Ca2+ is a highly versatile intracellular signal that operates over a wide temporal range to regulate many different cellular processes. An extensive Ca2+-signalling toolkit is used to assemble signalling systems with very different spatial and temporal dynamics. Rapid highly localized Ca2+ spikes regulate fast responses, whereas slower responses are controlled by repetitive global Ca2+ transients or intracellular Ca2+ waves. Ca2+ has a direct role in controlling the expression patterns of its signalling systems that are constantly being remodelled in both health and disease.

The universality of calcium as an intracellular messenger depends on its enormous versatility. Cells have a calcium signalling toolkit with many components that can be mixed and matched to create a wide range of spatial and temporal signals. This versatility is exploited to control processes as diverse as fertilization, proliferation, development, learning and memory, contraction and secretion, and must be accomplished within the context of calcium being highly toxic. Exceeding its normal spatial and temporal boundaries can result in cell death through both necrosis and apoptosis.

Extracellular-signal-regulated kinases (ERKs) are emerging as important regulators of neuronal function. Recent advances have increased our understanding of ERK signalling at the molecular level. In particular, it has become evident that multiple second messengers, such as cyclic adenosine monophosphate, protein kinase A, calcium, and diacylglycerol, can control ERK signalling via the small G proteins Ras and Rap1. These findings may explain the role of ERKs in the regulation of activity-dependent neuronal events, such as synaptic plasticity, long-term potentiation and cell survival. Moreover, they allow us to begin to develop a model to understand both the control of ERKs at the subcellular level and the generation of ERK signal specificity.

Many receptors that couple to heterotrimeric guanine-nucleotide binding proteins (G proteins) have been shown to mediate rapid activation of the mitogen-activated protein kinases Erk1 and Erk2. In different cell types, the signaling pathways employed appear to be a function of the available repertoire of receptors, G proteins, and effectors. In HEK-293 cells, stimulation of either alpha1B- or alpha2A-adrenergic receptors (ARs) leads to rapid 5-10-fold increases in Erk1/2 phosphorylation. Phosphorylation of Erk1/2 in response to stimulation of the alpha2A-AR is effectively attenuated by pretreatment with pertussis toxin or by coexpression of a Gbetagamma subunit complex sequestrant peptide (betaARK1ct) and dominant-negative mutants of Ras (N17-Ras), mSOS1 (SOS-Pro), and Raf (DeltaN-Raf). Erk1/2 phosphorylation in response to alpha1B-AR stimulation is also attenuated by coexpression of N17-Ras, SOS-Pro, or DeltaN-Raf, but not by coexpression of betaARK1ct or by pretreatment with pertussis toxin. The alpha1B- and alpha2A-AR signals are both blocked by phospholipase C inhibition, intracellular Ca2+ chelation, and inhibitors of protein-tyrosine kinases. Overexpression of a dominant-negative mutant of c-Src or of the negative regulator of c-Src function, Csk, results in attenuation of the alpha1B-AR- and alpha2A-AR-mediated Erk1/2 signals. Chemical inhibitors of calmodulin, but not of PKC, and overexpression of a dominant-negative mutant of the protein-tyrosine kinase Pyk2 also attenuate mitogen-activated protein kinase phosphorylation after both alpha1B- and alpha2A-AR stimulation. Erk1/2 activation, then, proceeds via a common Ras-, calcium-, and tyrosine kinase-dependent pathway for both Gi- and Gq/11-coupled receptors. These results indicate that in HEK-293 cells, the Gbetagamma subunit-mediated alpha2A-AR- and the Galphaq/11-mediated alpha1B-AR-coupled Erk1/2 activation pathways converge at the level of phospholipase C. These data suggest that calcium-calmodulin plays a central role in the calcium-dependent regulation of tyrosine phosphorylation by G protein-coupled receptors in some systems.

A mitochondrial complex comprising the voltage-dependent anion channel (outer membrane), the adenine nucleotide translocase (inner membrane) and cyclophilin-D (matrix) assembles at contact sites between the inner and outer membranes. Under pathological conditions associated with ischaemia and reperfusion the junctional complex 'deforms' into the permeability transition (PT) pore, which can open transiently, allowing free permeation of low Mr solutes across the inner membrane. This may be a critical step in the pathogenesis of lethal cell injury in ischaemia and reperfusion. Moreover, it is argued, the degree of pore opening may be an important determinant of the relative extent of apoptosis and necrosis under these conditions. In addition, mitochondria are the major sites of action of Bax and other apoptotic regulatory proteins of the Bcl-2 family. These proteins control a mitochondrial amplificatory loop in the apoptotic signalling pathway in which cytochrome c and other apoptogenic proteins of the mitochondrial intermembrane space are released into the cytosol. There are indications that the junctional complex, or components of it, may also mediate the action of Bax, but in a way that does not involve PT pore formation.

High voltage-activated Ca(2+) channels of the Ca(V)1.2 class (L-type) are crucial for excitation-contraction coupling in both cardiac and smooth muscle. These channels are regulated by a variety of second messenger pathways that ultimately serve to modulate the level of contractile force in the tissue. The specific focus of this review is on the most recent advances in our understanding of how cardiac Ca(V)1.2a and smooth muscle Ca(V)1.2b channels are regulated by different kinases, including cGMP-dependent protein kinase, cAMP-dependent protein kinase, and protein kinase C. This review also discusses recent evidence regarding the regulation of these channels by protein tyrosine kinase, calmodulin-dependent kinase, purified G protein subunits, and identification of possible amino acid residues of the channel responsible for kinase regulation.

Calcineurin is a calcium (Ca2+)/calmodulin (CaM)-dependent protein phosphatase that has been shown to regulate the activity of ion channels, neurotransmitter and hormone release, synaptic plasticity and gene transcription. At glutamatergic synapses, the inhibition of calcineurin with immunosuppressant drugs has been reported to enhance both the presynaptic release of glutamate and postsynaptic responsiveness. Several other ligand- and voltage-gated ion channels are negatively regulated by calcineurin. Hormone release in insulin-secreting pancreatic beta cells and pituitary corticotrope tumour (AtT20) cells is also negatively regulated by calcineurin. In this article, Jerrel Yakel discusses the evidence that calcineurin plays a vital role in regulating neuronal excitability and hormone release.

An impressive array of cytosolic calcium ([Ca2+](i)) signals exert control over a broad range of physiological processes. The specificity and fidelity of these [Ca2+](i) signals is encoded by the frequency, amplitude, and sub-cellular localization of the response. It is believed that the distinct characteristics of [Ca2+](i) signals underlies the differential activation of effectors and ultimately cellular events. This "shaping" of [Ca2+](i) signals can be achieved by the influence of additional signaling pathways modulating the molecular machinery responsible for generating [Ca2+](i) signals. There is a particularly rich source of potential sites of crosstalk between the cAMP and the [Ca2+](i) signaling pathways. This review will focus on the predominant molecular loci at which these classical signaling systems interact to impact the spatio-temporal pattern of [Ca2+](i) signaling in non-excitable cells.

Mutations in genes encoding the calcium-release activated calcium (CRAC) channel abolish calcium influx in cells of the immune system and cause severe congenital immunodeficiency. Patients with autosomal recessive mutations in the CRAC channel gene ORAI1, its activator stromal interaction molecule 1 (STIM1), and mice with targeted deletion of Orai1, Stim1, and Stim2 genes reveal important roles for CRAC channels in adaptive and innate immune responses to infection and in autoimmunity. Because CRAC channels have important functions outside the immune system, deficiency of either ORAI1 or STIM1 is associated with a unique clinical phenotype. This review will give an overview of CRAC channel function in the immune system, examine the consequences of CRAC channel deficiency for immunity in human patients and mice, and discuss genetic defects in immunoreceptor-associated signaling molecules that compromise calcium influx and cause immunodeficiency.

NF-kappaB is an ubiquitous transcription factor that is a key in the regulation of the immune response and inflammation. T-cell receptor (TCR) cross-linking leads to NF-kappaB activation, an IkappaB kinase (IKK)-dependent process. However, the upstream kinases that regulate IKK activity following TCR activation remain to be fully characterized. Herein, we demonstrate using genetic analysis, pharmacological inhibition, and RNA interference (RNAi) that the conventional protein kinase C (PKC) isoform PKCalpha, but not PKCbeta1, is required for the activation of the IKK complex following T-cell activation triggered by CD3/CD28 cross-linking. We find that in the presence of Ca(2+) influx, the catalytically active PKCalphaA25E induces IKK activity and NF-kappaB-dependent transcription; which is abrogated following the mutations of two aspartates at positions 246 and 248, which are required for Ca(2+) binding to PKCalpha and cell membrane recruitment. Kinetic studies reveal that an early phase (1 to 5 min) of IKK activation following TCR/CD28 cross-linking is PKCalpha dependent and that a later phase (5 to 25 min) of IKK activation is PKCtheta dependent. Activation of IKK- and NF-kappaB-dependent transcription by PKCalphaA25E is abrogated by the PKCtheta inhibitor rottlerin or the expression of the kinase-inactive form of PKCtheta. Taken together, our results suggest that PKCalpha acts upstream of PKCtheta to activate the IKK complex and NF-kappaB in T lymphocytes following TCR activation.

Recent advances in molecular genetics provide strong evidence for a relationship between hippocampal long-term potentiation (LTP) and hippocampus-dependent memory. The alpha-CaM kinase II knock-out mouse and transgenic mice expressing a mutant form of CaM kinase II clearly demonstrate that CaM kinase II plays a prominent role in hippocampal LTP and hippocampus-dependent memory. Furthermore, the observation that there is a diversity of silent as well as functional synapses has shed light on the molecular basis of learning and memory during development as well as in adult brain. Here we present a working model of CaM kinase II activity as a memory molecule in hippocampal LTP and describe molecular targets of CaM kinase II involved in the establishment of functional synapses following LTP induction.

Two size forms of the class B N-type calcium channel alpha 1 subunit were recently identified with CNB1, an antipeptide antibody directed against an intracellular loop of this channel (Westenbroek, R.E., Hell, J.W., Warner, C., Dubel, S.J., Snutch, T.P., and Catterall, W.A. (1992) Neuron 9, 1099-1115). To investigate the biochemical differences between these two size forms, the antibodies CNB3 and CNB4 were raised against peptides with sequences corresponding to the COOH-terminal end of the full-length form. Immunoblot experiments demonstrated that both antibodies specifically recognize the longer form of 250 kDa, indicating that the COOH-terminal regions of the two size forms of the class B N-type channel alpha 1 subunit are different. Phosphorylation experiments with immunopurified calcium channels and different second messenger-activated protein kinases revealed that both the 220- and 250-kDa forms of the class B N-type calcium channel alpha 1 subunit are substrates for cAMP-dependent protein kinase, cGMP-dependent protein kinase, and protein kinase C. These three kinases incorporated approximately 1 mol of phosphate/mol of binding sites for omega-conotoxin (omega-CgTx) GVIA, a ligand specific for the N-type calcium channel, and may regulate the activity of both forms in vivo. In contrast, calcium- and calmodulin-dependent protein kinase II (CaM kinase II) phosphorylated only the long form of the class B N-type calcium channel alpha 1 subunit, with a stoichiometry of 0.5 mol of phosphate/mol of total omega-CgTx GVIA binding sites. Specific phosphorylation of the long form of the class B alpha 1 subunit by CaM kinase II may differentially regulate the function of N-type calcium channels containing different size forms of their alpha 1 subunits in vivo.

Although T-type calcium channel currents were observed almost 30 years ago, the genes that encode the pore-forming subunits have only been recently reported. When expressed in heterologous systems, three distinct alpha1 subunits (alpha1G (Cav3.1), alpha1H (Car3.2), and alpha1I (Cav3.3)) conduct T-type currents with insert similar but not identical electrophysiological characteristics that. Alpha 1G, alpha 1H, and alpha 1I transcripts are found throughout neural and nonneural tissues, suggesting multiple types of T-type channels (also called low voltage-activated calcium channels (LVAs)) are coexpressed by many tissues. The study of endogenous LVAs has been hampered by a lack of highly selective antagonists that differentiate between LVA subtypes. Furthermore, many pharmacological agents attenuate currents conducted by LVA and high voltage-activated calcium channels (HVAs). At least 15 classes of pharmacological agents affect T-type currents, and the therapeutic use of many of these drugs has implicated LVAs in the etiology of a variety of diseases. Comparison of the responses of recombinant and native LVAs to pharmacological agents and endogenous modulatory molecules will lead to a better understanding of LVAs in normal and diseased cells.

Activation of Cdc2/cyclin B kinase and entry into mitosis requires dephosphorylation of inhibitory sites on Cdc2 by Cdc25 phosphatase. In vertebrates, Cdc25C is inhibited by phosphorylation at a single site targeted by the checkpoint kinases Chk1 and Cds1/Chk2 in response to DNA damage or replication arrest. In Xenopus early embryos, the inhibitory site on Cdc25C (S287) is also phosphorylated by a distinct protein kinase that may determine the intrinsic timing of the cell cycle. We show that S287-kinase activity is repressed in extracts of unfertilized Xenopus eggs arrested in M phase but is rapidly stimulated upon release into interphase by addition of Ca2+, which mimics fertilization. S287-kinase activity is not dependent on cyclin B degradation or inactivation of Cdc2/cyclin B kinase, indicating a direct mechanism of activation by Ca2+. Indeed, inhibitor studies identify the predominant S287-kinase as Ca2+/calmodulin-dependent protein kinase II (CaMKII). CaMKII phosphorylates Cdc25C efficiently on S287 in vitro and, like Chk1, is inhibited by 7-hydroxystaurosporine (UCN-01) and debromohymenialdisine, compounds that abrogate G2 arrest in somatic cells. CaMKII delays Cdc2/cyclin B activation via phosphorylation of Cdc25C at S287 in egg extracts, indicating that this pathway regulates the timing of mitosis during the early embryonic cell cycle.

L-type voltage-gated calcium channels (VGCCs) are multisubunit membrane proteins that regulate calcium influx into excitable cells. Within the last two years there have been four separate reports describing the structure of the skeletal muscle VGCC determined by electron microscopy and single particle analysis methods. There are some discrepancies between the structures, as well as reports for both monomeric and dimeric forms of the channel. This article considers each of the VGCC structures in terms of similarities and differences with an emphasis upon translation of data into a biological context.

The steps that couple depolarization of the cardiac cell membrane to initiation of contraction remain controversial. Depolarization triggers a rise in intracellular free Ca(2+) which activates contractile myofilaments. Most of this Ca(2+) is released from the sarcoplasmic reticulum (SR). Two fundamentally different mechanisms have been proposed for SR Ca(2+) release: Ca(2+)-induced Ca(2+) release (CICR) and a voltage-sensitive release mechanism (VSRM). Both mechanisms operate in the same cell and may contribute to contraction. CICR couples the release of SR Ca(2+) closely to the magnitude of the L-type Ca(2+) current. In contrast, the VSRM is graded by membrane potential rather than Ca(2+) current. The electrophysiological and pharmacological characteristics of the VSRM are strikingly different from CICR. Furthermore, the VSRM is strongly modulated by phosphorylation and provides a new regulatory mechanism for cardiac contraction. The VSRM is depressed in heart failure and may play an important role in contractile dysfunction. This review explores the operation and characteristics of the VSRM and CICR and discusses the impact of the VSRM on our understanding of cardiac excitation-contraction coupling.

ADP-ribosyl cyclase and CD38 are multi-functional enzymes involved in calcium signaling. Both can cyclize NAD and its guanine analog, NGD, at two different sites of the purine ring, N1 and N7, respectively, to produce cyclic ADP-ribose (cADPR) and cyclic GDP-ribose, a fluorescent but inactive analog. Both enzymes can also catalyze the exchange of the nicotinamide group of NADP with nicotinic acid, producing yet another potent activator of Ca2+ mobilization, nicotinic acid adenine dinucleotide phosphate (NAADP). The Ca2+ release mechanism activated by NAADP is totally independent of cADPR and inositol trisphosphate indicating it is a novel and hitherto unknown Ca2+ signaling pathway. This article summarizes the current results on the structures and activities of cADPR, NAADP and the enzymes that catalyze their syntheses. A comprehensive model accounting for the novel multi-functionality of ADP-ribosyl cyclase and CD38 is presented.

Highly efficient mechanisms regulate intracellular calcium (Ca2+) levels. The recent discovery of new components linking intracellular Ca2+ stores to plasma membrane Ca2+ entry channels has brought new insight into the understanding of Ca2+ homeostasis. Stromal interaction molecule 1 (STIM1) was identified as a Ca2+ sensor essential for Ca2+ store depletion-triggered Ca2+ influx. Orai1 was recognized as being an essential component for the Ca2+ release-activated Ca2+ (CRAC) channel. Together, these proteins participate in store-operated Ca2+ channel function. Defective regulation of intracellular Ca2+ is a hallmark of several diseases. In this review, we focus on Ca2+ regulation by the STIM1/Orai1 pathway and review evidence that implicates STIM1/Orai1 in several pathological conditions including cardiovascular and pulmonary diseases, among others.

In many cell types metabolites of sphingomyelin have a profound role in cellular signalling. One particular field where these derivatives have obtained a crucial role is calcium signalling. This is an interesting aspect on how lipids may wield their physiological role, as calcium is probably one of the most versatile signalling molecules in the cell, and modulation of calcium signalling may have profound effects on cellular physiology. In this review we discuss a novel aspect of sphingolipid signalling, i.e. the autocrine role of sphingosine 1-phosphate (S1P) in regulating calcium entry in thyroid cells. Although many investigations have highlighted the importance of S1P as a regulator of both calcium release from the endoplasmic reticulum and calcium entry through plasma membrane channels, the autocrine mechanism presented here introduces a new aspect of S1P signalling in thyroid cells. This mechanism may be physiologically relevant in many other cell types, including cancer cells.