Monitoring Dynamic Changes In Mitochondrial Calcium Levels During Apoptosis Using A Genetically Encoded Calcium Sensor

Dynamic changes in intracellular calcium concentration in response to various stimuli regulates many cellular processes such as proliferation, differentiation, and apoptosis¹. During apoptosis, calcium accumulation in mitochondria promotes the release of pro-apoptotic factors from the mitochondria into the cytosol². It is therefore of interest to directly measure mitochondrial calcium in living cells in situ during apoptosis. High-resolution fluorescent imaging of cells loaded with dual-excitation ratiometric and non-ratiometric synthetic calcium indicator dyes has been proven to be a reliable and versatile tool to study various aspects of intracellular calcium signaling. Measuring cytosolic calcium fluxes using these techniques is relatively straightforward. However, measuring intramitochondrial calcium levels in intact cells using synthetic calcium indicators such as rhod-2 and rhod-FF is more challenging. Synthetic indicators targeted to mitochondria have blunted responses to repetitive increases in mitochondrial calcium, and disrupt mitochondrial morphology³. Additionally, synthetic indicators tend to leak out of mitochondria over several hours which makes them unsuitable for long-term experiments. Thus, genetically encoded calcium indicators based upon green fluorescent protein (GFP)⁴ or aequorin⁵ targeted to mitochondria have greatly facilitated measurement of mitochondrial calcium dynamics. Here, we describe a simple method for real-time measurement of mitochondrial calcium fluxes in response to different stimuli. The method is based on fluorescence microscopy of ''ratiometric-pericam'' which is selectively targeted to mitochondria. Ratiometric pericam is a calcium indicator based on a fusion of circularly permuted yellow fluorescent protein and calmodulin⁴. Binding of calcium to ratiometric pericam causes a shift of its excitation peak from 415 nm to 494 nm, while the emission spectrum, which peaks around 515 nm, remains unchanged. Ratiometric pericam binds a single calcium ion with a dissociation constant in vitro of ~1.7 μM⁴. These properties of ratiometric pericam allow the quantification of rapid and long-term changes in mitochondrial calcium concentration. Furthermore, we describe adaptation of this methodology to a standard wide-field calcium imaging microscope with commonly available filter sets. Using two distinct agonists, the purinergic agonist ATP and apoptosis-inducing drug staurosporine, we demonstrate that this method is appropriate for monitoring changes in mitochondrial calcium concentration with a temporal resolution of seconds to hours. Furthermore, we also demonstrate that ratiometric pericam is also useful for measuring mitochondrial fission/fragmentation during apoptosis. Thus, ratiometric pericam is particularly well suited for continuous long-term measurement of mitochondrial calcium dynamics during apoptosis.     

用于细胞核钙成像的新型钙指示剂的构建与鉴定

细胞核钙离子是基因转录等细胞核反应过程重要的调控因子.然而,细胞核内钙离子信号的调控机制尚不清楚.缺乏稳定的、敏感的细胞核钙指示剂,是导致其调控机制难以研究的重要原因之一.针对这一问题,设计了能够在细胞核内特异性表达的、具有核定位功能的钙指示剂.以基因编码钙指示剂（GECIs）家族成员GCaMP6为模板,首先融合了对钙离子不敏感的红色荧光蛋白tdTomato来对局部的钙信号进行量化,其次融合了核定位信号（NLS）,使GCaMP6能够特异定位于细胞核中.结果表明,NLS-GCaMP6-tdTomato能够在细胞核中有效发挥作用,并且在钙敏感性与动力学上,也与GCaMP6相当. 这一新型细胞核钙指示剂将为研究细胞核钙离子的功能及其调控机制提供新的方法与途径.     

Measurement of ionized calcium in normal human blood platelets

To measure the concentrations of cytosolic ionized calcium in platelets we used a calcium-sensitive fluorophor (Fura-2) with two different spectrofluorometers (Perkin-Elmer LS-5 and Fluorolog 222). Values obtained by these two instruments for the basal cytosolic ionized calcium concentration of resting platelets and those of agonist-activated platelets did not differ significantly. Both instruments were capable of monitoring the shifts in wavelengths induced by the dye-calcium complex, the ratio between absorbances at the two wavelengths (340/380 nm), and calcium concentrations continuously during agonist-induced platelet activation. We conclude that a relatively inexpensive instrument may be adequate for measuring ionized calcium in cells by this method, although sophisticated kinetic studies may require analytical or research-grade instruments.     

Structural basis of the ultrasensitive calcium indicator GCaMP6

GCaMP is one of the most widely used calcium indicators in neuronal imaging and calcium cell biology.The newly developed GCaMP6 shows superior brightness and ultrasensitivity to calcium concentration change.In this study,we determined crystal structures of Ca2+-bound GCaMP6 monomer and dimer and presented detailed structural analyses in comparison with its parent version GCaMP5G.Our analyses reveal the structural basis for the outperformance of this newly developed Ca2+indicator.Three substitution mutations and the resulting changes of local structure and interaction explain the ultrasensitivity and increased fluorescence intensity common to all three versions of GCaMP6.Each particular substitution in the three GCaMP6 is also structurally consistent with their differential sensitivity and intensity,maximizing the potential of using GCaMP6 in solving diverse problems in neuronal research and calcium signaling.Our studies shall also be beneficial to further structure-guided optimization of GCaMP and facilitate the design of novel calcium indicators.     

Measuring calcium dynamics in living cells with genetically encodable calcium indicators

Genetically encoded calcium indicators (GECIs) allow researchers to measure calcium dynamics in specific targeted locations within living cells. Such indicators enable dissection of the spatial and temporal control of calcium signaling processes. Here we review recent progress in the development of GECIs, highlighting which indicators are most appropriate for measuring calcium in specific organelles and localized domains in mammalian tissue culture cells. An overview of recent approaches that have been undertaken to ensure that the GECIs are minimally perturbed by the cellular environment is provided. Additionally, the procedures for introducing GECIs into mammalian cells, conducting calcium imaging experiments, and analyzing data are discussed. Because organelle-targeted indicators often pose an additional challenge, we underscore strategies for calibrating GECIs in these locations.     

A model of the single atrial cell: relation between calcium current and calcium release

The hypothesis that calcium release from the sarcoplasmic reticulum in cardiac muscle is induced by rises in free cytosolic calcium (Fabiato 1983, Am. J. Physiol 245) allows the possibility that the release could be at least partly regenerative. There would then be a non-linear relation between calcium current and calcium release. We have investigated this possibility in a single-cell version of the rabbit-atrial model developed by Hilgemann & Noble (1987, Proc. R. Soc. Lond. B 230). The model predicts different voltage ranges of activation for calcium-dependent processes (like the sodium-calcium exchange current, contraction or Fura-2 signals) and the calcium current, in agreement with the experimental results obtained by Earm et al. (1990, Proc. R. Soc. Lond. B 240) on exchange current tails, Cannell et al. (1987, Science, Wash. 238) by using Fura-2 signals, and Fedida et al. (1987, J. Physiol., Lond. 385) and Talo et al. (1988, Biology of isolated adult cardiac myocytes) by using contraction. However, when the Fura-2 concentration is sufficiently high (greater than 200 microM) the activation ranges become very similar as the buffering properties of Fura-2 are sufficient to remove the regenerative effect. It is therefore important to allow for the buffering properties of calcium indicators when investigating the correlation between calcium current and calcium release.     

Mitochondria: The calcium connection

Calcium handling by mitochondria is a key feature in cell life. It is involved in energy production for cell activity, in buffering and shaping cytosolic calcium rises and also in determining cell fate by triggering or preventing apoptosis. Both mitochondria and the mechanisms involved in the control of calcium homeostasis have been extensively studied, but they still provide researchers with long-standing or even new challenges. Technical improvements in the tools employed for the investigation of calcium dynamics have been–and are still–opening new perspectives in this field, and more prominently for mitochondria. In this review we present a state-of-the-art toolkit for calcium measurements, with major emphasis on the advantages of genetically encoded indicators. These indicators can be efficiently and selectively targeted to specific cellular sub-compartments, allowing previously unavailable high-definition calcium dynamic studies. We also summarize the main features of cellular and, in more detail, mitochondrial calcium handling, especially focusing on the latest breakthroughs in the field, such as the recent direct characterization of the calcium microdomains that occur on the mitochondrial surface upon cellular stimulation. Additionally, we provide a major example of the key role played by calcium in patho-physiology by briefly describing the extensively reported–albeit highly controversial–alterations of calcium homeostasis in Alzheimer's disease, casting lights on the possible alterations in mitochondrial calcium handling in this pathology.     

Advantages of calcium green-1 over other fluorescent dyes in measuring cytosolic calcium in platelets.

Fluorescent indicators are widely used in the measurements of cytosolic calcium in many cell types for many purposes because they are relatively easy to use. Notwithstanding, they have some defects to prevent accurate measurements under certain conditions, such as significant dye leakage and UV-quenching effect. Menadione, a representative quinone derivative with antiaggregating effect, is also UV-absorbent. To investigate whether menadione can affect the change of cytosolic calcium in platelets by agonist, we measured the change of cytosolic calcium level using calcium green-1. Since this dye has not been used previously in platelets, we determined that the optimal loading of calcium green-1 to platelets was achieved using 3 microM dye incubated for 60 min at 37 degrees C. Our study compared the use of calcium green-1 with fura-2 and fluo-3 (two widely used dyes) in measurements of cytosolic calcium. Fura-2 is UV-excited, so when menadione was treated in fura-2-loaded cells, it had a quenching effect. Fluo-3, the other visible fluorescent indicator, leaked from platelets very rapidly and required the use of anion channel blockers which are known to affect physiological response of platelets. Our study demonstrated that changes in cytosolic calcium levels can be accurately measured without these problems by using calcium green-1. We therefore were able to demonstrate that menadione inhibited calcium increase by thrombin in a dose-dependent manner similar to menadione's antiaggregating effect in platelets.     

Characterization and subcellular targeting of GCaMP-type genetically-encoded calcium indicators

Genetically-encoded calcium indicators (GECIs) hold the promise of monitoring [Ca(2+)] in selected populations of neurons and in specific cellular compartments. Relating GECI fluorescence to neuronal activity requires quantitative characterization. We have characterized a promising new genetically-encoded calcium indicator-GCaMP2-in mammalian pyramidal neurons. Fluorescence changes in response to single action potentials (17+/-10% DeltaF/F [mean+/-SD]) could be detected in some, but not all, neurons. Trains of high-frequency action potentials yielded robust responses (302+/-50% for trains of 40 action potentials at 83 Hz). Responses were similar in acute brain slices from in utero electroporated mice, indicating that long-term expression did not interfere with GCaMP2 function. Membrane-targeted versions of GCaMP2 did not yield larger signals than their non-targeted counterparts. We further targeted GCaMP2 to dendritic spines to monitor Ca(2+) accumulations evoked by activation of synaptic NMDA receptors. We observed robust DeltaF/F responses (range: 37%-264%) to single spine uncaging stimuli that were correlated with NMDA receptor currents measured through a somatic patch pipette. One major drawback of GCaMP2 was its low baseline fluorescence. Our results show that GCaMP2 is improved from the previous versions of GCaMP and may be suited to detect bursts of high-frequency action potentials and synaptic currents in vivo.     

Imaging of mitochondrial Ca2+ dynamics in astrocytes using cell-specific mitochondria-targeted GCaMP5G/6s: Mitochondrial Ca2+ uptake and cytosolic Ca2+ availability via the endoplasmic reticulum store

Mitochondrial Ca²⁺ plays a critical physiological role in cellular energy metabolism and signaling, and its overload contributes to various pathological conditions including neuronal apoptotic death in neurological diseases. Live cell mitochondrial Ca²⁺ imaging is an important approach to understand mitochondrial Ca²⁺ dynamics. Recently developed GCaMP genetically-encoded Ca²⁺ indicators provide unique opportunity for high sensitivity/resolution and cell type-specific mitochondrial Ca²⁺ imaging. In the current study, we implemented cell-specific mitochondrial targeting of GCaMP5G/6s (mito-GCaMP5G/6s) and used two-photon microscopy to image astrocytic and neuronal mitochondrial Ca²⁺ dynamics in culture, revealing Ca²⁺ uptake mechanism by these organelles in response to cell stimulation. Using these mitochondrial Ca²⁺ indicators, our results show that mitochondrial Ca²⁺ uptake in individual mitochondria in cultured astrocytes and neurons can be seen after stimulations by ATP and glutamate, respectively. We further studied the dependence of mitochondrial Ca²⁺ dynamics on cytosolic Ca²⁺ changes following ATP stimulation in cultured astrocytes by simultaneously imaging mitochondrial and cytosolic Ca²⁺ increase using mito-GCaMP5G and a synthetic organic Ca²⁺ indicator, x-Rhod-1, respectively. Combined with molecular intervention in Ca²⁺ signaling pathway, our results demonstrated that the mitochondrial Ca²⁺ uptake is tightly coupled with inositol 1,4,5-trisphosphate receptor-mediated Ca²⁺ release from the endoplasmic reticulum and the activation of G protein-coupled receptors. The current study provides a novel approach to image mitochondrial Ca²⁺ dynamics as well as Ca²⁺ interplay between the endoplasmic reticulum and mitochondria, which is relevant for neuronal and astrocytic functions in health and disease.     

Mitochondria determine the sequential propagation of the calcium macrodomains revealed by the super-resolution calcium lantern imaging

Despite the wide application of super-resolution(SR) microscopy in biological studies of cells, the technology is rarely used to monitor functional changes in live cells. By combining fast spinning disc-confocal structured illumination microscopy(SD-SIM)with loading of cytosolic fluorescent Ca~(2+) indicators, we have developed an SR method for visualization of regional Ca~(2+) dynamics and related cellular organelle morphology and dynamics, termed SR calcium lantern imaging. In COS-7 cells stimulated with ATP, we have identified various calcium macrodomains characterized by different types of Ca~(2+) release from endoplasmic reticulum(ER) stores. Finally, we demonstrated various roles of mitochondria in mediating calcium signals from different sources; while mitochondria can globally potentiate the Ca~(2+) entry associated with store release, mitochondria also locally control Ca~(2+) release from the neighboring ER stores and assist in their refilling processes.     

Assessment of cytosolic free calcium changes during ceramide-induced cell death in MDA-MB-231 breast cancer cells expressing the calcium sensor GCaMP6m

Alterations in Ca²⁺ signaling can regulate key cancer hallmarks such as proliferation, invasiveness and resistance to cell death. Changes in the regulation of intracellular Ca²⁺ and specific components of Ca²⁺ influx are a feature of several cancers and/or cancer subtypes, including the basal-like breast cancer subtype, which has a poor prognosis. The development of genetically encoded calcium indicators, such as GCaMP6, represents an opportunity to measure changes in intracellular free Ca²⁺ during processes relevant to breast cancer progression that occur over long periods (e.g. hours), such as cell death. This study describes the development of a MDA-MB-231 breast cancer cell line stably expressing GCaMP6m. The cell line retained the key features of this aggressive basal-like breast cancer cell line. Using this model, we defined alterations in relative cytosolic free Ca²⁺ ([Ca²⁺]_CYT) when the cells were treated with C2-ceramide. Cell death was measured simultaneously via assessment of propidium iodide permeability. Treatment with ceramide produced delayed and heterogeneous sustained increases in [Ca²⁺]_CYT. Where cell death occurred, [Ca²⁺]_CYT increases preceded cell death. The sustained increases in [Ca²⁺]_CYT were not related to the rapid morphological changes induced by ceramide. Silencing of the plasma membrane Ca²⁺ ATPase isoform 1 (PMCA1) was associated with an augmentation in ceramide-induced increases in [Ca²⁺]_CYT and also cell death. This work demonstrates the utility of GCaMP6 Ca²⁺ indicators for investigating [Ca²⁺]_CYT changes in breast cancer cells during events relevant to tumor progression, which occur over hours rather than minutes.     

Structural insight into enhanced calcium indicator GCaMP3 and GCaMPJ to promote further improvement

Genetically encoded Ca²⁺ indicators (GECI) are important for the measurement of Ca²⁺in vivo. GCaMP2, a widelyused GECI, has recently been iteratively improved. Among the improved variants, GCaMP3 exhibits significantly better fluorescent intensity. In this study, we developed a new GECI called GCaMPJ and determined the crystal structures of GCaMP3 and GCaMPJ. GCaMPJ has a 1.5- fold increase in fluorescence and 1.3-fold increase in calcium affinity over GCaMP3. Upon Ca²⁺ binding, GCaMP3 exhibits both monomeric and dimeric forms. The structural superposition of these two forms reveals the role of Arg-376 in improving monomer performance. However, GCaMPJ seldom forms dimers under conditions similar to GCaMP3. St ructural and mutagenesis studies on Tyr-380 confirmed its importance in blocking the cpEGFP β-barrel holes. Our study proposes an efficient tool for mapping Ca²⁺ signals in intact organs to facilitate the further improvement of GCaMP sensors.     

Green-to-Red Photoconversion of GCaMP

Genetically encoded calcium indicators (GECIs) permit imaging intracellular calcium transients. Among GECIs, the GFP-based GCaMPs are the most widely used because of their high sensitivity and rapid response to changes in intracellular calcium concentrations. Here we report that the fluorescence of GCaMPs—including GCaMP3, GCaMP5 and GCaMP6—can be converted from green to red following exposure to blue-green light (450–500 nm). This photoconversion occurs in both insect and mammalian cells and is enhanced in a low oxygen environment. The red fluorescent GCaMPs retained calcium responsiveness, albeit with reduced sensitivity. We identified several amino acid residues in GCaMP important for photoconversion and generated a GCaMP variant with increased photoconversion efficiency in cell culture. This light-induced spectral shift allows the ready labeling of specific, targeted sets of GCaMP-expressing cells for functional imaging in the red channel. Together, these findings indicate the potential for greater utility of existing GCaMP reagents, including transgenic animals.     

Thy1-GCaMP6 Transgenic Mice for Neuronal Population Imaging In Vivo

Genetically-encoded calcium indicators (GECIs) facilitate imaging activity of genetically defined neuronal populations in vivo. The high intracellular GECI concentrations required for in vivo imaging are usually achieved by viral gene transfer using adeno-associated viruses. Transgenic expression of GECIs promises important advantages, including homogeneous, repeatable, and stable expression without the need for invasive virus injections. Here we present the generation and characterization of transgenic mice expressing the GECIs GCaMP6s or GCaMP6f under the Thy1 promoter. We quantified GCaMP6 expression across brain regions and neurons and compared to other transgenic mice and AAV-mediated expression. We tested three mouse lines for imaging in the visual cortex in vivo and compared their performance to mice injected with AAV expressing GCaMP6. Furthermore, we show that GCaMP6 Thy1 transgenic mice are useful for long-term, high-sensitivity imaging in behaving mice.     

CRF facilitates calcium release from intracellular stores in midbrain dopamine neurons

Changes in cytosolic calcium are crucial for numerous processes including neuronal plasticity. This study investigates the regulation of cytosolic calcium by corticotropin-releasing factor (CRF) in midbrain dopamine neurons. The results demonstrate that CRF stimulates the release of intracellular calcium from stores through activation of adenylyl cyclase and PKA. Imaging and photolysis experiments showed that the calcium originated from dendrites and required both functional IP3 and ryanodine receptor channels. The elevation in cytosolic calcium potentiated calcium-sensitive potassium channels (sK) activated by action potentials and metabotropic Gq-coupled receptors for glutamate and acetylcholine. This increase in cytosolic calcium activated by postsynaptic Gs-coupled CRF receptors may represent a fundamental mechanism by which stress peptides and hormones can shape Gq-coupled receptor-mediated regulation of neuronal excitability and synaptic plasticity in dopamine neurons.     

Plant calcium signaling and monitoring: pros and cons and recent experimental approaches

Summary This review focusses on Ca²⁺-mediated plant cell signaling and optical methods for in vivo [Ca²⁺] monitoring and imaging in plants. The cytosolic free calcium concentration has long been considered the central cellular key in plants. However, more and more data are turning up that critically question this view. Conflicting arguments show that there are still many open questions. One conclusion is that the cytosolic free Ca²⁺ concentration is just one of many cellular network parameters orchestrating complex cellular signaling. Novel experimental strategies which unveil interference of cellular parameters and communication of transduction pathways are required to understand this network. To date only optical methods are able to provide both kinetic and spatial information about cellular key parameters simultaneously. Focussing on calcium there are currently three classes of calcium indicators employed (i.e., chemical fluorescent dyes, luminescent indicators, and green-fluorescent-protein-based indicators). Properties and capabilities as well as advantages and disadvantages of these indicators when used in plant systems are discussed. Finally, general experimental strategies are mentioned which are able to answer open questions raised here.Abbreviations CTZ coelenterazine - GFP green-fluorescent protein - FRET fluorescence resonance energy transfer - [Ca²⁺] calcium ion concentration - CaM calmodulin - CDPKs calmodulindomain protein kinases - IP₃ inositol 1,4,5-trisphosphate     

Optical measurement of presynaptic calcium currents.

Measurements of presynaptic calcium currents are vital to understanding the control of transmitter release. However, most presynaptic boutons in the vertebrate central nervous system are too small to allow electrical recordings of presynaptic calcium currents (I(Ca)pre). We therefore tested the possibility of measuring I(Ca)pre optically in boutons loaded with calcium-sensitive fluorophores. From a theoretical treatment of a system containing an endogenous buffer and an indicator, we determined the conditions necessary for the derivative of the stimulus-evoked change in indicator fluorescence to report I(Ca)pre accurately. Matching the calcium dissociation rates of the endogenous buffer and indicator allows the most precise optical measurements of I(Ca)pre. We tested our ability to measure I(Ca)pre in granule cells in rat cerebellar slices. The derivatives of stimulus-evoked fluorescence transients from slices loaded with the low-affinity calcium indicators magnesium green and mag-fura-5 had the same time courses and were unaffected by changes in calcium influx or indicator concentration. Thus both of these indicators were well suited to measuring I(Ca)pre. In contrast, the high-affinity indicator fura-2 distorted I(Ca)pre. The optically determined I(Ca)pre was well approximated by a Gaussian with a half-width of 650 micros at 24 degrees C and 340 micros at 34 degrees C.     

Localization of intracellular calcium release in cells injured by venom from the ectoparasitoid Nasonia vitripennis (Walker) (Hymenoptera: Pteromalidae) and dependence of calcium mobilization on G-protein activation

Venom from the ectoparasitic wasp Nasonia vitripennis induces cellular injury that appears to involve the release of intracellular calcium stores via the activation of phospholipase C, and culminates in oncotic death. A linkage between release of intracellular Ca2+ and oncosis has not been clearly established and was the focus of this study. When BTI-TN-5B1-4 cells were treated with suramin, an uncoupler of G-proteins, venom-induced swelling and oncotic death were inhibited in a dose-dependent manner for at least 24 h. Suramin also blocked increases in free cytosolic [Ca2+], arguing that venom induces calcium mobilization through G-protein signaling pathways. Endoplasmic reticulum (ER) was predicted to be the source of intracellular calcium release, but labeling with the fluorescent probe ER-tracker revealed no indication of organelle swelling or loss of membrane integrity as would be expected if the Ca(2+)-ATPase pump was disabled by crude venom. Incubation of cell monolayers with calmodulin or nitrendipine, modulators of ER calcium release channels, neither attenuated nor augmented the effects of wasp venom. These results suggest that wasp venom stimulates calcium release from ER compartments distinct from RyRs, L-type Ca2+ channels, and the Ca(2+)-ATPase pump, or calcium is released from some other intracellular store. A reduction of mitochondrial membrane potential delta psi(m) appeared to precede a rise in cytosolic free Ca2+ as evidenced by fluorescent microscopy using the calcium-sensitive probe fluo-4 AM. This argues that the initial insult to the cell resulting from venom elicits a rapid loss of (delta psi(m)), followed by unregulated calcium efflux from mitochondria into the cytosol. Mobilization of calcium in this fashion could stimulate cAMP formation, and subsequently promote calcium release from NAADP-sensitive stores.     

Genetically encoded indicators of cellular calcium dynamics based on troponin C and green fluorescent protein

Genetic calcium probes offer tremendous potential in the fields of neuroscience, cell biology, and pharmaceutical screening. Previously, ratiometric and non-ratiometric indicators of cellular calcium dynamics have been described that consist of mutants of the green fluorescent protein (GFP) as fluorophores and calmodulin as calcium-binding moiety in several configurations. However, these calmodulin-based types of probes have a series of deficiencies, such as reduced dynamic ranges, when expressed within transgenic organisms and lack of calcium sensitivity in certain targetings. We developed novel types of calcium probes based on troponin C variants from skeletal and cardiac muscle. These indicators have ratio changes up to 140%, K(d)s ranging from 470 nm to 29 microm, and improved subcellular targeting properties. We targeted the indicators to the plasma membrane of HEK293 cells and primary hippocampal neurons. Upon long lasting depolarization, submembrane calcium levels in hippocampal neurons were found to be in equilibrium with bulk cytosolic calcium levels, suggesting no standing gradient persists from the membrane toward the cytosol. We expect that such novel indicators using specialized calcium sensing proteins will be minimally interacting with the cellular biochemical machinery.