Involvement of palmitate/Ca2 +(Sr2 +)-induced pore in the cycling of ions across the mitochondrial membrane

The palmitate/Ca^2 +-induced (Pal/Ca^2 +) pore, which is formed due to the unique feature of long-chain saturated fatty acids to bind Ca^2 + with high affinity, has been shown to play an important role in the physiology of mitochondria. The present study demonstrates that the efflux of Ca^2 + from rat liver mitochondria induced by ruthenium red, an inhibitor of the energy-dependent Ca^2 + influx, seems to be partly due to the opening of Pal/Ca^2 + pores. Exogenous Pal stimulates the efflux. Measurements of pH showed that the Ca^2 +-induced alkalization of the mitochondrial matrix increased in the presence of Pal. The influx of Ca^2 + (Sr^2 +) also induced an outflow of K⁺ followed by the reuptake of the ion by mitochondria. The outflow was not affected by a K⁺/H⁺ exchange blocker, and the reuptake was prevented by an ATP-dependent K⁺ channel inhibitor. It was also shown that the addition of Sr^2 + to mitochondria under hypotonic conditions was accompanied by reversible cyclic changes in the membrane potential, the concentrations of Sr^2 + and K⁺ and the respiratory rate. The cyclic changes were effectively suppressed by the inhibitors of Ca^2 +-dependent phospholipase A₂, and a new Sr^2 + cycle could only be initiated after the previous cycle was finished, indicating a refractory period in the mitochondrial sensitivity to Sr^2 +. All of the Ca^2 +- and Sr^2 +-induced effects were observed in the presence of cyclosporin A. This paper discusses a possible role of Pal/Ca^2 + pores in the maintenance of cell ion homeostasis.     

KMUP-1 ameliorates monocrotaline-induced pulmonary arterial hypertension through the modulation of Ca2+ sensitization and K+-channel

AimsThis study investigates the actions of KMUP-1 on RhoA/Rho-kinase (ROCK)-dependent Ca²⁺ sensitization and the K⁺-channel in chronic pulmonary arterial hypertension (PAH) rats.Main methodsSprague–Dawley rats were divided into control, monocrotaline (MCT), and MCT + KMUP-1 groups. PAH was induced by a single intraperitoneal injection (i.p.) of MCT (60 mg/kg). KMUP-1 (5 mg/kg, i.p.) was administered once daily for 21 days to prevent MCT-induced PAH. All rats were sacrificed on day 22.Key findingsMCT-induced increased right ventricular systolic pressure (RVSP) and right ventricular hypertrophy were prevented by KMUP-1. In myograph experiments, KCl (80 mM), phenylephrine (10 µM) and K⁺ channel inhibitors (TEA, 10 mM; paxilline, 10 µM; 4-AP, 5 mM) induced weak PA contractions in MCT-treated rats compared to controls, but the PA reactivity was restored in MCT + KMUP-1-treated rats. By contrast, in β-escin- or α-toxin-permeabilized PAs, CaCl₂-induced (1.25 mM, pCa 5.1) contractions were stronger in MCT-treated rats, and this action was suppressed in MCT + KMUP-1-treated rats. PA relaxation in response to the ROCK inhibitor Y27632 (0.1 μM) was much higher in MCT-treated rats than in control rats. In Western blot analysis, the expression of Ca²⁺-activated K⁺ (BK_Ca) and voltage-gated K⁺ channels (Kv2.1 and Kv1.5), and ROCK II proteins was elevated in MCT-treated rats and suppressed in MCT + KMUP-1-treated rats. We suggest that MCT-treated rats upregulate K⁺-channel proteins to adapt to chronic PAH.SignificanceKMUP-1 protects against PAH and restores PA vessel tone in MCT-treated rats, attributed to alteration of Ca²⁺ sensitivity and K⁺-channel function.     

Calcium-mediated pore expansion and cell death following nanoelectroporation

Opening of long-lived pores in the cell membrane is the principal primary effect of intense, nanosecond pulsed electric field (nsPEF). Here we demonstrate that the evolution of pores, cell survival, the time and the mode of cell death (necrotic or apoptotic) are determined by the level of external Ca^2 + after nsPEF. We also introduce a novel, minimally disruptive technique for nsEP exposure of adherent cells on indium tin oxide (ITO)-coated glass coverslips, which does not require cell detachment and enables fast exchanges of bath media. Increasing the Ca^2 + level from the nominal 2–5 μM to 2 mM for the first 60–90 min after permeabilization by 300-nsPEF increased the early (necrotic) death in U937, CHO, and BPAE cells. With nominal Ca^2 +, the inhibition of osmotic swelling rescued cells from the early necrosis and increased caspase 3/7 activation later on. However, the inhibition of swelling had a modest or no protective effect with 2 mM Ca^2 + in the medium. With the nominal Ca^2 +, most cells displayed gradual increase in YO-PRO-1 and propidium (Pr) uptake. With 2 mM Ca^2 +, the initially lower Pr uptake was eventually replaced by a massive and abrupt Pr entry (necrotic death). It was accompanied by a transient acceleration of the growth of membrane blebs due to the increase of the intracellular osmotic pressure. We conclude that the high-Ca^2 +-dependent necrotic death in nsPEF-treated cells is effected by a delayed, sudden, and osmotically-independent pore expansion (or de novo formation of larger pores), but not by the membrane rupture.     

Alterations in ryanodine receptors and related proteins in heart failure

Sarcoplasmic reticulum (SR) Ca^2 + release plays an essential role in mediating cardiac myocyte contraction. Depolarization of the plasma membrane results in influx of Ca^2 + through l-type Ca^2 + channels (LTCCs) that in turn triggers efflux of Ca^2 + from the SR through ryanodine receptor type-2 channels (RyR2). This process known as Ca^2 +-induced Ca^2 +release (CICR) occurs within the dyadic region, where the adjacent transverse (T)-tubules and SR membranes allow RyR2 clusters to release SR Ca^2 + following Ca^2 + influx through adjacent LTCCs. SR Ca^2 + released during systole binds to troponin-C and initiates actin–myosin cross-bridging, leading to muscle contraction. During diastole, the cytosolic Ca^2 + concentration is restored by the resequestration of Ca^2 + into the SR by SR/ER Ca^2 +-ATPase (SERCA2a) and by the extrusion of Ca^2 + via the Na⁺/Ca^2 +-exchanger (NCX1). This whole process, entitled excitation–contraction (EC) coupling, is highly coordinated and determines the force of contraction, providing a link between the electrical and mechanical activities of cardiac muscle. In response to heart failure (HF), the heart undergoes maladaptive changes that result in depressed intracellular Ca^2 + cycling and decreased SR Ca^2 + concentrations. As a result, the amplitude of CICR is reduced resulting in less force production during EC coupling. In this review, we discuss the specific proteins that alter the regulation of Ca^2 + during HF. In particular, we will focus on defects in RyR2-mediated SR Ca^2 + release. This article is part of a Special Issue entitled: Heart failure pathogenesis and emerging diagnostic and therapeutic interventions.     

Enhanced parkin levels favor ER-mitochondria crosstalk and guarantee Ca2 + transfer to sustain cell bioenergetics

Loss-of-function mutations in PINK1 or parkin genes are associated with juvenile-onset autosomal recessive forms of Parkinson disease. Numerous studies have established that PINK1 and parkin participate in a common mitochondrial-quality control pathway, promoting the selective degradation of dysfunctional mitochondria by mitophagy. Upregulation of parkin mRNA and protein levels has been proposed as protective mechanism against mitochondrial and endoplasmic reticulum (ER) stress. To better understand how parkin could exert protective function we considered the possibility that it could modulate the ER–mitochondria inter-organelles cross talk. To verify this hypothesis we investigated the effects of parkin overexpression on ER–mitochondria crosstalk with respect to the regulation of two key cellular parameters: Ca^2 + homeostasis and ATP production. Our results indicate that parkin overexpression in model cells physically and functionally enhanced ER–mitochondria coupling, favored Ca^2 + transfer from the ER to the mitochondria following cells stimulation with an 1,4,5 inositol trisphosphate (InsP₃) generating agonist and increased the agonist-induced ATP production. The overexpression of a parkin mutant lacking the first 79 residues (ΔUbl) failed to enhance the mitochondrial Ca^2 + transients, thus highlighting the importance of the N-terminal ubiquitin like domain for the observed phenotype. siRNA-mediated parkin silencing caused mitochondrial fragmentation, impaired mitochondrial Ca^2 + handling and reduced the ER–mitochondria tethering. These data support a novel role for parkin in the regulation of mitochondrial homeostasis, Ca^2 + signaling and energy metabolism under physiological conditions.     

How do reactive oxygen species and calcium trigger mitochondrial membrane permeabilisation?

BackgroundMitochondrial membrane permeabilisation (MMP) is classically considered as a point of no return in several forms of cell death and is involved in numerous diseases such as cancer, neurodegenerative disorders or ischemia/reperfusion injuries. Many studies established that reactive oxygen species (ROS) and Ca^2 + were the prominent inducers of MMP. However, the mechanisms connecting ROS and Ca^2 + to the players of MMP are still a matter of debate.Scope of reviewThe aim of this review is to summarise the various studies related to the mechanisms of ROS- and Ca^2 +-induced MMP. Several lines of evidence suggest that ROS and Ca^2 + cooperate to induce MMP but the molecular details of the ROS–Ca^2 +-MMP network remain controversial. We then discuss recent data depicting this topic.Major conclusionsCytotoxic stimuli may be transduced within the cell by ROS and Ca^2 + increases. In most models, Ca^2 + and ROS can cooperate to induce MMP. Moreover, several data suggest that MMP increases mitochondrial Ca^2 + and ROS which therefore amplify the cytotoxic signal. Intriguingly, many reports have identified players of MMP as direct ROS targets. On the contrary, direct targets of Ca^2 + remain elusive. At the same time, the mechanisms by which mitochondrial Ca^2 + overload induces ROS generation are well documented. Upon these observations, we hypothesise that Ca^2 + cannot directly induce MMP and requires ROS production as a mandatory step.General significanceGiven the importance of Ca^2 +- and ROS-induced MMP in diseases, we expect that a better understanding of this process will lead to the development of novel therapies.     

The use of transgenic mouse models to reveal the functions of Ca2 + buffer proteins in excitable cells

BackgroundCytosolic Ca^2 + buffers are members of the large family of Ca^2 +-binding proteins and are essential components of the Ca^2 + signaling toolkit implicated in the precise regulation of intracellular Ca^2 + signals. Their physiological role in excitable cells has been investigated in vivo by analyzing the phenotype of mice either lacking one of the Ca^2 + buffers or mice with ectopic expression.Scope of ReviewIn this review, results obtained with knockout mice for the three most prominent Ca^2 + buffers, parvalbumin, calbindin-D28k and calretinin are summarized.Major ConclusionsThe absence of Ca^2 + buffers in specific neuron subpopulations, and for parvalbumin additionally in fast-twitch muscles, leads to Ca^2 + buffer-specific changes in intracellular Ca^2 + signals. This affects the excitation–contraction cycle in parvalbumin-deficient muscles, and in Ca^2 + buffer-deficient neurons, properties associated with synaptic transmission (e.g. short-term modulation), excitability and network oscillations are altered. These findings have not only resulted in a better understanding of the physiological function of Ca^2 + buffers, but have revealed that the absence of Ca^2 + signaling toolkit components leads to protein-and neuron-specific adaptive/homeostatic changes that also include changes in neuron morphology (e.g. altered spine morphology, changes in mitochondria content) and network properties.General SignificanceThe complex phenotype of Ca^2 + buffer knockout mice arises from the direct effect of these proteins on Ca^2 + signaling and moreover from the homeostatic mechanisms induced in these mice. For a better mechanistic understanding of neurological diseases linked to disturbed/altered Ca^2 + signaling, a global view on Ca^2 + signaling is expected to lead to new avenues for specific therapies. This article is part of a Special Issue entitled Biochemical, biophysical and genetic approaches to intracellular calcium signaling.     

Acute effects of cocaine,morphine and their combination on bioenergetic function and susceptibility to oxidative stress of rat liver mitochondria

AimsCocaine and heroin are frequently co-abused in a combination known as speedball. Despite the relevance of the liver in the metabolism and detoxification of these drugs, little is known about the impact of speedball on liver function.Main methodsIn this work, we evaluated the effects of cocaine, morphine and morphine + cocaine (Mor + Coc) combination (1:1) in isolated rat liver mitochondria, upon glutamate/malate or succinate energization, on bioenergetics and oxidative stress-related parameters by using Clark O₂, Ca^2 +, TPP⁺ and pH electrodes and by measuring thiobarbituric acid reactive substances (TBARS) and H₂O₂ production.Key findingsCocaine and Mor + Coc at the higher concentrations (1 mM) similarly increased O₂ consumption at state 2, state 4 and state oligomycin. In these conditions, maximum respiration was decreased only upon glutamate/malate energization, suggesting an involvement of complex I. Morphine (1 mM) only increased state 2 respiration. Cocaine and Mor + Coc induced a similar decrease in maximum mitochondrial membrane potential and in ADP-induced depolarization, whereas morphine had no effect. The drugs and their combination similarly decreased mitochondrial ATPase activity and had no effect on Ca^2 +-induced permeability transition. Morphine and Mor + Coc prevented lipid peroxidation, since in these conditions there was a decrease in O₂ consumption and in TBARS upon ADP/Fe^2 + stimulus, and a decrease in H₂O₂ formation, suggesting an antioxidant effect. Interestingly, heroin did not share morphine antioxidant properties.SignificanceOur results show that the sequential direct exposure of liver mitochondria to morphine and cocaine does not alter the effects observed in the presence of each drug alone.     

Enhanced charge-independent mitochondrial free Ca2 + and attenuated ADP-induced NADH oxidation by isoflurane: Implications for cardioprotection

Modulation of mitochondrial free Ca^2 + ([Ca^2 +]_m) is implicated as one of the possible upstream factors that initiates anesthetic-mediated cardioprotection against ischemia–reperfusion (IR) injury. To unravel possible mechanisms by which volatile anesthetics modulate [Ca^2 +]_m and mitochondrial bioenergetics, with implications for cardioprotection, experiments were conducted to spectrofluorometrically measure concentration-dependent effects of isoflurane (0.5, 1, 1.5, 2 mM) on the magnitudes and time-courses of [Ca^2 +]_m and mitochondrial redox state (NADH), membrane potential (ΔΨ_m), respiration, and matrix volume. Isolated mitochondria from rat hearts were energized with 10 mM Na⁺- or K⁺-pyruvate/malate (NaPM or KPM) or Na⁺-succinate (NaSuc) followed by additions of isoflurane, 0.5 mM CaCl₂ (≈ 200 nM free Ca^2 + with 1 mM EGTA buffer), and 250 μM ADP. Isoflurane stepwise: (a) increased [Ca^2 +]_m in state 2 with NaPM, but not with KPM substrate, despite an isoflurane-induced slight fall in ΔΨ_m and a mild matrix expansion, and (b) decreased NADH oxidation, respiration, ΔΨ_m, and matrix volume in state 3, while prolonging the duration of state 3 NADH oxidation, respiration, ΔΨ_m, and matrix contraction with PM substrates. These findings suggest that isoflurane's effects are mediated in part at the mitochondrial level: (1) to enhance the net rate of state 2 Ca^2 + uptake by inhibiting the Na⁺/Ca^2 + exchanger (NCE), independent of changes in ΔΨ_m and matrix volume, and (2) to decrease the rates of state 3 electron transfer and ADP phosphorylation by inhibiting complex I. These direct effects of isoflurane to increase [Ca^2 +]_m, while depressing NCE activity and oxidative phosphorylation, could underlie the mechanisms by which isoflurane provides cardioprotection against IR injury at the mitochondrial level.     

Membrane potential-related effect of calcium on reactive oxygen species generation in isolated brain mitochondria

The effect of Ca²⁺ applied in high concentrations (50 and 300 µM) was addressed on the generation of reactive oxygen species in isolated mitochondria from guinea-pig brain. The experiments were performed in the presence of ADP, a very effective inhibitor of mitochondrial permeability transition. Moderate increase in H₂O₂ release from mitochondria was induced by Ca²⁺ applied in 50 µM, but not in 300 µM concentration as measured with Amplex red fluorescent assay starting with a delay of 100-150 sec after exposure to Ca²⁺. Parallel measurements of membrane potential (ΔΨm) by safranine fluorescence showed a transient depolarization by Ca²⁺ followed by the recovery of ΔΨm to a value, which was more negative than that observed before addition of Ca²⁺ indicating a relative hyperpolarization. NAD(P)H fluorescence was also increased by Ca²⁺ given in 50 µM concentration. In mitochondria having high ΔΨm in the presence of oligomycin or ATP, the basal rate of release of H₂O₂ was significantly higher than that observed in a medium containing ADP and Ca²⁺ no longer increased but rather decreased the rate of H₂O₂ release. With 300 µM Ca²⁺ only a loss but no tendency of a recovery of ΔΨm was detected and H₂O₂ release was unchanged. It is suggested that in the presence of nucleotides the effect of Ca²⁺ on mitochondrial ROS release is related to changes in ΔΨm; in depolarized mitochondria, in the presence of ADP, moderate increase in H₂O₂ release is induced by calcium, but only in ≤ 100 µM concentration, when after a transient Ca²⁺-induced depolarization mitochondria became more polarized. In highly polarized mitochondria, in the presence of ATP or oligomycin, where no hyperpolarization follows the Ca²⁺-induced depolarization, Ca²⁺ fails to stimulate mitochondrial ROS generation. These effects of calcium (≤ 300 µM) are unrelated to mitochondrial permeability transition.     

Thapsigargin decreases the Na+- Ca2 + exchanger mediated Ca2 + entry in pig coronary artery smooth muscle

Na⁺- Ca^2 + exchanger (NCX) has been proposed to play a role in refilling the sarco/endoplasmic reticulum (SER) Ca^2 + pool along with the SER Ca^2 + pump (SERCA). Here, SERCA inhibitor thapsigargin was used to determine the effects of SER Ca^2 + depletion on NCX–SERCA interactions in smooth muscle cells cultured from pig coronary artery. The cells were Na⁺-loaded and then placed in either a Na⁺-containing or in a Na⁺-substituted solution. Subsequently, the difference in Ca^2 + entry between the two groups was examined and defined as the NCX mediated Ca^2 + entry. The NCX mediated Ca^2 + entry in the smooth muscle cells was monitored using two methods: Ca^2 +sensitive fluorescence dye Fluo-4 and radioactive Ca^2 +. Ca^2 +-entry was greater in the Na⁺-substituted cells than in the Na⁺-containing cells when measured by either method. This difference was established to be NCX-mediated as it was sensitive to the NCX inhibitors. Thapsigargin diminished the NCX mediated Ca^2 + entry as determined by either method. Immunofluorescence confocal microscopy was used to determine the co-localization of NCX1 and subsarcolemmal SERCA2 in the cells incubated in the Na⁺-substituted solution with or without thapsigargin. SER Ca^2 + depletion with thapsigargin increased the co-localization between NCX1 and the subsarcolemmal SERCA2. Thus, inhibition of SERCA2 leads to blockade of constant Ca^2 + entry through NCX1 and also increases proximity between NCX1 and SERCA2. This blockade of Ca^2 + entry may protect the cells against Ca^2 +-overload during ischemia–reperfusion when SERCA2 is known to be damaged.     

A permeability transition in liver mitochondria and liposomes induced by α,ω-dioic acids and Ca2+

The article examines the molecular mechanism of the Ca²⁺-dependent cyclosporin A (CsA)-insensitive permeability transition in rat liver mitochondria induced by α,ω-dioic acids. The addition of α,ω-hexadecanedioic acid (HDA) to Ca²⁺-loaded liver mitochondria was shown to induce a high-amplitude swelling of the organelles, a drop of membrane potential and the release of Ca²⁺ from the matrix, the effects being insensitive to CsA. The experiments with liposomes loaded with sulforhodamine B (SRB) revealed that, like palmitic acid (PA), HDA was able to cause permeabilization of liposomal membranes. However, the kinetics of HDA- and PA-induced release of SRB from liposomes was different, and HDA was less effective than PA in the induction of SRB release. Using the method of ultrasound interferometry, we also showed that the addition of Ca²⁺ to HDA-containing liposomes did not change the phase state of liposomal membranes—in contrast to what was observed when Ca²⁺ was added to PA-containing vesicles. It was suggested that HDA/Ca²⁺- and PA/Ca²⁺-induced permeability transition occurs by different mechanisms. Using the method of dynamic light scattering, we further revealed that the addition of Ca²⁺ to HDA-containing liposomes induced their aggregation/fusion. Apparently, these processes result in a partial release of SRB due to the formation of fusion pores. The possibility that this mechanism underlies the HDA/Ca²⁺-induced permeability transition of the mitochondrial membrane is discussed.     

Mechanism of dopamine D2 receptor-induced Ca2 + release in PC-12 cells

Intracellular Ca^2 + levels are tightly regulated in the neuronal system. The loss of Ca^2 + homeostasis is associated with many neurological diseases and neuropsychiatric disorders such as Parkinson's, Alzheimer's, and schizophrenia. We investigated the mechanisms involved in intracellular Ca^2 + signaling in PC-12 cells. The stimulation of NGF-differentiated PC-12 cells with 3 μM ATP caused an early Ca^2 + release followed by a delayed Ca^2 + release. The delayed Ca^2 + release was dependent on prior ATP priming and on dopamine secretion by PC-12 cells. Delayed Ca^2 + release was abolished in the presence of spiperone, suggesting that it is due to the activation of D2 dopamine receptors (D2R) by dopamine secreted by PC-12 cells. This was shown to be independent of PKA activation but dependent on PLC activity. An endocytosis step was required for inducing the delayed Ca^2 + release. Given the importance of calcyon in clathrin-mediated endocytosis, we verified the role of this protein in the delayed Ca^2 + release phenomenon. siRNA targeting of calcyon blocked the delayed Ca^2 + release, decreased ATP-evoked IP₃R-mediated Ca^2 + release, and impaired subsequent Ca^2 + oscillations. Our results suggested that calcyon is involved in an unknown mechanism that causes a delayed IP₃R-mediated Ca^2 + release in PC-12 cells. In schizophrenia, Ca^2 + dysregulation may depend on the upregulation of calcyon, which maintains elevated Ca^2 + levels as well as dopamine signaling.     

Endothelium-independent vasorelaxant effect of sodium ferulate on rat thoracic aorta

AimsThis study was designed to investigate the effects of sodium ferulate (SF) on rat isolated thoracic aortas and the possible mechanisms.Main methodsIsometric tension was recorded in response to drugs in organ bath. Cytosolic free Ca²⁺ concentration ([Ca²⁺]_i) was measured using Fluo-3 in cultured rat aortic smooth muscle cells (RASMC).Key findingsSF (0.1–30 mM) relaxed the isolated aortic rings precontracted with phenylephrine (PE) and high-K⁺ in a concentration-dependent manner with respective pD₂ of 2.7 ± 0.02 and 2.6 ± 0.06. Mechanical removal of endothelium did not significantly modify the SF-induced relaxation. In Ca²⁺-free solution, SF noticeably inhibited extracellular Ca²⁺-induced contraction in high-K⁺ and PE pre-challenged rings, and suppressed the transient contraction induced by PE and caffeine. The vasorelaxant effect of SF was unaffected by various K⁺ channel blockers such as tetraethylammonium, glibenclamide, 4-aminopyridine, and barium chloride. In addition, SF concentration-dependently reduced the contraction induced by phorbol-12-myristate-13-acetate, an activator of protein kinase C (PKC), in the absence of extracellular Ca²⁺, with the pD₂ of 2.9 ± 0.03. In RASMC, SF had no effect on PE- or KCl-induced [Ca²⁺]_i increase either in the presence or in the absence of external Ca²⁺.SignificanceThese results indicate that SF acts directly as a non-selective relaxant to vascular smooth muscle. The direct inhibition of the common pathway after [Ca²⁺]_i increase may account for the SF-induced relaxation in Ca²⁺-dependent contraction, while the blockage of the PKC-mediated contractile mechanism is likely responsible for the SF-induced relaxation in Ca²⁺-independent contraction.     

Cholesterol enrichment of rabbit platelets enhances the Ca2 + entry pathway induced by platelet-derived secondary feedback agonists

AimsHypersensitivity of platelets due to increased platelet cholesterol levels has been reported in hypercholesterolemia. However, the signaling pathways linking increased platelet reactivity and cholesterol contents are not fully understood. This study aims to determine the direct effect of cholesterol enrichment of platelets on the pathways including Ca^2 + mobilization and secondary feedback agonists such as adenosine diphosphate (ADP) and thromboxane A₂ (TXA₂).Main methodsIn vitro cholesterol enrichment of rabbit platelets was performed by incubation with cholesterol complexed with methyl-β-cyclodextrin. Ca^2 + mobilization was monitored using platelets loaded with fura-PE3/AM, a fluorescent calcium indicator. Released ATP and TXB₂ from platelets were measured by a luciferin–luciferase ATP assay system and a TXB₂ ELISA Kit, respectively.Key findingsCholesterol enrichment of rabbit platelets significantly enhanced Ca^2 + mobilization induced by thrombin, accompanying an augmented Ca^2 + entry. The augmentation of Ca^2 + entry by cholesterol enrichment was significantly suppressed by treatment with inhibitors for secondary feedback agonists. In cholesterol-enriched platelets, the amount of released ATP or TXB₂ induced by thrombin was not significantly altered in comparison with control platelets, whereas an increase in [Ca^2 +]_i induced by ADP or U46619, a TXA₂ mimetic, was significantly enhanced.SignificanceThese results suggest that cholesterol enrichment of rabbit platelets results in enhanced Ca^2 + mobilization via ADP/TXA₂-dependent augmentation of the Ca^2 + entry pathway. The results reveal a novel mechanism by which platelet hypersensitivity is regulated by cholesterol contents.     

Involvement of store-operated Ca2 + entry in activation of AMP-activated protein kinase and stimulation of glucose uptake by M3 muscarinic acetylcholine receptors in human neuroblastoma cells

G_q/11-coupled muscarinic acetylcholine receptors (mAChRs) belonging to M₁, M₃ and M₅ subtypes have been shown to activate the metabolic sensor AMP-activated protein kinase (AMPK) through Ca^2 +/calmodulin-dependent protein kinase kinase-β (CaMKKβ)-mediated phosphorylation at Thr172. However, the source of Ca^2 + required for this response has not been yet elucidated. Here, we investigated the involvement of store-operated Ca^2 + entry (SOCE) in AMPK activation by pharmacologically defined M₃ mAChRs in human SH-SY5Y neuroblastoma cells. In Ca^2 +-free medium the cholinergic agonist carbachol (CCh) caused a transient increase of phospho-Thr172 AMPK that rapidly ceased within 2 min. Conversely, in the presence of extracellular Ca^2 + CCh-induced AMPK phosphorylation lasted for at least 180 min. The SOCE modulator 2-aminoethoxydiphephenyl borate (2-APB), at a concentration (50 μM) that suppressed CCh-induced intracellular Ca^2 + ([Ca^2 +]_i) plateau, inhibited CCh-induced AMPK phosphorylation. CCh triggered the activation of the endoplasmic reticulum Ca^2 + sensor stromal interaction molecule (STIM) 1, as indicated by redistribution of STIM1 immunofluorescence into puncta, and promoted the association of STIM1 with the SOCE channel component Orai1. Cell depletion of STIM1 by siRNA treatment reduced both CCh-induced [Ca^2 +]_i plateau and AMPK activation. M₃ mAChRs increased glucose uptake and this response required extracellular Ca^2 + and was inhibited by 2-APB, STIM1 knockdown, CaMKKβ and AMPK inhibitors, and adenovirus infection with dominant negative AMPK. Thus, the study provides evidence that SOCE is required for sustained activation of AMPK and stimulation of downstream glucose uptake by M₃ mAChRs and suggests that SOCE is a critical process connecting M₃ mAChRs to the control of neuronal energy metabolism.     

Transient receptor potential ankyrin-1 (TRPA1) modulates store-operated Ca2 + entry by regulation of STIM1-Orai1 association

TRPA1 is a non-selective Ca^2 + permeable channel located in the plasma membrane that functions as a cellular sensor detecting mechanical, chemical and thermal stimuli, being a component of neuronal, epithelial, blood and smooth muscle tissues. TRPA1 has been shown to influence a broad range of physiological processes that involve Ca^2 +-dependent signaling pathways. Here we report that TRPA1 is expressed in MEG01 but not in platelets at the protein level. MEG01 cells maturation induced by PMA results in attenuation of TRPA1 protein expression and enhances thapsigargin-evoked Ca^2 + entry without altering the release of Ca^2 + from intracellular stores. Inhibition of TRPA1 by HC-030031 results in enhancement of both thrombin- and thapsigargin-stimulated Ca^2 + entry. Co-immunoprecipitation experiments revealed that TRPA1 associates with STIM1, as well as Orai1, TRPC1 and TRPC6. Downregulation of TRPA1 expression by MEG01 maturation, as well as pharmacological inhibition of TRPA1 by HC-030031, results in enhancement of the association between STIM1 and Orai1. Altogether, these findings provide evidence for a new and interesting function of TRPA1 in cellular function associated to the regulation of agonist-induced Ca^2 + entry by the modulation of STIM1/Orai1 interaction.