Volume 33 reviews the current understanding of ion channel regulation by signal transduction pathways. Ion channels are no longer viewed simply as the voltage-gated resistors of biophysicists or the ligand-gated receptors of biochemists. They have been transformed during the past 20 years into signaling proteins that regulate every aspect of cell physiology. In addition to the voltage-gated channels, which provide the ionic currents to generate and spread neuronal activity, and the calcium ions to trigger synaptic transmission, hormonal secretion, and muscle contraction, new gene families of ion channel proteins regulate cell migration, cell cycle progression, apoptosis, and gene transcription, as well as electrical excitability. Even the genome of the lowly roundworm Caenorhabditis elegans encodes almost 100 distinct genes for potassium-selective channels alone. Most of these new channel proteins are insensitive to membrane potential, yet in humans, mutations in these genes disrupt development and increase individual susceptibility to debilitating and lethal diseases.
How do cells regulate the activity of these channels? How might we restore their normal function? In Ion Channel Regulation, many of the experts who pioneered these discoveries provide detailed summaries of our current understanding of the molecular mechanisms that control ion channel activity.
Key Features
* Reviews brain functioning at the fundamental, molecular level
* Describes key systems that control signaling between and within cells
* Explains how channels are used to stimulate growth and changes to activity of the nucleus and genome

Volume 30 examines the prominent role of calcium as an intracellular second messenger. Leading investigators review a wide variety of studies on how calcium enters and moves through cells, how it interacts with its many binding proteins, and how calcium and its intracellular receptor, calmodulin, control vital cellular processes. Coverage includes a detailed analysis of the mechanisms by which calcium bound to calmodulin regulates contractile proteins in smooth muscle cells. Close attention is given to the roles of calcium and calmodulin-dependent protein kinases and phosphatases in synaptic signal transduction, protein synthesis, gene expression, programmed cell death, activation of T-lymphocytes, and control of cell division cycles. Other chapters discuss studies using genetically manipulable nonmammalian organisms to further proble the functions of calcium and calmodulin.

This volume contains papers presented at the Ninth International Conference on Second Messengers and Phosphoproteins. Written by leading scientists - including two Nobel Laureates - the papers highlight contemporary advances in the rapidly evolving field of signal transduction. The findings presented are of vital significance to researchers in virtually all biomedical fields, including pharmacology, molecular biology, cell biology, biochemistry, the neurosciences, and physiology.
The contributors offer new insights into fundamental cell signalling mechanisms and explore the role of these mechanisms in physiological and pathophysiological responses in a variety of systems. Coverage includes many topics that are currently under intensive study, such as growth factors and special signalling systems; protein phosphatases and metabolic pathways; calcium and ion channels; cyclic GMP and cyclic AMP; and receptors and G proteins.