Sensory Processing in the Pallium of a Mormyrid Fish

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The Journal of Neuroscience, September 15, 1998, 18(18):7381-7393

Sensory Processing in the Pallium of a Mormyrid Fish
James C. Prechtl¹, Gerhard von der Emde², Jakob Wolfart¹, Saçit Karamürsel³, George N. Akoev⁴, Yuri N. Andrianov⁴, and Theodore H. Bullock¹
¹ Neurobiology Unit, Scripps Institution of Oceanography, University of California San Diego, La Jolla, California 92093, ² Zoologisches Institut, Universität Bonn, 53115 Bonn, Germany, ³ Center for Electroneurophysiology, Istanbul University School of Medicine, 34390 Istanbul, Turkey, and ⁴ Pavlov Institute of Physiology, Russian Academy of Sciences, 199034 St. Petersburg, Russia

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

To investigate the functional organization of higher brain levels in fish we test the hypothesis that the dorsal gray mantleof the telencephalon of a mormyrid fish has discrete receptiveareas for several sensory modalities. Multiunit and compound fieldpotentials evoked by auditory, visual, electrosensory, and waterdisplacement stimuli in this weakly electric fish are recordedwith multiple semimicroelectrodes placed in many tracks and depthsin or near telencephalic area dorsalis pars medialis (Dm).
Most responsive loci are unimodal; some respond to two or more modalities. Each modality dominates a circumscribed area, chieflyseparate. Auditory and electrical responses cluster in the dorsal500 µm of rostral and caudolateral Dm, respectively. Two auditorysubdivisions underline specialization of this sense. Mechanoreceptionoccupies a caudal area overlapping electroreception but centered500 µm deeper. Visual responses scatter widely through ventralareas.
Auditory, electrosensory, and mechanosensory responses are dominated by a negative wave within the first 50 msec, followedby 15-55 Hz oscillations and a slow positive wave with multiunitspikes lasting from 200 to 500 msec. Stimuli can induce shiftsin coherence of certain frequency bands between neighboring loci.Every electric organ discharge command is followed within 3 msecby a large, mainly negative but generally biphasic, widespreadcorollary discharge. At certain loci large, slow (" $delta$ F") wavesusually precede transient shifts in electric organ discharge rate.Sensory-evoked potentials in this fish pallium may be more segregatedthan in elasmobranchs and anurans and have some surprising similaritiesto those in mammals.

Key words: cerebral cortex; corollary discharge; induced rhythms; evoked potential; gamma band; lateral line; mormyrid

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The pallium is a general term for a mantle of gray matter that covers the telencephalon. In mammals it includes the cortex.Although the pallium is one of the most intensely studied structuresin mammals, in nonmammalian brain physiology it is perhaps themost neglected. We address the question whether this higher brainlevel in fish is basically different in functional organizationfrom that familiar in mammals. We chose to investigate sensoryrepresentation of multiple modalities in the pallium of a teleostwith an elaborated brain (Butler and Hodos, 1996).

Before recent anatomical tracer studies, the teleost pallium was considered to be dominated by olfactory input and involvedprimarily in mechanisms of arousal (Ito and Kishida, 1978; Finger,1980) and in sequencing of elementary "fixed action patterns"(Segaar, 1961; De Bruin, 1980). Multimodal sensory functions convergingin the forebrain were strongly suggested by the results of ablation:impairment of habituation to stimuli (Laming and McKee, 1981)and hyperdefensiveness or overreacting to familiar stimuli (Davisand Kassel, 1983).

We approach telencephalic sensory function by surveying the distributions and properties of evoked responses to several formsof stimuli. The chosen material is the highly differentiated palliumof Gnathonemus petersii (elephant nose fish, Mormyridae, Osteoglossiformes),an African freshwater weakly electric fish that continuously dischargesbrief electric pulses with varying interpulse intervals. The electricfields are used to localize and identify objects with differentohmic and capacitative electrical impedances than the ambientwater (von der Emde, 1990, 1998; Bastian, 1994) and to signalsocial states to other fish (Hopkins, 1988). They also show broad-frequencyvocalization (Rigley and Marshall, 1973) and have an exceptionallysensitive auditory system (McCormick and Popper, 1984). Gnathonemushas a reduced visual system but can use visual cues in socialand other behaviors (Moller, 1995; Cialo et al., 1997; von derEmde and Bleckman, 1998).

Our aims are to analyze compound field potentials, including slow, local field potentials (LFPs) and multiunit spike responsesrecorded concurrently at multiple loci. Unlike some electroencephalographicmeasures, compound field potentials (CFPs) recorded with semimicroelectrodesinclude highly local signals generated within 50-200 µm of theelectrode tip (Bullock, 1997; see Fig. 4A). LFPs, both spontaneouslyand during evoked responses, may be partially correlated withintracellular potentials of local cells (Prechtl and Kleinfeld,1997) and may predict the occurrence of spiking (Bullock, 1997).LFPs reflect the synchronous activity of cell populations andcan provide information on cognitive or contextual aspects ofsensory processing. The hypothesis we are testing is that an advancedteleost pallium has discrete receptive areas for each sensorymodality, as measured with evoked responses, roughly analogousto the organization of the mammalian cerebral cortex.

Recent work in amniotes has shown that many sensory responses as well as certain behavioral states include relatively high-frequencyoscillations (~15-55 Hz, " $gamma$ band"; here extended somewhat lowerthan usual for warm-blooded animals because our subjects are exothermicand at 24-27°C) and that temporal coordination of these oscillationsmay play a role in integration (Gray, 1994; Bullock, 1997). Toexamine for rhythmic response components that might not be closelyphase-locked to the stimulus, the emphasis of the present analysisis on unaveraged trials. Multiple electrodes are used to examinefor signs of cooperativity among neighboring neural assemblies.By comparing sensory responses of amniote cortex with those ofthis tiny, everted pallium we aim to gain insight into featuresof brain physiology that are conserved and perhaps fundamental.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Animals and surgery. Elephant-nose fish, Gnathonemus petersii, from tropical fish dealers (n = 33; size ~10 cm) were maintainedin filtered aquaria at 24-27°C on a 12 hr light/dark cycle. Experimentswere conducted during the light cycle in room temperature water(22-24°C; 10-15 k $Omega$ · cm) under guidelines established by the Universityof California San Diego and the National Institutes of Health.

Before craniotomy, the animals were anesthetized by immersion in 0.01% solution of tricaine methanesulfonate (MS-222), maintainedduring the surgery, and the incision area was coated with 2% lidocainegel. After paralysis with 10-15 µl of 1% tubocurarine pentahydrate(i.m.; w/v), the fish was supported in a loose foam rubber clampin an acrylic tank (40 × 40 × 15 cm) and respired with a mouthtube (one to two drops per second). The skull was stabilized bycementing it to a clamped acrylic rod and then drilled to exposethe forebrain area. In most experiments the left hemisphere wassampled after its overlying portion of valvula was removed byaspiration; in some experiments the valvula was left intact. Waterlevel was maintained above the level of the eyes, and the animal'sdorsum was kept moist by a wick of wet tissue paper.

Electrodes, recording, and data analysis. Commercially available tungsten or stainless steel microelectrodes (F. Haer Inc.,Brunswick, ME; Micro Probe Inc., Clarksburg, MD) were used singlyor in comb-like arrays of 3-6 with spacings of 100-500 µm. Initialelectrode impedances of ~10 M $Omega$ were reduced to ~1 M $Omega$ by passingcurrent and depositing platinum black. Some depth profiles wererecorded with in-line, silicon electrode printed circuit arraysmade by the Center for Neural Communication Technology (Universityof Michigan, Ann Arbor, MI). Field potentials were differentiallyrecorded with the common reference wire in the nasal area, amplified,bandpassed (0.3-2000 Hz), and digitized at 4096 points/sec (DataWaveInc., Boulder, CO). A bipolar tail electrode was used to recordconcurrently the electric organ discharge motor command (EODC);it is probably a junction potential in the electrocytes when thenatural discharge is blocked or reduced by the curare. Programsdeveloped by M. C. McClune (University of California San Diego)were used for off-line analyses of the data. Changes in coherencewere calculated with Matlab by comparing 200 msec of baselineactivity with the first 200 msec interval of the response. Coherenceestimates (a frequency-specific measure of the correlation betweentwo places) were averaged from ~5 responses in each animal andthen combined and statistically evaluated with paired, two-tailedt tests.

Sampling and histological reconstruction. The dorsal pallium, except for its rostral tip, is divided into medial and lateralparts by the epsiliform sulcus (Fig. 1). A three-axis hydraulicmicromanipulator provided coordinates for several penetrationsin each animal, each consisting of 30-50 advances of 50 µm. Electrodepenetrations mostly traversed the telencephalic area dorsalispars medialis (Dm) and the underlying Dm-associated part of areadorsalis pars centralis (Dcm; nomenclature adopted from Nieuwenhuys,1963). Most of the Dm was sampled except for its caudomedial pole(Fig. 1). Some experiments also included penetrations lateralto the epsiliform sulcus, through the area dorsalis pars dorsalis(Dd) and into the Dd-associated part of the of the area dorsalispars centralis (Dcd). Penetrations from the dorsal surface extendedat least 1500-2000 µm deep and thus extended into structures underDm (Figs. 2, 3). In eight experiments the valvula was left intactand approximately the same pallial areas were sampled after traversingthe ~2000 µm height of the valvula (Fig. 1A).

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Figure 1. Diagrams of gross anatomy of the Gnathonemus brain and the area sampled. A, Cross-hatched area indicates the segment of valvula that was removed on one side for most experiments. Dark shading approximates the area in which most recordings were made. B, Dorsal view of the cerebrum, as though transparent, that summarizes the horizontal distribution of unimodal octavolateral sensory responses. Center of mechanosensory response zone (thick line) lies ~400 µm ventral to the center of electrosensory area, which is ~300 µm deep to the dorsal surface with almost no overlap (dashed line). Auditory zone, also 0-500 µm deep, overlaps the electric. Stars represent the diffuse distribution of visually responsive loci, 600-1700 µm below the surface. Cross-section markers a-f indicate transverse reference planes used in Figures 2 and 3. Dd, Telencephalic area dorsalis pars dorsalis; Dm, telencephalic area dorsalis pars medialis; hyp, hypothalamus; LC, caudal lobe; lfb, lateral forebrain bundle; LP, posterior lateral line lobe; TH, thalamus.

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Figure 2. Forebrain transverse sections corresponding to planes a-f in Figure 1B, used as templates for the reconstruction of sensory-evoked response loci in Figure 3 (30 µm sections; cresyl violet; nomenclature adapted from Nieuwenhuys, 1963). ca, Anterior commissure; Dcd, Dd-associated part of the Dc; Dcm, Dm-associated part of the Dc; Dd, telencephalic area dorsalis pars dorsalis; Dla, telencephalic area dorsalis pars lateralis, part a; Dlb, telencephalic area dorsalis pars lateralis, part b; Dlc, telencephalic area dorsalis pars lateralis, part c; Dlm, telencephalic area dorsalis pars lateralis, medialis; ent, nucleus entopeduncularis; lfb, lateral forebrain bundle; V, telencephalic area ventralis; Vd, telencephalic area ventralis pars dorsalis; Vm, telencephalic area ventralis pars medialis; Vv, telencephalic area ventralis pars ventralis.

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Figure 3. a-f, Reconstructed distribution of sensory-evoked responses, superimposing data from 18 animals, projected onto six transverse planes (half sections). Sections a-f correspond to the planes of the section in Figures 1B and 2. Sampled depths in each penetration were usually 50 µm apart; here a small fraction of the loci recorded from are plotted. Responses to each stimulus type are color-coded, and multimodal responses are represented by larger polygons with combinations of color codes. White marks indicate a lack of response to any stimulus; their scatter among responsive loci reflects the between-animal variability in the size and location of unimodal response zones. g, Plan view of left cerebral hemisphere, as in Figure 1B, shows the superimposed unimodal response distributions from four specimens represented by four symbols (triangle, diamond, circle, and star) but with the same color code as in transverse sections. Depth of response sites is not indicated.

To establish reference points, one or two recording loci were marked by lesions or by anodally deposited iron and then histologicallyprocessed (cresyl violet or neutral red and Prussian blue staining)to localize the markings in coronal (transverse) sections. Themajority of loci were inferred directly from surface penetrationmarks of arrays in combination with depth-coordinate records.Surface penetration maps with depth coordinates were translatedinto coronal loci. Rostrocaudal spacing of successive tracks varied,but results were collapsed onto the six templates from a controlbrain (Figs. 1B, 2).

Stimuli and protocol. In the usual protocol, at each recording locus a series of four different stimuli were presented, separatedby >7 sec intervals, and the sequence was repeated at least tentimes. Thus, each stimulus type occurred less than once every30 sec.

The first stimulus, designed for lateral line mechanoreceptors, was water displacement ~1 cm from the contralateral gill areaby a Styrofoam shaft (6.0 × 0.7 × 0.7 cm, ~1 cm submerged). Theshaft was driven in its own axis by an audio speaker (excursion~2 mm) with two cycles of a 10 Hz sine wave. This is a moderatelystrong but submaximal stimulus for lateral line afferents in otherfish we have studied. We did not attempt to prove that this stimuluscannot excite auditory receptors of the eighth nerve, but behavioralliterature has shown that auditory thresholds in many teleostsrise steeply at frequencies well above this. The second stimuluswas a contralateral 100 msec light flash from a red (620 nm) light-emittingdiode ~10 cm from the eye that was covered with a moistened tissuepaper. Ambient illumination was 2-11 lux. The third stimulus wasa quasiuniform transverse electric field of 1 mV/cm at 1 cm fromthe lateral body surface, and 1 msec duration was delivered throughcarbon rods located 21.5 cm from the animal on the left and rightsides. The fourth stimulus was a 100 msec duration, 1000 Hz tonefrom a speaker suspended 1 m above the tank; rise and fall timeswere abrupt. The intensity of the equivalent steady tone measuredat the water surface was 85-90 dB SPL. This is a quite inadequatestimulus for lateral line afferents in other teleosts we havestudied.

In some experiments the intensity, frequency, and/or location of one or more of these stimuli were varied. Modified protocolswere used to examine frequency-following responses in some modalities,by repeated interleaved presentation of 0.5, 1, 2, 3, 4, 5, and10 Hz trains of some of the stimuli; each train was 7 sec in durationand was separated from the next by an interval of 10 sec.

The EODC was monitored as a behavioral variable and used to identify corollary discharge potentials in the brain recordings.No experiments are reported in this study in which stimuli weretimed by the EODC, but by chance they have occurred at all phases,with EODCs happening several times every second and thousandsof stimuli at arbitrary times.

Response classification. Response loci are described as unimodal if the responses recorded were repeatedly and unambiguouslyelicited by only one of the stimuli used. Because different stimuliwere separated by >7 and up to 15 sec, and the same stimulus wasrepeated once at >30 sec to 1 min, there was ample recovery time.Because all possible stimulus types were not implemented (e.g.,tactile, proprioceptive, thermoreceptive) we cannot conclude theloci to be unimodal in the strictest sense. The responses inventoriedfor functional mapping usually consisted of single-sweep, time-lockedwaveforms (i.e., unaveraged evoked potentials) with superimposedmultiunit activity. In some cases, however, the reproducible soundsof multiunit activity on an audiomonitor ("hash"; see below) wereused as indices of responses that had smaller, less conspicuouswaveforms.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Distribution of sensory-evoked responses

Figure 1A provides a sagittal view with the portion of valvula that was removed unilaterally in most experiments (stripes)and the approximate area that was sampled (dark shading). Figure1B is a dorsal view of the pallium that shows the general distributionof responses mapped on transverse planes (a-f) in Figure 3. Theoutlined areas are based on the combined response patterns of18 animals. The animals were selected for having had several electrodetracks with responses to more than one stimulus type. The combineddistributions, based on 251 tracks, define regions (Figs. 1B,3) that are larger than would be seen in an individual, but theyindicate where a particular response type is likely to be obtained.Sampling in each track represented in Figure 3a-f was at 50 µmspacings, but to simplify the display only a fraction of ~7600loci in these animals (n = 18) were plotted. Sample spacing onthe rostrocaudal axis varied and is collapsed onto six coronaltemplates of a control brain whose basic divisions are illustratedin Figure 2. The individual data sets were adjusted for brainsize, but because of individual differences and nonlinear featuresof different brains, the extrapolation of individual responseloci onto a template of a standard brain incorporates some errorby spatial smoothing. Thus, the trends of distributions are moreinformative than outliers. Figure 3g shows a dorsal plan view,similar to Figure 1B, of mapping results from four specimens.Each specimen is represented with a different symbol so that itscontribution to the general pattern given in Figure 1B can beappreciated. The color codes for stimulus modalities are the samefor Figure 3a-g.

Responses to auditory stimuli were obtained reliably in every animal in the dorsal 600 µm of the rostral tip of the Dm, alongthe epsiliform sulcus (Figs. 1B, 3). In the same sulcal regionof the Dm but more caudally and laterally, 89% of the animalsshowed unimodal responses to electrical stimuli. An area responsiveto mechanical stimuli (water movement) is centered ~500-600 µmventral and ~100 µm medial to the electrosensory area and wasobserved in all animals with deep electrode penetrations in thiszone (Fig. 1B). In individual animals, areas responsive to electricalor mechanical stimuli were less extensive than those responsiveto auditory stimuli. Whereas auditory responses were often observedover areas 600-900 µm across, electrical and mechanosensory responseareas were generally confined to areas <500 µm in diameter. Theresponsive areas were small, and their position varied betweenanimals but tended to cluster in areas delineated in Figure 1B.

The sample of visual responses was smaller, and responsive loci were scattered and deep, 600-1700 µm below the surface (Fig.3). The diffuse distribution of the deep visual loci is representedin Figure 1B by stars. The apparent clustering of visual responsesin the lateral pallium suggests that further sampling might haverevealed visual areas in the Dcd and/or the Dcm.

Responses to auditory stimuli

As indicated by local field potentials or changes in multiunit activity (see Materials and Methods), auditory responses beginto rise out of background in unaveraged Dm recordings at ~10 msecafter the onset of the stimulus. With averaging, a small positivewave peaks as early as 4 msec (Fig. 4B, P4; ~5 µV base-to-peak);this may be a far-field auditory brainstem wave (Corwin et al.,1982). Figure 4B compares the averaged responses to 10 and 300msec tone pips and indicates that the similar N40 waves are dueto the stimulus onset rather than its duration or termination.The early, large negative wave increases in amplitude within afew hundred microns from the surface (Fig. 4A) and then declinesdeeper. Some changes in shape may appear during the dorsal-to-ventralpenetration (Fig. 5A), however; phase reversal of the responseis not observed.

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Figure 4. Aspects of auditory-evoked response recorded in the Dm. A, Depth profile of simultaneous single sweeps of AEP recorded with a multichannel, in-line silicon probe (see Materials and Methods). Vertical lines mark the onset of the 100 msec tone pip. Arrows indicate 35-45 Hz waves that are separated by higher frequency waves and spikes. B, Averaged AEPs to 10 and 300 msec tone pips (thick and thin traces) recorded 100-200 µm below the surface. Traces plotted on log-log scales to emphasize early, small, far-field potentials. The baseline is arbitrarily set at 7-8 µV negative instead of the zero of the AC amplifier. The early positive wave at 4 msec (i.e., P4) has a base-to-peak amplitude of ~5 µV, whereas the N40 represents a negative excursion of ~85 µV. Plot is clipped at the beginning of a slow positive potential that lasts for hundreds of milliseconds. Note that the averaging has greatly reduced the high-frequency-induced waves and spikes.

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Figure 5. Latencies and frequency compositions of sensory-evoked potentials. A, AEP depth profile illustrating a shift of principal wave (N45) to a shorter latency (N30) below 500 µm, which is still an active depth, judging by local spikes. Large arrows indicate the peaks of principal waves. An intermediate form at 500 µm shows a loss of the N45 (small arrow) and emergence of the N30 (star). B, Amplitude spectra show the distribution of power in the different frequency bands before the stimulus and during the response. Shaded areas indicate the mean ± SEM. White areas between the shaded traces are proportional to the reliability of the power increases. Plots based on the averages of averaged responses, 10 auditory, 8 electrical, 6 mechanical, and 4 visual from different animals.

Deep responses that extended ventrally to 800 and 900 µm were shown by 69% of subjects in which there was broad sampling ofthe auditory area. The deeper responses have significantly shorteronset and peak latencies, and their early negative waves are usuallylarger in amplitude (Fig. 5A). These zones were more often foundin the rostral half of the auditory area. Although responses inthese zones have markedly different structures at superficialand deep levels, sampling at 50 µm intervals shows a transitionbetween responses. The star in Figure 5A at 500 µm indicates theemergence of the shorter latency response at a transitional level.

$gamma$ Band activity (15-55 Hz), most prominent during the 200-300 msec immediately after the large negative wave, is not "multiunitactivity", which has a frequency content mostly >100 Hz. The spectrumshows an increase in power at all frequencies from 1-120 Hz, butwe point with interest to the $gamma$ band activity and especially tothe hump peaking at 30 Hz (Fig. 5B). Examples of this activityare given in Figures 4A and 5A. Because the frequency is modulatedduring the response and the individual waves are not time-lockedto the stimulus, it is small or absent in the averaged response. $gamma$ Band activity, smaller but still above baseline, usually continuesduring the late positive slow component for >450 msec after thestimulus (Table 1). The bottom trace in Figure 4A ends at 490msec after stimulus where this band of frequencies is still elevated.


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Table 1. Average evoked potentials, means of four measures

Different acoustic frequencies between 500 and 2000 Hz affected the amplitude of the auditory response but usually to within50% of the maximum. Increasing or decreasing stimulus intensityalso changed the amplitude response but little; the responsesin Figures 4-6 are of medium to near maximal amplitude (Table 1).The response was also particularly diminished by interstimulusintervals shorter than 0.5 sec; even at 1 Hz the third and laterauditory-evoked potentials (AEPs) are reduced in the initial negativepeak. Figure 6 shows several series of responses to trains ofevenly spaced stimuli at different repetition rates to show "frequencyfollowing". A prestimulus period of 10 sec precedes the firstresponse in each trace (only ~0.8 sec shown). Responses to stimulipresented at 0.5 Hz show little or no decline; the smaller thirdresponse in the top trace of Figure 6 is atypical and not maintainedwith subsequent stimuli (data not shown). Although responses to1 Hz stimuli fail only slightly on the third and later stimuli,at increasingly higher rates they become small and irregular orattenuated. Averages of four trials (Fig. 6) reveal periods ofrepetitive response at 4 and 5 Hz that are particularly vulnerableand periods when frequency following is more resistant. The upperfollowing frequency (no misses in unaveraged trials) extends onlyup to 3 or 4 Hz; the lowest fusion frequency (no ripple in averagedtraces) was not determined but is also likely to be low. We arenot aware of equivalent auditory data by other techniques or onother fish, but in the visual modality these numbers vary widelybetween species with apparent ethological significance (Bullocket al., 1991).

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Figure 6. Auditory frequency after response. Presentation of repetitive stimuli at different rates (1-5 Hz) shows that the amplitudes of AEPs are markedly attenuated and become labile at rates >2 Hz. Even at 1 Hz, the third and later AEPs are reduced in initial negativity.

Responses to electrosensory or mechanosensory stimuli

Electrosensory-evoked potentials (EEPs) and mechanosensory-evoked potentials (MEPs) were similar in shape and compositionto auditory responses but, in other indices, were more similarto each other. The average onset latencies for EEPs and MEPs werealmost twice as great as those for auditory responses (Table 1).This is a significant comparison if, as we believe, the severalstimulus modalities were roughly equivalent in effectiveness;i.e., near-maximal. EEPs and MEPs also had significantly smalleramplitudes and shorter duration than AEPs. On these differencesfrom auditory responses, the EEP was the more extreme; their smalleramplitudes and durations are illustrated in Figure 7. EEPs andMEPs, like auditory responses, showed broad-band increases inactivity as compared with the prestimulus CFP (Fig. 5B). The mechanosensorystimulus, designed to excite lateral line receptors, was a localwater displacement, but the response did not appear to have spatialspecificity because similar responses could be elicited by manuallyintroducing other objects several centimeters away from the standardstimulus. Because the electrical stimulus was delivered throughbilateral carbon rods separated by >40 cm it is considered tobe a whole-field stimulus (i.e., not a point source). Of subjectswith well developed EEPs, 71% had some electrode tracks with bothEEPs and MEPs, although at different depths (Fig. 7). The degreeof overlap of EEP and MEP loci shown in the experiment of Figure7, however, is more than usual. Except for changes in amplitude,neither the EEPs nor MEPs appeared to show systematic structuralchanges with depth.

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Figure 7. Responses to electrical and mechanical stimuli at different depths in the pallium. Responses to electrical are superficial, in the caudal half of the Dm. Responses to mechanical stimuli are obtained in a similar area but always more ventrally, beginning ~700 µm below the surface. Note that in this sample an electrosensory response resumes in an altered form at 800-900 µm. Single sweeps, vertical line marks stimulus onset.

Visual responses

Unlike the responses to other stimuli, visual response loci were rare in the areas most thoroughly sampled but numerous inthe surveys of a few of the animals. The visual loci were mostcommonly found at sites >1000 µm below the surface of the pallium.Unlike the more dorsal responses to octavolateral stimuli (i.e.,auditory, electrosensory, and mechanosensory), the visual responsesin our sample did not seem to be concentrated in a well definedarea. They most often consisted of relatively slow positive waveswith superimposed high-frequency (>100 Hz) multiunit activity(Fig. 8B). Only a few loci had responses that began with negativesharp waves, marginally similar to the usual octavolateral responses.

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Figure 8. Example of a rare multimodal locus, recorded at successive depths at which responses were observed to each of the four stimuli tested (A-D). Single sweeps all from the same animal and locus. The mechanosensory response at this locus includes a late, positive slow wave (P180). The responses to all four stimuli include long-lasting increases in multiunit activity. Note the tendency of visual and mechanical stimuli to induce bursts of corollary discharges (some marked by stars).

Responses at multimodal loci

Twenty-four percent of responsive loci showed responses to two or more kinds of stimuli. These were near boundary regionsof the outlined unimodal areas (Fig. 1B), and they were also scatteredthroughout the caudal half of the pallium, mostly 330-1400 µmbelow the surface of the Dm. Unlike the responses to the differentoctavolateral stimuli, responses at multimodal loci had variableshapes that did not correlate with the particular stimulus groups.In some cases the response to one stimulus was the characteristicunimodal potential, beginning with a large negative wave, whereasthe other stimulus mainly evoked changes in spiky high-frequencyactivity (Figs. 7, 8). Figure 8 shows data from one of the fewmultimodal loci (2%) that were sensitive to all four types ofstimuli, complicated by particularly large corollary dischargesthat accompany every EODC. Although electrosensory and mechanosensoryareas were closely apposed, their combination constituted only5% of the multimodal sites. Rather, sites responsive to auditoryand electrical (16%) or auditory and mechanical stimuli (31%)were far more common.

Potentials related to electric organ discharge commands, singly and in sequence

All fish showed a virtually continuous background of spontaneous EODCs ranging from approximately one to seven pulses persecond (mean, 3.4 ± 0.3; 113 responses; 18 animals). The EODCbehavior also included bursts, both spontaneous and sensory-relatedin which the discharge frequency increased to an average maximumof 17 ± 3 pulses per second. Most of the animals persistentlyshowed EODC bursts after one or two specific types of stimuli.Of these animals 52% showed bursts only after mechanical stimuli,33% only after visual stimuli, and 15% showed bursts after eithervisual or mechanical stimuli or after mechanical or auditory stimuli.Electrical stimuli of the kind tested did not reproducibly induceelectric organ discharge (EOD) bursts. The evoked potentials (tophotic, acoustic, or mechanical stimuli) that accompanied EODCbursts were not noticeably different from those evoked withoutchanges in EODC behavior.

The EODC potential recorded with the tail electrode (a stereotyped, multipeaked complex lasting ~5 msec) is invariably accompaniedby a conspicuous slow wave at all brain loci sampled, includingthe medullary nucleus preeminentialis, the mesencephalic torussemicircularis and tectum, and the cerebellar valvula as wellas all cerebral loci examined (Figs. 8-10, stars or arrows). Thisslow wave we identify with the corollary discharge studied byothers (Bell 1981, 1986). It is biphasic, with an initially positive20-30 msec phase followed by a negative phase lasting $>=$ 80 msecand varying from insignificance to larger than the first (positive)phase, which is rather consistently 60-100 µV in height. The firstphase starts within 3 msec of the initial deflection of the EODCand reaches its peak ~10 msec after the first large spike of theEODC, much sooner than evoked potentials follow electric stimuli(Fig. 7, left). The same form and latency of slow wave is seenat all the sites just listed, both at the surface and ~1.5 mmdeep, except that the second (negative) phase peaks much sooner(at 15-20 msec instead of 30-40 msec) in deep loci of the nucleuspreeminentialis, torus, and valvula. It is also much larger inthe nucleus preeminentialis and torus, exceeding 400 µV peak-to-peakin the former. Seemingly electrotonically spread from a strongbrainstem dipole, it is not surprising that we see no multiunitspike components in the cerebral loci, with the same electrodesthat see them in the sensory-evoked potential foci. Being early,large, slow, consistent, and robust accompaniments of all EODCs,they appear to be independent of sensory feedback. We believethey are part of or consequences of the central signals calledcorollary discharges by Bell (1981, 1986), because he regardedthem as central corollaries of the motor command; we thereforerefer to them as CDs.

In some loci in a few animals large, broad negative potentials linked to changes in EODC frequency (henceforth $delta$ F waves) werefound in deep recordings in or near the overlap of sensory areasoutlined in Figure 1B. Unlike the other sensory-evoked potentialsthat vary in structure but occur on every trial, $delta$ F waves appearto be facultatively triggered, or induced, because they occurredfrequently after the stimulus but were entirely absent on sometrials. Moreover, they sometimes occurred spontaneously, beforeor between stimuli. Figure 9 shows examples of $delta$ F waves from threeanimals. Note that the negative and positive excursions of thesewaves are fairly symmetrical, whereas those evoked with the abruptstimuli used in this study begin with a sharper negative excursion.The $delta$ F waves are not part of a gradual increase in frequency,but rather they typically appear in a long inter-EODC intervalthat precedes the EODC burst. Sensory-induced EODC bursts, however,could also occur without these $delta$ F waves. In one animal with ahigh-background EODC frequency, spontaneous $delta$ F waves correlatedwith brief pauses in ongoing EODC activity. Whereas sensory-evokedpotentials could be linked to subsequent changes in EODC frequency,theydid not interact with concurrent EODCs that could occur atall phases of the sensory-evoked potential (Fig. 8).

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Figure 9. Samples of stimulus-induced (top trace) and spontaneous (bottom traces) $delta$ F waves from three animals. These large waves that begin with relatively slow negative excursions (peaking at 350 msec from the arbitrary time of the sweep start) precede bursts of EODCs and their corollary discharges (some marked by stars). The $delta$ F wave of the top trace occurred after an electrical stimulus whose artifact appears as a vertical line.

Multichannel coherence analyses

Recently, the correlation of $gamma$ band activity between brain loci has been implicated as a mechanism of integration (Gray, 1994;Bullock, 1997). To examine for evidence of temporal cooperativitybetween electrode channels in the responses of Gnathonemus, weapplied coherence analysis to simultaneously recorded responsesfrom pairs of electrodes with a spacing of ~200 µm. Coherenceis a number between zero and one computed for each frequency ina chosen band indicating the proportion of energy at that frequencythat maintains a fixed phase (any phase) between the two sitesduring the analysis epoch. Using auditory responses from six animals,coherence estimates were averaged for two 200 msec epochs, onejust before stimulus and one immediately after the principal N-wave,in which most of the stimulated changes in $gamma$ activity occur. Figure10A shows that the auditory stimulus induced a significant decreasein coherence in the 35-55 Hz band (p < 0.05; two-tailed t test)compared with the prestimulus epoch. Figure 10B provides examplesof 15-55 Hz filtered responses, superimposed from three electrodes(spaced 200-400 µm apart). The thin arrows before the stimulusline indicate some of the waves (>25 Hz) from the three electrodesthat are congruent. The thick arrows delineate moments duringthe response period in which the phase relationships are morevariable so that coherence drops. The statistical decrease incoherence observed in the means from several animals (Fig. 10A)validate that such incongruence is typical. Recovery of the prestimulushigh coherence is more variable and not well time-locked to thestimulus.

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Figure 10. Stimulus-induced changes in coherence between recording loci. A, In comparison with the immediately prestimulus baseline, coherence during the peak of the response (200 msec window) between neighboring electrodes (200 µm) decreases in the ~35-50 Hz band and increases in no band <60 Hz. B, Filtered (15-55 Hz) and superimposed traces from three electrodes show the synchrony across the three loci in the ongoing LFP (thin arrows) and the phase shifts that occur during most of the response (thick arrows). C, Reproducible coherence increases in a single animal in the 52-60 Hz band after a visual stimulus. D, Superimposed traces from channels 1 and 3 in panel C before and after filtering. Arrows indicate synchronous high-frequency waves in Trial 1 and dotted lines show the jitter of these waves between trials. A, C, stars represent statistical significance at the 0.05 level, two-tailed t test.)

Figure 10C gives an example of four deep loci (900-1000 µm below the surface) in one animal with visual responses that showedstatistically significant, poststimulus increases in coherencein the 52-60 Hz range. We cannot say that this is typical becausethere were too few suitable preparations for this type of multichannelanalysis. Each trace represents the mean change in coherence fora particular pair of recording loci shown on the pallium diagramin the lower corner. The same stimuli induced a reliable decreasein coherence between loci 1 and 4 in the 12-20 Hz band. Bandpass-filteredtraces in panel D show the congruent $gamma$ waves that underlie theincrease in coherence. The dotted lines point to phase differencesbetween two trials indicating that the synchronized waves arenot consistently time-locked to the stimulus.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The major findings of this study are that the pallium in a teleost responds to each of four modalities of physiological sensoryinput in circumscribed zones and that these are mainly segregatedfrom each other. The discrete areas for sound, water displacement,and weak electric fields in this electrosensory fish lie chieflyin the pallial area dorsalis, pars medialis; vision is distributedmore widely and sparsely, mainly deep in area dorsalis, pars lateralis.In addition, a number of the dynamic features of the evoked responsesare described. The auditory representation is the most developedin size, reliability of response, and reproducibility of area.It is subdivided into physiologically differentiated zones, possiblyequivalent to the two auditory areas in the carp pallium (Echteler,1985). Its responses have the highest voltage, shortest latencies,and longest durations of the four modalities. These results areconsistent with the conclusion that this mormyrid is a sound specialist(McCormick and Popper, 1984).

A remark is in order on the limitations of the data because of our choice of four modalities, multiple electrodes, many lociin depth, many repetitions, and long rest periods. We could notsample sufficiently in each individual, without excessive damage,to delineate the borders and shapes of modality-specific zonesprecisely. Pooling the maps from many experiments certainly blursdetails; features that survive pooling are likely to be real andgeneral. We could not vary the stimuli to find the optimum parametersin each place and fish, or equivalent valency (relative intensity)across modalities, or certain forms of subdivisions of recipientzones, although some ranges were tested without finding betterparameters, and all stimuli were behaviorally effective in elicitingEOD acceleration. Major questions remain for future studies, suchas the possibility of mapping of sensory space in each modalityand of multiple, differentiated areas in senses besides the auditory.Many trials were negative (i.e., no response to the four teststimuli) and are not shown on Figure 3, because they were crowdedout by positive trials. With several possible causes, we cannotassign a meaning to negative trials.

Comparisons with other teleosts and other classes

Almost nothing has been known, heretofore, about the segregation or diffuseness and overlap of the projections of differentsensory pathways in the pallium of fishes or amphibians. Untilthe development of experimental tracers, little was known aboutthe existence of such pathways, apart from the olfactory. Thenew methods revealed gross projections into Dm, telencephalicarea dorsalis pars lateralis (Dl), Dd, and extending into Dcdand Dcm from various diencephalic sensory areas but without clearevidence of modality segregation (Ebbesson, 1980; Northcutt andBraford, 1980; Schroeder, 1980; Northcutt, 1981; Crosby and Schnitzlein,1982; Fiebig and Bleckmann, 1988; Wulliman and Northcutt, 1990;Bass, 1991; Striedter, 1991; Nieuwenhuys et al., 1998). The evokedpotential method was applied by a Russian school in the 1960sand led to an evolutionary scheme about visual and octavolateralsegregation in the forebrain pallium of teleosts, although theyexpressed serious concern over the extent of electrotonic spread(Voronin et al., 1968). In elasmobranchs and teleosts, later electrophysiologicalstudies revealed pallial responses to photic and microvolt electricalstimuli (Veselkin and Kova $c'$ evi $c'$ , 1969, 1973; Cohen et al., 1973;Bullock, 1979; Rakic et al., 1979; Nikonorov and Luk'yanov, 1980;Luiten, 1981; Luk'yanov and Nikonorov, 1983; Hofmann and Meyer,1993). Finally, localized recipient zones for acoustic and lateralline mechanical input (Bodznick and Northcutt, 1984; Echteler,1985; Bleckmann et al., 1987) were demonstrated but in separateexperiments so that their overlap or discreteness could not beevaluated.

Anurans, with a more differentiated forebrain than urodeles, are poorly known but apparently much less differentiated thanGnathonemus. They send visual, acoustic, and somatosensory inputin parallel to the striatum and medial pallium (hippocampal homolog),the visual favoring the striatum and the somatosensory and acousticfavoring the pallium, but without as yet known segregation ofmodalities in these structures or any sensory input into the dorsalpallium (Nieuwenhuys et al., 1998).

Comparisons with mammalian cortical-evoked potentials

The teleost telencephalon is vastly different from the mammalian. It develops by inversion, lacks a laminated cortex, andis quite different in the tracts and connections, particularlyof sensory pathways; homologies are not yet agreed on (Northcutt,1995; Nieuwenhuys et al., 1998). Differences between the responsesin teleosts and mammals are expected and easy to list; for example,the distribution of polarity with depth. It is all the more remarkablethat the evoked responses obtained in Gnathonemus with simple,abrupt stimuli share key features with cortical-evoked potentialsof mammals. These include the large, sharp, surface negative wavethat peaks within 100 msec, sometimes known as N1; its augmentationof amplitude with abruptness and intensity of stimulus and itsattenuation with stimulus repetition are reasonably similar. Anotheris the slow, positive, late wave (200-400 msec) in both classes.Obviously brain size and propagation distance play a negligiblerole in accounting for the long latencies. Equivalent data arerare in other fish but appear to be rather similar, in which comparisoncan be made in the studies cited two paragraphs above.

Both the mormyrid and mammals also show a class of slow wave corollary to some motor or effector behavior. In Gnathonemuswe have reported a new species of this class, the $delta$ F wave thatfacultatively accompanies shifts in EODC repetition rate suchas that during active electrosensory probing (von der Emde andZelick, 1995), perhaps the relevant state correlate is initiationof orienting, like the wave linked to spontaneous changes in gazeand visual accommodation we discovered in turtles (Prechtl andBullock, 1995). Others have studied (Bell, 1986) the EODC corollarydischarge, a slow wave (and in the brainstem, a spike burst) thatpromptly follows each EODC, first found in the cerebellar valvulabut well known and largest in the nucleus preeminentialis of themedulla and, in our observations, also large in the torus semicircularisand somewhat smaller in the tectum of the mesencephalon, apparentlyquite simultaneous in all these regions. We find a slow wave ofthe same form and latency widespread in the cerebrum and believeit is another part or electrotonically spread sign of the same,corollary discharge system.

In the next section we single out the similarity in induced, $gamma$ -like rhythms. The present study did not include expectation-likewaves such as the omitted stimulus potential reported with visualand electrosensory stimuli in elasmobranchs and teleosts (Leuresthes,Atherinidae; Bullock et al., 1990) but we fully expect such "cognitive"waves will be found in Gnathonemus and will resemble the similarlyelicited "fast" omitted stimulus wave in humans (Bullock et al.,1994).

$gamma$ Band-induced rhythms and cooperativity

The 20-55 Hz LFP component of the Gnathonemus evoked potentials can be considered analogous to $gamma$ waves in amniote cortex andother structures (Bullock, 1992, 1997). As in most examples, the $gamma$ waves of our fish are not phase locked to the stimulus, as arethe large, early EP waves. Our hypothesis, based on the analogywith examples especially in reptiles and mammals, is that temporalpatterns of such induced rhythms play some role in sensory integration.This is supported by the findings that coherence between recordingsites 200-400 µm apart changes significantly, typically decreasing,for certain frequency bands in the 200 msec period after the principalN-wave of auditory and visual evoked potentials in our data. Thisnot only points to stimulus-induced shifts in cooperativity butprovides a control that volume conduction is not substantial inthis part of the data, as it is for the corollary discharge waves.One possible cause of coherence decrease is active wave propagation,such as that shown in turtle cortex (Prechtl et al., 1997); thiscould not be examined under our conditions but might be detectedwith optical recording or high-resolution arrays of electrodesin a plane.

This preliminary evidence of cooperative $gamma$ activity as well as the finding of segregated sensory areas and of spontaneous,motor-related electrical events provides further indications thatthe teleost pallium may mediate associative and executive functionsanalogous to those of the amniote telencephalon. At the same time,these features are compatible with some quite divergent physiology,organization, and role. It remains for deeper insights, basedon new evidence, to reveal the proper perspective on the teleostpallium.

  FOOTNOTES

Received Feb. 17, 1998; revised June 29, 1998; accepted June 29, 1998.

This work comes from the laboratory of the late Walter F. Heiligenberg and was supported by grants from the National Instituteof Neurological Diseases and Stroke, the National Institute ofMental Health, and the National Science Foundation. Silicon probeswere provided by the University of Michigan Center for NeuralCommunication Technology, which is sponsored by a National Institutesof Health/ Center for Neural Communication Technology grant. Wethank Andrea Thor and Agnieszka Brzozowska-Prechtl for histologyassistance. Calvin J.H. Wong provided thoughtful advice and generoushelp accommodating visiting Heiligenberg Scholars who participatedin the study.
Correspondence should be addressed to Theodore H. Bullock, Neurobiology Unit, 0201, Scripps Institution of Oceanography, Universityof California San Diego, La Jolla, CA 92093-0201.

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Materials & Methods
Results
Discussion
References

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