Animal embryonic development

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Embryonic cells differentiate into a variety of different cell types. Image from NCBI.

Embryogenesis is the process by which the embryo is formed and develops. It starts with the fertilization of the ovum, which is then called a zygote. The zygote undergoes rapid mitotic divisions with no significant growth (a process known as cleavage) and cellular differentiation, leading to development of an embryo. It occurs in both animal and plant development, but this article addresses the common features among different animals.

The zygote

The egg cell (and hence the fertilized egg) is always asymmetric, having an "animal pole" (future ectoderm and mesoderm) and a "vegetal pole" (future endoderm), it is also covered with different protective envelopes. The first envelope, the one which is in contact with the membrane of the egg, is made of glycoproteins and is called vitelline membrane (zona pellucida in mammals). Different taxa show different cellular and acellular envelopes.

Cleavage

Cleavage during embryogenesis

The zygote undergoes rapid cell divisions with no significant growth, producing a cluster of cells that is the same size as the original zygote. Depending mostly on the amount of yolk in the egg, the cleavage can be holoblastic (total) or meroblastic (partial) (Campbell).

Holoblastic cleavage occurs in animals with little yolk in their eggs, such as humans and other mammals who receive nourishment as embryos from the mother via placenta or milk. On the other hand meroblastic cleavage occurs in animals whose eggs have more yolk; i.e. birds and reptiles. Because cleavage is impeded in the vegetal pole, there is a very uneven distribution of cells concentrating at the animal pole of the zygote (Campbell).

The different cells derived from cleavage, up to the blastula stage, are called blastomeres.

In holoblastic eggs the first cleavage always occurs along the vegetal-animal axis of the egg, the second cleavage is perpendicular to the first. From here the spatial arrangement of blastomeres can follow various patterns, due to different planes of cleavage, in various organisms:

Cleavage patterns followed by holoblastic and meroblastic eggs

Holoblastic	Meroblastic
Radial (sea urchin, amphioxus) Bilateral (tunicates, amphibians) Spiral (annelids, mollusks) Rotational (mammals)	Discoidal (fish, birds, reptiles) Superficial (insects)

Blastula and Gastrula

After the cleavage has produced over 100 cells, the embryo is called a blastula (Campbell). The blastula is usually a spherical layer of cells (the blastoderm) surrounding a fluid-filled or yolk-filled cavity (the blastocoel).

Mammals form a structure called the blastocyst(NCBI), characterized by an inner cell mass that is not present in the blastula. The blastocyst must not be confused with the blastula; even though they are similar in structure their, cells have different fates.

During gastrulation cells migrate to the interior of the blastula, consequently forming two (in diploblastic animals) or three (triploblastic) germ layers. The embryo during this process is called a gastrula. The germ layers are reffered to as the ectoderm, endoderm and mesoderm. In diploblastic animals only the ectoderm and the endoderm are present while triploblastic animals also have the mesoderm (Campbell).

• Among the different animals, different combinations of the following processes occur to place the cells in the interior of the embryo:
  • Epiboly-expansion of one cell sheet over other cells (NCBI)
  • Ingression-cells move with pseudopods (NCBI)
  • Invagination-forming the mouth, anus, and archenteron (Campbell)
  • Delamination-the external cells divide, leaving the daughter cells in the cavity (NCBI)
  • Polar proliferation

• Other major changes during gastrulation:
  • Heavy RNA transcription using 'zygotic' genes; up to this point the RNAs used were maternal (stored in the unfertilized egg).
  • Cells start major differentiation processes, losing their pluripotentiality.

At Gastrulation we begin to see the first seperation of animal developement. This seperation comes from the duterostomes and protostomes. Deutrostomes mouth forms from the from the blastopore and the Protostomes anus forms from the blastopore.

Organogenesis

At some point after the different germ layers are defined, organogenesis begins. The first stage in vertebrates is called neurulation, where the neural plate folds forming the neural tube (Campbell). Other common organs or structures which arise at this time include the heart and somites, but from now on embryogenesis follows no common pattern among the different taxa of the animal kingdom.

In most animals organogenesis along with morphogenesis will result in a larva. The hatching of the larva, which must then undergo metamorphosis, marks the end of embryonic development.

See also

• Mammalian embryogenesis
• Drosophila embryogenesis
• Plant embryogenesis
• Cdx2 gene
• Homeobox genes

Reference

• What is a cell? 2004. A Science Primer: A Basic Introduction to the Science Underlying NCBI Resources. NCBI.
• Campbell, Neil A.; Reece, Jane B.; Biology Benjamin Cummings, Pearson Education Inc 2002