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1. Neuronal Circuits That Control Rhythmic Pectoral Fin Movements in Zebrafish

Author

Koichi Kawakami, Shin-ichi Higashijima, Yuto Uemura, Yukiko Kimura, Yoichi Oda, and Kagayaki Kato

Subjects
0301 basic medicine, Periodicity, Movement, Inhibitory postsynaptic potential, 03 medical and health sciences, 0302 clinical medicine, Rhythm, Alternation (formal language theory), Animals, Zebrafish, Research Articles, Motor Neurons, biology, General Neuroscience, Fish fin, Central pattern generator, Commissure, Zebrafish Proteins, biology.organism_classification, musculoskeletal system, body regions, DNA-Binding Proteins, 030104 developmental biology, Excitatory postsynaptic potential, Animal Fins, Central Pattern Generators, Neuroscience, 030217 neurology & neurosurgery, Transcription Factors
Abstract

The most basic form of locomotion in limbed vertebrates consists of alternating activities of the flexor and extensor muscles within each limb coupled with left/right limb alternation. Although larval zebrafish are not limbed, their pectoral fin movements exhibit the following fundamental aspects of this basic movement: abductor/adductor alternation (corresponding to flexor/extensor alternation) and left/right fin alternation. Because of the simplicity of their movements and the compact neural organization of their spinal cords, zebrafish can serve as a good model to identify the neuronal networks of the central pattern generator (CPG) that controls rhythmic appendage movements. Here, we set out to investigate neuronal circuits underlying rhythmic pectoral fin movements in larval zebrafish, using transgenic fish that specifically express GFP in abductor or adductor motor neurons (MNs) and candidate CPG neurons. First, we showed that spiking activities of abductor and adductor MNs were essentially alternating. Second, both abductor and adductor MNs received rhythmic excitatory and inhibitory synaptic inputs in their active and inactive phases, respectively, indicating that the MN spiking activities are controlled in a push-pull manner. Further, we obtained the following evidence that dmrt3a-expressing commissural inhibitory neurons are involved in regulating the activities of abductor MNs: (1) strong inhibitory synaptic connections were found from dmrt3a neurons to abductor MNs; and (2) ablation of dmrt3a neurons shifted the spike timing of abductor MNs. Thus, in this simple system of abductor/adductor alternation, the last-order inhibitory inputs originating from the contralaterally located neurons play an important role in controlling the firing timings of MNs. SIGNIFICANCE STATEMENT Pectoral fin movements in larval zebrafish exhibit fundamental aspects of basic rhythmic appendage movement: alternation of the abductor and adductor (corresponding to flexor–extensor alternation) coupled with left–right alternation. We set out to investigate the neuronal circuits underlying rhythmic pectoral fin movements in larval zebrafish. We showed that both abductor and adductor MNs received rhythmic excitatory and inhibitory synaptic inputs in their active and inactive phases, respectively. This indicates that MN activities are controlled in a push-pull manner. We further obtained evidence that dmrt3a-expressing commissural inhibitory neurons exert an inhibitory effect on abductor MNs. The current study marks the first step toward the identification of central pattern generator organization for rhythmic fin movements.

Published
2020

2. Lateralized expression of left-right axis formation genes is shared by adult brains of lefty and righty scale-eating cichlids

Author

Asano Ishikawa, Jun Kitano, Yoichi Oda, and Yuichi Takeuchi

Subjects
Male, 0301 basic medicine, Physiology, Gene Expression, Hindbrain, Biochemistry, 03 medical and health sciences, Cichlid, Perissodus microlepis, Genetics, medicine, Animals, Molecular Biology, biology, Sequence Analysis, RNA, Cerebrum, Brain, Inversion (evolutionary biology), Lefty, Cichlids, Feeding Behavior, biology.organism_classification, 030104 developmental biology, medicine.anatomical_structure, Evolutionary biology, Laterality, Female, Transcriptome, NODAL
Abstract

Variation in the laterality often exists within species and can be maintained by frequency-dependent selection. Although the molecular developmental mechanisms underlying the left-right axis formation have been investigated, the genomic mechanisms underlying variation in laterality remain largely unknown. The scale-eating cichlid Perissodus microlepis in Lake Tanganyika exhibit lateralized predation; lefty individuals with the mouth opening toward the right preferentially attack on the prey's left trunk, while righty individuals with the opposite opening attacks on the right trunk. Here, we performed RNA-sequencing and subsequent confirmation with quantitative-PCR in the telencephalon, optic tectum, and hindbrain of the cichlid and identified five genes (pkd1b, ntn1b, ansn, pde6g, and rbp4l1) that were differentially expressed between the hemispheres regardless of the laterality. Surprisingly, pkd1b and ntn1b are involved in nodal and netrin signalling, respectively, which are important for left–right asymmetry formation during early embryogenesis. This result indicates that nodal- and netrin-related signals may also play important roles in the maintenance of asymmetry in adult brain. By contrast, no genes showed reversal of lateral differences between lefty and righty individuals in any brain regions examined, suggesting that laterality in the scale-eating cichlid does not simply result from inversion of the left–right asymmetry of gene expression.

Published
2018
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3. Astroglial Ca 2+ signaling is generated by the coordination of IP 3 R and store-operated Ca 2+ channels

Author

Shigeo Sakuragi, Katsuhiko Mikoshiba, Hiroko Bannai, Yoichi Oda, and Fumihiro Niwa

Subjects
0301 basic medicine, Voltage-dependent calcium channel, Endoplasmic reticulum, Biophysics, Cell Biology, Biology, Hippocampal formation, Neurotransmission, Biochemistry, Calcium in biology, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, 0302 clinical medicine, chemistry, Inositol, Receptor, Molecular Biology, 030217 neurology & neurosurgery, Homeostasis
Abstract

Astrocytes play key roles in the central nervous system and regulate local blood flow and synaptic transmission via intracellular calcium (Ca2+) signaling. Astrocytic Ca2+ signals are generated by multiple pathways: Ca2+ release from the endoplasmic reticulum (ER) via the inositol 1, 4, 5-trisphosphate receptor (IP3R) and Ca2+ influx through various Ca2+ channels on the plasma membrane. However, the Ca2+ channels involved in astrocytic Ca2+ homeostasis or signaling have not been fully characterized. Here, we demonstrate that spontaneous astrocytic Ca2+ transients in cultured hippocampal astrocytes were induced by cooperation between the Ca2+ release from the ER and the Ca2+ influx through store-operated calcium channels (SOCCs) on the plasma membrane. Ca2+ imaging with plasma membrane targeted GCaMP6f revealed that spontaneous astroglial Ca2+ transients were impaired by pharmacological blockade of not only Ca2+ release through IP3Rs, but also Ca2+ influx through SOCCs. Loss of SOCC activity resulted in the depletion of ER Ca2+, suggesting that SOCCs are activated without store depletion in hippocampal astrocytes. Our findings indicate that sustained SOCC activity, together with that of the sarco-endoplasmic reticulum Ca2+-ATPase, contribute to the maintenance of astrocytic Ca2+ store levels, ultimately enabling astrocytic Ca2+ signaling.

Published
2017
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4. Phosphorylation of Gephyrin in Zebrafish Mauthner Cells Governs Glycine Receptor Clustering and Behavioral Desensitization to Sound

Author

Kozo Kaibuchi, Kazutoyo Ogino, Yoichi Oda, Tomoki Nishioka, Hiromi Hirata, and Kenta Yamada

Subjects
0301 basic medicine, Startle response, Reflex, Startle, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Receptors, Glycine, Desensitization (telecommunications), medicine, Animals, Phosphorylation, Glycine receptor, Zebrafish, Research Articles, Glycine receptor clustering, Neurons, medicine.diagnostic_test, Gephyrin, biology, Chemistry, General Neuroscience, Membrane Proteins, Long-term potentiation, Zebrafish Proteins, 030104 developmental biology, Command neuron, Synapses, biology.protein, Auditory Perception, Calcium-Calmodulin-Dependent Protein Kinase Type 2, Neuroscience, 030217 neurology & neurosurgery
Abstract

The process by which future behavioral responses are shaped by past experiences is one of the central questions in neuroscience. To gain insight into this process at the molecular and cellular levels, we have applied zebrafish larvae to explore behavioral desensitization to sound. A sudden loud noise often evokes a defensive response known as the acoustic startle response (ASR), which is triggered by firing Mauthner cells in teleosts and amphibians. The probability of evoking ASR by suprathreshold sound is reduced after exposure to repetitive auditory stimuli insufficient in amplitude to evoke the ASR (subthreshold). Although it has been suggested that the potentiation of inhibitory glycinergic inputs into Mauthner cell is involved in this desensitization of the ASR, the molecular basis for the potentiation of glycinergic transmission has been unclear. Through thein vivomonitoring of fluorescently-tagged glycine receptors (GlyRs), we here showed that behavioral desensitization to sound in zebrafish is governed by GlyR clustering in Mauthner cells. We further revealed that CaMKII-dependent phosphorylation of the scaffolding protein gephyrin at serine 325 promoted the synaptic accumulation of GlyR on Mauthner neurons through the enhancement of the gephyrin-GlyR binding, which was indispensable for and could induce desensitization of the ASR. Our study demonstrates an essential molecular and cellular basis of sound-induced receptor dynamics and thus of behavioral desensitization to sound.SIGNIFICANCE STATEMENTBehavioral desensitization in the acoustic startle response of fish is known to involve the potentiation of inhibitory glycinergic input to the Mauthner cell, which is a command neuron for the acoustic startle response. However, the molecular and cellular basis for this potentiation has been unknown. Here we show that an increase in glycine receptor (GlyR) clustering at synaptic sites on zebrafish Mauthner cells is indispensable for and could induce desensitization. Furthermore, we demonstrate that CaMKII-mediated phosphorylation of the scaffolding protein gephyrin promotes GlyR clustering by increasing the binding between the β-loop of GlyRs and gephyrin. Thus, the phosphorylation of gephyrin is a key event which accounts for the potentiation of inhibitory glycinergic inputs observed during sound-evoked behavioral desensitization.

Published
2019

5. Behavioral Role of the Reciprocal Inhibition between a Pair of Mauthner Cells during Fast Escapes in Zebrafish

Author

Masashi Tanimoto, Shin-ichi Higashijima, Takashi Shimazaki, and Yoichi Oda

Subjects
0301 basic medicine, Hindbrain, Animals, Genetically Modified, 03 medical and health sciences, 0302 clinical medicine, Calcium imaging, Mauthner cell, Escape Reaction, Interneurons, Neural Pathways, medicine, Animals, Zebrafish, Research Articles, Neurons, biology, General Neuroscience, Reciprocal inhibition, Excitatory Postsynaptic Potentials, biology.organism_classification, Rhombencephalon, Electrophysiology, 030104 developmental biology, medicine.anatomical_structure, Acoustic Stimulation, Spinal Cord, Larva, Excitatory postsynaptic potential, Neuron, Neuroscience, 030217 neurology & neurosurgery, Psychomotor Performance
Abstract

During many behaviors in vertebrates, the CNS generates asymmetric activities between the left and right sides to produce asymmetric body movements. For asymmetrical activations of the CNS, reciprocal inhibition between the left and right sides is believed to play a key role. However, the complexity of the CNS makes it difficult to identify the reciprocal inhibition circuits at the level of individual cells and the contribution of each neuron to the asymmetric activity. Using larval zebrafish, we examined this issue by investigating reciprocal inhibition circuits between a pair of Mauthner (M) cells, giant reticulospinal neurons that trigger fast escapes. Previous studies have shown that a class of excitatory neurons, called cranial relay neurons, is involved in the reciprocal inhibition pathway between the M cells. Using transgenic fish, in which two of the cranial relay neurons (Ta1 and Ta2) expressed GFP, we showed that Ta1 and Ta2 constitute major parts of the pathway. In larvae in which Ta1/Ta2 were laser-ablated, the amplitude of the reciprocal IPSPs dropped to less than one-third. Calcium imaging and electrophysiological recording showed that the occurrence probability of bilateral M-cell activation upon sound/vibration stimuli was greatly increased in the Ta1/Ta2-ablated larvae. Behavioral experiments revealed that the Ta1/Ta2 ablation resulted in shallower body bends during sound/vibration-evoked escapes, which is consistent with the observation that increased occurrence of bilateral M-cell activation impaired escape performance. Our study revealed major components of the reciprocal inhibition circuits in the M cell system and the behavioral importance of the circuits.SIGNIFICANCE STATEMENTReciprocal inhibition between the left and right side of the CNS is considered imperative for producing asymmetric movements in animals. It has been difficult, however, to identify the circuits at the individual cell level and their role in behavior. Here, we address this problem by examining the reciprocal inhibition circuits of the hindbrain Mauthner (M) cell system in larval zebrafish. We determined that two paired interneurons play a critical role in the reciprocal inhibition between the paired M cells and that the reciprocal inhibition prevents bilateral firing of the M cells and is thus necessary for the full body bend during M cell-initiated escape. Further, we discussed the cooperation of multiple reciprocal inhibitions working in the hindbrain and spinal cord to ensure high-performance escapes.

Published
2019

6. Detailed movement and laterality of fin-biting behaviour with special mouth morphology inGenyochromis mentoin Lake Malawi

Author

Bosco Rusuwa, Makiko Fukui, Richard Zatha, Takuma Nishikawa, Takuto Yamada, Yoichi Oda, Yuichi Takeuchi, Hiroki Hata, and Atsushi Maruyama

Subjects
0301 basic medicine, biology, Physiology, Foraging, Zoology, Aquatic Science, biology.organism_classification, Genyochromis mento, Predation, 03 medical and health sciences, 030104 developmental biology, Biting, Predatory fish, Perissodus microlepis, Cichlid, Insect Science, Laterality, Animal Science and Zoology, Molecular Biology, Ecology, Evolution, Behavior and Systematics
Abstract

Several vertebrates, including fish, exhibit behavioural laterality and associated morphological asymmetry. Laterality may increase individual fitness as well as foraging strength, accuracy and speed. However, little is known about which behaviours are affected by laterality or what fish species exhibit obvious laterality. Previous research on the predatory behaviour of the scale-eating Lake Tanganyika cichlid Perissodus microlepis indicates behavioural laterality that reflects asymmetric jaw morphology. The Lake Malawi cichlid Genyochromis mento feeds on the fins of other fish, a behaviour that G. mento developed independently from the Tanganyikan Perissodini scale eaters. We investigated stomach contents and behavioural laterality of predation in aquarium to clarify the functional roles and evolution of laterality in cichlids. We also compared the behavioural laterality and mouth asymmetry of G. mento and P. microlepis . The diet of G. mento mostly includes fin fragments, but also scales of several fish species. Most individual G. mento specimens showed significant attack bias favouring the skew mouth direction. However, there was no difference in success rate between attacks from the preferred side and those from the non-preferred side, and no lateralized kinetic elements in predation behaviour. Genyochromis mento showed weaker laterality than P. microlepis , partly because of their different feeding habits, the phylogenetic constraints from their shorter evolutionary history and their origin from ancestor Haplochromini omnivorous/herbivorous species. Taken together, this study provides new insights into the functional roles of behavioural laterality: predatory fish aiming for prey that show escape behaviours frequently exhibit lateralized behaviour in predation.

Published
2018
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7. Lateralized scale-eating behaviour of cichlid is acquired by learning to use the naturally stronger side

Author

Yoichi Oda and Yuichi Takeuchi

Subjects
0106 biological sciences, 0301 basic medicine, medicine.medical_specialty, Science, Audiology, 010603 evolutionary biology, 01 natural sciences, Article, Functional Laterality, Predation, 03 medical and health sciences, Perissodus microlepis, Cichlid, medicine, Animals, Learning, Dominant side, Eating behaviour, Multidisciplinary, biology, Cichlids, Feeding Behavior, biology.organism_classification, 030104 developmental biology, Predatory Behavior, Forage fish, Laterality, Medicine, Maximum amplitude
Abstract

The scale-eating cichlid Perissodus microlepis exhibits significant lateralised predation behaviour using an asymmetric mouth. But how the acquisition of the behavioural laterality depends, if at all, on experience during development remains obscure. Here, naïve juveniles were tested in a series of predation sessions. Initially, they attacked both sides of the prey, but during subsequent sessions, attack direction gradually lateralised to the skewed mouth (dominant) side. Attack side preference of juveniles that had accumulated scale-eating experience during successive sessions was significantly higher than that of naïve juveniles at the same age and naïve adults. Thus, the lateralised behaviour was a learned experience, and did not develop with age. Surprisingly, however, both maximum amplitude and angular velocity of body flexion during attack of naïve fish was dominant on one side. Therefore, scale-eating fish have a naturally stronger side for attacking prey fish, and they learn to use the dominant side through experience.

Published
2017
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8. Coexpression of auxiliary Kvβ2 subunits with Kv1.1 channels is required for developmental acquisition of unique firing properties of zebrafish Mauthner cells

Author

Yoichi Oda, Takaki Watanabe, Takashi Shimazaki, Takako Suzuki, Hiromi Hirata, Masashi Tanimoto, and Aoba Mishiro

Subjects
Elapid Venoms, Neurons, biology, Physiology, Chemistry, General Neuroscience, Action Potentials, Zebrafish Proteins, biology.organism_classification, Potassium channel, Rhombencephalon, Protein Subunits, medicine.anatomical_structure, Mauthner cell, Potassium Channel Blockers, medicine, Biophysics, Animals, Neuron, Protein Multimerization, Kv1.1 Potassium Channel, Zebrafish, Neuroscience, Ion channel
Abstract

Each neuron possesses a unique firing property, which is largely attributed to heterogeneity in the composition of voltage-gated ion channel complexes. Zebrafish Mauthner (M) cells, which are bilaterally paired giant reticulospinal neurons (RSNs) in the hindbrain and induce rapid escape behavior, generate only a single spike at the onset of depolarization. This single spiking is in contrast with the repetitive firing of the M cell's morphologically homologous RSNs, MiD2cm and MiD3cm, which are also involved in escapes. However, how the unique firing property of M cells is established and the underlying molecular mechanisms remain unclear. In the present study, we first demonstrated that the single-spiking property of M cells was acquired at 4 days postfertilization (dpf), accompanied by an increase in dendrotoxin I (DTX)-sensitive low-threshold K+currents, prior to which the M cell repetitively fires as its homologs. Second, in situ hybridization showed that among DTX-sensitive Kv1 channel α-subunits, zKv1.1a was unexpectedly expressed even in the homologs and the bursting M cells at 2 dpf. In contrast, zKvβ2b, an auxiliary β-subunit of Kv1 channels, was expressed only in the single-spiking M cells. Third, zKv1.1a expressed in Xenopus oocytes functioned as a low-threshold K+channel, and its currents were enhanced by coexpression of zKvβ2b subunits. Finally, knockdown of zKvβ2b expression in zebrafish larvae resulted in repetitive firing of M cells at 4 dpf. Taken together, these results suggest that associative expression of Kvβ2 subunits with Kv1.1 channels is crucial for developmental acquisition of the unique firing properties of the M cells among homologous neurons.

Published
2014
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9. Functional Motifs Composed of Morphologically Homologous Neurons Repeated in the Hindbrain Segments

Author

Takashi Fujii, Hisako Nakayama, Haruko Matsui-Furusho, Daisuke Neki, and Yoichi Oda

Subjects
Male, Patch-Clamp Techniques, Action Potentials, Hindbrain, Biology, Inhibitory postsynaptic potential, Functional Laterality, Statistics, Nonparametric, Mauthner cell, Postsynaptic potential, Goldfish, Neural Pathways, Reaction Time, Animals, Zebrafish, Neurons, General Neuroscience, Depolarization, Articles, biology.organism_classification, Electric Stimulation, Rhombencephalon, Electrophysiology, Spinal Cord, Excitatory postsynaptic potential, Female, Neuroscience
Abstract

Segmental organization along the neuraxis is a prominent feature of the CNS in vertebrates. In a wide range of fishes, hindbrain segments contain orderly arranged reticulospinal neurons (RSNs). Individual RSNs in goldfish and zebrafish hindbrain are morphologically identified. RSNs sharing similar morphological features are called segmental homologs and repeated in adjacent segments. However, little is known about functional relationships among segmental homologs. Here we investigated the electrophysiological connectivity between the Mauthner cell (M-cell), a pair of giant RSNs in segment 4 (r4) that are known to trigger fast escape behavior, and different series of homologous RSNs in r4–r6. Paired intracellular recordings in adult goldfish revealed unidirectional connections from the M-cell to RSNs. The connectivity was similar in morphological homologs. A single M-cell spike produced IPSPs in dorsally located RSNs (MiD cells) on the ipsilateral side and excitatory postsynaptic depolarization on the contralateral side, except for MiD2cm cells. The inhibitory or excitatory potentials effectively suppressed or enhanced target RSNs spiking, respectively. In contrast to the lateralized effects on MiD cells, single M-cell spiking elicited equally strong depolarizations on bilateral RSNs located ventrally (MiV cells), and the depolarization was high enough for MiV cells to burst. Therefore, the morphological homology of repeated RSNs in r4–r6 and their functional M-cell connectivity were closely correlated, suggesting that each functional connection works as a functional motif during the M-cell-initiated escape.

Published
2014
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10. Short-term desensitization of fast escape behavior associated with suppression of Mauthner cell activity in larval zebrafish

Author

Megumi Takahashi, Tsunehiko Kohashi, Masashi Tanimoto, Yoichi Oda, and Maya Inoue

Subjects
0301 basic medicine, Tail, Time Factors, Neural Inhibition, Escape response, 03 medical and health sciences, 0302 clinical medicine, Calcium imaging, Mauthner cell, Escape Reaction, Physical Stimulation, Conditioning, Psychological, medicine, Reaction Time, Animals, Inner ear, Neurons, Afferent, Mechanotransduction, Organic Chemicals, Zebrafish, Evoked Potentials, Microphthalmia-Associated Transcription Factor, Microscopy, Confocal, biology, General Neuroscience, General Medicine, Zebrafish Proteins, biology.organism_classification, Adaptation, Physiological, 030104 developmental biology, medicine.anatomical_structure, Sound, Larva, Calcium, sense organs, Neuron, Neuroscience, 030217 neurology & neurosurgery
Abstract

Escape is among the simplest animal behaviors employed to study the neural mechanisms underlying learning. Teleost fishes exhibit behavioral learning of fast escape initiated with a C-shaped body bend (C-start). C-starts are subdivided into short-latency (SLC) and long-latency (LLC) types in larval zebrafish. Whether these two can be separately modified, and the neural correlates of this modification, however, remains undetermined. We thus performed Ca2+ imaging of Mauthner (M-) cells, a pair of giant hindbrain neurons constituting a core element of SLC circuit, during behavioral learning in larval zebrafish. The Ca2+ response corresponding to a single spiking of the M-cells was coupled with SLCs but not LLCs. Conditioning with a repeated weak sound at subthreshold intensity to elicit C-starts selectively suppressed SLC occurrence for 10min without affecting LLC responsiveness. The short-term desensitization of SLC was associated with the suppression of M-cell activity, suggesting that changes in single neuron responsiveness mediate behavioral learning. The conditioning did not affect the acoustically evoked mechanotransduction of inner ear hair cells, further suggesting plastic change in transmission efficacy within the auditory input circuit between the hair cells and the M-cell.

Published
2017

11. Glycinergic transmission and postsynaptic activation of CaMKII are required for glycine receptor clusteringin vivo

Author

Koichi Kawakami, Mariko Miki, Hiromi Hirata, Iori Yamanaka, Yoichi Oda, and Kazuhide Asakawa

Subjects
medicine.medical_specialty, Calcium Channels, L-Type, Glycine, Biology, Neurotransmission, Synaptic Transmission, Postsynapse, Receptors, Glycine, Mauthner cell, Neurotransmitter receptor, Postsynaptic potential, Ca2+/calmodulin-dependent protein kinase, Internal medicine, Genetics, medicine, Animals, Glycine receptor, Zebrafish, Neurons, Glycine receptor clustering, Strychnine, Cell Biology, Calcium Channel Blockers, Rhombencephalon, Endocrinology, Synapses, Calcium-Calmodulin-Dependent Protein Kinase Type 2, Neuroscience
Abstract

Synaptic transmission-dependent regulation of neurotransmitter receptor accumulation at postsynaptic sites underlies the formation, maintenance and maturation of synaptic function. Previous in vitro studies showed that glycine receptor (GlyR) clustering requires synaptic inputs. However, in vivo GlyR regulation by synaptic transmission is not fully understood. Here, we established a model system using developing zebrafish, in which GlyRs are expressed in Mauthner cells (M-cells), a pair of giant, reticulospinal, hindbrain neurons, thereby enabling analysis of GlyR clusters over time in identifiable cells. Bath application of a glycinergic blocker, strychnine, to developing zebrafish prevented postsynaptic GlyR cluster formation in the M-cells. After strychnine removal, the GlyR clusters appeared in the M-cells. At a later stage, glycinergic transmission blockade impaired maintenance of GlyR clusters. We also found that pharmacological blockade of either L-type Ca(2+) channels or calcium-/calmodulin-dependent protein kinase II (CaMKII) disturbed GlyR clustering. In addition, the M-cell-specific CaMKII inactivation using the Gal4-UAS system significantly impaired GlyR clustering in the M-cells. Thus, the formation and maintenance of GlyR clusters in the M-cells in the developing animals are regulated in a synaptic transmission-dependent manner, and CaMKII activation at the postsynapse is essential for GlyR clustering. This is the first demonstration of synaptic transmission-dependent modulation of synaptic GlyRs in vivo.

Published
2013
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12. Dissection of local Ca(2+) signals inside cytosol by ER-targeted Ca(2+) indicator

Author

Fumihiro Niwa, Katsuhiko Mikoshiba, Shigeo Sakuragi, Ayana Kobayashi, Shin Takagi, Hiroko Bannai, and Yoichi Oda

Subjects
0301 basic medicine, Recombinant Fusion Proteins, Green Fluorescent Proteins, Biophysics, chemistry.chemical_element, Calcium, Biology, Endoplasmic Reticulum, Biochemistry, Time-Lapse Imaging, Animals, Genetically Modified, 03 medical and health sciences, Cytosol, Chlorocebus aethiops, Extracellular, Animals, Humans, Calcium Signaling, Rats, Wistar, Caenorhabditis elegans, Molecular Biology, Cells, Cultured, Microscopy, Confocal, Endoplasmic reticulum, Cell Membrane, Cell Biology, Cell biology, Intracellular Second Messenger, 030104 developmental biology, chemistry, Astrocytes, COS Cells, Signal transduction, Bacterial outer membrane, Intracellular, HeLa Cells
Abstract

Calcium (Ca(2+)) is a versatile intracellular second messenger that operates in various signaling pathways leading to multiple biological outputs. The diversity of spatiotemporal patterns of Ca(2+) signals, generated by the coordination of Ca(2+) influx from the extracellular space and Ca(2+) release from the intracellular Ca(2+) store the endoplasmic reticulum (ER), is considered to underlie the diversity of biological outputs caused by a single signaling molecule. However, such Ca(2+) signaling diversity has not been well described because of technical limitations. Here, we describe a new method to report Ca(2+) signals at subcellular resolution. We report that OER-GCaMP6f, a genetically encoded Ca(2+) indicator (GECI) targeted to the outer ER membrane, can monitor Ca(2+) release from the ER at higher spatiotemporal resolution than conventional GCaMP6f. OER-GCaMP6f was used for in vivo Ca(2+) imaging of C. elegans. We also found that the spontaneous Ca(2+) elevation in cultured astrocytes reported by OER-GCaMP6f showed a distinct spatiotemporal pattern from that monitored by plasma membrane-targeted GCaMP6f (Lck-GCaMP6f); less frequent Ca(2+) signal was detected by OER-GCaMP6f, in spite of the fact that Ca(2+) release from the ER plays important roles in astrocytes. These findings suggest that targeting of GECIs to the ER outer membrane enables sensitive detection of Ca(2+) release from the ER at subcellular resolution, avoiding the diffusion of GECI and Ca(2+). Our results indicate that Ca(2+) imaging with OER-GCaMP6f in combination with Lck-GCaMP6f can contribute to describing the diversity of Ca(2+) signals, by enabling dissection of Ca(2+) signals at subcellular resolution.

Published
2016

13. Origin of Inner Ear Hair Cells: Morphological and Functional Differentiation from Ciliary Cells into Hair Cells in Zebrafish Inner Ear

Author

Yoichi Oda, Masashi Tanimoto, Maya Inoue, and Yukiko Ota

Subjects
Stereocilia (inner ear), Mechanotransduction, Cellular, Otolithic Membrane, otorhinolaryngologic diseases, medicine, Animals, Inner ear, Mechanotransduction, Zebrafish, Vestibular system, Hair Cells, Auditory, Inner, Microscopy, Confocal, biology, General Neuroscience, Cell Differentiation, Articles, Anatomy, Kinocilium, biology.organism_classification, Immunohistochemistry, Embryonic stem cell, Cell biology, Electrophysiology, medicine.anatomical_structure, Ear, Inner, sense organs, Transduction (physiology)
Abstract

Auditory and vestibular functions in vertebrates depend on the transduction of sound vibration or head acceleration into electrical responses in inner ear hair cells. Mechanoelectrical transduction occurs at the tip of stereocilia, which are polarized to form an orientational arrangement that determines directional sensitivity. It remains to be clarified when and how premature hair cells acquire their specialized structure and function in living animals. The developmental origin of inner ear hair cells has been studiedin vivoin zebrafish embryos. Tether cells, a small number of ciliated cells associated with an “ear stone” (or otolith) in the embryonic zebrafish inner ear, are believed to be precocious hair cells. However, whether or not tether cells acquire hair bundles and mechanosensitivity remains unknown. In the present study, we investigated the morphological and functional development of tether cells. Immunohistochemical examination revealed that stereocilia appeared on the tether cell apex in a polarized arrangement at 22 h postfertilization (hpf). Labeling with FM1-43, a marker of functional mechanotransduction channels, and thein vivoelectrophysiological recording of mechanotransducer responses in the developing inner ear demonstrated that tether cells acquired direction-selective mechanosensitivity at 23 hpf. These results revealed that tether cells begin to function as hair cells within an hour after the appearance of a polarized array of stereociliary bundles. Thus, the ciliary cells morphologically and functionally differentiate into the first sensory hair cells in the inner ear of the zebrafish.

Published
2011
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14. Biogenesis of GPI-anchored proteins is essential for surface expression of sodium channels in zebrafish Rohon-Beard neurons to respond to mechanosensory stimulation

Author

Morihisa Fujita, Kazutoyo Ogino, Taroh Kinoshita, Yuri Nakano, Yoichi Oda, Louis Saint-Amant, and Hiromi Hirata

Subjects
Embryo, Nonmammalian, animal structures, Sensory Receptor Cells, Glycosylphosphatidylinositols, Sodium, Protein subunit, Mutant, chemistry.chemical_element, Stimulation, CHO Cells, Mechanotransduction, Cellular, Sodium Channels, Animals, Genetically Modified, Cricetulus, Cricetinae, Physical Stimulation, Animals, RNA, Small Interfering, Molecular Biology, Zebrafish, Cell Death, biology, Sodium channel, Membrane Proteins, biology.organism_classification, Embryonic stem cell, Cell biology, Electrophysiology, chemistry, Gene Knockdown Techniques, Antigens, Surface, embryonic structures, Developmental Biology
Abstract

In zebrafish, Rohon-Beard (RB) neurons are primary sensory neurons present during the embryonic and early larval stages. At 2 days post-fertilization (dpf), wild-type zebrafish embryos respond to mechanosensory stimulation and swim away from the stimuli, whereas mi310 mutants are insensitive to touch. During ~2-4 dpf, wild-type RB neurons undergo programmed cell death, which is caused by sodium current-mediated electrical activity, whereas mutant RB cells survive past 4 dpf, suggesting a defect of sodium currents in the mutants. Indeed, electrophysiological recordings demonstrated the generation of action potentials in wild-type RB neurons, whereas mutant RB cells failed to fire owing to the reduction of voltage-gated sodium currents. Labeling of dissociated RB neurons with an antibody against voltage-gated sodium channels revealed that sodium channels are expressed at the cell surface in wild-type, but not mutant, RB neurons. Finally, in mi310 mutants, we identified a mis-sense mutation in pigu, a subunit of GPI (glycosylphosphatidylinositol) transamidase, which is essential for membrane anchoring of GPI-anchored proteins. Taken together, biogenesis of GPI-anchored proteins is necessary for cell surface expression of sodium channels and thus for firings of RB neurons, which enable zebrafish embryos to respond to mechanosensory stimulation.

Published
2010
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15. Acquisition of Lateralized Predation Behavior Associated with Development of Mouth Asymmetry in a Lake Tanganyika Scale-Eating Cichlid Fish

Author

Shinya Tada, Yoichi Oda, Yuichi Takeuchi, and Michio Hori

Subjects
0106 biological sciences, 0301 basic medicine, Scale (anatomy), Physiology, lcsh:Medicine, Predation, 01 natural sciences, Medicine and Health Sciences, lcsh:Science, media_common, Multidisciplinary, biology, Ecology, Animal Behavior, Stomach, General Medicine, Cichlids, Trophic Interactions, Community Ecology, Physiological Parameters, Laterality, %22">Fish , Anatomy, General Agricultural and Biological Sciences, Research Article, media_common.quotation_subject, 010603 evolutionary biology, Zooplankton, Asymmetry, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, stomatognathic system, Cichlid, Perissodus microlepis, Adults, Animals, Mouth, Behavior, lcsh:R, Ecology and Environmental Sciences, Biology and Life Sciences, biology.organism_classification, Gastrointestinal Tract, 030104 developmental biology, Jaw, Age Groups, Predatory Behavior, People and Places, lcsh:Q, Population Groupings, Digestive System, Zoology, Head
Abstract

The scale-eating cichlid Perissodus microlepis with asymmetric mouth is an attractive model of behavioral laterality: each adult tears off scales from prey fishes' left or right flanks according to the direction in which its mouth is skewed. To investigate the development of behavioral laterality and mouth asymmetry, we analyzed stomach contents and lower jaw-bone asymmetry of various-sized P. microlepis (22 ≤ SL

Published
2016

16. Coordinated Expression of Two Types of Low-Threshold K+Channels Establishes Unique Single Spiking of Mauthner Cells among Segmentally Homologous Neurons in the Zebrafish Hindbrain

Author

Yoichi Oda, Takaki Watanabe, and Takashi Shimazaki

Subjects
biology, General Neuroscience, Xenopus, Hindbrain, Biological neuron model, General Medicine, In situ hybridization, biology.organism_classification, Cell biology, Mauthner cell, nervous system, Neuroscience, Zebrafish, Ion channel, Microfold cell
Abstract

Expression of different ion channels permits homologously-generated neurons to acquire different types of excitability and thus code various kinds of input information. Mauthner (M) series neurons in the teleost hindbrain consist of M cells and their morphological homologs, which are repeated in adjacent segments and share auditory inputs. When excited, M cells generate a single spike at the onset of abrupt stimuli, while their homologs encode input intensity with firing frequency. Our previous study in zebrafish showed that immature M cells burst phasically at 2 d postfertilization (dpf) and acquire single spiking at 4 dpf by specific expression of auxiliary Kvβ2 subunits in M cells in association with common expression of Kv1.1 channels in the M series. Here, we further reveal the ionic mechanisms underlying this functional differentiation. Pharmacological blocking of Kv7/KCNQ in addition to Kv1 altered mature M cells to fire tonically, similar to the homologs. In contrast, blocking either channel alone caused M cells to burst phasically. M cells at 2 dpf fired tonically after blocking Kv7.In situhybridization revealed specific Kv7.4/KCNQ4 expression in M cells at 2 dpf. Kv7.4 and Kv1.1 channels expressed inXenopusoocytes exhibited low-threshold outward currents with slow and fast rise times, while coexpression of Kvβ2 accelerated and increased Kv1.1 currents, respectively. Computational models, modified from a mouse cochlear neuron model, demonstrated that Kv7.4 channels suppress repetitive firing to produce spike-frequency adaptation, while Kvβ2-associated Kv1.1 channels increase firing threshold and decrease the onset latency of spiking. Altogether, coordinated expression of these low-threshold K+channels with Kvβ2 functionally differentiates M cells among homologous neurons.

Published
2017
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17. The role of ear stone size in hair cell acoustic sensory transduction

Author

Masashi Tanimoto, Yoichi Oda, and Maya Inoue

Subjects
Vestibular system, Multidisciplinary, Hindbrain, Anatomy, Biology, Article, body regions, medicine.anatomical_structure, Hearing, Ear, Inner, Utricle, Hair Cells, Auditory, otorhinolaryngologic diseases, medicine, Animals, Inner ear, sense organs, Saccule, Hair cell, Saccule and Utricle, Auditory Physiology, Zebrafish, Otolith
Abstract

Hearing and bodily balance are different sensations initiated by a common mechanism. Both sound- and head movement-dependent mechanical displacement are converted into electrical signals by the sensory hair cells. The saccule and utricle inner ear organs, in combination with their central projections to the hindbrain, are considered essential in fish for separating auditory and vestibular stimuli. Here, we established an in vivo method in larval zebrafish to manipulate otolith growth. We found that the saccule containing a large otolith is necessary to detect sound, whereas the utricle containing a small otolith is not sufficient. Otolith removal and relocation altered otolith growth such that utricles with experimentally enlarged otoliths acquired the sense of sound. These results show that otolith biomineralization occurs in a region-specific manner and suggest that regulation of otolith size in the larval zebrafish ear is crucial to differentially sense auditory and vestibular information.

Published
2013
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18. Effective sensory modality activating an escape triggering neuron switches during early development in zebrafish

Author

Yoichi Oda, Tsunehiko Kohashi, and Natsuyo Nakata

Subjects
animal structures, Time Factors, Green Fluorescent Proteins, LIM-Homeodomain Proteins, Action Potentials, Hindbrain, Sensory system, Biology, Statistics, Nonparametric, Animals, Genetically Modified, Trigeminal ganglion, Stimulus modality, Escape Reaction, Physical Stimulation, medicine, Reaction Time, Animals, Trigeminal Nerve, Organic Chemicals, Zebrafish, Vestibular system, Neurons, Afferent Pathways, Behavior, Animal, General Neuroscience, Age Factors, Articles, biology.organism_classification, medicine.anatomical_structure, ELAV Proteins, Trigeminal Ganglion, Larva, embryonic structures, Neuron, Otic vesicle, Laser Therapy, Vestibule, Labyrinth, Neuroscience, Head, Transcription Factors
Abstract

Developing nervous systems grow to integrate sensory signals from different modalities and to respond through various behaviors. Here, we examined the development of escape behavior in zebrafish [45–170 h postfertilization (hpf)] to study how developing sensory inputs are integrated into sensorimotor circuits. Mature fish exhibit fast escape upon both auditory/vestibular (AV) and head-tactile stimuli. Newly hatched larvae, however, do not respond to AV stimuli before 75 hpf. Because AV-induced fast escape in mature fish is triggered by a pair of hindbrain neurons known as Mauthner (M) cells, we studied functional development of the M-cell circuit accounting for late acquisition of AV-induced escape. In fast escape elicited by head-directed water jet, minimum onset latency decreased throughout development (5 ms at 45–59 hpf, 3 ms after 75 hpf). After 75 hpf, lesioning the otic vesicle (OV) to eliminate AV input resulted in loss of short-latency (2+imaging of the M-cell during escape demonstrated that M-cell firing is required to initiate short-latency fast escapes at every developmental stage and further suggest that head-tactile input activates the M-cell before 75 hpf, but that after this point AV input activates the M-cell instead. Thus, a switch in the effective sensory input to the M-cells mediates the acquisition of a novel modality for initiating fast escape.

Published
2012

19. Lateralized kinematics of predation behavior in a Lake Tanganyika scale-eating cichlid fish

Author

Michio Hori, Yoichi Oda, and Yuichi Takeuchi

Subjects
Reflex, Startle, Anatomy and Physiology, Animal Types, Zoology, lcsh:Medicine, Veterinary Anatomy and Physiology, Escape response, Tanzania, Neurological System, Functional Laterality, Predation, Escape Reaction, Cichlid, Perissodus microlepis, Agonistic behaviour, Animals, lcsh:Science, Biology, Animal Management, Mouth, Multidisciplinary, Ecology, biology, lcsh:R, Cichlids, Feeding Behavior, Anatomy, biology.organism_classification, Startle reaction, Biomechanical Phenomena, Lakes, Acoustic Stimulation, Predatory Behavior, Laterality, Forage fish, Veterinary Science, lcsh:Q, Agonistic Behavior, Research Article, Neuroscience
Abstract

Behavioral lateralization has been documented in many vertebrates. The scale-eating cichlid fish Perissodus microlepis is well known for exhibiting lateral dimorphism in its mouth morphology and lateralized behavior in robbing scales from prey fish. A previous field study indicated that this mouth asymmetry closely correlates with the side on which prey is attacked, but details of this species' predation behavior have not been previously analyzed because of the rapidity of the movements. Here, we studied scale-eating behavior in cichlids in a tank through high-speed video monitoring and quantitative assessment of behavioral laterality and kinematics. The fish observed showed a clear bias toward striking on one side, which closely correlated with their asymmetric mouth morphologies. Furthermore, the maximum angular velocity and amplitude of body flexion were significantly larger during attacks on the preferred side compared to those on the nonpreferred side, permitting increased predation success. In contrast, no such lateral difference in movement elements was observed in acoustically evoked flexion during the escape response, which is similar to flexion during scale eating and suggests that they share a common motor control pathway. Thus the neuronal circuits controlling body flexion during scale eating may be functionally lateralized upstream of this common motor pathway.

Published
2012

20. A shift of the TOR adaptor from Rictor towards Raptor by semaphorin in C. elegans

Author

Shin Takagi, Akira Nukazuka, Kunihiro Matsumoto, Hajime Fujisawa, Yoichi Oda, and Shusaku Tamaki

Subjects
Male, animal structures, Torc, Blotting, Western, Mutant, Regulator, General Physics and Astronomy, Article, General Biochemistry, Genetics and Molecular Biology, Semaphorin, Animals, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Genetics, Messenger RNA, Multidisciplinary, biology, Plexin, Translation (biology), General Chemistry, biology.organism_classification, Mutation, embryonic structures, biology.protein, RNA Interference, Signal Transduction
Abstract

The target of rapamycin (TOR), a central regulator for cell growth and metabolism, resides in the two functionally distinct complexes TORC1 and TORC2, which are defined by their adaptors Raptor and Rictor, respectively. How the formation of the two TORCs is orchestrated remains unclear. Here we show the control of TOR partnering by semaphorin-plexin signalling in Caenorhabditis elegans. In semaphorin and plexin mutants, TOR-Raptor association decreases whereas TOR-Rictor association increases, concomitantly with TORC1 down- and TORC2 up-regulation. Epidermal defects in the mutants are suppressed by inhibiting TORC2 or reinforcing TORC1 signalling. Conversely, inhibition of TORC1 signalling phenocopies the mutants. Thus, our results indicate that TORC formation is a singularly important step in semaphorin signalling that culminates in diverse outcomes including TORC1-promoted messenger RNA translation and TORC2-regulated cytoskeletal remodelling., What controls the binding partner selection of the target of rapamycin protein, TOR, is unknown. Using the Caenorhabditis elegans tail as a model, Nukazuka et al. determine that signals of semaphorin through plexin control the binding partner selection of TOR and are required for the correct organization of rays in the tail.

Published
2011
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21. Semaphorin controls epidermal morphogenesis by stimulating mRNA translation via eIF2alpha in Caenorhabditis elegans

Author

Shin Takagi, Hajime Fujisawa, Akira Nukazuka, Yoichi Oda, and Toshifumi Inada

Subjects
Male, animal structures, Eukaryotic Initiation Factor-2, Morphogenesis, Down-Regulation, macromolecular substances, Semaphorins, Biology, eIF-2 Kinase, Semaphorin, Eukaryotic initiation factor, Genetics, Animals, Phosphorylation, Caenorhabditis elegans, Caenorhabditis elegans Proteins, 3' Untranslated Regions, eIF2, Microscopy, Confocal, Plexin, Microfilament Proteins, Translation (biology), biology.organism_classification, Molecular biology, Cell biology, nervous system, Actin Depolymerizing Factors, Protein Biosynthesis, embryonic structures, Perspective, biology.protein, Epidermis, Developmental Biology
Abstract

Conserved semaphorin–plexin signaling systems govern various aspects of animal development, including axonal guidance in vertebrates and epidermal morphogenesis in Caenorhabditis elegans. Here we provide in vivo evidence that stimulation of mRNA translation via eukaryotic initiation factor 2α (eIF2α) is an essential downstream event of semaphorin signaling in C. elegans. In semaphorin/plexin mutants, a marked elevation in the phosphorylation of eIF2α is observed, which causes translation repression and is causally related to the morphological epidermal phenotype in the mutants. Conversely, removal of constraints on translation by genetically reducing the eIF2α phosphorylation largely bypasses requirement for the semaphorin signal in epidermal morphogenesis. We also identify an actin-depolymerizing factor/cofilin, whose expression in the mutants is predominantly repressed, as a major translational target of semaphorin signaling. Thus, our results reveal a physiological significance for translation of mRNAs for cytoskeletal regulators, linking environmental cues to cytoskeletal rearrangement during cellular morphogenesis in vivo.

Published
2008

22. Common Sensory Inputs and Differential Excitability of Segmentally Homologous Reticulospinal Neurons in the Hindbrain

Author

Yoichi Oda and Hisako Nakayama

Subjects
Potassium Channels, Sensory system, Hindbrain, Stimulation, Behavioral/Systems/Cognitive, Biology, GABA Antagonists, Mauthner cell, Escape Reaction, Goldfish, medicine, Kv1.2 Potassium Channel, Animals, Evoked Potentials, Fluorescent Dyes, Elapid Venoms, Neurons, Afferent Pathways, Voltage-gated ion channel, General Neuroscience, Excitatory Postsynaptic Potentials, Depolarization, Glycine Agents, Bicuculline, Potassium channel, Electric Stimulation, Rhombencephalon, Acoustic Stimulation, Spinal Cord, Potassium Channels, Voltage-Gated, Neuroscience, medicine.drug
Abstract

In the hindbrain of zebrafish and goldfish, reticulospinal (RS) neurons are arranged in seven segments, with segmental homologs in adjacent segments. The Mauthner cell (M-cell) in the fourth segment (r4) is known to trigger fast escape behavior. Its serial homologs, MiD2cm in r5 and MiD3cm in r6, are predicted to contribute to this behavior, which can be evoked by head-tap stimuli. However, little is known about their input–output properties. Therefore, we studied afferent projections from the auditory posterior eighth nerve (pVIIIn) and firing properties of MiD2cm and MiD3cm for comparison with the M-cell in adult goldfish. Labeling of RS neurons and the pVIIIn afferents with fluorescent tracers showed that the pVIIIn projected to r4–r6. Tone burst and electrical stimulation of the pVIIIn evoked EPSPs in the M-cell, MiD2cm, and MiD3cm. Stepwise depolarization typically elicited a single spike at the onset in the M-cell but repetitive spiking in MiD2cm and MiD3cm. This atypical property of the M-cell was mediated by dendrotoxin-I (DTX-I)-sensitive voltage-gated potassium channels together with recurrent inhibition, because combined application of DTX-I, strychnine, and bicuculline led to continuous repetitive firing in M-cells. The M-cell but not MiD2cm or MiD3cm expressed Kv1.2, a DTX-I-sensitive potassium channel subunit. Thus, the M-cell and its segmental homologs may sense common auditory information but send different outputs to the spinal circuits to control adaptive escape behavior.

Published
2004

23. In vivo imaging of functional inhibitory networks on the mauthner cell of larval zebrafish

Author

Masaharu Takahashi, Madoka Narushima, and Yoichi Oda

Subjects
Patch-Clamp Techniques, Action Potentials, Neurotransmission, Biology, Inhibitory postsynaptic potential, Synaptic Transmission, Fluorescence, Membrane Potentials, Mauthner cell, Calcium imaging, Receptors, Glycine, medicine, Animals, Patch clamp, Axon, ARTICLE, Zebrafish, Fluorescent Dyes, Neurons, General Neuroscience, Reciprocal inhibition, Glycine Agents, Neural Inhibition, Calcium Channel Blockers, Electric Stimulation, Cell biology, Rhombencephalon, medicine.anatomical_structure, Spinal Cord, Larva, Calcium, Calcium Channels, Nerve Net, Orthodromic, Neuroscience
Abstract

Noninvasivein vivocalcium imaging was used to observe and characterize inhibitory circuitry in intact larval zebrafish. In the teleost hindbrain, the inhibitory network onto the major pair of reticulospinal neurons known as Mauthner cells (M-cells) has been described in detail. There are three sources of inhibition onto M-cells: recurrent inhibition mediated by an ipsilateral collateral of the M-cell axon, feedforward inhibition driven by sensory afferents, and reciprocal inhibition between bilaterally opposed M-cells. To visualize these inhibitions, M-cells were retrogradely loaded with the calcium indicator calcium green dextran. Recurrent inhibition attenuated the Ca2+response associated with an action potential in M-cells. Whole-cell recording revealed recurrent IPSCs, the conductance of which may underlie the shunting effect on action potentials and the attenuation of the Ca2+signal in M-cells. Blocking synaptic transmission within the recurrent network abolished both the Ca2+signal attenuation and the IPSCs. Electrical stimulation of the otic vesicle to activate VIII nerve afferents resulted in feedforward suppression of antidromically evoked test Ca2+responses in the contralateral M-cell. Orthodromic activation of M-cells produced a reciprocal reduction of the test Ca2+response in the contralateral M-cell. Thus, in the present study, we visualized the three types of inhibition and demonstrated that they are functional at 4 d after fertilization. The use of noninvasive techniques to image inhibitionin vivosuggest the plausibility of studying the hypothesis previously tested in adult goldfish that use-dependent changes in inhibitions underlie sound conditioning in escape behavior.

Published
2002

30. Long-term potentiation of inhibitory circuits and synapses in the central nervous system

Author

Yoichi Oda, Henri Korn, and Donald S. Faber

Subjects
Central Nervous System, Time Factors, Glycine, Neural Inhibition, Biology, Inhibitory postsynaptic potential, Membrane Potentials, Synapse, Excitatory synapse, Mauthner cell, Chlorides, Interneurons, Goldfish, medicine, Animals, Glycine receptor, Multidisciplinary, Electric Conductivity, Long-term potentiation, Anatomy, medicine.anatomical_structure, Synapses, Neuron, Neuroscience, Research Article
Abstract

Glycinergic inhibition evoked disynaptically in the teleost Mauthner cell by stimulation of the contralateral eighth nerve exhibits long-term potentiation following classical tetanization of that pathway. This enhancement occurs at the synapses between primary afferents onto second-order interneurons and the connections between these inhibitory cells and the Mauthner neuron. The evidence for modifications of glycinergic transmission is that the slope of the relation between the presynaptic volley and the synaptic conductance can be greater after the tetanus. This increase in gain is still manifest after pharmacological block of potentiation at the excitatory synapse with glutamate antagonists. Inhibitory long-term potentiation is induced by tetani weaker than those required for enhancement of the monosynaptic excitation of the other (ipsilateral) Mauthner cell. Thus, in vivo learning can alter the balance between excitation and inhibition within a network by modifying one or both of them.

Published
1992

32. Functional role of a specialized class of spinal commissural inhibitory neurons during fast escapes in zebrafish

Author

Shin-ichi Higashijima, Kazuki Horikawa, Hiroyuki Takeda, Tsunehiko Kohashi, Chie Satou, Yukiko Kimura, and Yoichi Oda

Subjects
Functional role, Patch-Clamp Techniques, Green Fluorescent Proteins, Biotin, Biology, Inhibitory postsynaptic potential, Membrane Potentials, Green fluorescent protein, Animals, Genetically Modified, Escape Reaction, Interneurons, Neural Pathways, Animals, Gene silencing, Zebrafish, Swimming, Behavior, Animal, Rhodamines, General Neuroscience, Gap Junctions, Dextrans, Neural Inhibition, Articles, General Medicine, Commissure, biology.organism_classification, Electric Stimulation, digestive system diseases, Electrophysiology, Inhibitory Postsynaptic Potentials, Spinal Cord, Larva, Calcium, Laser Therapy, Brainstem, Neuroscience
Abstract

In teleost fish, the Mauthner (M) cell, a large reticulospinal neuron in the brainstem, triggers escape behavior. Spinal commissural inhibitory interneurons that are electrotonically excited by the M-axon have been identified, but the behavioral roles of these neurons have not yet been addressed. Here, we studied these neurons, named CoLo (commissural local), in larval zebrafish using an enhancer-trap line in which the entire population of CoLos was visualized by green fluorescent protein. CoLos were present at one cell per hemi-segment. Electrophysiological recordings showed that an M-spike evoked a spike in CoLos via electrotonic transmission and that CoLos made monosynaptic inhibitory connections onto contralateral primary motoneurons, consistent with the results in adult goldfish. We further showed that CoLos were active only during escapes. We examined the behavioral roles of CoLos by investigating escape behaviors in CoLo-ablated larvae. The results showed that the escape behaviors evoked by sound/vibration stimuli were often impaired with a reduced initial bend of the body, indicating that CoLos play important roles in initiating escapes. We obtained several lines of evidence that strongly suggested that the impaired escapes occurred during bilateral activation of the M-cells: in normal larvae, CoLo-mediated inhibitory circuits enable animals to perform escapes even in these occasions by silencing the output of the slightly delayed firing of the second M-cell. This study illustrates (1) a clear example of the behavioral role of a specialized class of interneurons and (2) the capacity of the spinal circuits to filter descending commands and thereby produce the appropriate behavior.

Published
2009
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43. Sprouting as a Basis for Classical Conditioning in the Cat

Author

Nakaakira Tsukahara, Yoichi Oda, and Fujio Murakami

Subjects
Behavioral plasticity, Period (gene), Classical conditioning, Long-term potentiation, Neurotransmission, Biology, Plasticity, Neuroscience, Sprouting
Abstract

Plasticity of synaptic transmission is thought to underlie behavioral plasticity in invertebrates. In mammals, circumstantial evidence has been accumulating to suggest that long-term potentiation of synaptic transmission contributes to behavioral plasticity (e.g., Morris et al., 1986). Although long-term potentiation lasts for many days, some other mechanisms should be considered to explain behavioral modification that is retained for a much longer period.

Published
1988
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44. Simple and complex spike activities of Purkinje cells during locomotion in the cerebellar vermal zones of decerebrate cats

Author

H. Kamei, Masao Udo, Yoichi Oda, K. Minoda, and K. Matsukawa

Subjects
animal structures, Hindlimb, Biology, Inhibitory postsynaptic potential, Cerebellar Cortex, Purkinje Cells, Nerve Fibers, Forelimb, medicine, Animals, Evoked Potentials, Ulnar Nerve, General Neuroscience, Vestibular Nucleus, Lateral, Anatomy, Spinal cord, Sciatic Nerve, Axons, Electric Stimulation, Antidromic, medicine.anatomical_structure, Spinal Cord, Receptive field, Cerebellar vermis, Cats, Radial Nerve, Sciatic nerve, Neuroscience, Locomotion
Abstract

In walking cats decerebrated at the premammillary level, single neurone activity of Purkinje cells (P-cells) with long corticofugal axons was recorded in the cerebellar vermis. The P-cells (N = 145) were identified as they showed spontaneous simple and complex spikes and also antidromic activation from Deiters' nucleus. These P-cells were classified into 6 groups according to the receptive fields of the climbing fibre responses (CFRs) which were evoked by electrical stimulation in each limb at the radial and sciatic nerve bundles. One group designated as forelimb units received the CFRs from both forelimbs and from neither hindlimb. According to previous studies, this group of P-cells is thought to make inhibitory connections with Deiters neurones projecting to the ipsilateral cervicothoracic spinal cord. For the forelimb units, two types of discharge patterns for simple spikes were found in relation to limb movements during locomotion. Type I cells showed one peak in their firing rate in the late swing (E1) or early stance (E2) phase of the ipsilateral forelimb. Type II cells showed two peaks and two valleys during one step cycle: one peak was in the E1 phase, the other in the late stance (E3) or early swing (F) phase; each of the two valleys followed the peak. Complex spikes of the forelimb units occurred more frequently in the E1 phase than during the other phases. The increased activity of simple and complex spikes of the forelimb units in the E1 phase is suggested to have a functional significance in preparing the appropriate floor reaction forces that appear upon touchdown of the ipsilateral forelimb.

Published
1981

45. Cerebellar Control of Locomotion Investigated in Cats: Discharges from Deiters' Neurones, EMG and Limb Movements during Local Cooling of the Cerebellar Cortex

Author

J. Horikawa, K. Tanaka, M. Udo, and Yoichi Oda

Subjects
animal structures, CATS, nervous system, Stance phase, Quadrupedalism, Cerebellar cortex, Stimulation, Hindlimb, Anatomy, Biology, Neuroscience, Neuronal circuitry
Abstract

Publisher Summary This chapter investigates the neuronal mechanisms of the cerebellar control of locomotion, using a stepping preparation where the 4 limbs of cats are decerebrated at the thalamic level. Any electrical stimulation to induce locomotion is avoided as it might give artificial signals to the neuronal circuitry concerning coordinative control of stepping. In the stepping preparations, the activity of Deiters' neurones projecting to the ipsilateral lumbosacral cord (L-Deiters' neurones), the EMGs of hindlimb muscles, and limb movements are analyzed before, during, and after local cooling of the cerebellar cortex. During each cycle of quadrupedal stepping, most L-Deiters' neuroncs show two peaks of impulse discharges—the first (A peak) in the stance phase and the second (B peak) in the swing phase of the ipsilateral hindlimb. The A peak often starts rising shortly before the ipsilateral hindlimb is placed. When movements of either hind- or forelimbs are stopped, this frequency modulation in Deiters' neurones is greatly depressed. It is indicated that coordinated movements of fore- and hindlimbs are essential in building up the frequency modulation in L-Deiters' neurones.

Published
1976
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46. Formation of functional synapses in the adult cat red nucleus from the cerebrum following cross-innervation of forelimb flexor and extensor nerves

Author

Jun Maeda, Yoichi Oda, Nakaakira Tsukahara, and Y. Fujito

Subjects
Red nucleus, Population, Biology, Forelimb, medicine, Animals, education, Evoked Potentials, Red Nucleus, education.field_of_study, CATS, Cerebrum, General Neuroscience, Cerebral peduncle, Brain, Anatomy, Membrane hyperpolarization, Axons, Electric Stimulation, Antidromic, Spinal Nerves, medicine.anatomical_structure, Spinal Cord, Nerve Degeneration, Synapses, Cats
Abstract

We investigated the effects of cross-innervating the peripheral forelimb flexor and extensor nerves of adult cats on the time course of corticorubral EPSPs. Red nucleus neurons were identified by antidromic invasion from C1 or L1 spinal segments as innervating the upper spinal segments (C-cells) or sending axons to the lumbosacral cord (L-cells). In C-cells, a fast-rising component, superimposed on the slow-rising corticorubral EPSPs induced by the cerebral sensorimotor cortex or the cerebral peduncle (CP) stimulation, was noted. The mean time-to-peak of this component in cross-innervated cats operated more than two months earlier was 1.9 +/- 0.9 ms (n = 160), shorter than in normal cats (3.6 +/- 1.4 ms, n = 100). The same value in cats cross-innervated less than two months before was 2.7 +/- 1.0 ms (n = 53). The mean time-to-peak of CP-EPSPs from L-cells was 2.9 +/- 0.9 ms (n = 115). The fast-rising component had a latency of 0.96 +/- 0.19 ms (n = 122), and it was mediated by fibers with conduction velocities of less than 20 m/s. The projective area of the fast-rising component is organized somatotopically. Since it is more sensitive to membrane hyperpolarization than slow rising corticorubral EPSPs, it is mediated by synapses located more proximally than the corticorubral synapses of normal cats. The time course of facilitation by preceding cerebral peduncle stimulation of the nucleus interpositus (IP)-induced RN population responses was measured. It was characterized by a rapid, followed by a slower, rise time in the RN region where C-cells are concentrated. In contrast, the L-cell region was characterized by a slow rise time. In cats subjected to self-union of the peripheral flexor and extensor nerves, the majority of C-cells had CP-EPSPs with a time-to-peak within the normal range. Our results suggest that after cross-innervation sprouting and formation of functional synapses occur on the proximal portion of the soma-dendritic membrane of red nucleus neurons.

Published
1982
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47. Synaptic currents at interpositorubral and corticorubral excitatory synapses measured by a new iterative single-electrode voltage-clamp method

Author

Mitsuo Kawato, Fujio Murakami, Yoichi Oda, Manabu Etoh, and Nakaakira Tsukahara

Subjects
Synaptic potential, Cerebral Cortex, General Neuroscience, Voltage clamp, Neural facilitation, Neural Conduction, Neural Inhibition, General Medicine, Biology, Neurotransmission, Synaptic Transmission, Membrane Potentials, Electrophysiology, Cerebellar Nuclei, Synaptic augmentation, Synaptic plasticity, Neural Pathways, Synapses, Excitatory postsynaptic potential, Cats, Animals, Neuroscience, Red Nucleus
Abstract

A new iterative single-electrode voltage clamp method was applied to the measurement of synaptic currents in the red nucleus (RN) neuron of the cat. Voltage clamp was attained within 10 repetitions with great stability and the new algorithm was demonstrated to be superior to the original algorithm of iterative voltage clamp. With a conventional microelectrode, it was possible to measure the synaptic current with the time resolution of 50 microseconds. The synaptic currents evoked by stimulation of the contralateral interpositus nucleus (IP) had time-to-peak ranging from 200 to 540 microseconds and fitted well to alpha functions. Corticorubral (CR) synaptic current was also measured by making use of synaptic plasticity. The stimulation of the ipsilateral cerebral peduncle in cats with chronic lesion of the contralateral IP evoked fast rising EPSPs, as reported previously. The CR-EPSPs with times-to-peak less than 1 ms were subjected to voltage clamp. The CR synaptic currents had times-to-peak ranging from 350 to 880 microseconds. Since most of the interpositorubral (IR) synapses and a part of the CR synapses in IP-lesioned cats are situated on the somatic membrane of RN neurons and some of the CR synaptic currents were as rapid as the IR synaptic currents, the observed synaptic currents evoked by stimulation of the IP and those of the fast-rising CR-EPSPs were taken to originate from the synaptic membrane under space-clamp, i.e. soma. The present study provided additional evidence for the sprouting of the CR fibers as well as the time course of the synaptic current at the dendritic synapses remote from the soma, for the first time.

Published
1986

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