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Advances in the neural bases of orientation and navigation
Authors:Murray James A  Estepp Jessica  Cain Shaun D
Affiliation:* Department of Biology, 156 Lewis Science Center, University of Central Arkansas Conway, AR 72035, USA
"{dagger}" 620 University Road, Friday Harbor Labs, Friday Harbor, WA 98250, USA
Abstract:The ability to locomote in one direction (oriented movement),and the ability to navigate toward a distant goal are relatedbehaviors that are phylogenetically widespread. Orientationbehaviors include finding the source of an odor or acousticsignal, using a sun-compass for guidance, and moving relativeto fluid-dynamic cues. Such abilities might require little morethan directionally selective sensors coupled to a turning mechanism.This type of behavior, therefore, can be implemented by relativelysimple circuits. In contrast, navigation involves both the abilityto detect direction, as well as a map-sense that provides position.Navigation is less common and arguably requires greater braincomputation than does simple orientation, but may be presentin arthropods as well as in vertebrates. Great progress hasbeen made in exploring the biophysical and sensory bases forthese behaviors, and in recent years the locations and the identityof the cellular transducers of the sensory stimuli (for example,geomagnetic fields) have been narrowed in some taxa. Similarly,neurons within the central nervous that most likely functionin higher order computational processes have been identified.For example, direction-selective and position-responsive braincells have been located in the brains of mammals and birds,and these cells might contribute to a cognitive map that canenable navigation. One model organism in which orientation andnavigation has been extensively studied is the sea slug Tritoniadiomedea. This animal orients its crawling to chemical, hydrodynamic,and geomagnetic cues. The brain of Tritonia has ~7000 relativelylarge neurons that facilitate circuit analysis. Recent workhas characterized both peripheral and central neural correlatesof orientation signals, as well as the control of thrust andturning, and studies of their field behavior have suggestedhow these disparate orientation systems may be integrated. Thesefindings provide the basis for future studies to determine howthe nervous system combines multiple sensory cues into a complexhierarchy of signals that can direct motor output and thereforeguide navigational tasks.
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