Lecture 11: Prevention of Polyspermy PDF

Summary

This lecture covers the prevention of polyspermy, a critical process ensuring only one sperm fertilizes an egg in many species, such as sea urchins. It details the fast block, involving ionic changes in the plasma membrane, and the slow block, the cortical granule reaction, releasing enzymes to modify the zona pellucida's sperm receptors. The involvement of intracellular calcium is also described.

Full Transcript

Lecture 10

Prevention of
polyspermy
The prevention of polyspermy
In normal monospermy, in which only one sperm
enters the egg, a haploid sperm nucleus and a haploid
egg nucleus combine to form the diploid nucleus of the
fertilized egg (zygote), thus restoring the chromosome
number appropriate for the species.
The centriole of the sperm, will divide to form the two
poles of the mitotic spindle during cleavage.

The entrance of multiple sperm -------polyspermy
 Consequences of
polyspermy
In the sea urchin

Fertilization by two sperms results
in a triploid nucleus (3 copies of
each chromosome)
Centriole of each sperm divides to
form the two poles of a mitotic
apparatus (4 poles total)
So, triploid chromosomes divide
into four cells
 Consequences of
polyspermy
As there is no mechanism to
control proper distribution of
chromosome number and type
So, chromosomes are
distributed unequally.
Some cells receive extra
copies of certain chromosomes
and other cells lack them.
Such cells either die or
develop abnormally.
Block to polyspermy
Species have evolved different ways to
prevent union of more than two haploid
nuclei.

The most common way is to prevent the
entry of more than one sperm into the egg.
 Block to polyspermy
The sea urchin egg has two mechanisms to avoid
polyspermy

Fast reaction ---- an electric change in the egg
plasma membrane

Slower reaction ------ exocytosis of the cortical
granules.
Fast Block to
polyspermy
The fast block to polyspermy
Electric potential of the egg plasma membrane
changes.

Membrane potential = Voltage/ Charge/ ionic
difference across two sides of membrane i.e.,
outside and inside.

This membrane is a selective barrier between
Egg cytoplasm
Outside environment
 The fast block to polyspermy
The ionic concentration of Na+ and K+ is
different
Inside
outside the plasma membrane
This concentration difference is
important for sodium and potassium
ions.

Seawater has high sodium ion
concentration
 The fast block to polyspermy
Plasma membrane regulates
differences by
Inhibiting the entry of sodium
ions into the oocyte
Preventing potassium ions from
leaking out into the environment

The resting membrane potential
is generally about -70 mV
Because the inside of the cell is
negatively charged with respect to
 The fast block to polyspermy
Occurs 1-3 seconds after the binding of the first
sperm

Membrane potential changes to +20 mV

Small influx of sodium ions into the egg.
 Significance
Sperm can fuse if resting
potential is
-70 mV

Cannot fuse if membrane
potential is positive

So, no more sperm can fuse
with egg.
 Confirmatory
Experiments
Polyspermy can be induced if sea urchin eggs are
artificially supplied with an electric current that keeps
their membrane potential negative.

Conversely, fertilization can be prevented entirely by
artificially keeping the membrane potential of the eggs
positive.

The fast block to polyspermy can also be prevented by
lowering the concentration of sodium ions in the water.
If the supply of sodium ions is not sufficient to cause
the positive shift in membrane potential, polyspermy
 The fast block to
polyspermy
How the changes in membrane potential of egg
block secondary fertilization???
Not known
Perhaps, sperm contains a voltage-sensitive
component (possibly a positively charged
fusogenic protein)
Insertion of this component into the egg plasma
membrane is regulated by the electric charge
across the membrane.
Electric block to polyspermy occurs in frogs
Fast Block of
polyspermy
 Slow Block to
polyspermy in Sea
Urchin
 The slow block to polyspermy
The eggs of sea urchins (and many other animals) have a
second mechanism to ensure that multiple sperms do not
enter the egg cytoplasm.

The fast block to polyspermy is transient, as the membrane
potential of the sea urchin egg remains positive for only
about a minute.

The slow block is accomplished by the cortical granule
reaction
A slower, mechanical block to polyspermy

 The slow block to polyspermy
Directly beneath the sea urchin egg plasma membrane
are about 15,000 cortical granules, each about 1 μm in
diameter.

Upon sperm entry, these cortical granules fuse with the
egg plasma membrane

They release their contents into the space between
plasma membrane and vitelline envelope.
The slow block to polyspermy
 The slow block to polyspermy
Several proteins are released during
cortical granule exocytosis.

1. Proteases
2. Mucopolysaccharides
3. Peroxidase
4. Hyaline
 The slow block to polyspermy
1. Proteases

dissolve the protein that connect
the vitelline envelope proteins to
the cell membrane
remove the bindin receptors and
any sperm attached to it
 The slow block to polyspermy
2. Mucopolysaccharides
produce an osmotic gradient that causes water to rush
into the space between the plasma membrane and the
vitelline envelope
This causes the envelope to expand and become the
fertilization envelope
The slow block to polyspermy ---
sea urchin
3. Peroxidase
hardens the fertilization envelope ---- by cross
linking tyrosine residues on adjacent proteins.
The fertilization envelope begins to form at the site of
sperm entry and continues its expansion around the
egg.
As it forms, bound sperms are released from the
envelope.

This process starts about 20 seconds after sperm
attachment and is completed by the end of the first
minute of fertilization.
 The slow block to polyspermy ---
sea urchin
4. Hyaline
forms a coating around the egg.
Elongated microvilli extend from plasma
membrane and their tips get attach with hyaline
layer.
This layer provides support for the blastomeres
during cleavage.
 Slow Block to
polyspermy in Mammals
The slow block to polyspermy ---
mammals
In mammals, the cortical granule reaction does not create
a fertilization envelope ----- but its ultimate effect is the
same.

Released enzymes modify the zona pellucida sperm
receptors in a way that they can no longer bind with the
sperm.

During this process ----- zona reaction, both ZP3 and ZP2
are modified.
The slow block to polyspermy ---
mammals
The cortical granules of mouse eggs contain an enzyme
that removes the terminal sugar residues of ZP3

This results in the
release of bound sperm from the zona
prevention of the attachment of other sperms
The slow block to polyspermy ---
mammals
Cortical granules of mouse eggs contain

N-acetylglucosaminidase enzymes
Cleaves N-acetylglucosamine from ZP3
carbohydrate chains
N-acetylglucosamine binds with sperm
The slow block to polyspermy ---
mammals
Proteases
Clip ZP2
ZP2 loses its ability to bind with sperm.

Thus, once a sperm has entered the egg,
other sperms can no longer initiate or maintain their
binding to the zona pellucida
and hence rapidly shed.
Calcium as the initiator of the
cortical granule reaction.
The mechanism of the cortical granule reaction is similar to
that of the acrosomal reaction.

After fertilization, intracellular calcium ions are released
from their intracellular stores (endoplasmic reticulum).

In this high-calcium environment,
cortical granule membranes fuse with the egg plasma
membrane
release their contents.
Calcium as the initiator of the
cortical granule reaction.
Once the fusion of the cortical granules begins near the
point of sperm entry, a wave of cortical granule
exocytosis propagates around the cortex to the opposite
side of the egg.

In sea urchins and frogs, Endoplasmic reticulum is
present in the cortex and surrounds the cortical
granules