1. Mount Larvae for Behavior Experiments
<ol>
	<li>Make 1.5% low melt agarose in ddH2O and store in a 42 &#176;C heat block to prevent it from solidifying.</li>
	<li>Using a glass Pasteur pipette, transfer one of the pre-screened larvae into a tube of 1.5% low melt agarose with as little blue/embryo water as possible.</li>
	<li>Transfer larvae in a drop of agarose onto a small Petri dish.</li>
	<li>Under a dissecting microscope, position larva dorsal up.</li>
	<li>When agarose has solidified, cut away ...

zebrafish optogenetics: activating genetically modified somatosensory neuron to study larval behavioral responses

Source: Palanca A. M. S., et al. <a href="https://www.jove.com/v/50184/" target="_blank">Optogenetic Activation of Zebrafish Somatosensory Neurons using ChEF-tdTomato</a>. J. Vis. Exp. (2013).
This video describes optogenetic techniques by activating genetically modified somatosensory neurons and recording elicited behavioral response with a high-speed video camera.

<img alt="Figure 1" class="xfigimg" src="/files/ftp_upload/20189/20189fig1.jpg" /> 
Figure 1. Diagram of a mounted zebrafish larva and representative neurons involved in the larval touch response. Zebrafish larvae were partially mounted in 1.5% low melt agarose (represented by dashed lines surrounding the rostral portion of the larva). A trigeminal neuron (in the head) and a Rohon-Beard neuron (in the trunk) are depicted in red. Mauthner cells are outlined by dashed lines in the larva. The optic cab...

Zebrafish Optogenetics: Activating Genetically Modified Somatosensory Neuron to Study Larval Behavioral Responses

Source: Palanca A. M. S., et al. Optogenetic Activation of Zebrafish Somatosensory Neurons using ChEF-tdTomato. J. Vis. Exp. (2013).
This video describes ...

- In zebrafish larvae, a visual stimulus can activate somatosensory neurons and trigger an escape response. There are two types of such neurons found in the larva, trigeminal and Rohon-Beard neurons. We can manipulate the activity of these neurons by modifying them to express transgenic light-sensitive ion channels. This approach is called optogenetics.
To perform this technique, mount a transgenic larva with the dorsal side facing up in agarose gel and place it under a dissecting microscope. Use a razor blade to detach a wedge-shaped portion of agarose from around the yolk and tail. Fill this area with egg water. Pull the agarose away from the trunk and tail of the larva.
Position the tip of an optic cable near the trunk where the cell body of the Rohon-Beard neuron is located. Deliver a pulse of blue laser light. Upon exposure to the blue light, the transgenic light-sensitive ion channels in the neuron&#39;s membrane open, allowing ions to enter, triggering an action potential that elicits the escape response. Record the larva&#39;s behavior using a high-speed camera.
In the example protocol, we will mount the larvae to activate the Rohon-Beard neuron, expressing a channelrhodopsin variant and observe the behavioral response.
- Make 1.5% low-melt agarose in double-distilled water and store in a 42 degrees Celsius heat block to prevent it from solidifying. Using a glass Pasteur pipette, transfer one of the prescreen larvae into a tube of 1.5% low-melt agarose with as little blue embryo water as possible. Then transfer the larva in a drop of agarose onto a small Petri dish.
Under a dissecting microscope, position the larva dorsal side up. When the agarose is solidified, use a thin razor blade to cut away agarose from both sides of the larva. Fill the area surrounding the agarose with embryo blue water.
Next, make two diagonal cuts of both sides of the yolk, being careful not to nick the larva. Afterwards, pull the agarose away from the trunk and the tail of the larva.
Now mount the high-speed camera onto the dissecting scope and connect the camera to the computer. Then turn on the computer and the high-speed camera. Open the video imaging software and adjust the camera settings. Next, connect the optic cable, the laser, and the stimulator together. Then turn on the stimulator and set it to a maximum of 5 volts and a pulse duration of 5 milliseconds. Subsequently, turn on the laser.
Next, use the fluorescent dissecting microscope to position the tip of the optic cable near a neuron cell body with ChEF-tdTomato expression. Deliver a pulse of blue light to activate the sensory neuron. Then record the responses using a high-speed camera set at 500 or 1,000 frames per second and repeat the experiments with at least 1 minute between activations to avoid habituation.
To release the larva, pry apart the agarose with forceps and be careful not to injure the animal. Then transfer it into fresh blue embryo water. The animals can be allowed to develop further, and the procedure can be repeated at older stages. The embryo could also be remounted for high-resolution confocal imaging of the activated cell in order to correlate the behavior with cellular structure.

zebrafish-optogenetics-activating-genetically-modified-somatosensory

Research

JoVE Encyclopedia of Experiments

Biology

Danio rerio (zebrafish)

Larva

This video describes optogenetic techniques by activating genetically modified somatosensory neurons and recording elicited behavioral response with a high-speed video camera.

Overview

Protocol

<img title="figure-representative results-25" alt="figure-representative results-25" class="xfigimg" src="/files/ftp_upload/20189/20189fig1.jpg" /> 
Figure 1. Diagram of a mounted zebrafish larva and representative neurons involved in the larval touch response. Zebrafish larvae were partially mounted in 1.5% low melt agarose (represented by dashed lines surrounding the rostral portion of the larva). A trigeminal neuron (in the head) and a Rohon-Beard neuron (in the trunk) are depicted in red. Mauthner cells are outlined by dashed lines in the larva. The optic cab...

Zebrafish Optogenetics: Activating Genetically Modified Somatosensory Neuron to Study Larval Behavioral Responses

In This Article

Overview

Protocol

Representative Results