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Body symmetry

Animals may be asymmetrical, radial, or bilateral in form ( [link] ). Asymmetrical animals are animals with no pattern or symmetry; an example of an asymmetrical animal is a sponge ( [link] a ). An organism with radial symmetry ( [link] b ) has a longitudinal (up-and-down) orientation: Any plane cut along this up–down axis produces roughly mirror-image halves. An example of an organism with radial symmetry is a sea anemone.

Illustration a shows an asymmetrical sponge with a tube-like body and a growth off to one side. Illustration b shows a sea anemone with a tube-like, radially symmetrical body. Tentacles grow from the top of the tube. Three vertical planes arranged 120 degrees apart dissect the body. The half of the body on one side of each plane is a mirror image of the body on the other side. Illustration c shows a goat with a bilaterally symmetrical body. A plane runs from front to back through the middle of the goat, dissecting the body into left and right halves, which are mirror images of each other. The top part of the goat is defined as dorsal, and the bottom part is defined as ventral. The front of the goat is defined as anterior, and the back is defined as posterior.
Animals exhibit different types of body symmetry. The (a) sponge is asymmetrical and has no planes of symmetry, the (b) sea anemone has radial symmetry with multiple planes of symmetry, and the (c) goat has bilateral symmetry with one plane of symmetry.

Bilateral symmetry is illustrated in [link] c using a goat. The goat also has upper and lower sides to it, but they are not symmetrical. A vertical plane cut from front to back separates the animal into roughly mirror-image right and left sides. Animals with bilateral symmetry also have a “head” and “tail” (anterior versus posterior) and a back and underside (dorsal versus ventral).

Getting a head

A product of bilateral symmetry and of organisms having a head (anterior) and a tail (posterior) is the fact organisms move through their environment head first. Since organisms move through their environment head first, a significant advantage can be seen with organisms that have a concentration of sensory organs in the head region or cephalization . In other words, placement of sensory organs around the mouth of a heterotroph allows it to be more efficient at finding food. In addition, organisms moving around with the sensory organs in the front will be more efficient at detecting potential predators and not becoming food.

Segmentation

The division of an animal into repeating body parts is called segmentation . You can clearly see segmentation in earthworms and millipeds, but in some insects and chordates the subdivisions are not as obvious. What are the advantages of a segmented body? Segmentation allows for greater flexibility and mobility. The repeating body parts allows for specialization of specific body parts, such as the development of legs, arm and wings.

Germ layers

Nearly all animal species undergo a layering of early tissues during embryonic development. These layers are called germ layers . Each layer develops into a specific set of tissues and organs. Animals develop either two or three embryonic germ layers ( [link] ). The animals that display radial symmetry develop two germ layers, an inner layer (endoderm) and an outer layer (ectoderm). These animals are called diploblasts. Animals with bilateral symmetry develop three germ layers: an inner layer (endoderm), an outer layer (ectoderm), and a middle layer (mesoderm). Animals with three germ layers are called triploblasts.

The left illustration shows the two embryonic germ layers of a diploblast. The inner layer is the endoderm, and the outer layer is the ectoderm. Sandwiched between the endoderm and the ectoderm is a non-living layer. The right illustration shows the three embryonic germ layers of a triploblast. Like the diploblast, the triploblast has an inner endoderm and an outer ectoderm. Sandwiched between these two layers is a living mesoderm.
During embryogenesis, diploblasts develop two embryonic germ layers: an ectoderm and an endoderm. Triploblasts develop a third layer—the mesoderm—between the endoderm and ectoderm.

In triploblasts, the three germ layers develop in all the parts of an adult animal. The endoderm gives rise to the innermost lining of internal organs, such as those in the digestive tract, the liver, the pancreas and the lining of the lungs. The majority of organs and tissues in an adult animal such as the kidney, heart, muscles, blood vessels, bones and the dermis (inner layer of skin) develop from the mesoderm . Lastly, the ectoderm develops into the outermost layer of skin (epidermis), the lens and cornea of the eye, and the nervous system (brain and nerves).

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Source:  OpenStax, Principles of biology. OpenStax CNX. Aug 09, 2016 Download for free at http://legacy.cnx.org/content/col11569/1.25
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