A Hybrid Electrical/Chemical Circuit in the Spinal Cord Generates a Transient Embryonic Motor Behavior

Knogler, Laura D.; Ryan, Joël; Saint-Amant, Louis; Drapeau, Pierre

doi:10.1523/jneurosci.1225-14.2014

Cited by 31 publications

(73 citation statements)

References 45 publications

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“…Early spontaneous activity consists of single coils that are driven by periodic, non-chemically-mediated depolarizations, excitation spikes, and gap-junction-mediated electrical coupling within early spinal neurons (Saint-Amant and Drapeau, 2001, 2000). On the other hand, late spontaneous activity consists of side-to-side double coils that arise through the addition of chemically-mediated synapses to the existing electrical circuit and is regulated within the spinal cord as well as the hindbrain of embryonic zebrafish (Behra et al, 2002; Knogler et al, 2014; Raftery and Volz, 2015). As such, late spontaneous activity represents an intermediate form of behavior that precedes secondary motoneuron development and bridges early spontaneous activity with stimuli-induced responses observed during later stages of embryonic and larval development (Knogler et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

“…Although different forms of larval and adult zebrafish locomotion have been leveraged within behavioral assays, spontaneous activity (tail contraction) – a behavior that occurs from late-segmentation (~17–19 hours post-fertilization, hpf) through early-pharyngula (~27–29 hpf) – represents an early, primitive form of motor activity within zebrafish embryos, providing a potential readout for rapid identification of neuroactive chemicals (Kokel et al, 2010; Raftery et al, 2014; Reif et al, 2015; Truong et al, 2016). Although previous studies have explored the biological basis of this behavior (Knogler et al, 2014; Knogler and Drapeau, 2014; Saint-Amant and Drapeau, 2001, 2000), it remains unclear whether spontaneous activity is responsive only to certain compounds with specific mechanisms of action.…”

Section: Introductionmentioning

confidence: 99%

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Behavioral screening of the LOPAC1280 library in zebrafish embryos

Vliet

Volz

2017

Toxicology and Applied Pharmacology

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Spontaneous activity represents an early, primitive form of motor activity within zebrafish embryos, providing a potential readout for identification of neuroactive compounds. However, despite use as an endpoint in chemical screens around the world, the predictive power and limitations of assays relying on spontaneous activity remain unclear. Using an improved high-content screening assay that increased throughput from 384 to 3,072 wells per week, we screened a well-characterized library of 1,280 pharmacologically active compounds (LOPAC1280) – 612 of which target neurotransmission – to identify which targets are detected using spontaneous activity as a readout. Results from this screen revealed that (1) 8% of the LOPAC1280 library was biologically active; (2) spontaneous activity was affected by compounds spanning a broad array of targets; (3) only 4% of compounds targeting neurotransmission impacted spontaneous activity; and (4) hypoactivity was observed for 100% of hits detected, including those that exhibit opposing mechanisms of action for the same target. Therefore, while this assay was able to rapidly identify potent neuroactive chemicals, these data suggest that spontaneous activity may lack the ability to discriminate modes of action for compounds interfering with neurotransmission, an issue that may be due to systemic uptake following waterborne exposure, persistent control variation, and/or interference with non-neurotransmission-related mechanisms.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Behavioral screening of the LOPAC1280 library in zebrafish embryos

Vliet

Volz

2017

Toxicology and Applied Pharmacology

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“…Further studies should be also carried out on more precise architecture including synaptic interactions between cell populations. In zebrafish embryos, chx10 positive V2a interneurons have been recently shown to establish putative synaptic contacts with others and motoneurons (Knogler et al, ). We suggest that a correlation between physiological recordings and histology could help to provide answers in adults.…”

Section: Discussionmentioning

confidence: 99%

Neuronal labeling patterns in the spinal cord of adult transgenic Zebrafish

Stil

Drapeau

2015

Developmental Neurobiology

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We describe neuronal patterns in the spinal cord of adult zebrafish. We studied the distribution of cells and processes in the three spinal regions reported in the literature: the 8th vertebra used as a transection injury site, the 15th vertebra mainly used for motor cell recordings and also for crush injury, and the 24th vertebra used to record motor nerve activity. We used well-known transgenic lines in which expression of green fluorescent protein (GFP) is driven by promoters to hb9 and isl1 in motoneurons, alx/chx10 and evx1 interneurons, ngn1 in sensory neurons and olig2 in oligodendrocytes, as well as antibodies for neurons (HuC/D, NF and SV2) and glia (GFAP). In isl1:GFP fish, GFP-positive processes are retained in the upper part of ventral horns and two subsets of cell bodies are observed. The pattern of the transgene in hb9:GFP adults is more diffuse and fibers are present broadly through the adult spinal cord. In alx/chx10 and evx1 lines we respectively observed two and three different GFP-positive populations. Finally, the ngn1:GFP transgene identifies dorsal root ganglion and some cells in dorsal horns. Interestingly some GFP positive fibers in ngn1:GFP fish are located around Mauthner axons and their density seems to be related to a rostrocaudal gradient. Many other cell types have been described in embryos and need to be studied in adults. Our findings provide a reference for further studies on spinal cytoarchitecture. Combined with physiological, histological and pathological/traumatic approaches, these studies will help clarify the operation of spinal locomotor circuits of adult zebrafish.

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“…Zebrafish motor neurons are activated via descending interneurons such as CiD (Circumferential ipsilateral descending) and IC (ipsilateral projecting), which form electrical connections by gap junction to synchronize neural activity among them and motor neurons, and also form glutamatergic synapses that excite motor neurons (Saint‐Amant & Drapeau ; Knogler et al . ). Probably commissural axons from CoPA neuron provide sensory signal to these descending interneuron, whereas connections between CoPA and the descending neurons are not clarified yet in current studies.…”

Section: Switching Of the Turning Laterality According To The Number mentioning

confidence: 97%

From neuron to behavior: Sensory‐motor coordination of zebrafish turning behavior

Umeda

Watanabe

2017

Dev Growth Differ

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Recent development of optogenetics brought non-invasive neural activation in living organisms. Transparent zebrafish larva is one of the suitable animal models for this technique, which enables us to investigate neural circuits for behaviors based on a whole individual nervous system. In this article we review our recent finding that suggests sensory-motor coordination in larval zebrafish escape behavior. When water vibration stimulates mechanosensory Rohon-Beard (RB) neurons, intra-spinal reflex circuit launches contralateral trunk muscle contraction that makes rapid body curvature for turning. In addition, positional information of the stimulus is conveyed to supra-spinal circuits, and then regulates the curvature strength for appropriate escape pathway from the threat. Sensory-motor coordination is a fundamental feature to adapt behaviors to environment, and zebrafish larvae would be an excellent model for elucidating its neural backbones.

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A Hybrid Electrical/Chemical Circuit in the Spinal Cord Generates a Transient Embryonic Motor Behavior

Cited by 31 publications

References 45 publications

Behavioral screening of the LOPAC1280 library in zebrafish embryos

Behavioral screening of the LOPAC1280 library in zebrafish embryos

Neuronal labeling patterns in the spinal cord of adult transgenic Zebrafish

From neuron to behavior: Sensory‐motor coordination of zebrafish turning behavior

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