Embryology Long Exam 2 Notes PDF

Summary

These notes provide an overview of embryology concepts, focusing on the establishment of germ layers and derivatives, implantation, fetal membranes, placentation, hormonal control, and the development of the somites. This is relevant to a course on embryology at De La Salle university.

Full Transcript

DE LA SALLE UNIVERSITY
College of Science, BS-PSYC ID 121
EMBRYOL: Embryology (Lecture)
Ms. Marigold Uba
EMBRYOLOGY LONG EXAM 2 NOTES
○ No distinct cellular separation
○ Spaces: Lacunae
COURSE OUTLINE: Proliferation of blood cells for
forming of the placenta
1. Establishment of Germ Layers & Derivatives ○ Gives rise to the Extra Embryonic Mesoderm
Formation of Placenta: Extra Embryonic Membranes
2. Neural Crest Cells ○ Membranes forming outside the embryo

3. Implantation, Fetal Membrane, and Placentation

4. Hormonal Control

FIRST MODULE

Establishment of Germ Layers & Their Derivatives
Epiblast (splits into two)
○ Embryonic Epiblast
○ Helmet like: Amniotic ectoderm
Epiblast and hypoblast formation due to delamination
Hypoblast
process during gastrulation
○ Expands laterally and moves downward over
Movement of cells via invagination passing through
the blastocoel
the primitive streak
Synciotrophoblast
○ Moving downwards displacing the hypoblast
○ No longer distinct cellular membranes
forming the endoderm
○ Lacunae
Ingressing into the cavity into the blastocoel is the
embryonic mesoderm
Endoderm, Mesoderm, and Ectoderm

RECALL

ICM
ICM undergoes delamination
○ Epiblast and Hypoblast Yolk sac is derived from components of hypoblast
○ Epiblast will also undergo delamination Primitive node
Bilaminar Disc Formation ○ Site of invaginating cells
○ Formation of Epiblast and Hypoblast Migrating Pre notochordal cells cephalically passing
Trilaminar Disk Formation primitive node
○ Formation of the 3 Embryonic Germ Layers

TROPHOBLAST
Cytotrophoblast
○ Contains original cells of the trophoblast,
with increased population
○ Highly cellular
○ Layer of trophoblast that is responsible for
the initial attachment of blastocyst to uterine
lining
→ Uterine Wall
Syncytiotrophoblast
○ It has lost cellular membranes
○ Continuous layer
○ secretes enzymatic enzymes that break
uterine wall for implantation of embryo

YSABELA ANGELA FERNANDEZ 1
 Paraxial Mesoderm means sides of axial mesoderm
○ Also known as epimere

Lateral plate Mesoderm splits into 2
○ Parietal Mesoderm
○ Visceral Mesoderm
Paraxial Mesoderm → Future Somites
Intermediate Mesoderm → Future Urogenital Units
Lateral Plate Mesoderm
Some cells migrate downward at the hypoblast and ○ → Somatic/Parietal Mesoderm
displace the hypoblast to the side to form the yolk ○ → Splanchnic/Visceral Mesoderm
sac
Hyopblastic layer will be replaced by forming
mesodermal cells DEVELOPMENT OF SOMITE
Mesoderm
○ Ingressing cells to fill in the cavity
Ectoderm Epithelization of cells around a cavity
○ Cells left at the top: ○ Transformation of embryonic cells to flat cells
Endoderm that are tightly packed
○ Cells displacing hypoblast: Cells loose epithelial arrangement; cells migrate
Notochord deriving from pre-notochordal cells; of around neural tube and notochords as the
mesodermal origin sclerotome
○ Epithelial → mesenchymal transition
○ To mesenchymal type, which can migrate
FORMATION OF NOTOCHORD (CRANIAL TO CAUDAL)
Dorsomedial and ventrolateral cells will form the
Sagittal Section = Side View myotome
Prenotochordal cells migrate through the primitive Cells that remain between the Dorsomedial and
streak moving cranially Ventrolateral cells will form the dermatome
Layers of Somites
Cross Section: Level of Notochordal Plate ○ Sclerotome
become intercalated in the endoderm to form the innermost
notochordal plate around the neural tube and
Stays at the midline notochord
skeleton (bones)
○ Myotome
Middle Layer
Muscles
○ Dermatome
Outermost Layer
Definitive notochord Connective Tissue
Finally, it detaches to form the definitive notochord
Flanked on the side by intraembryonic mesoderm EXPRESSION OF GENES IN SOMITE
Detached from lateral endoderm DIFFERENTIATION
Formation of notochord, cranial to caudal, formed first
at the cephalic region and then to the caudal region
Shh and noggin expressed by the notochord and
floor plate of NT→ form sclerotome
FORMATION OF THREE MESODERMAL SHEETS Scleretome express PAX1 gene → controls
chondrogenesis and vertebrae formation
○ Scleretome participates in the formation of
vertebral column
WNT proteins secreted by dorsal NT activate PAX3
gene → demarcate the dermomyotome
○ Cells that give rise to the dermis and
Paraxial Mesoderm muscles
Intermediate Mesoderm WNT proteins also direct dorsomedial portion of
Lateral Plate Mesoderm somite → differentiate into muscle cell precursors

○ Muscle cells precursors express MYF5
Definitive notochord (muscle specific gene)
○ Mesoderm at the sides NT3 expressed by dorsal Neural Tube → middorsal
It expands further to the sides to form the lateral portion of somite → dermis
plate mesoderm
○ hypomere WNT protein and BNMP4 activates MyoD expression
In between Lateral Plate and Paraxial is the ○ Muscle specific gene
Intermediate Mesoderm
○ mesomere ENDODERM FORMATION

YSABELA ANGELA FERNANDEZ 2
 Originating from Endoderm: 4 Pharyngeal Pouches
Cephalocaudal folding
Midsagittal sections of embryos at various stages of
development showing cephalocaudal foldings and its Pharyngeal Arches or Branchial Arches
effects upon positions of the ○ Contain respective Aortic Arches
○ Heart Pharyngeal Folds or Gill Slits
○ Septum transversum Pharyngeal Pouch lining the gut
○ Yolk sac amnion
GERM LAYER TRACING

ENDODERM
Digestive and Respiratory System
Pharynx or foregut
○ Will give rise to pharyngeal pouches
○ Thyroid
ECTODERM
Nervous System, Integumentary System, and
Sensory Structures
Epidermal Placodes are in charge of the sensory
As folding proceeds, the opening of the gut tube into vesicles
the yolk sac narrows until it forms a connection Stomodeum
○ The vitelline duct ○ Anteriorly
Between midgut and yolk sac ○ Rathke’s Pocket will form at the floor
○ Houses vitelline blood vessels Proctodeum
○ Lining the end part of the gut
○ Posteriorly
Neural Tube
○ Central Nervous System
Epiphysis
Infundibulum
○ Floor of the diencephalon
Infundibulum and Rathke’s Pocket
○ Pituitary gland
Neural Crest Cells
○ Different ganglia
Region of mesonephros showing the 2 layers of the ○ Sympathetic and parasympathetic
lateral plate mesoderm Adrenal Glands
○ somatic/parietal mesoderm
○ splanchnic/visceral mesoderm
MESODERM
Splanchnic/Visceral Mesoderm forms linings around
body cavities Lateral plate Mesoderm or Hypomere
○ Give rise to various visceral organs of the ○ Somatic Mesoderm, lining of body cavities
body ○ Circulatory System
Intraembryonic Cavity is formed when it splits Intermediate Mesoderm
○ Urogenital system
○ Excretory
○ reproductive system
Paraxial Mesoderm
○ Skeletal system
○ Muscular System
○ Components of Integumentary System
Angiogenic Clusters
Mesonephric Ducts
○ For males
Mullerian Ducts
○ For Females
○ These degenerate for males
Muscular System
Components of endodermal layers ○ Paraxial Mesoderm
Digestive gut running from stomodeum to proctodeum ○ Lateral Plate Mesoderm (visceral)
or cloaca
Outpocketing of the digestive gut Sporadically Distributed
○ Liver ○ Endocrine System
○ Gallbladder ○ Adrenal and Pituitary Glands
○ Pancreas
Vitelline Duct to Yolk Sac
○ Outpocketing the Allantois

YSABELA ANGELA FERNANDEZ 3
 SECOND MODULE Migrating downwards following different routes to their
target routes/organs
Neural Crest Cells Differentiation via cell-to-cell signaling
Derived from the brim of the neuroectoderm/neural
crest cells during the process of neurulation
Indicative of topographical location and origin

Pathway 1
○ NCCs travel ventrally through the anterior
Migrate away from the neural tube before it fully sclerotome
closes Dermamayotome
NCCs are Pluripotent Cells Myotome
○ Giving birth to various cell types ○ Get lodged in the anterior sclerotome of the
Migratory cells from neuroectoderm somite
○ Loosely arranged ○ NCCs that will participate in the formation of
○ Amoboied movement cartilages and bones of the vertebral
Undergo Epithelial-Mesenchymal Transition column
○ When giving rise to different cell types ○ No NCCs in the Posterior Sclerotome
Pathway 2
NCC migratory cells to the cranial region form the ○ Take a dorsolateral route
components of the face and neck: ○ Under the epidermis, above the
○ facial bones dermomyotome
○ Facial cartilages ○ Form the pigment cells in the body
○ and facial connective tissues
Form pigment cells of the skin: melanocytes FOUR OVERLAPPING DOMAINS
Adrenal Medulla
Sensory Ganglia
○ Sympathetic Ganglia Cranial
○ Parasympathetic Ganglia ○ Pigment Cells
○ Sensory ganglia
○ Parasympathetic ganglia
WHAT BECOMES OF NCCs? ○ Hormone-producing cells
○ Glia cells
Neural Crest Migration Pathway Route They Follow Vagal
Cell Signaling Factors in their Microenvironment of Trunk
Final Destination Lumbosacral
Between Vagal and Cranial
MIGRATORY PATHWAYS ○ Cardiac Neural Crest Cells
Lateral migration pathway ○ Fill up the innermost layer of the aortic arch
○ Form the melanocytes arteries
Medial migration pathway ○ Layer that lines the lumen of arteries
○ Form the ganglia Endothelium

Cranial NCC → Pharyngeal arches, face and neck
Cardiac NCC (Somites 1-3) → septum between PA
and Aorta
Trunk NCC (Somites 6 to tail) → parasympathetic
neurons
Vagal NCC (Somites 1-7)
Sacral NCC (Posterior to Somite 28)
○ → parasympathetic nerves of the gut
Somites 18-24 → Adrenal Medulla

Cardiac Neural Crest Cells
○ From Neural Tube downward to the
developing Embryonic Heart
Forming septum
Target organs
○ Colonized by Cardiac Neural Crest Cells
○ Final locations where NCCs settle

YSABELA ANGELA FERNANDEZ 4
 Cardiac Neural Crest Cells line Cardiac Arteries

MIGRATORY PATHS OF NCC IN HEAD REGION
NCC leaves the crests of the neural folds prior to the
neural tube closer
Migrate to form the structures in the
○ Neck and face
○ Pharyngeal arches (1-6)
○ Epibranchial placodes (V, VII, IX, and X)
Neurons and Ganglia

FGF: Fibroblast Growth Factor
Timing of activation of SNAIL gene is almost
simultaneous with the closing of the neural tube
SNAIL and FOXD3: specify cells as NCCs
SLUG: promotes NCC migration from neuroectoderm
Timing is almost simultaneous
○ As neural tube closes;
○ SLUG gene activates for migration of NCCs

HOW IS MIGRATION INITIATED?

CRANIAL NCC FROM RHOMBOMERE REGIONS
Depending on what level of rhombomere they are
coming from
○ Also called 4th germ layer
Rhombomeres 1&2 migrate → 1st pharyngeal arch
○ Jawbones
○ Ear bones (Malleus and Incus)
○ Frontonasal process
Rhombomere 4 migrate → 2nd pharnygeal arch
○ Hyoid cartilage
Rhombomeres 6 migrate → 3rd and 4th Pharyngeal 1. BMP 4&7 Induce → RhoB & Slug genes (protein
arch and Pouches products)
○ Thymus a. Establish cytoskeletal conditions that
○ Parathyroid gland promote migration
○ Thyroid b. Activate factors that dissociate the tight
Rhombomeres 3 and 5 do not migrate through the junction in between the cells
surrounding mesoderm → stay on either side of the 2. Loss of cell adhesion molecules, they are now free to
rhombomere mesoderm move via amoeboid movement

Neural Plate Formation
○ Concentration of BMPs (Bone HOW DO MIGRATORY AGENTS KNOW THE ROUTE ON
Morphogenetic Protein) in the junctional WHICH TO TRAVEL?
border of surface ectoderm neural plate 1. Path of NCC is controlled by the extracellular matrix
○ Different concentrations a. Proteins that give contact guidance/promote
○ High Level → induces epidermis formation migrations
○ Intermediate level → induces neural crest Substrate Adhesion Molecules
cell formation (SAMs)
○ Low Level → Induces neural ectoderm Fibronectin, laminin,
formation tenascin, collagen
molecules, proteoglycans
REGULATION OF NCC INDUCTION b. Proteins that restrict migrations
Ephrin Proteins in the posterior
sclerotome

YSABELA ANGELA FERNANDEZ 5
 ○ They exist in clusters of similar genes in the
genome

Hox genes are evolutionarily conserved from
invertebrates to vertebrates
Colored boxes are the clusters
Paralogous chromosomes
○ A1, and B1, C1
○ A2, B2
○ Similar on the sides (para=side)
Genes found within the same cluster
○ Orthology
2. Chemotactic and maintenance factors ○ A1, A2, A3….
a. Same in the microenvironment of the final 5’ to 3’
location of NCCs that will influence their final ○ Position of Hox Gene on the Chromosome
differentiation ○ Cephalic to Caudal Region
b. Soluble factors secreted by potential ○ Moves
destinations The first genes to be expressed are in the anterior
Ex. stem cell factors (allow side
continuously proliferation of NCC)
HoxA is in Chrosome 6
HoxB in Chromosome 11
FINAL DIFFERENTIATION OF TRUNK NCC HoxC in Chromosome 15
Determined by the environment into which they HoxD in Chromosome 2
migrate and settle
○ Cell signaling factors
THIRD MODULE
TGF-β superfamily
Transformation Growth Extraembryonic Membranes
Factor
BMP
Growth factors
FGF
Examples
○ BMP2 (secreted by the lungs, heart, dorsal
aorta):
NCC differentiates → cholinergic
neurons → sympathetic ganglia in
the regions
○ Endothelin-3
NCC → Melanocytes
NCC → Adrenergic neurons in the
gut
○ Glucocorticoids (Somite 18-24):
NCC → adrenalmedullary cells
○ FGF: NCC → sympathetic neurons
Formation of placenta in mammals
4 types
WHAT SPECIFY THE FATES OF NCC? ○ Amnion
Hox genes code for Homeodomains ○ Chorion
○ Highest hierarchy of genes ○ Allantois
Control the activity of other genes ○ Yolk sac
below them
○ Modify body plan DEVELOPMENT OF EXTRAEMBRYONIC MEMBRANES
Combination of Hox genes
○ The genes that specify A-P axis)
Hox genes have the task of organising the body plan Distinction between embryonic and extraembryonic
of an animal tissues
Hox genes are a particular subfamily of homeobox Scoop it up from the yolk mass
that contains genes that evolved together with a Formation of Body Folds
complex multicellular body plan ○ Head Folds
They are utilized to convey positional information and Cephalic
organize the body plan ○ Lateral Folds
3 feautures of Hox genes Sides
○ They contain a sub-class of highly conserved ○ Tail Folds
homeobox sequences, so they encode Caudal
transcription factors
○ They are involved in organizing body plan ICM where Primitive Streak is
Formation of germ layers

YSABELA ANGELA FERNANDEZ 6
 ○ Endodermal cells move downward 1. Amnion
occupying yolk mass 2. Chorion
○ Mesoderm move outward from the region of ○ Encompasses all the other 3 membranes
the embryo to become extraembryonic 3. Allantois
mesoderm 4. Yolk Sac
○ The ectoderm spreads outside away from
the region of the embryo
Develop a hood or helmet above
the embryo the amnion
Amniochorionic Fold
Amnion
○ Ectoderm as innermost
○ Mesoderm as outermost
○ Forming a hood over the embryo
Chorion
○ Outermost layer Oviparous Development
○ Ectoderm as outermost ○ Development outside the parent/mother
○ Extramebryonic mesoderm as innermost ○ Avian
Amnion and Chorion are somatopleuric in origin ○ Plenty of yolk
Yolk Sac Viviparous Development
○ Endoderm as innermost layer ○ Development inside the mother
○ Extraembryonic mesoderm as outer layer ○ Mammalian
○ In line with midgut ○ Yolk sac is vestigial, evolutionarily conserved
Allantois ○ Allantois is not showed, integrated in the
○ Outpocketing of hindgut umbilical cord
○ Lined with endoderm
○ Outside with extraembryonic mesoderm
Yolk Sac and Allantois and splanchnopleuric in YOLK SAC
origin First membrane to make its appearance
Grows over the yolk mass
Functions
○ Change yolk into soluble materials for the
embryo via the open midgut passing through
yolk stalk
○ Endodermal cell lining as site of synthesis of
serum proteins
○ Site of hematopoiesis
Generation of blood cells and blood
vessels
○ Site of Primordial germ Cell Specification
(PGCs)

AMNION
Encloses the embryo in a fluid-filled cavity (amniotic
cavity)
○ Most intimate with the embryo
amniotic fluid
Function
○ Fluid content protects the embryo from
adhesions and mechanical stress

CHORION
In chick
○ Transport Ca2+ egg shell into the embryonic
circulation → beak & skeleton
○ Exchange of respiratory gases
In Mammals
○ Respiration filtration, hormone production
○ Hormone production
it forms a large part of the placenta
ALLANTOIS
Evagination from ventral wall of hindgut
Its mesoderm fused with the chorion and to some
extreme with amnion
Functions
4 SETS OF ExEM

YSABELA ANGELA FERNANDEZ 7
 ○ Chorioallantoic membrane as an efficient
respiratory structure
Once fused with the Chorion
○ Reservoir for excretory wastes
Birds and reptiles: sequester
nitrogenous wastes
Hard white in the Balut
Humans: contribute to the vascular
network of the placenta
DECIDUOUS PLACENTA
At the time of parturition, the uterine tissues are
Epiblast delaminates to form the amnionic ectoderm damaged and shed off; bleeding occurs
Amnion separates the ICM from the trophoblast Villi are embedded within the endometrium
Intimate contact
Inner layer endoderm
Outer layer of mesoderm NON-DECIDUOUS PLACENTA
At the time of parturition, the uterine tissues are not
Formation of Allantois and Chorion damaged nor shed off
Villi are not embedded within the endometrium
Chorion is a combination is a combination of the Loose contact
extraembryonic mesoderm and the trophoblast No bleeding occurs
(cytotrophoblast)
Outpocketing of the hindgut Types of Placenta
○ Lined with endoderm and extraembryonic
Based on shape and distribution of placental villi on
mesoderm
the chorionic sack enclosing the fetus
Chorion in Placental Mammals
○ Diffuse
○ Mesoderm + Trophoblast
○ Cotyledonary
○ Zonary
○ Discoidal
Is allantois the same as the umbilical cord?
Chrorion will form a connective stalk with the maternal
placenta DIFFUSE
○ This connective stalk houses the blood Greater part of chorion surface associated with
vessels (arteries and veins) and allantois endometrium; the villi are spread-out
The connecting stalk with blood vessels and allantois ○ Pig
will be wrapped with the amnion
○ yolk sac stalk and the connecting stalk COTYLEDONARY
wrapped by the amnion is the umbilical cord Contact is restricted to the localized patches of villi
called cotyledons
Placenta ○ Ruminants: sheep, cow, and deer

ZONARY
Contact involving girdlike band encircling the
blastocyst; the villi are arranged in transverse zones
and penetrate the uterine wall
○ Carnivores, cats, dogs

DISCOIDAL
Contact is restricted to a disc or plate; the villi form a
disc that is intimately connected to the uterine wall
○ Humans, some rodents, rabbits

Site of physiological exchange between mother and
embryo
○ Made up of maternal tissue contribution and
embryonic tissue contribution

Types of Placenta
Based on the degree of contact of placental
components
○ Non deciduous placenta Types of Placenta
○ Deciduous placenta Based on histology
According to the number of layers of cells separating
fetal circulation from maternal circulation

YSABELA ANGELA FERNANDEZ 8
 Epitheliochorial is the most primitive and superficial Types of Placenta
Hemochorial is the most invasive type
○ Direct connection of blood to fetal Based on the architecture of the chorionic membrane
component in contact with maternal tissues
Endometrial is an unusual type

FOLDED
Ex. swine
Chorionic folds line the wrinkled surface of uterine
epithelium

VILLOUS
Ex. primates, ruminants
Chorion develops into villa (1°, 2°, 3°)
○ Primary
○ Secondary
○ Tertiary
Formation of finger-like projections depending on the
branches

LABYRINTHINE
Rodents
Feto-maternal space (labyrinth) forms a network
(merging of the chorionic villi surrounding maternal
blood lacunae)
TISSUE BARRIERS
Mesh-work
Point of exchange is the placenta Basal Zone, Decidual Zone
Fetal Blood Vessel, Maternal Blood Vessel
Maternal Components (going down) ○ Fetal nucleated, maternal non-nucleated
1. Maternal Endothelium
2. Endometrial Connective Tissue
3. Uterine Epithelium
Formation of Placental Complex
Fetal Components (going up)
4. Chorionic Epithelium
5. Chorionic connective tissue
6. Fetal Endothelium

YSABELA ANGELA FERNANDEZ 9
 Decidual
○ Components of maternal tissues that are
shed off

Implantation

Fertilization takes place in the Ampulla of the COMPARATIVE GESTATION
Oviduct
○ Travels down to the uterus
Day 5
○ It is already in the uterus
○ Blastocyst stage
ICM and Trophoblast
Day 7 - 10
○ Implantation in the lining of the Uterus

Earliest stage for implantation is for rabbit and swine
Latest is the horse (organogenesis stage)
3 layers of the Uterus Definitive placentation is in 90 days (3 months; first
○ Endometrium trimester)
○ Myometrium
○ Perimetrium Differentiation of Trophoblast
Involved in the formation of the placenta

MOLECULES IN THE FORMATION OF PLACENTA
cAMP & hCG
○ Direct cytotrophoblast differentiation towards
a hormonally-active syncytiotrophoblast
phenotype
cAMP & hCG
○ Cyclic adenosine monophosphate
○ Human chorionic gonadotropin
○ Secreted when the embryo is already in the
vicinity of the uterus
LIF
○ Leukemia inhibitory factor
TGFᵝ Cytotrophoblast
LIF and TGFᵝ ○ Highly cellular
○ Downregulate the hCG synthesis and Syncitiorphoblast
upregulate TUN secretion ○ Cellular boundaries are lost
TUN ○ Vacuoles and fusion of vacuoles forming
○ Tropho utero nectin spaces called lacuna or lacunae
○ A part of fibronectin (substrate adhesion
molecule)
○ Mediate thes the attachment of the placenta
to the uterus
○ Secreted at the anchoring site

YSABELA ANGELA FERNANDEZ 10
 Chorion gives rise to the villa
○ Chorionic villa
Chorionic plate
○ Extraembryonic mesoderm
Villous capillaries will start to invade intraembryonic
villi of chorion fusing with the allantoic duct
Body Stalk
○ Allantoic duct
○ Invading villous capillaries
Formation of Chorionic Villi Umbilical Cord
○ Umbilical Arteries and Veins
Previllous embryo ○ Allantoic Duct
○ Contains mesenchymal cells Urinary
Primary Villi 2nd week ○ Yolk Sac Duct
○ Mesodermal core
Secondary to Tertiary Villa 3rd week
○ Branching out from primary villi
○ Core will have formation of villous capillaries

ExEm of Chorion enveloping allantoid duct, yolk sac
duct, villous capillaries
○ All enclosed as the umbilical cord
Umbilical Cord Center has the umbilical arteries
○ Originating from the villous capillaries
The Allantoic Duct/Allantois will form the urinary
bladder
Yolk sac will be vestigial

HUMAN EMBRYONIC DISC AT 3 WEEKS Chorionic Villi to Maternal Blood in Uterus
Maternal surface = Decidual cells
Fetal Cell = Chorionic cells/vesicle
Supply of blood from the mother is via the developing
spiral arteries unloading into the intervillous spaces
Pressure is high thus facilitating the blood and
nutrients
Pressure decreases, blood goes back to the mother
passing through the maternal vein
Site of exchange: placenta

YSABELA ANGELA FERNANDEZ 11
 Side with no villi
Capsularis and parietalis fuse together will result into
Umbilical cord contains the gradual disappearance of uterine cavity
○ Umbilical arteries and veins
○ Wharton’s jelly (mesenchyme cells)
Chorionic Tissue

Decidual Reaction LAVAE
transformation of the stromal cells of the endometrium Smooth area of chorion
Decidium Lacks villi; middle ply of amniotic sac
○ Tissues shed at birth
○ Extraembryonic tissues + superficial layers FRONDOSUM
of endometrial connective tissue and Fetal portion of placenta
epithelium Develops in the placenta
Depending on its relationship with the embryo
DECIDUA BASALIS (SEROTINA)
Maternal placenta
Where the implantation takes place and the basal
plate is formed
Lies between the chorionic vesicle and the uterine
wall
Endometrium of pregnancy beneath chorionic sac
Supplies maternal blood to placenta

DECIDUA CAPSULARIS (REFLEXA)
Forms a capsule around the chorionic vesicle
Superficial part of endometrium of pregnancy

DECIDUA PARIETALIS (VERA)
The remaining decidua consists of decidualized Figure 1: Blastocyst
endometrium on the sides of the uterus not
immediately occupied by the embryo
Non-implantation area of the uterus
Potential but unused site of implantation
Outer ply of amnion

By 4-5 days after fertilization the embryo differentiates
into two distinct cell types:
○ Inner Cells Mass
Develop into the fetus
○ Trophoblast
Will develop into the placenta and
external membranes

YSABELA ANGELA FERNANDEZ 12
 By this stage, the trophoblast cells have begun to Day 12 Implantation Site
make the hallmark hormone
○ Human Chorionic Gonadotropin (hCG) Blastocyst completely embedded into endometrial
the hormone of pregnancy-test fame stroma
↓
The invading trophoblasts have penetrated the
Implantation maternal capillaries (sinusoids)
↓
Form pools of maternal blood which surround the
growing trophoblasts

Floating blastocyst → become attached to the uterine
lining (endometrium) 3 Weeks Implantation Site (21 Days)
↓ All lacunae filled up with maternal blood via spiral
Blastocyst is first slowed down by lone molecules arteries
(mucins) that extend from the endometrium The embryo has already began to make an early
↓ circulatory system
Cascade of molecules bring the trophoblasts into ○ All lacunae filled via spiral arteries
closer contact with the endometrium ↓
↓ Embryonic tissue and maternal blood separated by a
Intimate contact is made → trophoblasts cells invade layer of cytotrophoblasts and syncytiotrophoblasts
the endometrium (process of plantation)
4 Weeks Implantation Site (1 Month)
Day 9 Implantation Site The basic structure of the placenta has been formed
Spiral arteries are seen
With maternal blood being delivered to the forming
placenta via spiral arteries while being drained away
via uterine veins
The developing chorionic villi remain immersed in a
space filled with the nutrient rich maternal blood

Embryo surrounded by two layers of trophoblast
○ Inner mononuclear cytotrophoblasts
○ Outer multinucleated syncytiotrophoblast
Vacuoles form → fused lacunar
(lacunar stage)
This arrangement of embryo, trophoblasts, and
maternal tissues remains the paradigm throughout
gestation
Trophoblasts interface serves as
○ The means to extract nutrients from the
mother
○ Protects the embryo and fetus from maternal
immunological attack

YSABELA ANGELA FERNANDEZ 13
 Point of exchange is the placenta at the intervillous IDENTICAL TWINS
spaces
Fetuses are one of the same sex;
Share one placenta
One outer membrane envelopes both amniotic sac
has the same decidual basalis

FRATERNAL TWINS
Fetuses may be of different sex; two placentas
Two separate amniotic sacs, each with its own
membrane
Fraternal has different decidual basalis

Functions of Placenta
1. Physiological site of maternal-fetal exchange
a. Fetal maternal blood mixing
Passive diffusion of blood gasses,
oxygen co2 and nitrogen
b. Facilitated diffusion of
monosaccharides/glucose
Main energy source; fetal glycemia
is directly correlated with maternal
glycemia
Placenta & Membranes in Multiple Pregnancies
c. Active transfer of amino acids
Types of Twinning Diffusion of urea, ethanol
2. Works as endocrine gland; Hormone synthesis
a. The syncytiotrophoblast cells of the placenta
secrete four main kinds of hormones
Estrogen
Progesterone
Two hormonal peculiar to the
placenta hPL and hCG
3. Immunological Barrier
a. Two important roles in fetal-maternal
immunological balance
Passive immunity
Immunosuppression, suppression
of the mother’s immune response
against the fetus
b. Most of the antibodies needed by the baby
are acquired from the mother directly
ESTROGEN
During pregnancy
○ Stimulates the growth of the uterus
○ Enhances the blood flow between the uterus
and the placenta
○ Causes the breast to enlarge as a
preparation for milk production
During baby delivery the placenta produces
Progesterone and Estrogen
HPL

Human placental lactogen
Influences growth, lactation, lipid and carbohydrate
metabolism

Side Notes
The cytotrophoblast-the stem cell of the
placenta-gives rise to the differentiated forms of
trophoblasts
Within the chorionic villi, cytotrophoblasts fuse to form
the overlying syncytiotrophoblast
The villous syncytiotrophoblast makes the majority of
the placental hormones, the most studied being hCG
Cyclin AMP and its analogs, and more recently hCG
itself, have been sown to direct cytotrophoblast

YSABELA ANGELA FERNANDEZ 14
 differentiation towards a hormonally active ○ Period of sexual activity
syncytiotrophoblast phenotype ○ The only time the condition of the vagina
permits mating
FOURTH MODULE “Period of heat”
Stages (changes in the uterus, ovary, and vagina)
HORMONAL CONTROL OF REPRODUCTION ○ Proestrus
Period of preparation (follicles
grow)
Vertebrate Reproduction ○ Estrus
Cyclic activity (often related to changing seasons) When mating occurs
Hormonal control are regulated by environmental Corresponds with the time of
cues ovulation
○ Day length Within the time range of ovulation
○ Seasonal temperature ○ Metestrus
○ Amount of rainfall Formation of corpus luteum
○ Lunar cycles Period of repair
Female shifts have a cycle that lasts from 15-17 days ○ Diestrus
which means that ovulation can occur on the 7th, 8th, Becomes small and anemic
or 9th day Frequency of the estrous cycle during the breeding
It starts summer season varies
○ Those days day length is decreasing ○ Monestrous
○ With decreasing day length, ovulatory surges Single estrous cycle in a breeding
start season
They end in winter Dogs and foxes
○ Season when day length is increasing ○ Polyestrous
Gestation period is about 5 months Recurrence of estrous cycle in a
○ If mating is successful in October or late breeding season
September, the following months until Mice, rabbits, squirrels
January
○ Birth will be on February or March Their gonadal steroids and their control
Spring is the most optimal time for birth ○ Ovaries
Palolo worms Estrogen
○ Testes
Testosterone
RECALL
MENSTRUAL CYCLE
Anthropoid primates
○ Including humans
Refers specifically to the changes that occur in the
uterus
○ Uterine cycle
It is caused by cyclic events that occur in the ovaries
(ovarian cycle)

Hypothalamus secretes and synthesizes
gonadotropin releasing hormones via the portal
vessels
○ Transported in the pituitary gland
Gonadotropin hormones are FSH and LH
○ Follicle Stimulating Hormone
○ Luteinizing Hormone
Gonads
○ Estrogen and Testosterone

CYCLIC REPRODUCTIVE PATTERNS OF MAMMALS
HORMONAL REGULATION FOR MALES
Two types

ESTROUS CYCLE
Lower vertebrates
Associated with more pronounced behavior cycles
than are menstrual cycles
Estrus

YSABELA ANGELA FERNANDEZ 15
 Secondary sex characteristics
○ The physical and behavioral characteristics

HORMONAL REGULATION FOR FEMALES

First bracket is the ovarian cycle
The second bracket is the uterine cycle
○ Histological changes in the endometrium of
uterus
The length of the menstrual cycle on average is 28
days
Ovulation is in the middle of this cycle (14th day)

OVARIAN CYCLE
Follicular phase (Day 1-14)
○ Day 1 of the cycle to the middle of the cycle
(14th day)
○ FSH produced by the pituitary gland
stimulates the growth of the
follicles/granulosa cells surrounding the
oocyte
○ Towards the middle, only 1 of them go into
full maturation
That one will be fertilized
Androgens via aromatase ○ FSH and LH are released
Granulosa cells secrete additional estrogen Ovulation (around Day 14)
○ Building up of estrogen secretion ○ Release of mature egg
○ Triggered by a surge in LH
FOURTH MODULE An increase in estrogen from the
dominant follicle causes rapid surge
HORMONAL CONTROL OF REPRODUCTION in LH
○ LH surge prompts the mature follicle to
release egg
Luteal Phase
○ 15th-28th day
○ Ruptured follicle transforms into corpus
luteum
Transient endocrine structure
This will cause it to produce
progesterone primarily and
estrogen
○ Increase in the level of Estrogen = thicken
uterine lining (endometrium)
○ More granulosa cells = greater estrogen
levels

YSABELA ANGELA FERNANDEZ 16
 ○ It sends a feedback regulation to the consists of three main phases: the follicular phase, ovulation,
hypothalamus and pituitary gland and the luteal phase. These phases are regulated by various
It stimulates further release in FSH hormones and take place roughly over a 28-day cycle,
and LH although the length can vary from person to person.
○ LH is tagged as the hormone for ovulation
A steep increase in LH causes the 1. Follicular Phase (Days 1-14)
release of the mature oocyte from ○ Overview: The follicular phase begins on the
the ovary first day of menstruation and ends with
○ Theca interna and the externa collapse ovulation. During this phase, the follicles
Yellow body remains called the (tiny sacs containing immature eggs) in the
corpus luteum ovaries start to mature, with one eventually
○ Decline at the end becoming dominant.
Will send a feedback regulation at ○ Hormones Involved:
the hypothalamus and pituitary Follicle-Stimulating Hormone
gland (FSH): Produced by the pituitary
Will generate a new batch of gland, FSH stimulates several
granulosa cells follicles in the ovary to grow.
WHAT IS HAPPENING IN THE UTERUS? Estrogen: As the follicles develop,
they produce increasing amounts of
Corresponds to Follicular Phase
estrogen. Rising estrogen levels
○ Menstrual phase
help thicken the uterine lining
○ Proliferative Phase
(endometrium) in preparation for a
With increasing level of estrogen, the uterine lining is
potential pregnancy.
being prepared
○ Process
○ Undergoing growth and thickening
Multiple follicles begin to develop,
○ Proliferation of endometrial cells, blood
but only one (or sometimes more)
vessels, and endocrine glands
becomes dominant, continuing to
Luteal Phase
grow while others regress.
○ Secretory Phase
As the dominant follicle matures, it
○ Highest level of progesterone (primarily) with
produces high levels of estrogen,
estrogen
which eventually triggers a surge in
○ These hormones keep the integrity and
Luteinizing Hormone (LH).
thickness of the endometrial lining
2. Ovulation (Around Day 14)
Thickest at this point
○ Overview: Ovulation is the release of the
○ Prepared for future implantation and support
mature egg (oocyte) from the dominant
of the development of the embryo
follicle in the ovary, triggered by a surge in
In the event that the ovulated oocyte is not fertilized, it
LH.
will undergo degeneration
○ Hormones Involved:
○ Decline of progesterone and estrogen
Luteinizing Hormone (LH): The
○ Endometrial lining will no longer be
increase in estrogen from the
maintained
dominant follicle causes a rapid
○ Followed by the bursting of blood vessels
surge in LH. This LH surge prompts
○ Result in the menstrual flow (towards the
the mature follicle to release its
end of the menstrual cycle)
egg.
Interplay of
○ Process:
○ gonadotropic hormones
The dominant follicle ruptures,
FSH
releasing the egg into the fallopian
LH
tube.
○ sex hormones
The egg then begins its journey
Progesterone
toward the uterus, where it may
Estrogen
meet sperm and be fertilized.
The secretory phase is the most stable
3. Luteal Phase (Days 15-28)
The length of menstrual flow can vary
○ Overview: After ovulation, the ruptured
○ Menstrual and proliferative phase phase
follicle transforms into the corpus luteum,
○ A range (check graph)
which secretes hormones to support the
Ideally
uterine lining and maintain pregnancy if
○ 28-day cycle (28-14)
fertilization occurs.
○ Ovulation can happen on the 14th
○ Hormones Involved:
○ It can be later or later
Progesterone: The corpus luteum
Can be 3 days earlier
produces progesterone, which
Safe days to not get pregnant
stabilizes and maintains the
○ Proliferative days (before the 11th)
thickened endometrial lining,
○ After the 17th day onward
creating an ideal environment for a
fertilized egg.
OVARIAN CYCLE Estrogen: The corpus luteum also
The ovarian cycle is a series of changes that occur in the produces some estrogen to further
ovaries to prepare for potential fertilization and pregnancy. It support the endometrial lining.
○ Process:

YSABELA ANGELA FERNANDEZ 17
 If fertilization occurs, the corpus
luteum continues to produce
progesterone to maintain the
pregnancy until the placenta takes
over.
If fertilization does not occur, the
corpus luteum degenerates, leading
to a drop in progesterone and
estrogen levels. This hormonal
decrease causes the endometrial
lining to shed, marking the
beginning of menstruation and the
start of a new cycle.

Summary of Phases:
Follicular Phase: Follicles mature, estrogen
levels rise, and the uterine lining thickens.
Ovulation: Release of the mature egg from
the ovary
Luteal Phase: Corpus luteum forms,
secretes hormones to support a potential
pregnancy, and if pregnancy does not occur,
hormone levels drop, leading to
menstruation.

LH’s role in stimulating the release of oocyte from the
granulosa cells
○ The hormone for ovulation

YSABELA ANGELA FERNANDEZ 18
 VARIATIONS IN THE LENGTH OF MC/PHASES
Most cycles: 25 to 30 days
○ >25d Older women
○ 15-18 years old = 30d
○ 30 years old = 30 days
○ 35 years old = 28 days
25, 28, 30 day cycles

SUMMARY OF HORMONE EFFECTS
FSH
○ Stimulates the growth & development of the
follicle
○ Stimulates secretion of estrogen
○ Enhances effect of LH in stimulation
ovulation
LH
○ Stimulates the final development of the
follicle
○ Stimulates the ovulation
○ Stimulates the development of the corpus
luteum
○ stimulates the production of progesterone
Estrogen
○ Stimulates repair of uterine lining
○ Inhibits release of FSH
○ Inhibits release of LH
○ Falls in concentration results in menstruation
○ Fall in concentration removes inhibition of
FSH and a new cycle begins

YSABELA ANGELA FERNANDEZ 19