Molecular and Biophysical Mechanisms of Ca2+ Sparklets in Smooth Muscle

Overview

Journal J Mol Cell Cardiol

Specialty Cardiology & Vascular Diseases

Date 2009 Jul 21

PMID 19616004

Citations 24

Authors

Luis F Santana

Manuel F Navedo

Affiliations

Soon will be listed here.

Abstract

In this article, we review the biophysical basis and functional implications of a novel Ca(2+) signal (called "Ca(2+) sparklets") produced by Ca(2+) influx via L-type Ca(2+) channels (LTCCs) in smooth muscle. Ca(2+) sparklet activity is bimodal. In low activity mode, Ca(2+) sparklets are produced by random, brief openings of solitary LTCCs. In contrast, small clusters of LTCCs can function in a high activity mode that creates sites of continual Ca(2+) influx called "persistent Ca(2+) sparklets". Low activity and persistent Ca(2+) sparklets contribute to Ca(2+) influx in arterial, colonic, and venous smooth muscle. Targeting of PKCalpha by the scaffolding protein AKAP150 to specific sarcolemmal domains is required for the activation of persistent Ca(2+) sparklets. Calcineurin, which is also associated with AKAP150, opposes the actions of PKCalpha on Ca(2+) sparklets. At hyperpolarized potentials, Ca(2+) sparklet activity is low and hence does not contribute to global [Ca(2+)](i). Membrane depolarization increases low and persistent Ca(2+) sparklet activity, thereby increasing local and global [Ca(2+)](i). Ca(2+) sparklet activity is increased in arterial myocytes during hypertension, thus increasing Ca(2+) influx and activating the transcription factor NFATc3. We discuss a model for subcellular variations in Ca(2+) sparklet activity and their role in the regulation of excitation-contraction coupling and excitation-transcription coupling in smooth muscle.

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