1. Fertilization: Part 2: Prevention of Polyspermy Gilbert - Chapter 7
pp. 187-192
2. Todays Objectives Identify the following important components of the process of fertilization: gametes, spermatogonia, acrosome, flagellum, tubulin, oocyte, pronuclei, vitelline membrane, zona pellucida, resting membrane potential, capacitation, cortical granule reaction
Identify the structure of an oocyte
Recognize the harm of polyspermy
Describe various ways that polyspermy is inhibited
Recognize that fertilization is species-specific
3. Fuse membranes
Prevent further sperm from enteringFuse membranes
Prevent further sperm from entering
4. Polyspermy Monospermy is the norm
Restores the diploid chromosome number
Sperm centriole becomes the mitotic spindle
Polyspermy is disastrous
Results in triploid nucleus
Multiple mitotic spindles form
8. Prevention of Polyspermy Usually done by preventing multiple sperm from entering the egg
Sea Urchins have 2 mechanisms:
Fast Block
Involves a change in egg cell membrane potential
Slow Block
Involves exocytosis of the cortical granules in the egg
9. Fast Block to Polyspermy�(Sea Urchin model) The egg has a different ionic concentration from the seawater in which it exists
Egg has lower sodium ion concentration; higher potassium concentration
This is maintained by sodium/potassium pumps in the egg cell membrane
The difference in charge across the egg membrane can be measured as -70mV and is called the resting membrane potential
10. Sodium-Potassium Pump
Pumps Sodium Out of cell
Pumps Potassium Into Cell
11. Fast Block to Polyspermy�(Sea Urchin model) 1-3 seconds after first sperm binds, the membrane potential shifts to +20 mV
Sperm can no longer fuse to the egg
Experimental evidence - Polyspermy can occur if*:
Eggs are supplied with an electrical current that keeps charge at -70mV
Fertilization occurs in water with a low sodium ion concentration
***This fast-block is only transient and lasts only for about a minute
***This fast-block is only transient and lasts only for about a minute
13. Slow Block to Polyspermy -�Sea urchin model Slower, mechanical, permanent block
Occurs about a minute after sperm-egg fusion
Upon sperm entry cortical granules fuse with the cell membrane and release several molecules
14. Cortical Granule Molecues Cortical granule serine protease
Releases vitelline membrane from its anchors to the cell membrane
Clips off bindin molecules
Mucopolysaccharides
Cause osmotic gradient
Water rushes into space between vitelline envelope
Vitelline envelope expands (lifts) and becomes the fertilization envelope
Peroxidase
Hardens the fertilization envelope
Hyaline
Forms a coating around the egg, protects during early embryonic development
19. Mammalian Cortical Granule Reaction Does not form a fertilization envelope
Does modify Zona Pellucida so sperm cannot bind
In mice, cortical granules cleave an essential portion of the ZP3 molecule
20. Calcium and the Cortical Granule Reaction Upon fertilization, intracellular concentration of Calcium ion in the egg increases
This is necessary for the fusion of cortical granules with the cell membrane
Calcium comes not from outside the egg, but from inside the egg itself
The fusion begins near the site of sperm entry and continues in a wave across the egg
A similar wave of calcium ion release can be observed
21. Egg injected with a dye that fluoresces when it binds calcium ionEgg injected with a dye that fluoresces when it binds calcium ion
22. Calcium experiments - Ca2+ is directly responsible for cortical reaction A23187 is a calcium ionophore
Transports Ca2+ across lipid membranes
Placing sea urchin embryos in sea water containing A23187 results in cortical granule reaction & fertilization envelope to rise (without presence of sperm)
If Ca2+ chelator is injected into egg, no cortical reaction occurs
23. Fertilization: 4 major events Sperm and egg make contact and must recognize each other as the same species
ONE (and only one) sperm enters egg
Fusion of the genetic material
Activation of egg to begin development
