First and Second Week of Developmant (Fertilization, Cleavage and Formation of Blastocyst-Implantation-Bilaminar Germ Disk Formation)Assoc. Prof. Aylin YABA UÇAR-2020.pdf

Transcript

FERTILIZATION, CLEVAGE
AND
IMPLANTATION: First week of
development
Prof. Dr. Aylin YABA UÇAR

Department of Histology and Embryology

Learning objectives
• Explain the phases of fertilization
• Define important results of fertilization
• Describe the clevage and compaction of
embryo
• Define the phases of implantation

PREPUBERTY

FETAL LIFE
meiotic
arrest

LH
FSH

OVULATION

Oocyte
maturation

meiosis

mitosis
oogonia

REPRODUCTIVE PERIOD

Primary
oocyte

PI

PI

PI

MII

Translational
control

Blastocyst

8C

4C

2C

Pre-implantation embryonic development

1C

fertilization

Main Events During Fertilization
•
•
•
•
•
•
•
•

Capacitation
Acrosomal reaction
Penetration of corona radiata and zona pellucida
Binding and fusion of the oocyte and sperm cell
membranes
Cortical and zona pellucida reactions
Resumption of 2nd meiotic division
Metabolic activation of the egg
Restoration of diploid number of chromosomes

Capacitation
A series of maturational
changes
that
ejaculated
spermatozoa must undergo in
order to fertilize.

Capacitation
• Changes the surface characteristics of the
sperm
– seminal plasma factors that coat the surface of
the sperm are removed
– surface charge is modified
– receptor mobility becomes more restricted

• Capacitation leads to:
– Ability to bind to the zona pellucida
– Ability to undergo the acrosome reaction
– The acquisition of hypermotility

Effect of Capacitation

Andrew Raid et al., Asian Journal of Andrology, 2010

Diana S. Chu, PlosOne, 2018

• Increased activity of adenylyl cyclase leading to increasing
levels of cAMP
• Increased rate of tyrosine phosphorylation
• Activation of Ca2+ channels resulting in increased
intracellular Ca2+ levels
• Release of seminal fluid glycoconjugates from the surface
of the head of the spermatozoon
• Extensive modification of the plasma membrane by removal
of cholesterol, the predominant inhibitor of capacitation, and
redistribution of phospholipids and carbohydrate moieties

Capacitation
Sperm hyperactivity is necessary for breaking physical
barriers that protect the secondary oocyte from
fertilization.

• No change in sperm
morphology
• Motility change
– hyperactivation

Acrosome reaction
•

Breakdown and merging of the plasma membrane and the outer acrosomal
membrane allowing the release of acrosomal enzymes.

• Is mediated by binding ZP3. Free swimming
sperm and those negotiating the cumulus are
acrosome intact.
• Ca++ influx is a prerequisite.
• Results in release of acrosin, esterase,
neuraminidase and other enzymes facilitates
penetration of ZP.

Penetration of corona
radiata and zona pellucida

Likely Sperm Receptors:
b1,4 galactosyltransferase
SP 56
P 95
a mannoside
a mannosidase
Galactosyl receptors
Lectin-like fructose binding protein

Sperm

Passage of a sperm through the corona
radiata of the oocyte:
• Dispersal of the follicular cells of the corona
radiata results mainly from the action of the
enzyme hyaluronidase, which is released from
the acrosome of the sperm.
• Tubal mucosal enzymes also appear to assist
hyaluronidase.
• Movements of the tail of the sperm are
important during penetration of the corona
radiata.

Binding of Zona Proteins
• The zona pellucida, which is 13 µm thick in humans, consists
principally of four glycoproteins—ZP1 to ZP4.
• ZP2 and ZP3 combine to form basic units that polymerize into long
filaments. These filaments are periodically linked by cross-bridges of
ZP1 and ZP4 molecules.

2
1

3

Binding of Zona Proteins

• Three sulfated glycoproteins: ZP1, ZP2, ZP3 of 200,
120 and 83 kDa respectively.
• Basic structural unit: ZP2-ZP3 dimers cross linked by
ZP1.
• ZP3: polypeptide + N and O linked oligosaccharides.
The oligosaccharides mediate initial sperm binding,
the polypeptide initiates the acrosome reaction (via
G protein mediated Ca++ permeability).
• ZP2: secondary sperm receptor, after fertilization,
prevents polyspermy.

Nearly 20,000 cumulus cells are extruded with the oocyte
at ovulation.
Although not necessary for
fertilization, denuded oocytes
have low fertility.
1 PB
Ovum

ZP

Cumulus
cells

Prof. Dr. Aylin Yaba Uçar

Sperm binds oligosaccharide
on ZP3

3

2
1

Prof. Dr. Aylin Yaba Uçar

Binding to ZP3
leads to influx
of Ca++

3

2
1

Ca++
Prof. Dr. Aylin Yaba Uçar

Prof. Dr. Aylin Yaba Uçar

The proteolytic enzyme

acrosin,
esterases,
neuraminidase,
appears to cause lysis of the zona pellucida,
thereby forming a path for the sperm to follow to
the oocyte.

• Sperm passing the ZP are actively motile.
• After crossing the ZP and perivitelline space,
the sperm become apposed to the oolemma
at the equatorial segment.
• Following fusion, the sperm membrane
becomes part of the oocyte membrane.

Fusion of the oocyte and sperm cell
membranes

Assoc. Prof. Aylin Yaba Uçar

Cortical and zona pellucida reactions

Cortical Granules

Prof. Dr. Aylin Yaba Uçar

Cortical Reaction
Induced by IP3-mediated
increased intracellular Ca++
Release of trypsin-like protease
Zona Reaction
Block to Polyspermy
Loss of sperm binding
due to alterations in ZP2-3

Cortical granules

Prof. Dr. Aylin Yaba Uçar

• Immaturity or excessive aging may result in an
incomplete block to polyspermy.
• In the presence of excess spermatozoa such as in
IVF (in vitro fertilization), the polyspermy rate
can be as high as 5%.

Resumption of 2nd meiotic
division
•

Breakdown of Sperm Nuclear
Membrane

•

Nuclear Decondensation

•

Nuclear Dispersion

Prof. Dr. Aylin Yaba Uçar

• Formation of pro-nuclear membrane
• Formation of enlarged nucleus with 8 nucleoli

Prof. Dr. Aylin Yaba Uçar

• Formation of pro-nuclear membrane
• Formation of enlarged nucleus with 8 nucleoli

Prof. Dr. Aylin Yaba Uçar

Apposition of pronuclei

Prof. Dr. Aylin Yaba Uçar

Fusion of male and female pronuclei
Restoration of diploid number of chromosomes

Zygote

The zygote is genetically unique because half of its chromosomes
come from the mother and half are derived
from the father.
This mechanism forms the basis for biparental inheritance and
variation of the human species.

Prof. Dr. Aylin Yaba Uçar

Phases of
Fertilization

Results of Fertilization
• Stimulates the secondary oocyte to complete the
second meiotic division, producing the second polar
body.
• Restores the normal diploid number of chromosomes
(46) in the zygote.
• Results in variation of the human species through
mingling of maternal and paternal chromosomes.

Results of Fertilization
• Determines the chromosomal sex of the
embryo; an X-bearing sperm produces a
female embryo and a Y-bearing sperm
produces a male embryo.
• Causes metabolic activation of the oocyte,
which initiates cleavage of the zygote.

CLEAVAGE OF ZYGOTE

• 30 hrs after fertilization

Blastomeres

Assoc. Prof. Aylin Yaba Uçar

After the eight-cell stage, the blastomeres
change their shape and tightly align themselves
against each other—compaction.

• This phenomenon may be mediated by cell surface
adhesion glycoproteins.
• Compaction permits greater cell-to-cell interaction
and is a prerequisite for segregation of the internal
cells that form the inner cell mass .

What determines
whether a blastomere will
form inner cell mass or
trophoblast?

Development 2014

Development 2016

BLASTULATION

Expanded Blastocyst
Trophectoderm

Blastocoelic
cavity

Inner Cell
Mass

Blastocyst

Hatching Blastocyst

Blastocyst hatches from zona pellucida before implanting

Hatching Blastocyst

Hatched Blastocyst

Zona pellucida

An implantation window refers to the period of time in which the
uterus is ready to receive the blastocyst for implantation.

Nature Medicine 2012

IMPLANTATION
1. Apposition
2. Adhesion – attachment of blastocyst to the
surface of endometrium – day 5
3. Invasion – introduction of blastocyst inside
the uterine wall resulting from its lytic
digestion – days 6-12
4. Implantation

Nature Medicine 2012

FORMATION OF BLASTOCYST
• The trophoblast, the thin outer cells that give rise to
the embryonic part of the placenta.
• The embryoblast, a discrete group of blastomeres
that is the primordium of the embryo

• During this stage of development—
blastogenesis—the conceptus is called a
blastocyst

• Approximately 6 days after fertilization, the
blastocyst attaches to the endometrial
epithelium
• The cytotrophoblast, the inner layer of cells
•The syncytiotrophoblast, the outer layer
consisting of a multinucleate protoplasmic mass
formed by the fusion of cells

The cytotrophoblast is a mitotically active inner cell layer
producing cells that fuse with the syncytiotrophoblast,
the outer erosive layer.

The syncytiotrophoblast is not mitotically active and consists of a
multinucleate cytoplasmic mass; it actively invades the epithelium
and
underlying
stroma
of
the
endometrium.

Scanning electron microscopy (SEM)
photomicrographs of luminal surface of
human endometrial biopsies were taken from
(A) early, (B) mid and (C) late luteal phases of
normal menstrual cycle

The hypoblast forms
the roof of the
exocoelomic cavity
and is continuous
with the cells that
migrated from the
hypoblast to form the
exocoelomic
membrane.
This
membrane surrounds
the
blastocystic
cavity and lines the
internal surface of
the cytotrophoblast.

The exocoelomic membrane and cavity soon become modified
to form the primary umbilical vesicle. The embryonic disc then
lies between the amniotic cavity and primary umbilical vesicle.

The lacunae are soon filled with a mixture of maternal blood from
ruptured endometrial capillaries and cellular debris from eroded
uterine glands. The fluid in the lacunae—embryotroph—passes to
the embryonic disc by diffusion.

The communication of the
eroded uterine vessels with
the lacunae represents the
beginning of the primordial
uteroplacental circulation.

• Uteroplacental circulation – starts day 12 day,
when maternal blood from eroded uterine
vessels provide nutritional support to the
developing embryo.
• When maternal blood flows into the lacunae,
oxygen and nutritive substances become
available to the extraembryonic tissues over the
large surface of the syncytiotrophoblast.
• Oxygenated blood passes into the lacunae from
the spiral endometrial arteries in the
endometrium; deoxygenated blood is removed
from the lacunae through endometrial veins.

As the extraembryonic coelom forms, the primary umbilical
vesicle decreases in size and a smaller, secondary umbilical
vesicle forms.

• During formation of the secondary umbilical
vesical, a large part of the primary umbilical
vesicle is pinched off.
• The umbilical vesicle contains no yolk;
however, it may have a role in the selective
transfer of nutritive materials to the
embryonic disc.

Development of Chorionic Sac
The end of the second week is
characterized
by
the
appearance
of
primary
chorionic villi.

• https://www.youtube.com/watch?v=bIdJOiXp
p9g

After implantation, the endometrium undergoes
decidualization. During pregnancy, the portion of the
endometrium that undergoes morphologic changes is
called the decidua or decidua
graviditas.

Decidualization

• As its name implies, this layer is shed with the placenta at
parturition. The decidua includes all but the deepest layer of
the endometrium. The stromal cells differentiate into large,
rounded decidual cells.
• The uterine glands enlarge
and become more coiled
during the early part of
pregnancy and then become
thin and flattened as the
growing fetus fills the uterine
lumen.

Cell reports 2016

Three different regions of the decidua are identified
by their relationship to the site of implantation:
• The decidua basalis is the portion of the
endometrium that underlies the implantation site.
• The decidua capsularis is a thin portion of
endometrium that lies between the implantation site
and the uterine lumen.
• The decidua parietalis
includes the remaining
endometrium of
the uterus.

Ectopic Pregnancy