Calcium-Containing Organelles Display Unique Reactivity to Chemical Stimulation in Cultured Hippocampal Neurons

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Volume 17, Number 5, Issue of March 1, 1997 pp. 1670-1682
Copyright ©1997 Society for Neuroscience

Calcium-Containing Organelles Display Unique Reactivity to Chemical Stimulation in Cultured Hippocampal Neurons

Eduard Korkotian and Menahem Segal
Department of Neurobiology, The Weizmann Institute, Rehovot 76100, Israel

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Cultured rat hippocampal neurons grown on glass coverslips for 1-3 weeks were loaded with the calcium-sensitive fluorescentdye Fluo-3 and viewed with a confocal laser scanning microscope.Large pyramidal-shaped neurons were found to contain dye-accumulatingorganelles in their somata, primarily around nuclei and near thebase of their primary dendrites. These organelles varied in sizeand increased in density over weeks in culture, and were not colocalizedwith the endoplasmic reticulum or with mitochondria. The Fluo-3fluorescence in these calcium-containing organelles (CCOs) wastransiently quenched by exposure to Mn²⁺, indicating that the dye is a genuine [Ca²⁺] reporter and is not just a site of accumulating Fluo-3 dye.Recovery of fluorescence in the CCOs after washout of Mn²⁺ involved activation of a thapsigargin-sensitive process.
CCOs responded to stimuli that evoke a rise of cytosolic [Ca²⁺] ([Ca]_i) in a unique manner; perfusion of caffeine caused a prolongedrise of [Ca] in the CCOs ([Ca]_C), whereas it caused only a transientrise of [Ca]_i. Pulse application of caffeine also caused a fastereffect on [Ca]_C than on [Ca]_i. Glutamate caused a transient riseof both [Ca]_i and [Ca]_C, followed by a prolonged fall of only[Ca]_C to below rest level. This fall was blocked by preincubationwith thapsigargin. Ryanodine blocked the cytosolic effects ofcaffeine but not its effect on [C]_C.
A clear distinction between CCOs and the known calcium stores was seen in digitonin-permeabilized cells; in these, remainingFluo-3 reported changes in store calcium, i.e., caffeine causeda reduction in Fluo-3 fluorescence in permeabilized cells, whereasit still caused an increase in [Ca]_C. A possible role of CCOsin regulation of release of calcium from ryanodine-sensitive storeswas indicated by the observation that CCO-containing cells exhibiteda larger and faster response to caffeine than cells that did nothave them. We propose that CCOs constitute a unique functionalcompartment involved in release of calcium from calcium-sensitivestores.
Key words: hippocampus; calcium stores; confocal microscopy; cultured neurons; ryanodine; caffeine

INTRODUCTION

The presence of unique, calcium dye-accumulating organelles in somata of cultured neurons exposed to fluorescent calcium indicatorshas been noticed ever since the introduction of the membrane-permeablecalcium indicators Indo-1-AM, Fura-2 AM, and Fluo-3 AM (Malgaroliet al., 1987; Blatter and Wier, 1990; Gunter et al., 1990; Spurgeonet al., 1990; Wahl et al., 1990, 1992; Kuba et al., 1991). Thesedyes penetrate the plasma membrane and some membranous structureswithin the cell and are converted by local esterases to a fluorescent,calcium-sensitive, membrane-impermeant form. This loading procedureresults in their accumulation within organelles inside the cell.The functional significance of this apparent accumulation of fluorescencein organelles and the relations of these organelles to the knowncalciosome (Volpe et al., 1988; Burgoyne et al., 1989; Rossierand Putney, 1991; Spat et al., 1994) are not entirely clear. Theseorganelles are not seen when the cells are loaded with the acid,membrane-impermeant form of the dye (Almers and Nehers, 1985;Connor, 1993; Blatter, 1995), indicating that they constituteclosed, membranous structures into which the free dye does notdiffuse passively. Do these organelles fluoresce because theyhave a high concentration of the dye, or do they have a genuinehigh concentration of calcium, and can be considered as a uniqueclass of "calcium store"? If so, can they be identified with oneof the known stores, including mitochondria and endoplasmic reticulum?Whether these organelles accumulate dye or calcium, the presenceof dye in them interferes with accurate measurements of real free[Ca]_i elsewhere in the cytosol, and so it is important to determinewhether there are any systematic changes in fluorescence of these"organelles" that may affect measurements of cytosolic calcium.

Previous studies, done primarily in non-neuronal cells using digital imaging methods, reported that calciosomal calcium risesin the presence of ATP, indicating that the accumulation of calciumin calciosomes is energy-dependent (Connor, 1993). Other stimuliused include drugs that interact with the known calcium stores(Blatter, 1995; Hofer et al., 1995). Differences between celltypes can be expected, and an interaction among calciosomes, thenovel calcium compartment seen here, and different calcium storesmay be unique to the cell types studied. Their roles in neuronsremain enigmatic.

Using a confocal laser scanning microscope, which allows a focused, detailed view of living cells, we have studied the behaviorof the calcium-containing organelle in conditions expected toproduce a change in [Ca]_i and report that it does indeed expressa unique response pattern to drugs that modify [Ca]_i. Althoughwe are unable at the present time to verify that it is enclosedwithin a specific, known cellular organelle or a restricted compartmentof the cytosol, we operationally define it as calcium-containingorganelle (CCO) and demonstrate that it is a genuine functionalcalcium compartment, closely related to, but different from, intracellularcalcium stores.
Fig. 1. A, CCOs are distinct from the endoplasmic reticulum in cultured hippocampal neurons. Cells were initially stained with Fluo-3and reconstructed in three dimensions using eight optical sectionstaken at 1 µm intervals (left). The same cells were later stainedwith DiO, which labels the endoplasmic reticulum (right). Fluo-3fluorescence was photobleached before the second staining. Notethe absence of DiO in the nucleus and the network of labelingin the soma, especially near the base of the primary dendrites.B, An image taken at a single plane through another cell stainedwith Fluo-3 (left) and DiO (middle). Right, An amplified-differenceimage between the Fluo-3 and DiO images. Although some organellesare seen also with the DiO staining, they do not overlap withthose stained with Fluo-3.
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Fig. 2. CCOs are not colocalized with mitochondria. A, Fluo-3-loaded cell in control condition (left), after onset of exposure tothe mitochondria uncoupler SF-6847 (30 µM; middle), and after10 min exposure and 20 min wash (right). Note the increase innuclear and [Ca]_i but also of [Ca]_C. Fluorescence in the rightimage is saturated. B, Double-labeled cell stained with Fluo-3AM (left) and Rhodamine 6G (center). Right, Amplified differencebetween the left and center images. A single plane taken throughthe same cell indicates that the two dyes do not stain the sameorganelles. Rhodamine 6G staining was made in Fluo-3-labeled,and subsequently bleached, cells, as above. Staining was madewith 1 µM dye incubated for 10 min, followed by extensive washfor 40 min.
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Fig. 3. Transient disappearance of [Ca]_C fluorescence after exposure to Mn²⁺. A, A Fluo-3-loaded cell shown from left to right, in controlcondition, immediately after exposure to a pulse application ofhigh K⁺ (200 mM)-containing medium, 5 sec after K⁺, and 1 min later. The frame on the right is a net image, subtractingthe image taken 5 sec after onset of exposure to K⁺ from the image taken 1 min later. A and B are the same cell:A, in control medium; B, in a medium containing Mn²⁺ (2 mM), replacing Ca²⁺. C, Another cell, preincubated for 15 min in thapsigargin (1µM), exposed to Mn²⁺ as in B. The CCOs are clearly visible in B and are nearly absentin C after washout of K⁺.
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Fig. 4. Time course of changes in Fluo-3 fluorescence after a momentary exposure to high K⁺ in Mn²⁺-containing medium, as in Figure 4. Mean of five experiments.Note the log scale of the time base.
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Fig. 5. CCOs respond to chemical stimulation in cultured hippocampal neurons. A, Reactivity of CCOs to caffeine. Images 1 and 2 weretaken 20 min apart to illustrate the stability of the detectionof CCOs. Image 3, 10 min after perfusion of the cell with 10 mMcaffeine. Note that at this time, only CCOs respond to caffeine,whereas the rest of the cell is nearly at baseline level. Single-planeoptical sections, 16-frame average, 63× water immersion objective.Nucleus is out of the plane of focus. B, Responses to topicalapplication of glutamate. B1, Top, Three-dimensional reconstructedneuron with a line drawn through its soma and a CCO in one ofits primary dendrites. This cell was scanned at a rate of 0.8msec/line. Bottom, Raster display of the line scan, from top tobottom, comprising 512 lines, showing net fluorescence relativeto baseline fluorescence (DF/F). Glutamate (1 mM) was applied~50 msec from the top and is followed by a rise of fluorescencein the calciosome at about the same time as the rise in the somaof the same cell. B2, Three-dimensional display of the rise ofFluo-3 fluorescence, from bottom to top, illustrating the riseof fluorescence in the CCO and the soma. Intensity of fluorescenceis coded in the height/color of the plot with red indicating lowintensity and green-white indicating high intensity. C, Responsesof a cluster of cells to caffeine and glutamate. Image 1, control;image 2, after 15 min of exposure to caffeine (5 mM), illustratinga rise in [Ca]_C; image 3, 15 min wash; image 4, net frame of images2-1, image amplified to enhance detection of differences in theimage; image 5, during response to glutamate, (1 mM, 100 msecpulse). Note that nuclear fluorescence is saturated. Image 6,1 min later; image 7, 20 min later; image 8, net frame of images7-6, amplified. Note the decrease in CCOs fluorescence after exposureto glutamate, and the later recovery. Cells are three-dimensionallyreconstructed.
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Fig. 6. Cellular calcium responses to a brief application of caffeine (A) and glutamate (B and C). A, Exposure to a pulse applicationof caffeine (5 mM, 300 msec pulse, n = 11 cells) caused a transientrise in [Ca]i, which initially started in CCOs (see the insertamplification of the first part of the graph) and was larger inthe nucleus than in cytoplasm or the CCOs, and a slower recoveryto baseline in the latter than in former two compartments. B,Glutamate (1 mM, 100 msec pulse) caused a much larger rise innuclear [Ca]_i than caffeine, but a similar [Ca]_C rise and an undershootin the fluorescence of the latter compartment was clear (glutamate,1 mM, 50 msec pulse, C). D, Detailed comparison between CCO responsesto glutamate and caffeine, relative to the changes in cytoplasmic[Ca]_i, at successive time points before and after applicationof the drug: a, before application; b, the last nonsignificantpoint on cytoplasmic curve after drug application; c, the firstsignificant point in the cytosolic response; d, at the peak ofthe response; e, one-half recovery to baseline; f, four-fifthsrecovery; g, last significant point; h, first point of recoveryin cytoplasm. A significant rise of [Ca]_C in response to caffeineis seen before [Ca]_i changes. [Ca]_C remained elevated in responseto caffeine compared with the response to glutamate and to caffeinein cytoplasm. Ordinate, Ratio of net/baseline fluorescence. Abscissa(in A, B, and C), time; (in D), points in time relative to a defined[Ca]_i state. Abscissa of C is in a logarithmic scale.
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Fig. 7. Cell reactivity to short duration (50 msec, 1-2 mM) exposure to caffeine. The response lasted <1 sec. Note the increase in[Ca]_C and decrease in nuclear [Ca]_i. The same cells respondedto a longer exposure to caffeine with an increase in [Ca]_i inall compartments, as shown before for other cells.
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Fig. 8. Cellular reactivity to prolonged exposure to 5 mM caffeine. Caffeine was perfused in the recording medium (as in Fig. 5C),and changes in Fluo-3 fluorescence were monitored in 15 cells.After an initial rise in [Ca]_i, cytosolic and nuclear calciumreturned to baseline, whereas [Ca]_C continued to rise, and remainedhigh even after removal of caffeine.
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Fig. 9. A, Thapsigargin enhances [Ca]_C. Image 1, control; image 2, after 5 min exposure to the drug (0.5 µM); image 3, after 15 minexposure to thapsigargin. Note the increase in [Ca]_c in thapsigargin-treatedcell. B, Thapsigargin blocks the undershoot of the [Ca]_C responseto glutamate. CCO responses in control (as in Fig. 6C) and thapsigargin-pretreatedcells (15-20 min; n = 13) to same pulse application of glutamatewere compared. Unlike the control cases, in which a clear undershootlasting at least 10 min is seen, the thapsigargin-treated cellsdo not return to baseline fluorescence after glutamate. Abscissascale as in Figure 6C.
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Fig. 10. Ryanodine blocks cytosolic, but not [Ca]_C, reactivity to caffeine. Images were taken before (A), 3 sec after (B), and 6 secafter (C) exposure of the cell to a 300 msec puff of caffeine(5 mM). D-F, Same cell after 15 min of exposure to 10 µM ryanodine(with 2-3 intermediate responses not shown). Single plane/frameimages of the cell. Note that the bottom left area, rich in CCOs,increases fluorescence before other cell areas (B), and even afterryanodine, whereas the rest of the cell maintains a low levelof fluorescence (E and F).
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Fig. 11. Differential effects of ryanodine on [Ca]_i and [Ca]_C. Initially, caffeine (5 mM, applied by pressure) caused a larger changein [Ca]_i than in [Ca]_C (A). After 10-15 min superfusion of 5 µMryanodine, the baseline fluorescence was not different, the cytosolicresponse to caffeine was reduced drastically, and [Ca]_C was stilltransiently elevated by caffeine (B). Only 5 min later, and aftertwo to three more responses to caffeine, did [Ca]_C response tocaffeine attenuate significantly (C).
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Fig. 12. Changes in [Ca]_C caffeine are different from those of the calcium stores, measured in permeabilized cells. A-C, Control conditions.A, Baseline; B, response to a pulse of caffeine (10 mM, 300 msec);C, 3 min later. The cell was permeabilized for 2-3 min with intracellularmedium containing 10 µM digitonin and ATP. [Ca]_i was clamped byEGTA at 150 nM. D-F, Same sequence of exposure to caffeine, 5min after the cell was permeabilized. Contrast-enhanced images.
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Fig. 13. Nuclear reactivity to caffeine is correlated with the presence of calciosomes. The time course of change in nuclear [Ca]_iwas measured after application of 10 mM caffeine. Experimentswere conducted in young (A) and mature (B) cultures, and the cellswere classified into three groups: cells containing no visibleCCOs [group (gr.) 1], few CCOs (gr.2), and many CCOs (gr.3). Inthe older group, no organelle-free cells were found. In both agegroups, a shorter latency to caffeine was seen in CCO-containingneurons. A smaller response was seen in CCO-free cells. C, Timecourse of appearance of CCOs. Cultures were stained with Fluo-3,and the proportion of cells containing these organelles was registered.(The total number of cells counted in each age group is depictedat the bottom of each column.)
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MATERIALS AND METHODS
Cell culture. Primary dissociated cultures of rat hippocampus were prepared from E19 fetuses and grown on 13 mm cover glassesfor 1-4 weeks, as described elsewhere (Papa et al., 1995). Inbrief, cells were plated in DMEM containing 10% horse serum and10% fetal calf serum, which was replaced, after 1 week, with DMEMcontaining 10% horse serum. Glia proliferation was blocked byincubation with 5-fluoro-2 $'$ -deoxyuridine for 3 d, starting 5 dafter plating.

For [Ca]_i imaging, cover glasses were washed with recording medium and incubated at room temperature in a shaking bath for1-1.5 hr with one of the following dyes: Fluo-3 AM (3 µM), CalciumGreen-1 AM, Calcium Green-2 AM (both at 2.6 µM; all from MolecularProbes), or FFP-18 AM (7.8 µM; Teflabs), in the presence of pluronicF127 (30 nM). Cultures were then washed for at least 1 hr in therecording medium, and were used during the next 1-4 hr.

Endoplasmic reticulum was visualized with the membrane dye 3,3 $'$ -dihexyloxacarbocyanine iodide [DiO6(3), Molecular Probes](Blatter, 1995). The dye was prepared in a stock solution of 0.5mg/ml ethanol and was added to the culture dish to a final concentrationof 0.25 mg/ml for 15 min. The dye was then washed for 15 additionalmin, and the culture was mounted on the stage of the confocallaser scanning microscope. Mitochondria were visualized with Rhodamine6G chloride (Molecular Probes) prepared from stock DMSO solution.The cultures were incubated for 10 min with 1 µM of the dye andwashed for 40 min before visualization. The same cells were usedfor visualization of calcium, using Fluo-3, and for visualizationof the organelles, endoplasmic reticulum, or mitochondria. Incases of double labeling, the laser power was adjusted beforeloading with the second dye, so that Fluo-3 fluorescence was nolonger seen.

Solutions and drugs. The recording medium contained (in mM): 129 NaCl, 4 KCl, 1 MgCl₂, 2 CaCl₂, 4.2 glucose, and 10 HEPES,along with 0.5 µM tetrodotoxin. pH was adjusted to 7.4 with NaOH,and osmolarity to 320 mOsm by addition of sucrose. In Mn²⁺-containing solutions, CaCl₂ was replaced by MnCl₂. In some experiments,EGTA (0.1 mM) was added to the calcium-free medium. Permeabilizationmedium contained (in mM): 125 KCl, 25 NaCl, 10 HEPES, 3 Na₂ATP,0.1 MgCl₂, and 0.1 CaCl₂. Osmolarity was adjusted to 320 mOsmwith sucrose. [Ca]_i was clamped to 150 nM with 0.14 mM EGTA (Tsienand Pozzan, 1989), and pH was adjusted to 7.4 with KOH. Digitonin(10 µM, Merck) was added to the permeabilization medium. Fluo-3remained trapped in organelles, thereby permitting calcium measurementsin these conditions. Drugs were prepared in the recording mediumfrom frozen stocks before use. Glutamate (1 mM), caffeine (5-10mM), or KCl (200 mM) was loaded in a pressure pipette with a tipdiameter of 2 µm placed approximately 50 µm from the cell. Thedrugs were applied through the pipette with a pressure pulse of50-500 msec duration. Alternatively, drugs were applied in theperfusion medium [5 mM caffeine (Sigma), 10 µM ryanodine, and1 µM thapsigargin (Alåmone Lab, Jerusalem, Israel)]. SF-6847 (3,4-ditert,butyl-4-hydroxylbenzylidenemalononitrile), a carbonyl cyanide/p-trifluoromethoyx phenylhydrazone (FCCP)-like mitochondrial uncoupler (Whiteand Reynolds, 1995), was a gift from Dr. Y. Shahak (The WeizmannInstitute).

Imaging. After loading of the dye, the glass coverslips were placed in a confocal laser scanning microscope (Leica, Heidelberg,Germany) and superfused with the recording medium at a rate of3-5 ml/min at room temperature. The confocal laser scanning microscopeis equipped with an argon-ion laser for excitation at a wavelengthof 488 nm. Laser light was reduced to 1-3% of nominal intensityto avoid photodynamic damage. Images of 256 × 256 or 512 × 512pixels were taken with a 63× water immersion objective. A completethree-dimensional reconstruction of the cell was made from 15-20successive 0.5-1.0 µm optical sections taken through the cell.A line was scanned through the center of an image (~0.8 msec perline) to reveal fast changes in fluorescence during a responseto drug application. Fluorescence intensity was quantified usingLeica analysis software and Adobe Photoshop (Adobe Systems). Changesin Fluo-3 fluorescence were standardized by dividing the net fluorescenceby the pretreatment fluorescence, with background subtracted.Autofluorescence, measured in bis(2-aminophenoxy)ethane-N, N,N $'$ ,N $'$ -tetra-aceticacid AM-loaded cells, under identical conditions as used here,was negligible (Korkotian and Segal, 1996) Data are presentedas mean ± SEM.

RESULTS

A unique calcium-sequestering compartment
Fluo-3-containing organelles of different sizes and shapes were found primarily in the soma, around the nucleus, and nearthe base of the main dendrite. Their diameters ranged between0.3 and 1.5 µm. They tend to cluster, however, single, isolatedorganelles often could be seen as well. They were clearly absentin nuclei, and few of them were found in secondary dendrites (Fig.1A). CCOs were stable in shape and fluorescence intensity forat least half an hour of repetitive imaging (e.g., Fig. 5A1,2).In three-dimensional reconstructed neurons stained with both Fluo-3and DiO, which labels endoplasmic reticulum, the CCOs tended tocluster in the same regions of the cell as the DiO staining [e.g.,in perisomatic regions and in the base of the main dendrite (Fig.1A)], but a closer examination of single planes of the three-dimensionalreconstructed images (Fig. 1B) using digital subtraction methodsrevealed that CCOs do not colocalize with endoplasmic reticulum,stained with DiO.

CCOs do not colocalize with mitochondria, another small, highly abundant organelle in neurons. Mitochondria were stained withRhodamine 6G in the same protocol used for staining endoplasmicreticulum (Fig. 2B). Analyzing single-plane images, small organellesstained with Rhodamine 6G were seen throughout the cells, butthey were smaller in size and were not colocalized with Fluo-3-stainedorganelles, especially in dendrites rich in mitochondria and poorin CCOs. Another indication that CCOs are not mitochondria comesfrom experiments in which mitochondrial calcium was released withthe proton uncoupler SF-6847, (White and Reynolds, 1995). In theseconditions, Fluo-3 fluorescence increased throughout the cell(Fig. 2A), as expected, but also in CCOs, which never disappearedin these conditions, indicating that they are, like [Ca]_i, affectedby release of calcium from the stores, but probably are not mitochondriathemselves.

Fluo-3 is not a unique dye in its ability to label CCOs. They are stained also with Calcium Green-1 AM and with the membrane-boundratio dye FFP-18 AM (data not shown). The more common dye, Fura-2AM, also labeled CCOs but not as readily as Fluo-3. In most experiments,Fluo-3 was used for its wider dynamic range than that of the otherdyes. Membrane-impermeant dyes, Fluo-3 or Fura-2, introduced intocells through a micropipette, did not label CCOs (as in Segal,1995).

CCOs may constitute a genuine and independent compartment, which is related in some unique way to known free cytosolic orstore [Ca]. Alternatively, these may constitute dye-accumulatingorganelles, rich in esterases that convert Fluo-3 AM to the fluorescentform, but are insensitive to changes in cytosolic [Ca]. In theformer case, one would expect a fast and transient change in fluorescencein the presence of a divalent cation that competes with calciumat the binding site of the dye. Such is the case with Mn²⁺, which competes with calcium and quenches [Ca]_i fluorescencein the cytosol (Simpson et al., 1995b), and is used for calibrationof [Ca]_i (Segal and Manor, 1992). The effects of Mn²⁺ were examined in 14 cells. First, the cells were exposed momentarilyto a high K⁺-containing medium, which activated voltage-gated calcium channelsand raised [Ca]_i transiently (Fig. 3A). Next, the cells were perfusedfor 5 min with medium containing 2 mM Mn²⁺ replacing extracellular Ca²⁺. This, by itself, did not cause a change in [Ca]_i, because Mn²⁺ does not permeate the cells freely. After a subsequent pulseapplication of high K⁺-containing medium, Mn²⁺ quenched Fluo-3, and fluorescence level went down momentarilyin the cytosol and with a short lag also in the CCOs (Figs. 3B,4). [Ca]_C recovered to about the same level after the potassium/manganesetreatment in the two compartments even in the continuous presenceof Mn²⁺ in the extracellular medium. The recovery of [Ca]_C is likelyto involve an energy-dependent process, as it was prevented bypretreatment of the cells with thapsigargin, which blocks intracellularcalcium pumps (Fig. 3C, 5 cells). These experiments indicate thatCCOs are genuine calcium-sequestering organelles, because suchfluorescence transients would not be expected from a dye-accumulatingorganelle.

CCOs express a distinct response to calcium load
Two chemical stimuli were used routinely to raise [Ca]_i: caffeine, which causes release of calcium from intracellular stores(Burgoyne et al., 1989; Sacchetto et al., 1995), and glutamate,which activates ligand-gated calcium channels, causing influxof calcium ions into the cell.

Caffeine was applied by a short pressure pulse on 11 cells (Figs. 5C, 6A). It caused a rapid and transient rise in [Ca]_i,lasting <10 sec. The latency of the response to caffeine was significantlyshorter in the CCOs compared with nuclear and [Ca]_i (Fig. 6A,D).On the other hand, the magnitude of change of [Ca]_i was largestin the nucleus and smallest in the CCOs. After the initial rise,nuclear calcium ([Ca]_N) recovered to below the resting level,whereas [Ca]_C returned to baseline level, but slower than [Ca]_i.By comparison, a similarly brief application of glutamate (Figs.5B, 6B) onto 11 cells caused a larger and faster [Ca]_i surge,which had the same rise time in the CCOs and the cytosol, indicatedin fast line scans through CCOs and cytosolic compartments (Fig.5B). This was followed by a slower recovery in all compartments;[Ca]_N did not fully recover, and stabilized at a level slightlyabove baseline (as in Korkotian and Segal, 1996). By comparison,[Ca]_C recovered rapidly to a level below baseline (Figs. 5C5-8,6C). This recovery happened faster when the initial response toglutamate was higher (compare [Ca]_C reduction in Fig. 6B,C). Thedifference between the effects of caffeine and glutamate on [Ca]_Cis particularly striking, especially when these effects are relatedto changes in [Ca]_i (Fig. 6D).

The rise of [Ca]_C in response to caffeine and glutamate is not specific to the calcium dye, Fluo-3, used in these experiments.The membrane-bound Fura-2 analog FFP-18 was used under the sameconditions as those in the experiments with Fluo-3. Although FFP-18is used as a ratio dye, like Fura-2, with an optimal calcium-dependentexcitation wavelength of 340 nm, it can also be used with theconfocal microscope, and fluorescence excited at 488 nm is inverselyrelated to [Ca]_i. FFP-18 stains primarily intracellular membranes,including CCOs. A brief application of glutamate caused a transientreduction in FFP-18 fluorescence, indicating an increase in [Ca]_C(data not shown, 7 cells tested).

The shorter latency rise of [Ca]_C in response to caffeine by comparison to the changes in [Ca]_i (Fig. 6A, insert) promptedus to try to reach a threshold condition for caffeine effects.Indeed, when a low concentration (1-2 mM), short pulse (30 msec)of caffeine was applied (Fig. 7), there was a transient rise onlyin [Ca]_C, whereas [Ca]_i and [Ca]_N were slightly reduced. Thisindicates that the [Ca]_C rise is not a consequence of [Ca]_i rise,and that, in fact, [Ca]_i may serve as a source of the calciumrise in the CCOs (i.e., calcium may flow from the cytosol or endoplasmicreticulum to the CCOs).

Caffeine was also applied by continuous perfusion to 15 cells (Figs. 5A3, 8). It caused a moderate transient increase in [Ca]_N.The maximal response to perfused caffeine was smaller than theresponse to a fast, pressure application of the drug, probablybecause caffeine concentration rose slowly during the perfusion,and the response probably desensitized. After the initial rise,and while caffeine was still present, a recovery of [Ca]_i wasseen in the cytoplasm and the nucleus, but [Ca]_C continued tobe high, (up to 50 min after onset of perfusion (Fig. 8).

CCOs are not calcium stores: pharmacological effects
The effects of glutamate and caffeine on [Ca]_i and [Ca]_C in the presence of drugs that interact with the calcium pump (thapsigargin)and the calcium-induced calcium release store (ryanodine) werestudied to allow a distinction between the CCOs, the calcium stores,and the cytosol.

First, the 10-20 min undershoot of [Ca]_C after glutamate (as in Fig. 6B,C) was found to be blocked by a prolonged preincubationof the cell with thapsigargin (Fig. 9B), which by itself causeda small and selective rise in [Ca]_C (Fig. 9A). Taken together,these observations indicate that the CCOs may be instrumentalin pumping calcium into the stores but do not constitute stores(i.e., their fluorescence is not reduced, but increased, by thapsigargin).

A striking distinction between cytosolic calcium and [Ca]_C was seen after blockade of calcium-induced calcium release storeswith ryanodine. In the presence of 10 µM ryanodine superfusedfor 10-15 min (Figs. 10, 11), caffeine was no longer able to causean increase in [Ca]_i, but [Ca]_C was still elevated. The responseto caffeine could not be recovered after washout of ryanodine(n = 12 cells).

These experiments indicate that CCOs are genuine calcium-sequestering organelles. They are not likely to constitute "calciumstores," because their fluorescence increases rather than decreasesin the presence of caffeine, which releases calcium from stores.Another distinction between the stores and the CCOs was seen inthe following experiment, designed to measure calcium directlyin the stores (Hofer and Machen, 1994; Hofer et al., 1995). Themembrane was first permeabilized with digitonin (Fiskum, 1985),and [Ca]_i was clamped with EGTA while the cell was perfused withintracellular medium (Fig. 12). Under these conditions, changesin Fluo-3 fluorescence should be attributed to changes in storecalcium. Digitonin permeabilizes selectively the cell membrane,leaving intact intracellular membranous structures, includingCCOs, during the first few minutes of permeabilization (Malgaroliet al., 1987). At longer exposure times, digitonin can affectstability of intracellular membranes as well (Renard-Kooney etal., 1993). In digitonin-permeabilized cells, caffeine causeda transient reduction of fluorescence (by 21.8 ± 1.3 units) inthe clear cytosolic regions of the cell, presumably reflectinga reduction in stored calcium, while it increased [Ca]_C (by 14.2± 4.3 units, Fig. 12, n = 5 cells).

Functional implications
A possible function of CCOs in initiating reactivity of neurons to caffeine was studied in cultured neurons of different agesand in cultured neurons of the same age having different concentrationsof CCOs. The proportion of cells having distinct Fluo-3-labeledCCOs increased over weeks in culture; few neurons contained themin cultures younger than 2 weeks, whereas most of them were labeledat 3-4 weeks in culture (Fig. 13C).

Cells in the young cultures were divided into those having low (only few organelles detected in the cell, n = 7 cells), medium(approximately 5-10 organelles, n = 11 cells), and high (manyorganelles, or regions in the cell loaded with CCOs that cannotbe counted, n = 17 cells) density of CCOs. The latency and magnitudeof [Ca]_N response to caffeine were significantly shorter and larger,respectively, in CCO-containing neurons, compared with organelle-freeneurons (Fig. 13A). The reason the nucleus was chosen for the measurementswas because it is a CCO-free area and so the measurements in thenucleus could not be contaminated by different densities of CCOs.Thus, the nuclear response appears to be clearer than that ofthe cytosol (Korkotian and Segal, 1996). In the older cultures,only medium (n = 9) and high (n = 8) organelle-containing neuronswere found (Fig. 13B). The former group had significantly longerlatency than the latter group. It appears that CCOs may be instrumentalin reducing the threshold for a rise in [Ca]_N during exposureto caffeine. These results are congruent with the effects of lowconcentration/duration of caffeine effects (Fig. 7), which showa rise of [Ca]_C with no concomitant changes in [Ca]_i.

DISCUSSION
The present results demonstrate that calcium dye-containing organelles, present in cultured rat hippocampal neurons, behavein a characteristic manner in response to chemical stimulationto justify their classification as a unique cellular calcium compartment.These organelles are not colocalized with the endoplasmic reticulum,although the two compartments are found in close proximity. Also,CCOs do not colocalize with mitochondria, indicating that theyare not part of any major calcium storage compartment. Their responseto drugs that release calcium from stores (caffeine) and thatcause influx of calcium through voltage- and ligand-gated channels(glutamate) is unique in that it has a different time course,magnitude, and sensitivity to drugs that interact with stores(e.g., ryanodine) than the response of free cytosolic calcium,or that of presumed calcium stores.

The presence of dye-accumulating organelles has been noted before as a consequence of loading the cell with a membrane-permeable,ester-linked dye (Almers and Nehers, 1985; Malgaroli et al., 1987;Scanlon et al., 1987; Blatter and Wier, 1990). It was argued thatthe dye traverses membranes and accumulates in acidic organelles(e.g., lysosomes) (Malgaroli et al., 1987) equipped with highesterase activity. In support of this assertion was the observationthat cells loaded with the dye in its water-soluble, membrane-impermeableform via a micropipette do not compartmentalize into these organelles(Connor, 1993; Blatter, 1995). Also, it appears that the presenceof CCOs is a function of the procedure for dye loading (e.g.,temperature, composition of loading medium), as well as the dyeand cell type (Malgaroli et al., 1987; Gunter et al., 1990; Wahlet al., 1990; Blatter, 1995).

One of the cellular compartments that may accumulate calcium or calcium dye is the calciosome, first described almost a decadeago (Pozzan et al., 1988; Volpe et al., 1988; Krause et al., 1989)and still not identified at the ultrastructural level. One characterizingproperty of the calciosome is its colocalization with the calcium-bindingprotein calsequestrin (Van et al., 1989; Villa et al., 1991) orwith calreticulin (Van Delden et al., 1992) In fact, differentstudies probably call different organelles by the same name, andit is not clear that the calsequestrin-containing calciosome (Pozzanet al., 1988) is the same as our CCOs. At any rate, calreticulinstaining of our neurons is not colocalized with CCOs (M. Segal,unpublished observations).

The assertion that calciosomes do exist comes from studies attempting to correlate calsequestrin with markers of endoplasmicreticulum (for review, see Rossier and Putney, 1991). The calciosomeis situated close to the endoplasmic reticulum or inositol triphosphate(IP₃)-sensitive calcium stores, but is completely distinct fromother cell organelles such as mitochondria and lysosomes (Krauseet al., 1989; Ross et al., 1989; Van Delden et al., 1992; Spatet al., 1994). However, a distinct difference in distributionof calciosomes and IP₃-sensitive stores was found in liver andchromaffin cells (Pozzan et al., 1988; Volpe et al., 1988; Vanet al., 1989; Rossier and Putney, 1991; Burgoyne et al., 1992;Spat et al., 1994; Sacchetto et al., 1995).

Later studies on chick Purkinje neurons revealed a molecular heterogeneity of calsequestrin-rich calciosomes with probablesensitivity to both IP₃ and ryanodine (Volpe et al., 1991) anda clear difference in ontogenetic development between IP₃ andcalsequestrin-containing subcompartments. This indicates thatcalsequestrin is aggregated in calciosomes significantly laterthan IP₃ (Sacchetto et al., 1995). It was proposed that calciosomesrepresenting cisternal stacks of endoplasmic reticulum do not,however, represent a new kind of calcium store, but its functionalcompartment, probably characterized by different properties (Rossierand Putney, 1991; Villa et al., 1991).

The present CCOs, probably not identical to those described above, constitute a unique compartment, regulating calcium levelin a manner different from the surrounding cytosol. However, theycannot be considered as part of a calcium store, hence they arenot identical to calciosomes for the following reasons:

(1) CCOs are seen with ester-loaded dyes but not with acid-loaded dyes, indicating that they possess the ability to convertand store the dye in its active form, and that the dye is unableto penetrate these organelles freely. Furthermore, fluorescenceof these organelles is quenched rapidly, with a small delay relativeto cytosolic Fluo-3, by a brief exposure to Mn²⁺. This indicates that the CCO is a closed entity that accumulatesthe dye, but allows fast exchange with cytosolic calcium so thatMn²⁺ can compete with Ca²⁺ for the calcium-binding site and quench fluorescence. Furthermore,the CCO is not merely a passive compartment where the dye or dye/calciumenters and accumulates; the blockade of the reappearance of CCOsafter washout of Mn²⁺ by the calcium pump antagonist thapsigargin (Herrington et al.,1996) indicates that the CCO is probably linked to calcium stores,which require energy to be refilled. Our results suggest thatcalcium moves from the stores to the CCOs because [Ca]_C increasesrather than decreases during exposure of cells to thapsigargin(Fig. 2E).

(2) CCOs react to glutamate and caffeine in two totally different ways, unlike the response seen in cytosolic [Ca]. In thelatter compartment, both glutamate and caffeine evoke a rise of[Ca]_i, and the difference between the responses to the two stimuliis in magnitude and time course. Whereas caffeine produces a prolongedrise of [Ca]_C, glutamate causes a reduction in [Ca]_C to belowresting values, and this effect could be blocked by thapsigargin.Glutamate causes an influx of calcium, which induces a large releaseof calcium from calcium-sensitive stores, and the reduction in[Ca]_C may reflect an active refilling of the stores through theCCOs, whereas the action of caffeine is weaker and its prolongedapplication may not require an active pumping of calcium intothe stores. However, repetitive application of high caffeine concentration(10 mM) can bring about a fall in [Ca]_C down to their completedisappearance (data not shown). The difference in the responsemay indicate a role of CCOs in the regulation of calcium releasefrom stores (see below), but it undoubtedly validates the assertionthat CCOs are uniquely regulated calcium compartments, and themeasured changes in their calcium content do not merely reflectchanges in ambient [Ca]_i.

Although there is no unequivocal morphological identification of a CCO, it is not part of the endoplasmic reticulum or themitochondria, judged from DiO and rhodamine staining. Also, itappears to be unique in both its spatial localization and developmentalregulation (see also Malgaroli et al., 1987; Sacchetto et al.,1995). These organelles are not scattered randomly throughoutthe cell; they are not found in the nucleus, and they tend toaccumulate at the perinuclear area and at the base of the largestdendrite of the cell. Also, they are not found in young cultures,and begin to be prominent in more mature ones. Likewise, the CCOis not unique to a specific dye used; it is best seen with Fluo-3,but can also be seen with Fura-2, although with a lower intensitydifference from the cytosole. We have also seen CCOs when usingCalcium Green of the high and low affinity varieties and the lowaffinity dye FFP-18 (data not shown). In the latter case, thedye binds to membranes, thus indicating that CCOs are membranousorganelles.

Functions of CCOs
The association of the CCOs with the endoplasmic reticulum, as well as their response to a calcium challenge of the type thatevokes release from stores, indicates that these organelles areclosely linked to the calcium stores. They are not part of thestores, because they behave differently from what is expectedof a store (i.e., their fluorescence increases, rather than decreases,in response to caffeine). Parenthetically, the low level of [Ca]_Cis not likely to result from the high affinity of Fluo-3 to calcium,because the lower-affinity dye, Calcium Green-2, also reportsrelatively low [Ca]_C and is not saturated by the dye. The CCOsare related to the ability of the cell to respond to caffeine,as indicated in the faster time course of [Ca]_N changes in responseto caffeine in CCO-containing cells (Fig. 13). Also, in fast imagingseries, we found that [Ca]_i increases first near a cluster ofCCOs, and then spreads to the rest of the cell (e.g., Fig. 10),indicating that these organelles are instrumental in initiatingthe rise of [Ca]_i after release from stores, but not after influxfrom the extracellular space. Furthermore, small amounts of caffeine,or a larger amount applied during exposure to ryanodine, increasesonly [Ca]_C (Fig. 13). This difference may underlie the qualitativedifference between reactivity of CCOs to glutamate and caffeine.

If, indeed, the CCOs have the lowest threshold for raising [Ca], what is the source of calcium feeding into these organelles?A partial answer may be seen in Figure 7, in which a fast andsmall rise in [Ca]_C is accompanied by a small fall in [Ca]_i and[Ca]_N. It is quite likely that both cytoplasmic and store calciumfeed into the CCO, and under some conditions (e.g., after glutamate)the opposite direction is taken. Such will be the case when thecalcium-induced calcium stores are about to be emptied, and theCCO may provide the initial boost for these calcium stores.

Of the two types of calcium stores reported to exist in cells (for review, see Simpson et al., 1995a), it is likely that theCCOs are associated with the calcium-induced calcium release store,(the ryanodine-sensitive store) and not with the IP₃-related store.This is partly because the metabotropic glutamate receptor, knownto activate the IP₃ store (Sacchetto et al., 1995), does not causea rise of [Ca]_i in our cells (M. Segal and E. Korkotian, unpublishedobservations). The ryanodine store does exist and contributesto the glutamate-evoked rise in [Ca]_i (Segal and Manor, 1992);therefore, it is likely that the CCOs are linked functionallyto the ryanodine-sensitive calcium stores. The higher free-calciumconcentration in CCOs can be significant for the initiation ofcalcium-induced calcium release in the resting or weakly stimulatedcell, inducing local [Ca]_i release from calcium-sensitive stores.Whether the CCO acts as a promoter, helping to raise [Ca]_i toa sufficient enough level to activate the calcium release mechanism,remains to be elucidated.

FOOTNOTES

Received June 20, 1996; revised Dec. 3, 1996; accepted Dec. 10, 1996.

This work was supported by a grant from the Binational U.S.-Israel Science Foundation. We thank Ms. V. Greenberger for thepreparation of the cultures and Dr. J. E. Friedman for commentson earlier versions of this manuscript.

Correspondence should be addressed to Menahem Segal at the above address.

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Copyright ©1997 Society for Neuroscience   0270-6474/1997/171670-13$05.00/0

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