Four Stages of Growth and Development

Gametogenesis: formation of sperm and eggs
Embryonic development: from fertilization until birth
Childhood: birth to puberty (reproductive maturity)
Aging process: from puberty to death

First year biology texts only cover stages one and two. We have previously covered gametogenesis (males, females), so now we will look at embryonic development.

Stages of Embryonic Development

Fertilization: sperm penetrates the egg, forming a diploid cell called a zygote.
Cleavage: cell division without cell growth
Morula: a solid mass of cells about the same size as the original zygote
Blastula: liquid fills the center of the morula, forming a hollow sphere of cells called the blastula (think “water balloon in swimming pool”).
Gastrula: cells on the outside of the blastula push inward, forming a new central cavity that connects with the outside.
- The three primary tissue layers (ectoderm, mesoderm, endoderm) form.
Extraembryonic membrane development: in the amniotes (reptiles, birds, and mammals), tissue develops outside the embryo to support the embryo's development.
Organogenesis (“creation of organs”): the development of different tissues and organs

Fertilization

Research published last year in the journal Science describes “a significant advance in understanding how the sperm and egg find each other”:

A Far Side cartoon, depicting a humorous version of “how the human egg is often deceived.”

Far Side Cartoon, Gary Larson (unknown date)

Mammals and Sea Urchins

	Mammals	Sea Urchins
Outer coating	Cumulus: follicle cells in a gelatinous matrix	Jelly coat: noncellular gelatinous matrix
Extracellular matrix	Zona pellucida: made of glycoproteins	Vitelline layer (envelope): made of glycoproteins
Both are deuterostomes (“second mouths”).

Shows the different components of a mammal egg, including the cumulus and zona pellucida.

Shows the different components of a sea urchinegg, including the jelly coat and vitelline layer.

Unknown source

Fertilization in Sea Urchins

Contact: sperm contacts egg's jelly coat.
Acromosomal reaction:
- Hydrolytic enzymes are released from the sperm head, which cut a hole in the jelly.
- A protrusion called the acrosomal process begins to grow from the sperm head.
Growth of acrosomal process:
- The acrosomal process grows and binds to receptors on the egg's vitelline layer.
- It continues to grow until it contacts the egg's plasma membrane.
Fusion of plasma membrane:
- Plasma membranes of sperm and egg fuse.
- Known as the "Fast block to polyspermy"
  - Occurs within 1–3 seconds of fusion.
  - An influx of sodium ions depolarizes the membrane.
  - This prevents more than one sperm cell from fusing with the egg's plasma membrane.
Entry of sperm nucleus: sperm nucleus enters the egg's cytoplasm.
Creation of fertilization membrane

A result of the "cortical reaction"
Known as the "Slow block to polyspermy"
- Occurs within one minute of fusion.
- Egg's endoplasmic reticulum releases calcium ions into cytoplasm.
- This causes cortical granules to release their contents into the space between the vitelline layer and the plasma membrane (perivitelline space).
- Enzymes from the cortical granules cause the vitelline layer and plasma membrane to separate from one another, and cause the vitelline layer to become impenetrable to sperm.
  - It is now called the fertilization membrane.

Shows the steps in fertilization for sea urchins, numbered as in the above list.

Figure 47.2, page 938, Campbell's Biology, 5th Edition

Fertilization in Mammals

Shows the steps in fertilization for mammals; see the book for details.

Figure 47.5, page 940, Campbell's Biology, 5th Edition