Kanae Hiyoshi scite author profile

Optical measurement of membrane potentials enables fast, direct and simultaneous detection of membrane potentials from a population of neurons, providing a desirable approach for functional analysis of neuronal circuits. Here, we applied recently developed genetically encoded voltage indicators, ASAP1 (Accelerated Sensor of Action Potentials 1) and QuasAr2 (Quality superior to Arch 2), to zebrafish, an ideal model system for studying neurogenesis. To achieve this, we established transgenic lines which express the voltage sensors, and showed that ASAP1 is expressed in zebrafish neurons. To examine whether neuronal activity could be detected by ASAP1, we performed whole-cerebellum imaging, showing that depolarization was detected widely in the cerebellum and optic tectum upon electrical stimulation. Spontaneous activity in the spinal cord was also detected by ASAP1 imaging at single-cell resolution as well as at the neuronal population level. These responses mostly disappeared following treatment with tetrodotoxin, indicating that ASAP1 enabled optical measurement of neuronal activity in the zebrafish brain. Combining this method with other approaches, such as optogenetics and behavioural analysis may facilitate a deeper understanding of the functional organization of brain circuitry and its development.

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Two-Photon Laser Ablation and In Vivo Wide-Field Imaging of Inferior Olive Neurons Revealed the Recovery of Olivocerebellar Circuits in Zebrafish

Hiyoshi

Saito

Fukuda

et al. 2021

IJERPH

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The cerebellum, a brain region with a high degree of plasticity, is pivotal in motor control, learning, and cognition. The cerebellar reserve is the capacity of the cerebellum to respond and adapt to various disorders via resilience and reversibility. Although structural and functional recovery has been reported in mammals and has attracted attention regarding treatments for cerebellar dysfunction, such as spinocerebellar degeneration, the regulatory mechanisms of the cerebellar reserve are largely unidentified, particularly at the circuit level. Herein, we established an optical approach using zebrafish, an ideal vertebrate model in optical techniques, neuroscience, and developmental biology. By combing two-photon laser ablation of the inferior olive (IO) and long-term non-invasive imaging of whole-brain imaging at a single-cell resolution, we succeeded in visualization of the morphological changes occurring in the IO neuron population and showed at a single-cell level that structural remodeling of the olivocerebellar circuit occurred in a relatively short period. This system, in combination with various functional analyses, represents a novel and powerful approach for uncovering the mechanisms of the cerebellar reserve, and highlights the potential of the zebrafish model to elucidate the organizing principles of neuronal circuits and their homeostasis in health and disease.

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In vivo wide‐field voltage imaging in zebrafish with voltage‐sensitive dye and genetically encoded voltage indicator

et al. 2021

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Unraveling the function of brain circuitry is fundamental to understanding how the brain works during various behavioral conditions. A challenge is to define how populations of neurons within brain circuits communicate with each other to yield a network function. Recent advances in optical techniques have provided powerful tools to analyze organizing principles and the development of neuronal circuits. Prominent examples include optical measurements and control of neuronal activity known as optogenetic (Boyden et al., 2005;Lin & Schnitzer, 2016;Mancuso et al., 2011;Yizhar et al., 2011). These approaches have expanded the functional analysis of neuronal populations, which were previously analyzed mainly using electrophysiological recordings. For example, compared with electrophysiological detection, which records a limited number of neurons, optical approaches help analyze spatiotemporal dynamics from a large number of neurons.

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4D imaging identifies dynamic migration and the fate of gbx2-expressing cells in the brain primordium of zebrafish

Tsuda

Hiyoshi

Miyazawa

et al. 2019

Neuroscience Letters

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In Vivo Optical Detection of Membrane Potentials in the Cerebellum: Voltage Imaging of Zebrafish

Hiyoshi¹,

Fukuda²,

Shiraishi³

et al. 2022

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Kanae Hiyoshi

Optical interrogation of neuronal circuitry in zebrafish using genetically encoded voltage indicators

Two-Photon Laser Ablation and In Vivo Wide-Field Imaging of Inferior Olive Neurons Revealed the Recovery of Olivocerebellar Circuits in Zebrafish

In vivo wide‐field voltage imaging in zebrafish with voltage‐sensitive dye and genetically encoded voltage indicator

4D imaging identifies dynamic migration and the fate of gbx2-expressing cells in the brain primordium of zebrafish

In Vivo Optical Detection of Membrane Potentials in the Cerebellum: Voltage Imaging of Zebrafish

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