Direct Imaging of ER Calcium with Targeted-Esterase Induced Dye Loading (TED)

Visualization of calcium dynamics is important to understand the role of calcium in cell physiology. To examine calcium dynamics, synthetic fluorescent Ca²⁺ indictors have become popular. Here we demonstrate TED (= targeted-esterase induced dye loading), a method to improve the release of Ca²⁺ indicator dyes in the ER lumen of different cell types. To date, TED was used in cell lines, glial cells, and neurons in vitro. TED bases on efficient, recombinant targeting of a high carboxylesterase activity to the ER lumen using vector-constructs that express Carboxylesterases (CES). The latest TED vectors contain a core element of CES2 fused to a red fluorescent protein, thus enabling simultaneous two-color imaging. The dynamics of free calcium in the ER are imaged in one color, while the corresponding ER structure appears in red. At the beginning of the procedure, cells are transduced with a lentivirus. Subsequently, the infected cells are seeded on coverslips to finally enable live cell imaging. Then, living cells are incubated with the acetoxymethyl ester (AM-ester) form of low-affinity Ca²⁺ indicators, for instance Fluo5N-AM, Mag-Fluo4-AM, or Mag-Fura2-AM. The esterase activity in the ER cleaves off hydrophobic side chains from the AM form of the Ca²⁺ indicator and a hydrophilic fluorescent dye/Ca²⁺ complex is formed and trapped in the ER lumen. After dye loading, the cells are analyzed at an inverted confocal laser scanning microscope. Cells are continuously perfused with Ringer-like solutions and the ER calcium dynamics are directly visualized by time-lapse imaging. Calcium release from the ER is identified by a decrease in fluorescence intensity in regions of interest, whereas the refilling of the ER calcium store produces an increase in fluorescence intensity. Finally, the change in fluorescent intensity over time is determined by calculation of ΔF/F₀.     

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.     

Lack of evidence for presenilins as endoplasmic reticulum Ca2+ leak channels

Familial Alzheimer disease (FAD) is linked to mutations in the presenilin (PS) homologs. FAD mutant PS expression has several cellular consequences, including exaggerated intracellular Ca(2+) ([Ca(2+)](i)) signaling due to enhanced agonist sensitivity and increased magnitude of [Ca(2+)](i) signals. The mechanisms underlying these phenomena remain controversial. It has been proposed that PSs are constitutively active, passive endoplasmic reticulum (ER) Ca(2+) leak channels and that FAD PS mutations disrupt this function resulting in ER store overfilling that increases the driving force for release upon ER Ca(2+) release channel opening. To investigate this hypothesis, we employed multiple Ca(2+) imaging protocols and indicators to directly measure ER Ca(2+) dynamics in several cell systems. However, we did not observe consistent evidence that PSs act as ER Ca(2+) leak channels. Nevertheless, we confirmed observations made using indirect measurements employed in previous reports that proposed this hypothesis. Specifically, cells lacking PS or expressing a FAD-linked PS mutation displayed increased area under the ionomycin-induced [Ca(2+)](i) versus time curve (AI) compared with cells expressing WT PS. However, an ER-targeted Ca(2+) indicator revealed that this did not reflect overloaded ER stores. Monensin pretreatment selectively attenuated the AI in cells lacking PS or expressing a FAD PS allele. These findings contradict the hypothesis that PSs form ER Ca(2+) leak channels and highlight the need to use ER-targeted Ca(2+) indicators when studying ER Ca(2+) dynamics.     

Steady-state free Ca(2+) in the yeast endoplasmic reticulum reaches only 10 microM and is mainly controlled by the secretory pathway pump pmr1.

Over recent decades, diverse intracellular organelles have been recognized as key determinants of Ca(2+) signaling in eukaryotes. In yeast however, information on intra-organellar Ca(2+) concentrations is scarce, despite the demonstrated importance of Ca(2+) signals for this microorganism. Here, we directly monitored free Ca(2+) in the lumen of the endoplasmic reticulum (ER) of yeast cells, using a specifically targeted version of the Ca(2+)-sensitive photoprotein aequorin. Ca(2+) uptake into the yeast ER displayed characteristics distinctly different from the mammalian ER. At steady-state, the free Ca(2+) concentration in the ER lumen was limited to approximately 10 microM, and ER Ca(2+) sequestration was insensitive to thapsigargin, an inhibitor specific for mammalian ER Ca(2+) pumps. In pmr1 null mutants, free Ca(2+) in the ER was reduced by 50%. Our findings identify the secretory pathway pump Pmr1, predominantly localized in the Golgi, as a major component of ER Ca(2+) uptake activity in yeast.     

Highly cooperative dependence of sarco/endoplasmic reticulum calcium ATPase SERCA2a pump activity on cytosolic calcium in living cells

Sarco/endoplasmic reticulum (SR/ER) Ca(2+)-ATPase (SERCA) is an intracellular Ca(2+) pump localized on the SR/ER membrane. The role of SERCA in refilling intracellular Ca(2+) stores is pivotal for maintaining intracellular Ca(2+) homeostasis, and disturbed SERCA activity causes many disease phenotypes, including heart failure, diabetes, cancer, and Alzheimer disease. Although SERCA activity has been described using a simple enzyme activity equation, the dynamics of SERCA activity in living cells is still unknown. To monitor SERCA activity in living cells, we constructed an enhanced CFP (ECFP)- and FlAsH-tagged SERCA2a, designated F-L577, which retains the ATP-dependent Ca(2+) pump activity. The FRET efficiency between ECFP and FlAsH of F-L577 is dependent on the conformational state of the molecule. ER luminal Ca(2+) imaging confirmed that the FRET signal changes directly reflect the Ca(2+) pump activity. Dual imaging of cytosolic Ca(2+) and the FRET signals of F-L577 in intact COS7 cells revealed that SERCA2a activity is coincident with the oscillatory cytosolic Ca(2+) concentration changes evoked by ATP stimulation. The Ca(2+) pump activity of SERCA2a in intact cells can be expressed by the Hill equation with an apparent affinity for Ca(2+) of 0.41 ± 0.0095 μm and a Hill coefficient of 5.7 ± 0.73. These results indicate that in the cellular environment the Ca(2+) dependence of ATPase activation is highly cooperative and that SERCA2a acts as a rapid switch to refill Ca(2+) stores in living cells for shaping the intracellular Ca(2+) dynamics. F-L577 will be useful for future studies on Ca(2+) signaling involving SERCA2a activity.     

The conformation of calreticulin is influenced by the endoplasmic reticulum luminal environment

In order to understand the dynamics of the endoplasmic reticulum (ER) luminal environment, we investigated the role of Ca(2+), Zn(2+), and ATP on conformational changes of calreticulin. Purified calreticulin was digested with trypsin in the presence or absence of Ca(2+), Zn(2+), and ATP. At low Ca(2+) concentration (<100 micrometer), calreticulin is rapidly and fully degraded by trypsin, indicating that under these conditions the protein is in a highly trypsin-susceptible conformation. Increasing Ca(2+) concentration up to 500 micrometer or 1 mm resulted in protection of the full-length calreticulin and in generation of the 27-kDa fragment highly resistant to trypsin digestion. The 27-kDa protease-resistant core of the protein represented the NH(2)-terminal half of calreticulin and was identified by its reactivity with specific antibodies and by NH(2)-terminal amino acid sequence analysis. Ca(2+)-dependent changes in calreticulin's sensitivity to proteolysis indicate that agonist-induced fluctuation in the free ER luminal Ca(2+) concentration may affect the protein conformation and function. Trypsin digestion of calreticulin in the presence of Zn(2+) resulted in the formation of a 17-kDa central protease-resistant core in the protein corresponding to the central region of the protein, indicating that under these conditions the N- and C-domains of the protein are in an extended conformation. Here we also show that calreticulin is an ATP-binding protein but that it does not contain detectable ATPase activity. Digestion of the protein with trypsin in the presence of Mg(2+)-ATP protects the full-length protein. These results indicate that calreticulin may undergo frequent, ion-induced conformation changes, which may affect its function and its ability to interact with other proteins in the lumen of the ER.     

Intraluminal calcium as a primary regulator of endoplasmic reticulum function

The concentration of Ca2+ inside the lumen of endoplasmic reticulum (ER) regulates a vast array of spatiotemporally distinct cellular processes, from intracellular Ca2+ signals to intra-ER protein processing and cell death. This review summarises recent data on the mechanisms of luminal Ca2+-dependent regulation of Ca2+ release and uptake as well as ER regulation of cellular adaptive processes. In addition we discuss general biophysical properties of the ER membrane, as trans-endomembrane Ca2+ fluxes are subject to basic electrical forces, determined by factors such as the membrane potential of the ER and the ease with which Ca2+ fluxes are able to change this potential (i.e. the resistance of the ER membrane). Although these electrical forces undoubtedly play a fundamental role in shaping [Ca2+](ER) dynamics, at present there is very little direct experimental information about the biophysical properties of the ER membrane. Further studies of how intraluminal [Ca2+] is regulated, best carried out with direct measurements, are vital for understanding how Ca2+ orchestrates cell function. Direct monitoring of [Ca2+](ER) under conditions where the cytosolic [Ca2+] is known may also help to capture elusive biophysical information about the ER, such as the potential difference across the ER membrane.     

Live cell calcium imaging combined with siRNA mediated gene silencing identifies Ca²⁺ leak channels in the ER membrane and their regulatory mechanisms

In mammalian cells, the endoplasmic reticulum (ER) plays a key role in protein biogenesis as well as in calcium signalling. The heterotrimeric Sec61 complex in the ER membrane provides an aqueous path for newly-synthesized polypeptides into the lumen of the ER. Recent work from various laboratories suggested that this heterotrimeric complex may also form transient Ca(2+) leak channels. The key observation for this notion was that release of nascent polypeptides from the ribosome and Sec61 complex by puromycin leads to transient release of Ca(2+) from the ER. Furthermore, it had been observed in vitro that the ER luminal protein BiP is involved in preventing ion permeability at the level of the Sec61 complex. We have established an experimental system that allows us to directly address the role of the Sec61 complex as potential Ca(2+) leak channel and to characterize its putative regulatory mechanisms. This system combines siRNA mediated gene silencing and live cell Ca(2+) imaging. Cells are treated with siRNAs that are directed against the coding and untranslated region (UTR), respectively, of the SEC61A1 gene or a negative control siRNA. In complementation analysis, the cells are co-transfected with an IRES-GFP vector that allows the siRNA-resistant expression of the wildtype SEC61A1 gene. Then the cells are loaded with the ratiometric Ca(2+)-indicator FURA-2 to monitor simultaneously changes in the cytosolic Ca(2+) concentration in a number of cells via a fluorescence microscope. The continuous measurement of cytosolic Ca(2+) also allows the evaluation of the impact of various agents, such as puromycin, small molecule inhibitors, and thapsigargin on Ca(2+) leakage. This experimental system gives us the unique opportunities to i) evaluate the contribution of different ER membrane proteins to passive Ca(2+) efflux from the ER in various cell types, ii) characterize the proteins and mechanisms that limit this passive Ca(2+) efflux, and iii) study the effects of disease linked mutations in the relevant components.     

IP3 receptor activity is differentially regulated in endoplasmic reticulum subdomains during oocyte maturation

Fertilization competency results from hormone-induced remodeling of oocytes into eggs. The signaling pathways that effect this change exemplify bistability, where brief hormone exposure irrevocably switches cell fate. In Xenopus, changes in Ca(2+) signaling epitomize such remodeling: The reversible Ca(2+) signaling phenotype of oocytes rapidly adapts to support irreversible propagation of the fertilization Ca(2+) wave. Here, we simultaneously resolved IP(3) receptor (IP(3)R) activity with endoplasmic reticulum (ER) structure to optically dissect the functional architecture of the Ca(2+) release apparatus underpinning this reorganization. We show that changes in Ca(2+) signaling correlate with IP(3)R redistribution from specialized ER substructures called annulate lamellae (AL), where Ca(2+) release activity is attenuated, into IP(3)R-replete patches in the cortical ER of eggs that support the fertilization Ca(2+) wave. These data show: first, that IP(3)R sensitivity is regulated with high spatial acuity even between contiguous ER regions; and second, that drastic reorganization of Ca(2+) signaling dynamics can be driven by subcellular redistribution in the absence of changes in channel number or molecular or familial Ca(2+) channel diversity. Finally, these results define a novel role for AL in Ca(2+) signaling. Because AL are prevalent in other scenarios of rapid cell division, further studies of their impact on Ca(2+) signaling are warranted.     

Mitochondria recycle Ca(2+) to the endoplasmic reticulum and prevent the depletion of neighboring endoplasmic reticulum regions

To study Ca(2+) fluxes between mitochondria and the endoplasmic reticulum (ER), we used "cameleon" indicators targeted to the cytosol, the ER lumen, and the mitochondrial matrix. High affinity mitochondrial probes saturated in approximately 20% of mitochondria during histamine stimulation of HeLa cells, whereas a low affinity probe reported averaged peak values of 106 +/- 5 microm, indicating that Ca(2+) transients reach high levels in a fraction of mitochondria. In concurrent ER measurements, [Ca(2+)](ER) averaged 371 +/- 21 microm at rest and decreased to 133 +/- 14 microm and 59 +/- 5 microm upon stimulation with histamine and thapsigargin, respectively, indicating that substantial ER refilling occur during agonist stimulation. A larger ER depletion was observed when mitochondrial Ca(2+) uptake was prevented by oligomycin and rotenone or when Ca(2+) efflux from mitochondria was blocked by CGP 37157, indicating that some of the Ca(2+) taken up by mitochondria is re-used for ER refilling. Accordingly, ER regions close to mitochondria released less Ca(2+) than ER regions lacking mitochondria. The ER heterogeneity was abolished by thapsigargin, oligomycin/rotenone, or CGP 37157, indicating that mitochondrial Ca(2+) uptake locally modulate ER refilling. These observations indicate that some mitochondria are very close to the sites of Ca(2+) release and recycle a substantial portion of the captured Ca(2+) back to vicinal ER domains. The distance between the two organelles thus determines both the amplitude of mitochondrial Ca(2+) signals and the filling state of neighboring ER regions.     

Biophysical re-equilibration of Ca2+ fluxes as a simple biologically plausible explanation for complex intracellular Ca2+ release patterns

Physiological regulation of Ca(2+) release from the endoplasmic reticulum (ER) is critical for cell function. Recent direct measurements of free [Ca(2+)] inside the ER ([Ca(2+)](ER)) revealed that [Ca(2+)](ER) itself is a key regulator of ER Ca(2+) handling. However, the role of this new regulatory process in generating various patterns of Ca(2+) release remains to be elucidated in detail. Here, we incorporate the recently quantified experimental correlations between [Ca(2+)](ER) and Ca(2+) movements across the ER membrane into a mathematical model ER Ca(2+) handling. The model reproduces basic experimental dynamics of [Ca(2+)](ER). Although this was not goal in model design, the model also exhibits mechanistically unclear experimental phenomena such as "quantal" Ca(2+) release, and "store charging" by increasing resting cytosolic [Ca(2+)]. While more complex explanations cannot be ruled out, on the basis of our data we propose that "quantal release" and "store charging" could be simple re-equilibration phenomena, predicted by the recently quantified biophysical dynamics of Ca(2+) movements across the ER membrane.     

Functional coupling of chromogranin with the inositol 1,4,5-trisphosphate receptor shapes calcium signaling

Chromogranins A and B are high capacity, low affinity calcium (Ca(2+)) storage proteins that bind to the inositol 1,4,5-trisphosphate-gated receptor (InsP(3) R). Although most commonly associated with secretory granules of neuroendocrine cells, chromogranins have also been found in the lumen of the endoplasmic reticulum (ER) of many cell types. To investigate the functional consequences of the interaction between the InsP(3) R and the chromogranins, we disrupted the interaction between the two proteins by adding a chromogranin fragment, which competed with chromogranin for its binding site on the InsP(3)R. Responses were monitored at the single channel level and in intact cells. When using InsP(3) R type I incorporated into planar lipid bilayers and activated by cytoplasmic InsP(3) and luminal chromogranin, the addition of the fragment reversed the enhancing effect of chromogranin. Moreover, the expression of the fragment in the ER of neuronally differentiated PC12 cells attenuated agonist-induced intracellular Ca(2+) signaling. These results show that the InsP(3)R/chromogranin interaction amplifies Ca(2+) release from the ER and that chromogranin is an essential component of this intracellular channel complex.     

Intracellular Ca(2+) release triggers translocation of membrane marker FM1-43 from the extracellular leaflet of plasma membrane into endoplasmic reticulum in T lymphocytes

Stimulation of T cell receptor in lymphocytes enhances Ca(2+) signaling and accelerates membrane trafficking. The relationships between these processes are not well understood. We employed membrane-impermeable lipid marker FM1-43 to explore membrane trafficking upon mobilization of intracellular Ca(2+) in Jurkat T cells. We established that liberation of intracellular Ca(2+) with T cell receptor agonist phytohemagglutinin P or with Ca(2+)-mobilizing agents ionomycin or thapsigargin induced accumulation of FM1-43 within the lumen of the endoplasmic reticulum (ER), nuclear envelope (NE), and Golgi. FM1-43 loading into ER-NE and Golgi was not mediated via the cytosol because other organelles such as mitochondria and multivesicular bodies located in close proximity to the FM1-43-containing ER were free of dye. Intralumenal FM1-43 accumulation was observed even when Ca(2+) signaling in the cytosol was abolished by the removal of extracellular Ca(2+). Our findings strongly suggest that release of intracellular Ca(2+) may create continuity between the extracellular leaflet of the plasma membrane and the lumenal membrane leaflet of the ER by a mechanism that does not require global cytosolic Ca(2+) elevation.     

Calreticulin differentially modulates calcium uptake and release in the endoplasmic reticulum and mitochondria

To study the role of calreticulin in Ca(2+) homeostasis and apoptosis, we generated cells inducible for full-length or truncated calreticulin and measured Ca(2+) signals within the cytosol, the endoplasmic reticulum (ER), and mitochondria with "cameleon" indicators. Induction of calreticulin increased the free Ca(2+) concentration within the ER lumen, [Ca(2+)](ER), from 306 +/- 31 to 595 +/- 53 microm, and doubled the rate of ER refilling. [Ca(2+)](ER) remained elevated in the presence of thapsigargin, an inhibitor of SERCA-type Ca(2+) ATPases. Under these conditions, store-operated Ca(2+) influx appeared inhibited but could be reactivated by decreasing [Ca(2+)](ER) with the low affinity Ca(2+) chelator N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine. In contrast, [Ca(2+)](ER) decreased much faster during stimulation with carbachol. The larger ER release was associated with a larger cytosolic Ca(2+) response and, surprisingly, with a shorter mitochondrial Ca(2+) response. The reduced mitochondrial signal was not associated with visible morphological alterations of mitochondria or with disruption of the contacts between mitochondria and the ER but correlated with a reduced mitochondrial membrane potential. Altered ER and mitochondrial Ca(2+) responses were also observed in cells expressing an N-truncated calreticulin but not in cells overexpressing calnexin, a P-domain containing chaperone, indicating that the effects were mediated by the unique C-domain of calreticulin. In conclusion, calreticulin overexpression increases Ca(2+) fluxes across the ER but decreases mitochondrial Ca(2+) and membrane potential. The increased Ca(2+) turnover between the two organelles might damage mitochondria, accounting for the increased susceptibility of cells expressing high levels of calreticulin to apoptotic stimuli.     

The sarcoplasmic reticulum Ca(2+)-ATPase, SERCA1a, contains endoplasmic reticulum targeting information.

The fast-twitch skeletal muscle Ca(2+)-ATPase isoenzyme, SERCA1a, is localized in chick skeletal myotubes to both the sarcoplasmic reticulum (SR) and to the nuclear envelope, an extension of the endoplasmic reticulum (ER). The ER labeling remained after cycloheximide treatment, indicating that it did not represent newly synthesized SERCA1a in transit to the SR. Expression of the cDNA encoding SERCA1a in cultured non-muscle cells led to the localization of the enzyme in the ER, as indicated by organelle morphology and the co-localization of SERCA1a with the endogenous ER luminal protein, BiP. Immunopurification analysis showed that SERCA1a was not bound to BiP, nor was any degradation apparent. Thus, the SR Ca(2+)-ATPase appears to contain ER targeting information.     

Modulation of STIM1 and capacitative Ca2+ entry by the endoplasmic reticulum luminal oxidoreductase ERp57

STIM1 is an endoplasmic reticulum (ER) membrane Ca(2+) sensor responsible for activation of store-operated Ca(2+) influx. We discovered that STIM1 oligomerization and store-operated Ca(2+) entry (SOC) are modulated by the ER oxidoreductase ERp57. ERp57 interacts with the ER luminal domain of STIM1, with this interaction involving two conserved cysteine residues, C(49) and C(56). SOC is accelerated in the absence of ERp57 and inhibited in C(49) and C(56) mutants of STIM1. We show that ERp57, by ER luminal interaction with STIM1, has a modulatory role in capacitative Ca(2+) entry. This is the first demonstration of a protein involved in ER intraluminal regulation of STIM1.     

Modeling the dependence of the period of intracellular Ca2+ waves on SERCA expression

Contrary to intuitive expectations, overexpression of sarco-endoplasmic reticulum (ER) Ca(2+) ATPases (SERCAs) in Xenopus oocytes leads to a decrease in the period and an increase in the amplitude of intracellular Ca(2+) waves. Here we examine these experimental findings by modeling Ca(2+) release using a modified Othmer-Tang-model. An increase in the period and a reduction in the amplitude of Ca(2+) wave activity are obtained when increases in SERCA density are simulated while keeping all other parameters of the model constant. However, Ca(2+) wave period can be reduced and the wave amplitude and velocity can be significantly increased when an increase in the luminal ER Ca(2+) concentration due to SERCA overexpression is incorporated into the model. Increased luminal Ca(2+) occurs because increased SERCA activity lowers cytosolic Ca(2+), which is partially replenished by Ca(2+) influx across the plasma membrane. These simulations are supported by experimental data demonstrating higher luminal Ca(2+) levels, decreased periods, increased amplitude, and increased velocity of Ca(2+) waves in response to increased SERCA density.