Nucleus Reuniens Thalami Modulates Activity in Hippocampal Field CA1 through Excitatory and Inhibitory Mechanisms

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Volume 17, Number 14, Issue of July 15, 1997 pp. 5640-5650
Copyright ©1997 Society for Neuroscience

Nucleus Reuniens Thalami Modulates Activity in Hippocampal Field CA1 through Excitatory and Inhibitory Mechanisms

M. J. Dolleman-Van der Weel¹^,², F. H. Lopes da Silva², and M. P. Witter¹
¹ Graduate School for Neurosciences Amsterdam, Research Institute for Neurosciences, Faculty of Medicine, Department of Anatomy and Embryology, Vrije Universiteit, 1081 BT Amsterdam, The Netherlands, and ² Institute of Neurobiology, Faculty of Biology, University of Amsterdam, 1098 SM Amsterdam, The Netherlands

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The nucleus reuniens thalami (RE) originates dense projections to CA1, forming asymmetrical synapses on spines (50%) and dendrites(50%). The hypothesis that RE input modulates transmission inCA1 through excitation of both pyramidal cells and interneuronswas tested using electrophysiological methods in the anesthetizedrat. The RE-CA1 afferents were selectively stimulated at theirorigin; evoked field potentials and unit activity were recordedin CA1. RE-evoked depth profiles showed a prominent negative deflectionin the stratum lacunosum-moleculare and a positive one in thestratum radiatum. The lacunosum-moleculare sink-radiatum sourceconfiguration is compatible with RE-elicited depolarization ofapical dendrites of pyramidal cells. Despite a consistent androbust paired pulse facilitation of RE-evoked field potentials,population spikes in the stratum pyramidale were not detectedat any tested condition. This indicates the inability of RE-CA1input to discharge pyramidal cells. However, stimulation of RE-elicitedspiking of extracellularly recorded units in strata oriens/alveusand distal radiatum, indicative of the activation of local interneurons.Thus, RE seems to modulate transmission in CA1 through a (subthreshold)depolarization of pyramidal cells and a suprathreshold excitationof putative inhibitory oriens/alveus and radiatum interneurons.
RE-evoked monosynaptic or disynaptic field potentials were associated with stimulation of rostral or caudal RE, respectively.Anatomically, a projection from caudal to rostral RE was demonstratedthat can account for the disynaptic RE-CA1 input. Because caudalRE receives input from the hippocampus via the subiculum, we proposethe existence of a closed RE-hippocampal circuit that allows REto modulate the activity in CA1, depending on hippocampal output.
Key words: rat; electrophysiology; neuroanatomical tracing; hippocampus; midline thalamus; limbic system; learning and memory

INTRODUCTION

The involvement of thalamic midline nuclei in early stages of Alzheimer's disease (Braak and Braak, 1991, 1992) and in diencephalicamnesia (Rousseau, 1994) has recently drawn attention to the connectivitybetween the nucleus reuniens (RE) and structures of the medialtemporal lobe (Herkenham, 1978; Wouterlood et al., 1990; Dolleman-Vander Weel and Witter, 1996). In this study we focused on the REprojection to hippocampal field CA1, a crucial structure for learningand memory processes (Squire, 1992).

A few investigators have studied the contribution of RE to hippocampal functioning. Vanderwolf et al. (1985) examined whetherthe medial thalamic nuclei, including RE, were involved in generatinghippocampal atropine-resistant theta rhythm. Their extensive radiofrequencylesions, however, resulted in little or no effect on this typeof rhythmical activity. Hirayasu and Wada (1992a,b) injected NMDAin the thalamic midline of the rat. When NMDA was administeredto RE, it caused tonic and/or clonic generalized convulsions associatedwith temporal limbic EEG seizure discharge. They proposed thatRE participates in the modulation of temporal limbic excitabilityand seizure development. Their findings suggest that RE influencesthe state of activity of the entorhinal-hippocampal circuit. Yet,basic electrophysiological knowledge of RE is still lacking. Amodulatory role for RE in normal functioning of the hippocampushas also been suggested based on anatomical data (Wouterlood etal., 1990; Dolleman-Van der Weel and Witter, 1996). Within fieldCA1, RE fibers terminate in a dense laminar plexus confined tothe stratum lacunosum-moleculare (L-M) and form exclusively asymmetrical(i.e., excitatory) synapses on spines (50%) and dendrites (50%)(Wouterlood et al., 1990). These data indicate that RE fiberscontact the spinous apical dendrites of pyramidal cells, as wellas the largely aspinous dendrites of interneurons.

Based on the latter anatomical observations and the findings by Hirayasu and Wada (1992a,b), we proposed that RE modulatestransmission in CA1 through activation of both pyramidal and nonpyramidalcells. This hypothesis was tested using electrophysiological methodsto stimulate the RE-CA1 afferents selectively in anesthetizedrats. RE-CA1 fibers course mainly within the inferior thalamicpeduncle in a rostral direction, curve dorsally around the genuof the corpus callosum, and then run caudally via the cingulatebundle (in which many hippocampal afferents and efferents course)to enter CA1 (Wouterlood et al., 1990). Within their terminalfield in stratum L-M, RE axons overlap with the perforant pathfibers from the entorhinal cortex (Herkenham, 1978; Wouterloodet al., 1990; Dolleman-Van der Weel et al., 1994). Thus, stimulationof RE-CA1 fibers neither in the cingulate bundle nor within theirterminal field in stratum L-M can provide the selectivity required.Therefore, the RE neurons had to be stimulated at their origin,and depth profiles of evoked field potentials and recordings ofunit activity were performed in CA1.

Our electrophysiological observations indicated the occurrence of monosynaptic and disynaptic RE-CA1 input. To substantiatea possible intrinsic RE connectivity, which is likely to be involvedin disynaptically evoked CA1 responses, a neuroanatomical tracingmethod was used.

MATERIALS AND METHODS
We used 30 male Wistar rats (Harlan CPB, Zeist, The Netherlands), weighing 275-375 gm. Under halothane anesthesia the tracheawas intubated. The animal was then placed in a stereotaxic apparatusand throughout the experiment artificially ventilated by a mixtureof O₂ and N₂O with 1% halothane. Body temperature was maintainedusing a heating pad. The skull was exposed, and two burr holeswere made on the left side of the brain to accommodate placementof stimulating and recording electrodes in RE and CA1, respectively.Because the most dorsal (i.e., septal) part of CA1 is less denselyinnervated by RE fibers than the ventral (temporal) part (Wouterloodet al., 1990), recordings were made approximately at the levelof the splenium of the corpus callosum, or slightly more caudal(see Fig. 1A,B). Stereotaxic coordinates were derived from Paxinosand Watson (1986). They were zeroed at bregma (Br.), the midlineof the sinus, and the cortical (dura) surface [stimulation electrodein RE at an angle of 15° in the coronal plane: Br., $-$ 1.80 mm;lateral (L), 2.0 mm; ventral (V), 7.0 mm; recording electrodein CA1: Br., $-$ 5.6 mm; L, 4.3 mm; V, 1.6-3.1 mm, respectively].To prevent the exposed brain tissue from drying, it was coveredwith warm paraffin oil.
Fig. 1. A, B, Schematic representation of a six-channel recording probe and recording site in CA1. A, Depth profiles of the CA1 responseto RE stimulation were simultaneously recorded using a probe consistingof six equally spaced metal electrodes (interelectrode distance,250 µm). Generally, such an array of electrodes covered a trackthrough the depth of CA1 from the alveus (alv) down to the hippocampalfissure (F). Sub, Subiculum; CA1, CA1 cell layer; or, stratumoriens; pyr, stratum pyramidale; rad, stratum radiatum; l-m, stratumlacunosum-moleculare; DG, dentate gyrus. B, Representative exampleof a CA1 recording site. Lesions (arrows) mark the positions ofthe most superficial (1) and deepest (6) electrodes in the whitematter-deep cortical layer and at the fissure, respectively. Scalebar, 500 µm. C-E, Laminar CA1 field potentials to RE stimulation.C, Simultaneously recorded, typical CA1 profile evoked by pairedpulse stimulation (high intensity stimuli; interpulse interval,100 msec; 0.13 Hz) of the rostral part of RE. The dipole fieldconsists of a prominent negative-going deflection at the synapticlevel, i.e., in the stratum lacunosum-moleculare (l-m), and apositive-going deflection in strata radiatum (rad), pyramidale(pyr), and oriens (or) up to the alveus (alv). The markedly increasedamplitude of the second field potential illustrates the commonlyinduced paired pulse facilitation. Notice also the absence ofa population spike. D, Laminar CA1 responses recorded using aglass electrode that was lowered from the alveus down to the granularcell layer in the dentate gyrus (DG). The dipole field is similarto that recorded using a six-channel probe (see C). In addition,it is nicely shown that the polarity reverses at the border ofstrata radiatum/lacunosum-moleculare (rad/l-m). When the electrodewas lowered through the fissure (fis) into the dentate gyrus (DG),the negative deflection rapidly declined toward the granular celllevel (bottom trace). E, Example of an occasionally recorded complexCA1 response, resulting from stimulation of the caudal part ofRE. This CA1 dipole field displays a configuration similar tothat of the profiles shown in C and D. However, early (open arrow)as well as late (black arrow) potentials are present in both conditioningand test response. The early field potentials in these complexresponses are usually of small amplitude. Stimulation momentsin C-E are indicated by dots.
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Stimulation protocols and data acquisition. Electrical stimulation of RE was performed with the use of an electrode arrayof three stainless steel wires (diameter, 60 µm, insulated exceptthe tip). They were glued together in a glass micropipette, withtips obliquely arranged to cover the rostrocaudal extent of the(unilateral) RE. Because this nucleus is very small (~2 mm inlength and ~0.6 mm in diameter) it can be easily mechanicallydamaged by electrode position adjustment. We therefore followedthe strategy of placing the electrode array stereotaxically andfixing it in place. Stimulation was done between different pairsof the electrode array. As it turned out during the course ofexperiments, this strategy also allowed for a differential stimulationof either the entire rostrocaudal RE or of the rostral or caudalportion of the nucleus, separately. The standard stimulation protocolconsisted of monopolar paired pulses. The first stimulus of apair is referred to as the conditioning pulse, the second oneas the test pulse. Both stimuli were of equal strength and duration[0.2 msec; interpulse interval (IPI), 100 msec, unless statedotherwise; intensity, 150-650 µA; 0.13 Hz]. Occasionally, trainsof single pulses were applied at different frequencies rangingfrom 0.13-10 Hz.

CA1 depth profiles of evoked extracellular field potentials were typically obtained using an array of six equally spaced metalelectrodes (diameter, 60 µm, insulated except the tip; interelectrodedistance, 250 µm). They were arranged in the same plane, gluedin a glass micropipette, and then cut at an angle of 20-30°. Inthis way we were able to record simultaneously, and along a trackapproximately perpendicular to the curved longitudinal axis ofthe hippocampus, the laminar responses across CA1, from the overlyingdeep cortical layers and white matter down to the hippocampalfissure (Fig. 1A,B). Evoked field potentials were amplified anddigitized by way of an interface (CED 1401 plus) connected toa personal computer. They were sampled at a rate of 5000/sec,averaged (n = 32, unless stated otherwise), and stored for off-lineanalysis.

Unit activity was recorded using a glass electrode (15-30 M $Omega$ , filled with 2% Pontamine sky blue in 0.5 M sodium acetate buffer)that could be gradually lowered by way of a remotely controlledhydraulic manipulator. The signal was amplified and bandpass-filtered(500-3000 Hz). A window discriminator (WPI) was used to singleout spike events, the output of which was fed to a digital portof the CED interface. Unit activity was stored as individual sweepstogether with simultaneously recorded field potentials.

Off-line analysis. The characteristics of CA1 field potentials to RE stimulation were studied in laminar depth profiles. Responselatencies were defined as the time from the onset of the stimulusartifact to the peak of the conditioning response. Because RE-CA1afferents are known to form axospinous and axodendritic synapses(Wouterlood et al., 1990) (M. J. Dolleman-Van der Weel and M.P. Witter, unpublished observations), latencies correspondingto a monosynaptic RE input were to be expected. Our latencies,however, turned out to vary over a large range of values. Therefore,we additionally examined whether early (likely monosynaptic) andlate (presumed disynaptic) responses showed a relationship withdifferences in recording or stimulation sites. Based on histologicalanalysis, we sorted the experiments with regard to: (1) the siteof recording in septal-to-temporal CA1, and (2) the site of stimulationin rostral-to-caudal RE. Subsequently, experiments were sortedaccording to latencies (early vs late) and then with respect torecording and stimulation sites.

The application of paired stimuli provided the opportunity to study a particular form of short term plasticity, termed pairedpulse facilitation (PPF). PPF was expressed numerically by theratio between test response amplitude/conditioning response amplitudeand was calculated for elicited field potentials at the synapticlevel (stratum L-M).

Whether stimulation of RE was sufficient to discharge pyramidal cells and/or interneurons was further analyzed in extracellularrecordings of unit activity throughout the depth of field CA1.The latency of synaptic unit activity was measured as the timefrom the stimulus onset to the moment of occurrence of the spike.Simultaneously recorded field potentials were averaged to providethe corresponding population response.

Technical and theoretical considerations for current-source-density analysis. A one-dimensional current-source-density (CSD)analysis estimates the sites where currents flow into or out ofthe extracellular space during cellular activity (Freeman andStone, 1969; Freeman and Nicholson, 1975). Some theoretical andpractical issues, however, have to be taken into account. First,the recording should be in the plane of maximal activation, i.e.,corresponding to the orientation of the apical dendrites of pyramidalcells. In this way amplitude errors of calculated currents shouldbe minimal. A second point of importance is the distance betweenconsecutive recording electrodes. In our experiments 100 µm intervalCSD profiles were recorded using a glass electrode or, alternatively,a specially constructed array of 18 metal electrodes (diameter,60 µm, insulated except the tip). These stainless steel wireswere tightly glued together in the same plane and then cut atan angle of 20-30° (electrode heart-to-heart distance, 100 µm).This "knife-like" electrode array, not thicker than the diameterof the wires used, caused remarkably little damage. Moreover,its shape also met the criterion for recording perpendicular tothe longitudinal axis of CA1.

Histological control. At the end of the experiment, under deep anesthesia, stainless steel electrodes were marked by lesionsaccording to a procedure (three pulses of 1 mA anodal current)that results in a blue (because of the potassium ferrocyanidein the fixative; see below) spot in the brain tissue, occasionallywith a hole in the center of the lesion. Glass micropipettes weremarked by passing current (20 min, electrode as cathode) to ejectPontamine sky blue. The animal was then decapitated, and the brainwas quickly removed and stored for 3 d in 4% paraformaldehydeand 0.05% glutaraldehyde in 0.1 M phosphate buffer with potassiumferrocyanide. The tissue was cryoprotected by immersion in 2%dimethylsulfoxide and 20% glycerin in phosphate buffer until equilibrium.On a freezing microtome the brain was cut in coronal sections(40 µm) that were Nissl-stained and used for verification of electrodeplacements.

Neuroanatomical anterograde tracing. In the course of this study, we observed monosynaptic and presumably disynaptic responsesin CA1 after RE stimulation. In a previous anatomical study, Wouterloodet al. (1990) found that injections of the anterograde tracerPhaseolus vulgaris leucoagglutinin in caudal RE resulted in densefiber labeling in rostral RE. Their findings suggest a connectionfrom the caudal to the rostral portion of RE that may form theanatomical substrate for our electrophysiological observations.To specifically elucidate this issue, we performed additionalanatomical tracing experiments, using another five Wistar rats.The neuroanatomical tracer biotin-conjugated dextran amine (BDA;Molecular Probes, Eugene, OR) was used as described in detailelsewhere (Dolleman-Van der Weel et al., 1994). Briefly, ratswere deeply anesthetized with a 4:3 parts mixture of Aescoket(1% ketamine; Aesculaap BV, Boxtel, The Netherlands) and Rompun(2% xylazine; Bayer, Leverkussen, Germany) and then mounted ina stereotaxic frame. At coordinates derived from those of Paxinosand Watson (1986), BDA was iontophoretically applied (pulsed positiveDC current for 10 min, 5-6.5 µA, 7 sec on/7 sec off) to the caudalportion of RE. After 7-10 d of survival, the animals receivedan overdose of Nembutal (sodium pentobarbital; Ceva, Paris, France)and were transcardially perfused with 0.9% saline solution, followedby 4% paraformaldehyde and 0.05% glutaraldehyde in 0.1 M phosphatebuffer, pH 7.4. The brain was removed from the skull, post-fixedfor 1 hr, and then cryoprotected by immersion in 2% dimethylsulfoxideand 20% glycerin in phosphate buffer. On a freezing microtome,serial coronal sections (40 µm thick) were cut and were immunocytochemicallyprocessed for visualization of BDA using an avidin-biotin-peroxidasecomplex (Vectastain ABC kit; Vector Laboratories, Burlingame,CA). Following 1.5 hr of incubation with ABC solution, the sectionswere thoroughly rinsed and reacted with nickel-enhanced diaminobenzidineas a chromogen. BDA-stained sections were then mounted, Nissl-stained,dehydrated, and coverslipped with Entellan (Merck, Darmstadt,Germany).

RESULTS

Electrophysiological observations
CA1 field response to RE stimulation In CA1 a consistent dipole field was recorded in response to stimulation of RE in vivo. In all cases, the depth profiles,recorded with either metal or glass electrodes, were characterizedby a long latency, prominent negative-going deflection in thestratum L-M that reversed polarity at the border of strata L-Mand radiatum and a positive-going one in the stratum radiatumup to the alveus (Fig. 1C-E). Whenever recording electrodes werelowered into the dentate gyrus, the negative deflection of theCA1 response showed a steady decline in amplitude (Fig. 1D). Thislatter observation is in line with the anatomically demonstratedabsence of RE projections to the dentate gyrus and field CA3 (Herkenham,1978; Wouterlood et al., 1990; Dolleman-Van der Weel and Witter,1996). A similar fading of the positive deflection was noticedwhen recordings were made in the deep cortical layers overlyingCA1. Occasionally, the depth profile had a more complex waveformas documented in Figure 1E. In those cases, the CA1 responsesconsisted of two consecutive deflections (i.e., an "early," usuallysmaller, and a "late," larger, potential; see below) in both conditioningand test response. Yet, irrespective of waveform complexity, acommon feature of the laminar depth profiles was that the largestnegative peaks occurred in the stratum L-M, close to the hippocampalfissure; the largest positive peaks (as a rule smaller in amplitudethan the negative ones) were recorded in the stratum radiatum.We consistently observed that a population spike could not beinduced, even when the stimulus intensity was increased from 100to 650 µA, and the frequency was raised from 0.13 to 10 Hz. Infact, during stimulation at frequencies in the theta range, thepeak of the field potential markedly declined, whereas the amplitudeand duration of the decay phase became enhanced (data not illustrated).
CSD analysis Laminar depth profiles (Fig. 2A) for CSDs, obtained either by the use of a probe with 18 metal electrodes (electrode heart-to-heartdistance, 100 µm) or by stepwise lowering of a glass electrode(100 µm interval) from the white matter down to the hippocampalfissure, revealed a well defined sink at the level of the stratumL-M and a clear source in the stratum radiatum (Fig. 2B). Thesource declined in amplitude toward the strata pyramidale andoriens. This sink-source configuration is compatible with theinterpretation that RE input in the stratum L-M elicits a fieldEPSP (fEPSP) in the apical dendrites of pyramidal cells.
Fig. 2. Depth profile of RE-evoked field potentials in CA1 (A) with the corresponding CSD (B). A, The depth profile was recorded usinga probe with 18 metal electrodes (see Materials and Methods; electrodeheart-to-heart distance, 100 µm). Dots indicate the moments ofthe paired stimuli (100 msec interpulse interval, 0.13 Hz). Therecordings from electrodes 4-18 are depicted, covering CA1 fromthe white matter overlying the hippocampus down to just acrossthe hippocampal fissure into the dentate gyrus. Indicated arethe pyramidal cell layer (pyr), the radiatum/lacunosum-moleculareborder (rad/l-m), and the fissure (F). Note that in the bottomtrace, recorded just below the fissure, the negative deflectionis much smaller compared with the trace recorded above the fissure(also see Fig. 1D). B, The CSD, corresponding to the depth profileshown in A, clearly demonstrates the prominent lacunosum-molecularesink; the radiatum source rapidly declines toward the pyramidalcell layer (sinks are shown by a deflection downward, sourcesby a deflection upward, in arbitrary units).
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Paired pulse facilitation The short term dynamic properties of the RE-CA1 projection were studied by analyzing evoked fEPSPs to double pulse stimulationof RE (fixed IPI, 100 msec; 0.13 Hz) at different stimulus intensities.PPF was quantified by the ratio between test/conditioning peakand calculated for responses recorded in the stratum L-M, representingthe summed active RE-CA1 synaptic processes.

In general, the amplitude of the conditioning deflection was quite small at low (150-300 µA) and moderate (350-450 µA) intensitiesbut was better distinguishable at high stimulus intensity (500-650µA). RE-induced PPF of fEPSPs was robust at low to high intensitystimuli (low intensity: mean PPF, 1.5 ± 0.2; n = 7; moderate intensity:mean PPF, 2.1 ± 0.8; n = 6; high intensity: mean PPF, 1.9 ± 0.8;n = 18). We also examined PPF resulting from paired stimuli (highintensity, 0.13 Hz) at IPIs ranging from 20 to 200 msec. At 200msec IPI, PPF was comparable to that elicited by stimuli at 100msec IPI; at IPIs shorter than 100 msec, PPF was as robust asat 100 msec IPI or displayed a slight increase in magnitude. Pairedpulse depression of the test deflection under the stimulus conditionsused was not observed.
Synaptic unit activity to RE stimulation The consistent absence of a population spike in our CA1 profiles indicated the probable paucity of pyramidal cell dischargeto RE stimulation. Careful examination of all depth profiles revealedthat stimulus-triggered spike events did occur, but only in twoexperiments. In both cases, however, the spikes were not detectedat the pyramidal cell level; rather, they were superimposed onthe fEPSPs recorded in the distal stratum radiatum in both conditioningand test response (Fig. 3A). Thus the radiatum spikes can be consideredsynaptically elicited in radiatum interneurons. The latenciesof the radiatum spikes in these two experiments were remarkablysimilar (21 and 22 msec, respectively) and shorter than the latencyof the fEPSP peak. In addition, we noticed that radiatum spikeswere generated only after high intensity stimulation of RE andat low frequencies (range, 0.13-2 Hz; see Fig. 3B); they disappearedwhen we applied stimuli at frequencies in the theta range (5-10Hz) but reappeared when stimulation was resumed at low rates (e.g.,at 0.13 Hz).
Fig. 3. RE-evoked spikes in the distal stratum radiatum and at the oriens/alveus border, indicative of the activation of local interneurons.A, A simultaneously recorded CA1 depth profile reveals that stimulus-triggeredspikes (arrows) occurred only in the distal stratum radiatum (rad,*), in both the conditioning and test response, after high intensitystimulation of RE (0.13 Hz). pyr, stratum pyramidale; l-m, stratumlacunosum-moleculare; B, Magnification of recordings from thestratum radiatum. a, Radiatum spikes (arrows) shown in A (tracemarked *). b, Radiatum field potentials to single pulses appliedto RE at frequencies in the range from 0.13 to 2 Hz also exhibitedspikes. c, Stimulus-triggered radiatum spikes (arrows) in bothconditioning and test response, recorded in another rat. Noticethat in all cases the latencies of the radiatum spikes were highlycomparable. C, A synaptically driven neuron was encountered atthe oriens/alveus border. A short latency action potential (blackarrows) was recorded in both the conditioning and test response.D, The simultaneously recorded local field potential shows thatthe RE-evoked oriens/alveus spike (open arrows) preceded the postsynapticpyramidal cell response. Stimulation moments in A-D are indicatedby dots.
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Unit activity was systematically investigated in 11 cases by stepwise lowering of a glass electrode across CA1 from the alveusdown to the hippocampal fissure. Low to high intensity pairedstimuli (IPI, 100 msec; 0.13 Hz) were applied to RE, and unitactivity and fEPSPs were recorded simultaneously. In general,many spontaneously active neurons were encountered approachingthe pyramidal cell layer, but they became more sparse when theelectrode was lowered through strata radiatum and L-M. Only onesynaptically driven neuron was recorded at the oriens/alveus border.This neuron generated a short latency (9 msec) action potentialto both the conditioning and test pulses (Fig. 3C) at low as wellas high intensity stimulation of RE. The simultaneously recorded,small amplitude deflection at the oriens/alveus level (Fig. 3D)shows that the RE-elicited oriens/alveus spike preceded the localfield response.
Monosynaptic and disynaptic nature of RE-evoked fEPSPs in CA1 Because RE afferents in CA1 form axospinous and axodendritic contacts (Wouterlood et al., 1990), the RE input was thus expectedto be of a monosynaptic nature. During the series of experiments,however, we found a rather wide range (13-39 msec) of latenciesof fEPSPs to RE stimulation. Therefore, we analyzed whether theseresponses were monosynaptically and/or disynaptically evoked,possibly in relation to differences in recording or stimulationsites. Based on histological verification of electrode placements,the experiments were sorted for recording site (septal-to-temporalCA1) and stimulation site (rostral-to-caudal RE), respectively.By subsequent comparison with the sorting for early versus lateresponses, we found that so-called early (monosynaptic) responses(mean latency, 16.8 ± 3.6 msec; n = 18) were evoked by stimulationof the rostral two-thirds of RE (rRE; Fig. 4A,C); late (presumablydisynaptic) responses (mean latency, 33.0 ± 3.2 msec; n = 6) resultedfrom stimulation of caudal RE (cRE; Fig. 4A,D). Occasionally werecorded complex responses (n = 5), such as the one documentedin Figure 1E, displaying early as well as late deflections inboth conditioning and test response. In those complex field potentialsthe early conditioning and test fEPSPs were usually of small amplitude(see Fig. 1E). Because the (subtle) differences in CA1 recordingsites could not be associated with any variation in response latencyor waveform complexity, we concluded that the source of the disynapticnature of RE-CA1 input must be within RE itself.
Fig. 4. Stimulation of rostral versus caudal RE and associated early versus late CA1 responses. A, The histogram represents the distributionof latencies of CA1 field potentials corresponding with earlyor late responses to stimulation of rRE or cRE, respectively.B, Series of rostral-to-caudal coronal sections through the ratbrain, illustrating the location of the rostral (top row) andcaudal (bottom row) portions of RE (shaded areas). C, Representativeexample of the position of a stimulation electrode in rostralRE, marked by a small lesion (arrow). D, Representative exampleof a stimulation site in caudal RE. The dark spot, representingthe center of the lesion (arrow), indicates the position of thestimulation electrode. f, Fornix; mt, mammillothalamic tract.Scale bars, 500 µm.
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Anatomical observations
Intranucleus projection from caudal to rostral RE We reasoned that an intranucleus connectivity between caudal and rostral RE might underlie the observed monosynaptic and disynapticnature of rostral or caudal RE-evoked fEPSPs in CA1. Therefore,we investigated whether a projection that connects the caudaland rostral parts of the nucleus could be demonstrated. The neuroanatomicaltracer BDA was injected in the caudal RE, where it was incorporatedby neurons confined to the caudal portion of the nucleus (Fig.5A). BDA is primarily transported in an anterograde direction.Uptake of BDA by (damaged) fibers of passage may result in someretrograde transport (Veenman et al., 1992); anterograde transportof BDA in axons of passage has not been reported. Our BDA injectionsresulted in many anterogradely labeled varicose fibers and terminallabeling in rostral RE (Fig. 5B,C). In comparison with the denseterminal labeling in rostral RE resulting from injections in caudalRE, we detected a sparse terminal labeling in hippocampal fieldCA1. This latter observation confirms previous findings (Wouterloodet al., 1990; Dolleman-Van der Weel and Witter, 1996) that caudalRE gives rise to only a minor innervation of CA1. When BDA wasinjected in the poorly delineated thalamic area just caudal toRE, labeled fibers were absent in both rostral RE and field CA1.
Fig. 5. Intranucleus projection from caudal to rostral RE. A, Representative example of an injection site in caudal RE; the anterogradetracer BDA has been incorporated by neurons located in the caudalpart of the nucleus. B, The injection shown in A resulted in adense plexus of BDA-positive varicose fibers and terminal labelingin the rostral part of RE. C, High magnification of the terminallabeling in rostral RE shown in B. Arrows in B and C indicatethe same blood vessel. Scale bars: A and B, 500 µm; C, 20 µm.f, Fornix; mt, mammillothalamic tract.
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DISCUSSION
The present study provides the first electrophysiological evidence (schematically summarized in Fig. 6) that RE is able tomodulate transmission in CA1 through both excitatory and inhibitorymechanisms. First, electrical stimulation of RE-CA1 afferentsat their origin causes an active (subthreshold) depolarizationof the apical dendrites of pyramidal cells, which may enhancetheir state of excitability. Second, RE-elicited spiking of extracellularlyrecorded units was not detected in the stratum pyramidale butin strata oriens/alveus and radiatum, which indicates synapticexcitation of local nonpyramidal cells that are likely associatedwith inhibitory mechanisms (Lacaille et al., 1987; Samulack etal., 1993; McBain et al., 1994; Steffensen, 1995; Bergles et al.,1996; Maccaferri and McBain, 1996; for review, see Freund andBuzsáki, 1996). Furthermore, evidence is provided for the existenceof a projection from caudal to rostral RE that is considered toform the anatomical substrate underlying the presently observeddisynaptic and complex RE-evoked responses in CA1. Because caudalRE receives input from the hippocampus via the subiculum (Herkenham,1978; Witter and Groenewegen, 1990; Dolleman-Van der Weel et al.,1993), we propose that the caudal to rostral RE connection mightact to close a novel circuit (see Fig. 6) between rostral RE-CA1-subiculum-caudalRE-rostral RE, which allows RE to modulate the activity levelin CA1, depending on the output of the hippocampus.
Fig. 6. Schematic representation of the RE-CA1-subiculum-RE loop. The RE-CA1 input is both monosynaptically and disynaptically organized.Monosynaptic input originates predominantly in the rRE; only aminor portion of the monosynaptic afferents arises from cRE. Adense intranucleus projection from cRE to rRE can account forthe disynaptic cRE-rRE-CA1 input. In the stratum lacunosum-moleculare(l-m) of CA1, the RE axons form exclusively asymmetrical [i.e.,excitatory (excit)] synapses on the apical dendrites of pyramidalcells [P; stratum pyramidale (pyr)], as well as on those of subtypesof interneurons located at the oriens (or)/alveus (alv) border[vertical oriens/alveus interneuron (O/AI)] and in the distalstratum radiatum [rad; radiatum interneuron (RI)]. Electricalstimulation of RE in vivo elicits a subthreshold depolarizationin pyramidal cells and the generation of synaptic spikes in oriens/alveusand radiatum interneurons. The vertical oriens/alveus interneuronsare assumed to mediate feedforward inhibition (inhib) of pyramidalcells; the axonal targets of radiatum interneurons (the latterprobably containing both inhibitory and excitatory transmitters[undefined (undef); see Discussion], and thereby the role theseinterneurons play in the local circuit of CA1 awaits further investigation.Major output of CA1 is known to be transmitted to the subiculum(Sub), which, in turn, projects back to cRE. This suggests a closedrRE-CA1-subiculum-cRE-rRE loop that may enable RE to modulatethe flow of information through CA1 depending on the output ofthe hippocampus.
[View Larger Version of this Image (28K GIF file)]

The L-M sink-radiatum source configuration is in agreement with the interpretation that stimulation of RE evokes a synapticEPSP in the apical dendrites of pyramidal cells. However, thisdistal EPSP seems insufficient to elicit action potentials inthese cells. This can be attributable to its spatial decay inthe proximal direction, likely associated with an inhibitory actionat the somatic level (see compartmental-volume-conduction modelby Leung, 1995). The latter is in line with the observation thatRE is able to discharge interneurons that are likely inhibitoryand are known to contact the pyramidal cell bodies (see below).In CSDs, however, synaptically elicited activity by nonpyramidalcells can remain undetected, because these cells: (1) are widelydistributed and largely outnumbered by CA1 cells, and (2) displaya laminar dendritic orientation similar to that of pyramidal cells.

The RE-evoked dipole field, lacking a population spike, is remarkably similar to that evoked by stimulation of the excitatoryentorhinal cortex (EC)-CA1 input in the rat (Colbert and Levy,1992; Empson and Heinemann, 1995; Leung, 1995; Levy et al., 1995).Thus, like EC-evoked CA1 responses, RE-evoked fEPSPs may be mediatedby non-NMDA as well as NMDA receptors (Colbert and Levy, 1992;Empson and Heinemann, 1995). However, the pharmacology of CA1responses to RE stimulation awaits further investigation. Thepresently observed conspicuous RE-induced PPF of fEPSPs, notedto be largely independent on stimulus intensity and IPI duration(at least under all tested conditions), indicates that RE canexert a persistent influence on the state of pyramidal cell excitability.This will probably keep the latter cells close to the firing threshold,allowing them to discharge under certain conditions, for instance,during periods of diminished inhibition. Previously, the findingsby Hirayasu and Wada (1992a,b) also indirectly pointed to theability of RE to modulate temporal limbic excitability. Theseinvestigators observed that NMDA injections in RE caused remarkablebehavioral and temporal lobe EEG changes, i.e., tonic and/or clonicgeneralized convulsions, and seizure discharges.

Our interpretation that RE is able to elicit a suprathreshold activation of interneurons is based on the detection of elicitedspikes in the stratum radiatum and at the oriens/alveus border.Direct evidence for this interpretation (i.e., RE-evoked responsesin morphologically identified interneurons) should be obtainedin future studies using the in vivo intracellular recording andlabeling technique (e.g., Sik et al., 1995). Nevertheless, thepresent assumption is consistent with the observations that: (1)stimulation of RE never elicited action potentials in the stratumpyramidale; (2) stimulus-triggered action potentials were foundin strata containing interneurons that, from a morphological viewpoint (see below), can be contacted by RE fibers; and (3) anatomicallywe found that RE-CA1 axons form asymmetrical synapses on GABA-positivedendrites in the stratum L-M (M. J. Dolleman-Van der Weel andM. P. Witter, unpublished results). These latter observationssupport our interpretation that RE-elicited spiking of extracellularlyrecorded units reflects monosynaptic activation of interneurons.With respect to the observed radiatum spike events, however, wealso have to address the possibility that these actually representeddendritic spiking in pyramidal cells. High intensity, low frequencystimulation of radiatum fibers and Schaffer collaterals (Herreras,1990) has been shown to result in the consistent occurrence ofdendritic spikes generated by CA1 pyramidal cells. In our hands,using a standard protocol of high intensity stimulation at 0.13Hz, dendritic spiking thus should have been encountered on a farmore regular basis than the two cases in which triggered spikesin the stratum radiatum were detected. Moreover, the latency ofthe radiatum spikes in those two experiments was highly comparable,despite a difference in latency between the respective fEPSPs.This supports the interpretation that RE-elicited radiatum spikesreflect synaptic discharges in radiatum interneurons.

According to their distinctive morphologies, axonal targets, and neurochemical markers, CA1 interneurons in strata oriens/alveusand radiatum represent a heterogeneous class of nonpyramidal cells(McBain et al., 1994; Buckmaster and Soltesz, 1996; Freund andBuzsáki, 1996; Maccaferri and McBain, 1996). A prerequisite forthese interneurons to receive RE input is that their dendritictree extends into the stratum L-M. This has been shown for a subpopulationof cells at the oriens/alveus border, the so-called vertical oriens/alveuscells (McBain et al., 1994). These interneurons have an extensivelyarborizing axon that is largely confined to the stratum pyramidale,forming symmetrical (inhibitory) synapses on the somata and primarydendrites of numerous CA1 cells. Functionally, they are assumedto mediate both feedforward and feedback inhibition of pyramidalcells (Lacaille et al., 1987; Lacaille and Schwarzkroin, 1988;Samulack et al., 1993). Interneurons located in the distal radiatumthat fulfill the criterion to receive RE input are likely theones containing GABA as well as the putative excitatory transmitterscholecystokinin (CCK) and/or vasoactive intestinal polypeptide(VIP) (Kosaka et al., 1985; Gulyás et al., 1991; Haas and Gáhwiler,1992; Acsády et al., 1996a,b). GABA-CCK cells have been observedto form symmetrical synapses with pyramidal cell bodies (Harriset al., 1985; Nunzi et al., 1985); GABA-VIP cells have been shownto contact primarily other interneurons (Acsády et al., 1996a,b;Freund and Buzsáki, 1996). Although the function of these interneuronsubtypes in the stratum radiatum remains to be established, basedon their different axonal targets it can be assumed that eachsubtype plays a distinctive role in the local circuit of CA1.Thus, the ability to discharge interneuron subpopulations in strataoriens/alveus and radiatum (e.g., differing in discharge threshold,afferent and efferent targets, and transmitter contents) increasesthe flexibility of RE to modulate transmission in CA1. The possibleinteraction between the EC-CA1 and RE-CA1 inputs is also of interestin understanding the role RE might play in modulating the activityin the entorhinal-hippocampal circuit. In this respect, our preliminaryresults from paired stimulation of RE and EC revealed that aninteraction (i.e., facilitation of elicited-fEPSPs, yet withoutinducing a population spike) between perforant path and RE inputsoccurs in CA1 (M. J. Dolleman-Van der Weel and F. H. Lopez daSilva, unpublished results).

Based on the previously demonstrated RE-CA1 (asymmetrical) synapses on spines and dendrites (Wouterlood et al., 1990), a monosynapticRE input was to be expected. However, RE-evoked CA1 responsesdisplayed a wide range of latency values, indicating that bothmonosynaptic and disynaptic RE inputs exist. Interestingly, ourearly (monosynaptic) and late (disynaptic) CA1 responses seemedassociated with selective stimulation of rostral and caudal RE,respectively. Anatomically, rostral RE is the major source ofCA1 afferents, whereas caudal RE contributes very modestly tothis projection (Dolleman-Van der Weel and Witter, 1996). We nowreport that caudal RE gives rise to a dense innervation of rostralRE. Taken together, our anatomical and electrophysiological datathus suggest that the caudal-to-rostral RE projection is involvedin the disynaptic, or occasionally noted complex monosynapticand disynaptic, fEPSPs in CA1 evoked by stimulation of caudalRE. In these latter complex responses, the early potential ofa small amplitude likely represents the activation of few caudalRE neurons projecting monosynaptically to CA1; the late potentialof a larger amplitude then reflects the activation of the presentlydescribed caudal RE-rostral RE-CA1 disynaptic input. Because caudalRE receives input from the hippocampus via the subiculum (Herkenham,1978; Witter and Groenewegen, 1990; Dolleman-Van der Weel et al.,1993), we propose the existence of a closed circuit (see Fig.6) between rostral RE-CA1-subiculum-caudal RE-rostral RE, whichmay allow RE to modulate the activity level in CA1 depending onthe hippocampal output.

FOOTNOTES

Received Feb. 27, 1997; revised May 8, 1997; accepted May 8, 1997.

This work was supported by Neurowetenschappen Amsterdam Grant 90-20 from the Graduate School for Neurosciences Amsterdam.We thank Professor W. J. Wadman for his advice and A. J. A. Jutafor helping with the calculation of the CSDs.

Correspondence should be addressed to Menno P. Witter, Department of Anatomy and Embryology, Faculty of Medicine, Vrije Universiteit,7 van der Boechorststraat, 1081 BT Amsterdam, The Netherlands.

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