Remodelling Ca2+ signalling systems and cardiac hypertrophy.

In cardiac cells, Ca2+ signals appear as brief transients responsible for controlling both contraction and transcription. Information may be encoded in these digital signals through changes in both frequency and shape. An increase in Ca2+ signalling contributes to a process of phenotypic remodelling during hypertrophy. The increase in Ca2+ that drives the larger contractions may be responsible for switching on a second process of signalosome remodelling to down-regulate the Ca2+ signalling pathway. It is a change in the properties of the Ca2+ transient that seems to carry the information responsible for the remodelling of the cardiac gene transcription programme that leads first to hypertrophy and then to congestive heart failure.

Cardiac calcium signalling.

Calcium regulates three different aspects of cardiac contraction. It drives pacemaker activity, excitation-contraction coupling and the transcriptional events that remodel the Ca(2+) signalling system in both health and disease.

Calcium puffs are generic InsP(3)-activated elementary calcium signals and are downregulated by prolonged hormonal stimulation to inhibit cellular calcium responses.

Elementary Ca(2+) signals, such as "Ca(2+) puffs", which arise from the activation of inositol 1,4,5-trisphosphate receptors, are building blocks for local and global Ca(2+) signalling. We characterized Ca(2+) puffs in six cell types that expressed differing ratios of the three inositol 1,4,5-trisphosphate receptor isoforms. The amplitudes, spatial spreads and kinetics of the events were similar in each of the cell types. The resemblance of Ca(2+) puffs in these cell types suggests that they are a generic elementary Ca(2+) signal and, furthermore, that the different inositol 1,4,5-trisphosphate isoforms are functionally redundant at the level of subcellular Ca(2+) signalling. Hormonal stimulation of SH-SY5Y neuroblastoma cells and HeLa cells for several hours downregulated inositol 1,4,5-trisphosphate expression and concomitantly altered the properties of the Ca(2+) puffs. The amplitude and duration of Ca(2+) puffs were substantially reduced. In addition, the number of Ca(2+) puff sites active during the onset of a Ca(2+) wave declined. The consequence of the changes in Ca(2+) puff properties was that cells displayed a lower propensity to trigger regenerative Ca(2+) waves. Therefore, Ca(2+) puffs underlie inositol 1,4,5-trisphosphate signalling in diverse cell types and are focal points for regulation of cellular responses.

The versatility and complexity of calcium signalling.

Ca2+ is a universal second messenger used to regulate a wide range of cellular processes such as fertilization, proliferation, contraction, secretion, learning and memory. Cells derive signal Ca2+ from both internal and external sources. The Ca2+ flowing through these channels constitute the elementary events of Ca2+ signalling. Ca2+ can act within milliseconds in highly localized regions or it can act much more slowly as a global wave that spreads the signal throughout the cell. Various pumps and exchangers are responsible for returning the elevated levels of Ca2+ back to the resting state. The mitochondrion also plays a critical role in that it helps the recovery process by taking Ca2+ up from the cytoplasm. Alterations in the ebb and flow of Ca2+ through the mitochondria can lead to cell death. A good example of the complexity of Ca2+ signalling is its role in regulating cell proliferation, such as the activation of lymphocytes. The Ca2+ signal needs to be present for over two hours and this prolonged period of signalling depends upon the entry of external Ca2+ through a process of capacitative Ca2+ entry. The Ca2+ signal stimulates gene transcription and thus initiates the cell cycle processes that culminate in cell division.

The organisation and functions of local Ca(2+) signals.

Calcium (Ca(2+)) is a ubiquitous intracellular messenger, controlling a diverse range of cellular processes, such as gene transcription, muscle contraction and cell proliferation. The ability of a simple ion such as Ca(2+) to play a pivotal role in cell biology results from the facility that cells have to shape Ca(2+) signals in space, time and amplitude. To generate and interpret the variety of observed Ca(2+) signals, different cell types employ components selected from a Ca(2+) signalling 'toolkit', which comprises an array of homeostatic and sensory mechanisms. By mixing and matching components from the toolkit, cells can obtain Ca(2+) signals that suit their physiology. Recent studies have demonstrated the importance of local Ca(2+) signals in defining the specificity of the interaction of Ca(2+) with its targets. Furthermore, local Ca(2+) signals are the triggers and building blocks for larger global signals that propagate throughout cells.

Mitochondrial Ca(2+) uptake depends on the spatial and temporal profile of cytosolic Ca(2+) signals.

Using confocal imaging of Rhod-2-loaded HeLa cells, we examined the ability of mitochondria to sequester Ca(2+) signals arising from different sources. Mitochondrial Ca(2+) (Ca(2+)mit) uptake was stimulated by inositol 1,4,5-trisphosphate (InsP(3))-evoked Ca(2+) release, capacitative Ca(2+) entry, and Ca(2+) leaking from the endoplasmic reticulum. For each Ca(2+) source, the relationship between cytosolic Ca(2+) (Ca(2+)cyt) concentration and Ca(2+)mit was complex. With Ca(2+)cyt < 300 nm, a slow and persistent Ca(2+)mit uptake was observed. If Ca(2+)cyt increased above approximately 400 nm, Ca(2+)mit uptake accelerated sharply. For equivalent Ca(2+)cyt increases, the rate of Ca(2+)mit rise was greater with InsP(3)-evoked Ca(2+) signals than any other source. Spatial variation of the Ca(2+)mit response was observed within individual cells. Both the fraction of responsive mitochondria and the amplitude of the Ca(2+)mit response were graded in direct proportion to stimulus concentration. Trains of repetitive Ca(2+) oscillations did not maintain elevated Ca(2+)mit levels. Only low frequency Ca(2+) transients (<1/15 min) evoked repetitive Ca(2+)mit signals. Our data indicate that there is a lag between Ca(2+)cyt and Ca(2+)mit increases but that mitochondria will accumulate calcium when it is elevated over basal levels regardless of its source. Furthermore, in addition to the characteristics of Ca(2+) signals, Ca(2+) uniporter desensitization and proximity of mitochondria to InsP(3) receptors modulate mitochondrial Ca(2+) responses.

Calcium signalling--an overview.

Calcium (Ca2+) is an almost universal intracellular messenger, controlling a diverse range of cellular processes, such as gene transcription, muscle contraction and cell proliferation. The ability of a simple ion such as Ca2+ to play a pivotal role in cell biology results from the facility that cells have to shape Ca2+ signals in the dimensions of space, time and amplitude. To generate the variety of observed Ca2+ signals, different cell types employ components selected from a Ca2+ signalling 'toolkit', which comprizes an array of signalling, homeostatic and sensory mechanisms. By mixing and matching components from the toolkit, cells can obtain Ca2+ signals that suit their physiology.

Predetermined recruitment of calcium release sites underlies excitation-contraction coupling in rat atrial myocytes.

Excitation-contraction coupling (E-C coupling) was studied in isolated fluo-3-loaded rat atrial myocytes at 22 and 37 degrees C using rapid confocal microscopy. Within a few milliseconds of electrical excitation, spatially discrete subsarcolemmal Ca2+ signals were initiated. Twenty to forty milliseconds after stimulation the spatial overlap of these Ca2+ signals gave a 'ring' of elevated Ca2+ around the periphery of the cells. However, this ring was not continuous and substantial Ca2+ gradients were observed. The discrete subsarcolemmal Ca2+-release sites, which responded in a reproducible sequence to repetitive depolarisations and displayed the highest frequencies of spontaneous Ca2+ sparks in resting cells, were denoted 'eager sites'. Immunostaining atrial myocytes for type II ryanodine receptors (RyRs) revealed both subsarcolemmal 'junctional' RyRs, and also 'non-junctional' RyRs in the central bulk of the cells. A subset of the junctional RyRs comprises the eager sites. For cells paced in the presence of 1 mM extracellular Ca2+, the response was largely restricted to a subsarcolemmal 'ring', while the central bulk of the cell displayed a approximately 5-fold lower Ca2+ signal. Under these conditions the non-junctional RyRs were only weakly activated during E-C coupling. However, these channels are functional and the Ca2+ stores were at least partially loaded, since substantial homogeneous Ca2+ signals could be stimulated in the central regions of atrial myocytes by application of 2.5 mM caffeine. Neither the location nor activation order of the eager sites was affected by increasing the trigger Ca2+ current (by increasing extracellular Ca2+ to 10 mM) or the sarcoplasmic reticulum (SR) Ca2+ load (following 1 min incubation in 10 mM extracellular Ca2+), although with increased SR Ca2+ load, but not greater Ca2+ influx, the delay between the sequential activation of eager sites was reduced. In addition, increasing the trigger Ca2+ current or the SR Ca2+ load changed the spatial pattern of the Ca2+ response, in that the Ca2+ signal propagated more reliably from the subsarcolemmal initiation sites into the centre of the cell. Due to the greater spatial spread of the Ca2+ signals, the averaged global Ca2+ transients increased by approximately 500 %. We conclude that rat atrial myocytes display a predetermined spatiotemporal pattern of Ca2+ signalling during early E-C coupling. A consistent set of eager Ca2+ release sites with a fixed location and activation order on the junctional SR serve to initiate the cellular response. The short latency for activation of these eager sites suggests that they reflect clusters of RyRs closely coupled to voltage-operated Ca2+ channels in the sarcolemma. Furthermore, their propensity to show spontaneous Ca2+ sparks is consistent with an intrinsically higher sensitivity to Ca2+-induced Ca2+ release. While the subsarcolemmal Ca2+ response can be considered as stereotypic, the central bulk of the cell grades its response in direct proportion to cellular Ca2+ load and Ca2+ influx.

A comparison of fluorescent Ca2+ indicator properties and their use in measuring elementary and global Ca2+ signals.

Quantifying the magnitude of Ca2+ signals from changes in the emission of fluorescent indicators relies on assumptions about the indicator behaviour in situ. Factors such as osmolarity, pH, ionic strength and protein environment can affect indicator properties making it advantageous to calibrate indicators within the required cellular or subcellular environment. Selecting Ca2+ indicators appropriate for a particular application depends upon several considerations including Ca2+ binding affinity, dynamic range and ease of loading. These factors are usually best determined empirically. This study describes the in-situ calibration of a number of frequently used fluorescent Ca2+ indicators (Fluo-3, Fluo-4, Calcium Green-1, Calcium Orange, Oregon Green 488 BAPTA-1 and Fura-Red) and their use in reporting low- and high-amplitude Ca2+ signals in HeLa cells. All Ca2+ indicators exhibited lower in-situ Ca2+ binding affinities than suggested by previously published in-vitro determinations. Furthermore, for some of the indicators, there were significant differences in the apparent Ca2+ binding affinities between nuclear and cytoplasmic compartments. Variation between indicators was also found in their dynamic ranges, compartmentalization, leakage and photostability. Overall, Fluo-3 proved to be the generally most applicable Ca2+ indicator, since it displayed a large dynamic range, low compartmentalization and an appropriate apparent Ca2+ binding affinity. However, it was more susceptible to photobleaching than many of the other Ca2+ indicators.

Calcium-modulating cyclophilin ligand desensitizes hormone-evoked calcium release.

The Ca(2+)-modulating cyclophilin ligand (CAML) protein causes stimulation of transcription factors via activation of a store-operated Ca(2+) entry pathway. Since CAML is widely expressed in mammalian tissues, it may be an important regulator of Ca(2+) store function. In the present study, we investigated the consequence of CAML overexpression on Ca(2+) signaling using rapid confocal imaging of Fluo3-loaded NIH3T3 fibroblasts. Control and CAML-expressing cells gave concentration-dependent responses to the Ca(2+) mobilizing agonist ATP. CAML expression reduced the sensitivity of the cells so that higher concentrations of ATP were needed to achieve global Ca(2+) waves. The amplitudes of Ca(2+) waves were significantly reduced in CAML expressing cells, consistent with earlier suggestions that CAML causes depletion of internal Ca(2+) stores. With low ATP concentrations, only local Ca(2+) release events were observed. CAML did not affect the characteristics of these local Ca(2+) signals, suggesting that it does not directly affect Ca(2+) release channels.

Functional InsP3 receptors that may modulate excitation-contraction coupling in the heart.

The roles of the Ca2+-mobilising messenger inositol 1,4,5-trisphosphate (InsP3) in heart are unclear, although many hormones activate InsP3 production in cardiomyocytes and some of their inotropic, chronotropic and arrhythmogenic effects may be due to Ca2+ release mediated by InsP3 receptors (InsP3Rs) [1-3]. In the present study, we examined the expression and subcellular localisation of InsP3R isoforms, and investigated their potential role in modulating excitation-contraction coupling (EC coupling). Western, PCR and InsP3-binding analysis indicated that both atrial and ventricular myocytes expressed mainly type II InsP3Rs, with approximately sixfold higher levels of InsP3Rs in atrial cells. Co-immunostaining of atrial myocytes with antibodies against type II ryanodine receptors (RyRs) and type II InsP3Rs revealed that the latter were arranged in the subsarcolemmal space where they largely co-localised with the junctional RyRs. Stimulation of quiescent or electrically paced atrial myocytes with a membrane-permeant InsP3 ester, which enters cells and directly activates InsP3Rs, caused the appearance of spontaneous Ca2+-release events. In addition, in paced cells, the InsP3 ester evoked an increase in the amplitudes of action potential-evoked Ca2+ transients. These data indicate that atrial cardiomyocytes express functional InsP3Rs, and that these channels could modulate EC coupling.

Regulation of fertilization-induced Ca(2+)spiking in the mouse zygote.

Fertilization-induced Ca(2+)spiking in mouse zygotes ceases at the end of pre-G1 as pronuclei (PN) form. In the present studies we found that there was no consistent temporal relationship between PN formation and cessation of spiking. We also show that nucleate and anucleate fragments of zygotes, obtained by bisection of fertilized eggs prior to PN formation, both ceased spiking at times that did not depend on the presence of the PN. We, therefore, concluded that formation of the PN does not cause spiking cessation. The possibility that cessation of the fertilization-induced Ca(2+)spiking may be mediated by a redox sensitive mechanism affecting the sensitivity of Ca(2+)release from internal stores is proposed. At first mitosis, a small proportion of zygotes show low amplitude calcium spikes prior to pronuclear envelope breakdown (PNEBD), whereas all zygotes spiked at this time in the presence of high extracellular Ca(2+)and dithiothreitol. Nucleated zygotic fragments also spiked before PNEBD whereas anucleated ones rarely did. Exit from G2 was required for this spiking to be observed in nucleated zygotes or fragments. Arrest in M-phase resulted in the appearance of a prolonged series of small amplitude spikes. It is concluded that the spiking at mitosis is cell cycle regulated and may differ qualitatively in its control from that at fertilization.

Nuclear calcium signalling.

The topic of nuclear Ca2+ signalling is beset by discrepant observations of substantial nuclear/cytoplasmic gradients. The reasons why some labs have recorded such gradients, whilst other workers see equilibration of Ca2+(cyt) and Ca2+(nuc) using the same cells and techniques, is unexplained. Furthermore, how such gradients could arise across the NE that possesses many highly-conductive NPCs is a mystery. Although nuclei may have the capacity to be autonomous signalling entities, with functional Ca2+ release channels and an inositide cycle, the balance of evidence suggests that Ca2+ release on the inner NE does not occur during physiological stimulation. Our work suggests that elementary Ca2+ release events originating in the cytoplasm can give rise to Ca2+ signals without causing elevation of the bulk cytoplasm. Clearly, the many Ca2+ signalling mechanisms that may impinge on Ca2+(nuc) will remain a topic of controversy and debate for some time.

Inositol 1,4,5-trisphosphate-induced Ca2+ release is inhibited by mitochondrial depolarization.

We investigated the consequences of depolarizing the mitochondrial membrane potential (Deltapsi(mit)) on Ca(2+) signals arising via inositol 1,4,5-trisphosphate receptors (InsP(3)R) in hormone-stimulated HeLa cells. Carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) or a mixture of antimycin A+oligomycin were found to rapidly depolarize Deltapsi(mit). Mitochondrial depolarization enhanced the number of cells responding to a brief application of a Ca(2+)-mobilizing hormone and prolonged the recovery of cytosolic Ca(2+) after washout of the hormone; effects consistent with the removal of a passive Ca(2+) buffer. However, with repeated application of the same hormone concentration both the number of responsive cells and peak Ca(2+) changes were observed to progressively decline. The inhibition of Ca(2+) signalling was observed using different Ca(2+)-mobilizing hormones and also with a membrane-permeant Ins(1,4,5)P(3) ester. Upon washout of FCCP, the Ca(2+) signals recovered with a time course similar to the re-establishment of Deltapsi(mit). Global measurements indicated that none of the obvious factors such as changes in pH, ATP concentration, cellular redox state, permeability transition pore activation or reduction in Ca(2+)-store loading appeared to underlie the inhibition of Ca(2+) signalling. We therefore suggest that local changes in one or more of these factors, as a consequence of depolarizing Deltapsi(mit), prevents InsP(3)R activation.

Microscopic properties of elementary Ca2+ release sites in non-excitable cells.

BACKGROUND: Elementary Ca2+ signals, such as 'Ca2+ puffs', that arise from the activation of clusters of inositol 1 ,4,5,-trisphosphate (InsP3) receptors are the building blocks for local and global Ca2+ signalling. We previously found that one, or a few, Ca2+ puff sites within agonist-stimulated cells act as 'pacemakers' to initiate global Ca2+ waves. The factors that distinguish these pacemaker Ca2+ puff sites from the other Ca2+ release sites that simply participate in Ca2+ wave propagation are unknown. RESULTS: The spatiotemporal properties of Ca2+ puffs were investigated using confocal microscopy of fluo3-loaded HeLa cells. The same pacemaker Ca2+ puff sites were activated during stimulation of cells with different agonists. The majority of agonist-stimulated pacemaker Ca2+ puffs originated in a perinuclear location. The positions of such Ca2+ puff sites were stable for up to 2 hours, and were not affected by disruption of the actin cytoskeleton. A similar perinuclear distribution of Ca2+ puff sites was also observed when InsP3 receptors were directly stimulated with thimerosal or membrane-permeant InsP3 esters. Immunostaining indicated that the perinuclear position of pacemaker Ca2+ puffs was not due to the localised expression of InsP3 receptors. CONCLUSIONS: The pacemaker Ca2+ puff sites that initiate Ca2+ responses are temporally and spatially stable within cells. These Ca2+ release sites are distinguished from their neighbours by an intrinsically higher InsP3 sensitivity.

The versatility and universality of calcium signalling.

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.

Regulation of ryanodine receptor opening by lumenal Ca(2+) underlies quantal Ca(2+) release in PC12 cells.

Graded or "quantal" Ca(2+) release from intracellular stores has been observed in various cell types following activation of either ryanodine receptors (RyR) or inositol 1,4,5-trisphosphate receptors (InsP(3)R). The mechanism causing the release of Ca(2+) stores in direct proportion to the strength of stimulation is unresolved. We investigated the properties of quantal Ca(2+) release evoked by activation of RyR in PC12 cells, and in particular whether the sensitivity of RyR to the agonist caffeine was altered by lumenal Ca(2+). Quantal Ca(2+) release was observed in cells stimulated with 1 to 40 mM caffeine, a range of caffeine concentrations giving a >10-fold change in lumenal Ca(2+) content. The Ca(2+) load of the caffeine-sensitive stores was modulated by allowing them to refill for varying times after complete discharge with maximal caffeine, or by depolarizing the cells with K(+) to enhance their normal steady-state loading. The threshold for RyR activation was sensitized approximately 10-fold as the Ca(2+) load increased from a minimal to a maximal loading. In addition, the fraction of Ca(2+) released by low caffeine concentrations increased. Our data suggest that RyR are sensitive to lumenal Ca(2+) over the full range of Ca(2+) loads that can be achieved in an intact PC12 cell, and that changes in RyR sensitivity may be responsible for the termination of Ca(2+) release underlying the quantal effect.

Molecular cloning and immunolocalization of a novel vertebrate trp homologue from Xenopus.

We report the sequence, structure and distribution of a novel transient receptor potential (trp) homologue from Xenopus, Xtrp, determined by screening an oocyte cDNA library. On the basis of sequence similarity and predicted structure, Xtrp appears to be a homologue of mammalian trp1 proteins. Two polyclonal antibodies raised against distinct regions of the Xtrp sequence revealed Xtrp expression in various Xenopus tissues, and the localization of Xtrp at the plasma membrane of Xenopus oocytes and HeLa cells. Since capacitative calcium entry into Xenopus oocytes has been shown previously to be substantially inhibited by trp1 antisense oligonucleotides [Tomita, Kaneko, Funayama, Kondo, Satoh and Akaike (1998) Neurosci. Lett. 248, 195-198] we suggest that Xtrp may underlie capacitative calcium entry in Xenopus tissues.

Characterization of elementary Ca2+ release signals in NGF-differentiated PC12 cells and hippocampal neurons.

Elementary Ca2+ release signals in nerve growth factor- (NGF-) differentiated PC12 cells and hippocampal neurons, functionally analogous to the "Ca2+ sparks" and "Ca2+ puffs" identified in other cell types, were characterized by confocal microscopy. They either occurred spontaneously or could be activated by caffeine and metabotropic agonists. The release events were dissimilar to the sparks and puffs described so far, as many arose from clusters of both ryanodine receptors (RyRs) and inositol 1,4,5-trisphosphate receptors (InsP3Rs). Increasing either the stimulus strength or loading of the intracellular stores enhanced the frequency of and coupling between elementary release sites and evoked global Ca2+ signals. In the PC12 cells, the elementary Ca2+ release preferentially occurred around the branch points. Spatio-temporal recruitment of such elementary release events may regulate neuronal activities.