Depression of Fast Excitatory Synaptic Transmission in Large Aspiny Neurons of the Neostriatum after Transient Forebrain Ischemia

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The Journal of Neuroscience, December 15, 2002, 22(24):10948-10957

Depression of Fast Excitatory Synaptic Transmission in Large Aspiny Neurons of the Neostriatum after Transient Forebrain Ischemia
Zhi-Ping Pang, Ping Deng, Yi-Wen Ruan, and Zao C. Xu
Department of Anatomy and Cell Biology, Indiana University School of Medicine, Indianapolis, Indiana 46202

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Spiny neurons in the neostriatum die within 24 hr after transient global ischemia, whereas large aspiny (LA) neurons remainintact. To reveal the mechanisms of such selective cell deathafter ischemia, excitatory neurotransmission was studied in LAneurons before and after ischemia. The intrastriatally evokedfast EPSCs in LA neurons were depressed $<=$ 24 hr after ischemia.The concentration-response curves generated by application ofexogenous glutamate in these neurons were approximately the samebefore and after ischemia. A train of five stimuli (100 Hz) inducedprogressively smaller EPSCs, but the proportion of decrease inEPSC amplitude at 4 hr after ischemia was significantly smallercompared with control and at 24 hr after ischemia. Parallel depressionof NMDA receptor and AMPA receptor-mediated EPSCs was also observedafter ischemia, supporting the involvement of presynaptic mechanisms.The adenosine A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthineblocked the inhibition of evoked EPSCs at 4 hr after ischemiabut not at 24 hr after ischemia. Electron microscopic studiesdemonstrated that the most presynaptic terminals in the striatumhad a normal appearance at 4 hr after ischemia but showed degeneratingsigns at 24 hr after ischemia. These results indicated that theexcitatory neurotransmission in LA neurons was depressed afterischemia via presynaptic mechanisms. The depression of EPSCs shortlyafter ischemia might be attributable to the enhanced adenosineA1 receptor function on synaptic transmission, and the depressionat late time points might result from the degeneration of presynapticterminals.

Key words: ischemia; excitotoxicity; AMPA; neuronal death; striatum; interneurons; excitatory synaptic transmission

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Large aspiny (LA) neurons only account for <2% of the entire neuronal population in the neostriatum but have great influenceson the function of basal ganglia. They have large somata (20-60µm) with extended smooth dendrites and widespread axonal arborizations(DiFiglia and Carey, 1986; Wilson et al., 1990; Kawaguchi, 1992).LA neurons are the source of acetylcholine in the neostriatum(Butcher and Hodge, 1976; Bolam et al., 1984), and by activationof muscarinic receptors, they affect the output of the neostriatumthrough the complex modulation of synaptic transmission in spinyprojection neurons and interneurons (Kawaguchi et al., 1995; Galarragaet al., 1999; Koos and Tepper, 1999; Calabresi et al., 2000).

The striatum is one of the most vulnerable regions in the brain to cerebral ischemia. Small- to medium-sized neurons (mostlikely spiny neurons) in the dorsal striatum die 24 hr after 25-30min of forebrain ischemia (Pulsinelli et al., 1982). However,LA neurons in the same region are resistant to ischemic insult(Francis and Pulsinelli, 1982; Chesselet et al., 1990). The mechanismsunderlying this selective vulnerability after ischemia are poorlyunderstood. Excitotoxicity is one of the major causes of neuronaldeath after ischemia (Rothman and Olney, 1986; Choi and Rothman,1990). Previous studies have shown that the excitatory synaptictransmission is enhanced in ischemia-vulnerable CA1 pyramidalneurons in the hippocampus after ischemia/hypoxia (Urban et al.,1989; Crepel et al., 1993; Gao et al., 1998a). On the contrary,a depression in excitatory synaptic transmission has been observedin ischemia-resistant CA3 neurons and dentate granule cells afterischemia (Gao et al., 1998b). These results suggest that the enhancementof excitatory neurotransmission might be associated with ischemiccell death, and that the depression of excitation might be involvedin neuroprotection afterischemia.

Electrophysiological studies on selective cell death in the striatum after ischemia are less extensive. What are the differencesin synaptic transmission between spiny neurons and LA neuronsafter ischemia? What are the mechanisms underlying these changesand how these changes determine the ischemic outcome of theseneurons? In vitro studies have reported that the membrane potentialof spiny neurons was depolarized during hypoxia/hypoglycemia,whereas that of LA neurons was hyperpolarized (Calabresi et al.,1997b; Pisani et al., 1999). Deprivation of oxygen and glucosein brain slices has been shown to induce long-term potentiation(LTP) in spiny neurons but not in LA neurons (Calabresi et al.,2002). Because of the dramatic difference in temperature, microenvironment,and homeostasis, the neuronal responses to hypoxia/hypoglycemiain vitro might differ from those after ischemia in vivo. To revealthe synaptic transmission changes in striatal neurons after ischemia,especially those after reperfusion, studies using an intracellularrecording in vivo technique have shown that IPSPs in spiny neuronswere abolished, and that the incidence of cortically evoked polysynapticEPSPs was significantly increased after transient forebrain ischemia(Gajendiran et al., 2001). Little is known about synaptic transmissionchanges in LA neurons after ischemia in vivo, because recordingfrom LA neurons in vivo is extremely difficult because of theirsparse distribution. To circumvent this problem, the present studyexamined the evoked EPSCs from visually identified LA neuronsin brain slices prepared at different intervals after ischemiain vivo.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Male Wistar rats (100-180 gm; Charles River Laboratories, Wilmington, MA) of ~5-6 weeks of age were used in the present study.Experimental protocols were institutionally approved in accordancewith the National Institutes of Health Guide for the Care andUse of Laboratory Animals. All efforts were made to minimize boththe suffering and number of animalsused.

Transient forebrain ischemia. Transient forebrain ischemia was induced using the four vessel occlusion method (Pulsinelliand Brierley, 1979) with modifications (Ren et al., 1997). Theanimals were fasted overnight to provide uniform blood glucoselevels. For surgical preparation, the animals were anesthetizedwith a mixture of 1-2% halothane, 33% O₂, and 66% N₂ via a gasmask placed around the nose. A silicon tube loop was placed looselyaround each common carotid artery to allow subsequent occlusionof these vessels. The animal was then placed on a stereotaxicframe, and the vertebral arteries were electrocauterized. A verysmall temperature probe (0.025 inch D; Physitemp, Clifton, NJ)was inserted beneath the skull in the extradural space, and thebrain temperature was maintained at 37°C with a heating lamp usinga temperature-control system (BAT-10; Physitemp). Transient forebrainischemia was induced by occluding both common carotid arteriesto induce ischemic depolarization for ~22 min. Cerebral bloodflow resumed immediately on release of the carotid arteryclasps.

Slice preparation and whole-cell, voltage-clamped recording. Brain slices were prepared from animals before ischemia and at4-6 and 24 hr after reperfusion as described previously (Chi andXu, 2000). The animals were anesthetized with ketamine-HCl (80mg/kg, i.p.) and decapitated. The brains were quickly removedand immersed in ice-cold artificial CSF (ACSF), which was composedof the following (in mM): 130 NaCl, 3 KCl, 2 CaCl₂, 2 MgCl₂, 1.25NaH₂PO₄, 26 NaHCO₃, and 10 glucose. Transverse striatal slicesof 280 µm thickness were cut using a vibratome (VT 1000S; Leica,Nussloch, Germany) and incubated in ACSF for $>=$ 1 hr at room temperaturebefore being transferred to the recording chamber. The slice wassubmerged beneath the fluid surface and superfused continuouslywith oxygenated ACSF. The flow rate was adjusted to 2-3 ml/min.Recordings were performed at room temperature (~24°C).

For whole-cell recording, patch electrodes were prepared from borosilicate glass (Warner Instruments, Hamden, CT) using ahorizontal electrode puller (P-97; Flaming/Brown; Sutter, Novato,CA) to produce tip openings of 1-2 µm (3-5 M $Omega$ ). Electrodes werefilled with an intracellular solution containing (in mM): 43 CsCl,92 CsMeSO₄, 5 TEA, 2 EGTA, 1 MgCl₂, 10 HEPES, and 4 ATP (Sigma,St. Louis, MO). Neurobiotin (2%) (Vector Laboratories, Burlingame,CA) was included in some experiments to verify the neurons recorded.Neurons were visualized with an infrared-differential interferencecontrast (DIC) microscope (BX 50 WL; Olympus Optical, Tokyo, Japan)and a CCD camera. Only those with large somata (>20 µm) were selectedfor recording. Positive pressure was applied to the recordingpipette as it was lowered into the medium and approached the cellmembrane. Constant negative pressure was applied to form the seal(>1 G $Omega$ ) when the recording pipette attached to the membrane. Asharp pulse of negative pressure was applied to open the cellmembrane for whole-cell recording. The series resistance of thepipette was ~10 M $Omega$ . Voltage-clamped recording was performed withan Axopatch 200 B amplifier (Axon Instruments, Foster City, CA).Signals were filtered at 2 kHz and digitized at a sampling rateof 5 kHz using a data-acquisition program (Axograph 4.5; AxonInstruments). Intrastriatal stimulation was delivered every 10-20sec using a bipolar tungsten electrode (~5 M $Omega$ ; Micro Probe, Potomac,MD), and 0.1 msec current pulses were used to evoke the excitatoryresponses. Zero to five times of threshold stimulus intensity(0-5T) was used in the present experiments. In some experiments,a train of five stimuli at 100 Hz with the same intensity (4T)and duration (100 µsec) was applied at an interval of 60-90sec.

In some experiments, neurobiotin was iontophoresed into the cell by passing depolarizing pulses after recording. The slicewas then fixed in 4% paraformaldehyde overnight and incubatedin 0.1% horseradish peroxidase-conjugated avidin D (Vector Laboratories)in 0.01 M potassium PBS, pH 7.4, with 0.5% Triton X-100 for 24hr at room temperature. After detection of peroxidase activitywith 3,3'-diaminobenzidine, slices were examined in potassiumPBS. Slices containing labeled neurons were mounted on gelatin-coatedslides and processed for lightmicroscopy.

Electron microscopy. At 4-6 hr (n = 2) or 24 hr (n = 2) after transient forebrain ischemia, the animals were anesthetizedwith ketamine (80 mg/kg, i.p.) and then perfused transcardiallywith 100 ml of PBS, followed by 400 ml of 2% glutaraldehyde and2% paraformaldehyde in 0.1 M potassium PBS. The brain was removedand postfixed in the same fixative for $>=$ 12 hr. The brain blocks,including the striatum between 1.2 and 0.2 mm from the Bregmalevel, were cut in vibratome. Sections of 50 µm thickness werepostfixed with 0.5% osmium tetroxide for 1 hr and incubated in0.5% uranylacetate for 2 hr. The sections were embedded in Embed812 and put into an oven at 60°C for polymerization for 48 hr.Ultrathin sections were stained with 2% uranylacetate and 1% leadcitrate and examined under a Philips electron microscopic (EM)400 electron microscope. For quantitative analysis of degeneratedterminals at different intervals after ischemia, images at thedorsal striatum were captured randomly at 13,000× magnification(unit area of 42.3 µm² per image). The pictures were enlarged, and the presynaptic terminalswere counted and divided into different groups according to theirmorphological features. The data were analyzed using StatView5.0 (Abacus Concepts, Calabasas,CA).

Drug application. ( $-$ )-Bicuculline methiodide (BMI), ( $-$ )-2-amino-5-phosphonopentanoic acid (D-APV), scopolamine, 8-cyclopentyl-1,3-dipropylxanthine(DPCPX), and glybenclamide were obtained from Sigma. Antagonistswere applied via bath superfusion. BMI was used to block GABA_Areceptors at a concentration of 30 µM, and 50 µM D-APV was usedfor NMDA receptor (NMDAR) blockade. (±)-4-(4-aminophenyl)-1,2-dihydro-1-methyl-2-propylcarbamoyl-6,7-methylenedioxyphthalazine(SYM 2206), cyclothiazide (CTZ), and (RS)- $alpha$ -methyl-4-carboxyphenylglycine(MCPG) were purchased from Tocris Cookson (Ellisville, MO). Agonistswere applied through a "Y"-tube system (Kiyosawa et al., 2001).The tip of the Y-tube had a diameter between 100 and 150 µm andwas placed close to the neuron understudy.

Data analysis. A Michaelis-Menten equation using a least-squares fitting was applied for evaluation of the EC₅₀ of glutamatein the concentration-response relationships, as follows: a = bⁿ/(bⁿ + EC₅₀ⁿ), where a is relative activation, b is agonist concentration(molar concentration), and n is the Hillcoefficient.

The values were presented as mean ± SEM. The unpaired t test (for two groups) or ANOVA (for more than two groups) followedby post hoc Scheffe's test was used for statistical analysis (StatView5.0; Abacus Concepts). Changes were considered significant ifp < 0.05.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

LA neurons were easily identified according to their large somata, ranging from 20 to 60 µm in diameter under infrared-DICoptics (Fig. 1A). Intracellular staining with neurobiotin revealedthat these neurons have large somata with three to five primarydendrites bearing few spines (Fig. 1B). Forebrain ischemia thatinduces an ischemic depolarization of ~22 min consistently produced>90% cell death in the dorsal striatum (Ren et al., 1997). At24 hr after ischemia, it was difficult to find small- to medium-sizedneurons from brain slices, whereas neurons with large somata remainedintact.

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Figure 1. Photomicrographs of a LA neuron visualized in brain slice with an infrared-DIC microscope before recording (A) and after intracellular staining with neurobiotin (B). The cell body of this neuron is ~60 µm in diameter, and the dendrites are smooth.

Depression of AMPA receptor-mediated EPSCs after ischemia

Intrastriatal stimulation evoked both EPSCs and IPSCs from LA neurons. To block the IPSCs mediated by GABA_A receptors andmuscarinic receptors, BMI (30 µM) and scopolamine (3 µM) wereadded to the bath solution. Both AMPA receptor (AMPAR)- and NMDAR-mediatedcomponents contribute to EPSCs in LA neurons (Kawaguchi, 1992;Calabresi et al., 1998). Inward EPSCs were evoked at a holdingpotential of $-$ 60 mV. Because AMPARs, especially calcium-permeableAMPARs, play an important role in neuronal injury after ischemia(Pellegrini-Giampietro et al., 1994; Gorter et al., 1997), thepresent study focused on changes in AMPAR-mediated EPSCs in LAneurons after ischemia. Therefore, D-APV (50 µM) was added tothe bath solution to block NMDAR-mediated EPSCs. The remainingevoked responses could be reversibly blocked by 30 µM CNQX, indicatingnon-NMDAR-mediated responses (Fig. 2A). To further clarify thereceptor subtype that mediated the synaptic response, the AMPAR-specificantagonist SYM 2206 (100 µM) was applied and completely blockedthe EPSCs. The current-voltage relationship of AMPAR-mediatedEPSCs showed inward rectifications before and after ischemia (Fig.2B), suggesting that they are mediated by Ca²⁺-permeable AMPARs (Suzuki et al., 2001).

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Figure 2. Non-NMDAR-mediated EPSCs in LA neurons. A, Evoked synaptic currents were recorded from a LA neuron at a holding potential of $-$ 60 mV. Synaptic currents were elicited by intrastriatal stimulation in the presence of BMI (30 µM) and scopolamine (3 µM). D-APV (50 µM) was added to the bath subsequently. The evoked EPSCs were blocked by 30 µM CNQX, indicating that they are AMPAR-mediated currents. B, Current-voltage relationship of AMPAR-mediated EPSCs in LA neurons. BMI, scopolamine, and D-APV were added to the bath medium. B1, Representative traces showing the EPSCs recorded at different holding potentials with four times the threshold stimulus intensity (4T) before and at 4 hr after ischemia. The amplitude of EPSCs increased with more hyperpolarizing holding potentials, and the inward currents reversed to outward currents at positive holding potentials. B2, Current-voltage (I-V) curves of AMPAR-mediated EPSCs in LA neurons before (n = 9) and after (n = 9) ischemia. Amplitudes of evoked EPSCs at various holding potentials (V_H) were normalized to those at various holding potentials of $-$ 60 mV. The I-V curve showed strong inward rectification at positive holding potentials. All traces are the average of 6-10 consecutive recordings. The values of the plotting are mean ± SEM.

To examine the efficacy of synaptic transmission in LA neurons, the threshold of stimulus intensity was compared before andafter ischemia. The threshold of stimulus intensity was definedas the stimulating current that evokes the smallest detectableresponse from LA neurons. There were significant changes in thethreshold of stimulus intensity after ischemia (ANOVA; F = 4.07;df 2, 45; p = 0.024). In control animals, the threshold stimulusintensity for inducing EPSCs was 410 ± 61 µA (n = 18) in the presentexperimental conditions. The threshold stimulus intensity increasedto 524 ± 75 µA (n = 17) and 808 ± 16 µA (n = 13; post hoc Scheffe'stest; p < 0.05) at 4-6 and 24 hr after ischemia, respectively.The amplitudes of the evoked EPSCs increased according to theincrease in stimulus intensities (Fig. 3). In comparison withthe control levels, the amplitudes of EPSCs in LA neurons decreaseddramatically at most stimulus intensities after ischemia (Fig.3B). For example, at a stimulus intensity of four times the thresholdstimulus intensity (4T), the amplitude of EPSCs was significantlydepressed (ANOVA; F = 7.22; df 2, 45; p = 0.002). The amplitudewas 129.7 ± 14.4 pA in controls (n = 18) and 68.9 ± 11.9 pA (n= 17; post hoc Scheffe's test; p < 0.01) and 75.1 ± 10.5 pA (n= 13; p < 0.05) at 4-6 and 24 hr after reperfusion, respectively.

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Figure 3. Changes in EPSCs in LA neurons before and after ischemia. A, Representative traces recorded from LA neurons before and at 4 hr after ischemia. The amplitude of evoked EPSC increased with increasing stimulus intensities (0-5 times threshold intensities, 0-5T), but the amplitude of EPSCs at 4 hr after ischemia was significantly smaller than that of control ones. The traces are the average of six consecutive recordings. B, The input-out relationship of evoked EPSCs before and at different intervals after ischemia. The amplitude of EPSCs was dramatically decreased at 4 and 24 hr after ischemia at all stimulus intensities (1.5-5T). *p < 0.05; p < 0.01.

No significant change in postsynaptic AMPAR function after ischemia

To reveal whether the depression of evoked EPSCs after ischemia was caused by the attenuation of glutamate receptor functions,postsynaptic responses were examined by focal application of exogenousAMPA or glutamate in the presence of D-APV through a Y-tube system.The application of glutamate induced an inward current at a holdingpotential of $-$ 60 mV. The non-NMDAR antagonist CNQX (data not shown)and the AMPAR-specific antagonist SYM 2206 (Fig. 4A1) blockedthe glutamate-induced responses in a dose-dependent manner. TheAMPAR desensitization was extremely rapid, ranging from 2 to 40msec in neurons (Kiskin et al., 1986; Trussell et al., 1988; Tanget al., 1989), and the speed with which we could apply agoniststo our recorded neurons in slice was limited. The peak currentmight not be accurately detected in the present configuration.Therefore, the steady-state currents were compared before andafter ischemia. The glutamate-induced currents became detectableat a concentration of ~3 × 10⁵ M and then increased in a sigmoid manner with increasing glutamateconcentrations. The normalized concentration-response curves wereapproximately the same before and after ischemia (Fig. 4B). TheEC₅₀ values were 6 ± 0.31 × 10⁴ M (n = 13) for control neurons and 6.4 ± 0.29 × 10⁴ M (n = 11) and 6.8 ± 0.35 × 10⁴ M (n = 8) for neurons at 4-6 and 24 hr after ischemia, respectively.The Hill coefficients were 1.8 ± 0.2 (n = 13) in the control groupand 1.9 ± 0.2 (n = 11) and 1.9 ± 0.2 (n = 8) at 4-6 and 24 hrafter ischemia, respectively. To eliminate the impact of cellsize, currents were normalized by cell capacitance and expressedas current densities. No significant difference in current densitywas detected after ischemia (Fig. 4C).

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Figure 4. Exogenous glutamate induced whole-cell currents before and after ischemia. A, Application of exogenous glutamate induced an inward current at a holding potential of $-$ 60 mV in the presence of 50 µM D-APV. The glutamate responses were antagonized by SYM 2206, a specific AMPAR antagonist (A1). The amplitude of glutamate-induced currents was increased accordingly with increasing concentrations of glutamate before (A2) and after (A3) ischemia. B, Dose-response curve of glutamate responses before and after ischemia. The EC₅₀ values and Hill coefficients of the dose-response curve after ischemia were approximately the same as those in control neurons. C, Comparison of current densities of glutamate-induced currents in LA neurons before and after ischemia. The current density was slightly decreased at 4 hr after ischemia, but no statistic significance was detected.

AMPARs quickly desensitize, and a decrease in the desensitization of AMPAR-mediated responses has been shown to be involvedin cell death after trauma (Goforth et al., 1999). To examinethe possible changes in desensitization of AMPARs after ischemia,100 µM CTZ, a drug that selectively blocks AMPAR desensitization(Bertolino et al., 1993), was used to eliminate the fast desensitization.After coapplication of CTZ, AMPA-induced currents were increasedmore than twofold, but no significant difference in current densitieswas detected after ischemia (Fig. 5B). To further explore whetherthe desensitization contributes to the changes in EPSCs afterischemia, the decay time of evoked EPSCs was compared before andafter ischemia. The decay phase of EPSCs could be well fittedby a single exponential (Fig. 5C). The decay times were 7.86 ±0.46 msec (n = 14) in control neurons, and no significant differencewas found in neurons after ischemia (8.58 ± 1.05 msec at 4-6 hr,n = 10; 8.08 ± 1.04 msec at 24 hr, n = 11) (Fig. 5D). These dataindicated that the desensitization did not contribute to the changesin evoked EPSCs in LA neurons after ischemia.

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Figure 5. Comparison of desensitization of AMPAR-mediated responses before and after ischemia. A, Examples of whole-cell currents induced by 1 mM AMPA at 4 hr after ischemia before and after application of CTZ. After treatment with 100 µM CTZ, the amplitude of glutamate-induced responses dramatically increased. B, Current density of AMPA-induced responses in LA neurons was approximately the same before and after ischemia. No difference in current density was found between control and ischemic neurons after application of CTZ, despite the current density values of all neurons that were significantly increased. C, Representative traces showing the decay of evoked EPSCs were well fitted by the single exponential method. The traces are the average of six consecutive recordings. D, Histogram showing that the mean decay time of EPSCs in LA neurons did not change after ischemia. The above results indicate that desensitization plays little role in synaptic depression of LA neurons after ischemia.

Alterations of presynaptic mechanisms after ischemia

Another possible cause of the reduction of evoked EPSCs after ischemia is a decrease in presynaptic transmitter release probability.To investigate whether alteration of release probability accountsfor the reduction of evoked fast EPSCs, a paired-pulse test (50msec interstimulus interval) was conducted in LA neurons beforeand after ischemia. However, no obvious changes were detectedin paired-pulse ratio (PPR) at all stimulus intensities afterischemia (data not shown). The changes in release probabilitywere also examined by comparing the EPSCs evoked by a train offive stimuli at 100 Hz (Scheuss et al., 2002). A train of stimuliat high frequency markedly reduces synaptic release by depletingthe releasable pool of vesicles (Wang and Kaczmarek, 1998; Bellinghamand Walmsley, 1999). A decrease in release probability will decreasethe speed of vesicle depletion in the presynaptic terminals, andtherefore, the fifth/first EPSC ratio will increase. As shownin Figure 6A2, the fifth/first EPSC ratio was significantly increasedat 4 hr after ischemia (ANOVA; F = 12.57; df 2, 23; p < 0.001).In control conditions, the amplitude of the fifth EPSC was reducedto 28.7 ± 2.8% of the first one (n = 11). Four hours after reperfusion,the fifth EPSC was only reduced to 53.4 ± 8.2% of the initialEPSC (n = 7; post hoc Scheffe's test; p < 0.01). At 24 hr afterreperfusion, the fifth EPSC was reduced to 16.2 ± 4.6% of theinitial values, which was close to the control values. The aboveresults suggest that the releasing probability transiently decreased4-6 hr after ischemia.

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Figure 6. Comparison of EPSCs elicited by a train of high-frequency (100 Hz) stimulation and changes in NMDAR/AMPAR-mediated responses before and after ischemia. A1, Representative traces showing the synaptic responses induced by a train of five stimuli before ischemia and at 4 hr after reperfusion. The two traces were normalized to the same amplitude of the first EPSCs to show the difference in the fifth/first EPSC ratio between these traces (right). All traces are the average of six consecutive recordings. A2, Pooled data showing the changes in EPSCs during train stimuli. All amplitudes were normalized to the first EPSCs at each recording. The fifth/first EPSC ratio was significantly higher at 4 hr after ischemia compared with controls and at 24 hr after ischemia, suggesting that the releasing probability of LA neurons was transiently decreased shortly after ischemia. B, Parallel change in NMDAR-and AMPAR-mediated responses before and at 4 hr after ischemia. B1, left, Evoked EPSC in the presence of 20 µM BMI and 2 µM scopolamine (Scop.), at the holding potentials of $-$ 80 mV and +60 mV, respectively. Middle, Evoked AMPAR-mediated responses in the presence of BMI, scopolamine, and 50 nM D-APV. Right, top trace, The NMDAR-mediated response was obtained by subtracting the left two top traces. B2, left histogram, Parallel decrease in NMDAR- and AMPAR-mediated responses after ischemia. Right histogram, Comparison of NMDAR-mediated current with the AMPAR-mediated current ratio before and after ischemia. No significant difference in NMDA/AMPA ratio was detected between these two conditions. *p < 0.05; p < 0.01.

To further examine the involvement of a presynaptic mechanism in the changes in EPSCs after ischemia, the AMPAR- and NMDAR-mediatedresponses were compared before and after ischemia, because AMPARsand NMDARs are often colocalized at individual synapses. The changesin presynaptic transmitter release are expected to cause an equalincrease or decrease in the synaptic currents mediated by thesetwo receptor subtypes (Perkel and Nicoll, 1993; Liao et al., 1995;Malenka and Siegelbaum, 2001). With BMI- and scopolamine-containingmedium, NMDAR-mediated responses were obtained by subtractingthe responses at +60 mV with D-APV from those without D-APV (Fig.6B1). AMPAR-mediated responses were isolated in the presence ofBMI, scopolamine, and D-APV at a holding potential of $-$ 80 mV.At 4 hr after ischemia, NMDAR- and AMPAR-mediated EPSCs showedparallel decrease (NMDA: control, 201.89 ± 26.87 pA; ischemia,79.31 ± 23.72 pA; unpaired t test; p < 0.01) (AMPA: control, 181.28± 21.31 pA; ischemia, 77.07 ± 15.55 pA; p < 0.01). The ratio ofNMDAR-mediated EPSCs to AMPAR-mediated EPSCs was approximatelythe same before and after ischemia (Fig. 6B2). These data alsosupported a presynaptic mechanism in the decrease in AMPAR-mediatedresponses afterischemia.

Adenosine receptors and metabotropic glutamate receptors (mGluRs) have long been recognized to be associated with presynapticinhibition of transmitter release (Zhang and Schmidt, 1999). Toreveal the possible roles of these receptors in synaptic transmissionafter ischemia, the effects of the nonselective mGluR antagonistMCPG and the adenosine A1 receptor antagonist DPCPX on fast EPSCswere examined before and after ischemia. When MCPG (1 mM) andDPCPX (100 nM) were applied to control slices, no obvious changeswere found in the amplitude of EPSCs, indicating that no tonicinhibition was induced by endogenous mGluR and A1 receptor activationbefore ischemia. Four hours after ischemia, application of MCPGproduced no detectable changes, but application of DPCPX significantlyincreased the amplitude of evoked EPSCs (Fig. 7). The averageamplitude increased $<=$ 144 ± 2.1% after DPCPX application (n = 9;unpaired t test; p < 0.01) compared with the control one. However,application of DPCPX did not increase the amplitude of evokedEPSCs at 24 hr after ischemia. These data indicated that activationof the A1 receptor was involved in the reduction of fast EPSCsshortly after ischemia.

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Figure 7. Effects of mGluR and adenosine A1 receptor blockers on EPSCs in LA neurons. A, Effect of bath application of the mGluR blocker MCPG (1 mM) and the A1 receptor DPCPX (100 nM) on the amplitude of EPSCs 4 hr after ischemia. Application of MCPG has no effects on EPSC amplitude, whereas DPCPX significantly enhances the EPSCs. The insets are representative traces averaged from six recordings before and after DPCPX application. B, The plotting showing the effects of DPCPX on EPSCs before and after ischemia. DPCPX has no effect on EPSCs in control neurons but enhances the EPSCs of LA neurons 4 hr after ischemia. C, The plotting showing the effects of glybenclamide (10 µM) on the evoked EPSCs from LA neurons. Glybenclamide had no obvious effects on EPSCs before and after ischemia.

The decrease in excitatory transmission during energy depletion has been attributed, at least in part, to ATP-dependent potassiumchannels (K_ATP) (Ashcroft, 1988; Calabresi et al., 1997a). Toreveal the role of K_ATP in the changes in fast excitatory synaptictransmission after ischemia, the K_ATP channel blocker glybenclamide(10 µM) was applied to the medium, and no significant differencein EPSC amplitude was observed before and after ischemia (109.4± 0.8%, n = 9, controls; 101.6 ± 1.5%, n = 5, 4 hr after ischemia;95.9 ± 13.3%, n = 4, 24 hr after ischemia) (Fig. 7C).

Ultrastructural changes in presynaptic terminals of LA neurons

LA neurons receive excitatory inputs from the neocortex and thalamus (Lapper and Bolam, 1992). Certain neurons in the cortexand thalamus are vulnerable to transient cerebral ischemia (Pulsinelliet al., 1982). To investigate whether decreased EPSC amplitudeafter ischemia is caused by the degeneration of presynaptic terminals,the morphology of presynaptic terminals was examined at differentintervals after ischemia. Approximately 6 hr after ~22 min ofischemia, most of the small- to middle-sized neurons in the dorsalstriatum displayed shrunken and electron dense somata with manyvacuoles in the cytoplasm. Many swollen processes of astrocyteswere observed in the neuropil. The neurons with large somata,most likely LA neurons, remained intact at this time. Asymmetricalsynapses were found on the cell bodies or dendrites of large neurons.No degenerating signs were observed in most of these terminalsand their postsynaptic targets. A representative axosomatic synapseon a large neuron at 6 hr after ischemia is shown in Figure 8A.The postsynaptic membrane of this synapse had a prominent coatingof dense material on its cytoplasmic face, and the presynapticterminals contained a dense pack of small round vesicles, indicatingthat this is an asymmetrical synapse and is excitatory in nature.At 24 hr after ischemia, the small- to medium-sized neurons werefurther degenerated. The plasma membranes were ruptured, and theorganelles were collapsed. The only intact structures were thoseof ischemia-resistant interneurons, including LA neurons. Despitethe normal structure of dendrites and somata of these large neurons,some terminals making synaptic contacts on these neurons showeddegenerating signs. Some of these terminals were electron dense,and the fine structures within the terminals were obscured. Sometimesthe swollen vesicles were visible in these dark terminals (Fig.8B). Another type of degenerating terminal showed severely swollenstructures, but the presynaptic vesicles remained identifiable(Fig. 8C). To quantitatively compare the changes in presynapticterminals at different intervals after ischemia, a total of 497terminals at 6 hr after ischemia and 756 terminals at 24 hr afterischemia were analyzed. Within a unit area (42.3 µm²), the terminals with intact structures were 18.6 ± 0.5 per area,and the dark terminals were 7.5 ± 0.5 per area at 6 hr after ischemia(n = 19). No swollen terminals were observed at this time. Comparedwith those at 6 hr after ischemia, the number of intact terminalsat 24 hr after ischemia was decreased to 5.1 ± 0.8 per area (n= 25; unpaired t test; p < 0.01), the dark terminals were increasedto 19.5 ± 1.1 per area (p < 0.01), and the swollen terminals wereincreased to 5.6 ± 0.5 per area (p < 0.01). These changes representeda significant increase in degenerated terminals from 16% at 6hr after ischemia to 84% (20% swollen, 64% dark) at 24 hr afterischemia (Fig. 8D). The above ultrastructural studies indicatethat the neurons with large somata are resistant to transientcerebral ischemia, and most presynaptic terminals in the striatumremain intact at 4-6 hr after ischemia but show degenerating signsat 24 hr after reperfusion.

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Figure 8. Electron micrographs showing the changes in presynaptic terminals after ischemia. A, An electron micrograph taken from the dorsal striatum at 6 hr after ischemia showing an axosomatic synapse (arrow). The postsynaptic membrane is thicker than the presynaptic one, indicating that this is an asymmetrical synapse. The presynaptic terminal contains many round vesicles. The postsynaptic target is the soma of a large neuron, most likely a LA neuron, with intact cytoplasmic organelles. Next to this synapse are swollen processes of spiny neurons or astrocytes (asterisk). B, Electron micrograph showing the degenerating synapses in the dorsal striatum at 24 hr after ischemia. Two degenerating synapses are filled with electron-dense materials. The dense postsynaptic membrane of one synapse (arrow) is still visible, indicating that this is an asymmetrical synapse. The synaptic vesicles of the other dark terminal are swollen. C, Electron micrograph showing an example of another type of degenerating terminal in the striatum 24 hr after ischemia. The terminal is enlarged dramatically with swollen mitochondria (arrowhead). A cluster of presynaptic vesicles (arrow) is located in the center of the terminal. D, Quantitative comparison of presynaptic terminals in the dorsal striatum at 6 and 24 hr after ischemia. Left, Histogram showing the number of terminals counted in a unit area (42.3 µm²/field). Compared with that at 6 hr after ischemia, the number of terminals with normal appearances in a given area significantly decreases, and the number of degenerated terminals significantly increases at 24 hr after ischemia. No swollen terminals are observed at 6 hr after ischemia. Right, Comparison of percentage change of terminals in the dorsal striatum at different intervals after ischemia. The degenerated terminal significantly increases from 16% at 6 hr after ischemia to 84% at 24 hr after ischemia. *^,,#p < 0.01 compared with its counterpart at 6 hr after ischemia.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present study has shown that transient forebrain ischemia suppresses AMPAR-mediated EPSCs in LA neurons. Such suppressionresults from the alterations of presynaptic rather than postsynapticcomponents after ischemia. The decrease in release probabilitymediated by adenosine A1 receptors contributes, at least in part,to the reduction of EPSCs at 4-6 hr after ischemia, and the degenerationof presynaptic terminals is responsible for the reduction of EPSCsat late time points after reperfusion. The depression of excitatoryneurotransmission might be one of the mechanisms protecting LAneurons against transient globalischemia.

Several lines of evidence, based on studies of hippocampal neurons, suggest that enhancement of excitatory synaptic transmissionmight cause neuronal injury, and that suppression of excitatorysynaptic transmission might be neuroprotective after cerebralischemia. Evoked EPSPs in ischemia-vulnerable CA1 neurons arepotentiated after ischemia/hypoxia (Urban et al., 1989; Hori andCarpenter, 1994; Tsubokawa et al., 1994; Gao and Xu, 1996; Gaoet al., 1998a). In contrast, the slope and amplitude of EPSPsin ischemic-resistant CA3 neurons and dentate granule cells arereduced 12-36 hr after transient forebrain ischemia (Gao et al.,1998b). Further supporting the notion that synaptic depressionis associated with neuronal survival after ischemia, CA1 neuronsalso exhibit a depression of synaptic transmission after mildischemia (~5 min) that does not cause neuronal damage (Xu andPulsinelli, 1994, 1996). In the neostriatum, small- to medium-sizedneurons, most likely spiny neurons, die within 24 hr after transientforebrain ischemia, whereas interneurons, including LA neurons,survive (Francis and Pulsinelli, 1982; Pulsinelli et al., 1982;Chesselet et al., 1990). The incidence of polysynaptic EPSPs wassignificantly increased in spiny neurons after ~22 min of ischemia(Gajendiran et al., 2001), indicating the facilitation of excitatoryneurotransmission. When the ischemia duration was reduced to 5-8min, which does not produce cell death in the striatum, the synaptictransmission of spiny neurons was transiently depressed (Xu, 1995).Recent studies have shown that facilitation of synaptic transmissionin the form of LTP was induced from spiny neurons but not in LAneurons after deprivation of oxygen and glucose in vitro (Calabresiet al., 2002). Together with the above observations, the reductionof EPSCs in LA neurons after ischemia indicates that the depressionof excitatory neurotransmission also participates in neuroprotectionin the neostriatum after cerebralischemia.

Several mechanisms might be involved in the depression of synaptic transmission after ischemia: (1) a decrease in postsynapticresponsiveness after ischemia, which might be caused by the decreasedreceptor number or reduced receptor sensitivity, and (2) a reductionof presynaptic function, which might result from a decrease inrelease probability or in the number of active synapses. A differentialsensitivity of the presynaptic and postsynaptic component to ischemia/hypoxiahas been noticed for sometime. Because presynaptic impulses persisted,whereas postsynaptic potentials were depressed in the hippocampusby hypoxia, it was believed that hypoxia-induced synaptic depressionwas primarily caused by postsynaptic changes (Kass and Lipton,1982; Urban et al., 1989; Lee et al., 1991). However, studiesusing more sensitive techniques suggested that the hypoxia-induceddepression was caused by presynaptic alterations. The IPSPs andEPSPs were depressed during hypoxia without obvious change inpostsynaptic responses to focal application of GABA or quisqualicacid (Krnjevic et al., 1991; Rosen and Morris, 1993), and themean amplitude of spontaneous miniature EPSCs was not affectedby hypoxia at a time when the evoked synaptic responses were almostcompletely inhibited (Hershkowitz et al., 1993). In the presentstudy, several lines of evidence indicate that postsynaptic mechanismsare not involved in the reduction of EPSCs after ischemia. First,the amplitude of AMPAR-mediated EPSCs in LA neurons was significantlyreduced by $<=$ 24 hr after ischemia, whereas the response to exogenousglutamate remained the same as that before ischemia. Second, thedesensitization character of AMPARs does not change after ischemia,because application of CTZ, an agent that selectively blocks AMPARdesensitization (Bertolino et al., 1993), had similar potencyon EPSCs of control as well as ischemic neurons. Third, the decaytime constant of EPSCs after ischemia was the same as that ofcontrol neurons, further suggesting that the desensitization ofAMPARs does not contribute to the reduction of EPSCs in LA neuronsafter ischemia. However, evidence strongly indicates that thepresynaptic release probability has been transiently altered andis responsible for the reduction of EPSCs after ischemia. High-frequencystimulation depletes the release pool of synaptic terminals sothat the amplitude of consecutive EPSCs progressively decreases(Wang and Kaczmarek, 1998; Bellingham and Walmsley, 1999; Scheusset al., 2002). The alteration of fifth/first EPSC ratio in differentexperimental conditions suggests the change in release probability.The high (or low) release probability results in fast (or slow)depletion of the releasing pool and, therefore, the low (or high)fifth/first EPSC ratio. The fifth/first EPSC ratio of LA neuronsat 4-6 hr after ischemia was significantly higher than those ofcontrols and at 24 hr after reperfusion, suggesting that the releaseprobability transiently decreases shortly after ischemia. Despitethe fact that the paired-pulse experiment with an interstimulusinterval of 50 msec failed to show a significant change in PPRafter ischemia, the ratio of second/first EPSC in high-frequencytrain stimulation (interstimulus interval of 10 msec) at 4 hrafter ischemia was significantly higher than that seen for controlsand at 24 hr after ischemia (Fig. 6A2). In addition, a paralleldecrease in NMDAR- and AMPAR-mediated responses was observed afterischemia, indicating the decrease in transmitter release frompresynaptic terminals 4 hr after ischemia. However, the presentstudy could not exclude other presynaptic or postsynaptic factorsthat might also contribute to this short-term plasticity (Scheusset al., 2002).

Adenosine is a modulator that has broad actions on neuronal activities (Song et al., 2000; Dunwiddie and Masino, 2001). Ithas inhibitory effects on the release of neurotransmitter, especiallyin glutamatergic systems (Dunwiddie and Hoffer, 1980; Kocsis etal., 1984). Extracellular adenosine significantly increases afterischemia/hypoxia (Winn et al., 1979; Latini et al., 1998), andactivation of A1 receptors plays an important role in the depressionof excitatory synaptic transmission after ischemia (Fowler, 1989;Katchman and Hershkowitz, 1993; Tanaka et al., 2001), which offersneuroprotection against the insult (Hsu et al., 1994; Mitchellet al., 1995). In the present study, the A1 receptor antagonistDPCPX had no effects on EPSCs in control conditions but stronglyfacilitated the EPSCs of LA neurons at 4-6 hr after ischemia,suggesting that by activation of A1 receptors, adenosine contributes,at least in part, to the reduction of EPSCs in LA neurons at earlytime points after ischemia. The inhibitory effects of adenosineon spiny neurons have also been reported in corticostriatal synapsesand in GABAergic synapses during anoxia/aglycemia (Calabresi etal., 1997a,b; Centonze et al., 2001). However, different fromthe present study, these authors have shown that adenosine hasendogenous tonic inhibition in control conditions, and paired-pulsefacilitation has been observed in these studies. Besides the differencein cell type, one of the possible explanations for these discrepanciesis the difference in afferent fiber pathway. LA neurons are predominantlyinnervated by fibers from the thalamus (Lapper and Bolam, 1992).Thus, the EPSCs in the present study are mediated primarily bythalamostriatal synapses, whereas the synaptic transmission inother studies is mediated by corticostriatal or GABAergicsynapses.

Based on the above observations, transient changes in presynaptic components, most likely by activation of adenosine A1 receptors,may account for the reduction of EPSCs in LA neurons at 4-6 hrafter ischemia. However, the amplitude of EPSCs remained reducedat 24 hr after ischemia, whereas the release probability returnedto control levels, suggesting that other mechanisms must be involvedin the synaptic depression at late time points after reperfusion.The excitatory inputs to LA neurons are from the cerebral cortexand thalamus (Lapper and Bolam, 1992). The neurons in the cortexand thalamus die within 24 hr after ~15 min of forebrain ischemia(Pulsinelli et al., 1982). The forebrain ischemia induced in thepresent study lasts for ~22 min, and the ischemia-vulnerable neuronsin the cortex and thalamus certainly have died at 24 hr afterreperfusion. EM examination has found that most of the presynapticterminals in the striatum are degenerated at 24 hr after ischemia,suggesting that the reduction in excitatory inputs attributableto degeneration of presynaptic terminals is the major cause ofEPSC reduction in LA neurons at 24 hr after ischemia. The ultrastructureof most presynaptic terminals remains intact at 4-6 hr after ischemia,suggesting that the reduction of EPSCs in LA neurons at earlytime points after ischemia is primarily caused by the transientmalfunction of the presynaptic components rather than the structuraldamages.

  FOOTNOTES

Received May 9, 2002; revised Sept. 11, 2002; accepted Oct. 1, 2002.

This work was supported by National Institutes of Health/National Institute of Neurological Disorders and Stroke Grant NS38053.Z.-P.P. and P.D. are recipients of American Heart Associationpostdoctoral fellowships. We thank Dr. Yuan Fan for helpfuldiscussions.

Correspondence should be addressed to Dr. Zao C. Xu, Department of Anatomy and Cell Biology, Indiana University School ofMedicine, 635 Barnhill Drive, MS 507, Indianapolis, IN 46202.E-mail: zxu{at}anatomy.iupui.edu.

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