Mitochondrial Ca2+ Uptake Regulates the Excitability of Myenteric Neurons

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The Journal of Neuroscience, August 15, 2002, 22(16):6962-6971

Mitochondrial Ca²⁺ Uptake Regulates the Excitability of Myenteric Neurons
Pieter Vanden Berghe, James L. Kenyon, and Terence K. Smith
Department of Physiology and Cell Biology, University of Nevada, School of Medicine, Reno, Nevada 89557-0046

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We investigated the role of mitochondria in the regulation of intracellular Ca²⁺ ([Ca²⁺]_i) and excitability of myenteric neurons in guinea pig ileum,using microelectrodes and fura-2 [Ca²⁺]_i measurements. In AH/Type-II neurons, action potentials evokeryanodine-sensitive increases in [Ca²⁺]_i that activate Ca²⁺-dependent K⁺ channels and slow afterhyperpolarizations (AH) lasting ~15 sec.Exposure to the protonophore carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone(FCCP; 1 µM) had no significant effect on the membrane potentialor resting [Ca²⁺]_i. However, action potentials elicited in the presence of FCCPtriggered a sustained (>5 min) increase in [Ca²⁺]_i and a compound hyperpolarization (13.4 ± 1.5 mV). The respiratorychain blockers antimycin A and rotenone (10 µM) had similar effectsthat developed more slowly. Depletion of the intracellular Ca²⁺ stores with thapsigargin (2 µM) or ryanodine (10 µM) greatlyattenuated the hyperpolarization caused by FCCP. S/Type-I neuronsthat do not have AH were hyperpolarized by mitochondrial inhibitionindependently of action potentials. Blockade of the F₀F₁ ATPaseby oligomycin (10 µM) had variable effects on myenteric neurons.The majority of AH/Type-II neurons were hyperpolarized by oligomycin,most likely by activating ATP-dependent K⁺ channels. This hyperpolarization was not triggered by actionpotential firing and not accompanied by an increase in [Ca²⁺]_i. MitoTracker staining revealed a dense mitochondrial networkparticularly in myenteric AH/Type-II neurons, supporting the importanceof mitochondrial Ca²⁺ buffering in this subset of neurons. The data indicate that mitochondrialuptake of Ca²⁺ released from the endoplasmic reticulum sets [Ca²⁺]_i and the activity of Ca²⁺-dependent conductances, thus regulating the excitability of myentericneurons.

Key words: mitochondria; fura-2; intracellular calcium; MitoTracker; ER tracker; neuron; K_Ca channel; K_ATP channel; afterhyperpolarization; neuronal excitability; antimycin A; FCCP; rotenone; oligomycin; guinea pig ileum

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mitochondria produce ATP via ATPases that run in reverse, driven by the proton electrochemical gradient across the mitochondrialmembrane. This gradient is built up by electron transport duringoxidative phosphorylation. Besides their role in supplying energy,mitochondria are also important in apoptosis, aging, and Ca²⁺ homeostasis. Although the latter has long been debated, recentstudies have put mitochondria back on the Ca²⁺ scene as crucial players (Duchen, 2000; Friel, 2000; Rizzutoet al., 2000). Friel and Tsien (1994) described a Ca²⁺ store in bullfrog sympathetic neurons that was sensitive to theprotonophore FCCP [carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone],and mitochondria also have been shown to alter depolarization-induced[Ca²⁺]_i responses and the gating properties of Ca²⁺-activated currents in a variety of neurons, indicating substantialCa²⁺ removal by these organelles (Thayer and Miller, 1990; Werth andThayer, 1994; Kenyon and Goff, 1998; Nowicky and Duchen, 1998;Pivovarova et al., 1999; Friel, 2000; Vanden Berghe et al., 2002;Wang and Thayer, 2002). Quantitative measurements have revealeda double role for mitochondria: they sequester Ca²⁺ during depolarization to release it again during repolarization(Babcock and Hille, 1998; Colegrove et al., 2000). Several systems,including Ca²⁺ uniporters, Ca²⁺/H⁺ exchangers, Na⁺-dependent and independent release mechanisms, and permeabilitytransition pores, contribute to mitochondrial Ca²⁺ handling (Gunter et al., 2000). Further, mitochondria often arepositioned closely to the endoplasmic reticulum (ER), and optimalER function requires competent mitochondria (Landolfi et al.,1998).

Myenteric neurons are comprised in a ganglionated network in the intestinal wall. They include intrinsic sensory neurons,interneurons, and motor neurons that exert reflex activity andcoordinate the propulsion of the intestinal contents (Smith etal., 1992). Electrophysiologically, these neurons have been classifiedin two or more groups (Nishi and North, 1973; Hirst et al., 1974;Wood, 1994; Smith et al., 1999). S/Type-I neurons have eitherphasic or tonic firing characteristics and their action potentialsare TTX-sensitive. The AH/Type-II neurons are characterized byprolonged afterhyperpolarizations (AH) that follow action potentialfiring. Their action potentials have, besides the TTX-sensitivepart, also a Ca²⁺ component (Morita et al., 1982; Hirst et al., 1985) that triggersCa²⁺ release from the ER via the activation of ryanodine receptors(Hillsley et al., 2000; Vogalis et al., 2001). The increased intracellularCa²⁺ concentration opens Ca²⁺-activated K⁺ channels responsible for the transient slow AH, a mechanism alsoobserved in other neurons (Kawai and Watanabe, 1989; Sah and McLachlan,1991; Yoshizaki et al., 1995; Moore et al., 1998; Shah and Haylett,2000; Vogalis et al., 2002). The AH/Type-II neurons have beenidentified as intrinsic primary afferent neurons (Furness et al.,1998) and are therefore important in the organization of gastrointestinalmotility. By inhibiting the throughput of sensory informationduring the afterhyperpolarization, they determine the frequencyat which interneurons and motor neurons are driven. Because theAH is directly dependent on the [Ca²⁺]_i and because there is evidence that mitochondria play an importantrole in the Ca²⁺ handling in several other neurons, we aimed to investigate therole of mitochondria in the Ca²⁺ homeostasis and therefore the membrane excitability of myentericneurons.

Parts of this work have been published previously as an abstract (Vanden Berghe and Smith, 2001).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Tissue preparation. Adult guinea pigs (250-350 gm) were asphyxiated by CO₂, followed by exsanguination (a method approvedby the Animal Ethics Committee at the University of Nevada, Reno).A 5 cm segment of ileum was removed, flushed with cold Krebs'solution, and pinned flat in a Sylgard-lined dissection dish.The intestine was opened along the serosal border, and the mucosa,submucosa, and circular muscle layer were removed with fine forceps.During the dissection the preparation was perfused constantlywith ice-cold Krebs' solution bubbled with a 3% CO₂/97% O₂ gasmixture. The longitudinal muscle myenteric plexus preparationswere stretched and clipped on a stainless steel ring. The tissueswere equilibrated in a recording dish with a coverslip bottomfor at least 1 hr in warmed Krebs' solution (36°C; bubbled with3% CO₂/97% O₂). Shortly after the temperature reached steady state,vigorous contractions were observed in the tissue preparations.To make intracellular recordings possible, we added 1-2 µM nicardipineand 1 µM atropine to the bath solution to relax the underlyinglongitudinal muscle layer (Hillsley et al., 2000).

Membrane potential recordings. Ganglia were identified easily under bright-field light microscopy (Nikon TE 300; Nikon, Tokyo,Japan). The neurons were impaled with glass microelectrodes pulledon a 767 Sutter (Novato, CA) Microelectrode puller, and the membranepotential was recorded. To perform [Ca²⁺]_i measurements simultaneously, we filled the tips of the electrodeswith 1-2 mM bis-fura-2 (K_D = 370 nM) hexapotassium salt dissolvedin 1-2 M KCl. The rest of the electrode was filled with 2 M KCl.The resistance of the electrodes varied between 120 and 150 M $Omega$ .The signals were amplified with an Axoclamp 2B amplifier (AxonInstruments, Union City, CA) and monitored continuously on a TektronixR468 oscilloscope (Tektronix, Beaverton, OR). A bipolar electrodewas used to stabilize the tissue against the coverslip bottomand to elicit synaptic potentials in the impaled neurons. Intracellularpulses and extracellular pulse trains were triggered and generatedby a Master-8 pulse generator (A.M.P.I., Jerusalem,Israel).

Fura-2 measurements of [Ca²⁺]_i. Fura-2 was loaded iontophoretically into the neurons by applying a train of hyperpolarizingpulses (0.2-0.4 nA at 1-2 Hz) for 2-4 min. Fluorescent signalswere recorded with an Ionoptix (Milton, MA) Fluorescence System.A xenon lamp was used as a UV light source. Differential excitation(340/380 nm) of the Ca²⁺ indicator resulted from a spinning chopper wheel (at 60 Hz) toobtain ratiometric values at 30 Hz. Images were recorded witha CCD camera (Ionoptix), and rectangular regions of interest weredrawn in the image. The fura-2 ratio was calculated for that specificarea. The membrane potential recordings were sampled at the maximalrate (1 kHz) simultaneously with the fura-2 signals by using theanalog-to-digital board of the Ionoptix interface box and displayedand stored in the same data file. We chose to express the [Ca²⁺]_i signals as fura-2 ratios rather than calibrated Ca²⁺ signals, because the R_min could not be obtained reliably fromcalibrations by using ionomycin and 0 mM Ca²⁺ solutions. This was in part due to the way the preparation wasset up and also attributable to the fact that the underlying musclelayer interfered with exact calibration of thesignals.

Immunochemical stainings and fluorescent markers. Myenteric plexus longitudinal muscle preparations were pinned flat in sterileSylgard-lined dissection dishes. The tissues were incubated (37°C;5% CO₂) during 1 hr in the presence of 0.1-1 µM ER-Tracker BlueDPX and/or 0.1-1 µM MitoTracker Green. The organotypic mediumconsisted of HAM/F12 culture medium supplemented with 2% fetalbovine serum, 1 µM nifedipine, and 1% penicillin-gentamycin antibioticsolution. The tissues were washed thoroughly in cold Krebs' solution,fixed in 4% paraformaldehyde (30 min), and washed in a 0.1 M PO₄³ buffered 0.9% NaCl solution, pH 7.2. To identify calbindin-likeimmunoreactive neurons, we incubated the tissues (48 hr) in a0.1 M PO₄³ buffered 0.9% NaCl solution, pH 7.2, containing 1:100 mouse monoclonalanti-calbindin D-28K antibody. The secondary antibody was anti-mouseIgG coupled to Texas Red (1:150; 90 min). The tissues were washedand mounted on slides with Aquamount. An Olympus BX50 microscopewith specific filter cubes (FITC: EX, BP470/490; DM, 505; EM,BA 535/50; and aminomethylcoumarin: EX, D360/40; DM, BS 400 dichroiclongpass; EM, BA 435-485; Chroma, Brattleboro, VT) was used tovisualize the MitoTracker and ER tracker, respectively. Confocalimaging was performed with Bio-Rad (Hercules, CA) MRC 600 (60×lens) and Nikon confocal microscopes (40× lens). Images were acquiredvia excitation wavelengths of 488 nm (for MitoTracker Green) and568 nm (for Texas Red). Scion Image (Frederick, MD) was used toquantify MitoTracker intensity in composite images of z-seriesscans of five optical sections through a depth of 2.5 µm, usinga confocal aperture <20% ofmaximum.

Calculations and statistics. Amplitudes and durations of the transient events were calculated as indicated in Figure 1. Thetime to 90% recovery was calculated as a measurement of duration(90% duration) of the afterhyperpolarization and the Ca²⁺ transient. Resting membrane potentials were measured before andduring the application of mitochondrial blockers and comparedwith a paired Student's t test or ANOVA with a Bonferroni testas a post hoc analysis. To study the effect of mitochondrial blockerson the transient responses, we calculated both the 90% durationand the remaining amplitude of the AH and Ca²⁺ transient 15 sec after action potential spiking. The average± SEM duration and amplitudes of AH and Ca²⁺ transients were compared with a paired Student's t test. A pvalue of 0.05 was considered the cutoff for statistical significance;n values specify the number of neurons. Curve fittings and statisticalanalysis were performed in GraphPad Prism (San Diego, CA) or MSExcel (Microsoft, Redmond,WA).

Drugs and solutions. All drugs and the antibody against calbindin were obtained from Sigma (St. Louis, MO). Bis-fura-2 hexapotassiumsalt, MitoTracker Green, and ER-Tracker Blue DPX were obtainedfrom Molecular Probes (Eugene, OR). The anti-mouse IgG coupledto Texas Red was from Vector Labs (Burlingame, CA), and tissueculture supplies (HAM/F12, fetal bovine serum, and antibiotics)were obtained from Invitrogen (Grand Island, NY). The Krebs' solutionused throughout this study contained (in mM): 120.3 NaCl, 5.9KCl, 1.2 MgCl₂, 1.2 NaH₂PO₄, 15.5 NaHCO₃, 2.5 CaCl₂, and 11.5glucose.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Microelectrode recordings were obtained from 102 neurons (75 animals), 54 of which were identified as AH/Type-II neurons onthe basis of the prominent AH they displayed after action potential(AP) firing. Most of the hyperpolarizations consisted of botha fast (fAH) and a slow (sAH) component (Fig. 1A,B). The averageamplitude of the sAH, elicited by 2 APs, was 9.8 ± 0.6 mV, andthe average 90% duration was 15.9 ± 2.9 sec (n = 10). fAH valueswere smaller (5.1 ± 0.3 mV) and shorter (43.5 ± 1.5 msec). Theamplitudes of both fast and slow AH and the duration of the sAHincreased linearly (r² > 0.9) with the number of action potentials preceding the AH(fAH, ~2.5 mV/AP; sAH, ~2 mV/AP; DUR_sAH, 2.2 sec/AP; n = 6). SingleAPs usually did not elicit a detectable fAH. The amplitude ofthe sAH was also linearly dependent (r² > 0.85) on the holding potential (current clamp) and increased~1 mV for each 10 mV the neuron was depolarized. In 13 AH neuronsthe [Ca²⁺]_i was monitored simultaneously. The sAH was always closely matchedby a Ca²⁺ transient that started with the AP firing and reached a maximum385 ± 81 msec (n = 7) after onset of the depolarizing pulse. ThesAH itself reached its maximum 1115 ± 257 msec (n = 7) after theonset of AP firing (Fig. 1A). The amplitude and duration of theaccompanying Ca²⁺ transient, like for those of the AH, increased for an increasingnumber of action potentials (Fig. 2A), and the recovery followedan exponential time course ( $tau$ = ~2.4 sec) similar to that describedin a previous report (Hillsley et al., 2000).

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Figure 1. Schematic overview of some parameters calculated in this study. A, A slow afterhyperpolarization (sAH) and the matching Ca²⁺ transient. Amplitude and 90% duration were calculated as indicated with the dashed lines. B, Amplitude and duration of the fast afterhyperpolarization (fAH).

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Figure 2. A typical example of the responses as observed in myenteric neurons. Top panels show the changes in [Ca²⁺]_i; bottom panels are the changes in membrane potential (V_m). A, Action potential firing in AH/Type-II neurons is followed by a transient afterhyperpolarization that is larger for an increasing number of action potentials, as shown in the insets. The afterhyperpolarization is matched closely by a [Ca²⁺]_i transient, which decays exponentially. B, In S/Type-I neurons several action potentials are needed to elicit a detectable Ca²⁺ transient that is increasing and decaying gradually.

In phasic S/Type-I neurons the [Ca²⁺]_i increased gradually during the repetitive firing of single APs (up to 10) and decayedslowly afterward (Fig. 2B). Single APs never elicited a detectabletransient in these neurons. The Ca²⁺ transients in tonically firing S/Type-I neurons increased inamplitude with the number of APs during the depolarizing pulse,whereas the short afterhyperpolarization (3.5 ± 0.3 sec) thatsometimes was observed in these neurons (Shuttleworth and Smith,1999) was independent of the number ofAPs.

Effect of mitochondrial inhibitors on membrane potential and [Ca²⁺]_i of AH/Type-II neurons

Membrane potential and resting [Ca²⁺]_i
To assess the effect of mitochondrial inhibition on neuronal excitability, we challenged nine AH neurons with the protonophoreFCCP (1 µM). The membrane potential was measured in control conditionsand in the presence of FCCP before and after stimulation. Exposureto FCCP (~1.5 min) did not change the resting membrane potentialsignificantly ( $-$ 57.5 ± 4.2 to $-$ 59.2 ± 4.3 mV; ANOVA; Bonferronipost hoc analysis; p > 0.05; n = 9). However, when APs were elicitedin the presence of FCCP, the AH triggered by these APs was followedby a significant compound hyperpolarization ( $-$ 57.5 ± 4.2 to $-$ 71.6± 4.9 mV; ANOVA; Bonferroni post hoc analysis; p < 0.001; n =9) (Fig. 3A). In the majority (6 of 9) of AH neurons the membranepotential did not recover after the first AH and stayed hyperpolarized.The time to reach the maximum of the compound hyperpolarizationwas, on average, 146 ± 31 sec (n = 9). In the course of this hyperpolarizationdepolarizing current pulses no longer elicited action potentials(Fig. 3A). In six AH neurons in which the [Ca²⁺]_i was monitored simultaneously, the AP-induced compound hyperpolarizationin the presence of FCCP was accompanied by a ~10% increase infura-2 ratio (0.94 ± 0.13 to 1.04 ± 0.17; p = 0.04). This [Ca²⁺]_i rise was approximately twice the amplitude of the single AP-inducedtransients (Fig. 3A). Seven recordings were kept sufficientlylong to investigate the reversibility of FCCP. After washout (5-10min) the membrane potential recovered to control levels ( $-$ 61.3± 6.7 compared with $-$ 57.5 ± 4.2 mV; ANOVA; Bonferroni post hocanalysis; p > 0.05; n = 7). Similarly, after washout of FCCP the[Ca²⁺]_i no longer was elevated significantly (ratio, 1.11 ± 0.23 to1.05 ± 0.19; n = 4; p = 0.3) (Fig. 3A).

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Figure 3. Effect of mitochondrial blockers on the membrane potential and [Ca²⁺]_i of AH/Type-II neurons. A, Typical example of the effect of FCCP on an AH/Type-II neuron. The compound hyperpolarization induced by FCCP is triggered and amplified by action potential firing. The number of action potentials that are elicited is indicated under each stimulus. The top trace represents the [Ca²⁺]_i changes, whereas the membrane potential is shown in the bottom panel of A. The presence of FCCP (1 µM) is indicated with a horizontal bar. The inset shows a membrane potential recording from another neuron in control conditions (black), in the presence of FCCP (dark gray), and during current clamp in the presence of FCCP (light gray). Although clamped to the control potential, the amplitude of the AH remains reduced in FCCP. B, The average amplitude ± SEM of the compound hyperpolarization induced by FCCP, antimycin A, and rotenone in AH/Type-II neurons. C, The average time ± SEM to reach the maximum hyperpolarization. The number of neurons per condition is indicated in the bars.

To check the specificity of FCCP, we used two respiratory chain blockers, antimycin and rotenone, to block mitochondrial function.Similar to the effect of FCCP, antimycin (10 µM) and rotenone(10 µM) induced a compound hyperpolarization that was enhancedby AP firing. Antimycin caused a 6.9 ± 2.2 mV (n = 4) hyperpolarization,reaching its maximal amplitude in 450 ± 30 sec, and rotenone hyperpolarizedthe membrane 9.8 ± 3.8 mV (n = 3) in 255 ± 25 sec (Fig. 3B,C).The hyperpolarization in the presence of the respiratory chainblockers, however, never developed as rapidly as in FCCP. Noneof the three mitochondrial inhibitors had a detectable effecton the shape and duration of theAPs.

AH and Ca²⁺ transient characteristics
We examined the properties of the AH and associated Ca²⁺ transients during mitochondrial blockade; only those neurons were includedwith an AH elicited by the same number of APs in control and drugconditions. The amplitude of both the AH (11.6 ± 1.1 to 10.4 ±1.2 mV; p = 0.01; n = 4) and the accompanying Ca²⁺ transient were reduced (ratio, 0.077 ± 0.016 to 0.053 ± 0.011;p = 0.01; n = 4) in the presence of FCCP. When clamped back tothe predrug resting membrane potential, the AH amplitude remainedsmaller (Fig. 3A, inset). Although the 90% duration of the AHand Ca²⁺ transients was prolonged (n = 3), relevant statistical analysisof the AH duration was not possible because in four of seven neuronsthe AH did not recover and merged continuously into the compoundhyperpolarization induced by FCCP. To quantify the change in recovery,we measured the hyperpolarization 15 sec (the average 90% durationof the AH) after action potential firing. The neurons were hyperpolarizedsignificantly more in the presence of FCCP (2.0 ± 1.4 to 5.3 ±1.8 mV; p = 0.04; n = 7), and the residual Ca²⁺ elevation was increased slightly (ratio, 0.005 ± 0.003 to 0.011± 0.003; p = 0.02; n =4).
Antimycin A did not significantly alter the amplitude of the AH (8.7 ± 2 to 7.9 ± 1.8 mV; p = 0.19; n = 4), but the 90% durationwas prolonged by ~40%. Similarly, the amplitude of the AH wasnot altered by rotenone (7.2 ± 1.6 to 9.7 ± 0.9 mV; p = 0.37;n = 3), and the 90% duration increased, with one neuron that neverrecovered. Similar to the hyperpolarizing effect of the respiratorychain blockers, the effect on the AH was slower and less pronouncedthan that of FCCP. Also, unlike FCCP, a prolonged exposure torotenone and antimycin was required for the drug to become fullyeffective. None of the mitochondrial blockers altered the propertiesof the fastAH.

Input resistance
The AH that follows an action potential in myenteric neurons is caused by K⁺ efflux through Ca²⁺-dependent K⁺ channels (Hirst et al., 1985; Vogalis et al., 2002). Dependingon the neuron type, the Ca²⁺ responsible for opening of these channels originates directlyfrom the extracellular space or indirectly from the intracellularCa²⁺ stores (Berridge, 1998). In myenteric neurons the Ca²⁺-induced Ca²⁺ release from ryanodine-sensitive stores provides the bulk ofCa²⁺ responsible for this afterhyperpolarization (Hillsley et al.,2000). The opening of K⁺ channels leads to a decrease in input resistance (R_in), whichcan be monitored by measuring the amplitude of the voltage deflectionelicited by a constant hyperpolarizing current pulse (Fig. 4A).We set out to monitor the changes in R_in during the AH, whichis regulated by the opening and gradual closure of Ca²⁺-activated K⁺ channels. Single hyperpolarizing pulses were given every secondbefore and during the AH. During the AH the R_in dropped to 70%of the resting R_in, whereas in the presence of FCCP (1 µM) itdropped to almost 50% (Fig. 4B). Similarly, although the effectdeveloped more slowly, the drop in R_in was enhanced by antimycinA and was more pronounced for longer exposure times (69.8, 60.8,55.2, and 45.6% for 42, 115, 217, and 340 sec of exposure, respectively)(Fig. 4C). The input resistance also was measured at the timethe compound hyperpolarization in the presence of FCCP reachedits maximum. Surprisingly, this compound hyperpolarization wasnot accompanied by a decrease in general R_in when measured atthe maximal FCCP effect (113 ± 30 compared with 92 ± 18 M $Omega$ ; n= 6; p = 0.16), suggesting the inhibition of other conductances.

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Figure 4. The effect of FCCP (1 µM) and antimycin (10 µM) on the input resistance changes during the slow afterhyperpolarization in AH/Type-II neurons. A, The input resistance (R_in) is calculated by measuring the voltage deflection (X) for a fixed current step (0.2 nA) and is inversely dependent on the number of open channels in the membrane. B, The R_in (M $Omega$ ) during the first 15 sec of the AH in normal conditions (black) and in the presence of FCCP (gray). The data points are averages ± SEM of two to four trials in three neurons. The arrow at time 0 sec indicates the time of the action potential. C, The R_in (M $Omega$ ) in control (black) and in the presence of antimycin A (gray). Individual traces were measured at different time points (as indicated) after the start of the antimycin application. The arrow at time 0 sec indicates the time of the action potential.

Role of intracellular Ca²⁺ stores

To investigate the contribution of Ca²⁺ release from the intracellular Ca²⁺ stores, we performed some experiments after the depletion ofthe Ca²⁺ stores with thapsigargin (Tg) and during the blockade of ryanodine(Ry) receptors, shown to be crucial for the myenteric AH (Hillsleyet al., 2000; Vogalis et al., 2001). The blockade of the ATP-dependentCa²⁺ pump with Tg did not have major effects on the membrane potential(~5 mV depolarization in 30 min) but abolished the AH. The compoundhyperpolarization caused by FCCP was attenuated greatly by Tg.Indeed, in three Tg-treated neurons FCCP did not cause a significanthyperpolarization ( $-$ 59.6 ± 8.4 to $-$ 65.9 ± 6.8 mV; p = 0.07) evenwhen APs were fired (Fig. 5A). In two neurons a small depolarizationdeveloped after 3 min of FCCP exposure during the next 10 min.

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Figure 5. The involvement of intracellular Ca²⁺ stores in the effect of FCCP on AH/Type-II neurons. Drugs are added as indicated by the horizontal bars; the number of action potentials that are elicited is indicated under each stimulus. A, Effect of FCCP after blockade of the ATP-dependent Ca²⁺ pump with thapsigargin (2 µM). The AH is abolished almost completely after the thapsigargin treatment. Action potentials in the presence of FCCP induce only a small hyperpolarization. B, The effect of FCCP in the presence of ryanodine (10 µM). Ryanodine was applied 200 sec before the addition of FCCP. The FCCP-induced hyperpolarization develops slower than in the absence of ryanodine. C, The average amplitude ± SEM of the hyperpolarization induced by FCCP alone and in the presence of ryanodine. D, The average time ± SEM to reach the maximum hyperpolarization. In the presence of ryanodine the hyperpolarizing effect of FCCP is delayed significantly. The number of neurons per condition is indicated in the bars. Significant differences (p < 0.05) are indicated with an asterisk.

In preliminary experiments the AH neurons were perfused with Ry for at least 200 sec before exposure to FCCP. Here FCCP stillinduced a significant AP-dependent hyperpolarization ( $-$ 54.0 ±3.9 to $-$ 61.7 ± 5.5; n = 3; p = 0.03) (Fig. 5B). The amplitudeof the compound hyperpolarization was not different from thatof FCCP alone (Fig. 5C); however, the presence of Ry significantlydelayed the effect (360 ± 121 compared with 146 ± 31 sec; p =0.03) (Fig. 5D). This may indicate that Ca²⁺ release from Ry receptors is needed to accelerate the hyperpolarizingeffect of FCCP. To test this hypothesis, we exposed neurons toRy for >30 min, shown to reduce the AH to 40% (Hillsley et al.,2000). Similar to the Tg treatment, in Ry-treated neurons (n =3) FCCP no longer evoked a hyperpolarization ( $-$ 61.3 ± 3.9 to $-$ 67.0± 1.8 mV; p = 0.22) even in the presence of APfiring.

Effect of mitochondrial inhibitors on the membrane potential and [Ca²⁺]_i of S/Type-I neurons

S/Type-I neurons are heterogeneous in terms of firing characteristics, including phasic S neurons, having only 1 AP for aprolonged (100-500 msec) depolarization pulse, and tonic S neurons,with multiple spikes. The effect of mitochondrial inhibition wasstudied in 29 S/Type-I neurons (23 phasic and 6 tonic). All S/Type-Ineurons were pooled because no consistent differences in the effectof mitochondrial inhibitors were observed between the two typesof S neurons (Fig. 6A). FCCP (1 µM) significantly hyperpolarizedS/Type-I neurons ( $-$ 57.0 ± 3.9 to $-$ 67.9 ± 5.5 mV; p = 0.02; n =6) in 189 ± 42 sec. However, this hyperpolarization differed fromthat observed in AH neurons in that it developed independentlyof AP firing (Fig. 6A). The respiratory chain blocker rotenonecaused a similar hyperpolarization ( $-$ 54.1 ± 3.6 to $-$ 65.4 ± 2.4mV; p = 0.04; n = 4) (Fig. 6B), but it took longer for the hyperpolarizationto develop fully (271 ± 73 sec) (Fig. 6C). The complex I blockerantimycin hyperpolarized three of eight S/Type-I neurons ( $-$ 43.0± 8.7 to $-$ 65.7 ± 4.6 mV; p = 0.03) in 280 ± 53 sec (Fig. 6B,C)and had no effect on the other S/Type-I neurons ( $-$ 51.8 ± 5.1 to $-$ 51.2 ± 5.9 mV; p = 0.5). Within the limits of detection noneof the mitochondrial inhibitors had an effect on the shape ofthe APs of these neurons.

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Figure 6. Effect of mitochondrial blockers on the membrane potential and [Ca²⁺]_i of S/Type-I neurons. A, Typical example of the effect of FCCP on an S/Type-I neuron. The hyperpolarization develops slowly and is independent of action potential firing. The top trace represents the [Ca²⁺]_i changes, whereas the membrane potential is shown in the bottom panel of A. The presence of FCCP (1 µM) is indicated with a horizontal bar. B, The average amplitude ± SEM of the hyperpolarization induced by FCCP, antimycin A, and rotenone in S/Type-I neurons. C, The average time ± SEM to reach the maximum hyperpolarization. The number of neurons per condition is indicated in the bars.

In 12 S/Type-I neurons the [Ca²⁺]_i was monitored simultaneously during the application of mitochondrial blockers. The link between[Ca²⁺]_i and membrane potential changes was not as clear in S/Type-Ineurons as for AH/Type-II neurons (see also Shuttleworth and Smith,1999; Hillsley et al., 2000). Although some changes in [Ca²⁺]_i were observed in the presence of FCCP, on average the [Ca²⁺]_i levels were not significantly different at the time the hyperpolarizationreached its maximum (0.91 ± 0.11 to 0.95 ± 0.13; n = 5; p = 0.09).Similarly, antimycin and rotenone did not cause a significant[Ca²⁺]_i increase in S/Type-I neurons. The mitochondrial blockers didnot alter significantly the AP-induced Ca²⁺ transients elicited in S/Type-Ineurons.

Effect of F₀F₁ ATPase blockade on the membrane potential and [Ca²⁺]_i in myenteric neurons

During mitochondrial blockade the ATP/ADP balance may change because of the lack of ATP production or ATP consumption by thedepolarized mitochondria. Oligomycin (10 µM) blocks the mitochondrialF₀F₁ ATPase and therefore can be used to assess the contributionof ATP depletion. In five of seven AH neurons oligomycin induceda membrane hyperpolarization ( $-$ 50.5 ± 3.9 to $-$ 57.1 ± 4.3 mV; p= 0.01) that was not influenced by AP firing (Fig. 7A) and notaccompanied by a [Ca²⁺]_i rise. This hyperpolarization was smaller (Fig. 7B) and developedsignificantly slower than the FCCP-induced compound hyperpolarization(800 ± 183 compared with 146 ± 31 sec; p = 0.005; n = 5) (Fig.7C). In two other AH neurons a small depolarization (~5 mV) wasobserved. Oligomycin did not alter the amplitude and durationof the AH (n = 5). Oligomycin had no detectable effect on theAP of AH/Type-II neurons. In four AH neurons that were hyperpolarizedwith FCCP, we added the K_ATP blocker glibenclamide (1 µM) at least6 min after the addition of FCCP. The hyperpolarized neurons partiallyrecovered (from $-$ 76.6 ± 6.4 to $-$ 67.9 ± 5.2 mV; ANOVA; p < 0.01in FCCP; control, $-$ 66.6 ± 6.3 before FCCP), indicating the involvementof a K_ATP conductance. Blockade of the F₀F₁ ATPase in S/Type-Ineurons had variable effects; four of seven neurons hyperpolarizedslowly ( $-$ 48.9 ± 3.7 to $-$ 58.8 ± 3.8 mV in 420 ± 100 sec), whereasin three others a depolarization (~7 mV) was observed. Oligomycindid not induce a rise in [Ca²⁺]_i in S/Type-I neurons (n = 3).

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Figure 7. The effect of the mitochondrial F₀F₁ ATPase blocker oligomycin (10 µM) and FCCP on the membrane potential of AH/Type-II neurons. Oligomycin is added as indicated by the horizontal bar; the number of action potentials that are elicited is indicated under each stimulus. A, Oligomycin hyperpolarizes the membrane potential of AH/Type-II neurons. The hyperpolarization develops slowly and is not triggered by action potential firing. B, The average amplitude ± SEM of the hyperpolarization. C, Average time ± SEM to reach the maximum hyperpolarization induced by oligomycin compared with the effect of FCCP. The number of neurons per condition is indicated in the bars. Significant differences (p < 0.05) are indicated with an asterisk.

MitoTracker, ER tracker, and immunohistochemical stainings

Longitudinal muscle myenteric plexus preparations were stained with ER tracker and MitoTracker (Fogarty et al., 2000; Buckmanet al., 2001) to visualize the ER and the mitochondria in themyenteric neurons of the guinea pig ileum. Because the myentericplexus consists of a monolayer of neurons, we used conventionalfluorescence microscopy. Out-of-focus light, emerging from thecontinuous underlying muscle layer, equally contributed to thewhole field and therefore did not affect the assessment of organelletracker dyes in different myenteric neurons. Although ER trackerimages showed an overall staining of the preparation, the myentericneurons stained brighter than the underlying muscle layer (Fig.8A). Unlike the ER tracker staining, the intensity of MitoTrackerstaining (Fig. 8B) was higher in a certain subset of neurons (Fig.8B, arrows) in the myenteric plexus. To identify this subset ofneurons, we used an antibody against calbindin, a calcium-bindingprotein that is a marker for AH/Type-II neurons in various tissues(Iyer et al., 1988; Song et al., 1991; Furness et al., 1998).Confocal microscopy was used to examine preparations that weredouble labeled with MitoTracker (Fig. 8C) and the calbindin antibody(Fig. 8D). This revealed a colocalization between calbindin-likeimmunoreactivity and intense MitoTracker staining (Fig. 8E). InFigure 8F the MitoTracker intensity is plotted as a histogramfor both calbindin-positive and calbindin-negative neurons, clearlyindicating that calbindin-positive neurons have a more intenseMitoTracker staining (Fig. 8F).

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Figure 8. Endoplasmic reticulum (ER) tracker, MitoTracker, and calbindin-like immunostaining in whole-mount myenteric plexus preparations; scale bar, 20 µm. A, ER-Tracker Blue DPX was used to visualize the ER in the myenteric plexus. Note that ER-Tracker Blue DPX shows an overall staining of the ganglion and the underlying layers. B, MitoTracker Green was used to stain mitochondria in the same ganglion. The MitoTracker staining shows a different pattern, in that some neurons in the ganglion are brighter (arrows) than others (arrowheads). C-E, Confocal images of a MitoTracker (C) calbindin (D) double staining. The preparations were stained with MitoTracker Green and processed afterward with a primary antibody against calbindin and a secondary antibody coupled to Texas Red. E, The calbindin-like immunoreactive neurons (e.g., arrows) were stained intensely with MitoTracker, as clearly seen in the overlay of C and D. F, Distribution histogram of the MitoTracker intensity for calbindin-like immunoreactive neurons (red) and calbindin-negative neurons (gray). The MitoTracker signal is clearly higher in calbindin-like immunoreactive neurons.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study we combined intracellular recordings and Ca²⁺ imaging to assess the effect of mitochondrial blockers on restingmembrane potential and excitability of myenteric neurons of theguinea pig ileum. Mitochondria are important organelles not onlybecause they are the major source of energy but also because theyplay a crucial role in Ca²⁺ homeostasis. Here we showed that the resting membrane potentialand therefore the excitability of myenteric neurons, in particularAH/Type-II neurons, are regulated in part by Ca²⁺ uptake viamitochondria.

The AH/Type-II neurons displayed a double-phased afterhyperpolarization after AP firing. The slow phase was mirrored by atransient increase and exponential decay in [Ca²⁺]_i, closely linked to the afterhyperpolarization in amplitudeand duration (Tatsumi et al., 1988; Hillsley et al., 2000; Vogaliset al., 2000). Hirst et al. (1985) suggested that the delay observedat the onset of the slow AH was attributable to a Ca²⁺ priming period of the K⁺ channels that were involved, whereas Vogalis et al. (2001) attributedthe delay to a transient inward current, unmasked by TEA and blockedby niflumicacid.

The blockade of mitochondria hyperpolarized both S/Type-I and AH/Type-II myenteric neurons. In AH/Type-II neurons the restingmembrane potential was not altered significantly by FCCP untilaction potentials were elicited. Then the action potentials andthe AH were followed by a compound hyperpolarization that lastedfor several minutes. Simultaneous [Ca²⁺]_i recordings showed that the compound hyperpolarization in AHneurons was accompanied by a rise in [Ca²⁺]_i, suggesting that mitochondria sequester an important amountof Ca²⁺ during normal neuronal function. However, unlike the observationsin rat hippocampal neurons (Nowicky and Duchen, 1998), the risein [Ca²⁺]_i did not develop in the absence of activation. In line withother reports (Greenwood et al., 1997; Pivovarova et al., 1999)the FCCP effect was reversible, and both membrane potential and[Ca²⁺]_i recovered during washout. In contrast to AH/Type-II neurons,the FCCP induced hyperpolarization in S/Type-I neurons developedsteadily and independently of AP firing. To test whether the effectof FCCP was specific, we also used other mitochondrial blockers,rotenone and antimycin A, blocking complex I and III, respectively,of the respiratory chain. Hyperpolarizations of similar amplitudewere observed in both S/Type-I and AH/Type-II neurons. In AH/Type-IIneurons AP firing enhanced the effect, similar to that ofFCCP.

The effect of mitochondrial blockers on AH and [Ca²⁺]_i transient characteristics was studied in those neurons without an immediatecompound hyperpolarization. FCCP reduced the AH and the accompanyingCa²⁺ transient. Several studies report increased [Ca²⁺]_i responses to activation during mitochondrial blockade in differentneuronal preparations (Khodorov et al., 1999; Pivovarova et al.,1999; Friel, 2000; Wang and Thayer, 2002). However, in culturedmyenteric neurons mitochondrial blockade did not affect the amplitudeof K⁺-induced Ca²⁺ transients but slowed the [Ca²⁺]_i decay (Vanden Berghe et al., 2002). In the present study, aswell, mitochondrial blockade by FCCP significantly prolonged theduration of the Ca²⁺ transient. All of the effects on the Ca²⁺ transients invariably were reflected in effects on the AH. Inthe presence of FCCP the AH was smaller, but the time to reachthe maximum and the total duration were increased. These findingsindicate that hampered Ca²⁺ removal prolongs the [Ca²⁺]_i elevation and therefore delays the closure of Ca²⁺-activated channels. Similar observations for Ca²⁺-activated currents were made in smooth muscle cells (Greenwoodet al., 1997), chick DRG neurons (Kenyon and Goff, 1998), andrat hippocampal neurons (Nowicky and Duchen, 1998). More evidencefor this prolonged opening of Ca²⁺-activated K⁺ channels was found in the R_in measurements. Mitochondrial blockersamplified the drop in R_in during the AH. However, by the timethe compound hyperpolarization reached its maximum, the R_in hadrecovered to control levels. Therefore, the compound hyperpolarizationcannot be attributed simply to an increase in K⁺ conductance, unless another conductance is switched off accordingly.A possible candidate is I_h (Galligan et al., 1990; Rugiero etal., 2002), a cation current activated during hyperpolarization,which is reduced by metabolic inhibition and increases in [Ca²⁺]_i (Duchen, 1990).

Because mitochondria act both as a source and sink, the net effect on Ca²⁺ uptake is probably highly dependent on the kinetics of the blockadeand the state of the mitochondria (Gunter et al., 2000). Thisalso might explain why the AH and Ca²⁺ transient amplitude are affected differently by FCCP and rotenone.Also, the fact that the hyperpolarizing effect and the reductionin R_in by FCCP developed faster and more suddenly than for antimycinand rotenone was probably attributable to the mechanism of theaction of the drugs. The latter two block the respiratory cycleand therefore inhibit mitochondrial function more slowly thanthe sudden collapse of mitochondrial potential induced byFCCP.

The importance of AH/Type-II neuronal intracellular Ca²⁺ stores was assessed with ryanodine and thapsigargin, an irreversibleblocker of the ATP-dependent Ca²⁺ pump. Depletion of the ER with thapsigargin prevented the AP-inducedcompound hyperpolarization in the presence of FCCP. Similarly,prolonged exposure to Ry, shown to reduce the AH significantly(Hillsley et al., 2000), eliminated the compound hyperpolarization.Even short treatment with Ry already delayed the FCCP hyperpolarizationwithout affecting the amplitude. The Ca²⁺ release from ryanodine-sensitive Ca²⁺ stores seems to be prerequisite for FCCP to exert its effect,proving that mitochondria normally buffer substantial amountsof the Ca²⁺ release from the ER in myenteric AH/Type-IIneurons.

Although the maximal hyperpolarization induced by mitochondrial blockade was similar in S/Type-I neurons and AH/Type-II, inthe former the hyperpolarization was independent of AP firing.This suggested that another mechanism is responsible for the hyperpolarizationin S/Type-I neurons and maybe also in unstimulated AH neurons.To assess the contribution of the putative changes in cytosolicATP/ADP ratio attributable to the mitochondrial blockade, we blockedthe F₀F₁ ATPase with oligomycin. Oligomycin itself hyperpolarizedthe majority of AH neurons and had variable effects on S neurons.The hyperpolarization developed independently of AP firing ratherthan in FCCP. Also, the [Ca²⁺]_i did not rise during oligomycin, which led to the idea thata Ca²⁺-independent mechanism, probably based on the activation of ATP-sensitiveK⁺ channels, was involved (Otero and Carrasco, 1984; Roper and Ashcroft,1995; Hyllienmark and Brismar, 1996). Glibenclamide, a blockerof K_ATP, partially restored the membrane potential in myentericneurons that were hyperpolarized in FCCP. Liu et al. (1999) alsopresented evidence for such a K_ATP current in myenteric neuronsby showing that glucose deprivation induced a tolbutamide-sensitivehyperpolarization. They also showed that the subunits of the K_ATPchannel (Kir_1.6 and sulfonylurea receptor) were present in bothcalbindin-positive and other myenteric neurons. It is not clearwhat determines the different responses to oligomycin. Especiallyfor S/Type-I neurons, different subtypes (phasic/tonic) and underlyingdifferences in energy requirement may cause the variable effects.In AH neurons a shortage of ATP also may, besides activating K_ATP,slow down the ATP-dependent Ca²⁺ uptake by the ER (Landolfi et al., 1998).

In this study we also used fluorescent tracker molecules to trace mitochondria and ER in the myenteric plexus. The ER trackerstained the whole tissue, with a more extensive staining of themyenteric plexus. MitoTracker showed a more patterned staining,in which some neurons were brighter than others. In a double-labelingexperiment the neurons with intensive MitoTracker staining wereidentified as calbindin-positive AH/Type-II neurons. This suggestedthat AH/Type-II neurons had a higher number or a denser mitochondrialnetwork. Electron microscopy data showing that calbindin-positiveneurons, unlike the calbindin-negative neurons, had numerous electron-densemitochondria (Pompolo and Furness, 1988) corroborate our findings.These data tie in well with the physiological observations thatin AH/Type-II neurons the effect of mitochondrial blockers ismore pronounced than in S/Type-Ineurons.

In conclusion, the blockade of mitochondria triggers a series of events in AH/Type-II neurons involving several currents (Fig.9). First, the Ca²⁺ released from ER is not buffered efficiently by the impairedmitochondria, slowing the deactivation of Ca²⁺-dependent K⁺ conductances and leading to a prolongation of the AH. Second,the glibenclamide data imply that ATP-sensitive K⁺ channels also are activated in the course of the compound hyperpolarization.This mechanism is likely to explain the oligomycin-induced hyperpolarizationthat develops without a [Ca²⁺]_i rise. Further, the recovery of R_in at the peak of the compoundhyperpolarization implies the inhibition of a nonselective cationcurrent. The contribution of these different conductances probablyvaries throughout the course of the compound hyperpolarization.In an early stage, action potential firing and consecutive ERCa²⁺ release trigger the Ca²⁺-dependent component of the compound hyperpolarization. However,the ATP-dependent component also might be set off because, inan attempt to remove the excess Ca²⁺ ions, activated neurons might consume the remaining ATP morerapidly. Although mitochondrial blockade hyperpolarizes both typesof myenteric neurons, the effects on S/Type-I neurons are lesspronounced and not triggered by activation. It has to be notedthat the S/Type-I neurons are a mixed population, comprising descendingand ascending interneurons and inhibitory and excitatory motorneurons. Although the link between their function and the electricalproperties is not established clearly, it is likely that functionaldifferences are reflected in their electrical and Ca²⁺ handling properties. Mitochondria are highly sensitive to oxidativestress and therefore may be important in the pathological responsesduring inflammation. Reactive oxygen species induced fluctuationsin the membrane potential of colonic AH myenteric neurons (Wada-Takahashiand Tamura, 2000). In view of the results in this study, it islikely that mitochondrial dysfunction and therefore disabled Ca²⁺ sequestration underlie the initial hyperpolarizations.

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Figure 9. Schematic representation of the Ca²⁺ handling in myenteric neurons. Action potential firing causes Ca²⁺ entry through voltage-activated Ca²⁺ channels. The increase in [Ca²⁺]_i is amplified by the release of Ca²⁺ from the ER via activation of ryanodine receptors (Hillsley et al., 2000). Functional mitochondria sequester Ca²⁺ and thereby lower the [Ca²⁺]_i. A blockade of the mitochondria results in a prolonged elevation of the [Ca²⁺]_i, which in turn causes a prolonged activation of the Ca²⁺-dependent conductances. On the other hand, ATP depletion, occurring during mitochondrial blockade or the inhibition of the F₀F₁ ATPase by oligomycin, may activate K_ATP channels, thus leading to a Ca²⁺-independent hyperpolarization.

  FOOTNOTES

Received Feb. 25, 2002; revised May 17, 2002; accepted May 24, 2002.

This work was supported by National Institute of Diabetes and Digestive and Kidney Diseases Grant PO1 DK-41315. P.V.B. isa postdoctoral Fellow of the Fund for Scientific Research (FWO,Flanders,Belgium).

Correspondence should be addressed to Dr. T. K. Smith, Department of Physiology and Cell Biology/352, University of Nevada,School of Medicine, Reno, NV 89557-0046. E-mail: tks{at}physio.unr.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Babcock DF, Hille B (1998) Mitochondrial oversight of cellular Ca²⁺ signaling. Curr Opin Neurobiol 8:398-404[ISI][Medline].
Berridge MJ (1998) Neuronal calcium signaling. Neuron 21:13-26[ISI][Medline].
Buckman JF, Hernandez H, Kress GJ, Votyakova TV, Pal S, Reynolds IJ (2001) MitoTracker labeling in primary neuronal and astrocytic cultures: influence of mitochondrial membrane potential and oxidants. J Neurosci Methods 104:165-176[ISI][Medline].
Colegrove SL, Albrecht MA, Friel DD (2000) Quantitative analysis of mitochondrial Ca²⁺ uptake and release pathways in sympathetic neurons. Reconstruction of the recovery after depolarization-evoked [Ca²⁺]_i elevations. J Gen Physiol 115:371-388[Abstract/Free Full Text].
Duchen MR (1990) Effects of metabolic inhibition on the membrane properties of isolated mouse primary sensory neurones. J Physiol (Lond) 424:387-409[Abstract/Free Full Text].
Duchen MR (2000) Mitochondria and Ca²⁺ in cell physiology and pathophysiology. Cell Calcium 28:339-348[ISI][Medline].
Fogarty KE, Kidd JF, Turner A, Skepper JN, Carmichael J, Thorn P (2000) Microtubules regulate local Ca²⁺ spiking in secretory epithelial cells. J Biol Chem 275:22487-22494[Abstract/Free Full Text].
Friel DD (2000) Mitochondria as regulators of stimulus-evoked calcium signals in neurons. Cell Calcium 28:307-316[ISI][Medline].
Friel DD, Tsien RW (1994) An FCCP-sensitive Ca²⁺ store in bullfrog sympathetic neurons and its participation in stimulus-evoked changes in [Ca²⁺]_i. J Neurosci 14:4007-4024[Abstract].
Furness JB, Kunze WA, Bertrand PP, Clerc N, Bornstein JC (1998) Intrinsic primary afferent neurons of the intestine. Prog Neurobiol 54:1-18[ISI][Medline].
Galligan JJ, Tatsumi H, Shen KZ, Surprenant A, North RA (1990) Cation current activated by hyperpolarization (I_H) in guinea pig enteric neurons. Am J Physiol 259:966-972.
Greenwood IA, Helliwell RM, Large WA (1997) Modulation of Ca²⁺ activated Cl currents in rabbit portal vein smooth muscle by an inhibitor of mitochondrial Ca²⁺ uptake. J Physiol (Lond) 505[Pt 1]:53-64[ISI][Medline].
Gunter TE, Buntinas L, Sparagna G, Eliseev R, Gunter K (2000) Mitochondrial calcium transport: mechanisms and functions. Cell Calcium 28:285-296[ISI][Medline].
Hillsley K, Kenyon JL, Smith TK (2000) Ryanodine-sensitive stores regulate the excitability of AH neurons in the myenteric plexus of guinea pig ileum. J Neurophysiol 84:2777-2785[Abstract/Free Full Text].
Hirst GD, Holman ME, Spence I (1974) Two types of neurones in the myenteric plexus of the duodenum in the guinea pig. J Physiol (Lond) 361:297-314[Abstract/Free Full Text].
Hirst GD, Johnson SM, van Helden DF (1985) The slow calcium-dependent potassium current in a myenteric neurone of the guinea pig ileum. J Physiol (Lond) 361:315-337[Abstract/Free Full Text].
Hyllienmark L, Brismar T (1996) Effect of metabolic inhibition on K⁺ channels in pyramidal cells of the hippocampal CA1 region in rat brain slices. J Physiol (Lond) 496[Pt 1]:155-164[ISI].
Iyer V, Bornstein JC, Costa M, Furness JB, Takahashi Y, Iwanaga T (1988) Electrophysiology of guinea pig myenteric neurons correlated with immunoreactivity for calcium binding proteins. J Auton Nerv Syst 22:141-150[ISI][Medline].
Kawai T, Watanabe M (1989) Effects of ryanodine on the spike afterhyperpolarization in sympathetic neurones of the rat superior cervical ganglion. Pflügers Arch 413:470-475[ISI][Medline].
Kenyon JL, Goff HR (1998) Temperature dependencies of Ca²⁺ current, Ca²⁺-activated Cl current, and Ca²⁺ transients in sensory neurones. Cell Calcium 24:35-48[ISI][Medline].
Khodorov B, Pinelis V, Storozhevykh T, Yuravichus A, Khaspekhov L (1999) Blockade of mitochondrial Ca²⁺ uptake by mitochondrial inhibitors amplifies the glutamate-induced calcium response in cultured cerebellar granule cells. FEBS Lett 458:162-166[ISI][Medline].
Landolfi B, Curci S, Debellis L, Pozzan T, Hofer AM (1998) Ca²⁺ homeostasis in the agonist-sensitive internal store: functional interactions between mitochondria and the ER measured in situ in intact cells. J Cell Biol 142:1235-1243[Abstract/Free Full Text].
Liu M, Seino S, Kirchgessner AL (1999) Identification and characterization of glucoresponsive neurons in the enteric nervous system. J Neurosci 19:10305-10317[Abstract/Free Full Text].
Moore KA, Cohen AS, Kao JP, Weinreich D (1998) Ca²⁺-induced Ca²⁺ release mediates a slow post-spike hyperpolarization in rabbit vagal afferent neurons. J Neurophysiol 79:688-694[Abstract/Free Full Text].
Morita K, North RA, Tokimasa T (1982) The calcium-activated potassium conductance in guinea pig myenteric neurones. J Physiol (Lond) 329:341-354[Abstract/Free Full Text].
Nishi S, North RA (1973) Intracellular recording from the myenteric plexus of the guinea pig ileum. J Physiol (Lond) 231:471-491[Abstract/Free Full Text].
Nowicky AV, Duchen MR (1998) Changes in [Ca²⁺]_i and membrane currents during impaired mitochondrial metabolism in dissociated rat hippocampal neurons. J Physiol (Lond) 507[Pt 1]:131-145[Abstract/Free Full Text].
Otero MJ, Carrasco L (1984) Action of oligomycin on cultured mammalian cells. Permeabilization to translation inhibitors. Mol Cell Biochem 61:183-191[Medline].
Pivovarova NB, Hongpaisan J, Andrews SB, Friel DD (1999) Depolarization-induced mitochondrial Ca accumulation in sympathetic neurons: spatial and temporal characteristics. J Neurosci 19:6372-6384[Abstract/Free Full Text].
Pompolo S, Furness JB (1988) Ultrastructure and synaptic relationships of calbindin-reactive, Dogiel type II neurons, in myenteric ganglia of guinea pig small intestine. J Neurocytol 17:771-782[ISI][Medline].
Rizzuto R, Bernardi P, Pozzan T (2000) Mitochondria as all-round players of the calcium game. J Physiol (Lond) 529[Pt 1]:37-47[Abstract/Free Full Text].
Roper J, Ashcroft FM (1995) Metabolic inhibition and low internal ATP activate K-ATP channels in rat dopaminergic substantia nigra neurones. Pflügers Arch 430:44-54[Medline].
Rugiero F, Gola M, Kunze WA, Reynaud JC, Furness JB, Clerc N (2002) Analysis of whole-cell currents by patch clamp of guinea pig myenteric neurones in intact ganglia. J Physiol (Lond) 538:447-463[Abstract/Free Full Text].
Sah P, McLachlan EM (1991) Ca²⁺-activated K⁺ currents underlying the afterhyperpolarization in guinea pig vagal neurons: a role for Ca²⁺-activated Ca²⁺ release. Neuron 7:257-264[ISI][Medline].
Shah M, Haylett DG (2000) Ca²⁺ channels involved in the generation of the slow afterhyperpolarization in cultured rat hippocampal pyramidal neurons. J Neurophysiol 83:2554-2561[Abstract/Free Full Text].
Shuttleworth CW, Smith TK (1999) Action potential-dependent calcium transients in myenteric S neurons of the guinea pig ileum. Neuroscience 92:751-762[ISI][Medline].
Smith TK, Bornstein JC, Furness JB (1992) Convergence of reflex pathways excited by distension and mechanical stimulation of the mucosa onto the same myenteric neurons of the guinea pig small intestine. J Neurosci 12:1502-1510[Abstract].
Smith TK, Burke EP, Shuttleworth CW (1999) Topographical and electrophysiological characteristics of highly excitable S neurones in the myenteric plexus of the guinea pig ileum. J Physiol (Lond) 517:817-830[Abstract/Free Full Text].
Song ZM, Brookes SJ, Costa M (1991) Identification of myenteric neurons which project to the mucosa of the guinea pig small intestine. Neurosci Lett 129:294-298[ISI][Medline].
Tatsumi H, Hirai K, Katayama Y (1988) Measurement of the intracellular calcium concentration in guinea pig myenteric neurons by using fura-2. Brain Res 451:371-375[ISI][Medline].
Thayer SA, Miller RJ (1990) Regulation of the intracellular free calcium concentration in single rat dorsal root ganglion neurones in vitro. J Physiol (Lond) 425:85-115[Abstract/Free Full Text].
Vanden Berghe P, Smith TK (2001) Mitochondrial Ca²⁺ uptake regulates after-hyperpolarizations in guinea-pig myenteric neurons. Gastroenterology 120:A200.
Vanden Berghe P, Missiaen L, Janssens J, Tack J (2002) Calcium signaling and removal mechanisms in cultured myenteric neurons. Neurogastroenterol Motil 14:63-73[ISI][Medline].
Vogalis F, Hillsley K, Smith T (2000) Recording ionic events from cultured, DiI-labeled myenteric neurons in the guinea pig proximal colon. J Neurosci Methods 96:25-34[ISI][Medline].
Vogalis F, Furness JB, Kunze WA (2001) Afterhyperpolarization current in myenteric neurons of the guinea pig duodenum. J Neurophysiol 85:1941-1951[Abstract/Free Full Text].
Vogalis F, Harvey JR, Furness JB (2002) TEA- and apamin-resistant K_Ca channels in guinea pig myenteric neurons: slow AHP channels. J Physiol (Lond) 538:421-433[Abstract/Free Full Text].
Wada-Takahashi S, Tamura K (2000) Actions of reactive oxygen species on AH/Type 2 myenteric neurons in guinea pig distal colon. Am J Physiol Gastrointest Liver Physiol 279:G893-G902[Abstract/Free Full Text].
Wang GJ, Thayer SA (2002) NMDA-induced calcium loads recycle across the mitochondrial inner membrane of hippocampal neurons in culture. J Neurophysiol 87:740-749[Abstract/