Steady-state Ca2 Research Articles

Familial Alzheimer's Disease Mutations in Presenilin-1 and Store-Operated Calcium Entry

Alzheimer's disease (AD) is a progressive and irreversible neurodegenerative disorder. Familial AD (FAD) mutations in presenilins have been linked to Ca2+ signaling abnormalities. Presenilins (PS) are 50 kDa proteins in the endoplasmic reticulum (ER) membrane. The cleaved presenilins are well known as catalytic components of a gamma-secretase, which cleaves the amyloid precursor protein (APP) and releases the amyloid beta-peptide. In addition uncleaved presenilins function as passive ER Ca2+ leak channels which control steady-state ER Ca2+ levels. It was found that many FAD mutations in presenilins result in loss of ER Ca2+ leak function, leading to ER Ca2+ overload and supranormal Ca2+ release from the ER. The ER Ca2+ leak function of presenilins is independent of their gamma-secretase activity. We suggested that presenilins affect store-operated calcium influx (SOC) by controlling the filling state of ER Ca2+ stores. To determinate the influence of FAD presenilins mutations on SOC we performed a series of patch-clamp experiments in whole-cell mode.PS1-M146V and PS1-ΔE9 mutants have been shown to have loss and gain of ER Ca2+ leak channel function respectively. A decrease in maximum amplitude and speed of SOC current activation was observed in SK-N-SH neuroblastoma cells and primary culture of rat hippocampal neurons transfected with PS1-M146V mutant comparing to wild type PS1 transfected cells. An increase in maximum amplitude and speed of SOC current activation was observed in cells transfected by PS1-ΔE9 mutant comparing to wild type PS1. In experiments with triple transgenic AD mice hippocampal neurons (3XTg mice; KI-PS1M146V, Thy1-APPKM670/671NL, Thy1-tauP301L) the maximum amplitude of SOC were decreased comparing to WT, but the speed of activation was the same for 3XTg and WT hippocampal neurons. Electrophysiological properties of all impaired SOCs suggest that TRPC1 is the main target of presenilins FAD mutations affect.

An intimate liaison: spatial organization of the endoplasmic reticulum–mitochondria relationship

Organelle localization is often crucial to properly modulate cellular functions and signalling cascades. For example, the distribution of organelles in axons is crucial for their function and is dysregulated in several diseases. Similarly, relative positioning of two or more organelles is also important to perform certain specialized processes. Perhaps, the best-known form of interorganellar organization is that between endoplasmic reticulum (ER) and mitochondria. Close communication between these two compartments has been observed for a long time. Recent evidence suggests that this is the basis for a bidirectional communication regulating a number of physiological processes ranging from mitochondrial energy and lipid metabolism to Ca(2+) signalling and cell death. The recent discovery of some of the molecular mediators of the tethering already allowed to extend the function of this paradigmatic spatial organization to previously unexpected functions, and will foster future research to explore it in cellular signalling cascades as well as in disease.

Polycystin-1: Function as a mechanosensor

Polycystin-1 (PC1), encoded by the Pkd1 gene, is a large transmembrane protein whose mutation is involved in autosomal dominant polycystic kidney disease. When expressed, PC1 activates a G-protein signaling pathway that subsequently modulates Ca2+ channels. PC1 is highly expressed in developing tissue and via its C-terminus tail forms a complex with polycystin-2; this complex, found to be located at the primary cilia, seems to act as a mechanosensor that could affect proliferation, differentiation and apoptosis of cells. Also, loss of polycystins correlates with disruption of flow-dependent and steady-state intracellular Ca2+ signaling. Despite the lack of clarity on the role of the polycystins as mechanosensor molecules, a new interest in this PCs/primary cilium complex is providing continuously new insights. In this review, some of the known features of PC1 such as structure, function, signaling pathways involved and its role as a possible therapeutic target are being discussed.

Adaptive Retuning of Small Ca2+ Fluxes in Cardiomyocyte Syncytia Predicts the Response To Pro-Arrhythmic Stimuli

Cardiac cell phenotype is driven by the interplay between large ‘global’ Ca2+ events (transients) and much smaller, spatially restricted Ca2+ signals. Our previous studies revealed a link between these low amplitude inter-transient Ca2+ fluxes, and the spatiotemporal organisation of the intra- and intercellular global Ca2+ transients. We hypothesised that chronic cardiac cell dysfunction may be underpinned by the incremental resetting of these Ca2+ fluxes that ultimately leads to perturbed Ca2+ homeostasis. We constructed a database comprising more than one thousand independent manipulations of the Na/K ATPase/NCX systems in spontaneously oscillating, electrically-coupled HL-1 cardiomyocytes in which inter-transient Ca2+ signal noise, but not mean steady state Ca2+ levels had been precisely modulated. Data was interrogated using our SALVO program that generates a detailed spatiotemporal profile of intra- and intercellular Ca2+ signals. We determined a bell-shaped relationship between incremental increases in intracellular Ca2+ fluxes and the propensity for intercellular dyssynchrony. Modest but sustained elevations in inter-transient Ca2+ fluxes protected cell syncytia from manoeuvres designed to perturb intercellular synchrony. This protective effect did not occur if inter-transient Ca2+ fluxes had been acutely retuned (< 20 minutes) suggesting that cellular adaptation mechanisms were involved in these phenomena. In contrast, larger elevations in inter-transient Ca2+ fluxes exacerbated intercellular dyssynchrony in response to pro-arrhythmic stimuli. All alterations in steady-state inter-transient Ca2+ fluxes were associated with altered SERCA activity and decreased cellular levels of ATP, consistent with the concept that pathological alterations in Ca2+ homeostasis are linked to metabolic dysfunction. Our data supports the hypothesis that small Ca2+ fluxes tune global Ca2+ events and dictate the propensity of cell syncytia to arrhythmogenic perturbation.

Refractoriness of Sarcoplasmic Reticulum Calcium Release in Cardiac Muscle Due to Calsequestrin

In cardiac excitation-contraction coupling, L-type Ca2+ current (ICa) triggers Ca2+ release from the sarcoplasmic reticulum (SR) via ryanodine receptor (RyR) Ca2+ release channels. It is unclear why SR Ca2+ release cannot be elicited by premature stimuli, even though ICa is fully recovered. Here, we use calsequestrin null mice (Casq2 KO) and wild-type littermates (WT) to test the hypothesis that calsequestrin (Casq2) determines refractoriness of SR Ca2+ release. Ca2+ release refractoriness was measured in voltage-clamped myocytes dialyzed with Fluo-4 by applying premature extrastimuli (S2) at successively shorter S1-S2 coupling intervals following a 1 Hz train (S1 stimuli). To maintain constant trigger, Ca2+ release was activated with ICa tail currents that elicited maximal Ca2+ release during the S1 train. WT S2 Ca2+release was significantly depressed with short coupling interval whereas Casq2 KO cardiomyocytes exhibit no refractoriness of Ca2+ release (Figure, n=11 WT, 12 KO, p = 0.01). At the same time, ICa current density, SR Ca2+ content, and steady-state Ca2+ transients (S1) were not significantly different from WT-myocytes. We conclude that calsequestrin is a critical determinant of SR Ca2+ release refractoriness in cardiac muscle (Supported by NIH-R01HL71670, R01HL88635).

Redox Modifications of Ca2+-Release Events in Cardiomyocytes

Several cardiac diseases (e.g. heart failure, muscle dystrophy) are known to be associated with cellular oxidative stress. It is established that SR Ca2+ release channels (a.k.a. ryanodine receptors, RyRs) are susceptible to oxidation. Furthermore, our recent studies suggest that CICR and EC-coupling are sensitized in cardiomyocytes isolated from dystrophic mdx mice due to elevated levels of reactive oxygen species. The aim of this study was to examine the Ca2+ spark activity (as an indicator of RyR Ca2+ sensitivity) in mdx and wild-type (WT) cardiomyocytes at relevant redox potentials. Ventricular myocytes were permeabilized and exposed to solutions containing the Ca2+ indicator fluo-3 (50 μM) and a Ca2+ concentration of 50 nM. Ca2+ sparks were recorded with a laser-scanning confocal microscope in the line-scan mode and analyzed using SparkMaster software. Solutions mimicked intracellular redox potentials (EGSSG/GSH) determined in healthy hearts and in muscle dystrophy or heart failure, e.g. −226 mV and −217 mV. Under corresponding redox conditions the steady-state Ca2+ spark frequency did not show significant difference in mdx and WT cells (24±0.4 vs. 22±0.3 /100μms−1). Therefore, we used stronger reducing and oxidizing conditions to derive a redox/response relationship of spark parameters over a wider range of EGSSG/GSH from −263 mV to −146 mV. Under very oxidative conditions (EGSSG/GSH −146 mV) the spark frequency gradually declined but long-lasting Ca2+ release events appeared (> 70 ms, up to 700 ms) that were more frequent in mdx compared to WT cardiomyocytes (5.6 vs. 0.6 /100μms−1). Taken together, these results indicate that the average and modest change of the cytosolic redox potential may not significantly alter resting Ca2+ spark frequencies, but that stronger oxidative stress, as it has been reported to occur in subcellular regions as superoxide flashes, can lead to dramatic alterations of elementary Ca2+ signaling events.

Efficient memetic vector quantizer design based on reconfigurable hardware and softcore processor

This paper presents a novel hardware architecture for memetic vector quantizer (VQ) design. The architecture uses steady-state genetic algorithm (GA) for global search, and C-Means algorithm for local refinement. It adopts a shift register based circuit for accelerating mutation and crossover operations for steady state CA operations. It also uses a pipeline architecture for the hardware implementation of C-Means algorithm. The proposed architecture is embedded in a softcore CPU, and implemented on a field programmable logic array (FPGA) device for physical performance measurement. Experimental results show that the proposed architecture is an effective method for VQ optimization attaining both high performance and low computational time.

STIM1 Is a Calcium Sensor Specialized for Digital Signaling

When cells are activated by calcium-mobilizing agonists at low, physiological concentrations, the resulting calcium signals generally take the form of repetitive regenerative discharges of stored calcium, termed calcium oscillations [1]. These intracellular calcium oscillations have long fascinated biologists as a mode of digitized intracellular signaling. Recent work has highlighted the role of calcium influx as an essential component of calcium oscillations [2]. This influx occurs through a process known as store-operated calcium entry, which is initiated by calcium sensor proteins, STIM1 and STIM2, in the endoplasmic reticulum [3]. STIM2 is activated by changes in endoplasmic reticulum calcium near the resting level, whereas a threshold of calcium depletion is required for STIM1 activation [4]. Here we show that, surprisingly, it is STIM1 and not STIM2 that is exclusively involved in calcium entry during calcium oscillations. The implication is that each oscillation produces a transient drop in endoplasmic reticulum calcium and that this drop is sufficient to transiently activate STIM1. This transient activation of STIM1 can be observed in some cells by total internal reflection fluorescence microscopy. This arrangement nicely provides a clearly defined and unambiguous signaling system, translating a digital calcium release signal into calcium influx that can signal to downstream effectors.

Comparison of sarcoplasmic reticulum calcium content in atrial and ventricular myocytes of three fish species

Ryanodine (Ry) sensitivity of cardiac contraction differs between teleost species, between atrium and ventricle, and according to the thermal history of the fish. The hypothesis that variability in Ry sensitivity of contraction is due to species-specific, chamber-specific, and temperature-related differences in the sarcoplasmic reticulum (SR) Ca(2+) content, was tested by comparing steady-state (SS) and maximal (Max) Ca(2+) loads of the SR in three teleost fish, rainbow trout (Oncorhynchus mykiss), burbot (Lota lota), and crucian carp (Carassius carassius), which differ in the extent of SR contribution to excitation-contraction coupling. Fish were acclimated at 4 degrees C (cold-acclimation, CA) or 18 degrees C (warm-acclimation, WA), and SR Ca(2+) content was released by a rapid application of 10 mM caffeine to single cardiac myocytes; its amount was determined from the Na(+)-Ca(2+) exchange current at 18 degrees C. SS Ca(2+) load was larger in atrial (304-915 micromol/l) than ventricular (224-540 micromol/l) myocytes in all fish species (P < 0.05), and the same was true for Max SR Ca(2+) content: 550-1,522 micromol/l and 438-840 micromol/l for atrial and ventricular myocytes, respectively (P < 0.05). Consistent with the hypothesis, acclimation to cold increased Ca(2+) load of the cardiac SR in the burbot heart, but contrary to the hypothesis, temperature acclimation did not affect SR Ca(2+) content in rainbow trout and crucian carp hearts. Furthermore, there was an inverse relation between SR Ca(2+) content and Ry sensitivity of contraction force: the species with the smallest SR Ca(2+) content (burbot) is most sensitive to Ry. Collectively, these findings show that SR Ca(2+) content of fish cardiac myocytes is several times larger than that in mammalian cardiac SR.

Increased uncoupling protein (UCP) activity in Drosophila insulin-producing neurons attenuates insulin signaling and extends lifespan

To understand the role of mitochondrial uncoupling protein (UCP) in regulating insulin signaling and glucose homeostasis, we created transgenicDrosophila lines with targeted UCP expression in insulin producing cells (IPCs). Increased UCP activity in IPCs results in decreased steady state Ca(2+) levels in IPCs as well as decreased PI3K activity and increased FoxO nuclear localization in periphery. This reduced systemic insulin signaling is accompanied by a mild hyperglycemia and extended life span. To test the hypothesis that ATP-sensitive potassium (K(ATP)) channels may link changes in metabolic activity (e.g., glucose mediated ATP production or UCP-mediated ATP reduction) with insulin secretion, we characterized the effects of glucose and a specific K(ATP) channel blocker, glibenclamide on membrane potential in adult IPCs. Exposure to glucose depolarizes membrane potential of IPCs and this effect is mimicked with glibenclamide, suggesting that K(ATP) channels contribute to the mechanism whereby IPCs sense changes in circulating sugar. Further, as demonstrated in mammalian beta-pancreatic cells, high glucose initiates a robust Ca(2+) influx in adult IPCs. The presence of functional K(ATP) channels in adult IPCs is further substantiated by in situ hybridization detecting the transcript for the sulfonylurea receptor (Sur) subunit of the K(ATP) channel in those cells. Quantitative expression analysis demon-strates a reduction in transcripts for both Sur and the inward rectifying potassium channel (Kir) subunits when IPCs are partially ablated. In summary, we have demonstrated a role for UCP in adult Drosophila IPCs in influencing systemic insulin signaling and longevity by a mechanism that may involve K(ATP) channels.

A retrograde signal from RyR1 alters DHP receptor inactivation and limits window Ca 2+ release in muscle fibers of Y522S RyR1 knock-in mice

Malignant hyperthermia (MH) is a life-threatening hypermetabolic condition caused by dysfunctional Ca(2+) homeostasis in skeletal muscle, which primarily originates from genetic alterations in the Ca(2+) release channel (ryanodine receptor, RyR1) of the sarcoplasmic reticulum (SR). Owing to its physical interaction with the dihydropyridine receptor (DHPR), RyR1 is controlled by the electrical potential across the transverse tubular (TT) membrane. The DHPR exhibits both voltage-dependent activation and inactivation. Here we determined the impact of an MH mutation in RyR1 (Y522S) on these processes in adult muscle fibers isolated from heterozygous RyR1(Y522S)-knock-in mice. The voltage dependence of DHPR-triggered Ca(2+) release flux was left-shifted by approximately 8 mV. As a consequence, the voltage window for steady-state Ca(2+) release extended to more negative holding potentials in muscle fibers of the RyR1(Y522S)-mice. A rise in temperature from 20 degrees to 30 degrees C caused a further shift to more negative potentials of this window (by approximately 20 mV). The activation of the DHPR-mediated Ca(2+) current was minimally changed by the mutation. However, surprisingly, the voltage dependence of steady-state inactivation of DHPR-mediated calcium conductance and release were also shifted by approximately 10 mV to more negative potentials, indicating a retrograde action of the RyR1 mutation on DHPR inactivation that limits window Ca(2+) release. This effect serves as a compensatory response to the lowered voltage threshold for Ca(2+) release caused by the Y522S mutation and represents a novel mechanism to counteract excessive Ca(2+) leak and store depletion in MH-susceptible muscle.

Identification And Characterization Of Cardiac Troponin I From The Trout Heart

Trout cardiac myofibrils are ∼10-fold more sensitive to Ca+2 than those from mammalian hearts when measured at the same temperature. It has been demonstrated that trout cardiac troponin C (ScTnC) has 2.3 fold the Ca2+ affinity of human cTnC and is responsible for a 2-fold increase in cardiac myofibril Ca+2 sensitivity. The contributions of trout cardiac troponin I (ScTnI) to the Ca+2 sensitivity of the trout heart is currently unknown. The cDNA for ScTnI has been cloned using RACE-PCR. Sequencing results indicate that ScTnI is 59% and 56% identical to human cTnI and human skeletal troponin I, respectively, at the amino acid level. Interestingly, ScTnI lacks the ∼30-residue N-terminal sequence present in mammalian cTnI that contains two protein kinase A (PKA) target residues at positions 23 and 24. ScTnI has been expressed and the influence of it on the Ca2+ activation of human cardiac troponin is currently being characterized using steady state Ca2+ binding assays and stopped flow kinetic analysis. This work is supported by grants from the Natural Sciences and Engineering Research Council of Canada (NSERC) and the Canadian Foundation for Innovation (CFI) to TEG.

Changes In Cytosolic Ca2+ Have Greater Effects On SR Ca2+ Leak Than Changes In SR Ca2+

Attention has recently focused on preventing arrhythmias by controlling sarcoplasmic reticulum (SR) Ca2+ “leak”. Increased leak in ventricular myocytes is associated with regenerative Ca2+ waves and delayed afterdepolarizations, leading to arrhythmias. Studies that have measured SR Ca2+ leak have not examined changes in [Ca2+]SR independent of changes in [Ca2+]i, causing a degree of uncertainty as to which factor plays a greater role. Our current work explores the possibility that changes in [Ca2+]i have a greater effect on leak than changes in [Ca2+]SR.In quiescent rat ventricular myocytes, we recorded steady-state Ca2+ levels, then blocked the ryanodine receptors (RyRs) with a saturating concentration of tetracaine. Using the calcium indicator fluo-3, we recorded changes in [Ca2+]i using a confocal microscope and analyzed the data using leak calculations that took into account underlying assumptions about cytosolic and SR buffers.When extracellular Ca2+ ([Ca2+]e) was increased from 0.5 mM to 1.0 mM at rest, leak increased 37% (9±1.019 vs. 12.3±1.108 μM/s), [Ca2+]i increased 6.6% (98.9 ±0.09 vs. 105.4±3.2 nM, and [Ca2+]SR decreased 5.2% (489±21 vs. 464±23 μM). We also compared leak in resting cells versus leak in the same cells immediately after pacing for 10 s at 1 Hz. At 1 mM [Ca2+]e, pacing increased leak by 17.9% (12.3±1.108 vs. 14.5±8.8 μM/s), increased [Ca2+]i by 9.4% (105.4±3.2 vs. 115.3±5.7 nM), but increased [Ca2+]SR by only 1.0% (463.7±22.7 vs. 468.2±26.8 μM). Qualitatively similar results were obtained after pacing in 0.5 mmol [Ca2+]e. These results suggest that [Ca]i plays a larger role in determining diastolic SR Ca2+ leak than [Ca]SR.

Tumor Necrosis Factor-α Potentiates Intraneuronal Ca2+ Signaling via Regulation of the Inositol 1,4,5-Trisphosphate Receptor

Inflammatory events have long been implicated in initiating and/or propagating the pathophysiology associated with a number of neurological diseases. In addition, defects in Ca2+-handling processes, which shape membrane potential, influence gene transcription, and affect neuronal spiking patterns, have also been implicated in disease progression and cognitive decline. The mechanisms underlying the purported interplay that exists between neuroinflammation and Ca2+ homeostasis have yet to be defined. Herein, we describe a novel neuron-intrinsic pathway in which the expression of the type-1 inositol 1,4,5-trisphosphate receptor is regulated by the potent pro-inflammatory cytokine tumor necrosis factor-alpha. Exposure of primary murine neurons to tumor necrosis factor-alpha resulted in significant enhancement of Ca2+ signals downstream of muscarinic and purinergic stimulation. An increase in type-1 inositol 1,4,5-trisphosphate receptor mRNA and protein steady-state levels following cytokine exposure positively correlated with this alteration in Ca2+ homeostasis. Modulation of Ca2+ responses arising from this receptor subtype and its downstream effectors may exact significant consequences on neuronal function and could underlie the compromise in neuronal activity observed in the setting of chronic neuroinflammation, such as that associated with Parkinson disease and Alzheimer disease.

Phase Relationships between Calcium and Voltage Oscillations in Different Dendrites of Purkinje Neurons

We address the spatial dynamics of the membrane potential and intracellular Ca2+ concentration in the dendritic arborization of a simulated Purkinje neuron reconstructed at a high spatial resolution. We probe the mechanisms that couple spatial patterns of steady-state and oscillatory plateau potentials and Ca2+ dynamics with the dendritic geometry. Simulations were performed with both passive and active membranes. Steady currents applied to the soma produced heterogeneous voltage distributions revealing the geometry-linked features of voltage and current transfer in the dendrite. Branching asymmetry split the isoplanar dendritic field into domains of different efficiencies. Active dendrites equipped with P-type Ca2+, delayed rectifier K+, A-type K+, high-threshold Ca-activated K+ channels, and intracellular Ca2+ ([Ca2+] i ) dynamic mechanisms reproduced oscillatory plateau potentials. Occurring at given intensities of homogeneous tonic excitation via AMPA-type synapses over the whole arborization, the oscillatory activity of the dendritic domains is phase-ordered. An advance or a lag in the phase correlated with a lower or higher steady-transfer effectiveness of the corresponding domains. Snapshots of the dendritic field during plateau potentials reveal the dynamics of dendritic domains with different membrane potentials and [Ca2+] i , which are spatially reconfigured according to the phase of the cycle. This complex spatio-temporal behavior is hidden in single-site recordings.

Dual effect of Nai+ on Ca2+ influx through the Na+/Ca2+ exchanger in dialyzed squid axons. Experimental data confirming the validity of the squid axon kinetic model

We propose a steady-state kinetic model for the squid Na(+)/Ca(2+) exchanger that differs from other current models of regulation in that it takes into account, within a single kinetic scheme, all ionic [intracellular Ca(2+) (Ca(i)(2+))-intracellular Na(+) (Na(i)(+))-intracellular H(i)(+)] and metabolic (ATP) regulations of the exchanger in which the Ca(i)(2+)-regulatory pathway plays the central role in regulation. Although the integrated ionic-metabolic model predicts all squid steady-state experimental data on exchange regulation, a critical test for the validity of it is the predicted dual effect of Na(i)(+) on steady-state Ca(2+) influx through the exchanger. To test this prediction, an improved technique for the estimation of isotope fluxes in squid axons was developed, which allows sequential measurements of ion influx and effluxes. With this method, we report here two novel observations of the squid axon Na(+)/Ca(2+) exchanger. First, at intracellular pH (7.0) and in the absence of MgATP, Na(i)(+) has a dual effect on Ca(2+) influx: inhibition at low concentrations followed by stimulation at high Na(i)(+) concentrations, reaching levels higher than those seen without Na(i)(+). Second, in the presence of MgATP, the biphasic response to Na(i)(+) disappears and is replaced by a sigmoid activation. Furthermore, the model predicts that Ca(2+) efflux is monotonically inhibited by Na(i)(+), more pronouncedly without than with MgATP. These results are predicted by the proposed kinetic model. Although not fully applicable to all exchangers, this scheme might provide some insights on expected net Ca(2+) movements in other tissues under a variety of intracellular ionic and metabolic conditions.

Kinetic Model for Ca2+-induced Permeability Transition in Energized Liver Mitochondria Discriminates between Inhibitor Mechanisms

Cytotoxicity associated with pathophysiological Ca(2+) overload (e.g. in stroke) appears mediated by an event termed the mitochondrial permeability transition (mPT). We built and solved a kinetic model of the mPT in populations of isolated rat liver mitochondria that quantitatively describes Ca(2+)-induced mPT as a two-step sequence of pre-swelling induction followed by Ca(2+)-driven, positive feedback, autocatalytic propagation. The model was formulated as two differential equations, each directly related to experimental parameters (Ca(2+) flux/mitochondrial swelling). These parameters were simultaneously assessed using a spectroscopic approach to monitor multiple mitochondrial properties. The derived kinetic model correctly identifies a correlation between initial Ca(2+) concentration and delay interval prior to mPT induction. Within the model's framework, Ru-360 (a ruthenium complex) and Mg(2+) were shown to compete with the Ca(2+)-stimulated initiation phase of mPT induction, consistent with known inhibition at the phenomenological level of the Ca(2+) uniporter. The model further reveals that Mg(2+), but not Ru-360, inhibits Ca(2+)-induced effects on a downstream stage of mPT induction at a site distinct from the uniporter. The analytical approach was then applied to promethazine, an FDA-approved drug previously shown to inhibit both mPT and ischemia-reperfusion injury. Kinetic analysis revealed that promethazine delayed mPT induction in a manner qualitatively distinct from that of lower concentrations of Mg(2+). In summary, we have developed a kinetic model to aid in the quantitative characterization of mPT induction. This model is consistent with/informative about the biochemistry of several mPT inhibitors, and its success suggests that this kinetic approach can aid in the classification of agents or targets that modulate mPT induction.

IQ-Motif Proteins Influence Intracellular Free Ca2+in Hippocampal Neurons Through Their Interactions With Calmodulin

Calmodulin (CaM) is most recognized for its role in activating Ca(2+)-CaM-dependent enzymes following increased intracellular Ca(2+). However, CaM's high intracellular concentration indicates CaM has the potential to play a significant role as a Ca(2+) buffer. Neurogranin (Ng) is a small neuronal IQ-motif-containing protein that accelerates Ca(2+) dissociation from CaM. In cells that contain high concentrations of both Ng and CaM, like CA1 pyramidal neurons, we hypothesize that the accelerated Ca(2+) dissociation from CaM by Ng decreases the buffering capacity of CaM and thereby shapes the transient dynamics of intracellular free Ca(2+). We examined this hypothesis using a mathematical model constructed on the known biochemistry of Ng and confirmed the simulation results with Ca(2+) imaging data in the literature. In a single-compartment model that contains no Ca(2+) extrusion mechanism, Ng increased the steady-state free Ca(2+). However, in the presence of a Ca(2+) extrusion mechanism, Ng accelerated the decay rate of free Ca(2+) through its ability to increase the Ca(2+) dissociation from CaM, which in turn becomes subject to Ca(2+) extrusion. Interestingly, PEP-19, another neuronal IQ-motif protein that accelerates both Ca(2+) association and dissociation from CaM, appears to have the opposite impact than that of Ng on free Ca(2+). As such, Ng may regulate, in addition to the Ca(2+)-CaM-dependent process, Ca(2+)-sensitive enzymes by influencing the buffering capacity of CaM and subsequently free Ca(2+) levels. We examined the relative impact of these Ng-induced effects in the induction of synaptic plasticity.

SMAKing Ca2+ sparks in arterial myocytes

In the current issue of The Journal of Physiology, Essin et al. (2007) examined the relationship between Cav1.2 L-type Ca2+ channel function and Ca2+ spark activity in arterial myocytes. To do this, they took advantage of the SMAKO mouse (Moosmang et al. 2003) – a conditional, vascular smooth muscle-specific Cav1.2 knock-out mouse. Using SMAKO mice they provide what represents the strongest, most direct demonstration that, in arterial myocytes, local Ca2+ signalling between Cav1.2 channels and ryanodine receptors (RyRs) is not required for the activation of Ca2+ sparks. Rather, Cav1.2 activity influences Ca2+ spark activity in a subtler, indirect way by controlling sarcoplasmic reticulum (SR) Ca2+ load. The functional implications of these findings are discussed below. Cav1.2 is the predominant L-type Ca2+ channel isoform expressed in murine arterial smooth muscle (Moosmang et al. 2003; Navedo et al. 2007; Zhang et al. 2007). Local [Ca2+]i signals (called ‘Ca2+ sparklets’) resulting from the opening of individual L-type Ca2+ channels have been imaged in ventricular (Wang et al. 2001) and arterial myocytes (Navedo et al. 2005). Interestingly, Ca2+ sparklet activity varies within the sarcolemma of arterial myocytes (Navedo et al. 2005, 2006). The majority of L-type Ca2+ channels in these cells operate in low opening probability mode that causes small, sporadic elevations in [Ca2+]i (i.e. low activity Ca2+ sparklets). In contrast, discrete clusters of L-type Ca2+ channels associated with PKCα operate in a sustained, high activity mode that results in substantial Ca2+ influx (i.e. persistent Ca2+ sparklets) (Navedo et al. 2005, 2006; Amberg et al. 2007). On the basis of these data, a model for steady-state Ca2+ influx in arterial myocytes has been proposed in which membrane depolarization increases Ca2+ influx by activation of low and high activity persistent Ca2+ sparklets. Like Ca2+ sparklets, Ca2+ sparks increase [Ca2+]i locally near the surface sarcolemma (Nelson et al. 1995). However, unlike Ca2+ sparklets, Ca2+ sparks do not directly cause global increases in [Ca2+]i and contraction. Instead, Ca2+ sparks activate closely apposed, large-conductance, Ca2+-activated K+ (BK) channels, which hyperpolarize arterial smooth muscle and consequently decrease L-type Ca2+ channel activity, arterial wall [Ca2+]i, and myogenic tone (Nelson et al. 1995). Thus, dynamic regulation of BK channel activity by Ca2+ sparks is critical for the regulation of arterial function. In ventricular myocytes, Ca2+ sparks are rapidly activated by Ca2+ influx through L-type Ca2+ channels (presumably Cav1.2) by the mechanism of Ca2+-induced Ca2+ release (Lopez-Lopez et al. 1995; Wang et al. 2001). Activation of Ca2+ sparks by L-type Ca2+ channels occurs in specialized regions where the SR (i.e. junctional SR) comes into close apposition to the sarcolemma of ventricular myocytes. During an action potential, the simultaneous activation of multiple L-type Ca2+ channels results in the local recruitment of numerous Ca2+ sparks in these cells. Tight coupling between Cav1.2 L-type Ca2+ channels and Ca2+ sparks is a fundamental tenet of the local control model of excitation–contraction coupling in heart. Like ventricular myocytes, smooth muscle cells express Cav1.2 channels and have junctional SR, where Ca2+ sparks occur. However, as Essin et al. (2007) elegantly demonstrated, tight, cardiac-like Cav1.2-RyR coupling is not a major regulator of Ca2+ spark activity in arterial myocytes. The data supporting this view are compelling. (1) The frequency and amplitude of Ca2+ sparks and BK currents is lower in SMAKO than in wild-type arterial myocytes. (2) Dihydropyridine agonists and antagonists do not rapidly increase or eliminate BK currents and Ca2+ sparks. (3) Global [Ca2+]i and SR Ca2+ load are lower in SMAKO than in wild-type arterial myocytes. (4) Increasing [Ca2+]i increased BK currents (presumably by activating Ca2+ sparks) in SMAKO and wild-type myocytes. (5) Unlike ventricular myocytes (Lopez-Lopez et al. 1995; Wang et al. 2001), first-latency histograms of Ca2+ sparks showed only a weak voltage dependence. (6) The average latency of Ca2+ sparks between –30 and +50 mV occurred at > 100 ms, a value that is much longer than what would be expected for Cav1.2 channels. If, in arterial myocytes, Ca2+ sparks were locally controlled by Ca2+ influx via L-type Ca2+ channels, Ca2+ sparks would have kinetics resembling those of L-type Ca2+ channels. A limitation in the Essin et al. (2007) study is that they did not simultaneously record Ca2+ sparklet and spark activity. This is important because, as noted above, L-type Ca2+ channel activity varies within the sarcolemma of arterial myocytes. Is Ca2+ spark activity higher near persistent Ca2+ sparklet sites? Is SR Ca2+ locally controlled by the level of nearby Ca2+ sparklet activity? And, is the coupling strength between Cav1.2 channels and Ca2+ sparks modulated by vasodilators and/or vasoconstrictors? Future studies should address these important questions. Doing so will reveal in greater detail the inner workings of arterial smooth muscle. The challenge will be to integrate these studies on local excitation–contraction coupling into a coherent, integrative model of arterial function.

PKC-dependent autoregulation of membrane kainate receptors

Agonists of kainate receptors (KARs) cause both the opening of the associated ion channels and the activation of signalling pathways driven by G-proteins and PKC. Here we report the existence of an unknown mechanism of KAR autoregulation, involving the interplay of this two signalling mechanisms. Repetitive activation of native KARs evoked the rundown of the ionotropic responses in a manner that was dependent on the activation of PKC. Experiments on recombinant GluR5 expressed in neuroblastoma cells indicated that KARs trigger the activation of PKC and induce the internalization of membrane receptors. This phenomenon depends on the PKC-mediated phosphorylation of serines 879 and 885 of the GluR5-2b subunits, since mutation of these two residues abolished internalization. These results reveal that the non-canonical signalling of KARs is associated with a sensitive mechanism that detects afferent activity. Such a mechanism represents an active way to limit overactivation of the KAR system, by regulating the number of KARs in the cell membrane.