We have extensively studied the morphological and physiological changes of zebrafish MG over their development which has allowed us to categorise these cells into at least six progressive stages. These studies have indicated that, topographically, retinal glia have at least five independent regions (apical foot process, inner plexiform processes, soma region, outer plexiform processes, and the basal end foot process) each developing independently during different temporal windows.
We conducted transcriptomics on each defining stage of MG development and identified the genetic programs that give rise to each of the defining features (topographical regions) of these cell morphologies. These large transcriptomic databases serve as blueprints of the cell-specific differentiation process.
Recent advances in CRISPR technology that we and others have made have allowed us to use this dataset to conduct large-scale reverse genetic screens and for the first time test the functions of these differentiation factors in-mass. To date, we have screened over 130 genes using this approach and identified morphological defects in all MG compartments. Thus, we have developed a novel strategy for identifying distinct genetic pathways that drive morphological differentiation events that can experimentally be validated.
In combination with our current reverse genetic approaches, these studies will give us tremendous insights into a currently undefined area of glial biology. The implications of this research also provide novel insights into cellular evolution and have the potential to impact studies on many neural disease-related genes.