Inositol (1,4,5)-Trisphosphate Dynamics and Intracellular Calcium Oscillations in Pancreatic -Cells
http://www.100md.com
《糖尿病学杂志》
1 Department of Medicine, University of Chicago, Chicago, Illinois
2 Pacific Northwest Research Institute, Seattle, Washington
ATP, adenosine 5'-triphosphate; [Ca2+]i, intracellular calcium concentration; CCh, carbamoylcholine; EGFP, enhanced green fluorescent protein; Ins(1,4,5)P3, inositol (1,4,5)-trisphosphate; KRBB, Krebs-Ringer bicarbonate buffer; LSCM, laser scanning confocal microscope; PHD, pleckstrin homology domain; PIP2, phosphatidylinositol(4,5)-bisphosphate; PLC, phospholipase C; TEA, tetraethylammonium
ABSTRACT
Glucose-stimulated insulin secretion is associated with transients of intracellular calcium concentration ([Ca2+]i) in the pancreatic -cell. We tested the hypothesis that inositol (1,4,5)-trisphosphate [Ins(1,4,5)P3] [Ca2+]i release is incorporated in glucose-induced [Ca2+]i oscillations in mouse islets and MIN6 cells. We found that depletion of intracellular Ca2+ stores with thapsigargin increased the oscillation frequency by twofold and inhibited the slow recovery phase of [Ca2+]i oscillations. We employed a pleckstrin homology domaineCcontaining fluorescent biosensor, phospholipase C pleckstrin homology domaineCenhanced green fluorescent protein, to visualize Ins(1,4,5)P3 dynamics in insulin-secreting MIN6 cells and mouse islets in real time using a video-rate confocal system. In both types of cells, stimulation with carbamoylcholine (CCh) and depolarization with KCl results in an increase in Ins(1,4,5)P3 accumulation in the cytoplasm. When stimulated with glucose, the Ins(1,4,5)P3 concentration in the cytoplasm oscillates in parallel with oscillations of [Ca2+]i. Maximal accumulation of Ins(1,4,5)P3 in these oscillations coincides with the peak of [Ca2+]i and tracks changes in frequencies induced by the voltage-gated K+ channel blockade. We show that Ins(1,4,5)P3 release in insulin-secreting cells can be stimulated by depolarization-induced Ca2+ flux. We conclude that Ins(1,4,5)P3 concentration oscillates in parallel with [Ca2+]i in response to glucose stimulation, but it is not the driving force for [Ca2+]i oscillations.
In the pancreatic -cell, glucose stimulation is associated with increased intracellular calcium ([Ca2+]i). The [Ca2+]i increase and subsequent [Ca2+]i oscillations are initiated by glucose metabolism through an increase in the adenosine 5'-triphosphate (ATP) level, a decrease in adenosine 5'-diphosphate level, and the subsequent closure of ATP-sensitive K+ channels (1). A number of reports have suggested that the endoplasmic reticulum plays a role in the regulation of the electrical activity and [Ca2+]i responses in the pancreatic -cell (2eC5). Calcium stores in the endoplasmic reticulum provide a regulated source of Ca2+, which can be quickly mobilized upon hormonal stimulation in insulin-secreting cells (6). The endoplasmic reticulum also provides a source of Ca2+ that contributes to [Ca2+]i increase in the cytoplasm during glucose stimulation (3,5,7), along with the extracellular Ca2+ influx through L-type Ca2+ channels. It has been suggested that the endoplasmic reticulum is replete with Ca2+ when cells are depolarized and Ca2+ is released upon repolarization (8,9).
Although some studies have suggested that the endoplasmic reticulum Ca2+ stores are mainly discharged by a passive leak of Ca2+ into the cytoplasm (8), others have indicated that gated efflux of endoplasmic reticulum Ca2+ is an important signaling mechanism in the glucose-stimulated -cell (10,11). -Cells have been shown to contain inositol 1,4,5-trisphosphate [Ins(1,4,5)P3] receptors (12), ryanodine receptors (4,10), and Ca2+ channels gated by cyclic ADP-ribose (13) or nicotinic acid adenine dinucleotide phosphate (14,15). Ins(1,4,5)P3-dependent mobilization of endoplasmic reticulum Ca2+ has been well described in -cells as part of the response to various agonists, such as acetylcholine, purine nucleotides, or histamines. However, it is still unclear whether Ins(1,4,5)P3 signaling is important in glucose-dependent -cell activation, particularly for [Ca2+]i oscillations. Our simulations of -cell calcium responses, taking into account ATP and Na+ homeostasis as well as uptake and release of Ca2+ by the endoplasmic reticulum, indicate that Ca2+ in the endoplasmic reticulum is one of the main variables driving [Ca2+]i oscillations (16). Our model suggested that the effect of regulated Ca2+ efflux from the intracellular stores could shape the pattern of slow calcium oscillations. Using a biosensor capable of reporting Ins(1,4,5)P3 (17) and confocal microscopy, we have demonstrated dynamics of Ins(1,4,5)P3 in mouse primary -cells and in MIN6 insulinoma cells upon stimulation with glucose and carbamoylcholine (CCh), as well as depolarization with KCl. We show that Ins(1,4,5)P3 concentration oscillates in parallel with [Ca2+]i in response to glucose stimulation, but it is not the driving force for [Ca2+]i oscillations.
RESEARCH DESIGN AND METHODS
Isolation and culturing of mouse islets of Langerhans and islet cells.
Islets were isolated from the pancreata of 1- to 5-month-old C57BL/J6 mice (The Jackson Laboratories) as described previously (7). To dissociate islets into fragments, they were incubated 5eC20 min in dilute trypsin/EDTA solution (Sigma, St. Louis, MO), titurated to dissociate the cells, and plated on glass coverslips in RPMI 1640 medium supplemented with 10% FCS, 11.6 mmol/l glucose, 100 units/ml penicillin, and 100 e蘥/ml streptomycin on glass coverslips for 1eC4 days. We did not observe any significant association of [Ca2+]i oscillation frequency with time in culture.
Recombinant adenoviruses.
Recombinant adenoviruses were generated to express phospholipase C pleckstrin homology domaineCenhanced green fluorescent protein (PLCPHD-EGFP) driven by the cytomegalovirus early promoter as previously described (18,19) using a bacterial recombination method in BJ5183 E. coli cells (20). Adenovirus-expressing green fluorescent protein was used as a control virus. The amplification and purification of these adenoviruses and their infection protocol were as previously described (18,19). Viral transduction of mouse islets was performed after they were cultured for 2 days on glass coverslips with 5 x 108 pfu/ml for 3 h, followed by imaging 1eC2 days posttransduction. In MIN6 cells, the intracellular localization of PLCPHD-EGFP was the same with either plasmid DNA transfection or adenovirus delivery (not shown). The expression of PLCPHD-EGFP did not affect [Ca2+]i responses to glucose or CCh in mouse islets (not shown).
Cell culture.
Insulin-secreting MIN6 cells were maintained in a humidified incubator with 95% air: 5% CO2 at 37°C in medium (Dulbecco’s modified Eagle’s medium, high-glucose medium supplemented with 10% FCS, 25 mmol/l glucose, 100 IU/ml penicillin, and 100 e蘥/ml streptomycin). MIN6 cells on coverslips were transfected with plasmid-expressing PLCPHD-EGFP driven by the cytomegalovirus early promoter (gift of Dr. Tobias Meyer, Stanford University, Stanford, CA) using Lipofectamine 2000 (Invitrogen, Carlsbad, CA) 1eC3 days before the experiment.
Measurement of [Ca2+]i with fura-2.
Mouse or rat pancreatic islets and MIN6 mouse insulinoma cells were loaded with fura-2 for 30 min to 1 h at 37°C in the corresponding growth medium supplemented with 5 e蘭ol/l acetoxymethyl ester of fura-2 (Molecular Probes, Eugene, OR). Fluorescence imaging was performed using a charged coupled deviceeCbased imaging system and MetaFluor software (Universal Imaging). During imaging experiments, cells or islets were kept at 37°C and constantly perifused with appropriate Krebs-Ringer bicarbonate buffer (KRBB) containing (in mmol/l) 119 NaCl, 4.7 KCl, 2.5 CaCl2, 1.2 MgSO4, 1.2 KH2PO4, and 25 NaHCO3, with varying concentrations of glucose as needed and appropriate inhibitors at a flow rate of 2.5 ml/min. [Ca2+]i was expressed as the ratio of fluorescence intensity (at 535/30 nm) after illumination at 340 nm and 380 nm. Calibration of fura-2 was performed using the Fura-2 Calcium Imaging Calibration Kit (Molecular Probes). At least three independent preparations of islets were used for each experimental protocol.
Fluorescent measurements of EGFP and [Ca2+]i in MIN6 and islets.
Between 1 and 2 h before the experiment, cells were loaded with 10 e蘭ol/l acetoxymethyl ester of Fura Red in growth medium (10 e蘬 of 1 mmol/l Fura Red-AM in DMSO was first mixed with 10 e蘬 of 20% Pluronic F127 and then diluted with 1 ml medium). At least three independent preparations of transfected cells or islets were used for each experimental protocol.
Imaging experiments were performed in real time using the Leica SP2 AOBS spectral laser scanning confocal microscope (LSCM) with the Leica DMIRE2 inverted microscope (Leica Microsystems, Heidelberg, Germany). Photoexcitation of both fluorophores was achieved by illumination at 488 nm (Ar laser), and emitted light was acquired at 520eC540 nm (EGFP) and at 630eC690 (Fura Red). Data acquisition and analysis were performed with Leica Confocal software (Leica Microsystems). Alternatively, a Nipkow dual rotating-disk confocal scanner (CSU10; Yokogawa Electric, Tokyo, Japan) and inverted microscope (Olympus, Tokyo, Japan) were used for confocal imaging. Photoexcitation was achieved by illumination with the 488 nm line of the Kr-Ar mixed-gas laser (series 43; Melles-Griot, Carlsbad, CA). Emitted light was filtered through the 530/30 nm (for EGFP signal) or 660/50 nm (for Fura Red signal) emission filter (Omega Filters, Brattleboro, VT). Data acquisition and analysis were performed with MetaFluor or MetaMorph software (Universal Imaging, Downingtown, PA).
Statistical analysis was performed using Student’s t test. Statistical significance was set at P = 0.05; results were presented as means ± SE.
RESULTS
Mouse islets at elevated glucose (10eC18 mmol/l) often display [Ca2+]i oscillations (16). To study the role of the intracellular Ca2+ stores in the generation of these oscillations, endoplasmic reticulum stores were emptied following treatment with thapsigargin, a specific inhibitor of the sarcoplasmic or endoplasmic reticulum ATPase pump (21). Thapsigargin (1 e蘭ol/l) was added to islets incubated in 14 mmol/l glucose; the emptying of the stores was verified by the absence of the [Ca2+]i discharge peak that occurs in untreated islets after the addition of 0.25 mmol/l CCh. Two groups of islets were selected based on their oscillation frequency (22): "slow," with oscillations 0.1eC1.0/min (39 islets, average 0.34 ± 0.06/min) and "fast," with oscillations faster than 2.0/min (19 islets, average 3.2 ± 0.8/min).
In the first group, thapsigargin produced a sustained elevation of [Ca2+]i (2) in 10% of islets (4/39 islets), whereas in another subset (6/39 islets), oscillations occurred irregularly (Fig. 1B). The majority of islets (29/39 islets) continued to oscillate after the addition of thapsigargin (Fig. 1A). In these islets, thapsigargin brought about a change in the oscillation waveform. The descending phase (downstroke) of each oscillation was accelerated and lacked the prolonged recovery "tail" characteristic of the slow-type oscillations (Figs. 1A and C). Shortening the lag time between two consecutive oscillations contributed to an increase in the oscillation frequency by 2.11 ± 0.17eCfold (P < 0.01, n = 29). observed with thapsigargin treatment (Fig. 1C).
In the group of islets with fast oscillations, there were also a few islets (3/19) that displayed a sustained increase in [Ca2+]i after the addition of thapsigargin. In the majority of islets (16/19), [Ca2+]i oscillations persisted after thapsigargin addition. In these islets, thapsigargin produced an increase in the frequency of [Ca2+]i oscillations by 1.72 ± 0.56eCfold (P < 0.01, n = 16) and a change in the waveform, similar to the islets with slower oscillations (Fig. 1D).
There were other distinctions between the two groups of islets. Treatment of fast-oscillating islets with thapsigargin usually brought an immediate increase of [Ca2+]i, most likely originating from the emptying of intracellular stores. The absence of this increase in slowly oscillating islets might indicate a lower filling state of the Ca2+ stores. Another difference involved a thapsigargin-stimulated increase in amplitude of oscillations by 2.3 ± 0.6eCfold (P < 0.05, n = 16) in fast-oscillating islets, whereas in the group of slowly oscillating islets, this parameter did not change.
Thus, it appears that the control of [Ca2+]i oscillation frequency and the generation of the waveform are modulated by endoplasmic reticulum [Ca2+] stores. We therefore further tested the hypothesis that in -cells, [Ca2+]i oscillations are accompanied by simultaneous cyclical activation of thapsigargin-sensitive Ca2+stores.
Thapsigargin-sensitive calcium stores in many cell types can be discharged by phospholipase C (PLC)-dependent generation of Ins(1,4,5)P3. To test the hypothesis that Ins(1,4,5)P3 is involved in the regulation of [Ca2+]i, changes in mouse islets, and MIN6 insulinoma cells, we employed an Ins(1,4,5)P3 biosensor, which has been previously used to monitor Ins(1,4,5)P3 metabolism in madin-darbycanine kidney epithelial cells (17), in Chinese hamster ovary cells (23), in Purkinje neurons (24), and in INS-1 cells (25). The fusion protein PLCPHD-EGFP combines the pleckstrin homology domain (PHD) of PLC with the EGFP. The PHD of PLC is highly specific for phosphate residues in positions 4 and 5 of inositol phosphates and therefore, it binds phosphatidylinositol (4,5)-bisphosphate (PIP2) and Ins(1,4,5)P3 (26).
In Fig. 2, the stimulation of MIN6 cells with the muscarinic receptor agonist CCh is illustrated. In nonstimulated cells expressing PLCPHD-EGFP, the fluorescent EGFP labeling was located mostly in the plasma membrane (Figs. 2A and B), which reflects the binding of the PLCPHD to PIP2. After stimulation with CCh, accompanied by the generation of Ins(1,4,5)P3, the PLCPHD-EGFP fluorescent label was translocated into the cytoplasm (Figs. 2C and D), where it bound soluble Ins(1,4,5)P3. Line-scan graphs (Figs. 2B and D) show the decrease of the EGFP fluorescence intensity in the plasma membrane of the cell and the gain of intensity in the cytoplasmic region of the cell. By measuring fluorescence in a cytoplasmic region, we were able to monitor the dynamics of Ins(1,4,5)P3 generation.
In MIN6 cells, we found that Ins(1,4,5)P3 generation is also activated by treatment of cells with 30 mmol/l KCl (Fig. 3A). Stimulation with KCl caused a 10.0 ± 2.4% increase in PLCPHD-EGFP translocation, which was significantly less than that observed following CCh treatment (48.4 ± 7.5%, P < 0.05, n = 65). Simultaneous detection of [Ca2+]i with Fura Red confirmed that both KCl treatment and subsequent stimulation with CCh are accompanied by increases in [Ca2+]i (not shown). To determine the role of extracellular Ca2+ in depolarization-stimulated PLC activation, stimulation with KCl (30 mmol/l) (in Ca2+-free KRBB containing 0.1 mmol/l EGTA) produced no detectable increase in Ins(1,4,5)P3 (Fig. 3B). Adding Ca2+ back to the incubation medium immediately stimulated Ins(1,4,5)P3 accumulation in KCl-depolarized cells.
Mouse insulinoma cells can display [Ca2+]i oscillations resembling those in pancreatic islets (16,27). Stimulation of MIN6 cells with high glucose (14 mmol/l) results in a modest nonoscillatory increase in [Ca2+]i level. However, subsequent addition of 10eC20 mmol/l tetraethylammonium (TEA), a potassium channel blocker, reveals an oscillatory response (Fig. 4A). TEA-induced [Ca2+]i oscillations in MIN6 cells are glucose-dependent, since TEA does not stimulate oscillations in low glucose (Fig. 4B). We sought to determine whether [Ca2+]i oscillations in MIN6 cells are associated with PLC activity and generation of Ins(1,4,5)P3.
Next, we studied simultaneous changes of Ins(1,4,5)P3 and [Ca2+]i in MIN6 cells. TEA prompted clusters of 5eC10 cells (Fig. 4C) to start synchronous [Ca2+]i oscillations (indicated by decreases in the Fura Red emission in Figs. 4DeCF) with a frequency of 0.3 to 1/min. In PLCPHD-EGFPeCexpressing cells, TEA invoked periodic increases in cytoplasmic EGFP fluorescence (536 nm emission), with a frequency identical to [Ca2+]i oscillations (0.3 to 1/min) (Fig. 4D). In the nuclei of the same cells (Fig. 4E), there were no oscillations of EGFP fluorescence, which correlated with the fact that PLCPHD-EGFP is not directed to the nucleus. Similarly, there were no oscillations of EGFP fluorescence in the cytoplasm of control cells not expressing PLCPHD-EGFP (Fig. 4F). Therefore, the oscillations of EGFP fluorescence in the cytoplasm are directly related to the expression of PLCPHD-EGFP and are not the result of the Fura Red emissions. In the majority of experiments (five out of six), the dynamics of PLCPHD-EGFP fluorescence in the cytoplasm correlated with increases in [Ca2+]i. These findings indicate that periodic translocations of PLCPHD-EGFP [generation of Ins(1,4,5)P3 and decrease in PIP2] were coincident with peaks of [Ca2+]i in MIN6 cells stimulated with glucose/TEA.
In mouse islets transduced with adenoviral vectoreCexpressing PLCPHD-EGFP, 5eC20 cells per islet on the surface area expressed PLCPHD-EGFP ("green" cells). Double immunofluorescence staining with anti-insulin and anti-GFP antibodies revealed that most of the EGFP-expressing cells were also positive for insulin (Fig. 5). One to three cells from each islet in close proximity to each other and in the same focal plane were studied in individual experiments.
CCh (0.25 mmol/l) treatment of islets in low glucose induced a translocation of PLCPHD-EGFP from its membrane-bound location into the cytoplasm. This translocation was accompanied by an increase in [Ca2+]i (Fig. 6A). CCh treatment in 14 mmol/l glucose led to oscillations in both PLC activity and [Ca2+]i (after an initial increase) (Fig. 6B) in about half of the islets observed. Treatment of islets with KCl (30 mmol/l) induced a translocation of PLCPHD-EGFP from plasma membrane to the cytoplasm along with an increase in [Ca2+]i (not shown).
We also sought to determine whether we could visualize if Ins(1,4,5)P3 generation in islets is stimulated by an increase in glucose concentration alone. Islets expressing PLCPHD-EGFP were first incubated in low glucose (2 mmol/l) for 2eC3 h, followed by high glucose (14 mmol/l or 20 mmol/l) for 15eC30 min (shorter incubations in low glucose gave a less robust response on translocation without affecting [Ca2+]i responses [not shown]). Each experiment was concluded with the addition of CCh (0.25 mmol/l) to ensure that the Ins(1,4,5)P3 signaling remained functional.
Islets responded to the step increase in glucose concentration (from 2 to 20 mmol/l) with a sustained increase in [Ca2+]i (Fig. 6D), and an increase in cytoplasmic PLCPHD-EGFP fluorescence was observed in 70% of experiments (Fig. 6C). This increase was accompanied by a decrease in membrane-bound fluorescence, which indicates a translocation of PLCPHD-EGFP from the plasma membrane region into the cytoplasm (Fig. 6E). Addition of diazoxide (200 e蘭ol/l), an activator of ATP-sensitive K+ channels that hyperpolarizes the -cell and stops voltage-dependent [Ca2+]i influx (Fig. 6D), also decreased the cytoplasmic PLCPHD-EGFP fluorescence (Fig. 6C). This shows that PLC activity in -cells is sensitive to changes in glucose concentration and is likely mediated by [Ca2+]i.
Mouse islets stimulated with 14 mmol/l glucose typically exhibit [Ca2+]i oscillations. In these conditions, we observed repeated PLCPHD-EGFP translocations, which coincided with [Ca2+]i oscillations (Fig. 6F). The frequency of oscillations varied from 0.25 to 2.26 per min, which shows that both slow and faster oscillations were accompanied by PLC activation. Simultaneous recording of Fura Red and PLCPHD-EGFP fluorescence showed that the decrements in Fura Red fluorescence ([Ca2+]i increase) were almost simultaneous with peaks of cytoplasmic PLCPHD-EGFP fluorescence [Ins(1,4,5)P3 increase]. Islet fragments consisting of groups of 5eC50 cells also experienced glucose-dependent synchronous oscillations of Ins(1,4,5)P3 (not shown).
Treatment of mouse islet -cells with a blocker of delayed rectifier K+ channels, TEA, resulted in an increase in frequency and amplitude of [Ca2+]i oscillations (16,27,28). Treatment of glucose-stimulated islets with TEA (20 mmol/l) changed the frequency of PLCPHD-EGFP translocations [Ins(1,4,5)P3 accumulation] exactly in step with the change in [Ca2+]i oscillation frequency (Fig. 6G). This indicates that the [Ca2+]i changes in the -cell could be the activating mechanism for oscillations in PLC activity.
DISCUSSION
The regulation of intracellular Ca2+ stores in insulin-secreting cells is complex (29). There are several Ca2+ storage pools that can be discharged independently or semi-independently via various agonists. We sought to determine whether in addition to well-known pathways leading to insulin secretion via membrane depolarization following ATP-sensitive K+ channel blockade, glucose is also capable of discharging intracellular Ca2+ storage pools.
Thapsigargin-sensitive calcium stores in many cell types can be activated by PLC-dependent generation of Ins(1,4,5)P3. Secretagogue stimulation, as well as depolarization of the membrane potential can activate PLC and lead to Ins(1,4,5)P3 production in RINm5F cells (30), murine islets (31,32), and TC3 cells (33). Stimulation of Ins(1,4,5)P3 production by secretagogues was partially attributed to the effect of [Ca2+]i increase in RINmf cells (30).
However, none of the studies correlated the generation of Ins(1,4,5)P3 with glucose-stimulated [Ca2+]i oscillations. To test whether Ins(1,4,5)P3 is directly involved in the regulation of [Ca2+]i changes in mouse islets and MIN6 insulinoma cells, we used the Ins(1,4,5)P3/PIP2 biosensor PLCPHD-EGFP. Intracellular translocation of this biosensor is thought to be dependent upon both the decrease of PIP2 in the membrane and the increase of Ins(1,4,5)P3 in the cytoplasm (17,34,35). Although this system is semiquantitative, it is uniquely suited to real-time imaging and correlation of PLC activation with other cellular processes. We found that both video-rate spinning disk confocal microscopy and LSCM could report translocation, and each method had certain advantages. The dynamics of the processes induced by muscarinic stimulation and glucose/TEA in MIN6 cells could be analyzed by video-rate confocal microscopy (Figs. 2 and 4), but the smaller changes induced by glucose in islets were best observed with the somewhat increased sensitivity and enhanced band separation of our LSCM system (Fig. 6G).
We found that in primary mouse islets, stimulation with glucose can lead to oscillatory Ins(1,4,5)P3 generation. Cytoplasmic Ins(1,4,5)P3 increased with every [Ca2+]i increase so that the two processes were tightly coordinated. A change in frequency of [Ca2+]i oscillations in islets, induced by KV channel blockade, was immediately reflected in the frequency of Ins(1,4,5)P3 biosensor translocation oscillations. To our knowledge, this is the first report of dynamic visualization of glucose-induced Ins(1,4,5)P3 release in primary -cells. In MIN6 cells, glucose-dependent oscillations of [Ca2+]i in the presence of TEA were also accompanied by coordinated oscillations of Ins(1,4,5)P3 similar to those in islets.
It was tempting to argue that [Ca2+]i changes precede oscillatory changes of PLC activity, which can be seen in some of the graphs depicting simultaneous measurements. This conclusion seems logical based on the [Ca2+]i-dependence of PLC activation during depolarization with KCl and its sensitivity to diazoxide and TEA. However, experimental factors such as the differences in the diffusion times of [Ca2+]i and Ins(1,4,5)P3 might complicate the measurement and make correlation less certain. In addition, since Ins(1,4,5)P3 and [Ca2+]i can influence each other, we can expect that at different phases of the oscillations, one or the other might assume the "leading" role.
We recently suggested a role for Ins(1,4,5)P3 signaling in our mathematical model of slow [Ca2+]i oscillations in -cells (16). According to our model, Ca2+ mobilization from intracellular stores plays an important role in [Ca2+]i oscillations in pancreatic -cells. We proposed that endoplasmic reticulum calcium stores are filled, and PLC is activated at the upstroke of each [Ca2+]i oscillation. Both reach maximum shortly after [Ca2+]i is maximal, thus providing a source of Ins(1,4,5)P3 and a means for emptying the endoplasmic reticulum Ca2+ stores. Our data support this hypothesis since the increases in [Ca2+]i and Ins(1,4,5)P3 coincide.
The powerful signaling capacity of Ins(1,4,5)P3 makes it a potentially important factor in regulating glucose responses of the -cell, including [Ca2+]i oscillations. Ins(1,4,5)P3-mediated [Ca2+]endoplasmic reticulum release could potentially affect membrane potential by activating Ca2+-activated K+ channels in the -cell (36,37), or store-operated channels (16,38). In addition, cyclical activation of PLC suggests that diacylglycerol and PKC pathways are also likely to be glucose activated (39), which increases the potential importance of oscillations in -cell physiology.
In Chinese hamster ovary cells expressing the 1B-adrenergic receptor, [Ca2+]i oscillations are capable of stimulating transient increases in Ins(1,4,5)P3 via a positive feedback effect on PLC (40). Ca2+-dependent activation has been reported for PLC (41) and PLC- (30). Both of these isoforms are expressed in pancreatic -cells (31). Barker et al. (42) observed coordinate oscillations of [Ca2+]i and Ins(1,4,5)P3 in suspensions of mouse -cells that were stimulated to undergo synchronous oscillations by sequential applications of glucose (20 mmol/l), the 2-adrenergic agonist clonidine, and increased extracellular [Ca2+] (5 mmol/l) (43). Although these experiments did not represent normal glucose-induced oscillations and did not measure [Ca2+]i and Ins(1,4,5)P3 simultaneously in individual cells, they also suggest the presence of feedback mechanisms that connect [Ca2+]i and PLC activity in -cells. The PLCPHD-EGFP indicator was also used recently to simultaneously measure [Ca2+]i and Ins(1,4,5)P3 in INS-1 cells (25). This study established a positive correlation between changes of [Ca2+]i and Ins(1,4,5)P3 in INS-1 insulinoma cells, although [Ca2+]i oscillations in INS-1 cells studied by these authors were not glucose dependent.
Mechanisms that could be responsible for cyclic increases of Ins(1,4,5)P3 include direct activation of PLC by [Ca2+]i increase (40), indirect effect through [Ca2+]i-sensitive factors, or by cyclical stimulation of G-protein coupled receptors (42). It is also conceivable that glucose-stimulated Ins(1,4,5)P3 generation, no matter what its origin, is amplified by both membrane depolarization and Ca2+ influx. Additional factors resulting from secretagogue exposure or receptor stimulation are able to modify the sensitivity of PLC to Ca2+ in insulin secreting cells and also lead to partial desensitization to glucose stimulation, which might occur in hyperglycemic states (44). Further studies of PLC activity in insulin secreting cells are likely to contribute to the understanding and treatment of insulin secretion defects in type 2 diabetes.
FOOTNOTES
C.J.R. has served on an advisory panel for the Amylin/Eli Lilly partnership for exenatide (Byetta).
REFERENCES
Houamed K, Fu J, Roe MW, Philipson LH: Electrophysiology of the pancreatic -cell. In Diabetes Mellitus: A Fundamental and Clinical Text. 3rd ed. LeRoith D, Taylor SI, Olefsky JM, Eds. Philadelphia, Lippincott Williams and Wilkins, 2004, p.51eC70
Worley JF 3rd, McIntyre MS, Spencer B, Mertz RJ, Roe MW, Dukes ID: Endoplasmic reticulum calcium store regulates membrane potential in mouse islet beta-cells. J Biol Chem 269:14359eC14362, 1994
Dukes ID, Roe MW, Worley JF 3rd, Philipson LH: Glucose-induced alterations in -cell cytoplasmic Ca2+ involving the coupling of intracellular Ca2+ stores and plasma membrane ion channels. Curr Opin Endocrinol Diabetes 4:262eC271, 1997
Varadi A, Rutter GA: Dynamic imaging of endoplasmic reticulum Ca2+ concentration in insulin-secreting MIN6 Cells using recombinant targeted cameleons: roles of sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA)-2 and ryanodine receptors. Diabetes 51 (Suppl. 1):S190eCS201, 2002
Tengholm A, Hellman B, Gylfe E: Mobilization of Ca2+ stores in individual pancreatic beta-cells permeabilized or not with digitonin or alpha-toxin. Cell Calcium 27:43eC51, 2000
Gilon P, Henquin JC: Mechanisms and physiological significance of the cholinergic control of pancreatic beta-cell function. Endocr Rev 22:565eC604, 2001
Roe MW, Worley JF 3rd, Qian F, Tamarina N, Mittal AA, Dralyuk F, Blair NT, Mertz RJ, Philipson LH, Dukes ID: Characterization of a Ca2+ release-activated nonselective cation current regulating membrane potential and [Ca2+]i oscillations in transgenically derived beta-cells. J Biol Chem 273:10402eC10410, 1998
Gilon P, Arredouani A, Gailly P, Gromada J, Henquin JC: Uptake and release of Ca2+ by the endoplasmic reticulum contribute to the oscillations of the cytosolic Ca2+ concentration triggered by Ca2+ influx in the electrically excitable pancreatic B-cell. J Biol Chem 274:20197eC20205, 1999
Arredouani A, Henquin JC, Gilon P: Contribution of the endoplasmic reticulum to the glucose-induced [Ca2+]c response in mouse pancreatic islets. Am J Physiol Endocrinol Metab 282:E982eCE991, 2002
Islam S: The ryanodine receptor calcium channel of -cells: molecular regulation and physiological significance. Diabetes 51:1299eC1309, 2002
Barker CJ, Leibiger IB, Leibiger B, Berggren PO: Phosphorylated inositol compounds in beta-cell stimulus-response coupling. Am J Physiol Endocrinol Metab 283:E1113eCE1122, 2002
Hagar RE, Ehrlich BE: Regulation of the type III InsP3 receptor and its role in beta cell function. Cell Mol Life Sci 57:1938eC1949, 2000
Noguchi N, Takasawa S, Nata K, Tohgo A, Kato I, Ikehata F, Yonekura H, Okamoto H: Cyclic ADP-ribose binds to FK506-binding protein 12.6 to release Ca2+ from islet microsomes. J Biol Chem 272:3133eC3136, 1997
Johnson JD, Misler S: Nicotinic acid-adenine dinucleotide phosphate-sensitive calcium stores initiate insulin signaling in human beta cells. Proc Natl Acad Sci U S A 99:14566eC14571, 2002
Mitchell KJ, Lai FA, Rutter GA: Ryanodine receptor type I and nicotinic acid adenine dinucleotide phosphate receptors mediate Ca2+ release from insulin-containing vesicles in living pancreatic beta-cells (MIN6). J Biol Chem 28278:11057eC11064, 2003
Fridlyand L, Tamarina N, Philipson LH: Modeling of Ca2+ flux in pancreatic -cells: role of the plasma membrane and intracellular stores. Am J Physiol Endocrinol Metabolism 285:E138eCE154, 2003
Hirose K, Kadowaki S, Tanabe M, Takeshima H, Iino M: Spatiotemporal dynamics of inositol 1,4,5-trisphosphate that underlies complex Ca2+ mobilization patterns. Science 284:1527eC1530, 1999
Lingohr MK, Dickson LM, McCuaig JF, Hugl SR, Twardzik DR, Rhodes CJ: Activation of IRS-2-mediated signal transduction by IGF-1, but not TGF- or EGF, augments pancreatic -cell proliferation. Diabetes 51:966eC976, 2002
Dickson LM, Lingohr MK, McCuaig J, Hugl SR, Snow L, Kahn BB, Myers MG Jr, Rhodes CJ: Differential activation of protein kinase B and p70(S6)K by glucose and insulin-like growth factor 1 in pancreatic beta-cells (INS-1). J Biol Chem 276:21110eC21120, 2001
He TC, Zhou S, da Costa LT, Yu J, Kinzler KW, Vogelstein B: A simplified system for generating recombinant adenoviruses. Proc Natl Acad Sci U S A 95:2509eC2514, 1998
Inesi G, Sagara Y: Thapsigargin: a high affinity and global inhibitor of intracellular Ca2+ transport ATPases. Arch Biochem Biophys 298:313eC317, 1992
Liu YJ, Tengholm A, Grapengiesser E, Hellman B, Gylfe E: Origin of slow and fast oscillations of Ca2+ in mouse pancreatic islets. J Physiol 508:471eC481, 1998
Nash MS, Young KW, Challiss RA, Nahorski SR: Intracellular signalling: receptor-specific messenger oscillations. Nature 413:381eC382, 2001
Okubo Y, Kakizawa S, Hirose K, Iino M: Visualization of IP3 dynamics reveals a novel AMPA receptor-triggered IP3 production pathway mediated by voltage-dependent Ca2+ influx in Purkinje cells. Neuron 32:113eC122, 2001
Thore S, Dyachok O, Tengholm A: Oscillations of phospholipase C activity triggered by depolarization and Ca2+ influx in insulin-secreting cells. J Biol Chem 279:19396eC19400, 2004
Kavran JM, Klein DE, Lee A, Falasca M, Isakoff SJ, Skolnik EY, Lemmon MA: Specificity and promiscuity in phosphoinositide binding by pleckstrin homology domains. J Biol Chem 273:30497eC30508, 1998
Roe MW, Worley JF 3rd, Mittal AA, Kuznetsov A, DasGupta S, Mertz RJ, Witherspoon SM 3rd, Blair N, Lancaster ME, McIntyre MS, Shehee WR, Dukes ID, Philipson LH: Expression and function of pancreatic beta-cell delayed rectifier K+ channels: role in stimulus-secretion coupling. J Biol Chem 271:32241eC32246, 1996
Henquin JC: Role of voltage- and Ca2+-dependent K+ channels in the control of glucose-induced electrical activity in pancreatic B-cells. Pflugers Arch 416:568eC572, 1990
Michelangeli F, Ogunbayo OA, Wootton LL: A plethora of interacting Ca2+ stores. Curr Opin Cell Biol 17:135eC140, 2005
Kelley GG, Ondrako JM, Reks SE: Fuel and hormone regulation of phospholipase C beta 1 and delta 1 overexpressed in RINm5F pancreatic beta cells. Mol Cell Endocrinol 177:25107eC25115, 2001
Zawalich WS, Bonnet-Eymard M, Zawalich KC: Insulin secretion, inositol phosphate levels, and phospholipase C isozymes in rodent pancreatic islets. Metabolism 49:1156eC1163, 2000
Biden TJ, Peter-Riesch B, Schlegel W, Wollheim CB: Ca2+-mediated generation of inositol 1,4,5-triphosphate and inositol 1,3,4,5-tetrakisphosphate in pancreatic islets: studies with K+, glucose, and carbamylcholine. J Biol Chem 262:3567eC3571, 1987
Gromada J, Dissing S: Membrane potential and cytosolic free calcium levels modulate acetylcholine-induced inositol phosphate production in insulin-secreting TC3 cells. Biochim Biophys Acta 1310:145eC148, 1996
van der Wal J, Habets R, Varnai P, Balla T, Jalink K: Monitoring agonist-induced phospholipase C activation in live cells by fluorescence resonance energy transfer. J Biol Chem 276:15337eC15344, 2001
Xu C, Watras J, Loew LM: Kinetic analysis of receptor-activated phosphoinositide turnover. J Cell Biol 161:779eC791, 2003
Ammala C, Larsson O, Berggren PO, Bokvist K, Juntti-Berggren L, Kindmark H, Rorsman P: Inositol trisphosphate-dependent periodic activation of a Ca2+-activated K+ conductance in glucose-stimulated pancreatic beta-cells. Nature 353:849eC852, 1991
Tamarina NA, Wang Y, Mariotto L, Kuznetsov A, Bond C, Adelman J, Philipson LH: Small-conductance calcium-activated K+ channels are expressed in pancreatic islets and regulate glucose responses. Diabetes 52:2000eC2006, 2003
Roe MW, Philipson LH, Frangakis CJ, Kuznetsov A, Mertz RJ, Lancaster ME, Spencer B, Worley JF 3rd, Dukes ID: Defective glucose-dependent endoplasmic reticulum Ca2+ sequestration in diabetic mouse islets of Langerhans. J Biol Chem 269:18279eC18282, 1994
Zawalich WS, Zawalich KC: Regulation of insulin secretion by phospholipase C. Am J Physiol 271:E409eCE416, 1996
Young KW, Nash MS, Challiss RA, Nahorski SR: Role of Ca2+ feedback on single cell inositol 1,4,5-trisphosphate oscillations mediated by G-protein coupled receptors. J Biol Chem 278:20753eC20760, 2003
Allen V, Swigart P, Cheung R, Cockcroft S, Katan M: Regulation of inositol lipid-specific phospholipase Cdelta by changes in Ca2+ ion concentrations. Biochem J 327:545eC552, 1997
Barker CJ, Nilsson T, Kirk CJ, Michell RH, Berggren PO: Simultaneous oscillations of cytoplasmic free Ca2+ concentration and Ins(1,4,5)P3 concentration in mouse pancreatic beta-cells. Biochem J 297:265eC268, 1994
Shiga H, Tojima T, Ito E: Ca2+ signaling regulated by an ATP-dependent autocrine mechanism in astrocytes. Neuroreport 12:2619eC2622, 2001
Zawalich WS, Zawalich KC: Glucagon-like peptide-1 stimulates insulin secretion but not phosphoinositide hydrolysis from islets desensitized by prior exposure to high glucose or the muscarinic agonist carbachol. Metabolism 45:273eC278, 1996(Natalia A. Tamarina, Andr)
2 Pacific Northwest Research Institute, Seattle, Washington
ATP, adenosine 5'-triphosphate; [Ca2+]i, intracellular calcium concentration; CCh, carbamoylcholine; EGFP, enhanced green fluorescent protein; Ins(1,4,5)P3, inositol (1,4,5)-trisphosphate; KRBB, Krebs-Ringer bicarbonate buffer; LSCM, laser scanning confocal microscope; PHD, pleckstrin homology domain; PIP2, phosphatidylinositol(4,5)-bisphosphate; PLC, phospholipase C; TEA, tetraethylammonium
ABSTRACT
Glucose-stimulated insulin secretion is associated with transients of intracellular calcium concentration ([Ca2+]i) in the pancreatic -cell. We tested the hypothesis that inositol (1,4,5)-trisphosphate [Ins(1,4,5)P3] [Ca2+]i release is incorporated in glucose-induced [Ca2+]i oscillations in mouse islets and MIN6 cells. We found that depletion of intracellular Ca2+ stores with thapsigargin increased the oscillation frequency by twofold and inhibited the slow recovery phase of [Ca2+]i oscillations. We employed a pleckstrin homology domaineCcontaining fluorescent biosensor, phospholipase C pleckstrin homology domaineCenhanced green fluorescent protein, to visualize Ins(1,4,5)P3 dynamics in insulin-secreting MIN6 cells and mouse islets in real time using a video-rate confocal system. In both types of cells, stimulation with carbamoylcholine (CCh) and depolarization with KCl results in an increase in Ins(1,4,5)P3 accumulation in the cytoplasm. When stimulated with glucose, the Ins(1,4,5)P3 concentration in the cytoplasm oscillates in parallel with oscillations of [Ca2+]i. Maximal accumulation of Ins(1,4,5)P3 in these oscillations coincides with the peak of [Ca2+]i and tracks changes in frequencies induced by the voltage-gated K+ channel blockade. We show that Ins(1,4,5)P3 release in insulin-secreting cells can be stimulated by depolarization-induced Ca2+ flux. We conclude that Ins(1,4,5)P3 concentration oscillates in parallel with [Ca2+]i in response to glucose stimulation, but it is not the driving force for [Ca2+]i oscillations.
In the pancreatic -cell, glucose stimulation is associated with increased intracellular calcium ([Ca2+]i). The [Ca2+]i increase and subsequent [Ca2+]i oscillations are initiated by glucose metabolism through an increase in the adenosine 5'-triphosphate (ATP) level, a decrease in adenosine 5'-diphosphate level, and the subsequent closure of ATP-sensitive K+ channels (1). A number of reports have suggested that the endoplasmic reticulum plays a role in the regulation of the electrical activity and [Ca2+]i responses in the pancreatic -cell (2eC5). Calcium stores in the endoplasmic reticulum provide a regulated source of Ca2+, which can be quickly mobilized upon hormonal stimulation in insulin-secreting cells (6). The endoplasmic reticulum also provides a source of Ca2+ that contributes to [Ca2+]i increase in the cytoplasm during glucose stimulation (3,5,7), along with the extracellular Ca2+ influx through L-type Ca2+ channels. It has been suggested that the endoplasmic reticulum is replete with Ca2+ when cells are depolarized and Ca2+ is released upon repolarization (8,9).
Although some studies have suggested that the endoplasmic reticulum Ca2+ stores are mainly discharged by a passive leak of Ca2+ into the cytoplasm (8), others have indicated that gated efflux of endoplasmic reticulum Ca2+ is an important signaling mechanism in the glucose-stimulated -cell (10,11). -Cells have been shown to contain inositol 1,4,5-trisphosphate [Ins(1,4,5)P3] receptors (12), ryanodine receptors (4,10), and Ca2+ channels gated by cyclic ADP-ribose (13) or nicotinic acid adenine dinucleotide phosphate (14,15). Ins(1,4,5)P3-dependent mobilization of endoplasmic reticulum Ca2+ has been well described in -cells as part of the response to various agonists, such as acetylcholine, purine nucleotides, or histamines. However, it is still unclear whether Ins(1,4,5)P3 signaling is important in glucose-dependent -cell activation, particularly for [Ca2+]i oscillations. Our simulations of -cell calcium responses, taking into account ATP and Na+ homeostasis as well as uptake and release of Ca2+ by the endoplasmic reticulum, indicate that Ca2+ in the endoplasmic reticulum is one of the main variables driving [Ca2+]i oscillations (16). Our model suggested that the effect of regulated Ca2+ efflux from the intracellular stores could shape the pattern of slow calcium oscillations. Using a biosensor capable of reporting Ins(1,4,5)P3 (17) and confocal microscopy, we have demonstrated dynamics of Ins(1,4,5)P3 in mouse primary -cells and in MIN6 insulinoma cells upon stimulation with glucose and carbamoylcholine (CCh), as well as depolarization with KCl. We show that Ins(1,4,5)P3 concentration oscillates in parallel with [Ca2+]i in response to glucose stimulation, but it is not the driving force for [Ca2+]i oscillations.
RESEARCH DESIGN AND METHODS
Isolation and culturing of mouse islets of Langerhans and islet cells.
Islets were isolated from the pancreata of 1- to 5-month-old C57BL/J6 mice (The Jackson Laboratories) as described previously (7). To dissociate islets into fragments, they were incubated 5eC20 min in dilute trypsin/EDTA solution (Sigma, St. Louis, MO), titurated to dissociate the cells, and plated on glass coverslips in RPMI 1640 medium supplemented with 10% FCS, 11.6 mmol/l glucose, 100 units/ml penicillin, and 100 e蘥/ml streptomycin on glass coverslips for 1eC4 days. We did not observe any significant association of [Ca2+]i oscillation frequency with time in culture.
Recombinant adenoviruses.
Recombinant adenoviruses were generated to express phospholipase C pleckstrin homology domaineCenhanced green fluorescent protein (PLCPHD-EGFP) driven by the cytomegalovirus early promoter as previously described (18,19) using a bacterial recombination method in BJ5183 E. coli cells (20). Adenovirus-expressing green fluorescent protein was used as a control virus. The amplification and purification of these adenoviruses and their infection protocol were as previously described (18,19). Viral transduction of mouse islets was performed after they were cultured for 2 days on glass coverslips with 5 x 108 pfu/ml for 3 h, followed by imaging 1eC2 days posttransduction. In MIN6 cells, the intracellular localization of PLCPHD-EGFP was the same with either plasmid DNA transfection or adenovirus delivery (not shown). The expression of PLCPHD-EGFP did not affect [Ca2+]i responses to glucose or CCh in mouse islets (not shown).
Cell culture.
Insulin-secreting MIN6 cells were maintained in a humidified incubator with 95% air: 5% CO2 at 37°C in medium (Dulbecco’s modified Eagle’s medium, high-glucose medium supplemented with 10% FCS, 25 mmol/l glucose, 100 IU/ml penicillin, and 100 e蘥/ml streptomycin). MIN6 cells on coverslips were transfected with plasmid-expressing PLCPHD-EGFP driven by the cytomegalovirus early promoter (gift of Dr. Tobias Meyer, Stanford University, Stanford, CA) using Lipofectamine 2000 (Invitrogen, Carlsbad, CA) 1eC3 days before the experiment.
Measurement of [Ca2+]i with fura-2.
Mouse or rat pancreatic islets and MIN6 mouse insulinoma cells were loaded with fura-2 for 30 min to 1 h at 37°C in the corresponding growth medium supplemented with 5 e蘭ol/l acetoxymethyl ester of fura-2 (Molecular Probes, Eugene, OR). Fluorescence imaging was performed using a charged coupled deviceeCbased imaging system and MetaFluor software (Universal Imaging). During imaging experiments, cells or islets were kept at 37°C and constantly perifused with appropriate Krebs-Ringer bicarbonate buffer (KRBB) containing (in mmol/l) 119 NaCl, 4.7 KCl, 2.5 CaCl2, 1.2 MgSO4, 1.2 KH2PO4, and 25 NaHCO3, with varying concentrations of glucose as needed and appropriate inhibitors at a flow rate of 2.5 ml/min. [Ca2+]i was expressed as the ratio of fluorescence intensity (at 535/30 nm) after illumination at 340 nm and 380 nm. Calibration of fura-2 was performed using the Fura-2 Calcium Imaging Calibration Kit (Molecular Probes). At least three independent preparations of islets were used for each experimental protocol.
Fluorescent measurements of EGFP and [Ca2+]i in MIN6 and islets.
Between 1 and 2 h before the experiment, cells were loaded with 10 e蘭ol/l acetoxymethyl ester of Fura Red in growth medium (10 e蘬 of 1 mmol/l Fura Red-AM in DMSO was first mixed with 10 e蘬 of 20% Pluronic F127 and then diluted with 1 ml medium). At least three independent preparations of transfected cells or islets were used for each experimental protocol.
Imaging experiments were performed in real time using the Leica SP2 AOBS spectral laser scanning confocal microscope (LSCM) with the Leica DMIRE2 inverted microscope (Leica Microsystems, Heidelberg, Germany). Photoexcitation of both fluorophores was achieved by illumination at 488 nm (Ar laser), and emitted light was acquired at 520eC540 nm (EGFP) and at 630eC690 (Fura Red). Data acquisition and analysis were performed with Leica Confocal software (Leica Microsystems). Alternatively, a Nipkow dual rotating-disk confocal scanner (CSU10; Yokogawa Electric, Tokyo, Japan) and inverted microscope (Olympus, Tokyo, Japan) were used for confocal imaging. Photoexcitation was achieved by illumination with the 488 nm line of the Kr-Ar mixed-gas laser (series 43; Melles-Griot, Carlsbad, CA). Emitted light was filtered through the 530/30 nm (for EGFP signal) or 660/50 nm (for Fura Red signal) emission filter (Omega Filters, Brattleboro, VT). Data acquisition and analysis were performed with MetaFluor or MetaMorph software (Universal Imaging, Downingtown, PA).
Statistical analysis was performed using Student’s t test. Statistical significance was set at P = 0.05; results were presented as means ± SE.
RESULTS
Mouse islets at elevated glucose (10eC18 mmol/l) often display [Ca2+]i oscillations (16). To study the role of the intracellular Ca2+ stores in the generation of these oscillations, endoplasmic reticulum stores were emptied following treatment with thapsigargin, a specific inhibitor of the sarcoplasmic or endoplasmic reticulum ATPase pump (21). Thapsigargin (1 e蘭ol/l) was added to islets incubated in 14 mmol/l glucose; the emptying of the stores was verified by the absence of the [Ca2+]i discharge peak that occurs in untreated islets after the addition of 0.25 mmol/l CCh. Two groups of islets were selected based on their oscillation frequency (22): "slow," with oscillations 0.1eC1.0/min (39 islets, average 0.34 ± 0.06/min) and "fast," with oscillations faster than 2.0/min (19 islets, average 3.2 ± 0.8/min).
In the first group, thapsigargin produced a sustained elevation of [Ca2+]i (2) in 10% of islets (4/39 islets), whereas in another subset (6/39 islets), oscillations occurred irregularly (Fig. 1B). The majority of islets (29/39 islets) continued to oscillate after the addition of thapsigargin (Fig. 1A). In these islets, thapsigargin brought about a change in the oscillation waveform. The descending phase (downstroke) of each oscillation was accelerated and lacked the prolonged recovery "tail" characteristic of the slow-type oscillations (Figs. 1A and C). Shortening the lag time between two consecutive oscillations contributed to an increase in the oscillation frequency by 2.11 ± 0.17eCfold (P < 0.01, n = 29). observed with thapsigargin treatment (Fig. 1C).
In the group of islets with fast oscillations, there were also a few islets (3/19) that displayed a sustained increase in [Ca2+]i after the addition of thapsigargin. In the majority of islets (16/19), [Ca2+]i oscillations persisted after thapsigargin addition. In these islets, thapsigargin produced an increase in the frequency of [Ca2+]i oscillations by 1.72 ± 0.56eCfold (P < 0.01, n = 16) and a change in the waveform, similar to the islets with slower oscillations (Fig. 1D).
There were other distinctions between the two groups of islets. Treatment of fast-oscillating islets with thapsigargin usually brought an immediate increase of [Ca2+]i, most likely originating from the emptying of intracellular stores. The absence of this increase in slowly oscillating islets might indicate a lower filling state of the Ca2+ stores. Another difference involved a thapsigargin-stimulated increase in amplitude of oscillations by 2.3 ± 0.6eCfold (P < 0.05, n = 16) in fast-oscillating islets, whereas in the group of slowly oscillating islets, this parameter did not change.
Thus, it appears that the control of [Ca2+]i oscillation frequency and the generation of the waveform are modulated by endoplasmic reticulum [Ca2+] stores. We therefore further tested the hypothesis that in -cells, [Ca2+]i oscillations are accompanied by simultaneous cyclical activation of thapsigargin-sensitive Ca2+stores.
Thapsigargin-sensitive calcium stores in many cell types can be discharged by phospholipase C (PLC)-dependent generation of Ins(1,4,5)P3. To test the hypothesis that Ins(1,4,5)P3 is involved in the regulation of [Ca2+]i, changes in mouse islets, and MIN6 insulinoma cells, we employed an Ins(1,4,5)P3 biosensor, which has been previously used to monitor Ins(1,4,5)P3 metabolism in madin-darbycanine kidney epithelial cells (17), in Chinese hamster ovary cells (23), in Purkinje neurons (24), and in INS-1 cells (25). The fusion protein PLCPHD-EGFP combines the pleckstrin homology domain (PHD) of PLC with the EGFP. The PHD of PLC is highly specific for phosphate residues in positions 4 and 5 of inositol phosphates and therefore, it binds phosphatidylinositol (4,5)-bisphosphate (PIP2) and Ins(1,4,5)P3 (26).
In Fig. 2, the stimulation of MIN6 cells with the muscarinic receptor agonist CCh is illustrated. In nonstimulated cells expressing PLCPHD-EGFP, the fluorescent EGFP labeling was located mostly in the plasma membrane (Figs. 2A and B), which reflects the binding of the PLCPHD to PIP2. After stimulation with CCh, accompanied by the generation of Ins(1,4,5)P3, the PLCPHD-EGFP fluorescent label was translocated into the cytoplasm (Figs. 2C and D), where it bound soluble Ins(1,4,5)P3. Line-scan graphs (Figs. 2B and D) show the decrease of the EGFP fluorescence intensity in the plasma membrane of the cell and the gain of intensity in the cytoplasmic region of the cell. By measuring fluorescence in a cytoplasmic region, we were able to monitor the dynamics of Ins(1,4,5)P3 generation.
In MIN6 cells, we found that Ins(1,4,5)P3 generation is also activated by treatment of cells with 30 mmol/l KCl (Fig. 3A). Stimulation with KCl caused a 10.0 ± 2.4% increase in PLCPHD-EGFP translocation, which was significantly less than that observed following CCh treatment (48.4 ± 7.5%, P < 0.05, n = 65). Simultaneous detection of [Ca2+]i with Fura Red confirmed that both KCl treatment and subsequent stimulation with CCh are accompanied by increases in [Ca2+]i (not shown). To determine the role of extracellular Ca2+ in depolarization-stimulated PLC activation, stimulation with KCl (30 mmol/l) (in Ca2+-free KRBB containing 0.1 mmol/l EGTA) produced no detectable increase in Ins(1,4,5)P3 (Fig. 3B). Adding Ca2+ back to the incubation medium immediately stimulated Ins(1,4,5)P3 accumulation in KCl-depolarized cells.
Mouse insulinoma cells can display [Ca2+]i oscillations resembling those in pancreatic islets (16,27). Stimulation of MIN6 cells with high glucose (14 mmol/l) results in a modest nonoscillatory increase in [Ca2+]i level. However, subsequent addition of 10eC20 mmol/l tetraethylammonium (TEA), a potassium channel blocker, reveals an oscillatory response (Fig. 4A). TEA-induced [Ca2+]i oscillations in MIN6 cells are glucose-dependent, since TEA does not stimulate oscillations in low glucose (Fig. 4B). We sought to determine whether [Ca2+]i oscillations in MIN6 cells are associated with PLC activity and generation of Ins(1,4,5)P3.
Next, we studied simultaneous changes of Ins(1,4,5)P3 and [Ca2+]i in MIN6 cells. TEA prompted clusters of 5eC10 cells (Fig. 4C) to start synchronous [Ca2+]i oscillations (indicated by decreases in the Fura Red emission in Figs. 4DeCF) with a frequency of 0.3 to 1/min. In PLCPHD-EGFPeCexpressing cells, TEA invoked periodic increases in cytoplasmic EGFP fluorescence (536 nm emission), with a frequency identical to [Ca2+]i oscillations (0.3 to 1/min) (Fig. 4D). In the nuclei of the same cells (Fig. 4E), there were no oscillations of EGFP fluorescence, which correlated with the fact that PLCPHD-EGFP is not directed to the nucleus. Similarly, there were no oscillations of EGFP fluorescence in the cytoplasm of control cells not expressing PLCPHD-EGFP (Fig. 4F). Therefore, the oscillations of EGFP fluorescence in the cytoplasm are directly related to the expression of PLCPHD-EGFP and are not the result of the Fura Red emissions. In the majority of experiments (five out of six), the dynamics of PLCPHD-EGFP fluorescence in the cytoplasm correlated with increases in [Ca2+]i. These findings indicate that periodic translocations of PLCPHD-EGFP [generation of Ins(1,4,5)P3 and decrease in PIP2] were coincident with peaks of [Ca2+]i in MIN6 cells stimulated with glucose/TEA.
In mouse islets transduced with adenoviral vectoreCexpressing PLCPHD-EGFP, 5eC20 cells per islet on the surface area expressed PLCPHD-EGFP ("green" cells). Double immunofluorescence staining with anti-insulin and anti-GFP antibodies revealed that most of the EGFP-expressing cells were also positive for insulin (Fig. 5). One to three cells from each islet in close proximity to each other and in the same focal plane were studied in individual experiments.
CCh (0.25 mmol/l) treatment of islets in low glucose induced a translocation of PLCPHD-EGFP from its membrane-bound location into the cytoplasm. This translocation was accompanied by an increase in [Ca2+]i (Fig. 6A). CCh treatment in 14 mmol/l glucose led to oscillations in both PLC activity and [Ca2+]i (after an initial increase) (Fig. 6B) in about half of the islets observed. Treatment of islets with KCl (30 mmol/l) induced a translocation of PLCPHD-EGFP from plasma membrane to the cytoplasm along with an increase in [Ca2+]i (not shown).
We also sought to determine whether we could visualize if Ins(1,4,5)P3 generation in islets is stimulated by an increase in glucose concentration alone. Islets expressing PLCPHD-EGFP were first incubated in low glucose (2 mmol/l) for 2eC3 h, followed by high glucose (14 mmol/l or 20 mmol/l) for 15eC30 min (shorter incubations in low glucose gave a less robust response on translocation without affecting [Ca2+]i responses [not shown]). Each experiment was concluded with the addition of CCh (0.25 mmol/l) to ensure that the Ins(1,4,5)P3 signaling remained functional.
Islets responded to the step increase in glucose concentration (from 2 to 20 mmol/l) with a sustained increase in [Ca2+]i (Fig. 6D), and an increase in cytoplasmic PLCPHD-EGFP fluorescence was observed in 70% of experiments (Fig. 6C). This increase was accompanied by a decrease in membrane-bound fluorescence, which indicates a translocation of PLCPHD-EGFP from the plasma membrane region into the cytoplasm (Fig. 6E). Addition of diazoxide (200 e蘭ol/l), an activator of ATP-sensitive K+ channels that hyperpolarizes the -cell and stops voltage-dependent [Ca2+]i influx (Fig. 6D), also decreased the cytoplasmic PLCPHD-EGFP fluorescence (Fig. 6C). This shows that PLC activity in -cells is sensitive to changes in glucose concentration and is likely mediated by [Ca2+]i.
Mouse islets stimulated with 14 mmol/l glucose typically exhibit [Ca2+]i oscillations. In these conditions, we observed repeated PLCPHD-EGFP translocations, which coincided with [Ca2+]i oscillations (Fig. 6F). The frequency of oscillations varied from 0.25 to 2.26 per min, which shows that both slow and faster oscillations were accompanied by PLC activation. Simultaneous recording of Fura Red and PLCPHD-EGFP fluorescence showed that the decrements in Fura Red fluorescence ([Ca2+]i increase) were almost simultaneous with peaks of cytoplasmic PLCPHD-EGFP fluorescence [Ins(1,4,5)P3 increase]. Islet fragments consisting of groups of 5eC50 cells also experienced glucose-dependent synchronous oscillations of Ins(1,4,5)P3 (not shown).
Treatment of mouse islet -cells with a blocker of delayed rectifier K+ channels, TEA, resulted in an increase in frequency and amplitude of [Ca2+]i oscillations (16,27,28). Treatment of glucose-stimulated islets with TEA (20 mmol/l) changed the frequency of PLCPHD-EGFP translocations [Ins(1,4,5)P3 accumulation] exactly in step with the change in [Ca2+]i oscillation frequency (Fig. 6G). This indicates that the [Ca2+]i changes in the -cell could be the activating mechanism for oscillations in PLC activity.
DISCUSSION
The regulation of intracellular Ca2+ stores in insulin-secreting cells is complex (29). There are several Ca2+ storage pools that can be discharged independently or semi-independently via various agonists. We sought to determine whether in addition to well-known pathways leading to insulin secretion via membrane depolarization following ATP-sensitive K+ channel blockade, glucose is also capable of discharging intracellular Ca2+ storage pools.
Thapsigargin-sensitive calcium stores in many cell types can be activated by PLC-dependent generation of Ins(1,4,5)P3. Secretagogue stimulation, as well as depolarization of the membrane potential can activate PLC and lead to Ins(1,4,5)P3 production in RINm5F cells (30), murine islets (31,32), and TC3 cells (33). Stimulation of Ins(1,4,5)P3 production by secretagogues was partially attributed to the effect of [Ca2+]i increase in RINmf cells (30).
However, none of the studies correlated the generation of Ins(1,4,5)P3 with glucose-stimulated [Ca2+]i oscillations. To test whether Ins(1,4,5)P3 is directly involved in the regulation of [Ca2+]i changes in mouse islets and MIN6 insulinoma cells, we used the Ins(1,4,5)P3/PIP2 biosensor PLCPHD-EGFP. Intracellular translocation of this biosensor is thought to be dependent upon both the decrease of PIP2 in the membrane and the increase of Ins(1,4,5)P3 in the cytoplasm (17,34,35). Although this system is semiquantitative, it is uniquely suited to real-time imaging and correlation of PLC activation with other cellular processes. We found that both video-rate spinning disk confocal microscopy and LSCM could report translocation, and each method had certain advantages. The dynamics of the processes induced by muscarinic stimulation and glucose/TEA in MIN6 cells could be analyzed by video-rate confocal microscopy (Figs. 2 and 4), but the smaller changes induced by glucose in islets were best observed with the somewhat increased sensitivity and enhanced band separation of our LSCM system (Fig. 6G).
We found that in primary mouse islets, stimulation with glucose can lead to oscillatory Ins(1,4,5)P3 generation. Cytoplasmic Ins(1,4,5)P3 increased with every [Ca2+]i increase so that the two processes were tightly coordinated. A change in frequency of [Ca2+]i oscillations in islets, induced by KV channel blockade, was immediately reflected in the frequency of Ins(1,4,5)P3 biosensor translocation oscillations. To our knowledge, this is the first report of dynamic visualization of glucose-induced Ins(1,4,5)P3 release in primary -cells. In MIN6 cells, glucose-dependent oscillations of [Ca2+]i in the presence of TEA were also accompanied by coordinated oscillations of Ins(1,4,5)P3 similar to those in islets.
It was tempting to argue that [Ca2+]i changes precede oscillatory changes of PLC activity, which can be seen in some of the graphs depicting simultaneous measurements. This conclusion seems logical based on the [Ca2+]i-dependence of PLC activation during depolarization with KCl and its sensitivity to diazoxide and TEA. However, experimental factors such as the differences in the diffusion times of [Ca2+]i and Ins(1,4,5)P3 might complicate the measurement and make correlation less certain. In addition, since Ins(1,4,5)P3 and [Ca2+]i can influence each other, we can expect that at different phases of the oscillations, one or the other might assume the "leading" role.
We recently suggested a role for Ins(1,4,5)P3 signaling in our mathematical model of slow [Ca2+]i oscillations in -cells (16). According to our model, Ca2+ mobilization from intracellular stores plays an important role in [Ca2+]i oscillations in pancreatic -cells. We proposed that endoplasmic reticulum calcium stores are filled, and PLC is activated at the upstroke of each [Ca2+]i oscillation. Both reach maximum shortly after [Ca2+]i is maximal, thus providing a source of Ins(1,4,5)P3 and a means for emptying the endoplasmic reticulum Ca2+ stores. Our data support this hypothesis since the increases in [Ca2+]i and Ins(1,4,5)P3 coincide.
The powerful signaling capacity of Ins(1,4,5)P3 makes it a potentially important factor in regulating glucose responses of the -cell, including [Ca2+]i oscillations. Ins(1,4,5)P3-mediated [Ca2+]endoplasmic reticulum release could potentially affect membrane potential by activating Ca2+-activated K+ channels in the -cell (36,37), or store-operated channels (16,38). In addition, cyclical activation of PLC suggests that diacylglycerol and PKC pathways are also likely to be glucose activated (39), which increases the potential importance of oscillations in -cell physiology.
In Chinese hamster ovary cells expressing the 1B-adrenergic receptor, [Ca2+]i oscillations are capable of stimulating transient increases in Ins(1,4,5)P3 via a positive feedback effect on PLC (40). Ca2+-dependent activation has been reported for PLC (41) and PLC- (30). Both of these isoforms are expressed in pancreatic -cells (31). Barker et al. (42) observed coordinate oscillations of [Ca2+]i and Ins(1,4,5)P3 in suspensions of mouse -cells that were stimulated to undergo synchronous oscillations by sequential applications of glucose (20 mmol/l), the 2-adrenergic agonist clonidine, and increased extracellular [Ca2+] (5 mmol/l) (43). Although these experiments did not represent normal glucose-induced oscillations and did not measure [Ca2+]i and Ins(1,4,5)P3 simultaneously in individual cells, they also suggest the presence of feedback mechanisms that connect [Ca2+]i and PLC activity in -cells. The PLCPHD-EGFP indicator was also used recently to simultaneously measure [Ca2+]i and Ins(1,4,5)P3 in INS-1 cells (25). This study established a positive correlation between changes of [Ca2+]i and Ins(1,4,5)P3 in INS-1 insulinoma cells, although [Ca2+]i oscillations in INS-1 cells studied by these authors were not glucose dependent.
Mechanisms that could be responsible for cyclic increases of Ins(1,4,5)P3 include direct activation of PLC by [Ca2+]i increase (40), indirect effect through [Ca2+]i-sensitive factors, or by cyclical stimulation of G-protein coupled receptors (42). It is also conceivable that glucose-stimulated Ins(1,4,5)P3 generation, no matter what its origin, is amplified by both membrane depolarization and Ca2+ influx. Additional factors resulting from secretagogue exposure or receptor stimulation are able to modify the sensitivity of PLC to Ca2+ in insulin secreting cells and also lead to partial desensitization to glucose stimulation, which might occur in hyperglycemic states (44). Further studies of PLC activity in insulin secreting cells are likely to contribute to the understanding and treatment of insulin secretion defects in type 2 diabetes.
FOOTNOTES
C.J.R. has served on an advisory panel for the Amylin/Eli Lilly partnership for exenatide (Byetta).
REFERENCES
Houamed K, Fu J, Roe MW, Philipson LH: Electrophysiology of the pancreatic -cell. In Diabetes Mellitus: A Fundamental and Clinical Text. 3rd ed. LeRoith D, Taylor SI, Olefsky JM, Eds. Philadelphia, Lippincott Williams and Wilkins, 2004, p.51eC70
Worley JF 3rd, McIntyre MS, Spencer B, Mertz RJ, Roe MW, Dukes ID: Endoplasmic reticulum calcium store regulates membrane potential in mouse islet beta-cells. J Biol Chem 269:14359eC14362, 1994
Dukes ID, Roe MW, Worley JF 3rd, Philipson LH: Glucose-induced alterations in -cell cytoplasmic Ca2+ involving the coupling of intracellular Ca2+ stores and plasma membrane ion channels. Curr Opin Endocrinol Diabetes 4:262eC271, 1997
Varadi A, Rutter GA: Dynamic imaging of endoplasmic reticulum Ca2+ concentration in insulin-secreting MIN6 Cells using recombinant targeted cameleons: roles of sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA)-2 and ryanodine receptors. Diabetes 51 (Suppl. 1):S190eCS201, 2002
Tengholm A, Hellman B, Gylfe E: Mobilization of Ca2+ stores in individual pancreatic beta-cells permeabilized or not with digitonin or alpha-toxin. Cell Calcium 27:43eC51, 2000
Gilon P, Henquin JC: Mechanisms and physiological significance of the cholinergic control of pancreatic beta-cell function. Endocr Rev 22:565eC604, 2001
Roe MW, Worley JF 3rd, Qian F, Tamarina N, Mittal AA, Dralyuk F, Blair NT, Mertz RJ, Philipson LH, Dukes ID: Characterization of a Ca2+ release-activated nonselective cation current regulating membrane potential and [Ca2+]i oscillations in transgenically derived beta-cells. J Biol Chem 273:10402eC10410, 1998
Gilon P, Arredouani A, Gailly P, Gromada J, Henquin JC: Uptake and release of Ca2+ by the endoplasmic reticulum contribute to the oscillations of the cytosolic Ca2+ concentration triggered by Ca2+ influx in the electrically excitable pancreatic B-cell. J Biol Chem 274:20197eC20205, 1999
Arredouani A, Henquin JC, Gilon P: Contribution of the endoplasmic reticulum to the glucose-induced [Ca2+]c response in mouse pancreatic islets. Am J Physiol Endocrinol Metab 282:E982eCE991, 2002
Islam S: The ryanodine receptor calcium channel of -cells: molecular regulation and physiological significance. Diabetes 51:1299eC1309, 2002
Barker CJ, Leibiger IB, Leibiger B, Berggren PO: Phosphorylated inositol compounds in beta-cell stimulus-response coupling. Am J Physiol Endocrinol Metab 283:E1113eCE1122, 2002
Hagar RE, Ehrlich BE: Regulation of the type III InsP3 receptor and its role in beta cell function. Cell Mol Life Sci 57:1938eC1949, 2000
Noguchi N, Takasawa S, Nata K, Tohgo A, Kato I, Ikehata F, Yonekura H, Okamoto H: Cyclic ADP-ribose binds to FK506-binding protein 12.6 to release Ca2+ from islet microsomes. J Biol Chem 272:3133eC3136, 1997
Johnson JD, Misler S: Nicotinic acid-adenine dinucleotide phosphate-sensitive calcium stores initiate insulin signaling in human beta cells. Proc Natl Acad Sci U S A 99:14566eC14571, 2002
Mitchell KJ, Lai FA, Rutter GA: Ryanodine receptor type I and nicotinic acid adenine dinucleotide phosphate receptors mediate Ca2+ release from insulin-containing vesicles in living pancreatic beta-cells (MIN6). J Biol Chem 28278:11057eC11064, 2003
Fridlyand L, Tamarina N, Philipson LH: Modeling of Ca2+ flux in pancreatic -cells: role of the plasma membrane and intracellular stores. Am J Physiol Endocrinol Metabolism 285:E138eCE154, 2003
Hirose K, Kadowaki S, Tanabe M, Takeshima H, Iino M: Spatiotemporal dynamics of inositol 1,4,5-trisphosphate that underlies complex Ca2+ mobilization patterns. Science 284:1527eC1530, 1999
Lingohr MK, Dickson LM, McCuaig JF, Hugl SR, Twardzik DR, Rhodes CJ: Activation of IRS-2-mediated signal transduction by IGF-1, but not TGF- or EGF, augments pancreatic -cell proliferation. Diabetes 51:966eC976, 2002
Dickson LM, Lingohr MK, McCuaig J, Hugl SR, Snow L, Kahn BB, Myers MG Jr, Rhodes CJ: Differential activation of protein kinase B and p70(S6)K by glucose and insulin-like growth factor 1 in pancreatic beta-cells (INS-1). J Biol Chem 276:21110eC21120, 2001
He TC, Zhou S, da Costa LT, Yu J, Kinzler KW, Vogelstein B: A simplified system for generating recombinant adenoviruses. Proc Natl Acad Sci U S A 95:2509eC2514, 1998
Inesi G, Sagara Y: Thapsigargin: a high affinity and global inhibitor of intracellular Ca2+ transport ATPases. Arch Biochem Biophys 298:313eC317, 1992
Liu YJ, Tengholm A, Grapengiesser E, Hellman B, Gylfe E: Origin of slow and fast oscillations of Ca2+ in mouse pancreatic islets. J Physiol 508:471eC481, 1998
Nash MS, Young KW, Challiss RA, Nahorski SR: Intracellular signalling: receptor-specific messenger oscillations. Nature 413:381eC382, 2001
Okubo Y, Kakizawa S, Hirose K, Iino M: Visualization of IP3 dynamics reveals a novel AMPA receptor-triggered IP3 production pathway mediated by voltage-dependent Ca2+ influx in Purkinje cells. Neuron 32:113eC122, 2001
Thore S, Dyachok O, Tengholm A: Oscillations of phospholipase C activity triggered by depolarization and Ca2+ influx in insulin-secreting cells. J Biol Chem 279:19396eC19400, 2004
Kavran JM, Klein DE, Lee A, Falasca M, Isakoff SJ, Skolnik EY, Lemmon MA: Specificity and promiscuity in phosphoinositide binding by pleckstrin homology domains. J Biol Chem 273:30497eC30508, 1998
Roe MW, Worley JF 3rd, Mittal AA, Kuznetsov A, DasGupta S, Mertz RJ, Witherspoon SM 3rd, Blair N, Lancaster ME, McIntyre MS, Shehee WR, Dukes ID, Philipson LH: Expression and function of pancreatic beta-cell delayed rectifier K+ channels: role in stimulus-secretion coupling. J Biol Chem 271:32241eC32246, 1996
Henquin JC: Role of voltage- and Ca2+-dependent K+ channels in the control of glucose-induced electrical activity in pancreatic B-cells. Pflugers Arch 416:568eC572, 1990
Michelangeli F, Ogunbayo OA, Wootton LL: A plethora of interacting Ca2+ stores. Curr Opin Cell Biol 17:135eC140, 2005
Kelley GG, Ondrako JM, Reks SE: Fuel and hormone regulation of phospholipase C beta 1 and delta 1 overexpressed in RINm5F pancreatic beta cells. Mol Cell Endocrinol 177:25107eC25115, 2001
Zawalich WS, Bonnet-Eymard M, Zawalich KC: Insulin secretion, inositol phosphate levels, and phospholipase C isozymes in rodent pancreatic islets. Metabolism 49:1156eC1163, 2000
Biden TJ, Peter-Riesch B, Schlegel W, Wollheim CB: Ca2+-mediated generation of inositol 1,4,5-triphosphate and inositol 1,3,4,5-tetrakisphosphate in pancreatic islets: studies with K+, glucose, and carbamylcholine. J Biol Chem 262:3567eC3571, 1987
Gromada J, Dissing S: Membrane potential and cytosolic free calcium levels modulate acetylcholine-induced inositol phosphate production in insulin-secreting TC3 cells. Biochim Biophys Acta 1310:145eC148, 1996
van der Wal J, Habets R, Varnai P, Balla T, Jalink K: Monitoring agonist-induced phospholipase C activation in live cells by fluorescence resonance energy transfer. J Biol Chem 276:15337eC15344, 2001
Xu C, Watras J, Loew LM: Kinetic analysis of receptor-activated phosphoinositide turnover. J Cell Biol 161:779eC791, 2003
Ammala C, Larsson O, Berggren PO, Bokvist K, Juntti-Berggren L, Kindmark H, Rorsman P: Inositol trisphosphate-dependent periodic activation of a Ca2+-activated K+ conductance in glucose-stimulated pancreatic beta-cells. Nature 353:849eC852, 1991
Tamarina NA, Wang Y, Mariotto L, Kuznetsov A, Bond C, Adelman J, Philipson LH: Small-conductance calcium-activated K+ channels are expressed in pancreatic islets and regulate glucose responses. Diabetes 52:2000eC2006, 2003
Roe MW, Philipson LH, Frangakis CJ, Kuznetsov A, Mertz RJ, Lancaster ME, Spencer B, Worley JF 3rd, Dukes ID: Defective glucose-dependent endoplasmic reticulum Ca2+ sequestration in diabetic mouse islets of Langerhans. J Biol Chem 269:18279eC18282, 1994
Zawalich WS, Zawalich KC: Regulation of insulin secretion by phospholipase C. Am J Physiol 271:E409eCE416, 1996
Young KW, Nash MS, Challiss RA, Nahorski SR: Role of Ca2+ feedback on single cell inositol 1,4,5-trisphosphate oscillations mediated by G-protein coupled receptors. J Biol Chem 278:20753eC20760, 2003
Allen V, Swigart P, Cheung R, Cockcroft S, Katan M: Regulation of inositol lipid-specific phospholipase Cdelta by changes in Ca2+ ion concentrations. Biochem J 327:545eC552, 1997
Barker CJ, Nilsson T, Kirk CJ, Michell RH, Berggren PO: Simultaneous oscillations of cytoplasmic free Ca2+ concentration and Ins(1,4,5)P3 concentration in mouse pancreatic beta-cells. Biochem J 297:265eC268, 1994
Shiga H, Tojima T, Ito E: Ca2+ signaling regulated by an ATP-dependent autocrine mechanism in astrocytes. Neuroreport 12:2619eC2622, 2001
Zawalich WS, Zawalich KC: Glucagon-like peptide-1 stimulates insulin secretion but not phosphoinositide hydrolysis from islets desensitized by prior exposure to high glucose or the muscarinic agonist carbachol. Metabolism 45:273eC278, 1996(Natalia A. Tamarina, Andr)