Click here to close Hello! We notice that you are using Internet Explorer, which is not supported by Xenbase and may cause the site to display incorrectly. We suggest using a current version of Chrome, FireFox, or Safari.
Prog Neurobiol 1989 Jan 01;323:181-206. doi: 10.1016/0301-0082(89)90016-6.
Show Gene links Show Anatomy links

Development of the lateral line system in Xenopus.

Winklbauer R .

The lateral line system of fishes and amphibians consists of numerous epidermal mechano-receptors which are distributed over the whole body surface. As in other amphibians, the lateral line system of Xenopus develops from epidermal placodes situated on the head region of the embryo. The dorsolateralis placodes form a rostro-caudal series of epidermal thickenings centered around the otic placode. In this series, placodes remaining within the epidermis and forming lateral line primordia alternate with lateral line ganglion forming placodes. Each lateral line primordium elongates and migrates within the epidermis along a well-defined pathway, leaving behind a row of small cell groups, the primary lateral line organs. As the ganglion which supplies a given row of organs and the corresponding lateral line primordium originate in spatial contiguity, and as the axons of the lateral line nerve grow out together with the migrating primordium, the lateral line neurones remain in contact with their target cells throughout development. After segregation of a primary organ from a migrating primordium, cell differentiation occurs. Receptor cells establish afferent and efferent synaptic contacts with axons from the lateral line nerve. Apically, a bundle of stereocilia and a single, microtubule-containing kinocilium protrude from the surface of a receptor cell into a jelly-like cupula, which extends into the surrounding fluid. Displacement of the cupula and the concomitant bending of the cilia stimulates the receptor cells. The cilia of a receptor cell are asymmetrically arranged, and this structural polarity is related to the directional sensitivity of the cells. Two types of receptor cells, with opposite orientations, are intermingled within each organ, giving the whole organ a bidirectional sensitivity. The number of lateral line organs is increased by the process of accessory organ formation, where primary organs grow and divide to produce secondary organs. In this way, existing rows of organs are extended. Moreover, single primary organs are transformed into elongate plaques of closely apposed organs. The lateral line system has reached its greatest extent at late larval stages. During metamorphosis, the number of organ plaques is reduced in some lines, and one line even disappears completely. Two large, myelinated afferent fibers innervate a whole organ plaque. They branch repeatedly to supply every organ of the plaque, and each fiber is thought to innervate only receptor cells of the same polarity.(ABSTRACT TRUNCATED AT 400 WORDS)

PubMed ID: 2652193
Article link: Prog Neurobiol