Curated Optogenetic Publication Database

Abstract: Morphogenesis of multicellular organisms is driven by changes in cell behavior, which happen at precise locations and defined developmental stages. Therefore, the studying of morphogenetic events would greatly benefit from tools that allow the perturbation of cell activity with spatial and temporal precision. We recently developed an optogenetic approach to modulate cell contractility with cellular precision and on fast (seconds) timescales during Drosophila embryogenesis. We present here a protocol to handle genetically engineered photosensitive Drosophila embryos and achieve light-mediated inhibition of apical constriction during tissue invagination. The possibility to modulate the levels of optogenetic activation at different laser powers makes this method suited also for studying how mechanical stresses are sensed and interpreted in vivo. Given the conserved function of cell contractility during animal development, the application of this method to other morphogenetic processes will facilitate our understanding of tissue mechanics and cell-cell interaction during morphogenesis.

Abstract: Optogenetics is an emerging and powerful technique that allows the control of protein activity with light. The possibility of inhibiting or stimulating protein activity with the spatial and temporal precision of a pulse of laser light is opening new frontiers for the investigation of developmental pathways and cell biological bases underlying organismal development. With this powerful technique in hand, it will be possible to address old and novel questions about how cells, tissues, and organisms form. In this review, we focus on the applications of existing optogenetic tools for addressing issues in animal morphogenesis.

Abstract: Morphogenesis of multicellular organisms is driven by localized cell shape changes. How, and to what extent, changes in behavior in single cells or groups of cells influence neighboring cells and large-scale tissue remodeling remains an open question. Indeed, our understanding of multicellular dynamics is limited by the lack of methods allowing the modulation of cell behavior with high spatiotemporal precision. Here, we developed an optogenetic approach to achieve local modulation of cell contractility and used it to control morphogenetic movements during Drosophila embryogenesis. We show that local inhibition of apical constriction is sufficient to cause a global arrest of mesoderm invagination. By varying the spatial pattern of inhibition during invagination, we further demonstrate that coordinated contractile behavior responds to local tissue geometrical constraints. Together, these results show the efficacy of this optogenetic approach to dissect the interplay between cell-cell interaction, force transmission, and tissue geometry during complex morphogenetic processes.