Takanori Ikenaga

Cerebellar efferent neurons in teleost fish

In tetrapods, cerebellar efferent systems are mainly mediated via the cerebellar nuclei. In teleosts, the cerebellum lacks cerebellar nuclei. Instead, the cerebellar efferent neurons, termed eurydendroid cells, are arrayed within and below the ganglionic layer. Tracer injections outside of the cerebellum, which retrogradely label eurydendroid cells demonstrate that most eurydendroid cells possess two or more primary dendrites which extend broadly into the molecular layer. Some eurydendroid cells mostly situated in caudal portions of the cerebellum have only one primary dendrite. The eurydendroid cells receive inputs from the Purkinje cells and parallel fibers, but apparently do not receive inputs from the climbing fibers. Eurydendroid cells of the corpus cerebelli and medial valvula project to many brain regions, from the diencephalon to the caudal medulla. A few eurydendroid cells in the valvula project directly to the telencephalon. About half of the eurydendroid cells are aspartate immunopositive. Anti-GABA and anti-zebrin II antibodies that are known as markers for the Purkinje cells in mammals also recognize the Purkinje cells in the teleost cerebellum, but do not recognize the eurydendroid cells. These results suggest that the eurydendroid cells receive GABAergic inputs from the Purkinje cells. This relationship between the eurydendroid and Purkinje cells is similar to that between the cerebellar nuclei and Purkinje cells in mammals. The eurydendroid cells of teleost have both dissimilar as well as similar features compared to neurons of the cerebellar nuclei in tetrapods.

Morphology and immunohistochemistry of efferent neurons of the goldfish corpus cerebelli

In teleosts, cerebellar efferent neurons, known as eurydendroid cells, are dispersed within the cerebellar cortex rather than coalescing into deep cerebellar nuclei. To clarify their morphology, eurydendroid cells were labeled retrogradely by biotinylated dextran amine injection into the base of the corpus cerebelli. Labeling allowed the cells to be classified into three types—fusiform, polygonal, and monopolar—depending on their somal shapes and numbers of primary dendrites. The fusiform and polygonal type cells were distributed not only in the Purkinje cell layer but also in the molecular and granule cell layers. The monopolar type cells were distributed predominantly in the Purkinje cell layer of the ventrocaudal portion of the corpus cerebelli. These results suggest that there are some functional differences between these eurydendroid cell types. The eurydendroid cells were double‐labeled by retrograde labeling and immunohistochemistry using specific antibodies against GABA, aspartate, and zebrin II. No GABA‐like immunoreactivity was detected in the retrogradely labeled eurydendroid cells. About half of retrogradely labeled cells were immunoreactive to the anti‐aspartate antibody, suggesting that some eurydendroid cells utilize aspartate as a neurotransmitter. Zebrin II reacts with cerebellar Purkinje cells but left all retrogradely labeled neurons nonreactive, although some of these were surrounded by immunopositive fibers. This relationship between the eurydendroid and Purkinje cells is similar to that between the deep cerebellar nuclei and Purkinje cells in mammals. J. Comp. Neurol. 487:300–311, 2005.

Efferent Connections of the Cerebellum of the Goldfish, Carassius auratus

Efferent fiber connections of the corpus and valvula cerebelli in the goldfish, Carassius auratus, were studied using an anterograde neural fiber tracing technique. Efferent targets of the corpus cerebelli are the posterior parvocellular preoptic nucleus, the ventromedial and ventrolateral thalamic nucleus, dorsal posterior thalamic nucleus, periventricular nucleus of posterior tuberculum, dorsal periventricular pretectal nucleus, inferior lobe, optic tectum, torus semicircularis, nucleus of the medial longitudinal fascicle, nucleus ruber, dorsal tegmental nucleus, nucleus lateralis valvulae, reticular formation, torus longitudinalis, and the medial and lateral lobe of the valvula cerebelli. Projections to the posterior parvocellular preoptic nucleus and the periventricular nucleus of posterior tuberculum are not reported in previous studies. Efferent targets of the medial lobe of the valvula cerebelli are similar to that of the corpus cerebelli except for lacking a projection to the inferior lobe and torus longitudinalis, but showing one to the corpus cerebelli. On the other hand, the lateral lobe of the valvula cerebelli projects only to the dorsal zone of the periventricular hypothalamus, the diffuse nucleus of the inferior lobe, corpus mamillare, vagal lobe and the corpus cerebelli. There are topographical projections from the lateral valvula to the inferior lobe. These results suggest that the function of the corpus and medial lobe of the valvula cerebelli include not only motor control but also functions similar to the mammalian higher cerebellum. This study also suggests that there are obvious functional divisions between the medial and lateral lobes of the valvula cerebelli.

Central mechanisms underlying fish swimming.

Although the basic swimming rhythm is created by central pattern generators (CPGs) located in each spinal segment, command signals from the brain should be indispensable for the activation of CPGs to initiate swimming. We hypothesized that the nucleus of medial longitudinal fascicles (Nflm) is the midbrain locomotor region driving swimming rhythms in teleosts. To test this hypothesis, we recorded neuronal activities from Nflm neurons in swimming carp and analyzed the cytoarchitecture of the nucleus. We identified two types of Nflm neurons exhibiting electric activities closely related to swimming rhythms. Remarkably, tonic neurons that continued firing during swimming were found. The Nflm and neighboring oculomotor nucleus contain about 600 neurons in total, and among them as many as 500 were labeled retrogradely by an intraspinal tracer implantation and 400 neurons showed glutamatergic immunoreactivity. They are the most likely candidates for the descending neurons as the origin of driving signals that initiate swimming. Double-labeling experiments demonstrated direct connections of Nflm neurons to spinal neurons consisting of the CPG. These data imply that most Nflm neurons possibly exert an excitatory drive to the spinal CPGs through the descending axons with excitatory transmitter(s), probably glutamate. Furthermore, we confirmed that the caudal part of Nflm and the rostral part of the oculomotor nucleus overlap rostrocaudally by approximately 200 µm. In connection with the control of swimming by the brain, we carried out experiments to clarify the efferent system of the cerebellum of the goldfish. Cerebellar efferent fibers terminated in most brain regions except for the telencephalon. Importantly, the cerebellum projected also to the Nflm, suggesting the involvement of this brain region in the control of swimming. We have also determined that in the carp so-called eurydendroid cells are cerebellar efferent neurons.

Betanodavirus as a novel transneuronal tracer for fish

In order to obtain a potential new tool to analyze networks of the central nervous system of teleost fishes, we tested a fish-pathogenic betanodavirus, sevenband grouper nervous necrosis virus (SGNNV), as a transneuronal tracer using the freshwater angelfish Pterophyllum scalare as a test animal. Intravitreous injections of SGNNV into the right eye resulted first in the labelings of neuronal cell bodies in the ganglion cell layers of the retina and then those in the inner and outer nuclear layers in sequence. For the first time, labeled neurons were found also in the stratum periventriculare of the contralateral optic tectum, the ventrolateral and ventromedial thalamic nuclei, and the periventricular nucleus of posterior tuberculum in the brain, then the periventricular pretectal nucleus pars dorsalis and pars ventralis. In contrast, by injections of biotinylated dextran amine into the eye no labeled cell bodies were observed in these brain areas, but axons and terminals were labeled anterogradely. These results suggest that the virus could be transported in both directions in axons of the first order neuron and transfected the second and third order neurons by passing across synaptic clefts, and that this technique is practically applicable to the study of neurobiology in teleost.

Calcium-fluxing glutamate receptors associated with primary gustatory afferent terminals in goldfish (Carassius auratus).

Presynaptic ionotropic glutamate receptors modulate transmission at primary afferent synapses in several glutamatergic systems. To test whether primary gustatory afferent fibers express Ca2+‐permeable AMPA/kainate receptors, we utilized kainate‐stimulated uptake of Co2+ along with immunocytochemistry for the Ca2+‐binding proteins (CaBPs) calbindin and calretinin to investigate the primary gustatory afferents in goldfish (Carassius auratus). In goldfish, the primary gustatory nucleus (equivalent to the gustatory portion of the nucleus of the solitary tract) includes the vagal lobe, which is a large, laminated structure protruding dorsally from the medulla. Kainate‐stimulated uptake of Co2+ (a measure of Ca2+‐fluxing glutamate receptors) shows punctate staining distributed in the distinct laminar pattern matching the layers of termination of the primary gustatory afferent fibers. In addition, CaBP immunocytochemistry, which correlates highly with expression of Ca2+‐permeable AMPA/kainate receptors, shows a laminar pattern of distribution similar to that found with kainate‐stimulated cobalt uptake. Nearly all neurons of the vagal gustatory ganglion show Co2+ uptake and are immunopositive for CaBPs. Transection of the vagus nerve proximal to the ganglion results in loss of such punctate Co2+ uptake and of punctate CaBP staining as soon as 4 days postlesion. These results are consonant with the presence of Ca2+‐fluxing glutamate receptors on the presynaptic terminals of primary gustatory terminals, providing an avenue for modulation of primary gustatory input. J. Comp. Neurol. 506:694–707, 2008.

Distribution, Innervation, and Cellular Organization of Taste Buds in the Sea Catfish, Plotosus japonicus

The gustatory system of the sea catfish Plotosus japonicus, like that of other catfishes, is highly developed. To clarify the details of the morphology of the peripheral gustatory system of Plotosus, we used whole-mount immunohistochemistry to investigate the distribution and innervation of the taste buds within multiple organs including the barbels, oropharyngeal cavity, fins (pectoral, dorsal, and caudal), and trunk. Labeled taste buds could be observed in all the organs examined. The density of the taste buds was higher along the leading edges of the barbels and fins; this likely increases the chance of detecting food. In all the fins, the taste buds were distributed in linear arrays parallel to the fin rays. Labeling of nerve fibers by anti-acetylated tubulin antibody showed that the taste buds within each sensory field are innervated in different ways. In the barbels, large nerve bundles run along the length of the organ, with fascicles branching off to innervate polygonally organized groups of taste buds. In the fins, nerve bundles run along the axis of fin rays to innervate taste buds lying in a line. In each case, small fascicles of fibers branch from large bundles and terminate within the basal portions of the taste buds. Serotonin immunohistochemistry demonstrated that most of the taste buds in all the organs examined contained disk-shaped serotonin-immunopositive cells in their basal region. This indicates a similar organization of the taste buds, in terms of the existence of serotonin-immunopositive basal cells, across the different sensory fields in this species.

Chemosensory Systems in the Sea Catfish, Plotosus japonicus

The gustatory system of the Japanese sea catfish Plotosus japonicus is highly developed. P. japonicus has four pairs of barbels around its mouth that act as gustatory organs, and taste buds are distributed along the entire length of the barbels. The density of taste buds in barbels is higher at the tip than proximally and is also higher in rostral areas than in caudal areas. Taste bud-rich regions on barbels are more likely to come into frequent contact with environmental substrates, so uneven distribution of the taste buds would seem to benefit effective food searching. The taste buds are also distributed in the fins and trunk. The taste buds contain disk-shaped serotonin-immunopositive cells in their basal regions. The function of these basal cells and the associated serotonin regarding taste information transduction is currently unknown.