Otophysan Fishes Research Articles

Organization and connections of the dorsal descending nucleus and other presumed acoustic areas in the brainstem of the teleost fish, Astronotus ocellatus

This study provides new information on brainstem areas, assumed to be auditory based on observations in other species, in the oscar, Astronotus ocellatus. The primary goal of the study was to explore the morphology of the dorsal descending octaval nucleus, which contains a population of neurons that receives acoustic afferents from the inner ear. Using cytoarchitectonic and connectional criteria, we revised the previously defined dorsal boundary of the descending octaval nucleus, such that the most dorsomedial neurons in this nucleus are positioned ventral to the cerebellar crest and medial to nucleus medialis. At some levels, these dorsomedial cells are continuous with another part of the dorsal descending nucleus that underlies nucleus medialis. The terminal fields of the saccule and lagena are located within this latter, more ventral part of the dorsal descending nucleus. However, the dorsomedial cells that are proximate to the cerebellar crest have long ventral dendrites that extend into these terminal fields, and therefore likely receive saccular and lagenar input. In contrast to a previous report, saccular afferents terminate more medially within the dorsal descending nucleus than do lagenar inputs. Injections of horseradish peroxidase in nucleus centralis of the torus semicircularis revealed that many descending nucleus neurons that lie within the saccular and lagenar terminal fields, including the dorsomedial neurons proximate to the cerebellar crest, project to this acoustic midbrain area. These injections also revealed a secondary octaval population like that described in otophysan fishes.

Descending neural projections to the spinal cord in the channel catfish, Ictalurus punctatus.

Retrograde transport of horseradish peroxidase was used to determine the descending projections to the spinal cord in an otophysan fish, the channel catfish, Ictalurus punctatus. The majority of cells projecting to the spinal cord are located in the reticular formation, which is organized into rhombomeric segments. Vestibulospinal neurons are located in the descending, magnocellular, and tangential octaval nuclei, as well as in the medial octavolateralis nucleus of the lateral line system. Cells in the facial lobe project to the spinal cord. Additionally, axons of cells of the trigeminal system and the nucleus of the lateral lemniscus project caudally into the spinal cord. In the midbrain, descending spinal projections arise from cells of the medial longitudinal fasciculus and the red nucleus. More rostrally, cells of the ventrolateral thalamus, dorsal periventricular hypothalamus, central pretectal and magnocellular preoptic nuclei also project to the cord. The results of this study indicate that there are a number of homologies in the descending systems of bony fishes and other vertebrate taxa, including tetrapods. We also provide further evidence that a red nucleus is present in the brains of bony fishes and is therefore a primitive vertebrate character antedating the evolution of tetrapods.

Cell proliferation and hair cell addition in the ear of the goldfish, Carassius auratus

Cell proliferation and hair cell addition have not been studied in the ears of otophysan fish, a group of species who have specialized hearing capabilities. In this study we used the mitotic S-phase marker bromodeoxyuridine (BrdU) to identify proliferating cells in the ear of one otophysan species, Carassius auratus (the goldfish). Animals were sacrificed at 3 h or 5 days postinjection with BrdU and processed for immunocytochemistry. The results of the study show that cell proliferation occurs in all of the otic endorgans and results in the addition of new hair cells. BrdU-labeled cells were distributed throughout all epithelia, including the primary auditory endorgan (saccule), where hair cell phenotypes vary considerably along the rostrocaudal axis. This study lays the groundwork for our transmission electron microscopy study of proliferative cells in the goldfish ear (Presson et al., Hearing Research 100 (1996) 10–20) as well as future studies of hair cell development in this species. The ability to predict, based on epithelial location, the future phenotype of developing hair cells in the saccule of the goldfish make that endorgan a particularly powerful model system for the investigation of early hair cell differentiation.

A Molecular and Morphological Perspective on the Phylogenetic Relationships of the Otophysan Fishes

We examined the phylogenetic relationships among the major lineages of otophysan fishes (Cypriniformes, Characiformes, Siluroidei, and Gymnotoidei) using a combined analysis of molecular and morphological characters. The molecular characters comprised 160 phylogenetically informative sites from nuclear-encoded ribosomal RNA and 208 phylogenetically informative sites from the mitochondrial genes encoding ribosomal RNA and the valine transfer RNA for nine otophysan taxa and a gonorynchiform outgroup. The morphological data comprised 85 characters that were obtained from an earlier cladistic study. Congruence among molecular and morphological characters is generally high. The combined analysis supports a sister group relationship between the Gymnotoidei and Siluroidei, which together form a sister group to the Characiformes. The separation of the Cypriniformes from all other otophysans represents the earliest phylogenetic split within the Otophysi. Despite the generally high congruence among molecular and morphological characters, the molecular data analyzed separately produce a topology that differs from the analysis of the combined data. Sources of the taxonomic incongruence between the molecular and morphological data are examined.

Comparative Studies on the Mauthner Cell of Teleost Fish in Relation to Sensory Input

Most physiological and behavioral studies of the Mauthner cells have used the goldfish and a few other fish from the superorder Ostariophysi, series Otophysi (= otophysans). We first provide some background and recent findings on the Mauthner cells of otophysan fish and then compare this information to that known about the Mauthner cells in certain non-otophysan fish. These comparisons are meant to provide the impetus for a comparative approach to understanding the role of the Mauthner cells in behavior.

Zebrafish inner ear sensory surfaces are similar to those in goldfish

The inner ear of the zebrafish ( Brachydanio rerio) is very similar to that of the goldfish in its structural details, including the distribution and orientation of mechanosensory hair cell populations. Both species have been used in studying different aspects of the acoustic startle response. These structural similarities suggest that the zebrafish is a valid representative model for understanding peripheral hearing specializations in otophysan fishes.