Calcium signal compartmentalization

Cytosolic calcium signals are produced by suddenly increasing the concentration of free calcium ions (Ca2+). This can occur by opening channels permeable to Ca2+ either in the surface cell membrane or in the membranes of intracellular organelles containing high Ca2+ concentrations. Ca2+ signals can control several different processes, even in the same cell. In pancreatic acinar cells, for example, Ca2+ signals do not only control the normal secretion of digestive enzymes, but can also activate autodigestion and programmed cell death. Recent technical advances have shown that different patterns of Ca2+ signals can be created, in space and time, which allow specific cellular responses to be elicited. The mechanisms responsible for Ca2+ signal compartmentalization are now largely known and will be described on the basis of recent studies of Ca2+ transport pathways and their regulation in pancreatic acinar cells. It turns out that the Ca2+ handling as well as the structural characteristics of the endoplasmic reticulum (ER) and the mitochondria are of particular importance. Using a variety of Ca(2+)-sensitive fluorescent probes placed in different sub-cellular compartments in combination with local uncaging of caged Ca2+, many new insights into Ca2+ signal generation, compartmentalization and termination have recently been obtained.     

Ca2+- and voltage-dependent inactivation of the expressed L-type Ca(v)1.2 calcium channel

Ca2+-dependent regulation of the ion current through the alpha1Cbeta2aalpha2delta-1 (L-type) calcium channel transiently expressed in HEK 293 cells was investigated using whole cell patch clamp method. Ca2+ or Na+ ions were used as a charge carrier. Intracellular Ca2+ was either buffered by 10 mM EGTA or 200 microM Ca2+ was added into non-buffered intracellular solution. Free intracellular Ca2+ inactivated permanently about 80% of the L-type calcium current. The L-type calcium channel inactivated during a depolarizing pulse with two time constants, tau(fast) and tau(slow). Free intracellular calcium accelerated both time constants. Effect on the tau(slow) was more pronounced. About 80% of the channel inactivation during brief depolarizing pulse could be attributed to a Ca2+-dependent mechanism and 20% to a voltage-dependent mechanism. When Na+ ions were used as a charge carrier, the L-type current still inactivated with two time constants that were 10 times slower and were virtually voltage-independent. Ca2+ ions stabilized the inactivated state of the channel in a concentration-dependent manner.     

Modeling the interrelations between the calcium oscillations and ER membrane potential oscillations

A refined electrochemical model accounting for intracellular calcium oscillations and their interrelations with oscillations of the potential difference across the membrane of the endoplasmic reticulum (ER) or other intracellular calcium stores is established. The ATP dependent uptake of Ca2+ from the cytosol into the ER, the Ca2+ release from the ER through channels following a calcium-induced calcium release mechanism, and a potential-dependent Ca2+ leak flux out of the ER are included in the model and described by plausible rate laws. The binding of calcium to specific proteins such as calmodulin is taken into account. The quasi-electroneutrality condition allows us to express the transmembrane potential in terms of the concentrations of cytosolic calcium and free binding sites on proteins, which are the two independent variables of the model. We include monovalent ions in the model, because they make up a considerable portion in the balance of electroneutrality. As the permeability of the endoplasmic membrane for these ions is much higher than that for calcium ions, we assume the former to be in Nernst equilibrium. A stability analysis of the steady-state solutions (which are unique or multiple depending on parameter values) is carried out and the Hopf bifurcation leading from stable steady states to self-sustained oscillations is analysed with the help of appropriate mathematical techniques. The oscillations obtained by numerical integration exhibit the typical spike-like shape found in experiments and reasonable values of frequency and amplitude. The model describes the process of switching between stationary and pulsatile regimes as well as changes in oscillation frequency upon parameter changes. It turns out that calcium oscillations can arise without a permanent influx of calcium into the cell, when a calcium-buffering system such as calmodulin is included.     

Pharmacology of capacitative calcium entry

The versatility of Ca(2+) as a messenger in multiple signaling events requires that the concentration of calcium ions within the cytoplasm be highly regulated. In particular, the release of calcium from intracellular stores must often be linked to calcium influx across the cell membrane. Capacitative calcium entry, whereby the depletion of intracellular Ca(2+) stores induces the influx of extracellular calcium, is a crucial element of concerted calcium signaling. Investigations into the phenomenon are contributing to a new appreciation for the organized cytoplasmic framework that supports calcium signaling.     

Factors controlling the intracellular concentration of calcium and the spontaneous activity of the ureter

The role of the electrogenic Na(+)-Ca(2+)-exchange mechanism in regulating the spike activity of the ureter was studied. The ureter cells were shown to be capable of generating action potentials (AP) in sodium-free Krebs solution. The time during which the spikes are generated is in exponential dependence on the concentration of calcium ions in the medium, [Ca2+]o within 2.5 to 15 mmol/l. Simultaneously with the generation of the spikes, accumulation of calcium in the muscles is observed, proportional to the increase of [Ca2+]o. The addition of as little as 20 mmol/l Na+ or Li+ ions into the solution restores the prolonged electrical activity of the ureter. Under these conditions, the decrease of intracellular Ca2+ within 5 min was more than two times larger as compared with that in sodium-free medium. Upon substituting Ba2+ ions for Ca2+ ions in Krebs solution AP are generated within an interval which was the longer the higher the Ba2+ concentration in the medium. Li+ ions can replace Na+ ions in maintaining AP and in extruding calcium from the cell. It is supposed that the generation of the stable spike activity of the ureter depends on the functioning of Na(+)-Ca(2+)-exchange mechanism.     

Disease-causing mutations of calcium channels

Many cellular functions are directly or indirectly regulated by the free cytosolic calcium concentration. Thus, calcium levels must be very tightly regulated in time and space. Intracellular calcium ions are essential second messengers and play a role in many functions including, action potential generation, neurotransmitter and hormone release, muscle contraction, neurite outgrowth, synaptogenesis, calcium-dependent gene expression, synaptic plasticity and cell death. Calcium ions that control cell activity can be supplied to the cell cytosol from two major sources: the extracellular space or intracellular stores. Voltage-gated and ligand-gated channels are the primary way in which Ca2+ ions enter from the extracellular space. The sarcoplasm reticulum (SR) in muscle and the endoplasmic reticulum in non-muscle cells are the main intracellular Ca2+ stores: the ryanodine receptor (RyR) and inositol-triphosphate receptor channels are the major contributors of calcium release from internal stores. Mutations of genes encoding calcium have been implicated in the etiology of a diverse group of nerve and muscle diseases. These mutations have been identified in humans, mice and other organisms. In this review, we will summarize calcium channelopathies of humans and mice. Of the ten calcium channel α1 subunits cloned and sequenced (see ref. 1), disease-causing mutations have been found in CaV1.4 and CaV2.1 in the nervous system, and CaV1.1 and CaV1.2 in muscle. Mutations in calcium channel auxiliary subunits (α2δ, β and γ) have also been associated with both human and/or mouse neurological diseases. The disease-causing mutations may provide new insight into the cell biological roles of calcium channels as well as into relationships between structure and function. In addition, understanding how the mutations affect the physiology of the cell could lead to advances in disease treatment by relieving symptoms or slowing the progression of the disease. However, due to the multifaceted functions of calcium in the cell, the correlation between molecular mutation, physiological alterations and disease etiology is neither straightforward nor easily understood. Since calcium is an important intracellular signaling molecule, altered calcium channel function can give rise to widespread changes in cellular function. Indeed, serious diseases result from mutations that cause trivial alterations of calcium currents analyzed in vitro.     

Mechanisms of phospholipase C-regulated calcium entry

In a variety of cell types, activation of phospholipase C-linked receptors results in the generation of intracellular Ca2+ signals comprised of components of both intracellular Ca2+ release, and enhanced entry of Ca2+ across the plasma membrane. This entry of Ca2+ occurs by either of two general mechanisms: the release of stored Ca2+ can activate, by an unknown mechanism, store-operated channels in the plasma membrane, a process known as capacitative calcium entry. Alternatively, second messengers generated at the plasma membrane can activate Ca2+ channels more directly, a non-capacitative calcium entry process. This review summarizes current knowledge of the underlying signaling mechanisms and the nature of the channel molecules responsible for these two general categories of regulated Ca2+ entry.     

Involvement of cellular calcium incorporated from the medium in production of inositol trisphosphate in A-431 cells

The property of intensive 45Ca2+ uptake by A-431 human epidermoidal carcinoma cells was indicated to be an influx, not binding to the cell surface, since the two apparent dissociation constants (Kd) between 45Ca2+ and cells were almost the same when measured in either the presence or absence of 1 mM [ethylenebis (oxyethylenenitrilo)]tetraacetic acid (EGTA); these constants were approximately 5-10 x 10(-6) and 1 x 10(-4) M, respectively, which are much higher than the chelating constant of EGTA for Ca2+ (approximately 10(-11) M). Furthermore, addition of A23187, a calcium ionophore, rapidly released the 45Ca2+ incorporated into cells at both 37 degrees C and 0 degrees C. The 45Ca2+ associated with the cells was slowly released or exchanged when cells were incubated in medium depleted of Ca2+, or in that containing 1 mM non-radioactive Ca2+. The ability of A-431 cells to respond to extracellular ATP by elevating their level of intracellular calcium ions, as well as by producing inositol trisphosphate (InsP3), was suppressed in cells depleted of cellular calcium. These data suggest that calcium ions are extensively incorporated or exchanged with those outside the cells, maintained as stored calcium, and involved in production of InsP3, when A-431 cells are stimulated by ATP to trigger the signal transduction system.     

Mechanisms of regulation of Ca2+ levels in myometrium cells

The ways and mechanisms of the Ca2+ concentration regulation in myometrium cells are analyzed. The plasma membrane is thoroughly studied for its role in the calcium control provision for the contractile activity of the uterus. The systems of Mg2+-ATP-dependent transport of Ca2+, sodium-calcium metabolism as well as regularities of the Ca2+ passive transfer in the sarcolemma vesicles are considered. The systems of the Mg2+-ATP- and N+-dependent transport of calcium are discussed for their contribution into regulation of calcium concentration in the myoplasm. Oxytocin and ions of bivalent metals (stimulators of the contractile activity of the uterus) are studied for their effect on the activity of the sarcolemma calcium pump.     

Arrhythmogenic mechanisms in ryanodine receptor channelopathies

Ryanodine receptors(Ry Rs) are the calcium release channels of sarcoplasmic reticulum(SR) that provide the majority of calcium ions(Ca2+) necessary to induce contraction of cardiac and skeletal muscle cells.In their intracellular environment,Ry R channels are regulated by a variety of cytosolic and luminal factors so that their output signal(Ca2+) induces finely-graded cell contraction without igniting cellular processes that may lead to aberrant electrical activity(ventricular arrhythmias) or cellular remodeling.The importance of Ry R dysfunction has been recently highlighted with the demonstration that point mutations in RYR2,the gene encoding for the cardiac isoform of the Ry R(Ry R2),are associated with catecholaminergic polymorphic ventricular tachycardia(CPVT),an arrhythmogenic syndrome characterized by the development of adrenergically-mediated ventricular tachycardia in individuals with an apparently normal heart.Here we summarize the state of the field in regards to the main arrhythmogenic mechanisms triggered by Ry R2 channels harboring mutations linked to CPVT.Most CPVT mutations characterized to date endow Ry R2 channels with a gain of function,resulting in hyperactive channels that release Ca2+ spontaneously,especially during diastole.The spontaneous Ca2+ release is extruded by the electrogenic Na+/Ca2+ exchanger,which depolarizes the external membrane(delayed afterdepolarization or DAD) and may trigger untimely action potentials.However,a rare set of CPVT mutations yield Ry R2 channels that are intrinsically hypo-active and hypo-responsive to stimuli,and it is unclear whether these channels release Ca2+ spontaneously during diastole.We discuss novel cellular mechanisms that appear more suitable to explain ventricular arrhythmias due to Ry R2 loss-of-function mutations.     

Participation of annexins in Ca2+-regulated secretion of catecholamines

Secretion of catecholamines by adrenal medulla chromaffin cells occurs after their stimulation by nicotine or depolarization of plasma membrane. Adrenal medulla secrets mostly noradrenaline and adrenaline, both having pleyotropic action in the organism. Central role in regulation of exocytosis of catecholamines play calcium ions. Their intracellular concentration increases as a cell response to stimulus and creates signal to start secretion. Moreover, annexins are known to participate in regulation of biological membrane dynamics during intracellular transport processes, however their participation in secretion is less established then in endocytosis. Among twelve annexin subfamilies (AnxA1-A11 i A13) expressed in mammalian organisms only involvement of AnxA2 and AnxA6 in endocytosis is well documented. Some data suggests that annexins may play important functions also in Ca2+-regulated catecholamine secretion.     

The nature of the Ca2+-pump defect in the red blood cells of patients with cystic fibrosis

The reduction in (Ca2+ + Mg2+)-ATPase activity in the cystic fibrosis red blood cells can be attributed to a reduction in the number of active Ca2+ pumps per red blood cell and an altered interaction of calcium ions with the pump. Despite this, the normal free intracellular [Ca2+] is preserved due to a lower rate of passive calcium entry.     

Properties of different Ca2+ pools in permeabilized rat thymocytes

The regulation of free Ca2+ concentration by intracellular pools and their participation in the mitogen-induced changes of the cytosolic free Ca2+ concentration, [Ca2+]i, was studied in digitonin-permeabilized and intact rat thymocytes using a Ca2+-selective electrode, chlortetracycline fluorescence and the Ca2+ indicator quin-2. It is shown that in permeabilized thymocytes Ca2+ can be accumulated by two intracellular compartments, mitochondrial and non-mitochondrial. Ca2+ uptake by the non-mitochondrial compartment, presumably the endoplasmic reticulum, is observed only in the presence of MgATP, is increased by oxalate and inhibited by vanadate. The mitochondria do not accumulate calcium at a free Ca2+ concentration below 1 microM. The non-mitochondrial compartment has a greater affinity for calcium and is capable of sequestering Ca2+ at a free Ca2+ concentration less than 1 microM. At free Ca2+ concentration close to the cytoplasmic (0.1 microM) the main calcium pool in permeabilized thymocytes is localized in the non-mitochondrial compartment. Ca2+ accumulated in the non-mitochondrial pool can be released by inositol 1,4,5-triphosphate (IP3) which has been inferred to mediate Ca2+ mobilization in a number of cell types. Under experimental conditions in which ATP-dependent Ca2+ influx is blocked, the addition of IP3 results in a large Ca2+ release from the non-mitochondrial pool; thus IP3 acts by activation of a specific efflux pathway rather than by inhibiting Ca2+ influx. SH reagents do not prevent IP3-induced Ca2+ mobilization. Addition of the mitochondrial uncouplers, FCCP or ClCCP, to intact thymocytes results in no increase in [Ca2+]i measured with quin-2 tetraoxymethyl ester whereas the Ca2+ ionophore A23187 induces a Ca2+ release from the non-mitochondrial store(s). Thus, the data obtained on intact cells agree with those obtained in permeabilized thymocytes. The mitogen concanavalin A increases [Ca2+]i in intact thymocytes suspended in both Ca2+-containing an Ca2+-free medium. This indicates a mitogen-induced mobilization of an intracellular Ca2+ pool, probably via the IP3 pathway.     

Altered calcium homeostasis in the pathogenesis of myocardial ischemic and hypoxic injury

Pathological calcification, observed in infarcted myocardium under certain conditions, is the most severe manifestation of abnormal calcium (Ca2+) homeostasis induced by ischemia and related forms of myocardial injury. Specialized techniques for measurement of intracellular electrolytes, i.e., electron probe X-ray microanalysis, and intracellular free Ca2+, i.e. carboxylate indicators including fura-2, are providing new insights into regulation of intracellular Ca2+ and the role of altered Ca2+ homeostasis in the pathogenesis of myocardial cell injury. Several lines of investigation indicate that increased intracellular Ca2+ develops in association with other electrolyte alterations, altered cell volume regulation, and altered membrane phospholipid composition during the progression of myocardial cell injury.     

Characterization of [Ca2+]i responses in primary cultures of mouse cardiomyocytes induced by Trypanosoma cruzi trypomastigotes

Trypanosoma cruzi, the protozoan responsible for Chagas disease, employs distinct strategies to invade mammalian host cells. In the present work we investigated the participation of calcium ions on the invasion process using primary cultures of embryonic mice cardiomyocytes which exhibit spontaneous contraction in vitro. Using Fura 2-AM we found that T. cruzi was able to induce a sustained increase in basal intracellular Ca2+ level in heart muscle cells (HMC), the response being associated or not with Ca2+ transient peaks. Assays performed with both Y and CL strains indicated that the changes in intracellular Ca2+ started after parasites contacted with the cardiomyocytes and the evoked response was higher than the Ca2+ signal associated to the spontaneous contractions. The possible role of the extracellular and intracellular Ca2+ levels on T. cruzi invasion process was evaluated using the extracellular Ca2+ chelator EGTA alone or in association with the calcium ionophore A23187. Significant dose dependent inhibition of the invasion levels were found when intracellular calcium release was prevented by the association of EGTA +A23187 in calcium free medium. Dose response experiments indicated that EGTA 2.5 mM to 5 mM decreased the invasion level by 15.2 to 35.1% while A23187 (0.5 M) alone did not induce significant effects (17%); treatment of the cultures with the protease inhibitor leupeptin did not affect the endocytic index, thus arguing against the involvement of leupeptin sensitive proteases in the invasion of HMC.     

Ca2+ signaling, mitochondria and cell death

In the complex interplay that allows different signals to be decoded into activation of cell death, calcium (Ca2+) plays a significant role. In all eukaryotic cells, the cytosolic concentration of Ca2+ ions ([Ca2+]c) is tightly controlled by interactions among transporters, pumps, channels and binding proteins. Finely tuned changes in [Ca2+]c modulate a variety of intracellular functions ranging from muscular contraction to secretion, and disruption of Ca2+ handling leads to cell death. In this context, Ca2+ signals have been shown to affect important checkpoints of the cell death process, such as mitochondria, thus tuning the sensitivity of cells to various challenges. In this contribution, we will review (i) the evidence supporting the involvement of Ca2+ in the three major process of cell death: apoptosis, necrosis and autophagy (ii) the complex signaling interplay that allows cell death signals to be decoded into mitochondria as messages controlling cell fate.     

Regulation of calcium signaling by the second messenger cyclic adenosine diphosphoribose (cADPR)

Ca2+ ions are involved in the regulation of many diverse functions in animal and plant cells, e.g. muscle contraction, secretion of neurotransmitters, hormones and enzymes, fertilization of oocytes, and lymphocyte activation and proliferation. The intracellular Ca2+ concentration can be increased by different molecular mechanisms, such as Ca2+ influx from the extracellular space or Ca2+ release from intracellular Ca2+ stores. Release from intracellular Ca2+ stores is accomplished by the small molecular compounds D-myo-inositol 1,4,5-trisphosphate (InsP3), cyclic ADP-ribose (cADPR) and nicotinic acid adenine dinucleotide phosphate (NAADP). This review will focus on the effects of cADPR in different cells and tissues, the mechanisms of cADPR-mediated Ca2+ release and Ca2+ entry, extracellular effects of cADPR, and the role of cADPR in a cell system studied in detail, human T-lymphocytes.     

Mitochondria as biosensors of calcium microdomains

The notion that the agonist-dependent increases in intracellular Ca2+ concentration, on ubiquitous signalling mechanism, occur with a tightly regulated spatio-temporal pattern has become an established concept in modern cell biology. As a consequence, the concept is emerging that the recruitment of specific intracellular targets and effector system mechanisms depends on exposure to local [Ca2+] that differs substantially from the mean [Ca2+]. A striking example is provided by mitochondria, intracellular organelles that have been overlooked for a long time in the field of calcium signalling due to the low affinity of their Ca(2+)-uptake pathways. We will summarize here some of the evidence indicating that these organelles actively participate in Ca2+ homeostasis in physiological conditions (with consequences not only for the control of their function, but also for the modulation of the complexity of calcium signals) because they have the capability to respond to microdomains of high [Ca2+] transiently generated in their proximity by the opening of Ca2+ channels.