Behavioral responses of zebrafish larvae to environmental cues are important functional readouts that should be evoked on-demand and studied phenotypically in behavioral, genetical and developmental investigations. Very recently, it was shown that zebrafish larvae execute a voluntary and oriented movement toward the positive electrode of an electric field along a microchannel. Phenotypic characterization of this response was not feasible due to larva’s rapid movement along the channel. To overcome this challenge, a microfluidic device was introduced to partially immobilize the larva’s head while leaving its mid-body and tail unrestrained in a chamber to image motor behaviors in response to electric stimulation, hence achieving quantitative phenotyping of the electrically evoked movement in zebrafish larvae. The effect of electric current on the tail-beat frequency and response duration of 5–7 days postfertilization zebrafish larvae was studied. Investigations were also performed on zebrafish exposed to neurotoxin 6-hydroxydopamine and larvae carrying a pannexin1a (panx1a) gene knockout, as a proof of principle applications to demonstrate on-demand movement behavior screening in chemical and mutant assays. We demonstrated for the first time that 6-hydroxydopamine leads to electric response impairment, levodopa treatment rescues the response and panx1a is involved in the electrically evoked movement of zebrafish larvae. We envision that our technique is broadly applicable as a screening tool to quantitatively examine zebrafish larvae’s movements in response to physical and chemical stimulations in investigations of Parkinson’s and other neurodegenerative diseases, and as a tool to combine recent advances in genome engineering of model organisms to uncover the biology of electric response.
Pannexin 1 (Panx1) forms ATP-permeable membrane channels that play roles in the nervous system. The analysis of roles in both standard and pathological conditions benefits from a model organism with rapid development and early onset of behaviors. Such a model was developed by ablating the zebrafish panx1a gene using TALEN technology. Here, RNA-seq analysis of 6 days post fertilization larvae were confirmed by Real-Time PCR and paired with testing visual-motor behavior and in vivo electrophysiology. Results demonstrated that loss of panx1a specifically affected the expression of gene classes representing the development of the visual system and visual processing. Abnormal swimming behavior in the dark and the expression regulation of pre-and postsynaptic biomarkers suggested changes in dopaminergic signaling. Indeed, altered visuomotor behavior in the absence of functional Panx1a was evoked through D1/D2-like receptor agonist treatment and rescued with the D2-like receptor antagonist Haloperidol. Local field potentials recorded from superficial areas of the optic tectum receiving input from the retina confirmed abnormal responses to visual stimuli, which resembled treatments with a dopamine receptor agonist or pharmacological blocking of Panx1a. We conclude that Panx1a functions are relevant at a time point when neuronal networks supporting visualmotor functions undergo modifications preparing for complex behaviors of freely swimming fish. Pannexin 1 (Panx1) is an integral membrane glycoprotein forming ATP release channels in different tissues and cell types 1-5 , including neurons 6-8. In the CNS, evidence for physiological functions of Panx1 points at roles in the processing of sensory signals and learning and memory 9-11. For example, in Panx1 knockout mice, altered retinal contrast sensitivity 12 and hearing loss have been found 13,14. Also, performance in spatial learning and memory abilities such as object recognition and fear conditioning tasks are decreased 9,15,16. Intellectual disabilities, severe hearing loss, primary ovarian failure, kyphoscoliosis, and difficulties navigating in darkness were found in the first human patient identified with a homozygous Panx1 mutation 17. To form a better view of Panx1 functions in the processing of sensory information, we used the zebrafish as model organisms. Two Panx1 genes, panx1a and panx1b, originated from partial genome duplications during early teleost evolution 18,19. Although the two genes have been separated for more than 200 million years, principal channel functions are comparable to rodent or human Panx1 20. In the retina, the panx1a protein is expressed in horizontal cells 19,20 and plays essential roles in feedback from horizontal cells to cones in adult zebrafish 21-23. Here the panx1a gene was edited using transcription activator-like effector nucleases (TALEN). A loss of function mutation allowed to investigate Panx1a in 6 dpf old zebrafish larvae at a developmental stage when neuronal networks for visually guided locomotor behaviors were functional...
The molecular mechanisms of excitation/inhibition imbalances promoting seizure generation in epilepsy patients are not fully understood. Evidence suggests that Pannexin1 (Panx1), an ATP release channel, modulates the excitability of the brain. In this report, we performed electrophysiological, behavioral, and molecular phenotyping experiments on zebrafish larvae bearing genetic or pharmacological knockouts of Panx1a and Panx1b channels, each homologous to human PANX1. When Panx1a function is lost, or both channels are under pharmacological blockade, seizures with ictal-like events and seizure-like locomotion are reduced in the presence of pentylenetetrazol. Transcriptome profiling by RNA-seq demonstrates a spectrum of distinct metabolic and cell signaling states which correlate with the loss of Panx1a. Furthermore, the pro- and anticonvulsant activities of both Panx1 channels affect ATP release and involve the purinergic receptor P2rx7. Our findings suggest a subfunctionalization of Panx1 enabling dual roles in seizures, providing a unique and comprehensive perspective to understanding seizure mechanisms in the context of this channel.
Pannexin1 (Panx1) can form ATP-permeable channels that play roles in the physiology of the visual system. In the zebrafish two ohnologs of Panx1, Panx1a and Panx1b, have unique and shared channel properties and tissue expression patterns. Panx1a channels are located in horizontal cells of the outer retina and modulate light decrement detection through an ATP/pH-dependent mechanisms and adenosine/dopamine signaling. Here, we decipher how the strategic localization of Panx1b channels in the inner retina and ganglion cell layer modulates visually evoked motor behavior. We describe a panx1b knockout model generated by TALEN technology. The RNA-seq analysis of 6 days post-fertilization larvae is confirmed by real-time PCR and paired with testing of locomotion behaviors by visual motor and optomotor response tests. We show that the loss of Panx1b channels disrupts the retinal response to an abrupt loss of illumination and it decreases the larval ability to follow leftward direction of locomotion in low light conditions. We concluded that the loss of Panx1b channels compromises the final output of luminance as well as motion detection. The Panx1b protein also emerges as a modulator of the circadian clock system. The disruption of the circadian clock system in mutants suggests that Panx1b could participate in non-image forming processes in the inner retina.
Pannexin1 (Panx1) can form ATP-permeable integral membrane channels that play roles in the physiology of the visual system. Two independent gene copies of Panx1, panx1a and panx1b, have been identified in the zebrafish with unique and shared properties and tissue expression patterns. Panx1a channels, located in horizontal cells of the outer retina, modulate light decrement detection through an ATP/pH-dependent mechanisms and adenosine/dopamine signaling. Here, we decipher how the strategic localization of Panx1b channels in the inner retina and ganglion cell layer modulates visually evoked motor behavior. We describe a panx1b knockout model generated by TALEN technology. The RNA-seq analysis of 6 days post-fertilization larvae is confirmed by Real-Time PCR and paired with testing of visual-motor behaviors. The Panx1b protein emerges as a modulator of the circadian clock system. The loss of panx1b also disrupts the retinal response to the abrupt loss of illumination and decreases the larval ability to follow leftward direction of motion in the dark. The evidence suggests that in the retina Panx1b contributes to the OFF pathways function, like Panx1a, though through different signaling mechanisms. In this process, the loss of Panx1b channels compromises the final output of luminance as well as direction of motion detector RGCs. In addition, the disruption of the circadian clock system in mutants suggests that Panx1b could participate in non-image forming processes in the inner retina.
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