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Electrodes and electrode placement After the slices were allowed to incubate for at least 1.5 hr, monopolar stimulating electrodes (Teflon-insulated stainless steel wire; diameter, 25 µm) exposed only at the tip were placed on the surface of the slice in the outer and middle thirds of the molecular layer of the suprapyramidal (hidden) blade of the dentate gyrus for selective stimulation of the lateral (LPP) and medial perforant path (MPP), respectively (Dahl and Sarvey, 1989
Volume 16, Number 24, Issue of December 15, 1996 pp. 8123-8131
Copyright ©1996 Society for NeuroscienceEndogenous Activation of µ and
-1 Opioid Receptors Is Required for Long-Term Potentiation Induction in the Lateral Perforant Path: Dependence on GABAergic Inhibition
Clive R. Bramham and John M. Sarvey Department of Pharmacology, Uniformed Services University of the Health Sciences, Bethesda, Maryland 20814-4799
ABSTRACT
Opioid peptides costored with glutamate have emerged as powerful regulators of long-term potentiation (LTP) induction in several hippocampal pathways. The objectives of the present study were twofold: (1) to identify which opioid receptor types (µ,
Key words: long-term potentiation; synaptic plasticity; opioid receptor; dentate gyrus; NMDA receptor; hippocampus, or
) regulate LTP induction at lateral perforant path-granule cell synapses and (2) to test the hypothesis that endogenous opioids regulate LTP induction via modulation of GABAergic inhibition. LTP of lateral perforant path-evoked field EPSPs was induced selectively by high-frequency stimulation applied to the outer third of the molecular layer of the dentate gyrus of rat hippocampal slices. No changes in medial perforant path responses occurred. LTP was blocked when high-frequency stimulation was applied in the presence of the µ receptor antagonist CTAP, the selective
INTRODUCTION
Opioid receptor-dependent long-term potentiation (LTP) provides perhaps the most clear-cut example of neuropeptide regulation of synaptic plasticity in the mammalian brain (Bramham, 1992
; Bliss and Collingridge, 1993
The types of opioid receptor that regulate LTP of the enkephalinergic LPP-granule cell pathway are currently an issue of debate. We reported previously that a selective
The mechanism by which endogenous opioids facilitate LTP in the LPP is unknown. Exogenously applied µ and
The main goals of the study were twofold: (1) to identify the opioid receptor types regulating LTP in the LPP using highly selective antagonists at pharmacologically relevant concentrations and (2) to determine whether or not endogenous opioids act via modulation of GABAergic inhibition. The latter was tested by comparing the effect of naloxone on LTP induction in control slices and disinhibited slices treated with picrotoxin, a GABAA channel blocker. If the disinhibition hypothesis is correct, pharmacological suppression of GABA-mediated inhibition would be expected to obviate the need for opioids.
A potential problem that we wanted to avoid in the present study was cross-stimulation of medial perforant path (MPP) fibers that border on the LPP in the outer molecular layer. We have, therefore, used very low stimulus intensities to induce LTP in the LPP and monitored pathway selectivity in all experiments by parallel recording of LPP and MPP-evoked fEPSPs across a range of low stimulus intensities.
A preliminary account of this work has been reported (Bramham and Sarvey, 1994
MATERIALS AND METHODS
Preparation of hippocampal slices Male Sprague Dawley rats (Taconic, Germantown, NY) weighing between 75 and 200 gm were anesthetized with ketamine hydrochloride (100-200 mg/kg, i.p.). After decapitation, the brain was removed rapidly and placed in a Petri dish containing ice-cold artificial cerebrospinal fluid (ACSF) of the following composition (in mM): NaCl 125, KCl 3, CaCl2 2.4, NaH2PO4 1.2, MgSO4 1.3, NaHCO3 26, and dextrose 10 bubbled continuously with a gas mixture of 95% 02/5% CO2. The hippocampus was rapidly dissected free, and transverse slices (400 µm thick) from the mid-dorsal hippocampus were cut on a McIlwain tissue chopper and transferred by paint brush to a modified Oslo interface chamber. The recording stage of the chamber consisted of a nylon mesh support overlaid with fine-grained filter paper for greater stability of recording. Slices were perfused continuously with bubbled ACSF at a rate of 3 ml/min (Gilson Minipuls 2 peristaltic pump) and maintained at 31.5°C. In experiments involving picrotoxin (PTX) perfusion the MgSO4 concentration was raised to 4 mM, and in most slices the CA3 region was cut away before the slices were chopped. PTX-containing buffer was perfused continuously, starting 65 min before collection of baseline responses.) filled with 2 M NaCl. The recording electrodes were placed at least 500 µm from the stimulating electrodes along the trajectory of the perforant path fibers, and the distance between the electrode pairs in the middle and outer molecular layers was ~150 µm. Recording electrodes were lowered to a distance of 80-100 µm beneath the slice surface. Tests for assessing selective stimulation of the LPP and MPP The close proximity of the LPP and MPP fiber tracts in the molecular layer makes it important to ascertain the selectivity of stimulation, because cross-stimulation could occur. The positions of the stimulating and recording electrodes were adjusted to obtain maximal selectivity of stimulation, as described previously (Dahl and Sarvey, 1989
Depth profile. First, the fEPSP elicited by stimulation of the LPP or MPP should reverse polarity across the outer and middle third of the molecular layer. Thus, stimulation in one zone of the molecular layer should evoke a negative-going fEPSP in that layer, reflecting an inward current sink, and a positive-going potential in the other layer, reflecting an outward current source. The sharp polarity reversal of the waveforms over a distance of 150 µm indicates a highly focal stimulation of LPP and MPP fibers.
Paired-pulse facilitation. The LPP exhibits paired-pulse facilitation of the fEPSP peak amplitude at interpulse intervals where the MPP-evoked fEPSP fails to show facilitation, thus providing a means to distinguish operationally between the two pathways (McNaughton, 1980 9.42 ± 6.4%, respectively (see Table 1).
Table 1. Effect of picrotoxin on paired-pulse inhibition and facilitation in the LPP and MPP
20 msec IPI 80 msec IPI CON PTX CON PTX MPP 0.48 ± 3.3 LPP 9.76 ± 5.1 5.53 ± 6.6 32.1 ± 3.1 16.7 ± 2.8a Percentage change ± SEM in fEPSP amplitude relative to conditioning pulse. a Significant difference from control group (t test independent samples, p < 0.01.) Control, n = 8; picrotoxin (PTX), n = 9. IPI, Interpulse interval. Experimental protocol LPP and MPP fEPSPs were obtained at regular intervals for constructing both input-output curves (plots of the fEPSP slope as a function of stimulus strength) and time course plots on the basis of test pulses of constant stimulus strength. After stable fEPSPs were monitored for 30 min, an input-output curve was collected, followed by 20 min of recording at the test pulse intensity. Experimental groups then received drug-containing ACSF, and controls received ACSF only. Test responses were collected during the first 20 min of drug perfusion, followed by an input-output curve during the next 5 min. High-frequency stimulation (HFS; 100 Hz, 1 sec) then was applied to the LPP. Test responses were collected for 45 min, and an input-output curve was obtained 40 min post-HFS. Standard ACSF was reintroduced 3 min post-HFS.
Effect of L-amino-2-phosphonobutyrate (L-AP4). A final test of selectivity performed in three slices was pharmacological. Previous in vitro and in vivo studies have shown that L-AP4, which stimulates L-AP4 glutamate receptors, selectively inhibits LPP-evoked fEPSPs (Koerner and Cotman, 1981 Drugs The following drugs were used: D(
Input-output curves were considered a reliable method of assessing the selectivity of LTP induction in the LPP. Averaged responses (2 sweeps) were collected at six stimulus pulse durations. The stimulus pulse durations were selected in each slice to elicit fEPSPs ranging from just above threshold to a near-maximal fEPSP slope. These durations were 20, 30, 40, 50, 70, and 90 µsec above the fEPSP threshold. Current intensity was kept constant in each slice and ranged from 5 to 40 µA across slices. Stimulus pulse durations across slices ranged from 20 to 50 µsec at the lowest pulse duration and from 80 to 110 µsec at the highest duration. The pulse duration for test pulses and paired-pulse tests was set at either 30 or 40 µsec above the fEPSP threshold. This pulse duration corresponded to the steepest part of the input-output curve for each slice and was considered to afford maximal sensitivity in detecting fEPSP slope changes. The stimulus strength for HFS of the LPP was set to evoke a maximal fEPSP slope; this intensity was at least 50 µA below the population spike threshold. The threshold for eliciting a population spike in the LPP is much higher than in the MPP. As recorded in the granule cell layer, the LPP-evoked population spike typically appears on the descending phase of the positive field potential at intensities near 100 µA, 100 µsec. Preliminary experiments showed that HFS applied at intensities above the population spike threshold frequently resulted in cross-stimulation of the MPP, with LTP occurring in both pathways. Thus, low intensity stimulation was critical for obtaining selective LTP of the LPP. Data analysis and statistics The signals were amplified, filtered (from 1 Hz to 10 kHz), digitized at 20 kHz (DAS-20 interface, Keithley Metrabyte, Taunton, MA), and stored to disk for off-line analysis with Labman software (kind gift of Dr. T. Teyler, NeuroScientific Laboratories, Rootstown, OH). The initial slope of the fEPSP was used as a measure of synaptic efficacy. Slope values were normalized in each slice relative to the maximum fEPSP slope on the input-output curve collected immediately before HFS. Statistical analysis of drug and HFS effects was based on the raw input-output data and consisted of a within-group two-way ANOVA for repeated measures, followed by a post hoc Scheffé's test (STATISTICA package, StatSoft, Tulsa, OK). A probability of 0.05 was chosen as the level of statistical significance. For the time course plots, fEPSP slope values are expressed in percentage of baseline (all 12 pre-HFS responses). The magnitude of LTP was calculated as the mean percentage of increase above baseline for the last six time points in the time course (from 15 to 45 min post-HFS).
All drugs were dissolved in saline, and concentrated stock solutions were aliquoted in single doses, stored at
RESULTS
Selective induction of LTP in the LPP
Criteria used to assess selectivity of stimulation in response to single test pulses are described in Materials and Methods. The effect of HFS of the outer molecular layer on LPP and MPP-evoked fEPSPs is shown in input-output curves in Figure 1, and the time course plots are given in Figure 2A,B. HFS of the LPP in slices receiving standard ACSF evoked a robust increase in the LPP-evoked fEPSPs (n = 8; p < 0.05, ANOVA and post hoc Scheffé's) but had no significant effect on MPP responses recorded from the same slices (p > 0.05). Thus, LTP was induced selectively in the LPP with no significant cross-stimulation of MPP fibers or induction of heterosynaptic effects.
Fig. 1. Selective induction of LTP in the LPP. A, Representative input-output curves on the basis of LPP and MPP responses obtained before and 40 min after HFS of the LPP. The fEPSP slope is plotted as a function of stimulus pulse duration. Response averages (2 sweeps/average) were collected at six stimulus pulse durations ranging from 20 µsec above fEPSP threshold to 90 µsec above threshold (near the maximum fEPSP slope). B, Field potential traces used to derive input-output curves in A. C, Control group input-output curves. Input-output curves were obtained during perfusion with standard ACSF (baseline 1, dotted line), 20 min after further perfusion in ACSF (baseline 2, solid line), and 40 min after HFS (post-HFS, dashed line) applied to the LPP. fEPSP slope values from each slice are normalized relative to the maximum value on the baseline 2 input-output curve collected immediately before HFS. Plots are mean ± SEM (n = 8). Inset shows representative traces taken before (solid line) and after (dashed line) HFS. Horizontal bar, 2 msec; vertical bar, 3 mV.
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Fig. 2. Activation of µ and
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Endogenous activation of µ and
The effects of selective opioid receptor antagonists on LTP induction in the LPP are shown in input-output curves (Fig. 2A) and time course plots (Fig. 2B). No significant change in LPP fEPSPs occurred when HFS was applied in the presence of CTAP, a selective µ receptor antagonist, or BNTX (n = 5; 100 nM), a selectiveEffect of picrotoxin on paired-pulse inhibition and facilitation in the LPP and MPP
Consistent with a loss of GABA-mediated inhibition, slices continuously perfused with ACSF containing PTX (50 µM) exhibited a loss of paired-pulse inhibition of the population spike at the 20 msec interpulse interval in the both the LPP and MPP. At high stimulus intensities (typically 100 µA, 100 µsec) this hyperexcitability manifested as multiple population spikes. However, at the low intensities used for eliciting fEPSPs in this study, no polysynaptic activity could be detected during the paired-pulse tests or the subsequent LTP experiments (see traces in Fig. 3A,B). The effects of PTX on paired-pulse tests for the fEPSP are summarized in Table 1. In the LPP at the 80 msec interpulse interval the percentage of facilitation of the fEPSP amplitude was reduced significantly from 32.1 ± 3.1% in controls to 16.7 ± 2.8% in PTX-treated slices (t test independent samples, p < 0.01). PTX had no effect on paired-pulse responses in the LPP at the 20 msec interpulse interval and no effect on MPP-evoked fEPSPs at either interpulse interval. The results indicate that PTX strongly suppresses paired-pulse inhibition of the population spike in both pathways while selectively attenuating paired-pulse facilitation of the LPP-evoked fEPSP.
Fig. 3. Opioid peptides regulate LTP induction by a mechanism that depends on GABAergic inhibition. A, HFS was applied in the presence of standard ACSF (control; n = 8) or ACSF containing picrotoxin (PTX, 50 µM; n = 4). Input-output curves were obtained during perfusion with standard or PTX containing ACSF (baseline 1, dotted line), 20 min after further perfusion in this medium (baseline 2, solid line), and 40 min after HFS (post-HFS, dashed line) applied to the LPP. B, HFS was applied in the presence of naloxone (NLX, 5 µM) in slices continuously perfused with standard ACSF (n = 8) or PTX containing ACSF (n = 5). Plots are input-output curves obtained during perfusion with standard or PTX containing ACSF (predrug, dotted line), 20 min after addition of naloxone (drug baseline, solid line), and 40 min after HFS (post-HFS, dashed line). PTX perfusion commenced 80 min before the addition of naloxone. Inset shows representative traces taken before (solid line) and 40 min post-HFS (dashed line). All input-output curves are group mean ± SEM of fEPSP slope values normalized relative to the maximum value of the input-output curve collected immediately before HFS. Horizontal bar, 2 msec; vertical bar, 3 mV. C, Time course of changes in LPP-evoked fEPSPs. Plots are group mean ± SEM changes in fEPSP slope expressed in percentage of baseline. The period of drug perfusion is indicated by the stippled bar, and delivery of HFS to the LPP is indicated by an arrow. Perfusion with PTX abolished the ability of naloxone to block LTP. D, Time course of changes in MPP-evoked fEPSPs after HFS of the LPP in the presence of naloxone in slices perfused in standard ACSF or PTX containing ACSF. Note that LTP was induced selectively in LPP fibers in PTX-containing medium.
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The mechanism of opioid receptor-dependent LTP depends on GABAergic inhibition
The role of GABAergic inhibition in opioid receptor-dependent LTP was investigated by comparing the effect of naloxone on LTP induction in slices maintained in standard buffer and PTX-containing buffer. PTX perfusion commenced 80 min before the addition of naloxone. As expected, naloxone (5 µM) blocked LTP induction in standard medium. In dramatic contrast to this, naloxone had no effect on LTP in PTX-treated, disinhibited slices. Similar results were obtained in input-output curve (Fig. 3A,B) and time course data (Fig. 3C). The failure of naloxone to block LTP was not attributable to removal of the CA3 region in PTX-treated slices, because the same effect was obtained in intact slices. Control experiments showed that PTX treatment did not affect the amount of LTP obtained; the magnitude of LTP measured in time course plots was 49.5 ± 6.7% in standard ACSF and 55.6 ± 6.6% in PTX-containing ACSF (Fig. 3C). MPP-evoked fEPSPs were not affected significantly by HFS of the LPP in the presence of PTX (Fig. 3D), showing that LTP remained pathway-specific in the disinhibited slice.LTP induction in the LPP of hippocampal slices is NMDA receptor-dependent
As shown in Figure 4, LTP induction was blocked completely when HFS was applied in the presence of the NMDA receptor antagonist AP5 (20 µM; n = 8). Thus, LPP LTP is both NMDA and opioid receptor-dependent in hippocampal slices. Finally, AP5 also was found to block LTP in two slices perfused with PTX, indicating that, under conditions in which opioid receptors are not required, LTP remains completely NMDA receptor-dependent.
Fig. 4. NMDA receptor activation is required to induce LTP of LPP-evoked fEPSPs in both standard and PTX-containing medium. HFS was applied in the presence of AP5 (20 µM) in slices perfused with standard ACSF (n = 9) or PTX containing ACSF (n = 2). Input-output curves were obtained during perfusion with standard or PTX containing ACSF (baseline, dotted line), 20 min after addition of AP5 (drug baseline, solid line), and 40 min after HFS (post-HFS, dashed line). Plots are group mean ± SEM of fEPSP slope values normalized relative to the maximum value of the input-output curve collected immediately before HFS. PTX perfusion commenced 80 min before the addition of AP5. Inset shows representative traces taken before (solid line) and 40 min post-HFS (dashed line). Horizontal bar, 2 msec; vertical bar, 3 mV.
[View Larger Version of this Image (20K GIF file)]
DISCUSSION
We have used methods for selective stimulation and recording of LPP and MPP-evoked synaptic potentials in the dentate gyrus to identify which types of opioid receptor regulate LTP induction in the LPP and to investigate the role of GABAergic inhibition. The novel findings of the study include the following: (1) endogenous activation of µ andEndogenous activation of both µ and
On the basis of the effects of highly selective µ (CTAP) andLack of a role for
Studies in the guinea pig have led to the proposal that dynorphin released from granule cell dendrites during HFS of the perforant path acts on presynapticEvidence that opioid receptor-dependent LTP is regulated by GABAergic inhibition
One straightforward hypothesis for opioid receptor-dependent LTP is that opioid peptides released during HFS cause a transient suppression of GABA-mediated inhibition. The loss of inhibition would boost postsynaptic depolarization on granule cells, enabling voltage-dependent effects such as NMDA receptor activation at LPP-granule cell synapses. Figure 5 shows a schematic depiction of the ``disinhibition hypothesis'' of opioid receptor-dependent LTP. If endogenous opioids control LTP by suppressing GABAergic inhibition, then pharmacological suppression of GABA-mediated inhibition would be expected to obviate the need for opioids. The present results strongly support the disinhibition hypothesis; naloxone blocked LTP under normal conditions but failed to block LTP in disinhibited slices. One mechanism by which the disinhibition could be targeted to the LPP is if enkephalins act locally on GABA terminals to inhibit GABA release, as suggested by recent anatomical data (Commons and Milner, 1996b
Fig. 5. Schematic depiction of the disinhibition hypothesis of opioid receptor-dependent LTP. During HFS, enkephalins and glutamate are co-released from terminals of the LPP. Enkephalins activate µ- and
[View Larger Version of this Image (16K GIF file)]
Failure of naloxone to block LTP in the LPP also has been reported to occur in PTX-treated guinea pig hippocampal slices (Hanse and Gustafsson, 1992
Although enkephalin effects on interneurons offer the most parsimonious explanation for the present findings, we cannot rule out a direct action of enkephalins on the glutamatergic nerve terminal or granule cell dendrite. Indeed, a subpopulation of The NMDA receptor controversy: a matter of in vitro versus in vivo?
In agreement with previous work in standard (Xie and Lewis, 1991
We would like to emphasize differences between in vitro and in vivo preparations that may help to resolve this controversy. First, electrophysiological and anatomical evidence suggests that the inhibitory network is compromised in hippocampal slices (Halasy and Somogyi, 1993 Perspectives
In the LPP of the rat hippocampal slice, LTP induction seems to be controlled by µ and
FOOTNOTES
Received July 29, 1996; revised Sept. 24, 1996; accepted Sept. 26, 1996.
This work was supported by National Institutes of Health Grant NS23865 to J.M.S. We thank K. Commons for insightful discussions during the preparation of this manuscript and R. Berry, K. Pang, B. Srebro, and P. Voulalas for critical comments during the course of this work.
Correspondence should be addressed to Dr. John M. Sarvey, Department of Pharmacology, Uniformed Services University of the Health Sciences, 4301 Jones Bridge Road, Bethesda, MD 20814-4799.
Dr. Bramham's present address: Department of Physiology, University of Bergen, Årstadveien 19, N-5009 Bergen, Norway.
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