Intercellular Ca(2+) waves: mechanisms and function - PubMed (original) (raw)
Review
Intercellular Ca(2+) waves: mechanisms and function
Luc Leybaert et al. Physiol Rev. 2012 Jul.
Abstract
Intercellular calcium (Ca(2+)) waves (ICWs) represent the propagation of increases in intracellular Ca(2+) through a syncytium of cells and appear to be a fundamental mechanism for coordinating multicellular responses. ICWs occur in a wide diversity of cells and have been extensively studied in vitro. More recent studies focus on ICWs in vivo. ICWs are triggered by a variety of stimuli and involve the release of Ca(2+) from internal stores. The propagation of ICWs predominately involves cell communication with internal messengers moving via gap junctions or extracellular messengers mediating paracrine signaling. ICWs appear to be important in both normal physiology as well as pathophysiological processes in a variety of organs and tissues including brain, liver, retina, cochlea, and vascular tissue. We review here the mechanisms of initiation and propagation of ICWs, the key intra- and extracellular messengers (inositol 1,4,5-trisphosphate and ATP) mediating ICWs, and the proposed physiological functions of ICWs.
Figures
Figure 1.
Examples of intercellular Ca2+ waves (ICWs) in cell cultures. A: an ICW in C6 glioma cells transduced to express the gap junction connexin, connexin (Cx) 26. The ICW was initiated by the focal photolytic release of inositol 1,4,5-trisphosphate (IP3) within a cell (panel 2s) at the location indicated by the star symbol. B: an ICW in rat brain endothelial cells (endogenously expressing Cx37 and Cx43) induced by exposure of the cells to extracellular Ca2+-free conditions. Dimension bars = 50 μm. Color bar indicates change in fluorescence level. An increase in fluorescence represents an increase in [Ca2+]i. Sample time of each panel is indicated in seconds.
Figure 2.
Basic mechanisms driving a diffusive Ca2+ wave across a cell (either initiating or communicating the wave; see sect. III). Inositol 1,4,5-trisphosphate (IP3) diffuses across the cell and binds to an IP3 receptor (IP3R) to stimulate Ca2+ release from the endoplasmic reticulum (ER). The positive feedback (+ve) of Ca2+ on the IP3R initiates Ca2+-induced Ca2+ release (CICR) through the IP3R. The elevated [Ca2+]i has a negative feedback (−ve) on the IP3R to terminate CICR and limit the [Ca2+]i increase. Some Ca2+ may diffuse to adjacent ryanodine receptors (RyR) to initiate CICR via these receptors. However, IP3 diffusion occurs more quickly than Ca2+ diffusion (due to cytosol protein buffers) and propagates the Ca2+ wave more efficiently. IP3 may have been produced in response to cell stimulation or may have entered the cell via a gap junction.
Figure 3.
Overall hypothesis for the communication of ICWs. Local stimulation (see sect. II) can lead to elevated IP3 in the initiator cell. As IP3 diffuses across this cell, it generates an intracellular Ca2+ wave by the release of Ca2+ through IP3Rs with amplification from RyRs. Diffusion of IP3 through a gap junction to an adjacent cell initiates a second intracellular Ca2+ wave, via IP3Rs and RyRs. In addition, or alternatively, the stimulated cell releases ATP (in either a Ca2+-dependent or -independent manner) via plasma membrane channels (hemichannels, maxi-anion channels) or vesicular release. The extracellular diffusion of ATP (or other messengers; see sect. IV_B4_) to adjacent cells activates P2 receptors which, in turn, stimulate IP3 production to generate a Ca2+ signal in the adjacent cell. Propagation may involve the regenerative release of ATP (see sect. VI_B_). Each mechanism can occur in isolation or synergistically.
Figure 4.
Overview of mechanisms and functions of intercellular Ca2+ waves (ICWs), based on ex vivo and in vivo evidence from the organs indicated. ICWs between cells of the same type are indicated by circular arrows; noncircular arrows indicate ICWs between different cell types. Gap junctions (GJs) and paracrine purinergic signaling (PPS) are involved in most cases, but only the most prevalent mechanism is depicted. Dashed arrows indicate proposed functions (in italics). Retina: ICWs that propagate in astrocytes and Müller cells may provoke electrical activity in retinal ganglion cells (RGCs) and influence the blood vessel caliber. Retinal pigment epithelium cells (RPE) show ICWs which may influence proliferation and differentiation of neural progenitor cells (NPCs). Cochlea: ICWs in supporting cells may be involved in K+ recycling and may influence outer hair cells (OHCs) via ATP release to alter the cochlear amplifier gain and inner hair cells (IHCs) to modify electrical activity and synaptic connectivity during development. Blood vessels: ICWs propagate along the vessel wall via endothelial cells (ECs) and modulate white blood cell (WBC) interactions with ECs as well as smooth muscle cell (SMC) contractility via direct (myoendothelial gap junctions) or indirect mechanism to control vessel diameter. Brain: mechanisms of ICW propagation differ with brain region; GJs, GJs+PPS, or PPS mediate ICWs in the neocortex, hippocampus, and corpus callosum and Bergman glia, respectively. ICWs of astrocytes propagate via astrocyte endfeet to small-diameter blood vessels to influence blood vessel diameter. ICWs of astrocytes may also modulate synaptic signaling as well as contribute to neural development or disease processes (AD, Alzheimer disease; CSD, cortical spreading depression). Liver: ICWs propagating between hepatocytes may influence hepatic glucose output, bile production, and tissue regeneration.
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