Fusion of Aequorea victoria GFP and aequorin provides their Ca(2+)-induced interaction that results in red shift of GFP absorption and efficient bioluminescence energy transfer

The bioluminescence emitted by Aequorea victoria jellyfish is greenish while its single bioluminescent photoprotein aequorin emits blue light. This phenomenon may be explained by a bioluminescence resonance energy transfer (BRET) from aequorin chromophore to green fluorescent protein (GFP) co-localized with it. However, a slight overlapping of the aequorin bioluminescence spectrum with the GFP absorption spectrum and the absence of marked interaction between these proteins in vitro pose a question on the mechanism providing the efficient BRET in A. victoria. Here we report the in vitro study of BRET between homologous Ca(2+)-activated photoproteins, aequorin or obelin (Obelia longissima), as bioluminescence energy donors, and GFP, as an acceptor. The fusions containing donor and acceptor proteins linked by a 19 aa peptide were purified after expressing their genes in Escherichia coli cells. It was shown that the GFP-aequorin fusion has a significantly greater BRET efficiency, compared to the GFP-obelin fusion. Two main factors responsible for the difference in BRET efficiency of these fusions were revealed. First, it is the presence of Ca(2+)-induced interaction between the donor and acceptor in the aequorin-containing fusion and the absence of the interaction in the obelin-containing fusion. Second, it is a red shift of GFP absorption toward better overlapping with aequorin bioluminescence induced by the interaction of aequorin with GFP. Since the connection of the two proteins in vitro mimics their proximity in vivo, Ca(2+)-induced interaction between aequorin and GFP may occur in A. victoria jellyfish providing efficient BRET in this organism.     

Homogeneous assay for biotin based on Aequorea victoria bioluminescence resonance energy transfer system

Here we describe a homogeneous assay for biotin based on bioluminescence resonance energy transfer (BRET) between aequorin and enhanced green fluorescent protein (EGFP). The fusions of aequorin with streptavidin (SAV) and EGFP with biotin carboxyl carrier protein (BCCP) were purified after expression of the corresponding genes in Escherichia coli cells. Association of SAV-aequorin and BCCP-EGFP fusions was followed by BRET between aequorin (donor) and EGFP (acceptor), resulting in significantly increasing 510 nm and decreasing 470 nm bioluminescence intensity. It was shown that free biotin inhibited BRET due to its competition with BCCP-EGFP for binding to SAV-aequorin. These properties were exploited to demonstrate competitive homogeneous BRET assay for biotin.     

Red-shifted aequorin-based bioluminescent reporters for in vivo imaging of Ca2 signaling

Real-time visualization of calcium (Ca(2+)) dynamics in the whole animal will enable important advances in understanding the complexities of cellular function. The genetically encoded bioluminescent Ca(2+) reporter green fluorescent protein-aequorin (GA) allows noninvasive detection of intracellular Ca(2+) signaling in freely moving mice. However, the emission spectrum of GA is not optimal for detection of activity from deep tissues in the whole animal. To overcome this limitation, two new reporter genes were constructed by fusing the yellow fluorescent protein (Venus) and the monomeric red fluorescent protein (mRFP1) to aequorin. Transfer of aequorin chemiluminescence energy to Venus (VA) is highly efficient and produces a 58 nm red shift in the peak emission spectrum of aequorin. This substantially improves photon transmission through tissue, such as the skin and thoracic cage. Although the Ca(2+)-induced bioluminescence spectrum of mRFP1-aequorin (RA) is similar to that of aequorin, there is also a small peak above 600 nm corresponding to the peak emission of mRFP1. Small amounts of energy transfer between aequorin and mRFP1 yield an emission spectrum with the highest percentage of total light above 600 nm compared with GA and VA. Accordingly, RA is also detected with higher sensitivity from brain areas. VA and RA will therefore improve optical access to Ca(2+) signaling events in deeper tissues, such as the heart and brain, and offer insight for engineering new hybrid molecules.     

Presenilin mutations linked to familial Alzheimer's disease reduce endoplasmic reticulum and Golgi apparatus calcium levels

Presenilin-1 and -2 (PS1 and PS2) mutations, the major cause of familial Alzheimer's disease (FAD), have been causally implicated in the pathogenesis of neuronal cell death through a perturbation of cellular Ca(2+) homeostasis. We have recently shown that, at variance with previous suggestions obtained in cells expressing other FAD-linked PS mutations, PS2-M239I and PS2-T122R cause a reduction and not an increase in cytosolic Ca(2+) rises induced by Ca(2+) release from stores. In this contribution we have used different cell models: human fibroblasts from controls and FAD patients, cell lines (SH-SY5Y, HeLa, HEK293, MEFs) and rat primary neurons expressing a number of PS mutations, e.g. P117L, M146L, L286V, and A246E in PS1 and M239I, T122R, and N141I in PS2. The effects of FAD-linked PS mutations on cytosolic Ca(2+) changes have been monitored either by using fura-2 or recombinant cytosolic aequorin as the probe. Independently of the cell model or the employed probe, the cytosolic Ca(2+) increases, caused by agonist stimulation or full store depletion by drug treatment, were reduced or unchanged in cells expressing the PS mutations. Using aequorins, targeted to the endoplasmic reticulum or the Golgi apparatus, we here show that FAD-linked PS mutants lower the Ca(2+) content of intracellular stores. The phenomenon was most prominent in cells expressing PS2 mutants, and was observed also in cells expressing the non-pathogenic, "loss-of-function" PS2-D366A mutation. Taken as a whole, our findings, while confirming the capability of presenilins to modify Ca(2+) homeostasis, suggest a re-evaluation of the "Ca(2+) overload" hypothesis in AD and a new working hypothesis is presented.     

Measurements of the free luminal ER Ca(2+) concentration with targeted "cameleon" fluorescent proteins

The free ER Ca(2+) concentration, [Ca(2+)](ER), is a key parameter that determines both the spatio-temporal pattern of Ca(2+) signals as well as the activity of ER-resident enzymes. Obtaining accurate, time-resolved measurements of the Ca(2+) activity within the ER is thus critical for our understanding of cell signaling. Such measurements, however, are particularly challenging given the highly dynamic nature of Ca(2+) signals, the complex architecture of the ER, and the difficulty of addressing probes specifically into the ER lumen. Prompted by these challenges, a number of ingenious approaches have been developed over the last years to measure ER Ca(2+) by optical means. The two main strategies used to date are Ca(2+)-sensitive synthetic dyes trapped into organelles and genetically encoded probes, based either on the photoprotein aequorin or on the green fluorescent protein (GFP). The GFP-based Ca(2+) indicators comprise the camgaroo and pericam probes based on a circularly permutated GFP, and the cameleon probes, which rely on the fluorescence resonance energy transfer (FRET) between two GFP mutants of different colors. Each approach offers unique advantages and suffers from specific drawbacks. In this review, we will discuss the advantages and pitfalls of using the genetically encoded "cameleon" Ca(2+) indicators for ER Ca(2+) measurements.     

α-Synuclein controls mitochondrial calcium homeostasis by enhancing endoplasmic reticulum-mitochondria interactions

α-Synuclein has a central role in Parkinson disease, but its physiological function and the mechanism leading to neuronal degeneration remain unknown. Because recent studies have highlighted a role for α-synuclein in regulating mitochondrial morphology and autophagic clearance, we investigated the effect of α-synuclein in HeLa cells on mitochondrial signaling properties focusing on Ca(2+) homeostasis, which controls essential bioenergetic functions. By using organelle-targeted Ca(2+)-sensitive aequorin probes, we demonstrated that α-synuclein positively affects Ca(2+) transfer from the endoplasmic reticulum to the mitochondria, augmenting the mitochondrial Ca(2+) transients elicited by agonists that induce endoplasmic reticulum Ca(2+) release. This effect is not dependent on the intrinsic Ca(2+) uptake capacity of mitochondria, as measured in permeabilized cells, but correlates with an increase in the number of endoplasmic reticulum-mitochondria interactions. This action specifically requires the presence of the C-terminal α-synuclein domain. Conversely, α-synuclein siRNA silencing markedly reduces mitochondrial Ca(2+) uptake, causing profound alterations in organelle morphology. The enhanced accumulation of α-synuclein into the cells causes the redistribution of α-synuclein to localized foci and, similarly to the silencing of α-synuclein, reduces the ability of mitochondria to accumulate Ca(2+). The absence of efficient Ca(2+) transfer from endoplasmic reticulum to mitochondria results in augmented autophagy that, in the long range, could compromise cellular bioenergetics. Overall, these findings demonstrate a key role for α-synuclein in the regulation of mitochondrial homeostasis in physiological conditions. Elevated α-synuclein expression and/or eventually alteration of the aggregation properties cause the redistribution of the protein within the cell and the loss of modulation on mitochondrial function.     

The prion protein and its paralogue Doppel affect calcium signaling in Chinese hamster ovary cells

The function of the prion protein (PrP(c)), implicated in transmissible spongiform encephalopathies (TSEs), is largely unknown. We examined the possible influence of PrP(c) on Ca(2+) homeostasis, by analyzing local Ca(2+) fluctuations in cells transfected with PrP(c) and Ca(2+)-sensitive aequorin chimeras targeted to defined subcellular compartments. In agonist-stimulated cells, the presence of PrP(c) sharply increases the Ca(2+) concentration of subplasma membrane Ca(2+) domains, a feature that may explain the impairment of Ca(2+)-dependent neuronal excitability observed in TSEs. PrP(c) also limits Ca(2+) release from the endoplasmic reticulum and Ca(2+) uptake by mitochondria, thus rendering unlikely the triggering of cell death pathways. Instead, cells expressing Doppel, a PrP(c) paralogue, display opposite effects, which, however, are abolished by the coexpression of PrP(c). These findings are consistent with the functional interplay and antagonistic role attributed to the proteins, whereby PrP(c) protects, and Doppel sensitizes, cells toward stress conditions.     

Multicolor imaging of Ca(2+) and protein kinase C signals using novel epifluorescence microscopy.

Dynamic changes in intracellular free Ca(2+) concentrations ([Ca(2+)](i)s) control many important cellular events, including binding of Ca(2+)-calmodulin (Ca(2+)-CaM) and phosphorylation by protein kinase C (PKC). The two signals compete for the same domains in certain substrates, such as myristoylated alanine-rich PKC-substrate (MARCKS). To observe the convergence and relative time of arrival of CaM and PKC signals at their shared domain of MARCKS, we need to image cells that are loaded with more than two fluorescent dyes at a reasonable speed. We have developed a simple and powerful multicolor imaging system using conventional fluorescence microscopy. The epifluorescence configuration uses a glass reflector and rotating filter wheels for excitation and emission paths. As it is free of dichroic (multichroic) mirrors, multiple fluorescence images can be acquired rapidly regardless of the colors of fluorophores. We visualized Ca(2+)-CaM and PKC together with the dynamics of their common target, MARCKS, in single live cells. Receptor-activation resulted in translocation of MARCKS from the plasma membrane to cytosol through its phosphorylation by PKC. By observing fluorescence resonance energy transfer, we also obtained direct evidence that Ca(2+)-CaM binds MARCKS to drag it away from the membrane in circumstances when Ca(2+)-mobilization predominates over PKC activation.     

Stable interactions between mitochondria and endoplasmic reticulum allow rapid accumulation of calcium in a subpopulation of mitochondria

To better understand the functional role of the mitochondrial network in shaping the Ca2+ signals in living cells, we took advantage both of the newest genetically engineered green fluorescent protein-based Ca2+ sensors ("Cameleons," "Camgaroos," and "Pericams") and of the classical Ca(2+)-sensitive photoprotein aequorin, all targeted to the mitochondrial matrix. The properties of the green fluorescent protein-based probes in terms of subcellular localization, photosensitivity, and Ca2+ affinity have been analyzed in detail. It is concluded that the ratiometric pericam is, at present, the most reliable mitochondrial Ca2+ probe for single cell studies, although this probe too is not devoid of problems. The results obtained with ratiometric pericam in single cells, combined with those obtained at the population level with aequorin, provide strong evidence demonstrating that the close vicinity of mitochondria to the Ca2+ release channels (and thus responsible for the fast uptake of Ca2+ by mitochondria upon receptor activation) are highly stable in time, suggesting the existence of specific interactions between mitochondria and the endoplasmic reticulum.     

The characterization of differential calcium signalling in tobacco guard cells

Two novel approaches for the study of Ca2+-mediated signal transduction in stomatal guard cells are described. Stimulus-induced changes in guard-cell cytosolic Ca2+ ([Ca2+]cyt) were monitored using viable stomata in epidermal strips of a transgenic line of Nicotiana plumbaginifolia expressing aequorin (the proteinous luminescent reporter of Ca2+) and in a new transgenic line in which aequorin expression was targeted specifically to the guard cells. The results indicated that abscisic acid (ABA)-induced stomatal closure was accompanied by increases in [Ca2+]cyt in epidermal strips. In addition to ABA, mechanical and low-temperature signals directly affected stomatal behaviour, promoting rapid closure. Elevations of guard-cell [Ca2+]cyt play a key role in the transduction of all three stimuli. However, there were striking differences in the magnitude and kinetics of the three responses. Studies using Ca2+ channel blockers and the Ca2+ chelator EGTA further suggested that mechanical and ABA signals primarily mobilize Ca2+ from intracellular store(s), whereas the influx of extracellular Ca2+ is a key component in the transduction of low-temperature signals. These results illustrate an aspect of Ca2+ signalling whereby the specificity of the response is encoded by different spatial or kinetic Ca2+ elevations.     

Transient expression of apoaequorin in zebrafish embryos: extending the ability to image calcium transients during later stages of development

When aequorin is microinjected into cleavage-stage zebrafish embryos, it is largely used up by ~24 hours. Thus, it is currently not possible to image Ca(2+) signals from later stages of zebrafish development using this approach. We have, therefore, developed protocols to express apoaequorin, i.e., the protein component of aequorin, transiently in zebrafish embryos and then reconstitute intact aequorin in vivo by loading the coelenterazine co-factor into the embryos separately. Two types of apoaequorin mRNA, aeq-mRNA and aeq::EGFP-mRNA, the latter containing the enhanced green fluorescent protein (EGFP) sequence, were in vitro transcribed and when these were microinjected into embryos, they successfully translated apoaequorin and a fusion protein of apoaequorin and EGFP (apoaequorin-EGFP), respectively. We show that aeq::EGFP -mRNA was more toxic to embryos than equivalent amounts of aeq-mRNA. In addition, in an in vitro reconstitution assay, apoaequorin-EGFP produced less luminescence than apoaequorin, after reconstitution with coelenterazine and with the addition of Ca(2+). Furthermore, when imaging intact coelenterazine-loaded embryos that expressed apoaequorin, Ca(2+ )signals from ~2.5 to 48 hpf were observed, with the spatio-temporal pattern of these signals up to 24 hpf, being comparable to that observed with aequorin. This transient aequorin expression approach using aeq-mRNA provides a valuable tool for monitoring Ca(2+ )signaling during the 2448 hpf period of zebrafish development. Thus, it effectively extends the aequorin-based Ca(2+) imaging window by an additional 24 hours.     

Cell volume regulation in response to hypotonicity is impaired in HeLa cells expressing a protein kinase Calpha mutant lacking kinase activity

The chloride conductance (G(Cl,swell)) that participates in the regulatory volume decrease process triggered by osmotic swelling in HeLa cells was impaired by removal of extracellular Ca(2+), depletion of intracellular Ca(2+) stores with thapsigargin, or by preloading the cells with BAPTA-AM (1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid). Furthermore, overnight exposure to the phorbol ester tetradecanoyl phorbol acetate and acute incubation with inhibitors of the conventional protein kinase C (PKC) isoforms bisindolylmaleimide I and G?6976 inhibited G(Cl,swell). Treatment of HeLa cells with U73122, a phospholipase C inhibitor, also prevented G(Cl,swell). Hypotonicity induced selective PKC alpha accumulation in the membrane/cytoskeleton fraction in fractionation experiments and translocation of a green fluorescent protein-PKC alpha fusion protein to the plasma membrane of transiently transfected HeLa cells. To further explore the role of PKCs in hypotonicity-induced G(Cl,swell), HeLa clones stably expressing either a kinase-dead dominant negative variant of the Ca(2+)-dependent PKC isoform alpha (PKC alpha K386R) or of the atypical PKC isoform zeta (PKCzeta K275W) were generated. G(Cl,swell) was significantly reduced in HeLa cells expressing the dominant negative PKC alpha mutant but remained unaltered in cells expressing dominant negative PKCzeta. These findings strongly implicate PKC alpha as a critical regulatory element that is required for efficient regulatory volume decrease in HeLa cells.     

The GAF domain of the cGMP-binding, cGMP-specific phosphodiesterase (PDE5) is a sensor and a sink for cGMP

We describe here a novel sensor for cGMP based on the GAF domain of the cGMP-binding, cGMP-specific phosphodiesterase 5 (PDE5) using bioluminescence resonance energy transfer (BRET). The wild type GAFa domain, capable of binding cGMP with high affinity, and a mutant (GAFa F163A) unable to bind cGMP were cloned as fusions between GFP and Rluc for BRET (2) assays. BRET (2) ratios of the wild type GAFa fusion protein, but not GAFa F163A, increased in the presence of cGMP but not cAMP. Higher basal BRET (2) ratios were observed in cells expressing the wild type GAFa domain than in cells expressing GAFa F163A. This was correlated with elevated basal intracellular levels of cGMP, indicating that the GAF domain could act as a sink for cGMP. The tandem GAF domains in full length PDE5 could also sequester cGMP when the catalytic activity of PDE5 was inhibited. Therefore, these results describe a cGMP sensor utilizing BRET (2) technology and experimentally demonstrate the reservoir of cGMP that can be present in cells that express cGMP-binding GAF domain-containing proteins. PDE5 is the target for the anti-impotence drug sildenafil citrate; therefore, this GAF-BRET (2) sensor could be used for the identification of novel compounds that inhibit cGMP binding to the GAF domain, thereby regulating PDE5 catalytic activity.     

Mitochondrial free [Ca(2+)] dynamics measured with a novel low-Ca(2+) affinity aequorin probe

Mitochondria have a very large capacity to accumulate Ca(2+) during cell stimulation driven by the mitochondrial membrane potential. Under these conditions, [Ca(2+)](M) (mitochondrial [Ca(2+)]) may well reach millimolar levels in a few seconds. Measuring the dynamics of [Ca(2+)](M) during prolonged stimulation has been previously precluded by the high Ca(2+) affinity of the probes available. We have now developed a mitochondrially targeted double-mutated form of the photoprotein aequorin which is able to measure [Ca(2+)] in the millimolar range for long periods of time without problems derived from aequorin consumption. We show in the present study that addition of Ca(2+) to permeabilized HeLa cells triggers an increase in [Ca(2+)](M) up to an steady state of approximately 2-3 mM in the absence of phosphate and 0.5-1 mM in the presence of phosphate, suggesting buffering or precipitation of calcium phosphate when the free [Ca(2+)] reaches 0.5-1 mM. Mitochondrial pH acidification partially re-dissolved these complexes. These millimolar [Ca(2+)](M) levels were stable for long periods of time provided the mitochondrial membrane potential was not collapsed. Silencing of the mitochondrial Ca(2+) uniporter largely reduced the rate of [Ca(2+)](M) increase, but the final steady-state [Ca(2+)](M) reached was similar. In intact cells, the new probe allows monitoring of agonist-induced increases of [Ca(2+)](M) without problems derived from aequorin consumption.     

Calcium Green FlAsH as a genetically targeted small-molecule calcium indicator

Intracellular Ca(2+) regulates numerous proteins and cellular functions and can vary substantially over submicron and submillisecond scales, so precisely localized fast detection is desirable. We have created a approximately 1-kDa biarsenical Ca(2+) indicator, called Calcium Green FlAsH (CaGF, 1), to probe [Ca(2+)] surrounding genetically targeted proteins. CaGF attached to a tetracysteine motif becomes ten-fold more fluorescent upon binding Ca(2+), with a K(d) of approximately 100 microM, <1-ms kinetics and good Mg(2+) rejection. In HeLa cells expressing tetracysteine-tagged connexin 43, CaGF labels gap junctions and reports Ca(2+) waves after injury. Total internal reflection microscopy of tetracysteine-tagged, CaGF-labeled alpha(1C) L-type calcium channels shows fast-rising depolarization-evoked Ca(2+) transients, whose lateral nonuniformity suggests that the probability of channel opening varies greatly over micron dimensions. With moderate Ca(2+) buffering, these transients decay surprisingly slowly, probably because most of the CaGF signal comes from closed channels feeling Ca(2+) from a tiny minority of clustered open channels. With high Ca(2+) buffering, CaGF signals decay as rapidly as the calcium currents, as expected for submicron Ca(2+) domains immediately surrounding active channels. Thus CaGF can report highly localized, rapid [Ca(2+)] dynamics.     

Mitochondrial uncoupling protein-4 regulates calcium homeostasis and sensitivity to store depletion-induced apoptosis in neural cells

An increase in the cytoplasmic-free Ca(2+) concentration mediates cellular responses to environmental signals that influence a range of processes, including gene expression, motility, secretion of hormones and neurotransmitters, changes in energy metabolism, and apoptosis. Mitochondria play important roles in cellular Ca(2+) homeostasis and signaling, but the roles of specific mitochondrial proteins in these processes are unknown. Uncoupling proteins (UCPs) are a family of proteins located in the inner mitochondrial membrane that can dissociate oxidative phosphorylation from respiration, thereby promoting heat production and decreasing oxyradical production. Here we show that UCP4, a neuronal UCP, influences store-operated Ca(2+) entry, a process in which depletion of endoplasmic reticulum Ca(2+) stores triggers Ca(2+) influx through plasma membrane "store-operated" channels. PC12 neural cells expressing human UCP4 exhibit reduced Ca(2+) entry in response to thapsigargin-induced endoplasmic reticulum Ca(2+) store depletion. The elevations of cytoplasmic and intramitochondrial Ca(2+) concentrations and mitochondrial oxidative stress induced by thapsigargin were attenuated in cells expressing UCP4. The stabilization of Ca(2+) homeostasis and preservation of mitochondrial function by UCP4 was correlated with reduced mitochondrial reactive oxygen species generation, oxidative stress, and Gadd153 up-regulation and increased resistance of the cells to death. Reduced Ca(2+)-dependent cytosolic phospholipase A2 activation and oxidative metabolism of arachidonic acid also contributed to the stabilization of mitochondrial function in cells expressing human UCP4. These findings demonstrate that UCP4 can regulate cellular Ca(2+) homeostasis, suggesting that UCPs may play roles in modulating Ca(2+) signaling in physiological and pathological conditions.     

Aluminum as a specific inhibitor of plant TPC1 Ca2+ channels

In plant cells, Al ion plays dual roles as an inducer and an inhibitor of Ca(2+) influx depending on the concentration. Here, the effects of Al on Ca(2+) signaling were assessed in tobacco BY-2 cells expressing aequorin and a putative plant Ca(2+) channel from Arabidopsis thaliana, AtTPC1 (two-pore channel 1). In wild-type cells (expressing only aequorin), Al treatment induced the generation of superoxide, and Ca(2+) influx was secondarily induced by superoxide. Higher Al concentrations inhibited the Al-stimulated and superoxide-mediated Ca(2+) influx, indicating that Ca(2+) channels responsive to reactive oxygen species (ROS) are blocked by high concentration of Al. H(2)O(2)-induced Ca(2+) influx was also inhibited by Al. Thus, inhibitory action of Al against ROS-induced Ca(2+) influx was confirmed. Similarly, known Ca(2+) channel blockers such as ions of La and Gd inhibited the H(2)O(2)-induced Ca(2+) influx. While La also inhibited the hypoosmotically induced Ca(2+) influx, Al showed no inhibitory effect against the hypoosmotic Ca(2+) influx. The effects of Al and La on Ca(2+) influx were also tested in the cell line overexpressing AtTPC1 and the cell line AtTPC1-dependently cosuppressing the endogenous TPC1 equivalents. Notably, responsiveness to H(2)O(2) was lost in the cosuppression cell line, thus TPC1 channels are required for ROS-responsive Ca(2+) influx. Data also suggested that hypoosmotic shock induces TPC1-independent Ca(2+) influx and Al shows no inhibitory action against the TPC1-independent event. In addition, AtTPC1 overexpression resulted in a marked increase in Al-sensitive Ca(2+) influx, indicating that TPC1 channels participate in osmotic Ca(2+) influx only when overexpressed. We concluded that members of TPC1 channel family are the only ROS-responsive Ca(2+) channels and are the possible targets of Al-dependent inhibition.     

A cytoplasmic Ca2+ functional assay for identifying and purifying endogenous cell signaling peptides in Arabidopsis seedlings: identification of AtRALF1 peptide

Transient increases in the cytoplasmic Ca(2+) concentration are key events that initiate many cellular signaling pathways in response to developmental and environmental cues in plants; however, only a few extracellular mediators regulating cytoplasmic Ca(2+) singling are known to date. To identify endogenous cell signaling peptides regulating cytoplasmic Ca(2+) signaling, Arabidopsis seedlings expressing aequorin were used for an in vivo luminescence assay for Ca(2+) changes. These seedlings were challenged with fractions derived from plant extracts. Multiple heat-stable, protease-sensitive peaks of calcium elevating activity were observed after fractionation of these extracts by high-performance liquid chromatography. Tandem mass spectrometry identified the predominant active molecule isolated by a series of such chromatographic separations as a 49-amino acid polypeptide, AtRALF1 (the rapid alkalinization factor protein family). Within 40 s of treatment with nanomolar concentrations of the natural or synthetic version of the peptides, the cytoplasmic Ca(2+) level increased and reached its maximum. Prior treatment with a Ca(2+) chelator or inhibitor of IP 3-dependent signaling partially suppressed the AtRALF1-induced Ca(2+) concentration increase, indicating the likely involvement of Ca(2+) influx across the plasma membrane as well as release of Ca(2+) from intracellular reserves. Ca(2+) imaging using seedlings expressing the FRET-based Ca(2+) sensor yellow cameleon (YC) 3.6 showed that AtRALF1 could induce an elevation in Ca(2+) concentration in the surface cells of the root consistent with the very rapid effects of addition of AtRALF1 on Ca(2+) levels as reported by aequorin. Our data support a model in which the RALF peptide mediates Ca(2+)-dependent signaling events through a cell surface receptor, where it may play a role in eliciting events linked to stress responses or the modulation of growth.     

Monitoring agonist-induced phospholipase C activation in live cells by fluorescence resonance energy transfer

Agonist-induced intracellular Ca(2+) signals following phospholipase C (PLC) activation display a variety of patterns, including transient, sustained, and oscillatory behavior. These Ca(2+) changes have been well characterized, but detailed kinetic analyses of PLC activation in single living cells is lacking, due to the absence of suitable indicators for use in vivo. Recently, green fluorescent protein-tagged pleckstrin homology domains have been employed to monitor PLC activation in single cells, based on (confocal) imaging of their fluorescence translocation from the membrane to the cytosol that occurs upon hydrolysis of phosphatidylinositol bisphosphate. Here we describe fluorescence resonance energy transfer between pleckstrin homology domains of PLCdelta1 tagged with cyan and yellow fluorescent proteins as a sensitive readout of phosphatidylinositol bisphosphate metabolism for use both in cell populations and in single cells. Fluorescence resonance energy transfer requires significantly less excitation intensity, enabling prolonged and fast data acquisition without the cell damage that limits confocal experiments. It also allows experiments on motile or extremely flat cells, and can be scaled to record from cell populations as well as single neurites. Characterization of responses to various agonists by this method reveals that stimuli that elicit very similar Ca(2+) mobilization responses can exhibit widely different kinetics of PLC activation, and that the latter appears to follow receptor activation more faithfully than the cytosolic Ca(2+) transient.