Your search keyword '"mauthner cell"' showing total 511 results

1. A computational model of the shrimp-goby escape and communication system

Author

G. Bard Ermentrout, Klaus M. Stiefel, and Joseph A. Landsittel

Subjects

0301 basic medicine, Computational model, biology, Cognitive Neuroscience, Goby, Central pattern generator, Zoology, biology.organism_classification, Communications system, Sensory Systems, Shrimp, 03 medical and health sciences, Cellular and Molecular Neuroscience, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, Predatory fish, Zebrafish, 030217 neurology & neurosurgery

Abstract

Fish escape from approaching threats via a stereotyped escape behavior. This behavior, and the underlying neural circuit organized around the Mauthner cell command neurons, have both been extensively investigated experimentally, mainly in two laboratory model organisms, the goldfish and the zebrafish. However, fish biodiversity is enormous, a number of variants of the basal escape behavior exist. In marine gobies (a family of small benthic fishes) which share burrows with alpheid shrimp, the escape behavior has likely been partially modified into a tactile communication system which allow the fish to communicate the approach of a predatory fish to the shrimp. In this communication system, the goby responds to intermediate-strength threats with a brief tail-flick which the shrimp senses with its antennae.We investigated the shrimp goby escape and communication system with computational models. We asked how the circuitry of the basal escape behavior could be modified to produce behavior akin to the shrimp-goby communication system. In a simple model, we found that mutual inhibitions between Mauthner cells can be tuned to produce an oscillatory response to intermediate strength inputs, albeit only in a narrow parameter range.Using a more detailed model, we found that two modifications of the fish locomotor system transform it into a model reproducing the shrimp goby behavior. These modifications are: 1. modifying the central pattern generator which drives swimming such that it is quiescent when receiving no inputs; 2. introducing a direct sensory input to this central pattern generator, bypassing the Mauthner cells.

Published

2021

2. Evolutionary and homeostatic changes in morphology of visual dendrites of Mauthner cells in<scp>Astyanax</scp>blind cavefish

Author

Daihana Rivera, Daphne Soares, Gal Haspel, Zainab Tanvir, and Kristen E. Severi

Subjects

0301 basic medicine, genetic structures, Neurogenesis, Cavefish, Hindbrain, Dendrite, Sensory system, Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, medicine, Animals, Homeostasis, Natural selection, Characidae, General Neuroscience, Dendrites, Darkness, Adaptation, Physiological, Biological Evolution, 030104 developmental biology, medicine.anatomical_structure, Eye development, Neuron, Adaptation, Neuroscience, 030217 neurology & neurosurgery

Abstract

Mauthner cells are the largest neurons in the hindbrain of teleost fish and most amphibians. Each cell has two major dendrites thought to receive segregated streams of sensory input: the lateral dendrite receives mechanosensory input while the ventral dendrite receives visual input. These inputs, which mediate escape responses to sudden stimuli, may be modulated by the availability of sensory information to the animal. To understand the impact of the absence of visual information on the morphologies of Mauthner cells during development and evolutionary time scales, we examined Astyanax mexicanus. This species of tetra is found in two morphs: a seeing surface fish and a blind cavefish. We compared the structure of Mauthner cells in surface fish raised under daily light conditions, surface fish that raised in constant darkness, and two independent lineages of cave populations. The length of ventral dendrites of Mauthner cells in dark-raised surface larvae were longer and more branched, while in both cave morphs the ventral dendrites were smaller or absent. The absence of visual input in surface fish with normal eye development leads to a homeostatic increase in dendrite size, whereas over evolution, the absence of light led to the loss of eyes and a phylogenetic reduction in dendrite size. Consequently, homeostatic mechanisms are under natural selection that provide adaptation to constant darkness.

Published

2020

3. Effector gene expression underlying neuron subtype-specific traits in the Motor Ganglion of Ciona

Author

Christopher J. Johnson, Sarthak Sharma, Elijah K. Lowe, Paula Martinez-Feduchi, Jameson Orvis, Alberto Stolfi, Kwantae Kim, and Susanne Gibboney

Subjects

Central Nervous System, Embryo, Nonmammalian, Interneuron, Neurogenesis, Gene regulatory network, Nerve Tissue Proteins, Hindbrain, Chordate, Microtubules, Article, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Interneurons, Connectome, medicine, Animals, Molecular Biology, 030304 developmental biology, Centrosome, Gene Editing, Motor Neurons, Neurons, 0303 health sciences, biology, Calcium-Binding Proteins, Gene Expression Regulation, Developmental, Cell Biology, Netrin-1, Cell sorting, biology.organism_classification, Axon Guidance, Ciona intestinalis, Ganglia, Invertebrate, Cell biology, Repressor Proteins, Ciona, medicine.anatomical_structure, Larva, Neuron, CRISPR-Cas Systems, Transcriptome, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The central nervous system of the Ciona larva contains only 177 neurons. The precise regulation of neuron subtype-specific morphogenesis and differentiation observed during the formation of this minimal connectome offers a unique opportunity to dissect gene regulatory networks underlying chordate neurodevelopment. Here we compare the transcriptomes of two very distinct neuron types in the hindbrain/spinal cord homolog of Ciona, the Motor Ganglion (MG): the Descending decussating neuron (ddN, proposed homolog of Mauthner Cells in vertebrates) and the MG Interneuron 2 (MGIN2). Both types are invariantly represented by a single bilaterally symmetric left/right pair of cells in every larva. Supernumerary ddNs and MGIN2s were generated in synchronized embryos and isolated by fluorescence-activated cell sorting for transcriptome profiling. Differential gene expression analysis revealed ddN- and MGIN2-specific enrichment of a wide range of genes, including many encoding potential “effectors” of subtype-specific morphological and functional traits. More specifically, we identified the upregulation of centrosome-associated, microtubule-stabilizing/bundling proteins and extracellular guidance cues part of a single intrinsic regulatory program that might underlie the unique polarization of the ddNs, the only descending MG neurons that cross the midline. Consistent with our predictions, CRISPR/Cas9-mediated, tissue-specific elimination of two such candidate effectors, Efcab6-related and Netrin1, impaired ddN polarized axon outgrowth across the midline.

Published

2020

4. Audiovisual integration in the Mauthner cell enhances escape probability and reduces response latency

Author

Nicolas Martorell and Violeta Medan

Subjects

Male, Empirical data, Computer science, Science, Decision, Sensory system, Neural circuits, Article, Behavioural methods, Mauthner cell, Sensorimotor processing, Escape Reaction, Motor control, Goldfish, Reaction Time, Animals, Latency (engineering), Neurons, Network models, Multidisciplinary, Mechanism (biology), Multisensory integration, Rhombencephalon, Behavioral data, Acoustic Stimulation, Motion detection, Computational neuroscience, Auditory Perception, Visual Perception, Medicine, Perceptual ambiguity, Female, Sensory processing, Cues, Visual system, Neuroscience

Abstract

Fast and accurate threat detection is critical for animal survival. Reducing perceptual ambiguity by integrating multiple sources of sensory information can enhance perception and reduce response latency. However, studies addressing the link between behavioral correlates of multisensory integration and its underlying neural basis are rare. Fish that detect an urgent threat escape with an explosive behavior known as C-start. The C-start is driven by an identified neural circuit centered on the Mauthner cell, an identified neuron capable of triggering escapes in response to visual and auditory stimuli. Here we demonstrate that goldfish can integrate visual looms and brief auditory stimuli to increase C-start probability. This multisensory enhancement is inversely correlated to the salience of the stimuli, with weaker auditory cues producing a proportionally stronger multisensory effect. We also show that multisensory stimuli reduced C-start response latency, with most escapes locked to the presentation of the auditory cue. We make a direct link between behavioral data and its underlying neural mechanism by reproducing the behavioral data with an integrate-and-fire computational model of the Mauthner cell. This model of the Mauthner cell circuit suggests that excitatory inputs integrated at the soma are key elements in multisensory decision making during fast C-start escapes. This provides a simple but powerful mechanism to enhance threat detection and survival.

Published

2022

5. Escaping from multiple visual threats: modulation of escape responses in Pacific staghorn sculpin (Leptocottus armatus)

Author

Kimura, Hibiki, Pfalzgraff, Tilo, Levet, Marie, Kawabata, Yuuki, Steffensen, John F., Johansen, Jacob L., Domenici, and Paolo

Subjects

Visual stimuli, GOLDFISH, Turning angle, Physiology, Leptocottus, BEHAVIORAL ECOLOGY, C-start, PREY, Escape Reaction/physiology, Predation, Escape response, Stimulation, Aquatic Science, Escape latency, Stimulus (physiology), Biology, RESPONSIVENESS, Looming stimuli, FISH, Escape Reaction, Animals, Fast start, PREDATORS, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Fish escape response, MODEL SELECTION, Perciformes/physiology, Fishes, PERFORMANCE, biology.organism_classification, Perciformes, MAUTHNER CELL, Insect Science, Double stimulation, Predatory Behavior, Escape trajectory, STIMULUS, Animal Science and Zoology, Pacific staghorn sculpin, Sensory feedback, Neuroscience

Abstract

Fish perform rapid escape responses to avoid sudden predatory attacks. During escape responses, fish bend their bodies into a C-shape and quickly turn away from the predator and accelerate. The escape trajectory is determined by the initial turn (stage 1) and a contralateral bend (stage 2). Previous studies have used a single threat or model predator as a stimulus. In nature, however, multiple predators may attack from different directions simultaneously or in close succession. It is unknown whether fish are able to change the course of their escape response when startled by multiple stimuli at various time intervals. Pacific staghorn sculpin (Leptocottus armatus) were startled with a left and right visual stimulus in close succession. By varying the timing of the second stimulus, we were able to determine when and how a second stimulus could affect the escape response direction. Four treatments were used: a single visual stimulus (control); or two stimuli coming from opposite sides separated by a 0 ms (simultaneous treatment), 33 ms or 83 ms time interval. The 33 ms and 83 ms time intervals were chosen to occur either side of a predicted 60 ms visual escape latency (i.e. during stage 1). The 0 ms and 33 ms treatments influenced both the escape trajectory and the stage 1 turning angle, compared with a single stimulation, whereas the 83 ms treatment had no effect on the escape trajectory. We conclude that Pacific staghorn sculpin can modulate their escape trajectory only between stimulation and the onset of the response, but the escape trajectory cannot be modulated after the body motion has started., Journal of Experimental Biology, 225(9), art. no. jeb243328; 2022

Published

2021

6. Hypoxia Has a Lasting Effect on Fast-Startle Behavior of the Tropical FishHaemulon plumieri

Author

Steven J. Zottoli, Loretta M. Roberson, and Mayra A Sanchez-Garcia

Subjects

geography, Haemulon, geography.geographical_feature_category, biology, Zoology, Hypoxia (environmental), Estuary, Aquatic animal, biology.organism_classification, Predation, Mauthner cell, Tropical climate, General Agricultural and Biological Sciences, Bay

Abstract

Anthropogenic activities and climate change have resulted in an increase of hypoxic conditions in nearshore ecosystems worldwide. Depending on the persistence of a hypoxic event, the survival of aquatic animals can be compromised. Temperate fish exposed to hypoxia display a reduction in the probability of eliciting startle responses thought to be important for escape from predation. Here we examine the effect of hypoxia on the probability of eliciting fast-startle responses (fast-starts) of a tropical fish, the white grunt (Haemulon plumieri), and whether hypoxia has a prolonged impact on behavior once the fish are returned to normoxic conditions. White grunts collected from the San Juan Bay Estuary in Puerto Rico were exposed to an oxygen concentration of 2.5 mg L-1 (40% dissolved oxygen). We found a significant reduction in auditory-evoked fast-starts that lasted for at least 24 hours after fish were returned to normoxic conditions. Accessibility to the neuronal networks that underlie startle responses was an important motivator for this study. Mauthner cells are identifiable neurons found in most fish and amphibians, and these cells are known to initiate fast-starts in teleost fishes. The assumption that most of the short-latency responses in this study are Mauthner cell initiated provided the impetus to characterize the white grunt Mauthner cell. The identification of the cell provides a first step in understanding how low oxygen levels may impact a single cell and its circuit and the behavior it initiates.

Published

2019

7. Compensatory Changes in Mauthner Neurons in Goldfish Induced by Sensory Stimulation and Application of β-Amyloid

Author

I. B. Mikheyeva, G. Z. Mikhailova, Ye. N. Bezgina, N. R. Tiras, and N. A. Pen’kova

Subjects

0301 basic medicine, Sensory stimulation therapy, Chemistry, General Neuroscience, Dystrophy, Dendrite, law.invention, Synapse, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, medicine.anatomical_structure, nervous system, law, Ultrastructure, medicine, Neuron, Electron microscope, Neuroscience, 030217 neurology & neurosurgery

Abstract

Objectives. To study the structure and formation of Mauthner neuron dendrites in goldfish exposed to neurotoxic β-amyloid fragment 25–35 and prolonged sensory stimulation influencing the afferent inputs to these neurons. Materials and methods. Goldfish Mauthner neurons were studied by light and electron microscopy. Individual dendrites were identified, their volumes were determined, and synapse structure was assessed using virtual 3D images of Mauthner neurons obtained from serial sections of thickness 3 μm. The functional status of Mauthner neurons was evaluated indirectly from the motor lateralization of the fish. Results. Mauthner neurons responded to application of β-amyloid combined with subsequent prolonged sensory stimulation with decreases in the volume of the ventral dendrites, damage to their ultrastructure, and degeneration of a proportion of synapses. Degeneration of more active neurons was more significant than that of less active cells. Newly formed medial dendrites had greater volume and less damaged synapse ultrastructure than ventral dendrites. There were no differences in the sizes of specialized junctions between synapses of the same type on ventral and medial synapses. Conclusions. Medial dendrite formation is a compensatory reaction to dystrophy of the ventral dendrite due to the experimental treatment.

Published

2019

8. In vivo imaging of evoked calcium responses indicates the intrinsic axonal regenerative capacity of zebrafish

Author

Da-long Ren, Min Chen, Lei-qing Yang, Rongchen Huang, and Bing Hu

Subjects

0301 basic medicine, biology, Inward-rectifier potassium ion channel, Regeneration (biology), medicine.medical_treatment, chemistry.chemical_element, Calcium, biology.organism_classification, Biochemistry, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, nervous system, chemistry, In vivo, Genetics, medicine, Premovement neuronal activity, Axotomy, Molecular Biology, Zebrafish, 030217 neurology & neurosurgery, Biotechnology

Abstract

Calcium is an important messenger in the neuronal system, but its specific role in axonal regeneration has not been fully investigated. To clarify it, we constructed a noninvasive in vivo calcium-imaging model of zebrafish Mauthner cells and monitored subcellular calcium dynamics during axonal regeneration. Using the calcium indicator GCamp6f, we observed that the regenerative length correlated with the peak amplitude of the evoked calcium response before axotomy, which suggested that the evoked calcium response might serve as a useful indicator of evoked neuronal activity and axonal regenerative capacity. To investigate this possibility, we overexpressed an inward rectifying potassium channel protein, Kir2.1a, to decrease the Mauthner neuronal activity and found that the inhibition of the calcium response correlated with decreased axonal regeneration. In contrast, treatment of pentylenetetrazol and knockout of the sodium voltage-gated channel α subunit 1 gene increased the calcium response and thus enhanced axonal regeneration. Our results therefore increased the understanding of the correlation between the neural activity and the vertebrate axonal regeneration.-Chen, M., Huang, R.-C., Yang, L.-Q., Ren, D.-L., Hu, B. In vivo imaging of evoked calcium responses indicates the intrinsic axonal regenerative capacity of zebrafish.

Published

2019

9. Neuroplasticity in the acoustic startle reflex in larval zebrafish

Author

Hernán López-Schier

Subjects

0301 basic medicine, Reflex, Startle, Sensory system, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Neuroplasticity, medicine, Animals, Learning, Habituation, Zebrafish, Neuronal Plasticity, biology, General Neuroscience, medicine.disease, biology.organism_classification, 030104 developmental biology, Acoustic Stimulation, Larva, Acoustic Startle Reflex, Reflex, Autism, Neuroscience, 030217 neurology & neurosurgery

Abstract

Learning is essential for animal survival under changing environments. Even in its simplest form, learning involves interactions between a handful of neuronal circuits, hundreds of neurons and many thousand synapses. In this review I will focus on habituation - a form of non-associative learning during which organisms decrease their response to repetitions of identical sensory stimuli. I will discuss how recent studies of the acoustic startle reflex mediated by the Mauthner cell in the zebrafish larva are helping to understand the neuroplastic processes that underlie habituation. In addition to being a fascinating biological process, habituation is clinically relevant because it is affected in various neuropsychiatric disorders in humans, including autism, schizophrenia, Fragile-X and Tourette's syndromes.

Published

2019

10. The Role of Connexins in Gastrointestinal Diseases

Author

Jeremy Wong, Jeffery Ho, William K.K. Wu, Jasmine Chopra, Tong Liu, Gary Tse, Lorraine Lok Wing Chiang, and Sunny H. Wong

Subjects

chemistry.chemical_classification, 0303 health sciences, Gastrointestinal Diseases, Protein subunit, Gap junction, Gap Junctions, Connexin, Motility, Connexins, Connexon, Amino acid, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, chemistry, Structural Biology, Animals, Humans, Nucleotide, sense organs, Molecular Biology, 030217 neurology & neurosurgery, Signal Transduction, 030304 developmental biology

Abstract

Gap junctions are hexagonal arrays of protein molecules in the plasma membrane and were first described in Mauthner cell synapses of goldfish. They form pathways for coupling between cells, allowing passive, electrotonic spread of ions and also passage of larger molecules such as amino acids and nucleotides. They are expressed in both excitable and non-excitable tissues. Each gap junction is made of two connexons, which are hexameric proteins of the connexin subunit. In this review, the roles that connexins play in gastrointestinal motility, the mechanisms of altered connexin expression leading to inflammatory bowel disease, gastrointestinal infections, and gastrointestinal symptoms in autistic spectrum disorder are discussed in detail.

Published

2019

11. Changes in the Dendrite Morphology of Mauthner Neurons in Goldfish under the Conditions of Monocular Deprivation and Sensory Stimulation

Author

N. N. Kashirskaya, R. Sh. Shtanchaev, E. N. Bezgina, N. A. Pen’kova, G. Z. Mikhailova, and N. R. Tiras

Subjects

0301 basic medicine, Sensory stimulation therapy, 030102 biochemistry & molecular biology, Chemistry, Biophysics, Stimulation, Dendrite, Synaptic vesicle, 03 medical and health sciences, Monocular deprivation, 030104 developmental biology, Mauthner cell, medicine.anatomical_structure, nervous system, medicine, Soma, Neuron, Neuroscience

Abstract

—The effects of sensory stimulation on the model of paired Mauthner neurons of monocularly deprived goldfish have been studied by light- and electron microscopy. Three-dimensional reconstruction was performed using serial semi-thin sections in order to determine the volumes of soma and dendrites for the right and left Mauthner neurons. These data suggested that long-term stimulation of some fish caused a decrease in the volume of the lateral dendrites of neurons contralateral with respect to the side of the enucleated eye. As a result, the morphological homeostasis in the dendrites of Mauthner neurons, which was observed in the control fish, was disturbed after the effect of stimulation upon this group of fish. The main mechanism of this effect of stimulation, according to ultrastructural analysis, is the compaction of the cytoskeleton in the lateral dendrite of a neuron and a reduction in the number of synaptic vesicles in the region of afferent synapses. In contrast, stimulation of the remaining fish induced the resistance of the contralateral Mauthner neuron to prolonged stimulation, as well as the hypertrophy of its lateral and shortening of the ventral dendrites. These results suggest that the homeostasis of the dendrites of Mauthner neurons essentially depends on the state of the visual inputs, the load on which increased as a result of the doubled impact.

Published

2019

12. A neuronal circuit that generates the temporal motor sequence for the defensive response in zebrafish larvae

Author

Na N. Guan, Yunfeng Hua, Jianren Song, Chun-Xiao Huang, and Lulu Xu

Subjects

Nervous system, Neurons, Motor sequence, Hindbrain, Stimulation, Fascicle, Biology, General Biochemistry, Genetics and Molecular Biology, Rhombencephalon, medicine.anatomical_structure, Mauthner cell, Escape Reaction, Larva, Neural Pathways, medicine, Excitatory postsynaptic potential, Animals, General Agricultural and Biological Sciences, Neuroscience, Nucleus, Swimming, Zebrafish

Abstract

Animals use a precisely timed motor sequence to escape predators. This requires the nervous system to coordinate several motor behaviors and execute them in a temporal and smooth manner. We here describe a neuronal circuit that faithfully generates a defensive motor sequence in zebrafish larvae. The temporally specific defensive motor sequence consists of an initial escape and a subsequent swim behavior and can be initiated by unilateral stimulation of a single Mauthner cell (M-cell). The smooth transition from escape behavior to swim behavior is achieved by activating a neuronal chain circuit, which permits an M-cell to drive descending neurons in bilateral nucleus of medial longitudinal fascicle (nMLF) via activation of an intermediate excitatory circuit formed by interconnected hindbrain cranial relay neurons. The sequential activation of M-cells and neurons in bilateral nMLF via activation of hindbrain cranial relay neurons ensures the smooth execution of escape and swim behaviors in a timely manner. We propose an existence of a serial model that executes a temporal motor sequence involving three different brain regions that initiates the escape behavior and triggers a subsequent swim. This model has general implications regarding the neural control of complex motor sequences.

Published

2021

13. Spinal sensory neurons project onto hindbrain to stabilize posture and enhance locomotor speed

Author

Martin Carbo-Tano, Claire Wyart, Julian Roussel, Ming-Yue Wu, Kevin Fidelin, Feng Quan, François-Xavier Lejeune, and Olivier Mirat

Subjects

Synapse, medicine.anatomical_structure, Mauthner cell, nervous system, medicine, GABAergic, Sensory system, Hindbrain, Soma, Axon, Biology, Spinal cord, Neuroscience

Abstract

SUMMARYIn the spinal cord, cerebrospinal fluid-contacting neurons (CSF-cNs) are GABAergic interoceptive sensory neurons that detect spinal curvature via a functional coupling with the Reissner fiber. This mechanosensory system has recently been found involved in spine morphogenesis and postural control but the underlying mechanisms are not fully understood. In zebrafish, CSF-cNs project an ascending and ipsilateral axon reaching two to six segments away. Rostralmost CSF-cNs send their axons ipsilaterally into the hindbrain, a brain region containing motor nuclei and reticulospinal neurons (RSNs), which send descending motor commands to spinal circuits. Until now, the synaptic connectivity of CSF-cNs has only been investigated in the spinal cord where they synapse onto motor neurons and premotor excitatory interneurons. The identity of CSF-cN targets in the hindbrain and the behavioral relevance of these sensory projections from spinal cord to hindbrain are unknown. Here, we provide anatomical and molecular evidence that rostralmost CSF-cNs synapse onto the axons of large RSNs including the Mauthner cells and early born chx10+ neurons. Functional anatomy and optogenetic-assisted mapping reveal that rostral CSF-cNs also synapse onto the soma and dendrites of cranial motor neurons innervating hypobranchial muscles. During acousto-vestibular evoked escape responses, ablation of rostralmost CSF-cNs results in a weaker escape response with a decreased C-bend amplitude, lower speed and a deficient postural control. Our study demonstrates that spinal sensory feedback enhances speed and stabilizes posture, and reveals a novel spinal gating mechanism acting on the output of descending commands sent from the hindbrain to the spinal cord.eTOCCerebrospinal fluid-contacting neurons are mechanosensory cells that detect spinal curvature. Wu et al. show here that rostralmost CSF-cNs synapse in the hindbrain onto cranial motor neurons and the descending axons of reticulospinal neurons, and enhance speed and power as well as postural control during active locomotion.HighlightsCerebrospinal fluid-contacting neurons (CSF-cNs) in rostral spinal cord form inhibitory synapses onto cranial motor neuronsRostral CSF-cNs synapse onto descending axons of reticulospinal neuronsCSF-cN sensory feedback in the rostral spinal cord enhance speed and power of locomotionRostral CSF-cNs projecting to the hindbrain contribute to postural control

Published

2021

14. Latency of mechanically stimulated escape responses in the Pacific spiny dogfish, Squalus suckleyi

Author

Jacob L. Johansen, Mathias Schakmann, John F. Steffensen, Victoria Becker, Paolo Domenici, and Mathias Søgaard

Subjects

0106 biological sciences, Survival, Physiology, 030310 physiology, ved/biology.organism_classification_rank.species, Zoology, Aquatic Science, Biology, Escape latency, Escape kinematics, 010603 evolutionary biology, 01 natural sciences, Predator avoidance, 03 medical and health sciences, Squalus suckleyi, Mauthner cell, Pacific spiny dogfish, Mauthner cells, Latency (engineering), Molecular Biology, Predator, Ecology, Evolution, Behavior and Systematics, Reaction time, Rhacochilus vacca, 0303 health sciences, Elasmobranch, ved/biology, biology.organism_classification, Insect Science, Sculpin, Animal Science and Zoology

Abstract

Fast escape responses to a predator threat are fundamental to the survival of mobile marine organisms. However, elasmobranchs are often underrepresented in such studies. Here, we measured the escape latency (time interval between the stimulus and first visible reaction) of mechanically induced escape responses in the Pacific spiny dogfish, Squalus suckleyi, and in two teleosts from the same region, the great sculpin, Myoxocephalus polyacanthocephalus, and the pile perch, Rhacochilus vacca. We found that the dogfish had a longer minimum latency (66.7 ms) compared with that for the great sculpin (20.8 ms) and pile perch (16.7 ms). Furthermore, the dogfish had a longer latency than that of 48 different teleosts identified from 35 different studies. We suggest such long latencies in dogfish may be due to the absence of Mauthner cells, the giant neurons that control fast escape responses in fishes.

Published

2021

15. Electrical synaptic transmission requires a postsynaptic scaffolding protein

Author

Audrey J. Marsh, Kurt C. Marsden, Sundas Ijaz, Jennifer Carlisle Michel, E. Anne Martin, Abagael M Lasseigne, Alberto E. Pereda, Elisa Trujillo, Adam C. Miller, and Fabio A. Echeverry

Subjects

electrical synapse, Scaffold protein, QH301-705.5, Chemical synapse, Science, Connexin, zo1 zo-1, Synaptic Transmission, Connexins, General Biochemistry, Genetics and Molecular Biology, Electrical Synapses, Mauthner cell, Postsynaptic potential, medicine, Animals, Electrical synapse, Biology (General), Zebrafish, gap junctions, Ion channel, electrical coupling, General Immunology and Microbiology, biology, Chemistry, General Neuroscience, Gap junction, General Medicine, Zebrafish Proteins, biology.organism_classification, medicine.anatomical_structure, synapse formation, Zonula Occludens-1 Protein, Medicine, Neuron, Neuroscience, Intracellular, Research Article, Developmental Biology

Abstract

Electrical synaptic transmission relies on neuronal gap junctions containing channels constructed by Connexins. While at chemical synapses neurotransmitter-gated ion channels are critically supported by scaffolding proteins, it is unknown if channels at electrical synapses require similar scaffold support. Here, we investigated the functional relationship between neuronal Connexins and Zonula Occludens 1 (ZO1), an intracellular scaffolding protein localized to electrical synapses. Using model electrical synapses in zebrafish Mauthner cells, we demonstrated that ZO1 is required for robust synaptic Connexin localization, but Connexins are dispensable for ZO1 localization. Disrupting this hierarchical ZO1/Connexin relationship abolishes electrical transmission and disrupts Mauthner cell-initiated escape responses. We found that ZO1 is asymmetrically localized exclusively postsynaptically at neuronal contacts where it functions to assemble intercellular channels. Thus, forming functional neuronal gap junctions requires a postsynaptic scaffolding protein. The critical function of a scaffolding molecule reveals an unanticipated complexity of molecular and functional organization at electrical synapses., eLife digest Neurons ‘talk’ with each another at junctions called synapses, which can either be chemical or electrical. Communication across a chemical synapse involves a ‘sending’ neuron releasing chemicals that diffuse between the cells and subsequently bind to specialized receptors on the receiving neuron. These complex junctions involve a large number of well-studied molecular actors. Electrical synapses, on the other hand, are believed to be simpler. There, neurons are physically connected via channels formed of ‘connexin’ proteins, which allow electrically charged ions to flow between the cells. However, it is likely that other proteins help to create these structures. In particular, recent evidence shows that without a structurally supporting ‘scaffolding’ protein called ZO1, electrical synapses cannot form in the brain of a tiny freshwater fish known as zebrafish. As their name implies, scaffolding proteins help cells organize their internal structure, for example by anchoring other molecules to the cell membrane. By studying electrical synapses in zebrafish, Lasseigne, Echeverry, Ijaz, Michel et al. now show that these structures are more complex than previously assumed. In particular, the experiments reveal that ZO1 proteins are only present on one side of electrical synapses; despite their deceptively symmetrical anatomical organization, these junctions can be asymmetric, like their chemical cousins. The results also show that ZO1 must be present for connexins to gather at electrical synapses, whereas the converse is not true. This suggests that when a new electrical synapse forms, ZO1 moves into position first: it then recruits or stabilizes connexins to form the channels connecting the two cells. In many animals with a spine, electrical synapses account for about 20% of all neural junctions. Understanding how these structures form and work could help to find new treatments for disorders linked to impaired electrical synapses, such as epilepsy.

Published

2020

16. High behavioural variability mediated by altered neuronal excitability inauts2mutant zebrafish

Author

Igor Kondrychyn, Vladimir Korzh, Urvashi Jha, and Vatsala Thirumalai

Subjects

Candidate gene, ved/biology, ved/biology.organism_classification_rank.species, Wild type, Escape response, Biology, biology.organism_classification, medicine.anatomical_structure, Mauthner cell, medicine, Neuron, Model organism, Neuroscience, Zebrafish, Neural development

Abstract

Autism spectrum disorders (ASDs) are characterized by abnormal behavioral traits arising from neural circuit dysfunction. While a number of genes have been implicated in ASDs, in most cases, a clear understanding of how mutations in these genes lead to circuit dysfunction and behavioral abnormality is absent. Theautism susceptibility candidate 2(AUTS2) gene is one such gene, associated with ASDs, intellectual disability and a range of other neurodevelopmental conditions. Yet, the function of AUTS2 in neural development and circuit function is not at all known. Here, we undertook functional analysis of Auts2a, the main homolog of AUTS2 in zebrafish, in the context of the escape behavior. Escape behavior in wild type zebrafish is critical for survival and is therefore, reliable, rapid, and has well-defined kinematic properties.Auts2a−/−zebrafish are viable, have normal gross morphology and can generate escape behavior with normal kinematics. However, the behavior is unreliable and delayed, with high trial-to-trial variability in the latency. We demonstrate that this is due to the reduced excitability of Mauthner neurons resulting in unreliable firing with stimuli that normally elicit the escape response. Combined with previous studies that show Auts2-regulation of the transcription of ion channel proteins, our results suggest that Auts2 sets the excitability of neurons by activating a set transcriptional program.Significance statementAUTS2 is one among recently identified autism susceptibility candidate genes, whose function in neuronal circuits is unclear. Using zebrafish as a model organism, we probe the function of Auts2a (homolog of mammalian AUTS2) at the cellular, network and behavioral levels. The escape behavior of Auts2a mutant zebrafish is highly variable with normal short latency escapes, long latency escapes and total failures across trials in the same fish. This occurs because neuronal excitability is inappropriately set in the Mauthner neurons of mutants leading to the large trial-to-trial variability in responses. The behavioral variability is fully explained by variability in firing action potentials in the Mauthner neuron, providing an integrative understanding of how behavioral variability arises from mutations at the genetic level.

Published

2020

17. Author response for 'Evolutionary and homeostatic changes in morphology of visual dendrites of Mauthner cells in <scp> Astyanax </scp> blind cavefish'

Author

Daphne Soares, Zainab Tanvir, Kristen E. Severi, Gal Haspel, and Daihana Rivera

Subjects

Mauthner cell, Cavefish, Morphology (biology), Biology, Neuroscience, Homeostasis

Published

2020

18. Recording Channelrhodopsin-Evoked Field Potentials and Startle Responses from Larval Zebrafish

Author

Yagmur Idil Ozdemir, Christina A Hansen, Mohamed A Ramy, Eileen L. Troconis, Josef G. Trapani, and Lauren D McNeil

Subjects

0301 basic medicine, fungi, Channelrhodopsin, Sensory system, Evoked field, Biology, Stimulus (physiology), Optogenetics, biology.organism_classification, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, nervous system, Biological neural network, Neuroscience, Zebrafish, 030217 neurology & neurosurgery

Abstract

Zebrafish are an excellent model organism to study many aspects of vertebrate sensory encoding and behavior. Their escape responses begin with a C-shaped body bend followed by several swimming bouts away from the potentially threatening stimulus. This highly stereotyped motor behavior provides a model for studying startle reflexes and the neural circuitry underlying multisensory encoding and locomotion. Channelrhodopsin (ChR2) can be expressed in the lateral line and ear hair cells of zebrafish and can be excited in vivo to elicit these rapid forms of escape. Here we review our methods for studying transgenic ChR2-expressing zebrafish larvae, including screening for positive expression of ChR2 and recording field potentials and high-speed videos of optically evoked escape responses. We also highlight important features of the acquired data and provide a brief review of other zebrafish research that utilizes or has the potential to benefit from ChR2 and optogenetics.

Published

2020

19. Intersection of motor volumes predicts the outcome of ambush predation of larval zebrafish

Author

Malcolm A. MacIver, David L. McLean, and Kiran Bhattacharyya

Subjects

animal structures, Odonata, Physiology, Escape response, Context (language use), Aquatic Science, Biology, Predation, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Intersection, Escape Reaction, Zebrafish larvae, Animals, Latency (engineering), Molecular Biology, Ecology, Evolution, Behavior and Systematics, Zebrafish, 030304 developmental biology, 0303 health sciences, Escape velocity, Outcome (probability), Insect Science, Larva, Predatory Behavior, Animal Science and Zoology, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

The escape maneuvers of animals are key determinants of their survival. Consequently these maneuvers are under intense selection pressure. Current work indicates that a number of escape maneuver parameters contribute to survival including response latency, escape speed, and direction. This work has found that the relative importance of these parameters is context dependent, suggesting that interactions between escape maneuver parameters and the predatory context together determine the likelihood of escape success. However, it is unclear how escape maneuver parameters interact to contribute to escape success across different predatory contexts. To clarify these issues, we investigated the determinants of successful escape maneuvers by analyzing the responses of larval zebrafish to the attacks of dragonfly nymphs. We found that the strongest predictor of the outcome was the time needed for the nymph to reach the fish’s initial position at the onset of the attack, measured from the time that the fish initiates its escape response. We show how this result is related to the intersection of the swept volume of the nymph’s grasping organs with the volume containing all possible escape trajectories of the fish. By analyzing the intersection of these volumes, we compute the survival benefit of recruiting the Mauthner cell, a neuron in anamniotes devoted to producing escapes. We discuss how escape maneuver parameters interact in determining escape response. The intersection of motor volume approach provides a framework that unifies the influence of many escape maneuver parameters on the likelihood of survival.

Published

2020

20. Review for 'Evolutionary and homeostatic changes in morphology of visual dendrites of Mauthner cells in <scp> Astyanax </scp> blind cavefish'

Author

Violeta Medan

Subjects

Mauthner cell, Cavefish, Morphology (biology), Biology, Neuroscience, Homeostasis

Published

2020

21. Dual Oxidase Mutant Retards Mauthner-Cell Axon Regeneration at an Early Stage via Modulating Mitochondrial Dynamics in Zebrafish

Author

Bing Hu, Da-long Ren, Lei-qing Yang, and Min Chen

Subjects

0301 basic medicine, Physiology, Mutant, ved/biology.organism_classification_rank.species, Mitochondrion, Mitochondrial Dynamics, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Animals, Model organism, Zebrafish, Mitochondrial transport, Oxidase test, biology, Chemistry, ved/biology, General Neuroscience, Regeneration (biology), General Medicine, biology.organism_classification, Dual Oxidases, Axons, Cell biology, Nerve Regeneration, 030104 developmental biology, nervous system, Original Article, CRISPR-Cas Systems, Transcriptome, 030217 neurology & neurosurgery

Abstract

Dual oxidase (duox)-derived reactive oxygen species (ROS) have been correlated with neuronal polarity, cerebellar development, and neuroplasticity. However, there have not been many comprehensive studies of the effect of individual duox isoforms on central-axon regeneration in vivo. Here, we explored this question in zebrafish, an excellent model organism for central-axon regeneration studies. In our research, mutation of the duox gene with CRISPR/Cas9 significantly retarded the single-axon regeneration of the zebrafish Mauthner cell in vivo. Using deep transcriptome sequencing, we found that the expression levels of related functional enzymes in mitochondria were down-regulated in duox mutant fish. In vivo imaging showed that duox mutants had significantly disrupted mitochondrial transport and redox state in single Mauthner-cell axon. Our research data provide insights into how duox is involved in central-axon regeneration by changing mitochondrial transport. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (10.1007/s12264-020-00600-9) contains supplementary material, which is available to authorized users.

Published

2020

22. Visual escape in larval zebrafish: stimuli, circuits, and behavior

Author

Emmanuel Marquez-Legorreta, Ethan K. Scott, and Marielle Piber

Subjects

Visual processing, Alertness, Stimulus–response model, Mauthner cell, Visual perception, genetic structures, Computer science, Hindbrain, Stimulus (physiology), Tectum, Neuroscience

Abstract

Visual escape behavior is important for survival, and elements of this behavior are conserved from insects to humans. Because it needs to be robust and rapid, but also open to modulation, it is an excellent system in which to study visual processing and sensorimotor gating. Recent studies, especially in the transparent larvae of the zebrafish model system, have begun to shed light on the intricacies of visual escape circuitry, and in this chapter, we will review this progress. First, we will explore the essential properties of loom stimuli, including their movement, edges, and luminance changes, and will discuss how these stimulus properties, alone or in combination, can contribute to eliciting startle behavior. Next, we will describe the escape behavior itself, including the sequence of kinematic events that carries the animal away from the perceived threat and the various forms that this behavior can take depending on the stimulus and context. We will then provide an in-depth review of the core circuitry that lies between the stimulus and response, beginning with the retinal and thalamic projections that carry loom-relevant information to the tectum. We will also discuss how this information is likely to be processed in the tectum and the visuomotor projections to premotor cells in the hindbrain, including the well-known Mauthner neurons. Finally, we will describe ways in which context, such as alertness or hunger, can alter an animal's responses to threatening visual stimuli and the ways in which specific brain regions may detect these conditions and impinge on the core escape circuit to modulate behavior. We will conclude with perspectives on the important outstanding questions about visual escape circuits and specific experiments that might help in addressing them.

Published

2020

23. The Neuroprotective Effect of the Thr–Ser–Lys–Tyr Peptide in a Goldfish Mauthner Cell Model in vivo

Author

N. A. Ivlicheva, R. H. Ziganshin, Ludmila I. Kramarova, G. Z. Mikhailova, N. N. Kashirskaya, and E. N. Bezgina

Subjects

0301 basic medicine, chemistry.chemical_classification, Chemistry, Biophysics, Dystrophy, Dendrite, Hindbrain, Stimulation, Peptide, Neuroprotection, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Mauthner cell, In vivo, medicine, 030217 neurology & neurosurgery

Abstract

The effects of the Thr–Ser–Lys–Tyr peptide, which was shown to display neuroprotective activity in cell cultures in vitro, were studied in the model of paired Mauthner cells of goldfish. It was found that intracerebral injections provided the peptide to be applied into the zone of the right Mauthner cell under the fourth ventricle of the hindbrain lead to a dose-dependent decrease in the number of spontaneous turns of the goldfish to the left. It was shown that this effect is not eliminated under long-lasting optokinetic stimulation when the fish instinctively follow stimuli with a low spatial frequency that are moving in the nasal-to-temporal direction. We used the method of three-dimensional reconstruction by serial histological sections to study the dendrite morphology of the Mauthner cells in control and experimental goldfish. It was found that optokinetic stimulation of control goldfish evokes the dystrophy of the ventral dendrite of the right Mauthner cell, which is the target of this type of stimulation. Conversely, the peptide stabilize the size of the ventral dendrite of the right Mauthner cell under stimulation. These data could be interpreted as evidence of the neuroprotective effect of the Thr–Ser–Lys–Tyr peptide in vivo.

Published

2018

24. In vivo imaging of Mauthner axon regeneration, remyelination and synapses re-establishment after laser axotomy in zebrafish larvae

Author

Min Chen, Yu-bin Huang, Yang Xu, Rongchen Huang, Bing Hu, Wu Yin, Lei Li, and Bing-bing Hu

Subjects

0301 basic medicine, Intravital Microscopy, medicine.medical_treatment, Central nervous system, Biology, Time-Lapse Imaging, Animals, Genetically Modified, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Developmental Neuroscience, In vivo, medicine, Animals, Axon, Remyelination, Zebrafish, Regeneration (biology), Axotomy, biology.organism_classification, Axons, Nerve Regeneration, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Neurology, Larva, Synapses, Neuroscience, 030217 neurology & neurosurgery

Abstract

Zebrafish is an excellent model to study central nervous system (CNS) axonal degeneration and regeneration since we can observe these processes in vivo and in real time in transparent larvae. Previous studies have shown that Mauthner cell (M-cell) axon regenerates poorly after mechanical spinal cord injury. Inconsistent with this result, however, we have found that M-cell possesses a great capacity for axon regeneration after two-photon laser ablation. By using ZEISS LSM 710 two-photon microscope, we performed specific unilateral axotomy of GFP labeled M-cells in the Tol-056 enhancer trap line larvae. Our results showed that distal axons almost degenerated completely at 24h after laser axotomy. After that, the proximal axons initiated a robust regeneration and many of the M-cell axons almost regenerated fully at 4days post axotomy. Furthermore, we also visualized that regenerated axons were remyelinated when we severed fluorescent dye labeled M-cells in the Tg (mbp:EGFP-CAAX) line larvae. Moreover, by single M-cell co-electroporation with Syp:EGFP and DsRed2 plasmids we observed synapses re-establishment in vivo during laser injury-induced axon re-extension which suggested re-innervation of denervated pathways. In addition, we further demonstrated that nocodazole administration could completely abolish this regeneration capacity. These results together suggested that in vivo time-lapse imaging of M-cell axon laser injury may provide a powerful analytical model for understanding the underlying cellular and molecular mechanisms of the CNS axon regeneration.

Published

2018

25. Pecularities of the structure of glycogen as an indicator of the functional state of mauthner neurons in fish Percсottus glehni during wintering

Author

Rita Ya. Gordon, Irina M. Santalova, I. B. Mikheeva, Eugene I. Maevsky, and Sergei S. Khutsian

Subjects

Neurons, 0301 basic medicine, Glycogen, General Neuroscience, Fishes, Biology, Mitochondrion, Adaptation, Physiological, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, chemistry, Gluconeogenesis, Biochemistry, Cytoplasm, Ultrastructure, Biophysics, Animals, Glycolysis, Seasons, Reticulum, 030217 neurology & neurosurgery

Abstract

Mauthner neurons (MN)*, specific multifunctional neurons of fish, are a unique object for investigating the adaptive potentialities of the cell. The goal of the work was to study the structure of MN of fish Percсottus glehni during wintering under the conditions of hypothermia and deficit of oxygen and energy substrates. It was shown using a light microscope that the volume of the somatic moiety of neurons changes slightly at the beginning of wintering and is significantly reduced by the termination of wintering. It was found on the ultrastructural level that, at the beginning of wintering, glycogen exists in the central cytoplasm of MN in the form of large concentrated fields consisting of separate granules, whereas in the summer period the granules are distributed diffusely throughout the cell. In the vicinity of glycogen fields, lamellar structures of the smooth reticulum were seen. At the boundaries of glycogen fields, the aggregation of mitochondria and their active intrusion into glycogen fields were evident. By the end of wintering, the amount of glycogen significantly decreased, which was accompanied by a reduction of the smooth reticulum and rare contacts of mitochondria with glycogen fields. We assume that, because MN have a broader range of metabolic and functional possibilities than usual neurons in which glycogen is lacking or its content is negligible, they possess their own systems of glycolysis, glyconeogenesis, and deposition of glycogen. This allows them to maintain a sufficient level of energy supply under anaerobic conditions for performing the function of “guard neurons” during wintering.

Published

2018

26. High Behavioral Variability Mediated by Altered Neuronal Excitability inauts2Mutant Zebrafish

Author

Igor Kondrychyn, Vatsala Thirumalai, Urvashi Jha, and Vladimir Korzh

Subjects

biology, General Neuroscience, Mutant, Wild type, Context (language use), General Medicine, biology.organism_classification, Calcium imaging, medicine.anatomical_structure, Mauthner cell, medicine, Neuron, Neural development, Zebrafish, Neuroscience

Abstract

Autism spectrum disorders (ASDs) are characterized by abnormal behavioral traits arising from neural circuit dysfunction. While a number of genes have been implicated in ASDs, in most cases, a clear understanding of how mutations in these genes lead to circuit dysfunction and behavioral abnormality is absent. The autism susceptibility candidate 2 (AUTS2) gene is one such gene, associated with ASDs, intellectual disability and a range of other neurodevelopmental conditions. Yet, the role of AUTS2 in neural development and circuit function is not at all known. Here, we undertook functional analysis of Auts2a, the main homolog of AUTS2 in zebrafish, in the context of the escape behavior. Escape behavior in wild type zebrafish is critical for survival and is therefore, reliable, rapid, and has well-defined kinematic properties. Auts2a mutant zebrafish are viable, have normal gross morphology and can generate escape behavior with normal kinematics. However, the behavior is unreliable and delayed, with high trial-to-trial variability in the latency. Using calcium imaging we probed the activity of Mauthner neurons during otic vesicle stimulation and observed lower probability of activation and reduced calcium transients in the mutants. With direct activation of Mauthner by antidromic stimulation, the threshold for activation in mutants was higher than that in wild type, even when inhibition was blocked. Taken together, these results point to reduced excitability of Mauthner neurons in auts2a mutant larvae leading to unreliable escape responses. Our results show a novel role for Auts2a in regulating neural excitability and reliability of behavior.Significance statementAUTS2 is one among recently identified autism susceptibility candidate genes, whose function in neuronal circuits is unclear. Using zebrafish as a model organism, we probe the function of Auts2a (homolog of mammalian AUTS2) at the cellular, network and behavioral levels. The escape behavior of Auts2a mutant zebrafish is highly variable with normal short latency escapes, long latency escapes and total failures across trials in the same fish. This occurs because neuronal excitability is inappropriately set in the Mauthner neurons of mutants leading to large trial-to-trial variability in responses. The behavioral variability is fully explained by variability in firing action potentials in the Mauthner neuron, providing an integrative understanding of how behavioral variability arises from mutations at the genetic level.

Published

2021

27. Sonic hedgehog antagonists reduce size and alter patterning of the frog inner ear

Author

Kasra Zarei, Karen L. Elliott, Sanam Zarei, and Bernd Fritzsch

Subjects

0301 basic medicine, Pyridines, Morphogenesis, Xenopus, Vismodegib, Biology, Article, Xenopus laevis, 03 medical and health sciences, Cellular and Molecular Neuroscience, Imaging, Three-Dimensional, Mauthner cell, Olfactory Mucosa, Developmental Neuroscience, Escape Reaction, biology.animal, otorhinolaryngologic diseases, medicine, Animals, Anilides, Hedgehog Proteins, Inner ear, Axis specification, Sonic hedgehog, Pigment Epithelium of Eye, Swimming, Body Patterning, Dose-Response Relationship, Drug, Pigmentation, Gene Expression Regulation, Developmental, Vertebrate, Dextrans, Anatomy, biology.organism_classification, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Ear, Inner, Larva, Myosin Type IV, embryonic structures, biology.protein, Female, sense organs, Locomotion, medicine.drug

Abstract

Sonic Hedgehog (Shh) signaling plays a major role in vertebrate development, from regulation of proliferation to the patterning of various organs. In amniotes, Shh affects dorsoventral patterning in the inner ear but affects anteroposterior patterning in teleosts. Currently, it remains unknown the function of Shh in inner ear development in terms of how morphogenesis changes in the sarcopterygian/tetrapod lineage coincide with the evolution of limbs and novel auditory organs in the ear. In this study we used the tetrapod, Xenopus laevis, to test how increasing concentrations of the Shh signal pathway antagonist, Vismodegib, affects ear development. Vismodegib treatment dose dependently alters the development of the ear, hypaxial muscle, and indirectly the Mauthner cell through its interaction with the inner ear afferents. Together, these phenotypes have an effect on escape response. The altered Mauthner cell likely contributes to the increased time to respond to a stimulus. In addition, the increased hypaxial muscle in the trunk likely contributes to the subtle change in animal C-start flexion angle. In the ear, Vismodegib treatment results in decreasing segregation between the gravistatic sensory epithelia as the concentration of Vismodegib increases. Furthermore, at higher doses, there is a loss of the horizontal canal but no enantiomorphic transformation, as in bony fish lacking Shh. Like in amniotes, Shh signaling in frogs affects dorsoventral patterning in the ear, suggesting that auditory sensory evolution in sarcopterygians/tetrapods evolved with a shift of Shh axis specification of the ear. This article is protected by copyright. All rights reserved.

Published

2017

28. Local Spinal Cord Circuits and Bilateral Mauthner Cell Activity Function Together to Drive Alternative Startle Behaviors

Author

Melina E. Hale and Yen-Chyi Liu

Subjects

0301 basic medicine, Reflex, Startle, Startle response, Sensory Receptor Cells, Sensory system, Stimulation, Biology, Inhibitory postsynaptic potential, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Interneurons, Neural Pathways, medicine, Animals, Zebrafish, Motor Neurons, medicine.diagnostic_test, Motor control, Anatomy, Hyperpolarization (biology), 030104 developmental biology, Spinal Cord, General Agricultural and Biological Sciences, Neuroscience, 030217 neurology & neurosurgery

Abstract

The reticulospinal Mauthner cells (M-cells) of the startle circuit have been considered to be dedicated to one basic motor output and the C-type startle response in fish. The neural circuit underlying the C-start, a startle behavior in which the fish forms a "C"-shaped body bend has been described in depth in goldfish and zebrafish [1, 2] and is thought to occur in other species [3, 4]. However, previous research has shown that some species can perform a second type of startle called the S-start [5-7]. This startle response, in which the first movement creates an "S"-shaped body bend achieved with regional muscle activity on left and right sides, cannot be explained by M-cell circuit models. Here we use larval zebrafish to examine the S-start circuit. Since S-starts are elicited through tail stimulation [5-7] and ablating M-cells abolishes short-latency tail-elicited startles [8, 9], we hypothesized that M-cell activity was necessary for S-start generation. Our findings show that the M-cells fire simultaneously to generate the S-start. However, simultaneous M-cell spikes generated through direct current injection were not sufficient to generate S-starts. Through recordings of motoneurons, inhibitory interneurons, and sensory neurons, we uncover a mechanism for generating alternative startle behaviors; local sensory inputs drive inhibitory interneuron activity, which inhibits caudal motoneurons and pre-conditions their excitability prior to the arrival of M-cell spikes in the tail. We suggest that this motoneuron hyperpolarization can bias motor output to left or right sides, determining whether the fish performs a C-start or an S-start behavior.

Published

2017

29. Evolution of the acoustic startle response of Mexican cavefish

Author

Alex C. Keene, Alexandra Paz, Johanna E. Kowalko, Brittnee McDole, and Erik R. Duboué

Subjects

0106 biological sciences, 0301 basic medicine, Reflex, Startle, Startle response, Population, Cavefish, Escape response, Biology, 010603 evolutionary biology, 01 natural sciences, Predation, 03 medical and health sciences, Mauthner cell, Escape Reaction, Convergent evolution, Genetics, medicine, Animals, education, Ecology, Evolution, Behavior and Systematics, education.field_of_study, medicine.diagnostic_test, Characidae, Mechanism (biology), Evolutionary pressure, Darkness, Biological Evolution, Biomechanical Phenomena, Caves, 030104 developmental biology, Acoustic Stimulation, Evolutionary biology, Models, Animal, Molecular Medicine, Animal Science and Zoology, Developmental Biology

Abstract

The ability to detect threatening sensory stimuli and initiate an escape response is essential for survival and under stringent evolutionary pressure. In diverse fish species, acoustic stimuli activate Mauthner neurons, which initiate a stereotypical C-start escape response. This reflexive behavior is highly conserved across aquatic species and provides a model for investigating the neural mechanism underlying the evolution of escape behavior. Here, we define evolved differences in the C-start response between populations of the Mexican cavefish,Astyanax mexicanus. Cave populations ofA. mexicanusinhabit in an environment devoid of light and macroscopic predation, resulting in evolved differences in diverse morphological and behavioral traits. We find that the C-start is present in multiple populations of cavefish and river-dwelling surface fish, but response kinematics and probability differ between populations. The Pachón population of cavefish have an increased response probability, a slower response and reduction of the maximum bend angle, revealing evolved differences between surface and cave populations. In two other independently evolved populations of cavefish, the response probability and the kinematics of the response differ from one another, as well as from surface fish, suggesting the independent evolution of differences in the C-start response. Investigation of surface-cave hybrids reveals a relationship between angular speed and peak angle, suggesting these two kinematic characteristics are related at the genetic or functional levels. Together, these findings provide support for the use ofA. mexicanusas a model to investigate the evolution of escape behavior.

Published

2019

30. Dopamine Improves Resistance of Dendrites of Mauthner Neurons to Destruction Induced by Sensory Stimulation and Application of Β-Amyloid

Author

N. R. Tiras, G. Z. Mikhailova, I. B. Mikheeva, N. A. Pen’kova, and S. S. Khutsyan

Subjects

Neurons, Sensory stimulation therapy, Amyloid beta-Peptides, Chemistry, Dopamine, General Medicine, Dendrites, General Biochemistry, Genetics and Molecular Biology, law.invention, Mauthner cell, β amyloid, law, Afferent, Goldfish, Biophysics, medicine, Animals, Electron microscope, medicine.drug

Abstract

Mauthner neurons in goldfish fry were studied by the methods of light and electron microscopy. The structure and volume of individual dendrites as well as the structure of axodendritic synapses were examined using virtual images of neurons formed from serial 3-μ sections. In short-time (5 h) experiments with application of dopamine, β-amyloid fragment (25-35), and long-term sensory stimulation affecting afferent inputs to Mauthner neurons, the dendrites were larger than the same dendrites under the same conditions without dopamine application. Application of dopamine induced no pathological changes in the structure of axodendritic chemical and electric synapses containing desmosome-like contacts.

Published

2019

31. 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

32. Impacts of developmental exposures to the harmful algal bloom toxin domoic acid on neural development and behavior

Author

Jennifer M. Panlilio

Subjects

Startle response, medicine.diagnostic_test, Glutamate receptor, Neurotoxicity, Developmental toxicity, Biology, medicine.disease, Oligodendrocyte, Myelin, medicine.anatomical_structure, Mauthner cell, nervous system, medicine, Neural development, Neuroscience

Abstract

Harmful algal blooms (HABs) can produce potent neurotoxins that accumulate in seafood and affect human health. One HAB toxin of concern is domoic acid (DomA), a glutamate analog produced by the marine diatom Pseudo-nitzschia spp. Current regulatory limits are designed to prevent acute neurotoxicity in adult humans. However, research shows that low-level exposure during early life can lead to long-term changes in behavior, neural connectivity, and brain morphology. To determine the underlying mechanisms of developmental toxicity, this dissertation used zebrafish as a tool to: i) Establish the developmental window of susceptibility for DomA toxicity, ii) Characterize the behavioral consequences of exposures, and iii) Identify the cellular targets and processes perturbed by DomA. I found that DomA exposure particularly at 2 days post fertilization (dpf) led to altered startle response behavior, myelination defects, and the downregulation of axonal and myelin structural genes. Using vital dyes and immunolabeling, I assessed DomA-induced alterations in cells required for the startle response. I found no differences in the number of sensory neuromasts or in the sensory cranial ganglia structures that detect the acoustic stimuli. However, the majority of DomA-treated larvae lacked one or both Mauthner cells – hindbrain neurons critical for fast startle responses. DomA-treated larvae also had oligodendrocytes with fewer and shorter myelin sheaths, and appeared to aberrantly myelinate neuronal cell bodies. The loss of the Mauthner neurons and their axons may lead to a cellular environment where oligodendrocytes myelinate neuronal cell bodies in the absence of adequate axonal targets. Indeed, pharmacological treatment that reduced the oligodendrocyte number also led to the reduction in the number of these aberrant, myelinated cell bodies. These results indicate that exposure to DomA at a particular period in neural development targets specific cell types, disrupts myelination in the spinal cord, and leads to prolonged behavioral deficits. These mechanistic insights support hazard assessments of DomA exposures in humans during critical periods in early development.

Published

2019

33. The Formin Fmn2b Is Required for the Development of an Excitatory Interneuron Module in the Zebrafish Acoustic Startle Circuit

Author

Dhriti Nagar, Shrobona Guha, Tomin K. James, Aurnab Ghose, Shawn M. Burgess, and Ratnakar Mishra

Subjects

Nervous system, Reflex, Startle, Startle response, Interneuron, Fmn2, Formins, Development, acoustic startle, Mauthner cell, Interneurons, medicine, Biological neural network, Animals, Humans, Zebrafish, spiral fiber neuron, neurodevelopment, biology, medicine.diagnostic_test, General Neuroscience, Acoustics, General Medicine, Zebrafish Proteins, zebrafish, biology.organism_classification, medicine.anatomical_structure, Neuron, Neural development, Neuroscience, Research Article: New Research

Abstract

The formin family member Fmn2 is a neuronally enriched cytoskeletal remodeling protein conserved across vertebrates. Recent studies have implicated Fmn2 in neurodevelopmental disorders, including sensory processing dysfunction and intellectual disability in humans. Cellular characterization of Fmn2 in primary neuronal cultures has identified its function in the regulation of cell-substrate adhesion and consequently growth cone translocation. However, the role of Fmn2 in the development of neural circuitsin vivo, and its impact on associated behaviors have not been tested. Using automated analysis of behavior and systematic investigation of the associated circuitry, we uncover the role of Fmn2b in zebrafish neural circuit development. As reported in other vertebrates, the zebrafish ortholog of Fmn2 is also enriched in the developing zebrafish nervous system. We find that Fmn2b is required for the development of an excitatory interneuron pathway, the spiral fiber neuron, which is an essential circuit component in the regulation of the Mauthner cell (M-cell)-mediated acoustic startle response. Consistent with the loss of the spiral fiber neurons tracts, high-speed video recording revealed a reduction in the short latency escape events while responsiveness to the stimuli was unaffected. Taken together, this study provides evidence for a circuit-specific requirement of Fmn2b in eliciting an essential behavior in zebrafish. Our findings underscore the importance of Fmn2 in neural development across vertebrate lineages and highlight zebrafish models in understanding neurodevelopmental disorders.

Published

2021

34. N-Cadherin is Involved in Neuronal Activity-Dependent Regulation of Myelinating Capacity of Zebrafish Individual Oligodendrocytes In Vivo

Author

Shuchao Ge, Min Chen, Yang Xu, Rongchen Huang, Yu-bin Huang, and Bing Hu

Subjects

0301 basic medicine, Central nervous system, Neuroscience (miscellaneous), Models, Biological, Green fluorescent protein, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Mauthner cell, In vivo, Cyclic AMP, medicine, Animals, Premovement neuronal activity, Potassium Channels, Inwardly Rectifying, Zebrafish, Myelin Sheath, Neurons, biology, Cadherin, Electroporation, Zebrafish Proteins, Cadherins, biology.organism_classification, Axons, Molecular Imaging, Oligodendroglia, 030104 developmental biology, medicine.anatomical_structure, nervous system, Neurology, Pentylenetetrazole, Peptides, Neuroscience, 030217 neurology & neurosurgery

Abstract

Stimulating neuronal activity increases myelin sheath formation by individual oligodendrocytes, but how myelination is regulated by neuronal activity in vivo is still not fully understood. While in vitro studies have revealed the important role of N-cadherin in myelination, our understanding in vivo remains quite limited. To obtain the role of N-cadherin during activity-dependent regulation of myelinating capacity of individual oligodendrocytes, we successfully built an in vivo dynamic imaging model of the Mauthner cell at the subcellular structure level in the zebrafish central nervous system. Enhanced green fluorescent protein (EGFP)-tagged N-cadherin was used to visualize the stable accumulations and mobile transports of N-cadherin by single-cell electroporation at the single-cell level. We found that pentylenetetrazol (PTZ) significantly enhanced the accumulation of N-cadherin in Mauthner axons, a response that was paralleled by enhanced sheath number per oligodendrocytes. By offsetting this phenotype using oligopeptide (AHAVD) which blocks the function of N-cadherin, we showed that PTZ regulates myelination in an N-cadherin-dependent manner. What is more, we further suggested that PTZ influences N-cadherin and myelination via a cAMP pathway. Consequently, our data indicated that N-cadherin is involved in neuronal activity-dependent regulation of myelinating capacity of zebrafish individual oligodendrocytes in vivo.

Published

2016

35. β-Amyloid precursor protein-b is essential for Mauthner cell development in the zebrafish in a Notch-dependent manner

Author

Fredrik Eliassen, Petronella Kettunen, Malin Edling, Henrik Zetterberg, Rakesh Kumar Banote, and Alexandra Abramsson

Subjects

0301 basic medicine, Embryo, Nonmammalian, Morpholino, Neurogenesis, Oligonucleotides, Notch signaling pathway, Nerve Tissue Proteins, Morpholinos, Amyloid beta-Protein Precursor, 03 medical and health sciences, Mauthner cell, Amyloid precursor protein, Animals, Receptor, Notch1, Molecular Biology, Zebrafish, In Situ Hybridization, Gamma secretase, Cell Proliferation, Homeodomain Proteins, Motor Neurons, Neurons, Behavior, Animal, Receptors, Notch, biology, Gene Expression Regulation, Developmental, Cell Differentiation, Dipeptides, Cell Biology, Anatomy, Oligonucleotides, Antisense, Zebrafish Proteins, biology.organism_classification, Cell biology, 030104 developmental biology, Microscopy, Fluorescence, biology.protein, Amyloid Precursor Protein Secretases, Amyloid precursor protein secretase, Signal Transduction, Developmental Biology

Abstract

Amyloid precursor protein (APP) is a transmembrane glycoprotein that has been the subject of intense research because of its implication in Alzheimer's disease. However, the physiological function of APP in the development and maintenance of the central nervous system remains largely unknown. We have previously shown that the APP homologue in zebrafish (Danio rerio), Appb, is required for motor neuron patterning and formation. Here we study the function of Appb during neurogenesis in the zebrafish hindbrain. Partial knockdown of Appb using antisense morpholino oligonucleotides blocked the formation of the Mauthner neurons, uni- or bilaterally, with an aberrant behavior as a consequence of this cellular change. The Appb morphants had decreased neurogenesis, increased notch signaling and notch1a expression at the expense of deltaA/D expression. The Mauthner cell development could be restored either by a general decrease in Notch signaling through γ-secretase inhibition or by a partial knock down of Notch1a. Together, this demonstrates the importance of Appb in neurogenesis and for the first time shows the essential requirement of Appb in the formation of a specific cell type, the Mauthner cell, in the hindbrain during development. Our results suggest that Appb-regulated neurogenesis is mediated through balancing the Notch1a signaling pathway and provide new insights into the development of the Mauthner cell.

Published

2016

36. The Adhesion Molecule-Characteristic HNK-1 Carbohydrate Contributes to Functional Recovery After Spinal Cord Injury in Adult Zebrafish

Author

Melitta Schachner, Huifan Shen, Yan-Qin Shen, and Liping Ma

Subjects

Male, 0301 basic medicine, Nervous system, Sulfotransferase, animal structures, Morpholino, Neuroscience (miscellaneous), Motor Activity, Morpholinos, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Mauthner cell, medicine, Animals, RNA, Messenger, Zebrafish, Spinal cord injury, Spinal Cord Injuries, biology, Regeneration (biology), Recovery of Function, biology.organism_classification, Spinal cord, medicine.disease, Axons, Nerve Regeneration, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Spinal Cord, Neurology, Biochemistry, embryonic structures, Sulfotransferases, Cell Adhesion Molecules, 030217 neurology & neurosurgery, Brain Stem

Abstract

The human natural killer cell antigen-1 (HNK-1) is functionally important in development, synaptic activity, and regeneration after injury in the nervous system of several mammalian species. It contains a sulfated glucuronic acid which is carried by neural adhesion molecules and expressed in nonmammalian species, including zebrafish, which, as opposed to mammals, spontaneously regenerate after injury in the adult. To evaluate HNK-1's role in recovery of function after spinal cord injury (SCI) of adult zebrafish, we assessed the effects of the two HNK-1 synthesizing enzymes, glucuronyl transferase and HNK-1 sulfotransferase. Expression of these two enzymes was increased at the messenger RNA (mRNA) level 11 days after injury in the brainstem nuclei that are capable of regrowth of severed axons, namely, the nucleus of medial longitudinal fascicle and intermediate reticular formation, but not at earlier time points after SCI. mRNA levels of glucuronyl transferase and sulfotransferase were increased in neurons, not only of these nuclei but also in the spinal cord caudal to the injury site at 11 days. Mauthner neurons which are not capable of regeneration did not show increased levels of enzyme mRNAs after injury. Reducing protein levels of the enzymes by application of anti-sense morpholinos resulted in reduction of locomotor recovery for glucuronyl transferase, but not for HNK-1 sulfotransferase. The combined results indicate that HNK-1 is upregulated in expression only in those neurons that are intrinsically capable of regeneration and contributes to regeneration after spinal cord injury in adult zebrafish in the absence of its sulfate moiety.

Published

2016

37. Neural circuits that drive startle behavior, with a focus on the Mauthner cells and spiral fiber neurons of fishes

Author

Melina E. Hale, Hilary R. Katz, Martin Y. Peek, and Rachel T Fremont

Subjects

Neurons, 0301 basic medicine, Reflex, Startle, Behavior, Animal, Fishes, Poison control, Hindbrain, Biology, biology.organism_classification, Structure and function, 03 medical and health sciences, Cellular and Molecular Neuroscience, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, Neural Pathways, Genetics, Neural control, Biological neural network, Animals, Spiral (railway), Neuroscience, Zebrafish, 030217 neurology & neurosurgery

Abstract

Startle behaviors are rapid, high-performance motor responses to threatening stimuli. Startle responses have been identified in a broad range of species across animal diversity. For investigations of neural circuit structure and function, these behaviors offer a number of benefits, including that they are driven by large and identifiable neurons and their neural control is simple in comparison to other behaviors. Among vertebrates, the best-known startle circuit is the Mauthner cell circuit of fishes. In recent years, genetic approaches in zebrafish have provided key tools for morphological and physiological dissection of circuits and greatly extended understanding of their architecture. Here we discuss the startle circuit of fishes, with a focus on the Mauthner cells and associated interneurons called spiral fiber neurons and we add new observations on hindbrain circuit organization. We also briefly review and compare startle circuits of several other taxa, paying particular attention to how movement direction is controlled.

Published

2016

38. Heterogeneity in the regenerative abilities of central nervous system axons within species: why do some neurons regenerate better than others?

Author

William Rodemer, Jianli Hu, Michael E. Selzer, and Michael I. Shifman

Subjects

medicine.medical_treatment, Central nervous system, Population, lamprey, axonal regeneration, identifiable neurons, intrinsic factors, mauthner cell, müller cell, neuronal death, non-mammalian model organisms, spinal cord injury, zebrafish, Review, Biology, lcsh:RC346-429, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Developmental Neuroscience, medicine, Axon, education, lcsh:Neurology. Diseases of the nervous system, 030304 developmental biology, 0303 health sciences, education.field_of_study, Müller cell, Regeneration (biology), medicine.anatomical_structure, nervous system, Peripheral nervous system, Neuron, Axotomy, Neuroscience, 030217 neurology & neurosurgery

Abstract

Some neurons, especially in mammalian peripheral nervous system or in lower vertebrate or in vertebrate central nervous system (CNS) regenerate after axotomy, while most mammalian CNS neurons fail to regenerate. There is an emerging consensus that neurons have different intrinsic regenerative capabilities, which theoretically could be manipulated therapeutically to improve regeneration. Population-based comparisons between “good regenerating” and “bad regenerating” neurons in the CNS and peripheral nervous system of most vertebrates yield results that are inconclusive or difficult to interpret. At least in part, this reflects the great diversity of cells in the mammalian CNS. Using mammalian nervous system imposes several methodical limitations. First, the small sizes and large numbers of neurons in the CNS make it very difficult to distinguish regenerating neurons from non-regenerating ones. Second, the lack of identifiable neurons makes it impossible to correlate biochemical changes in a neuron with axonal damage of the same neuron, and therefore, to dissect the molecular mechanisms of regeneration on the level of single neurons. This review will survey the reported responses to axon injury and the determinants of axon regeneration, emphasizing non-mammalian model organisms, which are often under-utilized, but in which the data are especially easy to interpret.

Published

2020

39. Presynaptic Inhibition Selectively Gates Auditory Transmission to the Brainstem Startle Circuit

Author

Harold A. Burgess, Kathryn M. Tabor, Trevor Smith, Mary Brown, Sadie A. Bergeron, and Kevin L. Briggman

Subjects

0301 basic medicine, Reflex, Startle, Sensory system, Gating, Optogenetics, Biology, Synaptic Transmission, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Mauthner cell, Moro reflex, medicine, Animals, Prepulse inhibition, Zebrafish, Neurons, Sensory gating, Prepulse Inhibition, Brain, Sensory Gating, 030104 developmental biology, medicine.anatomical_structure, Command neuron, Auditory Perception, Calcium, Laser Therapy, General Agricultural and Biological Sciences, Neuroscience, 030217 neurology & neurosurgery, Brain Stem

Abstract

Filtering mechanisms prevent a continuous stream of sensory information from swamping perception, leading to diminished focal attention and cognitive processing. Mechanisms for sensory gating are commonly studied using prepulse inhibition, a paradigm that measures the regulated transmission of auditory information to the startle circuit, however the underlying neuronal pathways are unresolved. Using large-scale calcium imaging, optogenetics and laser ablations, we reveal a cluster of 30 morphologically identified neurons in zebrafish that suppress the transmission of auditory signals during prepulse inhibition. These neurons project to a key sensorimotor interface in the startle circuit — the termination zone of auditory afferents on the dendrite of a startle command neuron. Direct measurement of auditory nerve neurotransmitter release revealed selective presynaptic inhibition of sensory transmission to the startle circuit, sparing signaling to other brain regions. Our results provide the first cellular resolution circuit for prepulse inhibition in a vertebrate, revealing a central role for presynaptic gating of sensory information to a brainstem motor circuit.

Published

2018

40. The Mauthner cell in a fish with top-performance and yet flexibly tuned C-starts. I. Identification and comparative morphology

Author

Stefan Schuster, Wolfram Schulze, Kathrin Leupolz, Peter Machnik, and Sabine Feyl

Subjects

030110 physiology, 0301 basic medicine, Male, Morphology (linguistics), Physiology, Action Potentials, Escape response, Dendrite, Aquatic Science, Biology, 03 medical and health sciences, 0302 clinical medicine, Archerfish, Mauthner cell, Escape Reaction, Biological neural network, medicine, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Neurons, Neuroethology, biology.organism_classification, Spinal cord, Perciformes, medicine.anatomical_structure, Insect Science, Animal Science and Zoology, Female, Neuroscience, 030217 neurology & neurosurgery

Abstract

Archerfish use two powerful C-starts: One to escape threats, the other to secure prey that they have downed with a shot of water. The two C-starts are kinematically equivalent, are variable in both phases, and the predictive C-starts – used in hunting – are adjusted in the angle of turning and in the final linear speed to where and when their prey will hit the water surface. Presently nothing is known about the circuits that drive the archerfish C-starts. As the starting point for a neuroethological analysis, we first explored the presence and morphology of any paired Mauthner cell, a key cell in the teleost fast-start system. We show that archerfish have a typical Mauthner cell in each medullary hemisphere and that these send by far the largest axons down the spinal cord. Stimulation of the spinal cord caused short-latency all-or-none field potentials that could be detected even at the surface of the medulla and that had the archerfish Mauthner cell as its only source. The archerfish's Mauthner cell is remarkably similar morphologically to that of equally sized goldfish, except that the archerfish's ventral dendrite is slightly longer and its lateral dendrite thinner. Our data provide the necessary starting point for the dissection of the archerfish fast-start system and of any role potentially played by its Mauthner cell in the two C-start manoeuvres. Moreover, they do not support the recently expressed view that Mauthner cells should be reduced in animals with highly variable fast-start manoeuvres.

Published

2018

41. Rohon-Beard Neuron in Zebrafish

Author

Kazutoyo Ogino and Hiromi Hirata

Subjects

Cell type, education.field_of_study, Population, Biology, Somatosensory system, biology.organism_classification, Cell biology, Trigeminal ganglion, medicine.anatomical_structure, Mauthner cell, nervous system, Dorsal root ganglion, medicine, Neuron, education, Zebrafish

Abstract

We experience various sensations through our skin. The sensations are received by distinct sensory channels that are expressed in the trigeminal ganglion (TG) or the dorsal root ganglion (DRG). TG neurons innervate the head skin, whereas DRG neurons innervate the skin of the trunk and limbs. In addition to these neuronal populations, larvae of anamniote vertebrates (lampreys, teleosts, and amphibians) have an additional sensory neuronal population that develops prior to functional maturation of DRG neurons, termed Rohon-Beard (RB) neurons. RB neurons innervate the trunk skin; thus, the TG and RB neurons are responsible for larval somatosensation. After the maturation of DRG neurons, the physiological roles of the RB neurons are replaced progressively by the DRG neurons. Studies of somatosensation in zebrafish have suggested that the transition from RB neurons to DRG neurons is completed within 5 days post fertilization. During this transition, the RB neurons undergo programmed cell death; thus, RB neurons have been considered to be a transient neuronal population. However, recent studies using zebrafish have indicated that some RB neurons survive for at least 2 weeks post-fertilization. These long-lived RBs are distinguished by Protein Kinase C-α (PKCα) expression and comprise

Published

2018

42. Zebrafish TARP Cacng2 is required for the expression and normal development of AMPA receptors at excitatory synapses

Author

Marcus E. Cunningham, Birbickram Roy, Jannatul Ferdous, Declan W. Ali, Rajarshi Mukherjee, Xing-Zhen Chen, Kazi T. Ahmed, and Wang Zheng

Subjects

0301 basic medicine, Synaptic scaling, CACNG2, Glutamate receptor, AMPA receptor, Neurotransmission, Biology, Cell biology, 03 medical and health sciences, Cellular and Molecular Neuroscience, chemistry.chemical_compound, 030104 developmental biology, Mauthner cell, Developmental Neuroscience, chemistry, Excitatory postsynaptic potential, biology.protein, Neurotransmitter, Neuroscience

Abstract

Fast excitatory synaptic transmission in the CNS is mediated by the neurotransmitter glutamate, binding to and activating AMPA receptors (AMPARs). AMPARs are known to interact with auxiliary proteins that modulate their behavior. One such family of proteins is the transmembrane AMPA receptor-related proteins, known as TARPs. Little is known about the role of TARPs during development, or about their function in non-mammalian organisms. Here we report the presence of TARPs, specifically the prototypical TARP, stargazin, in developing zebrafish. We find that zebrafish express two forms of stargazin, Cacng2a and Cacng2b from as early as 12-h post fertilization (hpf). Knockdown of Cacng2a and Cacng2b via splice-blocking morpholinos resulted in embryos that exhibited deficits in C-start escape responses, showing reduced C-bend angles, smaller tail velocities and aberrant C-bend turning directions. Injection of the morphants with Cacng2a or 2b mRNA rescued the morphological phenotype and the synaptic deficits. To investigate the effect of reduced Cacng2a and 2b levels on synaptic physiology, we performed whole cell patch clamp recordings of AMPA mEPSCs from zebrafish Mauthner cells. Knockdown of Cacng2a results in reduced AMPA currents and lower mEPSC frequencies, whereas knockdown of Cacng2b displayed no significant change in mEPSC amplitude or frequency. Non-stationary fluctuation analysis confirmed a reduction in the number of active synaptic receptors in the Cacng2a but not in the Cacng2b morphants. Together, these results suggest that Cacng2a is required for normal trafficking and function of synaptic AMPARs, while Cacng2b is largely non-functional with respect to the development of AMPA synaptic transmission.

Published

2015

43. Opioids potentiate electrical transmission at mixed synapses on the Mauthner cell

Author

Roger Cachope and Alberto E. Pereda

Subjects

Fish Proteins, Physiology, Dopamine, Narcotic Antagonists, Glutamic Acid, Neurotransmission, Inhibitory postsynaptic potential, Glutamatergic, Electrical Synapses, Mauthner cell, Postsynaptic potential, Cellular and Molecular Properties of Neurons, Goldfish, Animals, Receptors, Dopamine D5, Neurons, Naloxone, Chemistry, Receptors, Dopamine D1, General Neuroscience, Neural Inhibition, Benzazepines, Enkephalin, Ala(2)-MePhe(4)-Gly(5), Cyclic AMP-Dependent Protein Kinases, Electric Stimulation, Analgesics, Opioid, Spinal Cord, Silent synapse, Excitatory postsynaptic potential, Dopamine Antagonists, Microelectrodes, Neuroscience

Abstract

Opioid receptors were shown to modulate a variety of cellular processes in the vertebrate central nervous system, including synaptic transmission. While the effects of opioid receptors on chemically mediated transmission have been extensively investigated, little is known of their actions on gap junction-mediated electrical synapses. Here we report that pharmacological activation of mu-opioid receptors led to a long-term enhancement of electrical (and glutamatergic) transmission at identifiable mixed synapses on the goldfish Mauthner cells. The effect also required activation of both dopamine D1/5 receptors and postsynaptic cAMP-dependent protein kinase A, suggesting that opioid-evoked actions are mediated indirectly via the release of dopamine from varicosities known to be located in the vicinity of the synaptic contacts. Moreover, inhibitory inputs situated in the immediate vicinity of these excitatory synapses on the lateral dendrite of the Mauthner cell were not affected by activation of mu-opioid receptors, indicating that their actions are restricted to electrical and glutamatergic transmissions co-existing at mixed contacts. Thus, as their chemical counterparts, electrical synapses can be a target for the modulatory actions of the opioid system. Because gap junctions at these mixed synapses are formed by fish homologs of the neuronal connexin 36, which is widespread in mammalian brain, it is likely that this regulatory property applies to electrical synapses elsewhere as well.

Published

2015

44. Effect of winter dormancy on three-dimensional structure of the Mauthner neurons in perccottus glehni fish

Author

I. B. Mikheeva, Irina M. Santalova, Nadezhda A. Penkova, and D. A. Moshkov

Subjects

Energy resources, Period (gene), Biophysics, Medicine (miscellaneous), Dendrite, Biology, Animal science, medicine.anatomical_structure, Mauthner cell, Afferent, Botany, medicine, %22">Fish , Dormancy, Soma

Abstract

Investigation of the Mauthner neurons (MN) morphology in fish Perccottus glehni revealed a significant reduction in their volumes during dormancy, probably stipulated by a need to spare the body energy resources. The initial period of winter dormancy was characterized by a decrease in volumes of both main dendrites with no changes in somatic part of MN. During the terminal period of winter dormancy a total volume of soma and lateral dendrite reduced by 50%, and for the ventral one it did by 80%. It can be assumed that a decrease in integral neuronal volumes is associated with developing hypometabolism, as well as with a significantly decreased inputs of afferent information, entering MN from auditory and visual analyzers. Probl Cryobiol Cryomed 2015; 25(2): 114-121

Published

2015

45. A Convergent and Essential Interneuron Pathway for Mauthner-Cell-Mediated Escapes

Author

Martin Haesemeyer, Drew N. Robson, Caroline Lei Wee, Owen Randlett, Alix M. B. Lacoste, Ruben Portugues, David Schoppik, Florian Engert, Alexander F. Schier, and Jennifer M. Li

Subjects

Startle response, Interneuron, Biology, Optogenetics, Axon hillock, Reticular formation, General Biochemistry, Genetics and Molecular Biology, Article, Animals, Genetically Modified, Mauthner cell, Escape Reaction, Interneurons, Biological neural network, medicine, otorhinolaryngologic diseases, Animals, Zebrafish, medicine.diagnostic_test, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Anatomy, medicine.anatomical_structure, nervous system, Neuron, General Agricultural and Biological Sciences, Neuroscience

Abstract

Summary The Mauthner cell (M-cell) is a command-like neuron in teleost fish whose firing in response to aversive stimuli is correlated with short-latency escapes [1–3]. M-cells have been proposed as evolutionary ancestors of startle response neurons of the mammalian reticular formation [4], and studies of this circuit have uncovered important principles in neurobiology that generalize to more complex vertebrate models [3]. The main excitatory input was thought to originate from multisensory afferents synapsing directly onto the M-cell dendrites [3]. Here, we describe an additional, convergent pathway that is essential for the M-cell-mediated startle behavior in larval zebrafish. It is composed of excitatory interneurons called spiral fiber neurons, which project to the M-cell axon hillock. By in vivo calcium imaging, we found that spiral fiber neurons are active in response to aversive stimuli capable of eliciting escapes. Like M-cell ablations, bilateral ablations of spiral fiber neurons largely eliminate short-latency escapes. Unilateral spiral fiber neuron ablations shift the directionality of escapes and indicate that spiral fiber neurons excite the M-cell in a lateralized manner. Their optogenetic activation increases the probability of short-latency escapes, supporting the notion that spiral fiber neurons help activate M-cell-mediated startle behavior. These results reveal that spiral fiber neurons are essential for the function of the M-cell in response to sensory cues and suggest that convergent excitatory inputs that differ in their input location and timing ensure reliable activation of the M-cell, a feedforward excitatory motif that may extend to other neural circuits.

Published

2015

46. Changes in Motor Asymmetry of the Goldfish Related to Adaptation to Vestibular Stimulation and Applications of Beta-Amyloid on Mauthner Cells

Author

N. R. Tiras, G. A. Alilova, N. A. Pen’kova, Ye. N. Besgina, and D. A. Moshkov

Subjects

Vestibular system, Physiology, General Neuroscience, Gap junction, Stimulation, Dendrite, Anatomy, Biology, medicine.anatomical_structure, Mauthner cell, Excitatory postsynaptic potential, medicine, Soma, Neuron, Neuroscience

Abstract

We examined effects resulting from application of aggregated beta-amyloid on Mauthner neurons (MNs) of ambidextral goldfishes and long-lasting rotatory stimulation on lateral motor behavior of such fishes; these individuals were preliminarily adapted to repetitive rotatory stimulation. Using 3D histological reconstruction of the above cells, we measured the volumes of the right and left MNs and examined the ultrastructure of specialized synaptic compartments in excitatory synapses localized on the surface of the soma, lateral dendrite, and ventral dendrite of these cells. In the course of the experiments, control fishes remain ambidextrals, and the mean volumes of the right and left MNs in these individuals were close to each other. In a fish of this group, dimensions of the active zones (AZs) of chemical synapses localized on the lateral dendrite were considerably greater in the right neuron, while those in synapses on the lateral dendrite were smaller in the left neuron. Experimental fishes subjected to the above-mentioned procedures demonstrated clearly expressed motor lateralization; the mean volumes of their right and left MNs were, however, practically equal to each other. Ultrastructural analysis of peculiarities of MNs of such a fish showed that dimensions of the AZs in chemical synapses on the soma and lateral dendrite of the left MN, which became much less active functionally, significantly exceeded the analogous indices in synapses of the same localization on the right, more active, MN. In mixed synapses, the mean dimensions of gap junctions in control and experimental individuals were similar to each other independently of localization of such synapses. Interrelations between functional asymmetry of MNs manifested in lateralization of motor behavior of the fishes and dimensions of synaptic structures on these cells are discussed.

Published

2015

47. Ear manipulations reveal a critical period for survival and dendritic development at the single-cell level in Mauthner neurons

Author

Douglas W. Houston, Rhonda DeCook, Bernd Fritzsch, and Karen L. Elliott

Subjects

biology, Period (gene), Cell, Xenopus, Hindbrain, Sensory system, Cellular level, biology.organism_classification, Cellular and Molecular Neuroscience, medicine.anatomical_structure, Mauthner cell, Developmental Neuroscience, medicine, Inner ear, Neuroscience

Abstract

Second-order sensory neurons are dependent on afferents from the sense organs during a critical period in development for their survival and differentiation. Past research has mostly focused on whole populations of neurons, hampering progress in understanding the mechanisms underlying these critical phases. To move toward a better understanding of the molecular and cellular basis of afferent-dependent neuronal development, we developed a new model to study the effects of ear removal on a single identifiable cell in the hindbrain of a frog, the Mauthner cell. Ear extirpation at various stages of Xenopus laevis development defines a critical period of progressively-reduced dependency of Mauthner cell survival/differentiation on the ear afferents. Furthermore, ear removal results in a progressively decreased reduction in the number of dendritic branches. Conversely, addition of an ear results in an increase in the number of dendritic branches. These results suggest that the duration of innervation and the number of inner ear afferents play a quantitative role in Mauthner cell survival/differentiation, including dendritic development. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 75: 1339–1351, 2015

Published

2015

48. Heterotypic gap junctions at glutamatergic mixed synapses are abundant in goldfish brain

Author

John O'Brien, James I. Nagy, Naomi Kamasawa, Alberto E. Pereda, Srikant Nannapaneni, John E. Rash, Kimberly G. Vanderpool, and Thomas Yasumura

Subjects

Fish Proteins, Glutamic Acid, Connexin, Biology, Article, Mauthner cell, Axon terminal, Postsynaptic potential, Goldfish, medicine, Animals, Axon, Microscopy, Confocal, General Neuroscience, Gap junction, Brain, Gap Junctions, Molecular asymmetry, Dendrites, Immunohistochemistry, Axons, Microscopy, Electron, Electrical Synapses, medicine.anatomical_structure, Synapses, Neuroscience

Abstract

Gap junctions provide for direct intercellular electrical and metabolic coupling. The abundance of gap junctions at "large myelinated club ending (LMCE)" synapses on Mauthner cells (M-cells) of the teleost brain provided a convenient model to correlate anatomical and physiological properties of electrical synapses. There, presynaptic action potentials were found to evoke short-latency electrical "pre-potentials" immediately preceding their accompanying glutamate-induced depolarizations, making these the first unambiguously identified "mixed" (i.e., chemical plus electrical) synapses in the vertebrate CNS. We recently showed that gap junctions at these synapses exhibit asymmetric electrical resistance (i.e., electrical rectification), which we correlated with total molecular asymmetry of connexin composition in their apposing gap junction hemiplaques, with connexin35 (Cx35) restricted to axon terminal hemiplaques and connexin34.7 (Cx34.7) restricted to apposing M-cell plasma membranes. We now show that similarly heterotypic neuronal gap junctions are abundant throughout goldfish brain, with labeling exclusively for Cx35 in presynaptic hemiplaques and exclusively for Cx34.7 in postsynaptic hemiplaques. Moreover, the vast majority of these asymmetric gap junctions occur at glutamatergic axon terminals. The widespread distribution of heterotypic gap junctions at glutamatergic mixed synapses throughout goldfish brain and spinal cord implies that pre- vs. postsynaptic asymmetry at electrical synapses evolved early in the chordate lineage. We propose that the advantages of the molecular and functional asymmetry of connexins at electrical synapses that are so prominently expressed in the teleost CNS are unlikely to have been abandoned in higher vertebrates. However, to create asymmetric coupling in mammals, where most gap junctions are composed of connexin36 (Cx36) on both sides, would require some other mechanism, such as differential phosphorylation of connexins on opposite sides of the same gap junction or on asymmetric differences in the complement of their scaffolding and regulatory proteins.

Published

2015

49. The Mauthner Cell Microcircuits: Sensory Integration, Decision-Making, and Motor Functions

Author

Henri Korn and Donald S. Faber

Subjects

Mauthner cell, Sensory system, Biology, Neuroscience

Abstract

The teleost and amphibian Mauthner (M) cell is the critical decision-making element in a brainstem microcircuit that decides whether unimodal or multimodal stimuli are sufficiently threatening to the animal’s survival to warrant a massive motor response. This behavior, called the startle response or C-start, was initially characterized as a reflex, when in fact its governing process involves computations that can occur over a period as short as a few milliseconds or as long as 0.5 s. Because much of what is known about this system was derived from studies in goldfish of the C-start evoked by loud, abrupt sounds and from the associated basic electrophysiology, this behavior is discussed first. Then the chapter addresses M-cell-initiated escapes triggered by more complex stimuli and the notion that the behavior can be voluntary. Finally, it describes insights from studying the M-cell system that provide a model for the construction of brainstem decision-making microcircuits.

Published

2017

50. Cellular Mechanisms of Cortisol-Induced Changes in Mauthner-Cell Excitability in the Startle Circuit of Goldfish

Author

Daniel R. Bronson and Thomas G. Preuss

Subjects

0301 basic medicine, Reflex, Startle, medicine.medical_specialty, Hydrocortisone, Cognitive Neuroscience, Neuroscience (miscellaneous), cortisol, Inhibitory postsynaptic potential, Membrane Potentials, startle, voltage-gated ion channels, lcsh:RC321-571, input resistance, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Mauthner cell, Postsynaptic potential, Goldfish, Internal medicine, Neural Pathways, excitability, medicine, Animals, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Prepulse inhibition, Original Research, Feedback, Physiological, Neurons, Membrane potential, hormones, Voltage-gated ion channel, in vivo electrophysiology, Neural Inhibition, Depolarization, Sensory Systems, 030104 developmental biology, Endocrinology, Acoustic Stimulation, Auditory Perception, Mauthner-cell, Psychology, Microelectrodes, Neuroscience, 030217 neurology & neurosurgery, medicine.drug

Abstract

Predator pressure and olfactory cues (alarm substance) have been shown to modulate Mauthner cell (M-cell) initiated startle escape responses (C-starts) in teleost fish. The regulation of such adaptive responses to potential threats is thought to involve the release of steroid hormones such as cortisol. However, the mechanism by which cortisol may regulate M-cell excitability is not known. Here, we used intrasomatic, in vivo recordings to elucidate the acute effects of cortisol on M-cell membrane properties and sound evoked post-synaptic potentials (PSPs). Cortisol tonically decreased threshold current in the M-cell within 10 min before trending towards baseline excitability over an hour later, which may indicate the involvement of non-genomic mechanisms. Consistently, current ramp injection experiments showed that cortisol increased M-cell input resistance in the depolarizing membrane, i.e., by a voltage-dependent postsynaptic mechanism. Cortisol also increases the magnitude of sound-evoked M-cell PSPs by reducing the efficacy of local feedforward inhibition (FFI). Interestingly, another pre-synaptic inhibitory network mediating prepulse inhibition (PPI) remained unaffected. Together, our results suggest that cortisol rapidly increases M-cell excitability via a post-synaptic effector mechanism, likely a chloride conductance, which, in combination with its dampening effect on FFI, will modulate information processing to reach threshold. Given the central role of the M-cell in initiating startle, these results are consistent with a role of cortisol in mediating the expression of a vital behavior.

Published

2017