Measuring voltage and ion concentrations in live embryos

Abstract Homeostasis of charged particles in biological systems is fundamental for life. Indeed, the efficient synthesis of ATP is predicated on an electrochemical gradient. Ion pumps and channels act as conduits that regulate membrane potential by controlling ion flux. This phenomenon is critical for the generation of action potentials in excitable cells such as neurons and muscle fibers, and for acidification of lysosomes in all cells. However, the production of action potentials or pH differentials is merely one facet of bioelectricity. Increasing evidence has shown that ion channels and pumps also play critical roles in other cellular processes: cell cycle regulation, wound healing, regeneration, and symmetry breaking during development. In recent years, the functional roles of ion channels have been explored in echinoderm development. The application of fluorescence-based ion- and voltage-sensitive dyes allows for live measurements of ion concentrations with both spatial and temporal resolution. In this chapter, we describe the use of such dyes for interrogating and visualizing ion and voltage gradients in sea urchin embryos.