Application of the Magnet-Cre optogenetic system in the chicken model

Chickens serve as an excellent model organism for developmental biology, offering unique opportunities for precise spatiotemporal access to embryos within eggs. Optogenes are light-activated proteins that regulate gene expression, offering a non-invasive method to activate genes at specific locations and developmental stages, advancing developmental biology research. This study employed the Magnet-Cre optogenetic system to control gene expression in developing chicken embryos. Magnet-Cre consists of two light-sensitive protein domains that dimerize upon light activation, each attached to an inactive half of the Cre recombinase enzyme, which becomes active upon dimerization. We developed an all-in-one plasmid containing a green fluorescent protein marker, the Magnet-Cre system, and a light-activated red fluorescent protein gene. This plasmid was electroporated into the neural tube of Hamburger and Hamilton (H&H) stage 14 chicken embryos. Embryo samples were cleared using the CUBIC protocol and imaged with a light sheet microscope to analyze optogenetic activity via red-fluorescent cells. We established a pipeline for Magnet-Cre activation in chicken embryos, demonstrating that a single 3-min exposure to blue light following incubation at 28 °C was sufficient to trigger gene activity within the neural tube, with increased activity upon additional light exposure. Finally, we showed a spatiotemporal control of gene activity using a localized laser light induction. This research lays the groundwork for further advancements in avian developmental biology and poultry research, enabling spatiotemporal control of genes in both embryos and transgenic chickens.