In Vitro Ischemia Promotes Glutamate-Mediated Free Radical Generation and Intracellular Calcium Accumulation in Hippocampal Pyramidal Neurons

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Volume 17, Number 23, Issue of December 1, 1997

In Vitro Ischemia Promotes Glutamate-Mediated Free Radical Generation and Intracellular Calcium Accumulation in Hippocampal Pyramidal Neurons

Jose L. Perez Velazquez, Marina V. Frantseva, and Peter L. Carlen
Playfair Neuroscience Unit, Toronto Hospital Research Institute, Toronto, Ontario M5T 2S8, Canada

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Ischemia-induced cell damage studies have revealed a complex mechanism that is thought to involve glutamate excitotoxicity,intracellular calcium increase, and free radical production. Weprovide direct evidence that free radical generation occurs inrat CA1 pyramidal neurons of organotypic slices subjected to ahypoxic-hypoglycemic insult. The production of free radicals istemporally correlated with intracellular calcium elevation, asmeasured by injection of fluo-3 in individual pyramidal cells,using patch electrodes. Free radical production (measured as changesin the fluorescence emission of dihydrorhodamine 123) peaked duringreoxygenation and paralleled rising intracellular calcium. Electrophysiologicalwhole-cell recordings revealed membrane potential depolarizationand decreased input resistance during the ischemic insult. Glutamatereceptor blockade resulted in decreased free radical productionand markedly diminished intracellular calcium accumulation, andprevented neuronal depolarization and input resistance decreaseduring the ischemic episode. These results provide evidence fora direct involvement of glutamate in oxidative damage resultingfrom ischemic episodes.
Key words: organotypic slices; free radicals; calcium; ischemia; glutamate transmission; whole-cell recordings

INTRODUCTION

Numerous experimental observations have led to the hypothesis that ischemia-induced neuronal damage results from a chain ofpathological events that involve glutamate excitotoxicity, increasein intracellular calcium ([Ca²⁺]_i), and oxidative strees (free radical formation) during reoxygenation(Cao et al., 1988; Choi, 1990; Floyd, 1990; Pellegrini-Giampietroet al., 1990; Martin et al., 1994; Hall et al., 1995; Duffy andMacVicar 1996). The pathological chain of events is thought tostart with mostly NMDA receptor-mediated calcium influx that triggersvarious mechanisms, such as activation of proteases, phospholipases,and free radical formation (Young, 1992; Lipton and Rosenberg1994). However, glutamate-induced increase in [Ca²⁺]_i was found to be nontoxic in conditions preventing free radicalgeneration (Dubinsky et al., 1995,; Patel et al., 1996), suggestingan essential role for free radicals in calcium-mediated neuronaldeath. In turn, free radicals promote further calcium accumulation,mitochondrial calcium uptake and release, and membrane damagein a pathological feedback cycle (Richter, 1993; Richter et al.,1996). Several experiments indicate that these events might converge,causing irreversible mitochondrial free radical-induced dysfunctionleading to cell death (Crompton et al., 1987; Zhang and Piantadosi,1992; Takeyama et al., 1993; Ankarcrona et al., 1995; Bindokasand Miller, 1995; Dugan et al., 1995; Nieminen et al., 1995; Schinderet al., 1996; White and Reynolds 1996).

Despite great interest, direct evidence of free radical production in neurons during ischemia and its relation to glutamatergictransmission has never been presented because of the lack of adequatetechniques for assessing this phenomenon in vivo. The methodsused to detect free radical production have been indirect, measuringmostly protein and lipid peroxidation, enzymatic activities, andratio of reduced to oxidized glutathione in brain superfusatesor homogenized membrane preparations (Watson et al., 1984; Oliveret al., 1990; Zhang and Piantadosi, 1992; Hall et al 1995; Hyslopet al., 1995).

A complete understanding of the relation between oxidative stress, glutamate neurotransmission, and intracellular calciumlevels requires the use of an in vitro model that resembles andhas characteristics similar to the neuronal circuitry found invivo. An ideal system to probe the collective action of neuronalnetworks is the organotypic slice culture. These cultures offerseveral advantages over dissociated cultures in that they keepthe three-dimensional organization of the neuronal circuitry andfunctional characteristics similar to those found in vivo (Zimmerand Gahwiler, 1984; Stoppini et al., 1991). Also, organotypicbrain slices can be loaded with fluorescence indicators much moreeasily than acutely prepared slices.

Using hippocampal organotypic slices cultures, we sought to investigate (1) whether free radicals are generated in the hippocampalCA1 area during and after hypoxia-hypoglycemia, (2) whether thereis a change in [Ca²⁺]_i levels correlating with free radical production and with ischemia-associatedelectrophysiological characteristics of pyramidal neurons; and(3) the role of glutamate transmission during the anoxic insultin free radical production and intracellular calcium levels. Weused changes in dihydrorhodamine 123 (DHR123) fluorescence toassess free radical production caused by hypoxia-hypoglycemiain organotypic hippocampal slices. Alterations in [Ca²⁺]_i were evaluated by changes in fluorescence emission of the calciumindicator fluo-3 injected into individual pyramidal neurons usingthe patch-clamp method, which also allowed us to correlate biophysicalmembrane parameters (membrane potential and input resistance)with free radical production and calcium levels during and afterthe ischemic insult.

MATERIALS AND METHODS
Preparation of organotypic slice cultures and solutions. Techniques for culturing embryonic brain slices were a modificationof those used by Stoppini et al. (1991). The brains of 7-d-oldWistar rats were aseptically removed and immersed in ice-colddissecting medium [50% Minimal Essential Media (MEM) with no bicarbonate,50% calcium and magnesium-free HBSS, 7.5 mM D-glucose, 20 mM HEPES,pH 7.15]. Hippocampi were dissected and then sectioned coronallyat 400 µm thickness with a mechanical tissue chopper. The sliceswere separated and transferred to sterile, porous (0.4 µm) membraneunits (Millicell-CM, Millipore). The units were placed into 6-welltrays with 1 ml of culturing medium in each dish (50% MEM withEarle's salts and L-glutamine, 25% HBSS, 25% horse serum with6.5 mg/l D-glucose, 20 mM HEPES, and 50 U/ml streptomycin-penicillin,pH 7.2). Cultures were kept at 36-37°C in 5% CO₂ and fed threetimes a week by 50% medium exchange. The experiments were carriedout after 7-9 d in vitro.

For data acquisition, slices were transferred to a superfusion chamber maintained at 37°C (Model PDMI-2, Medical Systems Corp.).The superfusion solution [artificial cerebrospinal fluid (ACSF)]contained (in mM): NaCl 125, KCl 2.5, NaH₂PO₄ 1.25, MgSO₄ 2, CaCl₂2, NaHCO₃ 25, glucose 10, pH 7.4, when aerated with 95% O₂/5%CO₂. Osmolarity was 300 ± 5 mOsm. Hypoxia-hypoglycemia was initiatedby superfusing slices (flow rate 4-5 ml/min) with glucose-freeACSF aerated with 95% N₂/5% CO₂ (deoxygenated); sucrose (10 mM)was added to the solution to maintain osmolarity. Glucose-freedeoxygenated ACSF was applied for 8 min. We monitored the timecourse of oxygen level in the perfusion chamber using an oxygenprobe (ISO2 Oxygen Meter, World Precision Instruments). Hypoxicconditions were achieved 1.5-2.0 min after the onset of perfusionwith deoxygenated and glucose-free ACSF. It took a similar timeto return to normoxic conditions superfusing with normal ACSF.When needed, the NMDA receptor blocker D-2 amino-5-phosphonopentanoicacid (D-AP-5) and the non-NMDA glutamate receptor blocker 6-cyano-7-nitroquinoxaline-2,3-dione(CNQX) (Tocris Cookson) were added to the ACSF at the concentrationsindicated in the text. For whole-cell recordings, the internalsolution in the patch recording electrode contained (in mM): potassiumgluconate 150, HEPES, 10, Mg-ATP 2, KCl 5, pH 7.2, adjusted withKOH, osmolarity 265 ± 5 mOsm.

Electrophysiological recordings and fluorescence measurements. Neuronal recordings were performed using the current-clampwhole-cell configuration of the patch-clamp technique (Hamillet al., 1981). Patch pipettes were pulled from borosilicate capillarytubing (World Precision Instruments). Electrodes had tip resistancesranging from 4 to 6 M $Omega$ when filled with internal solution. Theresistance to ground of the whole-cell seal was 2-8 G $Omega$ beforebreakthrough. Only neurons with resting potential more hyperpolarizedthan $-$ 50 mV and able to fire action potentials were used for allthe experiments described. Neuronal responses were recorded usingan Axoclamp 2A amplifier. Signals were filtered at 1 kHz, digitizedat 88 kHz, and stored on video tape using a digital data recorderVR-10 (Instrutech Corp.) for later playback and analysis. PCLAMPsoftware (Axon Instruments) was used for analysis of membranepotential and input resistances; these were measured from thelinear part of the current-voltage plot.

Intracellular calcium levels were measured using the calcium indicator fluo-3 (see below for loading details). Changes influorescence emission were monitored by a digital CCD camera (SenSys,Photometrics), and images were stored and analyzed using the AxonImaging Workbench (Axon Instruments). A fluorescein filter (450/490nm) was used to visualize fluo-3 emission. Fluorescence measurementswere not calibrated for absolute changes in calcium because fluo-3is a nonratiometric indicator. Free radical generation was followedby the conversion of nonfluorescent DHR123 to fluorescent rhodamine123(RH123) (Henderson and Chappell, 1993) using a rhodamine filter(510-560/590 nm). Images were collected and analyzed as describedabove. All images were taken through a 40× water immersion objective(Olympus, numerical aperture 0.7), with a relatively long workingdistance that allowed us to maneuver patching electrodes in thevisual field. Neutral density filters were used to reduce photobleaching.Electrodes filled with ACSF were used to clear the surface ofthe slices in the visual field, by gentle blowing. Infrared imageswere acquired by our CCD camera by placing an infrared filterin the light path. Micrographs were printed on a Kodak SV6500video printer.

For statistical tests of significance, the Student's t test was used unless specified otherwise. Values throughout the paperare mean ± SD.

Loading of slices with fluorescent dyes and injection of fluo-3. Stock solution of DHR123 (Molecular Probes) was preparedin dimethylsulfoxide (DMSO) under nitrogen at 15 mM concentration,aliquoted, and stored at $-$ 80°C. The slices were loaded with 15µM DHR123 for 30 min at 37°C; 50 µl of DHR-containing medium wasadded on the surface of the membranes and allowed to drip through,so that uniform staining of the slice might be achieved. Cultureswere then rinsed in ACSF for 10-15 min in the recording chamber.Only slices that had a stable background fluorescence were usedfor the experiments, which occurred in approximately 30% of theloadings. Although most of the cultured slices were loaded (atthe end of the experiments we bathed slices in ACSF containinghydrogen peroxide to test for proper loading), we were not succesfulin loading acutely prepared slices from 10- to 15-d-old animals(n = 11). For RH123 experiments, cultured slices were loaded withRH123 (10 µM) (Molecular Probes) for 4 h as detailed above, andrinsed for at least 30 min. When needed, the vital dye SYTOX (MolecularProbes) at 2.5 µM concentration was added to the perfusing ACSFand applied at the end of the experiments for 15-20 min at a rateof 4-5 ml/min.

For intracellular calcium measurements, individual neurons were patched under infrared illumination and dialyzed with an internalsolution containing 10 µM fluo-3 (pentapotassium salt, MolecularProbes). Only cells that showed a resting and stable level offluorescence were used for experiments (28 of 48 fillings). Thedye was allowed to dialyze into the cell for 5-10 min before thestart of the image acquisition, which was performed as describedabove.

RESULTS

Dihydrorhodamine oxidation during hypoxia-hypoglycemia and reoxygenation
Hippocampal organotypic slice cultures were loaded with the nonfluorescent dye DHR123 (15 µM) as detailed in Materials andMethods. The fluorescence emission of CA1 pyramidal cells wasexamined before, during, and after perfusion with glucose-freedeoxygenated ACSF aerated with 95% N₂/5% CO₂. Monitoring of theoxygen level in the perfusion chamber containing the brain slice(see Materials and Methods) revealed that complete hypoxic conditionswere achieved 1.5 min after the onset of perfusion with oxygenand glucose-free ACSF. The hypoxic-hypoglycemic insult was appliedfor 8 min.

The CA1 pyramidal layer was first localized by infrared microscopy (Figs. 1, 4, and 7), and then DHR123 oxidation to fluorescentRH123 was followed using a rhodamine filter. DHR123 has been shownto be oxidized primarily by superoxide and hydrogen peroxide (Hendersonand Chappell 1993). In slices not subjected to the hypoxic-hypoglycemicinsult, background DHR123 fluorescence was stable or slightlydecreased during the period of observation (Fig. 2A). At the endof the experiments, we perfused slices with hydrogen peroxide(3 mM) as a control for adequate loading, which caused a largeincrease in fluorescence in all slices. Fluorescence emissionincreased in 12 of 13 slices during reoxygenation after the 8min ischemic episode (Figs. 1, 2, and 6). We followed individualcells (identified with infrared light) of the CA1 layer in eachslice (see Table 2). The increase in fluorescence, reflectingDHR123 oxidation, was synchronous in all cells, but its magnitudewas variable from cell to cell, the average increase being 30.2± 22% (n = 115). Cells in the alveus (presumably interneuronsand glial cells) had fluorescence increases similar to those ofcells in the pyramidal cell layer. The time course of DHR123 oxidationcan be inspected in Figures 2 and 6. In general, fluorescenceemission was variable during the hypoxic-hypoglycemic episode(see Table 2). Thus, increase in free radical production duringhypoxia-hypoglycemia is not as consistent as during reoxygenation.DHR123 oxidation was prominent during reoxygenation in the majorityof cells (see Table 2), and two or three fluorescence peaks couldbe identified: the first 12.4 ± 1.6 min after the onset of reoxygenation(n = 105 cells in 13 of 15 slices), the second at 20.6 ± 2 min(n = 92 cells in 7 of 13 slices), and the third at 37.1 ± 2.7min (n = 53 cells in 2 of 2 slices). Most fluorescence signalwas seen in cell bodies. We also injected DHR123 into two individualpyramidal neurons using patch electrodes: the fluorescence emissionparallelled that of the loaded slices, increasing during the insultand reoxygenation. In control condition before hypoxia-hypoglycemiathere were no obvious effects of the injected dye on the electrophysiologicalcharacteristics of these neurons (see below).
Fig. 1. DHR123 oxidation to RH123 in the CA1 area of organotypic hippocampal slices subjected to a hypoxic-hypoglycemic episode. Sliceswere loaded for 25-30 min with DHR123 (15 µM). A, Infrared imageof the CA1 layer. B, Pseudocolor micrograph showing backgroundfluorescence emission before the ischemic insult. C, Fluorescenceduring hypoxic-hypoglycemic episode. D, Fluorescence emissionduring reoxygenation (25 min). Fluorescence increased in 12 of13 slices after the anoxic episode. Scale bar (shown in B): 20µm. Pseudocolor bar indicates arbitrary fluorescence units, whichalso applies to Figures 4 and 7.
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Fig. 4. Fluo-3 emission of a CA1 pyramidal neuron during and after hypoxia-hypoglycemia. A, Infrared image showing the pyramidal cellpatched with an electrode containing the calcium indicator fluo-3(10 µM). B, Resting fluorescence signal before the anoxic insult.Scale bar, 25 µm. C, Fluorescence emission increases slightlyduring hypoxia-hypoglycemia (4-6 min). D, Fluorescence increasedcontinuously during reoxygenation (10 min). E, The cell nucleusis prominently fluorescent 25 min after the hypoxic insult. Graphon the bottom right represents excursion of V_m for this cell,which followed the typical pattern (Table 1): depolarizing duringthe hypoxic-hypoglycemic insult (H-H), rebound hyperpolarizationin the first minutes of reoxygenation, and irreversible depolarizationstarting 12 min after the insult and continuing until the endof the recording period.
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Fig. 7. DHR123 oxidation to RH123 in the CA1 area subjected to a hypoxic-hypoglycemic episode in the presence of glutamate receptorblockers. CNQX (10 µM) and D-AP5 (50 µM) were applied throughoutthe experiment. Slices were loaded with DHR123 as explained before.A, Infrared image of the CA1 layer. One neuron was patched (centerof image) to monitor biophysical characteristics, as detailedin the text and in Figure 3. B, Background fluorescence emissionbefore the ischemic insult. Scale bar, 30 µm. C, Fluorescenceduring hypoxic-hypoglycemic episode. D, Emission 15-16 min duringreperfusion. Fluorescence emission in the presence of glutamateblockers did not increase in most of the cells of six slices (78.5%;n = 208 cells).
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Fig. 2. Time course of DHR123 oxidation to fluorescent RH123 during hypoxia-hypoglycemia and reoxygenation. A, Organotypic hippocampalslice cultures were loaded with DHR123 (15 µM), and its oxidationto RH123 was followed in individual cells of the CA1 pyramidalcell layer during hypoxia-hypoglycemia (H/H) and reperfusion withnormal oxygenated ACSF. Images were collected every minute. Whitecircles represent the average of 30 cells from two slices in controlcondition, without anoxic episode. Black squares represent theaverage of 30 cells from two slices subjected to hypoxia-hypoglycemiafor 8 min. The low level background fluorescence (Fig. 1B) wastaken as 100% (baseline). There was an increase in fluorescenceemission during the first 4-6 min of the hypoxic insult and duringreoxygenation. Notice the fluorescence peak during reperfusion,at 11 minutes after the hypoxic-hypoglycemic episode. B, Averagefluorescence emission of 40 cells from two slices exposed to theglutamate receptor blockers CNQX (10 µM) and D-AP-5 (50 µM) duringand after the anoxic insult. Fluorescence signal decreased inall slices tested under these conditions (see text), and onlya few cells showed an increase of fluorescence during reoxygenation(Table 2).
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Fig. 6. Comparison between DHR123 oxidation (A) and fluo-3 fluorescence emission (B) during and after hypoxia-hypoglycemia (H/H).Graph in A represents the average of 10 cells in one slice, whereasthe fluorescence signal of a pyramidal neuron in another slicefilled with fluo-3 via a patch electrode is shown in B. This neuronfired action potentials at low frequency (2.5 Hz) during H/H,which normally resulted in no [Ca²⁺]_i elevations. The first and second major fluorescence elevations(arrows) occurred at 12 and 21 min during reoxygenation in A,and at 11 and 20 min in B.
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Table 2. DHR123 oxidation to RH123 during hypoxia-hypoglycemia and reoxygenation in CA1 cells

n $up-arrow$ F $down-arrow$ F Stable CNQX/AP-5

n $up-arrow$ F $down-arrow$ F Stable

H/H 2-4 min 200 27% 0% 73% 210 0.9% 30.9% 68.1%

H/H 4-8 min 183 30.6% 66.7% 2.7% 209 0.4% 94.7% 4.8%

Reoxygenation 208 81.7% 3.4% 14.9% 200 21.5% 45.5% 33%

RH123 fluorescence was measured in individual pyramidal cells of the CA1 layer during a hypoxic-hypoglycemic (H/H) episodeof 8 min and reoxygenation. $up-arrow$ F and $down-arrow$ F indicate increase or decreasein fluorescence, respectively. First and fifth columns (n) indicatethe number of cells. Most cells had a stable level of fluorescenceemission during the first half of the anoxic insult (first row),and either decreased or increased during the second half (secondrow). Fluorescence increased in the majority of cells during reoxygenation(third row). Glutamate receptor blockers (see text) in generalcaused a decrease in DHR123 oxidation at all stages (columns 5-8),as shown by the low percentage of cells whose fluorescence increased(sixth column).

To follow the biophysical characteristics of neurons during the ischemic insult and the period of reoxygenation, we used thewhole-cell configuration of the patch-clamp method to record intrinsicmembrane properties. Table 1 and Figure 3 summarize changes inneuronal input resistances (R_N) and membrane potentials (V_m).Briefly, neurons depolarized during the first 4 min of hypoxia-hypoglycemia(15 of 19 cells) (Fig. 3A), the average V_m in control was $-$ 55.8± 2.5 mV (n = 13), and $-$ 48.5 ± 4.9 mV (n = 14) during the anoxicepisode (p < 0.0005). V_m repolarized during the last 2 min ofthe insult and during the onset of reoxygenation (10 of 19 cells)(Fig. 3 A and graph in Fig. 4). R_N decreased initially duringhypoxia-hypoglycemia (13 of 19) (Fig. 3B), and in some (nine neurons)there was a rebound toward the end of the insult and beginningof reoxygenation, increasing R_N. These changes in intrinsic membraneparameters are consistent with others reported in recordings fromacute hippocampal slices (Krnjevic and Leblond, 1989). Neuronsstarted to depolarize irreversibly 8-12 min after the onset ofreoxygenation (e.g., graph in Fig. 4); this time point correlateswith the first peak of DHR123 fluorescence (12.4 ± 1.6 min). Bythe end of the recordings, usually 40-50 min after the anoxicinsult, the V_m of most neurons was in the range of $-$ 20 to $-$ 30mV, the average depolarization being 24.7 ± 9.3 mV (n = 7). Intwo neurons loaded with DHR123 via patch electrodes, intrinsicmembrane parameters followed similar patterns as those recordedfrom neurons not loaded via patch pipette; membrane potentialdepolarized by 2.1 ± 0.8 mV (from $-$ 55.4 ± 1.3 mV) during the anoxicepisode and repolarized by 2.35 ± 1.6 mV at the start of the reperfusion.Input resistance decreased during the insult to a value 72 ± 9%of the original (85 ± 0.6 M $Omega$ ) and increased in one cell (23.9%increase with respect to the value during the ischemic episode)at the beginning of reoxygenation.

Table 1. Changes in intrinsic membrane properties of CA1 pyramidal neurons during hypoxia-hypoglycemia (H-H) and reoxygenation

H-H 2-4 min Reoxygenation 2-4 min

R_N (n = 19 cells) Decrease in 13 (24.3 ± 11%) Decrease in 3 (33.8 ± 3%)

Increase in 1 (18%) Increase in 9 (18 ± 8%)

V_m (n = 19 cells) Depolarize in 15 (7.9 ± 5.3 mV) Depolarize in 3 (6.2 ± 5 mV)

Hyperpolarize in 0 Hyperpolarize in 10 (3.9 ± 3.6 mV)

Whole-cell patch-clamp recordings were performed from identified pyramidal neurons (infrared microscopy). During the initialminutes of H-H (2-4 min), input resistances (R_N) decreased andmembrane potentials (V_m) depolarized in most of the cells. Numbersin parentheses represent percentage decrease or increase in R_Nand mean depolarization or hyperpolarization of the V_m (in mV).Values are mean ± SD. During the first few minutes of reoxygenation,most neurons showed a rebound response, increasing R_N and hyperpolarizingthe V_m. See Figure 3 and text for details.

Fig. 3. Changes in intrinsic membrane properties of CA1 pyramidal neurons during hypoxia-hypoglycemia and at the start of reoxygenation(2-4 min). A, Whole-cell recordings from visually identified pyramidalneurons revealed that membrane potential (V_m) depolarized duringthe hypoxic-hypoglycemic episode (H-H, black bars) as comparedwith control values (n = 14). Shown in the plot are mean (±SD)values of the depolarization from control V_m monitored in individualneurons (n = 14). In the presence of glutamate receptor blockers(CNQX, 10 µM, and D-AP-5, 50 µM), the depolarization induced bythe insult was not statistically significant compared with controlvalues (n = 7) (see text for details). The difference betweenthe mean depolarization with and without blockers is statisticallysignificant (asterisk indicates significance level; p < 0.05).V_m repolarized in most neurons (Table 1) at the start of thereoxygenation (RE, white bars) without drugs; comparison betweenmean values with and without blockers is not significant (p <0.4). B, Input resistance (R_N) decreased during the first 4-6min of hypoxia-hypoglycemia (n = 14; p < 0.025) in most of theneurons (for details, see Table 1) and increased in the first2-4 min of reoxygenation (p < 0.05 compared with control; n =9). When glutamate transmission was blocked, R_N values duringthe insult and subsequent reperfusion were not significantly differentfrom those of control (n = 6; p < 0.4).
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When DHR123 is oxidized and becomes RH123, it is taken up by healthy mitochondria because of their very hyperpolarized potential(160 mV more negative than the cytoplasm), and it is releasedin the cytoplasm if the mitochondrial potential depolarizes, whichcauses the fluorescence signal to become weaker, probably becauseof dilution, and eventually disappear (Duchen and Biscoe, 1992;Nieminen et al., 1995; Yang et al., 1997). This phenomenon couldexplain the decrease of fluorescence in the DHR123 experimentsat different time points (Figs. 2A, 6A). Hence, as a control experiment,we loaded six slices directly with RH123 (10 µM) and found thatthe fluorescence signal decreased in all slices during hypoxia-hypoglycemiaand was stable (n = 2) or continued decreasing (n = 4) duringreperfusion with oxygenated glucose-containing ACSF. This suggeststhat the mitochondrial potential depolarizes during the ischemicepisode.

Intracellular calcium levels increase during reoxygenation and parallel increases in DHR123 oxidation
Rises in [Ca²⁺]_i after excitotoxic insults have been linked to free radical production. Significant increases in [Ca²⁺]_i have been reported in glial cells and in dissociated neuronsduring ischemic episodes (Duffy and MacVicar, 1996), as well asafter intense glutamate receptor activation (Michaels and Rothman,1990; Tymianski et al., 1993). We assessed the changes in [Ca²⁺]_i in individual CA1 pyramidal neurons filled with the calciumindicator fluo-3 (10 µM), using the patch-clamp technique. Atthe same time, whole-cell recordings allowed us to follow theviability of neurons during and after the hypoxic-hypoglycemicchallenge. The neuron was first patched in the visual field underinfrared light (Fig. 4A), and the dye was allowed to dialyze for10-15 min. Fluo-3 fluorescence increased during reoxygenationin five of seven cells (Figs. 4, 5, and 6); the average increasewas 6.7 ± 2.6% relative to the baseline value before the anoxicepisode. In control experiments, fluorescence was monitored foran equivalent time in neurons that were not subjected to the challenge,and in these cases (n = 4), fluorescence emission tended to decrease(Fig. 5A), probably because of photobleaching and dye extrusion.
Fig. 5. Time course of intracellular calcium ([Ca²⁺]_i) accumulation measured by fluo-3 fluorescence emission in CA1 pyramidal neuronsduring and after hypoxia-hypoglycemia. A, Fluo-3 was injectedinto individual pyramidal cells in the visual field using patchelectrodes, as in Figure 4. Images were collected every 30 sec.White squares represent control fluo-3 signal in a pyramidal cellnot subjected to hypoxia-hypoglycemia (H/H). Black circles representfluo-3 emission in another pyramidal neuron during the H/H episodeand subsequent reoxygenation with normal ACSF. Increase in fluorescenceduring H/H was associated with a few seconds of intense actionpotential firing, as shown in the inset (point 2). Insets showwhole-cell recordings from this neuron at four time points. Initially(point 1), the cell did not fire and received postsynaptic potentials;the V_m at this point was $-$ 58 mV. H/H-induced depolarization causedspike firing (point 2; spike frequency was 15 Hz; Vm = $-$ 51 mV);neurons with lower spike frequencies did not present a rise influo-3 signal (Fig. 6B). After 15-16 min in normal oxygenatedACSF, the neuron depolarized (V = $-$ 46 mV; point 3), but firingwas greatly decreased (0.8 Hz); after 22-23 min it stopped firingcompletely (point 4; V_m = $-$ 38 mV). The increase in fluo-3 emissionwas not uniform during reoxygenation. B, Circles represent thefluo-3 emission of a neuron whose V_m was held at $-$ 60 mV by constantinjection of hyperpolarizing current. Two of six neurons underthese conditions showed an increase in fluorescence signal duringreoxygenation. The hyperpolarizing holding current was $-$ 0.15 nAinitially, $-$ 0.22 nA after 10 min, and $-$ 1.9 nA at 22 min duringreoxygenation, at which time the voltage clamp was removed, whichresulted in a large calcium influx. Squares show the fluorescencesignal of another voltage-clamped neuron that did not presentelevation in [Ca²⁺]_i; the clamp in this cell was maintained throughout the timeof recording. C, Blocking of glutamate transmission with CNQX(10 µM) and D-AP5 (50 µM) abolished fluorescence increase duringH/H and reoxygenation. The fluorescence signal in these cells(n = 7) was similar to those in control as shown in A (white squares).
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The increase in [Ca²⁺]_i during reoxygenation was evident not only in the cell body but also along the dendrites (Fig. 4); inparticular, cell nuclei showed the strongest increase in fluo-3fluorescence. The time course of calcium rise is shown for twoneurons in Figures 5A and 6B. [Ca²⁺]_i increased in the majority of neurons during the ischemic challenge(7 of 12), the average increase being 6.1 ± 3% of control. In2 of 12 neurons, fluo-3 fluorescence decreased slightly (Fig.6B), and in 3 of 12 neurons the fluorescence remained stable duringthe insult. The rise in [Ca²⁺]_i during hypoxia-hypoglycemia was associated with intense neuronalfiring (as shown in Fig. 5A, spike frequency was 15 Hz) broughtabout by depolarization. In the other four neurons that firedaction potentials at low frequencies, there was no rise in fluorescencesignal (see for example Fig. 6B; this cell fired at 2.5 Hz).

The rise in [Ca²⁺]_i during reperfusion was not uniform, but presented irregular steps, was not associated with neuronal firing.Three time points could be identified that showed a pronouncedrise in fluo-3 signal: the first occurred at 12.3 ± 0.67 min afterthe onset of reoxygenation in five of seven neurons, the secondat 20.6 ± 0.8 min (five of seven cells), and the third at 36.8± 3.9 min, which could be identified in four neurons. Interestingly,a comparison with DHR123 fluorescence peaks mentioned before showsa significant temporal correspondence: 12.4 ± 1.6, 20.6 ± 2, and37.1 ± 2.7 min: these times were not statistically different fromthose of the calcium signal (p < 0.25). [Ca²⁺]_i decreased abruptly toward the end of the recordings, after40-50 min reoxygenation (Figs. 5B, 6B), which coincided with theloss of DHR123 signal in some slices (Fig. 2A). At this pointwe stained slices (n = 4) with the vital dye SYTOX (2.5 µM) andfound that only a very small number of cells were stained (twoto four for a field of 0.04 mm²), indicating that cells still retained membrane integrity.

As mentioned before, irreversible neuronal depolarization started around 10-12 min during reperfusion (Fig. 4), which suggeststhat part of the calcium influx could be mediated by voltage-activatedcalcium channels. Hence, we assessed the effects of clamping V_mat a hyperpolarized level on fluo-3 fluorescence emission duringreoxygenation. Examples of changes in [Ca²⁺]_i in two neurons the V_m of which was kept at resting level byconstant injection of hyperpolarizing current are shown in Figure5B. Of six neurons that were voltage-clamped near the restingmembrane potential, two (33.3%) showed a rise in fluo-3 signal,the average increase being 5.25 ± 3.8% of control, which is notsignificant when compared with increases without voltage clamp(6.7 ± 2.6%; p < 0.4). Fluo-3 emission did not change in the otherfour neurons. When it was not possible to hold the clamp becauseof current leakage, [Ca²⁺]_i increased abruptly. These observations suggest that at leastpart of the calcium influx may occur via voltage-gated calciumchannels.

Glutamate receptor blockade reduces free radical generation and intracellular calcium accumulation
It is widely accepted that glutamate receptor overactivation promotes rises in [Ca²⁺]_i and free radicals, which results in delayed neuronal death(Rothman, 1984; Choi et al., 1988; Michaels and Rothman, 1990;for review, see Coyle and Puttfarcken, 1993; Patel et al., 1996).However, it remains unknown whether ischemia-induced free radicaloverproduction depends critically on glutamatergic transmission.Hence, we asked what effects the blockade of glutamate transmissioncould have on DHR123 fluorescence and calcium accumulation duringand after hypoxia-hypoglycemia.

The non-NMDA glutamate receptor blocker CNQX (10 µM) and the specific NMDA blocker D-AP-5 (50 µM) were bath-applied duringthe ischemic episode and the period of reperfusion. Whole-cellrecordings showed the complete abolition of spontaneous EPSPsseen in individual neurons 2-3 min after application of the blockers(data not shown). DHR123 oxidation decreased significantly duringreperfusion in all slices tested (n = 6), as shown in Figures2B and 7. Only 21.5% (43 of 200 cells) of cells in the CA1 layershowed increased fluorescence, compared with 81.7% without blockers(Table 2). The average increase of those 43 cells was 8.6 ± 3.2%of control baseline, which is significantly lower than the averageincrease without glutamate blockers (30.2 ± 22.6%; p < 0.0005).Interestingly, the peak of DHR123 oxidation in the presence ofblockers occurred 13.3 ± 1.8 min after the onset of reoxygenationin the 43 cells that exhibited increased fluorescence, which istemporally correlated with the first increase in DHR123 oxidationwith intact glutamate transmission (12.4 ± 1.6 min). Similarly,the number of cells that presented an increase in DHR123 fluorescenceduring the hypoxic-hypoglycemic insult in the presence of CNQXand D-AP-5 (0.9%) (Table 2) was much lower than when these blockerswere omitted (27%).

[Ca²⁺]_i accumulation was greatly reduced in the presence of glutamate receptor blockers during the insult and reperfusion (Fig.5C): only one neuron of eight had a rise in fluo-3 signal duringreoxygenation (6% increase), which occurred 11 min after the onsetof reperfusion, and in 4 of 10 neurons there was a [Ca²⁺]_i increase during hypoxia-hypoglycemia. The average fluo-3 signalrise during the insult in those four cells was 2.8 ± 0.9% of baselinelevel (before the challenge), which is significantly lower thanthe rise during the hypoxic episode with intact glutamate transmission(6.1 ± 3%; p < 0.05). Increased fluo-3 signal during hypoxia-hypoglycemiawas associated, as before, with neuronal firing: of six neuronsthat fired action potentials, four showed an elevation in [Ca²⁺]_i. It is worth noting that unlike what happened with intact glutamatetransmission, intrinsic membrane properties (R_N and V_m) of neuronsrecorded during the hypoxic episode were not significantly differentfrom those before the challenge (Fig. 3). V_m before the insultwas $-$ 54.1 ± 5.5 mV (n = 7) and $-$ 52.1 ± 5.2 mV during hypoxia-hypoglycemia(n = 7; p < 0.25). These observations suggest an important roleof glutamate receptor activation in hypoxia-hypoglycemia-inducedmembrane potential depolarization and decreased input resistance.

DISCUSSION
The precise mechanisms of ischemia-induced irreversible cellular damage remain unknown. Recent observations suggest an interplayamong three major mechanisms: glutamate excitotoxicity, risesin [Ca²⁺]_i, and free radical generation (Choi, 1990; Zhang and Piantadosi,1992; Lafon-Cazal et al., 1993; Lipton and Rosenberg, 1994; Martinet al., 1994; Bindokas and Miller, 1995; Dugan et al., 1995; Hallet al., 1995; Newell et al., 1995; Schinder et al., 1996; Whiteand Reynolds 1996). Despite the fact that oxidative damage seemsto play an essential role in ischemic injury, direct evidenceof free radical generation during ischemia in neurons has neverbeen presented. Free radical overproduction during ischemia-reperfusionhas been indicated by data obtained in vivo only (Cino and DelMaestro, 1989; Zhang and Piantadosi 1992; Hall et al., 1995),even though other experiments did not detect evidence for freeradical involvement in ischemic injury (Folbergrova et al., 1993;Lundgren et al, 1991). Although some of these experiments showan increase in peroxidation of membrane lipids and proteins andchanges in ratios of oxidized and reduced glutathione (Watsonet al., 1984; Oliver et al., 1990), they do not prove that freeradicals are generated in individual neurons, because the samplesare usually whole brain tissue and cortical superfusates (Ziniet al., 1992; Phillis and Sen, 1993; Hyslop et al., 1995). Inthis work, we have taken advantage of the fact that organotypicslice cultures maintain intact neuronal circuitry and cells haveproperties similar to those found in vivo (Zimmer and Gahwiler,1984; Stoppini et al 1991) to examine three main questions: (1)whether free radicals are generated in pyramidal neurons duringand after hypoxia-hypoglycemia, (2) whether there is a changein [Ca²⁺]_i in that period, and (3) whether glutamate transmission playsany role in free radical generation or intracellular calcium accumulation.

Our observations provide direct evidence that free radicals are generated in CA1 pyramidal neurons in response to a hypoxic-hypoglycemicepisode and that reperfusion with oxygenated ACSF promotes a largerand more consistant increase in free radical production. Becausethe oxidation of DHR123 to RH123 is an irreversible process, thedecreases in fluorescence signal after prolonged increases throughoutthe experiment (Figs. 2, 6) seemed paradoxical. However, thisis explained by the dynamics of RH123 distribution in the cell.It has been observed that RH123 is internalized in mitochondriabecause of their hyperpolarized potential and released on depolarization,which causes the fluorescence signal to become fainter becauseof dilution (Duchen and Biscoe, 1992; Henderson and Chappell,1993; Nieminen et al., 1995; Yang et al, 1997). Hence, the fluorescenceemission we detected in these experiments could reflect an interactionbetween DHR123 oxidation by free radical generation and redistributionof RH123 into hyperpolarized mitochondria and out of depolarizedmitochondria. Although it was not our purpose to determine mitochondrialdysfunction, we stained some slices directly with RH123 as a controlfor possible changes in fluorescence in the DHR123 experiments.In all slices, the fluorescence signal of RH123-loaded slicesdecreased during the hypoxic-hypoglycemic episode, and in mostof them four of six during reperfusion. These observations suggestthat mitochondria depolarize during this period, probably afterthe neuronal depolarization caused by the insult. The preciseorigin of free radical production can not be determined from ourexperiments. We speculate that the possible site of free radicalgeneration are the mitochondria, as proposed by others (Cino andDel Maestro, 1989; Zhang and Piantadosi, 1992; Richter, 1993;Dykens, 1994; Dugan et al., 1995; Reynolds and Hastings, 1995).

The observation that pyramidal neurons filled with the calcium indicator fluo-3 showed an increase in [Ca²⁺]_i during reoxygenation and that there was a significant temporalcorrespondence with DHR123 fluorescence provides evidence thatcellular calcium handling is closely related to neuronal freeradical generation. Increases in fluo-3 emission during hypoxia-hypoglycemiawere usually associated with neuronal spike generation (Fig. 5A),whereas increased fluorescence during reperfusion with oxygenatedACSF occurred with little or no spike firing. This could indicatethat part of the cytoplasmic calcium may come from internal stores,reversal of the Na/Ca exchanger (Barzilai and Rahaminoff, 1987),voltage-activated calcium channels, or nonspecific holes in themembrane (Phillis and Nicholson, 1978). The increased [Ca²⁺]_i during the insult could be responsible in part for the hyperpolarizationof the neuronal potential observed toward the end of the insultand beginning of the reoxygenation, by activating calcium-activatedpotassium conductances (Krnjevic and Leblond, 1989). We did notinvestigate the source of this calcium influx, but there is experimentalevidence that in vitro ischemia promoted intracellular calciumrelease in glial cells (Duffy and MacVicar, 1996). Because weobserved a continuous neuronal depolarization starting 10-12 minafter the ischemic insult, we assessed the contribution of thisdepolarization to calcium accumulation by holding V_m close toresting levels. A rise in fluo-3 emission was still evident in33% of voltage-clamped neurons, which suggests that at least partof the cytoplasmic calcium accumulation may be attributable toother sources as detailed above. For example, glutamate-inducedcalcium influx may further augment calcium release from mitochondria,as was suggested by several experiments in cultured neurons (Kiedrowskiand Costa, 1995; White and Reynolds, 1996). The mitochondrialcalcium uptake and release has been termed calcium "cycling" (Richter,1993). The high calcium load and oxidative stress that occur duringhypoxia-hypoglycemia have been proposed to cause the collapseof mitochondrial potential and impairment of mitochondrial abilityto retain calcium (Richter et al., 1996). The irregularly increasingfluo-3 emission during reoxygenation is suggestive of patternsattributed to mitochondrial calcium sequestration and releaseas observed in DRG neurons (Werth and Thayer, 1994). More experimentswill be needed to understand how mitochondrial function relatesto [Ca²⁺]_i during ischemia.

Finally, we present evidence for a direct connection between glutamate neurotransmission, rises in [Ca²⁺]_i, and free radical generation during and after hypoxia-hypoglycemia.Blockade of NMDA and non-NMDA glutamate receptors resulted ina significant decrease of DHR123 oxidation and [Ca²⁺]_i accumulation, with no significant changes in V_m and R_N duringthe anoxic challenge. Although these results may suggest thatneuronal depolarization and free radical formation are related,to investigate a possible causal relationship is beyond the scopeof the present study. Other experiments performing pharmacologicalmanipulations of potassium conductances, for example, will berequired before a clear causal relation between the two processesis established. It should be noted that our hypoxic insult andreoxygenation may not represent what is encountered during invivo conditions, in which neurons are supplied oxygen via hemoglobin.

In summary, our data provide a link between several mechanisms thought to cause irreversible neuronal damage in ischemia,such as the loss of CA1 neurons in organotypic slices subjectedto oxygen and glucose deprivation reported by Newell et al., (1995).We propose the following set of events: the initial depolarizationand spike-firing caused by hypoxia-hypoglycemia releases glutamate,which promotes further depolarization, [Ca²⁺]_i accumulation, and free radical generation, and possibly animpairment of mitochondrial function. A precise understandingof the interplay of these mechanisms can lead to the developmentof pharmacological strategies to prevent neurodegeneration.

FOOTNOTES

Received July 7, 1997; revised Aug. 28, 1997; accepted Sept. 10, 1997.

This work was supported by the Medical Research Council of Canada (MRC), the Bloorview Epilepsy Programme, and the NeurosciencesNetwork.

Correspondence should be addressed to Jose Luis Perez Velazquez, Playfair Neuroscience Unit, McL 12-413, Toronto Western Hospital,399 Bathurst Street, Toronto, Ontario M5T 2S8, Canada.

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