[Advances in methods for analyzing IP3 signaling and understanding of coupled Ca2+ and IP3 oscillations].

ABSTRACT

Inositol 1,4,5-trisphosphate (IP3) is an important intracellular messenger produced by phospholipase C via the activation of G-protein-coupled receptor- or receptor-tyrosine-kinase-mediated pathways, and is involved in numerous responses to hormones, neurotransmitters, and growth factors through the releases of Ca2+ from intracellular stores via IP3 receptors. IP3-mediated Ca2+ signals often exhibit complex spatial and temporal organizations, such as Ca2+ oscillations. Recently, new methods have become available to measure IP3 concentration ([IP3]) using AlphaScreen technology, fluorescence polarization, and competitive ligand binding assay (CFLA). These methods are useful for the high throughput screening in drug discovery. Calcium ions generate versatile intracellular signals such as Ca2+ oscillations and waves. Fluorescent sensors molecules to monitor changes in [IP3] in single living cells are crucial to study the mechanism for the spatially and temporally regulated Ca2+ signals. In particular, FRET-based IP3 sensors are useful for the quantitative monitoring intracellular [IP3], and allowed to uncovered the oscillatory IP3 dynamics in association with Ca2+ oscillations. A mathematical model of coupled Ca2+ and IP3 oscillations predicts that Ca2+ oscillations are the result of modulation of the IP3 receptor by intracellular Ca2+, and that the period is modulated by the accompanying IP3 oscillations. These model predictions have also been confirmed experimentally. At present, however, usefulness of FRET-based IP3 sensors are limited by their relatively small change in fluorescence. Development of novel IP3 sensors with improve dynamic range would be important for understanding the regulatory mechanism of Ca2+ signaling and for in vivo IP3 imaging.