Oxygen-sensitive Neuroepithelial Cells in the Gills of Aquatic Vertebrates

All vertebrates respond to acute hypoxic stress with reflex cardiorespiratory adjustments initiated by peripheral O₂ chemoreceptors. In mammals, these specialized cells are stimulated by hypoxia and lead to activation of sensory nerves, allowing central integration and resulting physiological responses, such as hyperventilation. While the role of O₂ chemoreceptors has been well characterized in mammals, relatively little is known about O₂ chemoreception in aquatic vertebrates. This chapter reviews the morphological, physiological and developmental studies that have examined the role of O₂-sensitive neuroepithelial cells (NECs), which display characteristics similar to mammalian chemoreceptors, and potential chemosensory pathways of the gills in fish and larval amphibians. The gill is a multifunctional organ that receives sensory innervation from the glossopharyngeal or vagus cranial nerves. Extracellular recordings from these nerves provide strong evidence for the gill as a site of O₂ chemoreception. NECs of the gill epithelium, most of which contain the neurotransmitter serotonin, are neurosecretory and associated with nerve fibres. In agreement with the membrane hypothesis’, patch-clamp recordings have indicated that NECs isolated from the zebrafish gill respond to acute hypoxia with decreased K⁺ channel activity and membrane depolarization. Thus, NECs are potential O₂ sensors of the gill that may initiate cardiorespiratory reflexes in aquatic vertebrates. The few available studies that have examined O₂ sensing in fish have indicated that afunctional system of O₂ chemoreception begins to develop before complete formation of the gills, but another extrabranchial site must regulate hypoxic responses during earlier stages. Aquatic vertebrates 2 represent attractive models for pursuing studies of O₂ sensing, from cellular mechanisms to behavioural responses. These studies will provide important information about O₂ sensing and respiratory regulation in aquatic species, and how this system has evolved in vertebrates.