderm to thicken
3. Both notochord and prenotochordal and differentiate into the neural tube
cells extend cranially to the prechordal  Remnants of Notochord
plate and caudally to the primitive pit o The notochord degenerates with the beginning
 Neurenteric canal of the formation of the vertebral body
o Temporarily connects the amniotic and yolk sac o The remnants of the notochord
cavities at the point where the pit forms an ▪ Nucleus pulposus of the intervertebral
indentation in the epiblast disc
 Cloacal membrane ▪ Apical ligament of dens
o Opposite to oropharyngeal
o Formed at the caudal end of the embryonic IV. ESTABLISHMENT OF THE BODY AXES
disc  Three axes of the body are established in development via
o Similar in structure to the oropharyngeal the expression of specific set of genes that regulate which
membrane cells will develop into specific structures:
o Consists of tightly adherent ectoderm and o Anterior posterior (A-P; craniocaudal),
endoderm cells with no intervening mesoderm. o Dorso-ventral (D-V)
o On appearance, the posterior wall of the yolk o Left-right (L-R)
sac forms a small diverticulum that extends into  Occurs early in embryogenesis
the connecting stalk called the allantoenteric  Probably initiated during late morula stage to blastocyst
diverticulum stages with A-P and D-V axes specified prior to L-R.
▪ Allantoenteric diverticulum or Allantois  Blastocyst stage
th
- Appears around the 16 day o A-P axis determined
of development. ▪ Cell from cranial end of endoderm
- May serve as a reservoir for layer of bilaminar disc migrate towards
excreting products of the what will become the head region to
renal system in lower form the anterior visceral endoderm
vertebrates (AVE)
- In humans may be involved
abnormalities of bladder
development

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 EMBRYOLOGY SAINT LOUIS UNIVERSITY

M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

▪ Spemann’s organizer: gave the
designation
 Antagonistic genes of BMP4:
o CHORDIN: activated by transcription factor
Goosecoid
o NOGGIN
o FOLLISTATIN
▪ potential neural inducers
▪ as a result, cranial mesoderm is
dorsalized into notochord, somites,
and somitomeres
 INVOLVED IN CONGENITAL ANOMALIES
o NODAL: initiating and maintaining primitive
streak
o HNF-3β
▪ Maintains node and later induces
regional specificity in forebrain and
Figure 5. Establishment of the Body Axes midbrain areas
A. THE ANTEROPOSTERIOR AXES ▪ Absence of HNF-3β: embryos fail to
 Is signaled by cells at the anterior (cranial) margin of the gastrulate properly and lack forebrain
embryonic disc. and midbrain structures
 The Anterior Visceral Endoderm (AVE) at the cranial end of o GOOSECOID
the endoderm layer of the bilaminar disc, cells from AVE ▪ activates inhibitors of BMP-4 and
express genes for head formation including: contributes to regulation of the head
o Transcription factors: OTX2, LIM1, and HESX1 development. Overexpression or
o Secreted factors: cerberus and LEFTY1 under expression of this gene results in
(members of the TGF-β family) severe malformations of the head
 Cerberus and LEFTY1 inhibit NODAL (a member of the TGF-β region, including duplications
family) activity hence establishing cranial end of embryo ▪ Ex. Conjoined twins
o Absence of Cerberus and LEFTY1 at caudal
end allows NODAL expression to continue C. DORSAL MESODERM FORMATION
o This signal establishes and maintains primitive  BRACHYURY (T) gene controls regulation of dorsal
streak mesoderm formation in the middle and caudal regions of
 The primitive streak itself is initiated and maintained by the the embryo
expression of NODAL, a member of the transforming growth o Expressed in the node, notochord precursor
factor- β family (TGF- β) expression will induce and maintain cells, and notochord
primitive streak o Responsible for cell migration through the
 Once the streak is formed, a number of genes regulate primitive streak
formation of dorsal and ventral mesoderm and head, tail o Encodes a sequence-specific DNA-binding
structures protein that functions as a transcription factor
o T-box: DNA-binding domain
▪ 20 genes in the T-box family
▪ Absence would result in caudal
dysgenesis (embryonic axis shortening)
▪ Degree of shortening
 The BRACHYURY (T) gene, encoding a transcription factor
secreted by the notochord, is also essential for expression of
NODAL, LEFTY1, LEFTY2
Figure 6. Sagittal section through the node and primitive streak o Expression of the transcription factor Snail is
restricted to the right lateral plate mesoderm
B. DORSOVENTRAL AXES o Probably regulates effector genes responsible
 Once the streak is formed, NODAL upregulate genes for establishing the right side
responsible for formation of dorsal and ventral mesoderm  Clinical Correlation: If absent – Caudal Dysgenesis
and head and tail structures
 Bone morphogenetic protein 4 (BMP4) is secreted
throughout the embryonic disc
 Presence of BMP4 with FGF: mesoderm will be ventralized to
contribute to kidneys (intermediate mesoderm), blood, and
body wall (lateral mesoderm)
o If BMP4 activity is not blocked by other genes
expressed in the node, all mesoderm would be
ventralized
o Node: organizer
o Hans Spemann
▪ First described this activity in the
blastophore’s dorsal lip (structure
Figure 7. Caudal Dysgenesis
analogous to the node) in Xenopus
(clawed frogs) embryos

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 EMBRYOLOGY SAINT LOUIS UNIVERSITY

M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

D. THE LEFT-RIGHT SIDEDNESS (LATERALITY) 3. The intermediate mesoderm at the middle of the streak
 Established early in development 4. Lateral plate of mesoderm at the caudal part of the
 Normally, many organs exhibit asymmetries: streak
o Heart, lungs, gut, spleen, stomach, liver, and 5. EEM extraembryonic mesoderm at the most caudal
others part
o Positioning these organs and establishing their
asymmetries is orchestrated by a cascade of
signal molecules and genes
 When primitive streak appears, cells of the node and
primitive steak secrete FGF8
o Induces expression of NODAL
 NODAL expression is then restricted to left side of embryo
due to serotonin (5-HT) accumulation on the left side
 LEFTY1 is expressed on the left side of the floor plate of the
neural tube and may act as a barrier to prevent left-sided
signals from crossing over.
 Sonic hedgehog (SHH) may also function in this role as well
as serving as a repressor for left-sided gene expression on
the right
 High concentrations of 5-HT activate transcription factor Figure 9. Dorsal view of the germ disc showing the primitive
MAD3 expression to the left side of primitive node streak and a Fate map for epiblast cells.
 From the left lateral plate, Nodal protein initiates a signaling
cascade with LEFTY2 to upregulate PITX2  Prechordal plate and notochord
 PITX2 o Formed from cells that ingress through cranial
o Homeobox-containing transcription factor. region of the node
o “Master gene” for left sidedness establishment  Paraxial mesoderm
o Repeated expression in left side of heart, o Formed from cells that migrated to the lateral
stomach, and gut primordial as they assume edges of the node and from the cranial end of
their normal asymmetrical body positions the streak
 Genes for right-side regulation not as well defined  Intermediate mesoderm
o Transcription factor SNAIL expression is restricted o Formed from cells that migrated through
to right lateral plate mesoderm. midstreak region
▪ Likely regulates effector genes for right  Lateral plate mesoderm
side establishment. o Formed from cells that migrated through the
more caudal part of the streak
READING ASSIGNMENT: CASCADE INITIATED ON THE LEFT SIDE  Extraembryonic membrane
Involve cilia on cells in the node that beat to create gradient o Formed from cells that migrated through the
of NODAL towards the left most caudal part of the streak
 Cloacal membrane
Involve gap junctions and small ion transport that establishes o Formed from the caudal part
signaling gradient  Other source is the primitive yolk sac (hypoblast)

VI. GROWTH OF EMBRYONIC DISC
 Initially flat and almost round, it become elongated with a
broad cephalic and a narrow caudal end

Figure 8. Dorsal views of germ disc showing gene expressions. Figure 10. Growth of embryonic disc
A. FGF8 secreted by node and primitive streak. B.  Cephalic region: mainly where embryonic disc expansion
Serotonin (5-HT) neurotransmitter increases concentration occurs
in right side. o Continuous cell migration from primitive streak in
cephalic direction causes its growth and
V. FATE MAP ESTABLISHED DURING GASTRULATION elongation
 The primitive streak is organized rostrocaudally for the o Primitive streak region remains the same size
formation of the mesoderm; therefore, invaginating ▪ Surface cell invagination and
epiblast cells develop into: migration forward and laterally
1. Notochord at the cranial end of the node at the continues until end of 4th week
primitive pit.  Middle of 3rd week: germ layers in the cephalic part begin
2. Paraxial mesodermal at the lateral margins of the node their specific differentiation.
and the cranial part of the streak o Organizer: primitive node

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 EMBRYOLOGY SAINT LOUIS UNIVERSITY

M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

o By the end of 4th week:
 Invagination of surface cells in the
primitive streak and their subsequent
migration forward and laterally.
 Primitive streak at the caudal end of
the disc continues to supply new cells.
 Primitive streak starts to show regressive
changes, shrink rapidly, and soon
disappears.
 Primitive streak diminishes in relative in
size and becomes an insignificant
Figure 12. A 13-day old implantation site showing primary villi
structure insignificant structure in the
of trophoblastic shell just beginning to be invaded by
sacrococcygeal region of the embryo.
mesoderm from the chorionic plate.
 Normally the primitive streak
 During further development:
undergoes degenerative changes
o Mesodermal cells penetrate the core of primary
and disappears by the end of 4th week
villi and grow toward the decidua
o Secondary villus: newly formed structure
o Sacrococcygeal Teratoma
 By the end of 3rd week:
▪ Remnants of the primitive streak
o Mesodermal cells in villus core differentiate into
- A teratoma is a type of germ
blood cells and small blood vessels forming the
cell tumor.
villous capillary system.
o Can either be
o Villus is now tertiary villus or definitive placental
malignant or
villus.
benign
o Tertiary villi capillaries contact developing
- Derived from pluripotent
capillaries in mesoderm of chorionic plate and
primitive streak cell
in connecting stalk.
- Contain tissues derived from
o Vessels establish contact intraembryonic
all three germ layers in
circulatory system connecting the placenta and
incomplete stages of
embryo.
differentiation.
o Tissues
o Bone
o Hair
o Thus, gastrulation or germ layer formation
continues in caudal segments while cranial
structures are differentiating causing the
embryo to develop.
▪ Embryo development:
cephalocaudally Figure 13. Development of a villus. A. Transverse section
o Cephalocaudally of primary villus showing a core of cytotrophoblastic cells
▪ Cephalic part: cell differentiation starts covered by a layer of syncytium. B. Transverse section of
at the middle of the 3rd week a secondary villus with a core of mesoderm covered by
▪ Caudal part: cell migration up to the a single layer of cytotrophoblastic cells, which in turn is
end of the 4th week; cell differentiation covered by syncytium. C. Mesoderm of villus showing a
starts at the end of the 4th week number of capillaries and venules.

 4th week of development:
o Heart begins to beat
o Villous system ready to supply the embryo
proper with essential nutrients and oxygen
 Cytotrophoblastic cells in villi penetrate progressively into
overlying syncytium until the maternal endometrium is
reached.
o Establish contact with similar extensions of
neighboring villous stems, forming a thin outer
cytotrophoblast shell.
 Cytotrophoblast shell surround trophoblast entirely and
attaches chorionic sac firmly to the maternal endometrial
tissue.
Figure 11. Teratoma o This is where nutrients enter the embryo
VII. FURTHER DEVELOPMENT OF THE TROPHOBLAST  Stem or anchoring villi: villi extending from the chorionic
 Begininning of 3rd week: trophoblast characterized by plate and decidua basalis (decidual plate)
primary villi with cytotrophoblast core covered by a o Decidual plate: part of endometrium where the
syncytial layer. placenta will form.
o Free (terminal) villi: branches from sides of stem
villi
o Where the exchange of nutrients and other
factors occurs

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M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

 Chorionic cavity becomes larger B. TERATOGENESIS ASSOCIATED WITH GASTRULATION
 By 19th or 20th day:  Beginning of the third week of development (initiation of
o Embryo attaches to its trophoblastic shell by a gastrulation)
narrow connecting stalk o A highly sensitive stage to teratogenic insult
o Connecting stalk develops into umbilical cord o Cell populations may be damaged by
(connects placentae and embryo) teratogens
 Pregnant woman may not take normal precautions
because she may not recognize that she is pregnant
because this stage is reached two weeks after fertilization,
and approximately four weeks from the last menses.

Holoprosencephaly
 High doses of alcohol at this stage kill cells in the anterior
midline of the germ disc, producing a deficiency of the
midline in cranio-facial structures.
 Characteristics in a child with this condition:
o Small forebrain
Figure 14. Presomite embryo and the trophoblast at the o Two lateral ventricles often merge into a single
end of the third week. Tertiary and secondary stem villi ventricle
give the trophoblast a characteristic radial appearance. o Hypotelorism (eyes are close together)
Intervillous spaces, which are found throughout the o Gastrulation itself may be disrupted by genetic
trophoblast, are lined with syncytium. Cytotrophoblastic abnormalities and toxic results.
cells surround the trophoblast entirely and are in direct
contact with the endometrium. The embryo is Caudal Dysgenesis (Sirenomelia) or Mermaid Syndrome
suspended in the chorionic cavity by means of the  Insufficient mesoderm is formed in the caudal-most region
connecting stalk. of the embryo
 Abnormalities in the following structures ensue because
mesoderm contributes to formation of lower limbs,
urogenital system (intermediate mesoderm), and
lumbosacral vertebrae
 Individuals exhibit a variable range of defects, including
hypoplasia and fusion of the lower limbs, vertebral
abnormalities, renal agenesis, imperforate anus, and
genital organ anomalies
 In humans: associated with maternal diabetes and other
cases
 In mice: abnormalities of BRACHYURY (T), WNT, and
ENGRAILED genes produce a similar phenotype
Figure 15. Longitudinal section through a villus at the end
of the fourth week of development. Maternal vessels
penetrate the cytotrophoblastic shell to enter intervillous
spaces, which surround the villi. Capillaries in the villi are
in contact with vessels in the chorionic plate and in the
connecting stalk, which in turn are connected to
intraembryonic vessels

VIII. CLINICAL CORRELATIONS
A. CONJOINED TWINS
 Over or under expression of GOOSECOID (activator of BMP4 Figure 17. Examples of (A) Holoprosencephaly and (B) Caudal
inhibitors and contributes to head development regulation) dysgenesis
 Severe malformations in head regions C. TUMORS ASSOCIATED WITH GASTRULATION
 Includes duplications such as in some types of conjoined
Sacrococcygeal teratomas
twins
 Remnants of the primitive streak persist in the
sacrococcygeal region sometimes. These clusters of
pluripotent cells proliferate and form tumors
 Commonly contain tissues derived from all three germ
layers
 most common tumor in newborns (1:37,000)
 Teratomas may also arise from primordial germ cells that fail
to migrate to the gonadal ridge
 Develops from a baby’s coccyx
 Commonly contain tissues from all three germ layers
 Probably resulting from remnants of the primitive streak
 Normally, the primitive streak under goes degenerative
Figure 16. Conjoined twins process, and will diminish by the end of the 4th of gestation

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M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

 May also arise from primordial germ cells that may become  Do not have complete situs inversus but appear to be
malignant predominantly bilaterally left-sided or right-sided
 Most commonly seen in female fetuses o Spleen
 Can be removed surgically ▪ Left-sided bilaterality: polysplenia
o Prognosis is good if removed as early as possible ▪ Right sided bilaterality: asplenia or
hypoplastic spleen
 High risk of having wide variety of other birth defects:
o Midline malformation
▪ Neural tube defects
▪ Cleft palate
▪ Anal atresia
 90%: complex congenital heart defects
o Heart exhibits more laterality than most organs;
increased susceptibility when L-R signaling
pathway is disrupted
 X-Linked Heterotaxy
o Caused by mutations in the zinc finger
transcription factor Z/C3, a gene located on the
Figure 18. Sacrococcygeal teratoma X chromosome
o Have variety of birth defects:
A. BIRTH DEFECTS ASSOCIATED WITH LATERALITY ▪ Neural tube defect
 Failure to properly establish the L-R axis, when genes are ▪ Limb abnormalities
expressed ectically (e.g., on the right side) ▪ Omphalocele: herniation of
abdominal viscera into the intact
Situs Solitus umbilical cord
▪ Heart malformations
 Normal positioning of the internal organs  Serotonin (5-hydroxytryptamine)
o Important signalling molecule (neurotransmitter)
Situs Inversus for establishing laterality
 A condition where the positioning of all organs is reversed in o Animal studies show that altering 5-HT signaling
a mirror image arrangement can result in
 Do not have high risk for having other congenital ▪ Situs invertus
abnormalities ▪ Dextrocardia
 Have slightly greater risk of having heart defect ▪ Heterotaxy
 Progeny: increased risk for having laterality defects and ▪ Wide variety of heart defects
even higher risk for having severe cardiac malformation o Similar effects in humans when 5-HT is disrupted
 Approximately 20% of patients with complete situs inversus by pharmaceutical agents
have: o Mothers who antidepressants from drug classes
o Kartagener Syndrome (abnormal cilia) known as selective serotonin reuptake inhibitors
▪ Causes bronchiechtasis and chronic (SSRIs):
sinusitis ▪ Examples: Prozac, Paxil, Zoloft,
▪ Cilia is normally present on the primitive Lexapro, Celexa, etc.
node’s ventral surface and may be ▪ Children born to this mother: increased
involved in L-R patterning risk of heart malformations and
 Serotonin (5-HT) multiple birth defects
o Important molecule in establishing laterality o Association between laterality and midline
defects suggests that signaling pathways
establishing A-P and L-R axes must interact to
specify correct positioning of body’s organs and
other structures
 Because the body axes start to be
specified late in the first week of
development: birth defects can
possibly be caused by disruption of
these patterning events

IX. SUMMARY
 The most characteristic event occurring during the third
Figure 19. Situs inversus week is gastrulation.
Situs ambiguous or Heterotaxy  Gastrulation begins with the appearance of the primitive
 Discordant organ positioning with respect to symmetry, streak, which has its cephalic end the primitive node.
where one or more organs are abnormally reversed in  In the region of the node and streak, epiblast cells move
position or if isomerism or inversion inward (to invaginate) to form new cell layers, endoderm
o Isomerism: e.g., both atria in the heart look the and mesoderm.
same  Cells that do not migrate through the streak but remain in
o Inversion: e.g., two ventricles in the heart are the epiblast form ectoderm.
reversed

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 EMBRYOLOGY SAINT LOUIS UNIVERSITY

M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

 Epiblast gives rise to all three germ layers in the embryo;
ectoderm, mesoderm, and endoderm, and these layers
form all of the tissues and organs.
 Prenotochordal cells invaginating in the primitive pit move
forward until they reach the prechordal plate. They
intercalate in the endoderm as the notochordal plate. With
further development, the plate detaches from the
endoderm, and a solid cord, the notochord, is formed.
 Notochord forms a midline axis, which will serve as the basis
of the axial skeleton.
 Cephalic and caudal ends of the embryo are established
before the primitive streak is formed.
 Thus,cells in the hypoblast(endoderm) at the cephalic
margin of the disc form the AVE (anterior visceral
endoderm), which expresses head-forming genes,
including OTX2, LIM1, HESX1 and the secreted factor Figure 21. Gastrulation
Cerberus.  15 days after fertilization
 Neurotransmitter serotonin (5-HT) plays a role in establishing o Primitive streak
laterality. ▪ A thickened structure that is formed
 Situs solitus is the normal left-right positioning of the organs. along the midline in the epiblast near
 Situs inversus complete reversal of the organs. the caudal end of the bilaminar
 Situs ambiguous (heterotaxy) one or more organs are embryonic disc.
abnormally positioned. ▪ Its formation defines the major body
 By the end of the third week, three basic germ layers, axes of the embryo including the
consisting of ectoderm, mesoderm, endoderm, established cranial end toward the head and the
in the head region, and the process continues to produce cauda end towards the tail as well as
these germ layers for more caudal areas of embryo until the the left and right side of the embryo.
end of the fourth week.
 Tissue and organ differentiation has begun, and it occurs in
a cephalocaudal (from head to toe) direction as
gastrulation continues.
 In the meantime, the trophoblast progresses rapidly.
 Primary villi obtain a mesenchymal core in which small
capillaries arise.
 Villous capillaries make contact with the capillaries in the
chorionic plate and connecting stalk, the villous system is
ready to supply the embryo with its nutrients and oxygen.

X. SUPPLEMENTAL VIDEO
 Gastrulation
o Process whereby the bilaminar embryonic disc
undergoes reorganization to form a trilaminar
disc
 End of 2nd week
o Bilaminar embryonic disc consisting of the
hypoblast and epiblast has formed throughout Figure 22. Primitive streak formation
the 3rd week of development.
 3rd week of development ▪ Cranial end: primitive streak expands
o Differentiates to establish three primary germ to create a primitive node which
layers in a process known as gastrulation. contains a circular depression known
as primitive pit
▪ Primitive pit: continues along the
midline of the epiblast towards the
caudal end of the primitive streak
forming a primitive groove.

Figure 20. Formation of epiblast and hypoblast

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M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

Figure 23. Primitive node
Figure 26. Invagination

 Day 16
o Majority of the hypoblast has been replaced.
o Ectoderm: remaining cells whicgh form the most
exterior distal layer

Figure 24. Primitive pit

Figure 27. Ectoderm

o Some of the invaginated epiblast cells remain in
the space between the ectoderm and newly
formed definitive endoderm.
o These cells form a germ layer known as the
mesoderm.

Figure 25. Primitive groove

 Invagination: once formed, cells of the epiblast migrate
inwards towards the streak, detach from the epiblast and
slip beneath into the interior of the embryo
o First cells to invaginate through the primitive
grove invade the hypoblast and displaced its
cells.
o Hypoblast cells are eventually replaced by a
new proximal cell layer which is referred to as
the definitive endoderm

Figure 28. Mesoderm

o Once the formation of the definitive endoderm
and mesoderm are complete, epiblast cells no
longer migrate towards the primitive streak.
o Throughout gastrulation, the ectoderm
continues to form from the cranial end to the
caudal end of the embryo, establishing three

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M.03 third week of development: trilaminar germ disc
Dr. Ma. Gemma M. Pinlac | October 9, 2024 SOM 2028

distinct primary germ layers throughout the
whole embryonic disc.
 In summary:
○ The first cells to invaginate through the primitive
groove form the definitive endoderm.
○ The remaining cells of the epiblast are called
ectoderm.
o Cells that remain in the space between the
ectoderm and definitive endoderm form a layer
called the mesoderm.

XI. CHECKPOINT!
1. Describes the inward movement when the cell of the
epiblast migrates towards the primitive streak.
2. A condition where the positioning of all organs is
reversed in a mirror image arrangement.
3. During what day does the allantoenteric diverticulum
or allantois appear?
4. The gene that controls the regulation of dorsal
mesoderm formation in the middle and caudal
regions of the embryo.
5. Important signaling molecule for establishing
laterality.
6. T/F: In the definitive notochord, the caudal end forms
first.
7. The structure that temporarily connects the amniotic
and yolk sac cavities.
8. A condition wherein there is an insufficient formation
in the caudal-most region of the embryo.
9. The heart begins to beat during what week of
development?
10. The master gene for left sidedness establishment.

PITX2 10.
4th week 9.
Caudal dysgenesis 8.
Neurentic canal 7.
F; the cranial end forms first 6.
Serotonin 5.
BRACHYURY (T) gene 4.
Day 16 3.
Situs Inversus 2.
Invagination 1.

XII. REFERENCES
Sadler T.W. (2019). Third week of development: Trilaminar germ
disc. Langman’s Medical Embryology (14th ed., pp. 59-71).
Wolters Kluwer.
Moore, K., et al. (2013). The Developing Human: Clinically Oriented
Embryology. (9th edition).
https://www.youtube.com/watch?v=3AOoikTEfeo

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 Embryology SAINT LOUIS UNIVERSITY
M.02 Embryonic Period: 3rd to 8th Week
Dr. Ma. Gemma M. Pinlac | October 16, 2024 SOM 2028

OUTLINE At the end of the 3rd week of development
o The ectoderm has a shape of a discs that is
I. EMBRYONIC PERIOD........................................... 1 broader in the cephalic than in the caudal
II. DERIVATIVES OF THE ECTODERMAL GERM LAYER........ 1 region
A. Molecular Regulation of Neural Induction.......... 1 o Neural plate
B. Neurulation............................................... 2 ▪ Appearance of the notochord and
C. Neural Crest Cells....................................... 3 pre-chordal mesoderm induces the
overlying ectoderm to thicken and
D. Molecular Regulation of Neural Crest Induction.. 3
form the neural plate
E. Other Ectodermal Derivatives........................ 4
▪ Neuroectoderm
F. Summary of Ectoderm.................................. 4
III. DERIVATIVES OF THE MESODERMAL GERM LAYER........ 4 A. MOLECULAR REGULATION OF NEURAL INDUCTION
A. Paraxial Mesoderm...................................... 4
B. Intermediate Mesoderm............................... 6 Upregulation of FGF (Fibroblast growth factor) signaling
C. Lateral Mesoderm....................................... 6 together with the inhibition of the activity of BMP4
D. Blood and Blood Vessels................................ 7 (Bone morphogenetic protein 4) causes the induction
E. Clinical Correlation...................................... 7 of the neural plate
FGF signaling promotes the pathway for neural tube
IV. DERIVATIVES OF THE ENDODERM GERM LAYER........... 8
development by an unknown mechanism, while it
V. Checkpoint..................................................... 8 represses BMP transcription
VI. References..................................................... 8 FGF also upregulate the expression of CHORDIN,
NOGGIN, and FOLLISTATIN which further inhibits BMP
activity;
I. EMBRYONIC PERIOD o These proteins are present in the organizer
(Primitive node), prechordal mesoderm, and
A.K.A period of organogenesis notochord
o Organogenesis: process where the 3 germ o In the early weeks of development, they
layers (ectoderm, mesoderm and endoderm) induce the mesoderm to become the
differentiate and give rise to a number of notochord and paraxial mesoderm
specific tissues. o The presence of these three proteins sets the
o This is also the period where majority of birth ECTODERM by default to become NEURAL
defects are induced; prior to this time, any TISSUE (only forms the forebrain and midbrain)
teratogen can result to fetal death and WNT3A and FGF causes the formation of caudal neural
spontaneous abortion plate structures (Hindbrain and Spinal Cord)
o Retinoic acid appears to play a role in
organizing the cranial-to-caudal axis of the
II. DERIVATIVES OF THE ECTODERMAL GERM LAYER
future brain; it causes re-specification of
cranial segments into more caudal ones by
regulation expression of Homeobox genes
However, with the presence of BMP; ectoderm will
become epidermis and mesoderm forms intermediate
and lateral plate mesoderm

Figure 2. (A) Dorsal view of a 16-day presomite embryo. The
primitive streak and primitive node are visible. (B) Dorsal view
of an 18-day presomite embryo. The embryo is pear-shaped,
with its cephalic region somewhat broader than its caudal
end.
Figure 1. Signals from notochord cause changes to ectoderm

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M.02 Embryonic Period: 3rd to 8th Week
Dr. Ma. Gemma M. Pinlac | October 16, 2024 SOM 2028

B. NEURULATION

Is the process whereby the neural plate forms the neural
tube
Regulated by Planar Cell Polarity Pathway which is
essential for neural tube development
As the thickened neural plate lengthens, its lateral edges
elevate to form neural folds, and the depressed mid-
region forms the neural groove.
Gradually, the neural folds approach each other in the
midline, where they fuse; fusion begins in the cervical
region (5th somite) then fusion proceeds cranially and
caudally.
End result is the formation of neural tube which is still open
cranially and caudally;
One of the key events in this process is lengthening of the
neural plate and body axis by the phenomenon of
convergent extension.
o Lateral to medial movement of cells

Figure 3.2. (A) Dorsal view of an embryo at approximately day 22.
Seven distinct somites are visible on each side of the neural tube.
(B) Dorsal view of a human embryo at 21 days. (C) Dorsal view of
an embryo at approximately day 23. Note the pericardial bulge on
each side of the midline in the cephalic part of the embryo. (D)
Dorsal view of a human embryo at 23 days.

Neurulation is complete when:
o Closing of the anterior and posterior neuropore
at day 25 and 28
o CNS is represented by a closed tubular structure
with a narrow caudal portion (spinal cord) and
a much broader cephalic portion characterized
by a number of dilation (brain vesicles)

Figure 3.1. (A) Dorsal view of a late presomite embryo
approximately 19 days). The amnion has been removed, and
the neural plate is clearly visible. (B) Dorsal view of a human
embryo at 19 days. (C) Dorsal view of an embryo at
approximately 20 days showing somites and formation of the
neural groove and neural folds. (D) Dorsal view of a human
embryo at 20 days.

Figure 4. (A) Lateral view of a 14-somite embryo (approximately
25 days). Note the bulging pericardial area and the first and
second pharyngeal arches. (B) The left side of a 25-somite

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M.02 Embryonic Period: 3rd to 8th Week
Dr. Ma. Gemma M. Pinlac | October 16, 2024 SOM 2028

embryo approximately 28 days old. The first three pharyngeal well as neurons for cranial ganglia, glial cells
arches and lens and otic placodes are visible. and melanocytes.

C. NEURAL CREST CELLS Neural crest derivatives
o Connective tissue and bones of the face
As the neural folds elevate and fuse, cells at the lateral
and skull
border or crest of the neuroectoderm begin to
dissociate from their neighbors. o Cranial nerve ganglia
This dissociation gave rise to the population of neural o C cells of the thyroid gland
crest cells o Conotruncal septum in the heart
Undergoes epithelial-to-mesenchymal transition as it o Odontoblasts
leaves the neuroectoderm by active migration and o Dermis in face and neck
displacement lo enter the underlying mesoderm o Spinal (dorsal root) ganglia
Fundamentally important because they contribute to
o Sympathetic chain and preaortic ganglia
the development of many organs and tissues thus they
are termed as fourth germ layer o Parasympathetic ganglia of the
Also involved in 1/3 of all birth defects and many gastrointestinal tract
cancers, such as melanomas, neuroblastomas and o Adrenal medulla
others o Schwann cells
o Glial cells
o Menges (forebrain)
o Melanocytes
o Smooth muscle cells to blood vessels of the
face and forebrain

D. MOLECULAR REGULATION OF NEURAL CREST INDUCTION

The fate of the entire ectodermal germ
o High levels - ectoderm undergoes epidermal
formation
o Intermediate levels - induction of neural crest
cells at the border of the neural plate and
surface ectoderm
o Low levels - ectoderm undergoes neural plate
formation
BMPs, other members of the TGF-ß and FGFs, regulate
NCC migration, proliferation, and differentiation.
o Abnormal concentrations of these proteins
have been associated with neural crest
defects in the craniofacial region of lab
animals.

Figure 5. Formation of neural tube

Crest cells from the trunk region leave the
neuroectoderm after closure of the neural tube and
migrate along one of 2 pathways:
o Dorsal pathway where they will enter the
ectoderm through holes in the basal lamina to
form melanocytes in the skin and hair follicles
o Ventral Pathway through the anterior half of
each somite to become sensory ganglia,
sympathetic and enteric neurons, Schwann
cells and the cells of the adrenal medulla
o Before closure of the neural tube, some NCC
migrate away and contribute to the
development of the craniofacial skeleton as

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 Embryology SAINT LOUIS UNIVERSITY
M.02 Embryonic Period: 3rd to 8th Week
Dr. Ma. Gemma M. Pinlac | October 16, 2024 SOM 2028

E. OTHER ECTODERMAL DERIVATIVES

By the time the neural tube li closed, two bilateral
ectodermal thickenings has formed, the olic
placodes and the lens placodes,
Otic placodes will invaginate and form the otic
vesicles which will eventually develop intro structures
needed for hearing and maintenance of equilibrium
Lens placodes forms the lenses of the eyes.

F. SUMMARY OF ECTODERM

In general, the ectodermal germ layer gives rise to
organs and structures that maintain contact with the
outside world;
o The central nervous system
o The peripheral nervous system
o The sensory epithelium of ihe ear, nose, and
eye
o The epidermis, including the hair and nails
In addition, it gives rise to the following:
o The subcutaneous glancis
o The mammary glands
o The pituitary gland
o Enamel of the teeth

III. DERIVATIVES OF THE MESODERMAL GERM LAYER

Initially, cells of the mesodermal germ layer form a
thin sheet of loosely woven tissue on each side of the
midline. By approximately the 17th day, however,
cells close to the
By approximately the 17th day, however, cells close
to the midline proliferate and form a thickened plate
Figure 6. Formation of the neural tube and neural crest cells of tissue known as paraxial mesoderm. More
(NCC) during early vertebrate embryogenesis. The neural laterally, the mesoderm layer remains thin and is
tube (blue) develops by convolution of the neural plate dorsal known as the lateral plate. With the appearance
to the notochord (red). At the neural plate border (green), and coalescence of intercellular cavities in the
neural crest cells are specified, and finally migrate away on lateral plate, this tissue is divided into two layers.
distinct pathways after closure of the neural tube. o A layer continuous with mesoderm
covering the amnion, known as the somalic
Induction of NCC requires and interaction of the or parietal mesoderm layer
JUNCTIONAL BORDER of the neural plate and surface o A layer continuous with mesoderm
ectoderm covering the yolk sac, known as the
Intermediate concentrations of BMPs are established at splanchnic or visceral mesoderm layer
this boundary (Neural crest cells) compared to neural Together, these layers line a newly formed cavity, the
plate cells that are intraembryonic cavity, which is continuous with the
exposed to very low levels of BMPs and surface extraembryonic cavity on each side of the embryo,
ectoderm cells (epidermis) that are exposed to very Intermediate mesoderm connects paraxial and lateral
high levels plate mesoderm.
Proteins NOGGIN and CHORDIN regulate these
concentrations by acting as BMP inhibitors A. PARAXIAL MESODERM
Intermediate concentrations of BMPs, together with
FGF and WNI proteins induce PAX3 and other By the beginning of the third week, paraxial mesoderm
transcription factors that specify the neural plate begins to be organized into segments.
border. These segments, known as somitomeres, first appear in
These transcription factors induce a second wave of the cephalic region of the embryo, and their formation
transcription factors: proceeds cephalocaudally.
o SNAIL AND FOXD3 which specify cells as Each somitomere consists of mesodermal cells
neural crest arranged in concentric whorls around the center of the
o SLUG promotes crest cell migration from the unit. In the head region, somitomeres form in
neuroectoderm association with segmentation of the neural plate into
neuromeres and contribute to mesenchyme in the
head

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M.02 Embryonic Period: 3rd to 8th Week
Dr. Ma. Gemma M. Pinlac | October 16, 2024 SOM 2028

Somites appear with a specified periodicity; the age of
an embryo can be accurately determined during this
early time period by counting somites.

MOLECULAR REGULATION OF SOMITE FORMATION

Formation of segmented somites from unsegmented
presomitic (paraxial) mesoderm depends on a
segmentation clock established by cyclic expression of
several genes.
The cyclic genes include members of the NOTCH and
WNT signaling pathways thai are expressed in an
oscillating pattern in presomitic mesoderm.
Thus, Notch protein accumulates in presomitic
mesoderm destined to form the next somite and then
decreases as that somite is established
The increase in Notch protein activates other segment-
pattering genes that establish the somite. Boundarles
for each somite are regulated by relinoic acid (RA) and
Figure 7. Transverse sections showing development of the a combination oi FGF8 and WNT3a
mesodermal germ layer. (A) Day 17. (B) Day 19. (C). Day 20.
(D) Day 21.

The thin mesodermal sheet gives rise to paraxial mesoderm
(future somites), intermediate mesoderm (future excretory
units), and the lateral plate, which is split into parietal and
visceral mesoderm layers lining the intraembryonic cavity.

Table 1. Number of somites correlated to approximate age in days

SOMITE DIFFERENTIATION

When somites first form from presomitic mesoderm, they
exist as a ball of mesoderm (fibroblast-like) cells, these
cells then undergo a process of epithelization and
arrange themselves in a donut shape around a small
lumen. By the beginning of the fourth week, cells in the
ventral and medial walls of the somite lose their
epithelial characteristics become mesenchymal
(fibroblast-like) again, and shift their position to surround
the neural tube and notochord
Colleclively, these cells form the sclerotome that will
differenliate into the vertebrae and ribs. Cells at the
dorsomedial and ventrolateral edges of the upper
region of the somite form precursors for muscle cells,
Figure 8. Dorsal view of somites forming along the neural tube whereas cells between these two groups form the
(the ectoderm has been partially removed). Somites form from dermatome.
unsegmented presomitic paraxial mesoderm caudally and Cells from both muscle precursor groups become
become segmented in more cranially positioned regions. mesenchymal again and migrate beneath the
dermatome to create the dermomyolome. Cells from
From the occipital region caudally, somitomeres further both muscle precursor groups become mesenchymal
organize into somites. The first pair of somites arises in again and migrate beneath the dermatome to creale
the occipital region of the embryo at approximately the dermomyotome.
the 20 th day of development. Each myotome and dermatome retains its innervation
New somites appear in craniocaudal sequence at a from its segment of origin, no matter where the cells
rate of approximately three pairs per day until, at the migrate. Hence, each somite forms its own sclerotome
end of the fifth week, 42 to 44 pairs are present. (the tendon cartilage and bone component), its own
There are 4 occipital, 8 cervical, 12 thoracic, 5 lumbar, myotome (providing the segmental muscle
5 sacral, and 8 to 10 coccygeal pairs. component), and its own dermatome, which forms the
The first occipital and the last five to seven coccygeal dermis of the back. Each myolome and dermatome
somites later disappear, whereas the remaining somites also has its own segmental nerve component.
form the axial skeleton.

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 Embryology SAINT LOUIS UNIVERSITY
M.02 Embryonic Period: 3rd to 8th Week
Dr. Ma. Gemma M. Pinlac | October 16, 2024 SOM 2028

Figure 9. Somite Differentiation

4th week
o Cells in the ventral and medial wall lose their
epithelial characteristic, become Figure 10.1. Both groups of muscle precursor cells become
mesenchymal (fibroblast-like) again, and mesenchymal and migrate beneath the dermatome to form the
surround the neural tube and notochord dermomyotome, while some cells from the ventrolateral group
o SCLEROTOME (differentiate into ribs and also migrate into the parietal layer of lateral plate mesoderm.
vertebrae)
Dermamyotone
o Cells from both the muscle precursorgroups
become mesenchymal and migrate beneath
the dermatome to create the
dermamyotome
o Forms dermis of Skin of back, muscles for back,
body wall (intercostal muscles), limb muscles
Also, cells from the ventrolateral edge migrate into the
parietal layer of lateral plate mesoderm to form most of
the musculature for the body and most of limb muscles
Each myotome and dermatome retains its innervation,
no matter where cells migrate
Each somite forms own sclerotome, myotome, and
dermatome
o Sclerotome – tendon cartilage and bone
component
o Myotome – provides the segmental muscle
component
o Dermatome – dermis of the back

B. INTERMEDIATE MESODERM
Figure 10. Cells from the ventral and medial walls of the somite
Intermediate mesoderm, which temporarily connects
lose their epithelial arrangement and migrate around the neural
paraxial mesoderm with the lateral plate, differentiates
tube and notochord. Collectively, these cells constitute the
into urogenital structures. In cervical and upper
sclerotome that will form the vertebrae and ribs. Meanwhile, cells thoracic regions, it forms segmental cell clusters (future
at the dorsomedial and ventrolateral regions differentiate into nephrolomes), whereas more caudally, it forms an
muscle precursor cells, while cells that remain between these unsegmented mass of tissue, the nephrogenic cord.
locations form the dermatome. Excretory units of the urinary system and the gonads
develop from this partly segmented, partly
unsegmented intermedi