Parallel Medullary Gustatospinal Pathways In a Catfish: Possible Neural Substrates for Taste-Mediated Food Search

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Web of Science (9)

Citing Articles via Google Scholar

Google Scholar

Articles by Kanwal, J. S.

Articles by Finger, T. E.

Search for Related Content

PubMed

PubMed Citation

Articles by Kanwal, J. S.

Articles by Finger, T. E.

Pubmed/NCBI databases
Substance via MeSH

Previous Article  |  Next Article

Volume 17, Number 12, Issue of June 15, 1997 pp. 4873-4885
Copyright ©1997 Society for Neuroscience

Parallel Medullary Gustatospinal Pathways In a Catfish: Possible Neural Substrates for Taste-Mediated Food Search

Jagmeet S. Kanwal and Thomas E. Finger
Department of Cellular and Structural Biology, University of Colorado School of Medicine, 4200 East Ninth Avenue, Denver, Colorado 80262

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Taste and tactile fibers in the facial nerve of catfish innervate extraoral taste buds and terminate somatotopically in thefacial lobe (FL) $---$ a medullary structure crucial for gustatory-mediatedfood search. The present study was performed to determine theneural linkages between the gustatory input and the spinal motoroutput. Spinal injections of horseradish peroxidase (HRP) labelspinopetal cells in the octaval nuclei, the nucleus of the mediallongitudinal fasciculus, and reticulospinal neurons (Rsps) inthe brainstem medial reticular formation (RF), including the Mauthnercell. A somatotopically organized, direct faciospinal system originatingfrom superficial cells scattered in the lateral lobule of thefacial lobe (ll) is also labeled. The brainstem reticulospinalcells are segmentally organized into 14 clusters within eightsegments of the reticular formation and includes one cluster (RS5)directly ventral to the FL. Injections of HRP or fluorescent tracersinto the medial lobule of the FL label a facioreticular projectionterminating around the Rsps of RS5. DiI injections into this areaof the RF retrogradely label deeply situated bipolar neurons,especially in the medial and intermediate lobules of the FL. Electrophysiologicalrecordings in and around RS5 show units with large receptive fieldsand with responses to chemical and tactile stimulation. The FLprojects to the spinal cord via two pathways: (1) a topographicallyorganized direct faciospinal pathway, and (2) an indirect facioreticulospinalpathway in which reticular neurons process and integrate gustatoryinformation before influencing spinal circuitry for motor controlduring food search.
Key words: facial lobe; nucleus of the solitary tract; reticular formation; taste; reticulospinal; feeding

INTRODUCTION

Many animal species possess elaborate sensory systems specialized for locating food in their environment. For example, batsuse a highly developed audiovocal system to hunt insects via echolocation(Galambos, 1942; Griffin, 1958), toads have a visual system specializedfor detecting worm-like movements (Ewert, 1970), pit vipers useinfrared receptors for tracking their prey (Molenaar, 1974; Gruberget al., 1979), and electric fish use electroreception for detectingand locating food in their environment (Bullock, 1982). Catfishhave a highly sensitive, large gustatory sense that plays a criticalrole in the search for food in muddy waters (Herrick, 1901, 1904,1905; Bardach et al., 1967; Atema, 1971; Caprio et al., 1993;Valentincic and Caprio 1993). Catfish can detect concentrationdifferences between their maxillary barbels and make turning movementsappropriate to locate food (Johnsen and Teeter, 1980). The extraoral(facial nerve-innervated) taste receptors are highly sensitiveto amino acids (Caprio, 1975, 1978) and are mapped spatially withinthe facial lobe (FL), the primary gustatory nucleus for externaltaste (Finger, 1976; Marui and Caprio 1982; Hayama and Caprio,1989). Neuroethological studies show that the FLs are necessaryfor food localization (Atema, 1971). These studies suggest thatcatfish use the facial gustatory sense to detect and orient tochemical stimuli at a distance. Gustatory information must, therefore,reach motor or premotor centers within the CNS to modulate orientationand swimming, which are two essential behavioral components offood search.

Previous anatomical studies (Herrick, 1905; Finger, 1978; Morita and Finger, 1985) have established that the FL gives riseto three major projection systems: (1) an ascending lemniscalpathway reaching diencephalic levels directly and via a pontinerelay, (2) a descending system ending in the funicular nucleiand spinal cord (Sp) dorsal horn, and (3) local reflex connectionsto brainstem reticular formation. The ascending system does notreach the optic tectum (TeO), often a site of multimodal sensoryintegration into a unified spatial map of the surroundings (Hartlineet al., 1978; Knudsen, 1982). Although the FL maintains a highlyordered somatotopic map of gustatory space, this map is not retainedin any of the higher lemniscal nuclei (Lamb and Caprio, 1992;Lamb and Finger, 1996). Thus, spatial information about gustatorystimuli must be relayed to premotor centers from the FL and notfrom higher-order gustatory nuclei.

The present study was initiated to identify premotor gustatory centers and descending gustatomotor pathways in the channelcatfish, Ictalurus punctatus. In an effort to localize these pathways,we describe here the reticulospinal system, because it has notbeen described adequately in siluroid fishes. Electrophysiologicalinvestigation of the relevant areas of the reticular formationwere performed to determine whether neurons located there respondto chemical as well as tactile cues, and whether the receptivefields of the reticular neurons are well defined and punctateas in the FL, or relatively nonspecific and broad as in higher-ordergustatory nuclei (Lamb and Caprio, 1993).

MATERIALS AND METHODS
Animal acquisition and maintenance. Channel catfish, Ictalurus punctatus, (weighing 50-150 gm) were obtained from a localfish farm (Cline's Trout Farm, Boulder, CO). The fish were maintainedin aquaria kept at a 12 hr light/dark cycle. Animals were generallyused for electrophysiological studies within 2-3 weeks after beingtransported to laboratory aquaria. Recordings from the reticularformation were obtained from >15 animals. In a few cases, therecording was followed by iontophoretic injection of HRP at therecording site. All studies were approved by the University ofColorado Health Science Center Institutional Animal Use and CareCommittee.

Neuroanatomical studies. Connections of the FL and reticular formation (RF) were examined by the use of two in vivo tracers,HRP and dextran amines, and by postmortem diffusion of the carbocyaninedye, diI (1,1 $'$ -dioctadecyl-3,3,3 $'$ ,3 $'$ -tetramethylindocarbocyanine perchlorate).Neuroanatomical results from in vivo tracer studies are basedon horseradish peroxidase (HRP; Sigma, St. Louis, MO; Type VI)injections into the Sp of 12 animals and into the FL or reticularformation of 14 animals. Formaldehyde-fixed brains of additionalanimals were used to obtain Nissl-stained sections in the transverseand horizontal planes for studying the normal pattern of nuclearorganization and for postmortem tracing. For postmortem studies,small crystals of diI were applied to the FL in previously fixed(4% buffered paraformaldehyde) brains. After 2-8 weeks, the tissuewas sectioned on a vibratome and examined with a Zeiss (Thornwood,NY) epifluorescent microscope.

Surgery. The animals were anesthetized by transferring them to a tank containing tricaine methane sulfonate (MS) 222 (~150mg/l). The anesthetized animals were positioned over a Plexiglasbase and respired artificially by water containing MS 222 (~90mg/l). The actual dose of the anesthetic varied with the sizeand the physiological condition of the animal and was adjustedto eliminate respiratory movements. The appropriate portion ofthe cranium was removed by means of a dental drill and the cerebrospinalfluid and mesenchymal tissues were aspirated from the surfaceof the brain.

Single-label HRP studies. HRP injections were accomplished by an insect pin coated with a paste of HRP (Finger, 1976) or deliveredcentrally using iontophoresis (Kanwal et al., 1988). For smalliontophoretic injections of HRP in the reticular formation, atrain of positive current pulses of 3-5 µA (duration of pulseand interstimulus interval: 5 or 10 sec) was applied for 10-15min using a A360, WPI constant current stimulator. HRP was appliedto the FL (primary gustatory nucleus) in the channel catfish toidentify the location of descending pathways. Unilateral and bilateralinjections of HRP were also made in the ventral horn and dorsomedialregions of the Sp. HRP was injected at either of two anteroposteriorlevels of the Sp; anterior injections were made immediately caudalto the dorsal fin, and posterior injections were made caudal tothe adipose fin and immediately anterior to the tail. A longitudinalincision, parallel and dorsal to the lateral line, was made inseparate animals for injection of HRP into the Sp. The muscletissue was separated gently with a pair of blunt forceps untilthe vertebral column was visible. The vertebral cartilage wasnipped with a pair of fine scissors and HRP crystals were insertedinto the Sp and canal. At the same time, the Sp was pinched atthe intended site of injection to facilitate uptake of HRP. Afterallowing 3-7 d for transport of HRP (3-4 d for FL injection and4-7 d for Sp injections), the animal was perfused with 4% glutaraldehydesolution. Frozen sections were collected in cold 0.1 M phosphatebuffer and treated according to either a modified Hanker-Yatesprotocol (Bell et al., 1981) or the tetramethylbenzidine method(Mesulam, 1978).

Single-label DiI studies. The carbocyanine dye, DiI was used as a postmortem retrograde tracer to determine the nature anddistribution of the cells that give rise to the facioreticularprojection. For these experiments, the brain was removed fromtwo catfish that had been perfused with 4% buffered paraformaldehyde,as above. After the brains were fixed for $>=$ 2 d, a 1-2 mm slabof the medulla was prepared by making transverse cuts rostraland caudal to the FL. The tissue, except for the medial reticularformation (RF) was covered with 2% agar to prevent inadvertentapplication of the dye to nontargeted areas. Small crystals ofDiI were then inserted bilaterally into the RF in the vicinityof cluster RS5, i.e., the area in receipt of facioreticular fibers.The tissue was then covered completely in agar and placed intofresh fixative at room temperature. After 2 weeks or 4 months,the agar was removed and the tissue was sectioned on a vibratomeat 40-50 µm. The sections were coverslipped with fluoromount andwere viewed with a Zeiss epifluorescent microscope equipped withrhodamine filter cube.

Double-label studies. In two cases, tracers were applied to both the Sp and FL. In one of these, two different fluorescent10K dextran amines were used; in the other, biotinylated dextranwas applied to the Sp and HRP was applied to the FL. In the formercase, fixation was with 4% paraformaldehyde in phosphate bufferand in the latter case, 2% paraformaldehyde and 0.2% glutaraldehydein buffer. The tissues were embedded in egg yolk, postfixed foran additional 2.5 hr, then transferred to sucrose buffer for cryoprotection.The next day, 60 µm transverse sections were cut on a cryostat.

For dual fluorescence, the sections were mounted and coverslipped in fluoromount. For the biotin-HRP label, free-floatingsections were reacted in a metal-intensified DAB solution containing25 mg DAB, 20 mg ammonium chloride, 0.5 ml of 1% cobalt chloride,0.8 ml of 1% nickelous ammonium sulfate, and 25 µl of glucoseoxidase (Sigma Type V; 4 mg/ml in acetate buffer) in 50 ml of0.1 M phosphate buffer. The reaction was started with the additionof 2 ml of 1% $beta$ -D-glucose and monitored visually. This reactionproduced a blue-black precipitate at the sites of peroxidase activity.After completion of the reaction, the sections were rinsed inphosphate buffer and placed overnight in avidin-biotin complexin PBS plus 0.3% Triton X-100 per standard ABC protocols. Thesections were reacted with nonintensified DAB (25 mg/50 ml bufferplus 30 µl of 3% hydrogen peroxide) the next day after rinsingin buffer, thereby producing a brown reaction product at the sitesof ABC binding.

Three-dimensional reconstruction of the reticulospinal system. Large unilateral injections of HRP were made in the ventralhorn of the Sp and the tissue was processed for visualizationof the labeled cells as explained in the previous section. Forpurposes of reconstruction, horizontal sections of the brainstemwere positioned above a light box and an image was stored electronicallyon the hard drive of a Macintosh IIx (Apple, Inc.) using the IMAGEprogram. The serial sections were positioned sequentially andlined up on the monitor using the lacuna of the fourth ventricleand large blood vessels as fiducial marks. Each stored image wasexamined for labeled cell bodies with a nucleolus and X-Y coordinatesof these were recorded by clicking a cross-hair on the screen.In case of ambiguity, the corresponding original section was examinedunder the microscope before registering a labeled cell on thecaptured image. The X-Y coordinates of labeled cells in each sectionwere transferred to a computer-aided design software package.This enabled the integration of all sections into a three-dimensionalimage, which could be viewed and plotted from any specified azimuthand elevation.

In addition, direct electronic image composites were prepared by scanning the microscopic sections at 1700 dpi with a NikonCoolscan slide scanner. The images were aligned by rotation andtranslation in Photoshop running on a Quadra 800 Macintosh computer.Intrinsic blood vessels were used as fiducial structures.

Electrophysiological recordings
Surgery. The fish were immobilized with Flaxedil (~0.1 ml of a 20% solution) and prepared for surgery in a Plexiglas holder.The head was kept in position by small brazing rods inserted throughvertical Plexiglas plates so that minor opercular movements wouldnot affect the stability of the recordings. A local anestheticwas applied over the skull before surgery by injecting ~0.1 mlof Xylocaine (1% lidocaine hydrochloride) under the skin or byrubbing in the anesthetic with a cotton swab. A flap of the epitheliumwas incised, flipped back, and the skull was opened with a pairof rongeurs or a Dremel drill.

Data acquisition and analysis. For purposes of recording, a borosilicate glass micropipette filled with 2 M NaCl was loweredinto the brain with a Narashige hydraulic microdrive. In somecases, the micropipette was back-filled with a dilute (~10%) filteredsolution of HRP in 0.1 M phosphate buffer, pH 7.2, for markingthe recording site. Beyond a depth of 2.0 or 2.5 mm (dependingon the size of the fish) the movement of the electrode was pausedand the epithelium was stimulated by gentle rubbing with a sable-hairbrush. The extent of the tactile receptive field was determinedby touching various areas of the fish with the brush or by directinga gentle stream of water (through a PE20 tube) at different areasof the skin, mouth, or gills. In the event of a tactile response,a fine water stream was directed to an area within the receptivefield and chemical stimulation was accomplished by injecting abolus of stimulus (millimolar concentrations of L-alanine, L-arginine,or L-proline, a mixture of all three amino acids, or a complexfood stimulus consisting of filtered beef liver extract; Kanwaland Caprio, 1987) into a stream of water flowing constantly. Inthis way, application of the chemical produced essentially nochange in the flow characteristics of the ongoing stimulus stream,i.e., this procedure permits the separation of chemical from mechanicalcues. The exact concentration of the applied chemicals cannotbe determined exactly with this system but was estimated to be~50% of the injected concentration (Kanwal and Caprio, 1987).Occasionally, chemical stimuli were tested even in the absenceof a unit response to mechanical stimulation. No units were foundthat responded only to chemical stimulation. The recorded neuralactivity was stored along with voice data on separate channelsof magnetic tape via a video cassette recorder (JVC, model HR-D470U).The tape was played back to an oscilloscope for photographingimpulse response patterns onto photographic film in a kymograph(Nihon-Koden).

RESULTS

Prespinal brainstem neurons
Small unilateral injections of HRP were restricted to the ventral horn of the Sp, whereas large injections extended eitherunilaterally to the lateral and dorsomedial region or bilaterallyto the ventral horn region of the opposite side. Only quantitativedifferences were observed between the labeling after similar injectionsof HRP into the rostral and the caudal levels of the Sp. The resultsdescribed in the following sections pertain primarily to spinalinjections at the level of the dorsal fin. Any differences observedin the labeling from spinal injections made at caudal levels areindicated in the appropriate sections of the text.

In general, after spinal injections of HRP, retrogradely filled cells occurred (Fig. 1) ipsilaterally in the ll, and occurredbilaterally in the primary octaval nuclei (n. Oct.), the reticularformation (RF), and the nucleus of the mlf (data not shown). Fiberbundles labeled within the Sp were restricted mostly to the ventraland lateral funiculi of the Sp. Within the reticular core of thebrainstem, the majority of labeled neurons resided in the ventromedialRF (Figs. 1, 2). Smaller neurons were also labeled in the lateralRF and the ventromedial RF (Fig. 1J, small triangles). In addition,anterogradely filled dense fibers terminals were observed in theventrolateral RF of the medulla (Fig. 1 H-J, dots) as describedfor other species by Hayle (1973). The facial and reticulospinalprojections are described in greater detail below.
Fig. 1. Chartings of HRP-labeled cell bodies in transverse sections through the Sp and medulla of the catfish brain after a largeunilateral injection of HRP in the Sp at the level of the anteriordorsal fin. A dorsal view of the catfish brain indicating thelevels of the transverse sections is shown in the top right corner.Triangles denote labeled cell bodies; dots represent labeled fibers.
[View Larger Version of this Image (42K GIF file)]

Fig. 2. A, Photomicrograph of a horizontal section through the FL of the right side showing labeled cell bodies (arrowheads) in thelateral lobule of the FL after spinal injection of HRP. Anterioris toward the top; medial is at left. B, Higher magnificationview showing faciospinal cell morphology.
[View Larger Version of this Image (91K GIF file)]

Direct faciospinal projections
Large injections in the Sp that included the dorsomedial quadrant also labeled medium-size (20-30 µm) cells situated superficiallyin the ll, ipsilateral to the site of injection (Fig. 2A). Approximately20 neurons were labeled after injections at the level of the firstdorsal fin, whereas more caudal injections (caudal to the seconddorsal fin) labeled only five to seven neurons. Filling of thedendrites of these neurons is generally incomplete (Fig. 2B).The large cell bodies, however, were filled densely with the reactionproduct and were scattered within the lateral lobule. In one case,longer survival times resulted in filling of most of the dendriticarbor of a few cells. Observations under higher magnificationshowed that although these neurons had an expansive dendriticarbor, the dendritic fields of neighboring neurons were largelynonoverlapping.

Reticulospinal projections
Retrograde labeling of reticular cells after spinal injections of HRP was examined in transverse, horizontal, and sagittalsections of the brain. Horizontal sections provided a convenientway to study the axial organization of the reticulospinal system,whereas transverse sections were useful to examine the dorsoventralseparation of clusters of labeled neurons. The location, clusteringpatterns, and cellular morphology, however, differed significantlybetween the caudal medullary, rostral medullary, and pontine andmesencephalic RF. As described previously (Lee et al., 1993),the RF is divisible into eight segments (RS 1-8). We find thatmany of the segments can be further divided into cell clustersthat share similar morphologies and position (Fig. 3C).
Fig. 3. Labeled cell bodies of the reticular formation in horizontal sections after a large bilateral injection of HRP in the Sp atthe level of the anterior dorsal fin. A, Image of a single horizontalsection as processed with the "NW Gradient" kernel in the imageto yield a pseudo-Nomarski effect. Asterisk indicates verticallyoriented blood vessel used for alignment of photocomposite sectionsshown in (B). Arrow indicates Mauthner cell. B, Electronic photocompositeof four horizontal sections including that shown in A. As in A,the asterisk indicates the fiduciary blood vessel and the arrowindicates the Mauthner cell. Relevant reticulospinal (RS) groupsare indicated by number. C, Diagrammatic representation of thereticulospinal system from a computer-generated three-dimensionalreconstruction of serial horizontal sections from the whole brainstemof a different animal. The injection in this case entirely coveredthe right side of the partially transected Sp and also diffusedto the opposite side. The 14 clusters that were distinguishedon the basis of spatial rotations of the image using a computerare shown by dashed boundaries. These are presumed to extend overeight rostrocaudal segments, RS1-RS8, based on the terminologyadopted by Lee et al. (1993). Note the location and extent ofthe cluster (RS5) that receives gustatory projections from theFL (circle). The thickness of the reconstructed brainstem containinglabeled cells is 900 µm.
[View Larger Version of this Image (86K GIF file)]

Caudal medullary reticular formation
At levels caudal to the vagal lobe (VL), large spinal injections of HRP labeled a continuous row of medium-size (10-20 µm)cells on both sides of the medial longitudinal fasciculus (mlf;including segments RS 7 and 8). A heavier label and a larger numberof cells were found ipsilateral to the site of injection. Thecell labeling on the contralateral side was also continuous, butthe labeled cells were scattered loosely in this region. Thispattern is quite similar to what is seen in the central gray ofrostral regions of the Sp (Fig. 3A).

Rostral medullary and pontine reticular formation
At the level of the FL and VL, three distinct clusters (RS5, RS6, RS7) of reticulospinal cells can be distinguished in theventromedial RF (Figs. 1, 3). These clusters consist of 15-20µm cells and are bilaterally symmetric in the degree of labeling.Of these three clusters, the middle one contains relatively largecells (~20 µm). The most caudal of these clusters contained acompact group of ~15 cells, whereas the most rostral cluster wasdivisible into two laterally placed subgroups.

These cell clusters were separated by decussating fiber bundles. Some of the larger cells had dendrites that extended intothe lateral RF. The most rostral cluster corresponded to the levelof the facial motor nucleus.

Lateral to the facial motor nucleus, several medium-size (~15 µm) cells were labeled bilaterally in the octaval nuclear complex(Fig. 1K-L). In horizontal sections, these cells appeared as anarrow band at the lateral margins of the brainstem. Immediatelyrostral and dorsolateral to the facial motor nucleus, the Mauthnerneurons were labeled heavily bilaterally if the injection siteencroached even partially to the opposite side, because the large-diameteraxons of the Mauthner neurons are situated medially in the Sp.In this respect, the Mauthner neuron provided a good way to confirmthe unilaterality of the injection site.

Mesencephalic reticular formation
The mesencephalic prespinal neurons are similar to those described in other species (Prasada Rao et al., 1987; Lee and Eaton,1991) and will not be described in detail here. Briefly, clustersof labeled cells extended laterally and rostrally on both sidesof the mlf. In the caudal region of the mesencephalic reticularformation, one lateral cell group was also labeled bilaterally.The labeling in this nucleus was heavier on the contralateralside compared with the side ipsilateral to the injection site.

Three-dimensional arrangement of Rsps
Serial reconstructions of horizontal sections of spinally injected brains revealed that the HRP-labeled neurons are organizedin a segmental manner along the anteroposterior axis and extendover the length of the medulla (Fig. 3). In a parasagittal view,Rsps are arranged as a punctuated longitudinal column of cellsthat is inclined dorsally toward rostral levels of the ventralbrainstem. Also, cells at rostral levels are located more laterallythan those in the caudal medulla (Fig. 3C).

A serial reconstruction was prepared from one fish with a partly bilateral (i.e., covering all of one side and encroachinginto the medial half of the other side) injection of HRP intothe rostral Sp (Fig. 3C). Altogether, 324 neurons are labeledcontralateral to the injection site in the fully reconstructedset. Of these, 306 cells were localized to 14 clusters in theventromedial RF, whereas 18 neurons are located too laterallyto be included in any cluster. Clusters in segments RS5-RS8 showan ipsilateral bias in labeling, whereas the Mauthner neuronsand clusters rostral to them are more heavily labeled on the sidecontralateral to the main injection site. Thus, the total numberof neurons projecting to any one side of the Sp is estimated at~360. The clusters are postulated to lie in eight metameric segments(RS1-RS8), with RS4 containing the Mauthner neurons as suggestedby Lee et al. (1993). The rostral segments RS1-RS5 contain twoclusters each (medial and dorsolateral), whereas each of the remainingcaudal segments contain one cluster organized relatively loosely.

The three-dimensional reconstruction identified two clusters of cells at the level of segment RS5 in the ventromedial RF.This corresponds to the mid to caudal region of the FL (as shownin Figs. 1J, 4) and matches the level at which facioreticularprojections were observed after injections of tracer into theFL (Fig. 4B).
Fig. 4. Photomicrographs of the right side of the ventral half of transverse sections through the brainstem at the level of the FL(approximate level of Fig. 1J). A, Reticulospinal neurons (Rsps)in segment RS5 labeled retrogradely by spinal injection of HRP.B, Approximately the same field of view showing projections fromthe FL as revealed by diI tracing.
[View Larger Version of this Image (144K GIF file)]

FL injections
The surface of the FL was divided approximately into quadrants. Small, superficial injections of HRP were made at variousloci in the FLs of separate animals. In general, the results ofascending and descending projections from the FLs were similarto those reported earlier (Finger, 1976, 1978; Morita and Finger,1985). For the present study, only new findings related to theprojections to premotor areas such as the RF are described.

Connections of the lateral lobule
Injection of HRP into the ll-labeled fibers terminating in the immediate vicinity of the injection site and also labeled severalfibers terminating sparsely in the medial and intermediate lobules.The most heavily labeled fiber groups included the primary inputsto the FL and the large-diameter fibers exiting the FL in theipsilateral secondary gustatory tract. A few (2-3) fibers werealso seen to decussate via the internal arcuate fibers (iaf) andtravel in a rostro-dorsal direction before terminating in superficialregions of the lateral lobule of the opposite side.

A separate group of fibers continued in a ventromedial direction after exiting the FL. Some of these fibers seemed to originatefrom retrogradely filled neurons located adjacent to the mlf,both ipsilateral and contralateral to the site of injection (seealso Morita and Finger, 1985, their Figs. 4 H, 8B). These neurons(~15 µm in width and 50 µm in length) were similar to one anotherin terms of their bipolar shape, situation between the medialRF and the intermediate nucleus of the FL, and orientation ofdendrites directed ventrally into the medial RF. A second pairof filled reticular cells were more triangular and located medialto the medial RF and adjacent to the mlf. In this case, the fillingof the cell ipsilateral to the site of injection was more intensethan the one on the contralateral side. In addition, as reportedelsewhere (Finger, 1978; Morita and Finger, 1985), retrogradelabeling was observed in cells of the nucleus lobobulbaris (nLB),whereas labeled fibers and terminals occurred in the parvocellularportion of nLB and preoptic nucleus.

Connections of the medial lobule
Injections of HRP into the medial lobule labeled local areas and fibers similar to those observed for the lateral lobule.Injections into the caudomedial quadrant, however, labeled a denseaxonal projection of anterogradely filled fibers (Fig. 5). Theseconnections were further attributed to one of two descending routes.Along one route, bipolar neurons in the dorsomedial reticularformation connected to the FL dorsally and to the ventromedialreticular formation ventrally. Along the other route, a slenderfacioreticular tract (FRt) (Fig. 5) originated from neurons inthe caudomedial region of the FL (including the medial lobuleand the medial region of the intermediate lobule), and projecteddirectly to the ipsilateral ventromedial reticular formation.At higher magnifications, terminal swellings were observed adjacentto the cell bodies in the medial reticular cells (Fig. 6A). Severalfibers also cross the midline between fascicles of the mlf andthe reticulospinal tract to terminate in the vicinity of the medialreticular neurons of the contralateral side. A few cell bodieswere also labeled in the dorsomedial reticular formation.
Fig. 5. Low-power composite photomicrograph of projections of the FL as shown by diI tracing. Three high-power, high resolution fluorescentimages were composited and scaled onto a low resolution imagefor orientation. The arrow shows the facioreticular fibers (FRt).A higher magnification view of the area of termination of thisfiber system in an adjacent section is shown in Figure 4B.
[View Larger Version of this Image (92K GIF file)]

Fig. 6. A, Photomicrograph of the RS5 group from a double-label preparation. HRP was injected in the Sp and appears gray in this picturetaken with a red-orange filter. Biotinylated dextran amine wasinjected in the FL and reacted to appear black in this micrograph.Note the black varicosities associated closely with the somataand proximal dendrites of two labeled reticulospinal neurons (Rsps).B, Photomicrograph of the ventral part of the medial lobule ofthe FL after a diI injection into the medial reticular formation.A retrogradely labeled neuron deep in the lobule is indicatedby the arrow. Fourth ventricle is at left; arrow indicates retrogradelyfilled cell.
[View Larger Version of this Image (140K GIF file)]

Deep medial injections of HRP into the FL also labeled a tract of fibers decussating at the level of the mlf and caudal tothe level of the iaf. These fibers terminate mostly in the intermediatenucleus of the FL (niF) of the opposite side. Electrophysiologicalrecordings from this region of the FL show that neurons in theniF have large receptive fields that are sometimes bilateral (Hayamaand Caprio, 1989).

To rule out the possibility that the FRt might be entirely attributable to collaterals of retrogradely labeled RF neurons,diI was applied to the medial RF. Such application results inretrograde labeling of large (20 × 40 µm) bipolar neurons andmedium-sized (12 × 20 µm $-$ 15 × 25 µm) bipolar neurons situateddeep in the FL (Fig. 6B). The majority of these neurons lie withinor adjacent to the fiber bundles lying along the ventral marginof the intermediate and medial lobules. A few scarce facioreticularcells can be found in association with fiber bundles of the laterallobule.

Responses of single reticular neurons
The neurophysiological data included in this study are presented only in so far as to establish whether: (1) chemical or tactilestimuli influence RF neurons of RS5, and (2) receptive fieldsof the neurons of RS5 are similar to those of the FL in maintaininga fine-grain somatotopically order map of the body surface. Inaddition to multiunit mapping studies (results not presented here),we obtained single-unit data from >60 neurons in the medullaryRF. Neurons in this region of the RF were generally divisibleinto three categories depending on their rate of spontaneous activity.Thirty-two percent of neurons exhibited very low rates (<1 spike/sec)or no spontaneous activity. This group of neurons showed an irregularspontaneous discharge rate of 0.64 ± 0.56 (mean ± SD) spikes/secand an excitatory response averaging 12.1 ± 8.2 spikes/sec. Themajority (50% of the population) of neurons showed a moderaterate (2-5 spikes/sec) of spontaneous activity. This group, witha mean rate of 2.72 ± 1.45 spikes/sec, showed a response, eitherexcitatory or inhibitory, to chemical and/or tactile stimulation.Finally, several neurons (18% of the population) showed high ratesof spontaneous activity and responded to taste and tactile stimulationeither with excitation or inhibition. One such unit that was excitedby tactile stimulation and inhibited by chemical stimulation isshown in Figure 7B. Several of these neurons fired rhythmicallyin synchrony with respiratory movements of the operculum. Theseneurons in the dorsomedial RF may belong to the "respiratory center"in the medulla. As shown for unit 3 in Figure 7A, some of therhythmically bursting neurons respond with an increase in thenumber of spikes per burst, whereas for other units, chemicalstimulation disrupted the bursting pattern of activity (Fig. 7A,unit 4). The other two types of units, those with slow to mediumrates of spontaneous activity, were intermingled within the ventromedialregion of the RF. Neurons responsive to tactile stimulation ofthe extraoral surface generally showed little or no spontaneousactivity. The spontaneous patterns of activity and responses totaste and tactile stimuli of a few neurons are shown in Figure7.
Fig. 7. A, Multiunit, and B, single unit recordings to show the different patterns of spontaneous activity and responses of tasteand touch sensitive reticular neurons at five different recordingsites from a single animal. The numerical labels indicate recordingsite and the lower case alphabetic labels indicate responses tostimulus applications at different parts of the receptive fieldand/or to different stimuli. A1 shows a strong phasic responseto tactile stimulation of the proximal portion of the maxillarybarbel ipsilaterally and to the flank bilaterally and a weak responseto stimulation of the head region on either side. Tactile stimulationof the contralateral maxillary barbel did not produce an obviousresponse. Cells at 2 show little spontaneous activity but respondedvigorously to tactile stimulation of the head region. Cells at3 and 4 exhibit a rhythmic bursting pattern (~1 spike/sec) ofspontaneous activity and respond to chemical stimulation witheither a higher firing rate within each burst (3) or with a tonicdischarge and transient disruption of the rhythmic pattern (4).The single unit shown in 5 is bimodal and responds with excitationand inhibition to tactile and taste stimuli, respectively. Thereceptive field of this unit is shown as stippled areas mappedon a dorsal view of the catfish on the left. Arrows indicate stimulusonset. All recordings, except 4, have a common time scale.
[View Larger Version of this Image (70K GIF file)]

The majority of neurons responded to punctate or tactile stimulation consisting of gliding movements of a soft brush. Bothadaptive and nonadaptive units were present and stimuli as shortas 200 msec in duration were sufficient to produce a response.As in the facial and vagal gustatory lobes, it was relativelydifficult to elicit and quantify a response to a chemical stimulus,perhaps because of complexities of generating natural stimulusprofiles. A mixture of amino acids (L-isomers of alanine, arginine,and proline at 10³ M concentration) and the liver extract were sometimes effectivein producing a response.

With regard to the spatial organization of receptive fields, bilateral receptive fields extending over the whole flank regionwere commonly observed (Fig. 8, unit 4). Units with receptivefields in the head region tended to have smaller receptive fields,typically restricted only to the proximal or distal portion ofthe maxillary barbels (Fig. 8, units 1, 2, and 3). These receptivefields are much larger than the receptive fields of FL neurons(Hayama and Caprio, 1989).
Fig. 8. PST histograms to show the variety of response properties exhibited by six different reticular units. The receptive fieldsof reticular neurons ranged from those restricted to the snoutregion to those covering most of the extraoral surface and/ororal cavity (see text). Stimuli were applied at time 0. Stimulustype is indicated at the top of each PST along with the locationof the stimulus application as shown on a dorsal view of the catfish.Neuron labeled as 1 is bimodal and exhibits a biphasic excitatory/inhibitoryresponse to tactile stimulation and tonic inhibition to tastestimuli. Activity can be suppressed for $<=$ 18 sec after applicationof millimolar concentrations of amino acids and a commerciallyobtained bait mixture. 2a and 2b show an excitatory versus inhibitoryresponse of two neurons at the same recording site. The cell shownin 3 responds with excitation and inhibition to ipsi- and contralateralreceptive fields, whereas the cell shown in 4 responds similarlyto ipsi- and contralateral mechanical stimulation. These datawere obtained with computer-controlled application of mechanicaland chemical stimuli.
[View Larger Version of this Image (44K GIF file)]

In a few cases, iontophoretic injections of HRP through the recording electrode confirmed that these recordings were obtainedfrom the vicinity of dendrites or cell bodies of neurons in theRS5 segment of the RF. As shown in Figure 9, we were successfulin labeling a few or single cells at the recording site usingthis technique. This type of labeling from extracellular recordingswas possible because of the typically large size of reticularneurons.
Fig. 9. A, PST to show the response of a reticular neuron to tactile stimulation of the mandibular barbels. Bin width is 150 msecand the total time is 13 sec. B, Schematic cross-section throughthe level of the FL (approximate level of Fig. 1J) to show thelocation of recording site at a depth of 2.88 mm within the medulla.C, HRP-filled neuron after iontophoretic injection of a 10% solutionof HRP at one of its dendrites from location of recordings shownin A.
[View Larger Version of this Image (103K GIF file)]

DISCUSSION

Medullary gustatospinal projections
Our results show that FL neurons have both direct and indirect connections with the Sp. The direct connections and pathwaysconstitute a monosynaptic route from the FL to the ipsilateraldorsal horn (Finger, 1978), whereas the indirect facioreticulospinalsystem seems to involve premotor pathways. The facioreticularprojection is quite circumscribed, involving only RF neurons ofsegment RS5. Recordings from neurons in this area show that thesecells respond to chemical and tactile stimuli applied to largeareas of the body or gills. Thus, chemosensory information necessaryfor directed food search has access to these prespinal neurons.Further, the reticular neurons exhibit relatively large receptivefields more similar to those of the niF or secondary gustatorynucleus (Hayama and Caprio, 1989; Lamb and Caprio, 1993) thanof the main portion of the FL. Thus, how the information encodedin the fine-grain somatotopic map in the FL is used by other areasof the brain remains enigmatic because none of the higher-orderprojection systems seems to retain this information.

This situation may be analogous to the remapping of visual information between the TeO and the midbrain premotor nuclei (Masino,1992). In that system, the retinotopically organized representationof visual space in the tectum is transformed to orthogonal movementcoordinates in the mesencephalic tegmentum. In this tectotegmentalsystem, as in the facioreticular system examined in this work,no simple anatomical remapping occurs between the primary sensorymap and the premotor control centers. That is, a small tracerinjection in the primary sensory area does not yield a discrete,limited projection to a portion of the premotor center. Rigorousanalysis of the midbrain premotor area has shown that it is organizedin a movement coordinate system. Similarly, more rigorous studyof the RS5 complex may reveal a map of orienting movements.

Whereas the facioreticular projection system affects premotor neurons of the reticular formation, the direct faciospinal systemdoes not. This direct system extends from the ll to terminatein the spinal dorsal horn (Finger, 1978; this study). That onlythe lateral lobule gives rise to this pathway is noteworthy inthat this lobule contains the representation of the territoryinnervated by the recurrent facial nerve, i.e., the same skinareas innervated by the segmental spinal nerves. Thus each dermatomereceives sensory innervation from two sources: the segmental spinalnerve and from segmental branches of the recurrent facial nerve(Herrick, 1901). Taste buds within a dermatome are innervatedby the recurrent facial fibers, whereas general somatosensoryreceptors in the same dermatome presumably are innervated by spinalnerves. Despite this seeming separation of modalities by nerve,the recurrent facial nerve exhibits both tactile and chemosensoryresponses (Davenport and Caprio, 1982). Thus, the specific contributionof the facial and spinal nerves to overall detection of cutaneousstimuli remains unclear. The direct projection from the ll tothe spinal dorsal horn is organized somatotopically, i.e., neuronsin the tail representation of the FL project to the caudalmostlevels of the Sp. Accordingly, the direct facioreticular systemmay be more involved in correlation of the facial and spinal nervesensory inputs from a single region of skin rather than in spinalmotor control.

The major route by which gustatory input is likely to influence spinal motor activity seems to be via the Rsps residing insegment RS5 (Lee et al., 1993) of the RF of the brainstem. Oneimportant finding of this study is that a localized subset ofreticulospinal cells, those of RS5, receive functional input froma gustatory lobe. The gustato-reticulospinal projection thereforerepresents a small part of the extensive reticulospinal system,which has been studied in aquatic species such as the lamprey(Rovainen, 1967, 1974), zebrafish (Kimmel et al., 1982; Mendelson,1986; Mendelson and Kimmel, 1986; Metcalfe et al., 1986), andmore recently goldfish (Prasada Rao et al., 1987; Lee and Eaton,1991; Lee et al., 1993) and dogfish (Timerick et al., 1992). Thecurrent study allowed us to define the origin and level of thegustatory projections in relation to the entire reticulospinalsystem in a catfish.

Only one reticulospinal cluster receives input from the FL. Possibly, different clusters in the reticulospinal system receivemajor inputs from different sensory modalities. Further, withina cluster, each Rsp may respond preferentially to stimuli presentedat one locus in space (Bosch and Paul, 1993).

Gustatory convergence and modulation of spinal motoneurons
We observed large tactile and chemosensory receptive fields of reticular neurons in the catfish. These receptive fields arequite different from the discrete, small receptive fields in theFL (Marui and Caprio, 1982). The receptive fields for reticularformation neurons extend typically either bilaterally over theanterior or posterior half of the body surface or unilaterallyover the entire flank region, and may involve both excitatoryand inhibitory effects. A few fibers that decussate transverselyacross bundles of the reticulospinal tract and terminate in thevicinity of ventromedial reticular neurons of the opposite sidemay account for the bilateral receptive fields of some reticularneurons. In addition, RF interneurons may relay information tothe contralateral side.

Our neuroanatomical results and the neurophysiological evidence for functional synaptic efficacy between facial inputs toreticular neurons suggest that facial gustatory information mayhave an important influence on the premotor (reticulospinal) centersthat control swimming. Our results outline an important neuralpathway mediating food search behavior, which is under the directinfluence of the highly sensitive extraoral taste system of thechannel catfish. Behavioral experiments have already shown thatdenervation of taste buds from one side of the flank results incircling toward the side of greater sensory input and locatingthe release point of a chemical stimulus such as dilute liverextract (Bardach et al., 1967).

The role of Rsps in vertebrate locomotion is well established (Grillner et al., 1987, 1995). Experiments involving electricalstimulation of Rsps also support a role of Rsps in the regulationof the pattern of locomotion and swimming movements. For example,in cats, electrical stimulation of the Rsps increased the amplitude,but not the stepping rate (Orlovsky, 1970). In goldfish, the circuitryfor controlling escape trajectories, which can be considered aspecial case of swimming, has been analyzed carefully using intracellularand optical recording techniques (Fetcho and Faber 1988; Fetchoand Svoboda, 1993; Fetcho and O'Malley 1995). In catfish, knowledgeof the neural mechanisms that mediate sensorimotor coordinationof swimming is lacking. A subset of gustatoreticular neurons,however, did show a monosynaptic projection to the Sp as evidencedby a short latency (<1 msec) response and lack of habituationto repetitive antidromic stimulation by a pair of electrodes insertedin the ventrolateral portion of the Sp (Kanwal, unpublished observation).

Gustatoreticular systems
Connections from a primary gustatory nucleus to the premotor reticular formation have been described also in rodents. Therostral, gustatory portion of the nucleus of the solitary tractmaintains direct and indirect projections to the parvocellularlateral reticular formation of the medulla (Beckman and Whitehead,1991). The portion of the reticular formation receiving the gustatoryinputs has connections to cranial motor nuclei implicated in mouthand tongue movements (Beckman and Whitehead, 1991; Ter Horst etal., 1991). Thus in mammals, too, a gustatoreticular system seemsinvolved in gustatory modulation of motor activity. In the caseof rodents, food acquisition entails tongue and mouth movements;the reticulomotor connection accordingly involves brainstem motornuclei. In catfish, food acquisition entails modulation of bodyposition and swimming orientation; thus, the reticulomotor connectioninvolves spinal motor networks. Whether any gustatory informationreaches prespinal reticular neurons in rodents is, however, unclear.Certainly, the region of the reticular formation receiving inputfrom the nucleus of the solitary tract contains neurons that projectto rostral spinal levels (Jones and Yang, 1985). Conceivably,such reticulocervical neurons might be involved in gustatory-evokedreflexive head turning in humans (Steiner, 1979) as well as rodents(Grill and Norgren, 1978).

In summary, two gustato-spinal pathways arise from the FL in the channel catfish. The direct faciospinal pathway may be involvedin coordinated processing of taste and somatic sensory inputsfrom the same site on the body surface. In contrast, the indirect,facioreticulospinal pathway may coordinate navigation toward food,i.e., the pattern of swimming movements, by modulating the activityof the spinal locomotor network.

FOOTNOTES

Received May 30, 1996; revised March 21, 1997; accepted April 7, 1997.

This work was supported by National Institutes of Health Grant DC00147 (T.E.F.) and National Institutes of Health TrainingGrant T32 NS 07083. We thank Bärbel Böttger for technical helpwith many of the neuroanatomical procedures and Steve Singer forassistance in preparation of the electronic images.

Correspondence should be addressed to Thomas E. Finger, Department of Cellular and Structural Biology, University of ColoradoSchool of Medicine, 4200 East Ninth Avenue, Denver, CO 80262.

Jagmeet Kanwal's present address: Department of Neurology, Georgetown University Medical Center, 3970 Reservoir Road NW, Washington,DC 20007.

REFERENCES

Atema J (1971) Structures and functions of the sense of taste in the catfish (Ictalurus natalis). Brain Behav Evol 4:273-294[Web of Science][Medline].
Bardach JE, Todd JH, Crickmer R (1967) Orientation by taste in fish of the genus Ictalurus. Science 155:1276-1278[Abstract/Free Full Text].
Beckman ME, Whitehead MC (1991) Intramedullary connections of the rostral nucleus of the solitary tract in the hamster. Brain Res 557:265-279[Web of Science][Medline].
Bell CC, Finger TE, Russell C (1981) Central connections of the posterior lateral line lobe in mormyrid fish. Exp Brain Res 42:9-22[Web of Science][Medline].
Bosch TJ, Paul DH (1993) Differential responses of single reticulospinal cells to spatially localized stimulation of the optic tectum in a teleost fish, Salmo trutta. Eur J Neurosci 5:742-750[Web of Science][Medline].
Bullock TH (1982) Electroreception. Annu Rev Neurosci 5:121-170[Web of Science][Medline].
Caprio J (1975) High sensitivity of catfish taste receptors to amino acids. Comp Biochem Physiol 52A:247-251.
Caprio J (1978) Olfaction and taste in the channel catfish: an electrophysiological study of the responses to amino acids and derivatives. J Comp Physiol 123:357-371.
Caprio J, Brand JG, Teeter JH, Valentincic T, Kalinoski DL, Kohbara J, Kumazawa T, Wegert S (1993) The taste system of the channel catfish: from biophysics to behavior. Trends Neurosci 16:192-197[Web of Science][Medline].
Davenport CJ, Caprio J (1982) Taste and tactile recordings from the ramus recurrens facialis innervating flank taste buds in the catfish. J Comp Physiol 147A:217-229.
Ewert J-P (1970) Neural mechanisms of prey-catching and avoidance behavior in the toad (Bufo bufo L.). Brain Behav Evol 3:36-56[Web of Science][Medline].
Fetcho JR, O'Malley DM (1995) Visualization of active neural circuitry in the spinal cord of intact zebrafish. J Neurophysiol 73:399-406[Abstract/Free Full Text].
Fetcho JR, Faber DS (1988) Identification of motoneurons and interneurons in the spinal network for escapes initiated by the Mauthner cell in goldfish. J Neurosci 8:4192-4213[Abstract].
Fetcho JR, Svoboda KR (1993) Fictive swimming elicited by electrical stimulation of the midbrain in goldfish. J Neurophysiol 70:765-780[Abstract/Free Full Text].
Finger TE (1976) Gustatory pathways in the bullhead catfish. I. Connections of the anterior ganglion. J Comp Neurol 165:513-526[Web of Science][Medline].
Finger TE (1978) Gustatory pathways in the bullhead catfish. II. Facial lobe connections. J Comp Neurol 180:691-706[Web of Science][Medline].
Galambos R (1942) Cochlear potentials elicited from bats by supersonic sounds. J Acoust Soc Am 14:41-49.
Griffin D (1958) In: Listening in the dark. New Haven, CT: Yale UP.
Grill HJ, Norgren R (1978) The taste reactivity test. I. Mimetic responses to gustatory stimuli in neurologically normal rats. Brain Res 143:263-279[Web of Science][Medline].
Grillner S, Wallén P, Dale N, Brodin L, Buchanan J, Hill RH (1987) Transmitters, membrane properties and network circuitry in the control of locomotion in lamprey. Trends Neurosci 10:34-41[Web of Science].
Grillner S, Deliagina T, Ekeberg O, El Manira A, Hill RH, Lansner A, Orlovski GN, Wallén P (1995) Neural networks that co-ordinate locomotion and body orientation in lamprey. Trends Neurosci 18:270-279[Web of Science][Medline].
Gruberg ER, Kicliter E, Newman EA, Kass L, Hartline PH (1979) Connections of the tectum of the rattlesnake Crotalus viridus: an HRP study. J Comp Neurol 188:31-42[Web of Science][Medline].
Hartline PH, Kass L, Loop MS (1978) Merging modalities in the optic tectum: infrared and visual interaction in rattlesnakes. Science 199:1225-1229[Abstract/Free Full Text].
Hayama T, Caprio J (1989) Lobule structure and somatotopic organization of the medullary facial lobe in the channel catfish, Ictalurus punctatus. J Comp Neurol 285:9-17[Web of Science][Medline].
Hayle TH (1973) A comparative study of spinal projections to the brain (except cerebellum) in three classes of poikilothermic vertebrates. J Comp Neurol 149:477-496[Web of Science][Medline].
Herrick CJ (1901) The cranial nerves and cutaneous sense organs of the North American siluroid fishes. J Comp Neurol 11:177-249.
Herrick CJ (1904) The organ and sense of taste in fishes. Bull US Fish Comm 22:237-272.
Herrick CJ (1905) The central gustatory paths in the brains of bony fishes. J Comp Neurol 15:375-456.
Johnsen PB, Teeter JH (1980) Spatial gradient detection of chemical cues by catfish. J Comp Physiol 140:95-99.
Jones BE, Yang TZ (1985) The efferent projections from the reticular formation and the locus coeruleus studies by anterograde and retrograde axonal transport in the rat. J Comp Neurol 242:56-92[Web of Science][Medline].
Kanwal JS, Caprio J (1987) Central projections of the glossopharyngeal and vagal nerves in the channel catfish, Ictalurus punctatus: clues to differential processing of visceral inputs. J Comp Neurol 264:216-230[Web of Science][Medline].
Kanwal JS, Finger TE, Caprio J (1988) Forebrain connections of the gustatory system in Ictalurid catfishes. J Comp Neurol 278:353-376[Web of Science][Medline].
Kimmel CB, Powell SL, Metcalfe WK (1982) Brain neurons which project to the spinal cord in young larvae of the zebrafish. J Comp Neurol 205:112-127[Web of Science][Medline].
Knudsen EI (1982) Auditory and visual maps of space in the optic tectum of the owl. J Neurosci 2:1177-1194[Abstract].
Lamb CF, Caprio J (1992) Convergence of oral and extraoral information in the superior secondary gustatory nucleus of the channel catfish. Brain Res 588:201-211[Web of Science][Medline].
Lamb CF, Caprio J (1993) Taste and tactile responsiveness of neurons in the posterior diencephalon of the channel catfish. J Comp Neurol 337:419-430[Web of Science][Medline].
Lamb CF, Finger TE (1996) Axonal projection patterns of neurons in the secondary gustatory nucleus of channel catfish. J Comp Neurol 365:585-593[Web of Science][Medline].
Lee RK, Eaton RC (1991) Identifiable reticulospinal neurons of the adult zebrafish, Brachydanio rerio. J Comp Neurol 304:34-52[Web of Science][Medline].
Lee RKK, Eaton RC, Zottoli SJ (1993) Segmental arrangement of reticulospinal neurons in the goldfish hindbrain. J Comp Neurol 329:539-556[Web of Science][Medline].
Marui T, Caprio J (1982) Electrophysiological evidence for the topographical arrangement of taste and tactile neurons in the facial lobe of the channel catfish. Brain Res 231:185-190[Web of Science][Medline].
Masino T (1992) Brainstem control of orienting movements: intrinsic coordinate systems and underlying circuitry. Brain Behav Evol 40:98-111[Web of Science][Medline].
Mendelson B (1986) Development of reticulospinal neurons of the zebrafish. II. Early axonal outgrowth and cell body position. J Comp Neurol 251:172-184[Web of Science][Medline].
Mendelson B, Kimmel CB (1986) Identified vertebrate neurons that differ in axonal projection develop together. Dev Biol 118:309-313[Web of Science][Medline].
Mesulam M-M (1978) Tetramethyl benzidine for horseradish peroxidase neurohistochemistry: a non-carcinogenic blue reaction product with superior sensitivity for visualizing general afferents and efferents. J Histochem Cytochem 26:106-117[Abstract].
Metcalfe WK, Mendelson B, Kimmel CB (1986) Segmental homologies among reticulospinal neurons in the hindbrain of the zebrafish larva. J Comp Neurol 251:147-159[Web of Science][Medline].
Molenaar GJ (1974) An additional trigeminal system in certain snakes possessing infrared receptors. Brain Res 78:340-344[Web of Science][Medline].
Morita Y, Finger TE (1985) Reflex connections of the facial and vagal gustatory systems in the brainstem of the bullhead catfish, Ictalurus nebulosus. J Comp Neurol 231:547-558[Web of Science][Medline].
Orlovsky GN (1970) Activity of reticulospinal neurons during locomotion. Biofzika 15:278-764 (English translation, 761-771).
Prasada Rao PD, Jadhao AG, Sharma SC (1987) Descending projection neurons to the spinal cord of the goldfish, Carassius auratus. J Comp Neurol 265:96-108[Web of Science][Medline].
Rovainen CM (1967) Physiological and anatomical studies on large neurons of central nervous system of the sea lamprey (Petromyzon marinus). I. Müller and Mauthner cells. J Neurophysiol 30:1000-1023[Free Full Text].
Rovainen CM (1974) Synaptic interactions of reticulospinal neurons and nerve cells in the spinal cord of the sea lamprey. J Comp Neurol 154:207-224[Web of Science][Medline].
Steiner J (1979) Human facial expression in response to taste and smell stimulation. Adv Child Dev 13:257-295.
Ter Horst GJ, Copray JCVM, Liem RSB, VanWilligen JD (1991) Projections from the rostral parvocellular reticular formation to pontine and medullary nuclei in the rat: involvement in autonomic regulation and orofacial motor control. Neuroscience 40:735-758[Web of Science][Medline].
Timerick S, Roberts BL, Paul DH (1992) Brainstem neurons projecting to different levels of the spinal cord of the dogfish, Scyliorhinus canicula. Brain Behav Evol 39:93-100[Web of Science][Medline].
Valentincic T, Caprio J (1993) In: In: Chemical signals in vertebrates VI (Doty RL, ed), pp 365-369. New York: Plenum.

Copyright ©1997 Society for Neuroscience   0270-6474/1997/174873-13$05.00/0

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Web of Science (9)

Citing Articles via Google Scholar

Google Scholar

Articles by Kanwal, J. S.

Articles by Finger, T. E.

Search for Related Content

PubMed

PubMed Citation

Articles by Kanwal, J. S.

Articles by Finger, T. E.

Pubmed/NCBI databases
Substance via MeSH