Font Size: Large | Normal | Small
Font Face: Verdana | Geneva | Georgia

Larvaceans (Class Appendicularia) are solitary, free-swimming tunicates found throughout the world's oceans. Like most tunicates, appendicularians are filter feeders. Unlike other tunicates, appendicularians live in the pelagic zone, specifically in the upper sunlit portion of the ocean (photic zone) or sometimes deeper. They are transparent planktonic animals, generally less than 1 centimetre (0.39 in) in body length (excluding the tail).

The appendicularian body shape resembles that of the tadpole-like larvae of most tunicates. Like a common tunicate larva, the adult appendicularian form has a discrete trunk and tail. Evolution by retaining juvenile traits as an adult is known as neoteny.

Like most urochordates, appendicularians feed by drawing particulate food matter into their pharyngo-branchial region, where food particles are trapped on a mucus mesh produced by the pharynx and drawn into t he digestive tract. The mucus mesh lies over two clefts in the pharynx, one on either side, rather than the much larger number of clefts found in most other tunicates. Furthermore, the clefts, and the anus, open directly to the outside, and the animal therefore lacks the atrium and atrial siphon found in related classes.

Appendicularians have greatly improved the efficiency of food intake by producing a test (skeleton) known as a "house" of protein and cellulose that, in most cases, surrounds the animal like a bubble and which contains a complicated arrangement of filters that allow food in the surrounding water to be brought in and concentrated prior to feeding. Even in those species in which the house does not completely surround the body, such as Fritillaria, it is always present and attached to at least one surface. The high efficiency of this method allows larvaceans to feed on much smaller nannoplankton than most other filter feeders.

These houses are discarded and replaced regularly as the animal grows in size and the filters become clogged; in Oikopleura, a house is kept no more than four hours before being replaced. No other Tunicate is able to abandon its test in this fashion. Discarded larvacean houses account for a significant fraction of organic material descending to the ocean deeps.(Robinson, Reisenbichler & Sherlock 2005)

The tail of appendicularians contain a central notochord, a dorsal nerve cord, and a series of striated muscle bands enveloped either by epithelial tissue (Oikopleurids) or by an acellular basement membrane (Fritillarids). By regularly beating the tail, the appendicularian can generate water currents within its house that allow the concentration of food.

Appendicularians reproduce sexually. The immature animals resemble the tadpole larvae of Ascidians, albeit with the addition of developing viscera. Once the trunk is fully developed, the larva undergoes "tail shift", in which the tai l moves from a rearward position to a ventral orientation and twists 90 degrees relative to the trunk. Following tail shift, the appendicularian will begin secretion of the first house.

The recent development of techniques for expressing foreign genes in Oikopleura dioica has led to the advancement of this species as a model organism for the study of gene regulation, chordate evolution and development.

b>Larvaceans (Class Appendicularia) are solitary, free-swimming tunicates found throughout the world's oceans. Like most tunicates, appendicularians are filter feeders. Unlike other tunicates, appendicularians live in the pelagic zone, specifically in the upper sunlit portion of the ocean (photic zone) or sometimes deeper. They are transparent planktonic animals, generally less than 1 centimetre (0.39 in) in body length (excluding the tail).

The appendicularian body shape resembles that of the tadpo le-like larvae of most tunicates. Like a common tunicate larva, the adult appendicularian form has a discrete trunk and tail. Evolution by retaining juvenile traits as an adult is known as neoteny.

Like most urochordates, appendicularians feed by drawing particulate food matter into their pharyngo-branchial region, where food particles are trapped on a mucus mesh produced by the pharynx and drawn into the digestive tract. The mucus mesh lies over two clefts in the pharynx, one on either side, rather than the much larger number of clefts found in most other tunicates. Furthermore, the clefts, and the anus, open directly to the outside, and the animal therefore lacks the atrium and atrial siphon found in related classes.

Appendicularians have greatly improved the efficiency of food intake by producing a test (skeleton) known as a "house" of protein and cellulose that, in most cases, surrounds the animal like a bubble and which contains a complicated arrangement of filters that allow food in t he surrounding water to be brought in and concentrated prior to feeding. Even in those species in which the house does not completely surround the body, such as Fritillaria, it is always present and attached to at least one surface. The high efficiency of this method allows larvaceans to feed on much smaller nannoplankton than most other filter feeders.

These houses are discarded and replaced regularly as the animal grows in size and the filters become clogged; in Oikopleura, a house is kept no more than four hours before being replaced. No other Tunicate is able to abandon its test in this fashion. Discarded larvacean houses account for a significant fraction of organic material descending to the ocean deeps.(Robinson, Reisenbichler & Sherlock 2005)

The tail of appendicularians contain a central notochord, a dorsal nerve cord, and a series of striated muscle bands enveloped either by epithelial tissue (Oikopleurids) or by a n acellular basement membrane (Fritillarids). By regularly beating the tail, the appendicularian can generate water currents within its house that allow the concentration of food.

Appendicularians reproduce sexually. The immature animals resemble the tadpole larvae of Ascidians, albeit with the addition of developing viscera. Once the trunk is fully developed, the larva undergoes "tail shift", in which the tail moves from a rearward position to a ventral orientation and twists 90 degrees relative to the trunk. Following tail shift, the appendicularian will begin secretion of the first house.

The recent development of techniques for expressing foreign genes in Oikopleura dioica has led to the advancement of this species as a model organism for the study of gene regulation, chordate evolution and development.

References

• Bone, Q. 1998. The Biology of Pelagic Tunicates. Oxford University Press.
• Robison, Bruce H.; Reisenbichler, Kim R.; Sherlock, Rob E. (2005), "Giant Larvacean Houses: Rapid Carbon Transport to the Deep Sea Floor", Science 308 (5758): 1609?1611, http://www.sciencemag.org/cgi/content/abstract/308/5728/1609 .
• Clarke; Bouquet (2007), "Rapidly evolving lamins in a chordate, Oikopleura dioica, with unusual nuclear architecture", Gene 396 (1): 159?169 .

External links

• General article on pelagic tunicates, including larvaceans
• Appendicularia Fact Sheet