Evolutionary increases in catecholamine signaling may underlie the emergence of adaptive traits and behaviors in the blind cavefish, Astyanax mexicanus

Abstract

AbstractEvolutionary changes in catecholamine neurotransmitters such as dopamine and noradrenaline can lead to habitat specific behaviors. We used tyrosine hydroxylase, a conserved precursor to the biosynthesis of dopamine and noradrenaline, to compare catecholaminergic neurons in the brain of a species undergoing allopatric speciation. The teleost fish Astyanax mexicanus is extant in two readily available forms, an ancestral river dwelling form (surface) and various derived blind cave forms (cavefish). Adaptation to nutrient poor cave life without predation has led to marked differences in the behavior of this species. The cavefish has lost defensive responses, such as stimulus aversion, found in the ancestral surface fish and instead displays enhanced food seeking behaviors. This is reflected by an increase in catecholamine immunoreactivity in the cavefish brain in regions associated with non-visual sensory perception, motor control pathways, attention, and endocrine release. These neuroanatomical regions include the olfactory system, the basal telencephalon, the preoptic nuclei, the posterior tuberculum, caudal hypothalamus, and isthmus. These results indicate that the evolutionary shift from aversive defensive responses to attractive exploratory behaviors was driven by increases in the size and/or quantity of catecholaminergic neurons in the cavefish brain.