Evidence that Glucose-Induced Electrical Activity in Rat Pancreatic b-Cells Does Not Require KATP Channel Inhibition

KATP-channel activity, recorded in cell-attached patches from isolated rat pancreatic beta-cells, was found to be maximally inhibited in the presence of a substimulatory concentration (5 mM) of glucose, with no further effect of higher, stimulatory glucose concentrations. KATP channel-independent effects of glucose on electrical activity were therefore investigated by incubating cells in the presence of a supramaximal concentration of tolbutamide. Addition of tolbutamide (500 mM) to cells equilibrated in the absence of glucose resulted in a rapid depolarization and electrical activity followed by a gradual repolarization and disappearence of electrical activity. Repolarization was not due to desensitization of KATP channels to the sulfonylurea, but was probably the result of activation of another K+ conductance. The subsequent application of 16 mM glucose in the continued presence of tolbutamide depolarized the cells again, leading to renewed electrical activity. Input conductance of the cells was markedly reduced by tolbutamide, reflecting KATP-channel inhibition, but was not significantly affected by the addition of glucose in the presence of the drug. In cells voltage-clamped at -70 mV, addition of glucose in the presence of tolbutamide generated a noisy inward current, probably representing activation of the volume-sensitive anion channel. KATP channel-independent activation of electrical activity by glucose was inhibited by the anion channel inhibitor 4,4'-dithiocyanatostilbene-2,2'-disulphonic acid. It is concluded that the induction of electrical activity in rat pancreatic b-cells does not require inhibition of KATP channels. The KATP channel-independent mechanism could involve, at least in part, activation by glucose of the volume-sensitive anion channel.     

Glucose-sensitive conductances in rat pancreatic beta-cells: contribution to electrical activity

The perforated patch technique was used to assess the relative contribution of K(ATP) channel activity, assessed from input conductance (G(input)), and volume-sensitive anion channel activity to the induction of electrical activity in single isolated rat pancreatic beta-cells by glucose, 2-ketoisocaproate and tolbutamide. In cells equilibrated in the absence of glucose, the membrane potential was -71 mV and G(input) 3.66 nS. Addition of 8 mM glucose resulted in depolarisation, electrical activity and a reduction in G(input), reflecting an inhibition of K(ATP) channels. Cells equilibrated in 4 mM glucose had a membrane potential of -59 mV and a G(input) of 0.88 nS. In this case, a rise in glucose concentration to 8-20 mM again resulted in depolarisation and electrical activity, but caused a small increase in G(input). 2-Ketoisocaproate also evoked electrical activity and an increase in G(input), whereas electrical activity elicited by addition of tolbutamide was accompanied by reduced G(input). Increasing the concentration of glucose from 4 to 8-20 mM generated a noisy inward current at -70 mV, reflecting activation of the volume-sensitive anion channel. The mean amplitude of this current was glucose-dependent within the range 4-20 mM. Addition of 2-ketoisocaproate or a 15% hypotonic solution elicited similar increases in inward current. In contrast, addition of tolbutamide failed to induce the inward current. It is concluded that K(ATP) channel activity is most sensitive to glucose within the range 0-4 mM. At higher glucose concentrations effective in generating electrical activity, activation of the volume-sensitive anion channel could contribute towards the nutrient-induced increase in G(input).     

Effects of Cl- deficiency on the membrane potential in mouse pancreatic beta-cells

The membrane potential of mouse pancreatic beta-cells was measured with microelectrodes. In the resting cell (3 mM D-glucose), the membrane potential was -63 +/- 3 mV (mean +/- S.E. for four experiments). In the presence of 3 mM D-glucose, total Cl- substitution by isethionate induced a depolarization by 3-4 mV, and readmission of Cl- induced a hyperpolarization by 3-5 mV. At 10 mM glucose, reduction of Cl- to 12 mM by substituting isethionate for Cl- reversibly shifted the repolarization potential by 6-9 mV in the positive direction and stimulated the burst activity during the initial 2-3 min by increasing the fraction of plateau phase. This was followed by a gradual inhibition of electrical activity, including decrease in fraction of plateau phase and slow wave amplitude. Total substitution of Cl- by isethionate or methyl sulphate reversibly shifted the repolarization potential by 3-4 mV in the positive direction and rapidly inhibited the electrical burst pattern without any initial stimulation. Glucose-induced (10 mM) insulin release (15 min) and 45Ca2+ uptake (3 min) were strongly inhibited by reducing the Cl- concentration to 10 mM (isethionate as substitute) and were further inhibited by further reduction of the Cl- concentration. It is suggested that beta-cells are equipped with on electrogenic Cl- flux, which can affect the burst pattern of electrical activity. The inhibitory effects of Cl- substitution may be explained by an influence of Cl- on the voltage-controlled Ca2+ channels.     

Glucose and tolbutamide trigger transients of Ca2+ in single pancreatic beta-cells exposed to tetraethylammonium.

Isolated pancreatic beta-cells respond to glucose stimulation with increase of the cytoplasmic Ca2+ concentration ([Ca2+]i) in terms of membrane-derived slow oscillations (0.2-0.5/min) with superimposed transient of intracellular origin. To evaluate under which conditions transients may result also from entry of extracellular Ca2+, the cytoplasmic concentration of the ion was measured with dual wavelength fluorometry and fura-2 in individual mouse beta-cells exposed to the K+ channel blocker tetraethylammonium (TEA). In the presence of 20 mM TEA, the beta-cells responded to closure of the KATP channels (increase of the glucose concentration to 11 mM or addition of 1 mM tolbutamide) with pronounced transients of [Ca2+]i. However, there were no transients when the beta-cells were depolarized by raising extracellular K+ to 30 mM in the presence of 20 mM TEA. The glucose-induced [Ca2+]i transients became more pronounced after thapsigargin inhibition of the endoplasmic reticulum Ca(2+)-ATPase. The tolbutamide-induced transients were amplified when promoting the entry of Ca2+ (rise of extracellular Ca2+ to 10 mM or addition of BAY K 8644), unaffected in the presence of thapsigargin and the Na+ channel blocker tetrodotoxin and slightly reduced by glucagon. Blockage of voltage-dependent Ca2+ channels with methoxyverapamil resulted in a prompt disappearance of the transients induced by glucose or tolbutamide. The observations indicate that closure of the KATP channels can precipitate pronounced transients of [Ca2+]i when other K+ conductances are suppressed.     

Modulation of the bursting properties of single mouse pancreatic beta-cells by artificial conductances

Glucose triggers bursting activity in pancreatic islets, which mediates the Ca2+ uptake that triggers insulin secretion. Aside from the channel mechanism responsible for bursting, which remains unsettled, it is not clear whether bursting is an endogenous property of individual beta-cells or requires an electrically coupled islet. While many workers report stochastic firing or quasibursting in single cells, a few reports describe single-cell bursts much longer (minutes) than those of islets (15-60 s). We studied the behavior of single cells systematically to help resolve this issue. Perforated patch recordings were made from single mouse beta-cells or hamster insulinoma tumor cells in current clamp at 30-35 degrees C, using standard K+-rich pipette solution and external solutions containing 11.1 mM glucose. Dynamic clamp was used to apply artificial KATP and Ca2+ channel conductances to cells in current clamp to assess the role of Ca2+ and KATP channels in single cell firing. The electrical activity we observed in mouse beta-cells was heterogeneous, with three basic patterns encountered: 1) repetitive fast spiking; 2) fast spikes superimposed on brief (<5 s) plateaus; or 3) periodic plateaus of longer duration (10-20 s) with small spikes. Pattern 2 was most similar to islet bursting but was significantly faster. Burst plateaus lasting on the order of minutes were only observed when recordings were made from cell clusters. Adding gCa to cells increased the depolarizing drive of bursting and lengthened the plateaus, whereas adding gKATP hyperpolarized the cells and lengthened the silent phases. Adding gCa and gKATP together did not cancel out their individual effects but could induce robust bursts that resembled those of islets, and with increased period. These added currents had no slow components, indicating that the mechanisms of physiological bursting are likely to be endogenous to single beta-cells. It is unlikely that the fast bursting (class 2) was due to oscillations in gKATP because it persisted in 100 microM tolbutamide. The ability of small exogenous currents to modify beta-cell firing patterns supports the hypothesis that single cells contain the necessary mechanisms for bursting but often fail to exhibit this behavior because of heterogeneity of cell parameters.     

A new class of calcium channels activated by glucose in human pancreatic beta-cells

Single calcium-channel currents were recorded from membrane patches of cultured beta-cells dissociated from human islets of Langerhans. In the absence of exogenous glucose, low frequency spontaneous calcium-channel openings of small amplitude (-0.34 +/- 0.02 pA at 0 mV pipet potential) were observed in all membrane patches examined (25 mM Ca2+ in the patch pipet). The frequency of channel openings was rather insensitive to the membrane potential across the patch (range from ca 0 to 60 mV pipet potential; chord conductance 4.9 +/- 0.2 pS). Addition of glucose induced a dose-dependent increase in the frequency of openings of the Ca2(+)-channel (from now on referred to as the CaG-channel). A few minutes after the addition of glucose (greater than or equal to 11 mM), bursts of action potentials were often observed which were elicited only if Ca2+ was present in the solution bathing the beta-cells. Application of glucose in the presence of mannoheptulose (11 mM), a blocker of the hexokinase controlling the first stage of glycolysis, had no effect and the activity of the CaG-channel remained at its resting level. The readily permeant mitochondrial substrate 2-keto-isocaproate (KIC, 10 mM) was as effective as glucose in eliciting action potentials from cells forming part of cell aggregates. The activity of the CaG-channel was significantly increased by KIC (11 mM). Although spike and Ca2(+)-channel activity were markedly stimulated by glucose or KIC in all cells examined, regular bursts of action potentials were seen only if the patch was formed on beta-cells which were part of a cell aggregate. Mannoheptulose (11 mM) prevented the activation of the CaG-channel by glucose (11 mM) but not by KIC (11 mM). Once activated, the CaG-channel remained active even after excision of the patch. We propose that the physiological control of this Ca2(+)-channel is mediated by one or more products of glucose metabolism.     

Inhibition of glucose-induced electrical activity by 4-hydroxytamoxifen in rat pancreatic beta-cells.

The antioestrogen 4-hydroxytamoxifen (10 or 2 microM) abolished the generation of action potentials and repolarized the membrane potential in rat pancreatic beta-cells stimulated by 16 mM glucose. This effect was slowly reversible upon withdrawal of the drug. In cells stimulated by tolbutamide (100 microM), application of 4-hydroxytamoxifen again inhibited action-potential generation but failed to repolarize the membrane potential. 4-Hydroxytamoxifen inhibited voltage-sensitive calcium currents and activity of the volume-sensitive anion channel. The drug had no effect on net K(+) conductance of the cell. Insulin release stimulated by either glucose or tolbutamide was inhibited by 4-hydroxytamoxifen. It is concluded that 4-hydroxytamoxifen impairs beta-cell electrical and secretory activity by inhibiting calcium and anion channel currents. This effect could contribute towards hyperglycaemia during therapy with tamoxifen, of which 4-hydroxytamoxifen is the major metabolite. This study also reveals differences between the depolarizing actions of glucose and tolbutamide in the beta-cell.     

Role of pH as a transduction device in triggering electrical and secretory responses in islet B cells

Changes in pH alter the oscillatory pattern of glucose-induced electrical activity of mouse islet B cells, thereby supporting the hypothesis that changes in intracellular pH (pHi) resulting from glucose metabolism serve as a coupling factor between metabolic and cationic events. A decrease in pHi in the present of 11.1 mM glucose induces an increase in the duration of the active phase similar to that evoked by higher concentrations of glucose. Regulation of pHi appears to occur by Na:H and HCO3:Cl exchange in the plasma membrane, because inhibition by 0.1 mM amiloride and 0.5 mM 4,4'-diisothiocyano-2,2'-stilbene disulfonic acid (DIDS), respectively, induces constant spike activity in the presence of 11.1 mM glucose. If the pH coupling hypothesis is correct, then inhibition of the putative pH regulatory mechanisms and the subsequent decrease in pHi should elicit electrical activity in the presence of subthreshold glucose (less than 7.0 mM). Amiloride induced electrical activity (threshold) at 4.4 +/- 0.3 mM (mean +/- SEM) glucose. The threshold for DIDS was 5.4 +/- 0.2 glucose, whereas with glucose alone the threshold was achieved at 7.0 +/- 0.4 mM. Thus the generation of H+ by glucose may trigger changes in ionic conductances that induce the typical electrical response. Amiloride was found to elicit a secretory response at subthreshold glucose (4.2-7.0 mM) in perifused rat islets. This indicates that pH-induced changes in the ionic events in the B cells also play an important role in information transfer to the secretory complex.     

Increased ATP-sensitive K+ channel expression during acute glucose deprivation

ATP-sensitive potassium (KATP) channels play a central role in glucose-stimulated insulin secretion (GSIS) by pancreatic beta-cells. Activity of these channels is determined by their open probability (Po) and the number of channels present in a cell. Glucose is known to reduce Po, but whether it also affects the channel density is unknown. Using INS-1 model beta-cell line, we show that the expression of K(ATP) channel subunits, Kir6.2 and SUR1, is high at low glucose, but declines sharply when the ambient glucose concentration exceeds 5mM. In response to glucose deprivation, channel synthesis increases rapidly by up-regulating translation of existing mRNAs. The effects of glucose deprivation could be mimicked by pharmacological activation of 5'-AMP-activated protein kinase with 5-aminoimidazole-4-carboxamide ribonucleotide and metformin. Pancreatic beta-cells which have lost their ability for GSIS do not show such changes implicating a possible (patho-)physiological link between glucose-regulated KATP channel expression and the capacity for normal GSIS.     

Nitric oxide-cyclic GMP system potentiates glucose-induced rise in cytosolic Ca2+ concentration in rat pancreatic beta-cells.

Involvement of nitric oxide (NO) in the regulation of insulin secretion from pancreatic beta-cells was investigated by measuring cytosolic Ca2+ concentration ([Ca2+]i) in isolated rat pancreatic beta-cells. At 7.0 mM glucose, L-arginine (0.1 mM) elevated [Ca2+]i in about 50% of the beta-cells examined. The response was partially inhibited by an NO synthase inhibitor, N(G)-monomethyl-L-arginine (L-NMA; 0.1 mM), suggesting that part of the response was mediated by the production of NO from L-arginine. D-Arginine at higher concentrations (3 or 10 mM) also increased [Ca2+]i at 7.0 mM glucose; however, the response was not affected by L-NMA (0.1 mM). Similar [Ca2+]i elevation was produced by NO (10 nM) and sodium nitroprusside (SNP; 10 microM) at 7.0 mM glucose. The SNP-induced increase in [Ca2+]i was abolished by nicardipine (1 microM), suggesting that the [Ca2+]i response is mediated by Ca2+ influx through L-type voltage-operated Ca2+ channels. In the presence of oxyhemoglobin (1 microM), the [Ca2+]i elevation induced by NO (10 nM) was abolished. Neither degradation products of NO, NO2- nor NO3-, caused any changes in [Ca2+]i. 8-Bromo-cyclic GMP (8-Br-cGMP; 3 mM) and atrial natriuretic peptide (0.1 microM) elevated [Ca2+]i at 7.0 mM glucose. We conclude that NO, which is produced from L-arginine in pancreatic islets, facilitates glucose-induced [Ca2+]i increase via the elevation of cGMP in rat pancreatic beta-cells. NO-cGMP system may physiologically regulate insulin secretion from pancreatic beta-cells.     

Glucose-induced increase in cytoplasmic pH in pancreatic beta-cells is mediated by Na+/H+ exchange, an effect not dependent on protein kinase C.

Glucose-induced changes in cytoplasmic pH (pHi) were investigated using pancreatic beta-cells isolated from obese hyperglycemic mice. Glucose, at concentrations above 3-5 mM, depolarized the beta-cell and increased pHi, cytoplasmic free Ca2+ ([Ca2+]i), and insulin release. This increase in pHi was dependent on the presence of extracellular Na+ and was inhibited by 5-(N-ethyl-N-isopropyl) amiloride, a blocker of Na+/H+ exchange. Stimulation of protein kinase C with phorbol ester also induced an alkalinization. However, when protein kinase C activity was down-regulated, glucose stimulation still induced alkalinization. At 20 mM glucose, 10 mM NH4Cl induced a marked rise in pHi, paralleled by repolarization, inhibition of electrical activity, and decreases in both [Ca2+]i and insulin release. Reduction in [Ca2+]i was prevented by 200 microM tolbutamide, but not by 10 mM tetraethylammonium. At 4 mM glucose, NH4Cl induced a transient increase in insulin release, without changing [Ca2+]i. Exposure of beta-cells to 10 mM sodium acetate caused a persistent decrease in pHi, an effect paralleled by a small transient increase in [Ca2+]i. Acidification per se did not change the beta-cell sensitivity to glucose, not excluding that the activity of the ATP-regulated K+ channels may be modulated by changes in pHi.     

Effect of perchlorate on calcium uptake and insulin secretion in mouse pancreatic islets.

Microdissected beta-cell-rich pancreatic islets of non-inbred ob/ob mice were used in studies of how perchlorate (CIO4-) affects stimulus-secretion coupling in beta-cells. CIO4- at 16 mM potentiated D-glucose-induced insulin release, without inducing secretion at non-stimulatory glucose concentrations. The potentiation mainly applied to the first phase of stimulated insulin release. In the presence of 20 mM-glucose, the half-maximum effect of CIO4- was reached at 5.5 mM and maximum effect at 12 mM of the anion. The potentiation was reversible and inhibitable by D-mannoheptulose (20 mM) or Ca2+ deficiency. CIO4- at 1-8 mM did not affect glucose oxidation. The effects on secretion were paralleled by a potentiation of glucose-induced 45Ca2+ influx during 3 min. K+-induced insulin secretion and 45Ca2+ uptake were potentiated by 8-16 mM-CIO4-. The spontaneous inactivation of K+-induced (20.9 mM-K+) insulin release was delayed by 8 mM-CIO4-. The anion potentiated the 45Ca2+ uptake induced by glibenclamide, which is known to depolarize the beta-cell. Insulin release was not affected by 1-10 mM-trichloroacetate. It is suggested that CIO4- stimulates the beta-cell by affecting the gating of voltage-controlled Ca2+ channels.     

Modulation of K+ conductance by intracellular pH in pancreatic beta-cells

Measurements of the effects of NH3/NH4+ on glucose-induced electrical activity in beta-cells from microdissected mouse islets of Langerhans and on intracellular pH in single collagenase-isolated islets pre-loaded with a fluorescent pH probe were performed and are reported here. Application of NH3/NH4+ (15 mM) in the presence of glucose (11 mM) promptly hyperpolarized the beta-cell membrane, reduced input resistance by 60% and blocked electrical activity. These changes were paralleled by an increase in islet fluorescence indicative of a cytosolic pH increase. Removal of NH4Cl initially stimulated electrical activity, which returned to resting level with a time constant of 51 s. Concomitant with the removal of NH4Cl there was a drop in pHi followed by a slow return to resting level with a time constant of 83 s. The results suggest that the [Ca2+]-dependent K+ channel in the beta-cell membrane is activated by a rise in cytosolic pH.     

Protein kinase C-dependent and -independent inhibition of Ca(2+) influx by phorbol ester in rat pancreatic beta-cells

Phorbol esters were used to investigate the action of protein kinase C (PKC) on insulin secretion from pancreatic beta-cells. Application of 80 nM phorbol 12-myristate 13-acetate (PMA), a PKC-activating phorbol ester, had little effect on glucose (15 mM)-induced insulin secretion from intact rat islets. In islets treated with bisindolylmaleimide (BIM), a PKC inhibitor, PMA significantly reduced the glucose-induced insulin secretion. PMA decreased the level of intracellular Ca(2+) concentration ([Ca(2+)](i)) elevated by the glucose stimulation when tested in isolated rat beta-cells. This inhibitory effect of PMA was not prevented by BIM. PMA inhibited glucose-induced action potentials, and this effect was not prevented by BIM. Further, 4alpha-phorbol 12,13-didecanoate (4alpha-PDD), a non-PKC-activating phorbol ester, produced an effect similar to PMA. In the presence of nifedipine, the glucose stimulation produced only depolarization, and PMA applied on top of glucose repolarized the cell. When applied at the resting state, PMA hyperpolarized beta-cells with an increase in the membrane conductance. Recorded under the voltage-clamp condition, PMA reduced the magnitude of Ca(2+) currents through L-type Ca(2+) channels. BIM prevented the PMA inhibition of the Ca(2+) currents. These results suggest that activation of PKC maintains glucose-stimulated insulin secretion in pancreatic beta-cells, defeating its own inhibition of the Ca(2+) influx through L-type Ca(2+) channels. PKC-independent inhibition of electrical excitability by phorbol esters was also demonstrated.     

Heterogeneity in glucose sensitivity among pancreatic beta-cells is correlated to differences in glucose phosphorylation rather than glucose transport.

Rat beta-cells differ in their individual rates of glucose-induced insulin biosynthesis and release. This functional heterogeneity has been correlated with intercellular differences in metabolic redox responsiveness to glucose. The present study compares glucose metabolism in two beta-cell subpopulations that have been separated on the basis of the presence (high responsive) or absence (low responsive) of a metabolic redox shift at 7.5 mM glucose. Mean rates of glucose utilization and glucose oxidation in high responsive beta-cells were 2- to 4-fold higher than in low responsive beta-cells, whereas their leucine and glutamine oxidation was only 10-50% higher. This heterogeneity in glucose metabolism cannot be attributed to differences in GLUT2 mRNA levels or in glucose transport. In both cell subpopulations, the rates of glucose transport (13-19 pmol/min/10(3) beta-cells) were at least 50-fold higher than corresponding rates of glucose utilization. On the other hand, rates of glucose phosphorylation (0.3-0.7 pmol/min/10(3) beta-cells) ranged within those of total glucose utilization (0.2-0.4 pmol/min/10(3) beta-cells). High responsive beta-cells exhibited a 60% higher glucokinase activity than low responsive beta-cells and their glucokinase mRNA level was 100% higher. Furthermore, glucose phosphorylation via low Km hexokinase was detected only in the high responsive beta-cell subpopulation. Heterogeneity in glucose sensitivity among pancreatic beta-cells can therefore be explained by intercellular differences in glucose phosphorylation rather than in glucose transport.     

Surface charge and properties of cardiac ATP-sensitive K+ channels

ATP-sensitive K+ (KATP) channels are present in a wide variety of tissues. The sensitivity of these channels to closure by cytosolic ATP (ATPi) varies significantly among different tissues and even within the same tissue. The purpose of this study was to test the hypothesis that negative surface charges modulate the sensitivity of the KATP channels to ATPi by influencing surface potential in the vicinity of the ATP- binding site(s) of the channel. Unitary currents through KATP channels were measured in inside-out membrane patches excised from rabbit ventricular myocytes using the patch-clamp technique. Agents known to be effective at screening negative surface charges were applied to the cytosolic surface of the patches, and their effects on ATP sensitivity were examined. These agents included Mg2+ (2-15 mM), Ba2+ (2-10 mM), and the polycations protamine (0.01-10 microM), poly-L-lysine (500 microM), and poly-L-arginine (0.5 microM). The divalent cations and the various polycations all dramatically reduced the concentration of ATPi required to half-maximally suppress current through KATP channels (Kd), from approximately 100 microM in the absence of these agents to 1.6-8 microM in their presence. The effects were dose dependent. Protamine also reduced the sensitivity of KATP channels to block by cytosolic ADP. The sensitivity of KATP channels to block by ATP was independent of membrane potential, suggesting that the ATP-binding site is not located within the transmembrane voltage field. The effects of the polycation poly-L-lysine on ATP sensitivity were also independent of membrane potential or the direction (inward or outward) of current through KATP channels. In addition to increasing ATP sensitivity, Mg2+, Ba2+, and the polycations all caused dose-dependent block of inward and outward currents through KATP channels over similar concentration ranges as their effects on ATP sensitivity. The block of inward current by polycations was not associated with reduction of single-channel conductance or evidence of fast open channel block. However, the polycations did cause a modest reduction in single-channel conductance of outward current. These results are consistent with the presence of negative surface charges that reduce the local ATP concentration at the ATP-binding site(s) on the channel, relative to the bulk cytosolic ATP concentration. Screening these negative surface charges with divalent cations or polycations decreases the local ATP gradient, resulting in a decrease in the apparent Kd for ATP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Diffusion of extracellular K+ can synchronize bursting oscillations in a model islet of Langerhans.

Electrical bursting oscillations of mammalian pancreatic beta-cells are synchronous among cells within an islet. While electrical coupling among cells via gap junctions has been demonstrated, its extent and topology are unclear. The beta-cells also share an extracellular compartment in which oscillations of K+ concentration have been measured (Perez-Armendariz and Atwater, 1985). These oscillations (1-2 mM) are synchronous with the burst pattern, and apparently are caused by the oscillating voltage-dependent membrane currents: Extracellular K+ concentration (Ke) rises during the depolarized active (spiking) phase and falls during the hyperpolarized silent phase. Because raising Ke depolarizes the cell membrane by increasing the potassium reversal potential (VK), any cell in the active phase should recruit nonspiking cells into the active phase. The opposite is predicted for the silent phase. This positive feedback system might couple the cells' electrical activity and synchronize bursting. We have explored this possibility using a theoretical model for bursting of beta-cells (Sherman et al., 1988) and K+ diffusion in the extracellular space of an islet. Computer simulations demonstrate that the bursts synchronize very quickly (within one burst) without gap junctional coupling among the cells. The shape and amplitude of computed Ke oscillations resemble those seen in experiments for certain parameter ranges. The model cells synchronize with exterior cells leading, though incorporating heterogeneous cell properties can allow interior cells to lead. The model islet can also be forced to oscillate at both faster and slower frequencies using periodic pulses of higher K+ in the medium surrounding the islet. Phase plane analysis was used to understand the synchronization mechanism. The results of our model suggest that diffusion of extracellular K+ may contribute to coupling and synchronization of electrical oscillations in beta-cells within an islet.     

Intact pancreatic islets and dispersed beta-cells both generate intracellular calcium oscillations but differ in their responsiveness to glucose

Pancreatic islets produce pulses of insulin and other hormones that maintain normal glucose homeostasis. These micro-organs possess exquisite glucose-sensing capabilities, allowing for precise changes in pulsatile insulin secretion in response to small changes in glucose. When communication among these cells is disrupted, precision glucose sensing falters. We measured intracellular calcium patterns in 6-mM-steps between 0 and 16 mM glucose, and also more finely in 2-mM-steps from 8 to 12 mM glucose, to compare glucose sensing systematically among intact islets and dispersed islet cells derived from the same mouse pancreas in vitro. The calcium activity of intact islets was uniformly low (quiescent) below 4 mM glucose and active above 8 mM glucose, whereas dispersed beta-cells displayed a broader activation range (2-to-10 mM). Intact islets exhibited calcium oscillations with 2-to-5-min periods, yet beta-cells exhibited longer 7–10 min periods. In every case, intact islets showed changes in activity with each 6-mM-glucose step, whereas dispersed islet cells displayed a continuum of calcium responses ranging from islet-like patterns to stable oscillations unaffected by changes in glucose concentration. These differences were also observed for 2-mM-glucose steps. Despite the diversity of dispersed beta-cell responses to glucose, the sum of all activity produced a glucose dose-response curve that was surprisingly similar to the curve for intact islets, arguing against the importance of “hub cells” for function. Beta-cells thus retain many of the features of islets, but some are more islet-like than others. Determining the molecular underpinnings of these variations could be valuable for future studies of stem-cell-derived beta-cell therapies.     

Cyclic AMP as a determinant for glucose induction of fast Ca2+ oscillations in isolated pancreatic beta-cells.

The effect of glucose on the cytoplasmic Ca2+ concentration ([Ca2+]i) of pancreatic beta-cells from ob/ob-mice was examined by dual wavelength recordings of the 340/380 nm fluorescence excitation ratio of fura-2. Single beta-cells responded to 11-20 mM glucose with an initial lowering of [Ca2+]i, followed by an increase usually manifested as large amplitude oscillations (300-500 nm) with a frequency of 0.2-0.5/min (a-type). Particularly in freshly isolated beta-cells, there were also superimposed fast oscillations with frequencies of 2-8/min amplitudes in the 70-250 nM range (b-type) and sometimes pronounced [Ca2+]i transients exceeding 250 nM with durations below 10 s (c-type). After addition of 1-100 nM glucagon or 1 mM of the dibutyryl or 8-bromo derivatives of cyclic AMP, glucose generated numerous b-type oscillations superimposed on those of the a-type or on an elevated steady-state level. The duration of the b-type oscillations increased slightly when glucose was raised from 11 to 16 mM. The c-type transients probably represent a separate reaction predominantly seen when raising cyclic AMP much above its normal concentration. It is concluded that glucose can induce fast oscillations of [Ca2+]i also in isolated beta-cells, especially when measures are taken to increase their cyclic AMP content.