The crux of the proposed project was based on having access to efficient optogenetic actuators. For this reason, I have performed an in-depth characterisation and calibration of most opsin excitatory and inhibitory transgenic lines. This work represents the first in vivo calibration of optogenetic tools with precise electrophysiological methods and has been published earlier in 2020 in Elife. The unexpected complexity of the calibration of the optogenetic methods, delayed the start of data collection to directly address our original aims. However, these questions were in fact addressed by other colleagues in the field via three recent and standout publications from the McLean, El Manira and Koyama lab [1-3].
[1] Pujala A, Koyama M. Chronology-based architecture of descending circuits that underlie the development of locomotor repertoire after birth. Elife 2019;8.
[2] Menelaou E, McLean DL. Hierarchical control of locomotion by distinct types of spinal V2a interneurons in zebrafish. Nat Commun 2019;10:4197.
[3] Song J, Pallucchi I, Ausborn J, Ampatzis K, Bertuzzi M, Fontanel P, et al. Multiple Rhythm-Generating Circuits Act in Tandem with Pacemaker Properties to Control the Start and Speed of Locomotion. Neuron 2020;105:1048–61.e4.