Optogenetic Perturbation of Neural Activity with Laser Illumination in Semi-intact Drosophila Larvae in Motion

Temporal and local perturbation of neural activity is an invaluable technique for analyzing the network dynamics of neural circuits. In this protocol, we present a method to manipulate neural activity by optogenetics using a laser. The laser’s high directionality allows more localized optogenetic stimulation than wide field stimulation using mercury or Xenon lamp. Though laser illuminations have already been applied to optogenetics in previous studies, special setups such as glass fiber, micromanipulator, and laser source, are required in most previous studies. In this protocol, we use a conventional confocal microscopy for local illumination. Since the confocal microscope system is widely used, this method will open the opportunity to apply higher resolution optogenetics in many labs.

The protocol has two critical points: larval dissection and laser power. Firstly, if the brain, the ventral nerve cord or a motor nerve is damaged during dissection, the larvae will exhibit less or none spontaneous peristaltic motion. Precision is therefore essential, especially when making an incision on the dorsal side with spring scissors and removing internal organs with forceps. Details about the dissection have been reported previously²¹. Secondly, if sufficient stimulation is to be achieved, a laser power of about 0.1~1 mW/ mm² for ChR2 or 1~10 mW/mm² for NpHR is required. We evaluated the laser power as total light power below an objective lens divided by an estimated area of illumination. We measured the total light power using a power meter (mobiken, Sanwa M.I. Technos, Japan). We estimated the area of illumination as circular constant times the square of the wave length of the laser, which roughly gives illuminated area in diffraction limit. Effective illumination power on the sample can be adjusted not only by the power of the laser output, but also by changing the scanning speed and number of repetitions. We scanned laser with 20-100 μsec/pixel for 63 times. In addition, the expression level of optogenetics protein and the amount of ATR are also critical for stimulation efficiency. Accordingly, if larvae showed no optogenetic response, the following points should be checked and corrected: 1) laser power (by optimizing microscope system), 2) expression level of optogenetics protein (by checking genotype and rearing temperature), and 3) amount of ATR (by adjusting concentration of ATR and feeding period). NpHR requires higher concentration of ATR than ChR2 does by unknown reasons ¹³. ChR2 works well in larvae reared in food containing lesser ATR (e.g. 0.1 mM) than described here (1 mM). As feeding larvae to 1 mM ATR is sufficient for making ChR2 photo-reactive, we recommend this concentration for the first trial in ChR2 experiments. The concentration of ATR can subsequently be titrated down from 1 mM. As to exposure duration for ATR, we recommend the duration described here for robust optogenetic control. We often failed to observe optogenetic response when feeding larvae to ATR for shorter duration.

In this protocol, laser illumination and image acquisition are operated by a separate computer. So, clear detection of spatiotemporal pattern of laser illumination by CCD camera is critical for data analysis. If laser spot or line is dim on CCD image, you should optimize the power of halogen lamp and gain value of the CCD camera to visualize the laser illumination while keeping body wall visible.

Spatiotemporal illumination shown in this protocol provides information on larval motor circuits; however, the method has some limitations. As to the “spatial” aspect, location of the illumination is recorded by low magnification CCD image used for videotaping body wall movements. Accordingly, illumination area can be assigned at segment level, but not at cellular level. As to the “temporal” aspect, time lag between switching on the laser scan by confocal microscope and illumination by laser depends on the confocal microscope system and scanning condition. Consequently, some testing by trial and error is required to adjust illumination timing. Since the timing of illumination can be determined in CCD image movies using adequate software like ImageJ, the critical factor in temporal resolution is frame rate of CCD camera imaging. We typically set the frame rate for 7.5-15 frames per second.

Advances in optogenetic tools provide us a chance to modify this protocol. We used 3^rd instar larvae possessing OK6-Gal4 and UAS-ChR2[H134R] or UAS-NpHR2. Other optogenetic tools instead of ChR2[H134R] or NpHR2 such as ChR2[T159C/E123T], NpHR3 or Arch can boost the efficiency of the activity control²². In addition, using other gal4 lines or analyzing in other developmental stages can provide more information about the motor circuits.

In this protocol, motor activity was monitored by transmission images of the bodywall contraction with a CCD camera. The activity of motor neurons with calcium-sensitive fluorescence molecules (e.g. GCaMP) can also be directly monitored while manipulating neural activity with ChR2 or NpHR. In this case, blue light illumination in a broad area and a highly sensitive CCD camera (e.g. EMCCD camera) are used instead of a halogen lamp and the normal CCD camera previously described herein. To improve spatial resolution of stimulation while monitoring bodywall movement, using an additional objective lens may be a more advanced method: illumination of the ventral nerve cord by a high magnification objective lens (e.g. 40x) from above the sample and monitoring bodywall by low magnification lens (e.g. 4x) below the sample. This dual lens system may allow us to stimulate nervous system in higher spatial resolution.

The protocol shown here can be applied to other neural circuits, provided optogenetic tools can be expressed in the nervous system and preparation in which sufficient light can be delivered into the neural tissue can be established.