Behavioral lateralization and otolith asymmetry

Abstract

Lateralized behavior is widespread among vertebrate animals and is determined primarily by structural-functional brain asymmetry as well as by the presence of somatic and visceral asymmetry. Some kinds of asymmetric reactions are suggested to be due to the presence of asymmetry at the level of sense organs, in particular, of otolith organs. This review presents data on values and characters of otolith asymmetry (OA) in animals of various species and classes and on the effect of weightlessness and hypergravity on OA; the issue of the effect of OA on vestibular and auditory functions also is considered. In symmetric vertebrates, OA was shown to be fluctuating, and its coefficient χ ranges from −0.2 to +0.2; in the overwhelming majority of individuals, |χ| < 0.06. The low OA level enables the paired otolith organs to work in coordination; this is why the OA level is equally low regardless of the individual taxonomic and ecological position, size, age, and otolith growth rate. Individuals with the abnormally high OA level can experience difficulties in analyzing auditory and vestibular stimuli; therefore, most of such individuals are eliminated by natural selection. Unlike symmetric vertebrates, labyrinths of many Pleuronectiformes have pronounced OA-otoliths in the lower labyrinth, on average, are significantly heavier than those in the upper labyrinth. The organs of flatfish represent the only example when OA, being directional, seem to play an essential role in lateralized behavior and are suggested to be used in the spatial localization of the source of sound. The short-term weightlessness and relatively weak hypergravity (≤ 2g) do not affect OA. However, it cannot be ruled out that the long-term weightlessness and hypergravity ≥ 3g as well as some diseases and age-related changes can enhance OA and cause some functional disturbances.