Long-Term Potentiation of Synaptic Transmission in the Avian Hippocampus

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The Journal of Neuroscience, February 15, 1998, 18(4):1207-1216

Long-Term Potentiation of Synaptic Transmission in the Avian Hippocampus
Troy W. Margrie¹, John A. P. Rostas¹, and Pankaj Sah²
The Neuroscience Group and the ¹ Disciplines of Medical Biochemistry and ² Human Physiology, Faculty of Medicine and Health Sciences, University of Newcastle, Callaghan NSW, 2308, Australia

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The avian hippocampus plays a pivotal role in memory required for spatial navigation and food storing. Here we have examinedsynaptic transmission and plasticity within the hippocampal formationof the domestic chicken using an in vitro slice preparation. Withthe use of sharp microelectrodes we have shown that excitatorysynaptic inputs in this structure are glutamatergic and activateboth NMDA- and AMPA-type receptors on the postsynaptic membrane.In response to tetanic stimulation, the EPSP displayed a robustlong-term potentiation (LTP) lasting >1 hr. This LTP was unaffectedby blockade of NMDA receptors or chelation of postsynaptic calcium.Application of forskolin increased the EPSP and reduced paired-pulsefacilitation (PPF), indicating an increase in release probability.In contrast, LTP was not associated with a change in the PPF ratio.Induction of LTP did not occlude the effects of forskolin. Thus,in contrast to NMDA receptor-independent LTP in the mammalianbrain, LTP in the chicken hippocampus is not attributable to achange in the probability of transmitter release and does notrequire activation of adenylyl cyclase. These findings indicatethat a novel form of synaptic plasticity might underlie learningin the avian hippocampus.

Key words: calcium; plasticity; NMDA; memory; forskolin; PPF; cAMP

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Activity-dependent changes in synaptic transmission are thought to be the cellular correlates of learning and memory in theCNS (Hebb, 1949; Squire, 1987). In the mammalian brain, the hippocampusplays a fundamental role in some forms of learning, and severalforms of synaptic plasticity have been described at excitatorysynapses within this structure (Malenka, 1994). The most intensivelystudied and best understood form of plasticity in the hippocampusis long-term potentiation (LTP), of which two distinct types existat synapses in the mammalian hippocampus (Bliss and Collingridge,1993; Nicoll and Malenka, 1995). The induction of LTP in areaCA1 demonstrates a dependence on NMDA receptor activation anda subsequent rise in postsynaptic calcium. By contrast, LTP atthe mossy fiber/CA3 synapse is attributable to activation of presynapticadenylyl cyclase, and its induction is NMDA receptor independent(Nicoll and Malenka, 1995).

Neuroethological studies have shown that the avian hippocampus plays a pivotal role in particular types of learning (Sherryet al., 1992; Clayton and Krebs, 1995). The volume of the hippocampusis relatively larger in food-storing than in nonfood-storing birds(Krebs et al., 1989; Hampton et al., 1995), and the developmentof food storing is correlated with growth of the hippocampus (Barnea,1994; Clayton, 1995). Retrieval of stored food is adversely affectedby lesions of the hippocampus (Patel et al., 1997). Homing performanceof pigeons is significantly reduced by hippocampal lesion (Bingmanand Yates, 1992), as is their performance on a sun compass-basedspatial learning task (Bingman and Jones, 1994). In addition,the chicken hippocampus has also been implicated in recall ofa passive avoidance task (Sandi et al., 1992). Thus, like itsmammalian counterpart, the avian hippocampal formation is a keyneuroanatomical structure involved in spatial and perhaps othertypes of memories.

Behavioral studies have suggested a functional similarity between the mammalian and avian hippocampus (Bingman et al., 1989;Krebs et al., 1989, and immunohistochemical studies reveal anabundance of homologous transmitters and related substances (Erichsenet al., 1991; Krebs et al., 1991; Veeman et al., 1994). However,some disagreement still remains concerning the degree of homologyof the hippocampal formation between the two classes (Ramon yCajal, 1911; Mollà et al., 1986). Because much about the physiologyof synapses and the mechanisms underlying neuronal plasticitywithin this structure in the avian brain is still unknown (Wieraszkoand Ball, 1993), an important question to ask is whether synapseswithin the avian hippocampus display forms of plasticity, suchas LTP. In this study, using intracellular recording techniquesin an in vitro slice preparation, we have investigated the mechanismsunderlying LTP at synapses within the hippocampal formation ofthe adult domestic chicken.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation. Adult chickens (older than 10 weeks of age) were anesthetized with intraperitoneal pentobarbitone and decapitated,and the brain was removed rapidly and immersed in ice-cold Ringer'ssolution. All experimental procedures were in accordance withthe guidelines of the University of Newcastle Animal Ethics andCare Committee. Coronal sections 400 µm thick containing the hippocampuswere cut on a vibratome [corresponding approximately to platesA 6.0 to A 8.6 of Kuenzel and Masson (1988)]. Slices were allowedto equilibrate in Ringer's solution at room temperature or 32°Cfor at least 1 hr, after which single slices were transferredto a recording chamber. Slices were immobilized with a flattenedpiece of platinum wire (outer diameter 0.5 mm) across which stretcheda "laddered" nylon stocking glued with cyanoacrylic glue. Sliceswere superfused with a Ringer's solution containing (in mM): 119NaCl, 2.5 KCl, 1.3 MgCl₂, 4.5 CaCl₂, 1.0 Na₂PO₄, 26.2 NaH₂CO₃,10 glucose, equilibrated with 95% O₂/5% CO₂ to maintain a pH of7.4. The zero Ca²⁺ Ringer's solution contained no calcium, 200 µM EGTA, and 6.5mM MgCl₂.

Electrophysiology. Intracellular recordings were made with sharp microelectrodes that had resistances of 50-120 M $Omega$ when filledwith 1 or 3 M KCl, 1 M CsCl, or 1 M KMeSO₄, pH 7.4. Microelectrodeswere fabricated on a Flaming-Brown microelectrode puller (P-87).Signals were amplified using an Axoclamp2A amplifier (Axon Instruments,Foster City, CA), filtered at 1 kHz, and digitized at 5 kHz usingsoftware (Neurosense) written under LabView for Windows (NationalInstruments). Input resistance was monitored continuously throughouteach experiment. In experiments in which LTP was studied, electrodeswere filled with KCl because they were found to be more stable.To measure the slope of the EPSP, two cursors were placed at theinitial rising phase of the EPSP, and the slope between thesetwo cursors was calculated. As with KCl-filled electrodes, GABA_A-mediatedinhibitory potentials were reversed, picrotoxin (25 µM) was addedto block them. When we tested for the presence of NMDA receptor-mediatedEPSPs, electrodes were filled with CsCl to reduce outward currentsand facilitate membrane depolarization. Only cells with membranepotentials more negative than $-$ 50 mV were included in this study.For loading cells with 1,2 bis(o-aminophenoxy)-ethane-N,N,N',N'-tetra-aceticacid (BAPTA), electrode tips were filled with 200 mM BAPTA in1 M KCl and 10 mM HEPES, pH 7.4, with KOH. Bipolar, stainlesssteel stimulation electrodes (Fredrick Haer) were insulated exceptat their tips and placed superior and inferior to the recordingelectrode (see Fig. 1A). Afferent fibers were stimulated usinga constant current stimulator (Axon Instruments). Stimuli typicallywere 0.5-2.0 mA and 20-40 µsec in duration. For baseline measurements,afferent fibers were stimulated at 0.1 Hz. LTP was generated byactivating the fibers at 100 Hz for 1 sec, repeated twice withan interval of 20 sec. Under control conditions, LTP was observedin 26 of 31 cells in which it was attempted (84%). During 1 yearof experiments, there was a period of 2 months during which LTPwas seen in only 1 of 21 cells in which it was attempted. Thesecells have not been included in our analysis.

For intracellular staining, electrode tips were loaded with biocytin (4% in 1 M KCl in 10 mM HEPES buffer, pH 7.4) by capillaryaction and then backfilled with 1 M KCl. All experiments wereperformed at room temperature. Sweep data shown are averages of5-10 individual traces. All values are expressed as mean ± SEM,and levels of statistical significance were determined by pairedStudent's t test.

Drugs used were 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), bicuculline methiodide (Tocris Neuramin), 1,9-dideoxyforskolin,2-amino-5-phosphonovalerate (D-APV) (RBI Research Chemicals),forskolin, biocytin (Sigma), and BAPTA (Molecular Probes, Eugene,OR). Stock solutions of 1,9-dideoxyforskolin and forskolin weremade up in dimethyl sulfoxide.

Histology. After the experiment, slices were fixed in 4% paraformaldehyde overnight. They were then permeabilized in 0.5%Triton X-100 and incubated overnight in avidin-horseradish peroxidase(ABC-Elite, Vectastain), washed again, and visualized using 3,3'-diaminobenzidineas a chromogen with nickel/cobalt intensification. Sections werethen dehydrated in ethanol, cleared in xylene, and coverslipped.Labeled cells were visualized at a final magnification of 400×and reconstructed with the aid of a camera lucida drawing tube.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Intracellular recordings were made from neurons in the middle third of the hippocampus in coronal brain slices maintainedin vitro (Fig. 1A, hatched region). We filled and recovered 22neurons. Of these, 18 of 22 were spiny, long-axon multipolar neurons(Fig. 1B,C), three were short-axon multipolar neurons, and onewas a horizontal neuron, according to the classification of Mollàet al. (1986). The average resting potential was $-$ 59 ± 1 mV (n= 30).

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Figure 1. Tissue preparation and cell types in the chicken hippocampus. A, Schematic diagram of a coronal slice of chicken brain illustratingthe location of the hippocampus and the position of stimulatingand recording electrodes. Stimulating electrodes were placed superior(Stim 1) and inferior (Stim 2) to the recording electrode, whichwas placed in the middle third of the hippocampal formation. B,Camera lucida drawing of a typical spiny cell, from which recordingswere made. Scale bar, 100 µm. C, High-power view of a dendriticsegment from the cell illustrated in B. Note the dendritic spinesthat are evident along the entire length of dendrite. Scale bar,10 µm.

Characterization of synaptic inputs

In cells impaled with electrodes filled with KMeSO₄, electrical stimulation of nearby afferents evoked an EPSP, followed byan IPSP (Fig. 2A) (n = 8). IPSP was blocked completely and reversiblyby application of bicuculline (10 µM; n = 7) (Fig. 2A) or picrotoxin(25-100 µM; n = 3), indicating that it was mediated by GABA_A receptors.When inhibition was blocked, the EPSP was graded in amplitudeand was blocked by application of calcium channel blockers, suchas cadmium (100 µM; n = 2) or nickel (1 mM; n = 3), or by thesodium channel blocker tetrodotoxin (1 µM; n = 3), confirmingthat it was a synaptic potential. Application of the nonspecificglutamate antagonist kynurenic acid (1-2 mM; n = 4) or the AMPA-kainatereceptor antagonist CNQX (10 µM; n = 7) (Fig. 2B) completely abolishedthe EPSP. Depolarization of the cell in the presence of CNQX revealeda slower EPSP, which was blocked by the NMDA receptor antagonist2-amino-5-phosphonovalerate D-APV (30 µM; n = 5) (Fig. 2C). Allantagonists were fully effective within 10 min of applicationbut were only slowly (>30 min) reversible. These results showthat the main excitatory transmitter at synapses in the avianhippocampus is glutamate and both AMPA and NMDA types of glutamatereceptors are active in the postsynaptic membrane.

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Figure 2. Synaptic transmission in the avian hippocampus. A shows a typical response to synaptic stimulation in a cell in which therecording electrode contained KMeSO₄. An EPSP is followed by aslower IPSP. Bath application of the GABA_A receptor antagonistbicuculline (10 µM) blocked the IPSP and revealed the EPSP; thiseffect was fully reversible after 30 min of washout. Resting membranepotential was $-$ 70 mV, and the cell was depolarized to $-$ 40 mV bycurrent injection to reveal the IPSP. B, When inhibitory transmissionwas blocked with bicuculline (10 µM), stimulation of afferentfibers generated an EPSP that was reversibly abolished by theAMPA-kainate receptor antagonist CNQX (10 µM). C, Depolarizationof the cell in the presence of CNQX revealed a slower EPSP, whichwas blocked by the NMDA receptor antagonist D-APV (30 µM). TheNMDA receptor-mediated EPSP could be recovered after washout ofAPV. Note that the NMDA receptor-mediated EPSP is reversed becausethe cell was depolarized beyond the reversal potential for NMDA.

LTP of synaptic transmission in the chicken hippocampus

Tetanic stimulation of afferent fibers (2 × 100 Hz, 1 sec, separated by 20 sec) caused an immediate and long-lasting potentiationof the initial slope of the EPSP (Fig. 3A). This increase in theinitial slope was maintained for the duration of the recording(up to 60 min). The average potentiated response 60 min aftertetanus was 215 ± 26% (n = 8) of the baseline response (Fig. 3B)and was abolished by application of CNQX (n = 3), indicating thatit was entirely attributable to an increase in glutamatergic transmission.To test whether the increase in synaptic strength was restrictedto the stimulated synapses, two separate inputs were activated.The independence of the two inputs was tested by checking thatthe response to stimulation of the second input did not show facilitationwhen delivered shortly after stimulation of the first input. Afterobtaining a stable baseline at both inputs, a tetanus was deliveredto one of the inputs. Only the input that was tetanized displayedLTP (n = 6) (Fig. 3C), showing that LTP is synapse specific (Andersenet al., 1977), as in the mammalian hippocampus.

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Figure 3. LTP in the chicken hippocampus. A, The normalized initial slope of the EPSP is plotted against time for one cell. Tetanicstimulation (2 × 100 Hz, 1 sec) was delivered at time 0. Sweepdata corresponding to the times shown in the top panel (1 and2) are illustrated below. B, Group data from nine cells. AverageLTP was 215 ± 26% of baseline, 60 min after the tetanus. C, LTPis input specific. Shown is ensemble data (n = 6) in which twoindependent inputs (S1 and S2) were alternately stimulated anda tetanus was delivered to S1 at 20 min. S1 showed a robust LTP,whereas S2 was unaffected.

Because both AMPA and NMDA receptors are active at these synapses, we next asked whether induction of LTP required the activationof NMDA receptors. Application of the NMDA receptor antagonistD-APV (2 × 25 µM, 4 × 50 µM, and 2 × 100 µM applied 20-50 minbefore tetanus) had no effect on the induction or maintenanceof LTP (Fig. 4A). The average potentiated response in the presenceof D-APV 30 min after tetanus (236 ± 49%; n = 8) was not significantlydifferent (p > 0.05) from the values for untreated slices (246± 46%; n = 8) (Fig. 4B).

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Figure 4. LTP does not require NMDA receptor activation. A, The normalized initial slope of the EPSP is plotted against time for a singlecell that was superfused with 100 µM D-APV for 40 min before deliveryof a tetanus at time 0. Sample traces taken at the times indicated(1 and 2) are shown below. B, Average LTP obtained in the presenceof D-APV (open circles; n = 8) was not different from that observedin control cells (filled circles). LTP measured at 30 min aftertetanus was 236 ± 49% and 245 ± 37% in control cells and cellsperfused with D-APV, respectively.

Although NMDA receptors are not involved in the induction of LTP, a rise in postsynaptic calcium may still be necessary. Totest for a possible role of postsynaptic Ca²⁺ in the induction of LTP, we loaded the postsynaptic cell withthe calcium chelator BAPTA for 20-40 min before delivery of thetetanus. The resting membrane potential in neurons loaded withBAPTA was $-$ 62 ± 4 mV (n = 7). We noted that action potentialswere broader in the BAPTA-loaded neurons than in control cells(data not shown), confirming that BAPTA had diffused out of themicroelectrode (Lancaster and Nicoll, 1987). Postsynaptic BAPTAfailed to prevent induction of LTP (Fig. 5A). The average potentiatedresponse in the BAPTA-loaded neurons 30 min after tetanus (261± 72%; n = 8) was not significantly different (p > 0.05) fromcontrols (Fig. 5B). These results indicate that a rise in postsynapticcalcium is not important in triggering LTP at synapses in thechicken hippocampus.

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Figure 5. LTP does not require an increase in postsynaptic calcium. A, The normalized initial slope of the EPSP is plotted against timein a cell that was loaded with the calcium chelator BAPTA (200mM in electrode) for 30 min before delivery of a tetanus at time0. Sample traces during the indicated times (1 and 2) are shownbelow. B, Average potentiated response of BAPTA-loaded cells (opencircles; n = 8) was not significantly different from control cells(filled circles; n = 8). LTP measured at 30 min after tetanuswas 261 ± 72% and 245 ± 37% in control cells and cells loadedwith BAPTA, respectively.

LTP requires Ca²⁺ entry into the presynaptic terminal

Because LTP was not affected by postsynaptic injection of BAPTA, we next investigated whether calcium was required at allfor LTP in the avian hippocampus. After a stable baseline wasobtained, extracellular calcium was removed, leading to a rapidblock of synaptic transmission (Fig. 6). An LTP-inducing stimuluswas then delivered to the afferent fibers (n = 4). After extracellularcalcium was restored to control levels, the EPSP was restoredto its original amplitude, indicating that no LTP had been generated.A subsequent tetanus delivered in the presence of extracellularcalcium was able to induce LTP. These data imply that Ca²⁺ entry into the presynaptic terminal is essential for LTP induction.

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Figure 6. Extracellular calcium is necessary for LTP induction. The initial slope of the EPSP is plotted against time. At the time indicated,extracellular Ca²⁺ was removed from the perfusing Ringer's solution, leading toa rapid block of synaptic transmission. A tetanus (2 × 100 Hz,1 sec) was then delivered (T1). Reapplication of Ca²⁺ showed that LTP had not been induced. A second identical tetanus(T2) delivered in the presence of Ca²⁺ induced LTP (n = 4). Representative sweep data correspondingto before and after zero Ca²⁺ and after LTP induction are shown below.

Activation of adenylyl cyclase potentiates synaptic transmission

NMDA receptor-independent forms of synaptic plasticity have been described at a number of synapses in mammalian and invertebratenervous systems (see Discussion). The one common feature of plasticityat these different synapses is activation of a presynaptic adenylylcyclase, which leads to an increase in the probability of transmitterrelease. Therefore, we next examined whether activation of adenylylcyclase might similarly potentiate synaptic transmission in theavian hippocampus.

Bath application of forskolin (1-25 µM), an activator of adenylyl cyclase (Laurenza et al., 1989), induced a large potentiationof the EPSP (225 ± 46%, 50 min after drug application; n = 5)(Fig. 7A). To determine whether the forskolin-induced potentiationwas caused by an increase in release probability, we tested fora change in paired-pulse facilitation (PPF). When a synapse isstimulated twice with a short interpulse interval, the ratio ofthe response to the second stimulus to that of the first is calledthe PPF ratio. Manipulations that increase the probability oftransmitter release reduce the PPF ratio (Katz and Miledi, 1968;Zucker, 1989; Manabe et al., 1993; Isaacson and Walmsley, 1995).Paired pulses were applied at an interval of 175 msec. The increasein the EPSP after forskolin application was associated with aclear decrease in the PPF ratio (normalized PPF ratio decreasedto 0.65 ± 0.03; p < 0.001; n = 5) (Fig. 7B), consistent with apresynaptic action of forskolin. The inactive isomer of forskolin,1,9-dideoxyforskolin, which mimics many of the nonspecific effectsof forskolin, but does not activate adenylyl cyclase (Laurenzaet al., 1989), had no effect on the EPSP when applied at a concentrationof 25-50 µM (n = 3) (Fig. 7C). This result is consistent withforskolin acting through the cAMP pathway to potentiate synaptictransmission via a presynaptic mechanism.

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Figure 7. Application of forskolin potentiates synaptic transmission by a presynaptic mechanism. A, The normalized initial slope ofthe EPSP (n = 5) is plotted against time. After a stable baselinewas obtained, a 10 min application of forskolin (FSK) (1-25 µM)at the times indicated by the bar produced a large sustained increase(225 ± 46%) in the EPSP slope. B, The PPF ratio was significantlyreduced during the forskolin-induced potentiation. Synapses werestimulated twice, with an interpulse interval of 175 msec. Theratio of the slope of the second EPSP to that of the first (thePPF ratio) has been normalized and plotted. Average traces takenat the times indicated in A are shown below. C, Di-deoxyforskolin(dd FSK) (25-50 µM) applied for 10 min during the period indicatedby the bar had no effect on the EPSP. A subsequent applicationof FSK produced a robust potentiation (n = 3).

LTP is not associated with a change in PPF

If tetanic stimulation recruits the same biochemical pathways as those activated by forskolin, we would expect LTP to alsobe associated with a reduction in the PPF ratio (Zalutsky andNicoll, 1990; Weisskopf et al., 1994). The results from sevencells in which we simultaneously measured LTP and the PPF ratioare shown in Figure 8. After an LTP inducing tetanus, the PPFratio decreased during post-tetanic potentiation, as expected(Zucker, 1989), but then returned to baseline levels. The PPFratio measured during LTP (0.98 ± 0.04, taken at 20 min) was notsignificantly different (p > 0.05) from that measured during thebaseline period (Fig. 8B). This result indicates that LTP in thechicken hippocampus is unlikely to result from a change in releaseprobability. However, it remains possible that because the absoluteenhancement of the EPSP by forskolin was larger than that associatedwith LTP, we were unable to detect a small change in the PPF duringLTP, when the increment in release probability was less.

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Figure 8. Long-term potentiation is not associated with a change in paired pulse facilitation. The average normalized initial slopeof the EPSP is plotted against time for seven cells. The normalizedPPF ratio is plotted in B. Tetanic stimulation (2 × 100 Hz, 1sec) was delivered at time 0. After the tetanus the PPF ratiowas transiently reduced during post-tetanic potentiation but thenreturned to baseline levels. Average traces taken at the timesindicated in A are shown at the bottom.

To examine this question, we manipulated release probability by altering the extracellular Ca²⁺/Mg²⁺ ratio (Katz and Miledi, 1968; Manabe et al., 1993) to increasethe EPSP to a similar level as that observed during LTP (Fig.9A). Changing the Ca²⁺/Mg²⁺ ratio from 0.5 Ca²⁺/6 Mg²⁺ to 2.5 Ca²⁺/4 Mg²⁺ increased the initial slope of the EPSP by 236 ± 9% (Fig. 9B₁)and was associated with a clear decrease in the PPF ratio (0.69± .05; n = 4) (Fig. 9B₂). This result demonstrates that if thePPF ratio had changed during LTP we would have detected it. Thus,forskolin and tetanic stimulation must engage distinct secondmessenger cascades with different final targets. Consistent withthis idea, previous induction of LTP had no effect on the potentiationproduced by forskolin (Fig. 9C).

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Figure 9. LTP does not occlude the action of forskolin. A, Pairs of EPSPs recorded in 0.5 mM Ca²⁺/6 mM Mg²⁺ and 2.5 mM Ca²⁺/4.0 mM Mg²⁺ are shown. Raising extracellular calcium concentration increasedthe EPSP and was associated with a clear decrease in the PPF ratio.The horizontal lines denote the relative size of the second pulseunder high Ca²⁺ conditions. B₁, The level of potentiation induced by variousexperimental manipulations: elevation of extracellular calcium(n = 4), forskolin (n = 5), PTP (measured 2 min after tetanus;n = 11), and LTP (measured 20 min after tetanus; n = 7). The correspondingchange in PPF ratio is shown in B₂. C, LTP did not occlude theeffect of forskolin. In two cells, LTP was induced at time 0;after 30 min the stimulus strength was reduced (asterisk) andforskolin was applied (filled circles). Forskolin caused a potentiationof 325 ± 48%, which was not different from the effect of forskolinunder control conditions (open circles). We noted in these cellsthat there was no change in the PPF ratio during LTP; however,a clear change in the PPF ratio was seen after application offorskolin.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

In this study we have examined some properties of excitatory synaptic transmission in the chicken hippocampus. Our resultsshow that although transmission in this structure shares manyfeatures with those in its mammalian counterpart, there are alsosome distinct differences.

At least six different cell types have been identified within the chicken hippocampus by Golgi staining techniques (Ramony Cajal, 1911; Mollà et al., 1986). The large, spiny neuronsfilled with biocytin and recovered in this study are likely tobe the long-axon, spiny cells described by Mollà et al. (1986).Afferent fibers, which are a mixture of cortical afferents andlocal axons, course through the hippocampal formation. Stimulationof these fibers evoked a glutamatergic EPSP followed by a GABAergicIPSP. Both GABA_A receptors (Veeman et al., 1994) and GAD-immunoreactivefibers (Krebs et al., 1991) have been demonstrated in the avianhippocampus, suggesting that local circuitry similar to that seenin the mammalian hippocampus (e.g., Buhl et al., 1994) may alsobe present in the avian homolog.

Stimulation of afferent fibers activated both AMPA-kainate and NMDA receptors in the postsynaptic membrane. These receptorsare thought to be colocalized in the postsynaptic membrane inthe mammalian hippocampus (Bekkers and Stevens, 1989). It willbe of interest to see whether a similar situation holds in theavian system. Tetanic stimulation of excitatory inputs led toan immediate and sustained enhancement of the EPSP. This LTP washomosynaptic, and its induction was not dependent on activationof NMDA receptors. In support of this, a previous study utilizingfield recordings in the pigeon hippocampus also reported thatLTP was not blocked by the NMDA receptor antagonist D-APV (Wieraszkoand Ball, 1991). In our study, injection of the calcium chelatorBAPTA into the postsynaptic cell also failed to prevent the inductionof LTP, indicating that a rise in postsynaptic calcium may alsobe unnecessary for LTP induction. As in other studies examiningthe role of postsynaptic calcium (e.g., Lynch et al., 1983), weloaded BAPTA via sharp microelectrodes. Because action potentialsin BAPTA-loaded cells were broader, we are confident that BAPTAhad reached regions of the cell involved in spike generation;however, we cannot be certain of the concentration of BAPTA reachedat the subsynaptic membrane. If postsynaptic calcium was not bufferedeffectively, then it remains possible that the induction of LTPmay require influx of calcium into the postsynaptic cell.

In the mammalian hippocampus, two distinct types of LTP have been described (Bliss and Collingridge, 1993; Nicoll and Malenka,1995). One form, best studied at synapses made by the Schaffercollaterals onto CA1 pyramidal neurons, requires the activationof postsynaptic NMDA receptors. The subsequent rise in postsynapticcalcium is necessary for the induction of LTP at these synapses.The locus of expression of this form of LTP is not yet resolved,but both presynaptic and postsynaptic mechanisms have been implicated((Bliss and Collingridge, 1993; Nicoll and Malenka, 1994). A secondtype of LTP is present at synapses made by the mossy fibers ontoCA3 pyramidal neurons (Harris and Cotman, 1986; Zalutsky and Nicoll,1990). Induction of LTP at these synapses does not require NMDAreceptor activation or a change in postsynaptic calcium; boththe induction and expression of this form of LTP appear to bepresynaptic (Zalutsky and Nicoll, 1990; Huang et al., 1994; Weisskopfet al., 1994).

Synaptic plasticity that is independent of NMDA receptors and postsynaptic calcium has also been described at synapses inthe mammalian cerebellum (Salin et al., 1996) and autonomic nervoussystem (Briggs and McAfee,1988), at the crustacean neuromuscularjunction (Wojtowicz and Atwood, 1988; Dixon and Atwood, 1989),and in the abdominal ganglion of Aplysia (Goelet et al., 1986).The one common feature of plasticity at these different synapsesis an essential role for adenylyl cyclase: in each case, activationof presynaptic adenylyl cyclase leads to an increase in the probabilityof transmitter release.

In the chicken hippocampus, application of forskolin, an activator of adenylyl cyclase, potentiated excitatory synaptic transmission.As shown at other synapses (e.g., Weisskopf et al., 1994), thisincrease in the EPSP was attributable to a presynaptic actionbecause it was associated with a clear decrease in the PPF ratio.In contrast, LTP was not associated with a change in PPF and didnot occlude the effect of forskolin. These results indicate thatthe increase in the EPSP during LTP is unlikely to be caused bya change in the probability of transmitter release. Furthermore,LTP in this system is unlikely to engage the cAMP pathway. Itshould be noted, however, that the locus of LTP could still bepresynaptic, resulting for example from an increase in the numberof release sites or a change in the amount of transmitter releasedper vesicle.

What then is the trigger for LTP in the avian hippocampus? Our data do not allow us to determine whether the induction ofLTP resides in the pre- or postsynaptic cell. Although changesin postsynaptic calcium do not appear to be important, calciumentry into the presynaptic terminal(s) was necessary for the inductionof LTP. This calcium entry may simply be necessary for transmitterrelease, or it may itself provide the trigger for LTP, as at mossyfiber terminals in the mammalian system. Several proteins presentin the presynaptic terminal are potential targets for calcium.Among the most abundant of these is calcium/calmodulin-dependentprotein kinase II (CaMPK-II). It has been suggested that activationof CaMPK-II regulates potentiation in a stimulus frequency-dependentmanner at the MF/CA3 synapse (Salin et al., 1996). CaMPK-II isalso present in presynaptic terminals in the avian forebrain (Weinbergerand Rostas, 1988), raising the possibility that this may be atarget for calcium during tetanic stimulation. It should be noted,however, that because we have introduced BAPTA via a sharp microelectrode,if the BAPTA concentration in the postsynaptic cell was ineffectivein completely buffering postsynaptic calcium, then the blockadeof LTP in low calcium could be interpreted as being caused bya reduction of calcium influx into the postsynaptic cell.

On the basis of results from behavioral studies, and the similarity in neurotransmitter and peptides in the two structures,a functional similarity has been suggested between the mammalianand avian hippocampus. The mammalian hippocampus has well definedanatomical landmarks, and cell layers are clearly seen in slices.No cell layers were evident in slices of chicken hippocampus;the area that we have recorded from has been suggested to be homologousto the dentate gyrus of the mammalian hippocampus (Showers, 1982;Erichsen et al., 1991). In the cell layer of the dentate gyrusin mammals, neurons are spiny, with a somewhat sparse apical dendritictree but few or no basal dendrites (Claiborne et al., 1990). Incontrast, the cells we have recorded from are spiny, with rathersymmetrical, bushy dendritic trees (as seen in coronal sections)(Fig. 1). Our observation that glutamatergic afferents activateboth NMDA and non-NMDA receptors is similar to observations ofsynapses in the dentate gyrus (Colino and Malenka, 1993); however,NMDA receptor-independent LTP has been demonstrated primarilyat synapses between the mossy fibers and CA3 pyramidal neuronsin the mammalian hippocampus (Nicoll and Malenka, 1995). AlthoughTimms stain does suggest the presence of heavy metals in the chickenhippocampus (Faber et al., 1989), the presence of a fiber systemsimilar to the mossy fibers in the avian hippocampus has beendisputed (Erichsen et al., 1991). Taken together, these resultspoint to similarities and differences between the mammalian andavian equivalents. Our physiological data indicate that the glutamatergicsynapses in the region we are recording from share features withneurons in the mammalian dentate as well as regions CA1 and CA3.Clear demarcation of anatomical boundaries similar to that seenin the mammalian hippocampus remains to be determined.

Lesions of the hippocampus in birds have shown that various learning tasks are dependent on this structure (Clayton and Krebs,1995). In the mammalian hippocampus, in which NMDA receptor-dependentLTP is predominant, disruption of NMDA receptors by pharmacologicalor genetic interventions blocks behavioral tasks thought to involveLTP (Tonegawa, 1995). In the avian system, we have shown thatLTP does not require activation of NMDA receptors. It will beinteresting, therefore, to examine the role of hippocampal NMDAreceptor function in spatial learning in birds.

In conclusion, we have shown that the synapses in the chicken hippocampus, like their mammalian counterparts, display LTP.This LTP does not require activation of NMDA receptors, is independentof adenylyl cyclase, and is not associated with a reduction inPPF. These findings indicate that a novel form of synaptic plasticitymay underlie learning in the avian hippocampus.

  FOOTNOTES

Received Sept. 11, 1997; revised Nov. 20, 1997; accepted Nov. 21, 1997.

This work was supported by grants from the National Health and Medical Research Council of Australia (J.A.P.R., P.S.). P.S.is a Sylvia and Charles Viertel Senior Medical Research Fellow.We thank Robert Callister, Nishith Mahanty, and David Perkel forcomments on this manuscript.
Correspondence should be addressed to Dr. Pankaj Sah, Neuroscience Group, Discipline of Human Physiology, Faculty of Medicineand Health Sciences, University of Newcastle, Callaghan, NSW 2308,Australia.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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