Differential Brainstem Fos-Like Immunoreactivity after Laryngeal-Induced Coughing and Its Reduction by Codeine

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Volume 17, Number 23, Issue of December 1, 1997

Differential Brainstem Fos-Like Immunoreactivity after Laryngeal-Induced Coughing and Its Reduction by Codeine

Christian Gestreau, Armand Louis Bianchi, and Laurent Grélot
Département de Physiologie et Neurophysiologie, Centre National de la Recherche Scientifique Unité de Recherche Associée 1832, Faculté des Sciences et Techniques Saint Jérôme, 13397 Marseille Cedex 20, France

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We used the expression of the immediate-early gene c-fos, a marker of neuronal activation, to localize brainstem neuronalpopulations functionally related to fictive cough (FC). In decerebrate,paralyzed, and ventilated cats, the level of Fos-like immunoreactivity(FLI) was examined in five groups of animals: (1) controls, sham-operatedunstimulated animals; (2) coughing cats, including both animalsin which FC was elicited by unilateral electrical stimulationof the superior laryngeal nerve (SLN) and (3) those in which FCwas elicited by bilateral SLN stimulation; (4) stimulated-treatedcats, in which bilateral SLN stimulation was applied after selectiveblockade of FC by codeine; and (5) codeine controls, sham-operatedunstimulated cats subjected to administration of codeine. Fifteenbrainstem structures were compared for numbers of labeled cells.Because codeine selectively blocks FC, brainstem nuclei activatedspecifically during FC were identified as regions showing increasedFLI after FC and significant reductions in FLI after FC suppressionby codeine in stimulated-treated cats. In coughing animals, weobserved a selective immunoreactivity in the interstitial andventrolateral subdivisions of the nucleus of the tractus solitarius,the medial part of the lateral tegmental field, the internal divisionof the lateral reticular nucleus, the nucleus retroambiguus, thepara-ambigual region, the retrofacial nucleus, and the medialparabrachial nucleus. FLI in all these nuclei was significantlyreduced in stimulated-treated cats. Our results are consistentwith the involvement of neurons overlapping the main brainstemrespiratory-related regions as well as the lateral tegmental fieldand the lateral reticular nucleus in the neural processing oflaryngeal-induced FC.
Key words: fictive cough; laryngeal afferents; antitussive drug; Fos-like immunocytochemistry; brainstem mapping; cat

INTRODUCTION

Cough, a defensive reflex of the airways, is evoked by various stimuli to sensory receptors of the pharyngolaryngeal and tracheobronchialmucosa. Laryngeal cough, induced by activation of afferents insuperior laryngeal nerves (SLNs), eliminates inhaled particlesfrom the upper airway. Cough can be divided into an inspiratoryphase characterized by an enhanced contraction of the diaphragmand abductor muscles of the upper airway, a compressive phaseduring which laryngeal adductor muscles close the glottis whileexpiratory muscles start to contract, and an expulsive phase thatresults from a sudden opening of the glottis and a powerful contractionof abdominal muscles (Korpas and Tomori, 1979).

Pharmacological studies have suggested the existence of a medullary cough center distinct from the respiratory centers (Bucher,1958; Pozzeto and Traimer, 1962; Korecky and Palecek, 1964). Laterexperiments using electrical microstimulation, electrocoagulation,and local administration of antitussive drugs into medullary regionsidentified a cough center in the medial part of the dorsal medulla(Kasé et al., 1970; Kasé, 1980), an area overlapping the nucleusof the tractus solitarius (nTS) and adjacent structures. However,the precise location of second- and higher-order neurons generatingcough remains unknown. Several electrophysiological studies haveshown that cough motor circuits share common elements with respiratorycenters (Jakus et al., 1985, 1987; Shannon et al., 1992; Oku etal., 1994; Gestreau et al., 1996), suggesting that cough and breathingmight result from the activation of similar sets of neurons. However,all respiratory regions were not explored, and cough-related activitiesof neurons located outside respiratory-related regions were notexamined. In an attempt to localize all brainstem regions containingneurons activated during SLN-induced fictive cough (FC), we usedactivity-driven Fos-like expression.

The expression of the nucleoprotein Fos, a product of the c-fos immediate-early gene, is widely considered a high resolutionmarker of neuronal activity (Dragunow and Faull, 1989; Morganand Curran, 1991). Immunocytochemical detection of transcriptsof the c-fos family genes (Fos and Fos-related antigens) has beenused to map functional brainstem pathways in response to variousstimuli (Erickson and Millhorn, 1991; Li and Dampney, 1992; Millerand Ruggiero, 1994; Yousfi-Malki and Puizillout, 1994; Walloiset al., 1995; Boissonade and Davison, 1996; Soulier et al., 1997).

In decerebrate and paralyzed cats, electrical stimulation of one or both SLNs elicits repetitive FC (Bolser, 1991; Grélotand Milano, 1991; Oku et al., 1994; Gestreau et al., 1996). Reflexactivities were characterized by recording phrenic, abdominal,and hypoglossal nerve discharges. Brainstem Fos-like immunoreactivity(FLI) was quantified in coughing cats, sham-operated animals (controls),cats whose SLNs were stimulated while FC was impaired by codeine(stimulated-treated animals), and cats treated only with codeine.Regions specifically activated during FC exhibited an increasein FLI in coughing cats, as compared with controls, and a decreasein FLI in stimulated-treated cats, as compared with coughing animals.

A preliminary account of this work has been published previously (Gestreau et al., 1994).

MATERIALS AND METHODS
Animal preparation. Animal care was in agreement with the principles approved by the European Community as well as with Frenchlaw. Experiments were performed on 22 adult cats of either sexweighing 2 to 4 kg. Surgical procedures were the same for allanimals. Cats were initially anesthetized by an intramuscularinjection of 1.5 mg/kg of a mixture of alphaxalone and alphadoloneacetate (9 and 3 mg/ml, respectively) (Saffan, Pitman-Moore).After cannulation of the trachea and the left femoral vein andartery, a surgical level of anesthesia was maintained with a mixtureof room air, oxygen (40%), and halothane (1.5 to 2.5%). In addition,local muscular infiltration of lidocaine and mepivacaine was performedat the surgical sites to alleviate any induction of Fos attributableto stimulation of nociceptors. Right and left SLNs and the righthypoglossal nerve were dissected free from surrounding tissuesand placed on bipolar silver electrodes isolated with Parafilmand Vaseline. The cats were then placed prone in a stereotaxicframe and decerebrated at the midcollicular level. After dissectionof a right C5 phrenic and a left iliohypogastric lumbar (L1, abdominal)rootlet, anesthesia was discontinued, and the animals were paralyzedwith gallamine triethiodide (Flaxedil, Specia) (2 mg/kg/hr, i.v.,supplemented as required) and artificially ventilated. Tidal volumeand pump frequency were set to maintain an end-tidal CO₂ around3% to reduce the central inspiratory drive. These conditions reducethe basal expression of Fos (our unpublished observations). Histologicalprocessing was restricted to animals that maintained a mean arterialblood pressure between 90 and 120 mm Hg throughout the experiment.Rectal temperature was maintained between 36 and 38°C using aservo-controlled heating pad. Because the experiments were performedon paralyzed and ventilated cats, cough was present only as neuraland not motor activity and is therefore called FC (Bolser, 1991;Grélot and Milano, 1991).

Recording and electrical stimulation. Activities were recorded from the hypoglossal and the intact C5 phrenic and iliohypogastric(L1) abdominal nerves using electrodes immersed in mineral oil.Under our experimental conditions (light hypocapnic hyperoxia),the reduced respiratory drive was evident as a weak augmentingramp of phrenic activity and absent L1 activity. FC was elicitedby repetitive electrical stimulation (0.1-0.2 msec pulses, 1-5V, 2-5 Hz) of the right or both SLNs. SLN shocks were appliedat an intensity twice that required to elicit an inhibitory responsein the phrenic nerve discharge. FC was characterized by an increasein duration, rate of rise, and amplitude of phrenic discharge,immediately followed by a large burst of L1 activity. A weak increasein hypoglossal discharge occurred during both phases of FC. Stimulationparameters were adjusted to minimize SLN-induced fictive swallowingindicated by short bursts of hypoglossal nerve activity (see Fig.1).
Fig. 1. Effects of SLN stimulation (black bars below each panel) (0.2 msec pulses, 5 V, 4 Hz) on phrenic (Phr), iliohypogastric (Abd),and hypoglossal (XII) nerve activities, and on arterial blood(BP) and tracheal (TP) pressures in coughing (A) and stimulated-treated(B) cats. In A, SLN stimulation induced multiple FCs (arrows)and transient hypertension and bronchoconstriction (slight increasein TP peaks above horizontal hatched line). In B, after the lastintravenous injection of codeine given 15 min before the startof SLN stimulation (see Materials and Methods for details), FCswere abolished, whereas transient changes in BP and TP were notaltered. Some buccopharyngeal stages of swallowing (stars) occurredregardless of the antitussive treatment. Stimulus artifacts wereerased to improve legibility.
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The SLN was stimulated using three different paradigms. (1) In three cats, electrical shocks were applied to the right SLNfor 30-40 min; (2) in three other cats, both SLNs were stimulatedduring three 30 min periods, each period being separated by 20min; and (3) in two additional cats, continuous stimulation ofboth SLNs was applied for 45 min. In each paradigm, stimulationwas interrupted for a few minutes when FC became difficult toelicit. SLN stimulation started 4.5 (2) or 6 hr (1 and 3) afterthe end of surgery.

The pattern of codeine injection was based on results from preliminary experiments (three cats not included in the presentreport) and aimed to minimize drastic drops in blood pressure(Cox, 1994). Nine cats were treated with 17 mg/kg of codeine chlorhydratediluted in 1.5 ml of saline and administered in multiple injectionsover a period of 90 min. All cats received the first injectionof codeine 3.5 hr before being killed and the last injection 15min before the start of SLN stimulation. Times and routes of codeineadministration were as follows. The drug was first injected intravenously(3 mg/kg slowly administered over 1 min); 20 min later, 3 mg/kgwas injected intramuscularly; two other intramuscular injections(4 mg/kg each, every 30 min) were made; and finally, 20 min later,a final intravenous injection (3 mg/kg) was given. In cats treatedwith codeine and in which laryngeal afferents were stimulated,bilateral SLN stimulation was applied continuously for 45 min[according to paradigm (3) above].

In the following text, "control" (n = 5) refers to untreated and unstimulated cats, "coughing" (n = 8) refers to untreatedcats in which FC was induced by stimulation of the right (n =3) or both SLNs (n = 5), "codeine-control" (n = 4) refers to unstimulatedcats treated with codeine, and "stimulated-treated" (n = 5) refersto cats in which bilateral stimulation of SLN was applied butFC was impaired by codeine administration.

Tissue processing. All cats had identical survival times (8 hr) after completion of surgery. Earlier deaths of control animalsin preliminary studies resulted in a higher level of FLI, probablycaused by the effect of anesthesia and/or surgery (Herdegen etal., 1991; Bonaz et al., 1994). Cats were perfused transcardiallywith 2 l of 0.1 M PBS, pH 7.4, containing 1000 U heparin and 0.1%procaine, followed by 2 l of 4% paraformaldehyde in phosphatebuffer, pH = 7.4. The brainstem, and in two cases the cervicalspinal cord (C2-C7), were removed and post-fixed for 6 hr. Tissueswere then successively cryoprotected at 4°C in solutions containing10, 20, and 30% sucrose. Transverse sections were cut at 50 µmusing a cryostat and collected in PBS. Every fourth section wasprocessed immunocytochemically for detection of Fos-like proteins.

Neural tissues from one or two stimulated animals were always processed simultaneously with those obtained from a controlcat using separate test wells. To block nonspecific binding sitesand facilitate tissue penetration, free-floating sections werefirst incubated for 1 hr in PBS containing 2% normal rabbit serumand 0.3% Triton X-100 (A solution). Afterward they were incubatedfor 24 hr at 4°C in polyclonal Fos sheep antibody (Fos OA 11-824,CRB/Euromedex) (diluted 1:3000 in A solution). This primary antibody,raised against amino acids 2-17 of the human Fos protein, recognizesboth Fos and Fos-related antigens. The use of this antibody ratherthan one specific to Fos protein could have contributed to therelatively high background observed in the present study (Dragunowand Faull, 1989). Sections from all experiments except those inwhich unilateral stimulation was applied (three cats) were processedwith the same batch of primary antibody. After they were rinsedtwice in PBS, sections were incubated for 1 hr in biotinylatedrabbit anti-sheep antiserum diluted (1:200) in PBS and then washedtwice. Finally, sections were incubated in avidin-biotin-peroxidasecomplex (1:100, 1 hr) (Vectastain ABC standard PK 4000, VectorLabs, Burlingame, CA). After three 10 min washes in PBS, the sectionswere processed for peroxidase using VIP substrate (SK 4600, VectorLabs) as the chromogen. After two washes in distilled water andthen in PBS for at least 30 min, sections were mounted on gelatin-coatedslices, air-dried, dehydrated, cleared, and coverslipped in DePeXmedium. Adjacent sections were counterstained with cresyl violetto delineate the location of nervous structures. In the presentstudy, specificity was assessed by omission of either the primaryor the secondary antibody. Such a procedure failed to produceany positive staining.

Determination of distribution and number of immunoreactive cell nuclei. Patterns of brainstem FLI were mapped, and Fos-positiveneurons were counted in four groups of animals according to theexperimental paradigms described above: control (n = 5), coughing(n = 8), codeine-control (n = 4), and stimulated-treated (n =5) cats. Sections processed immunocytochemically for Fos-likeproteins were examined with bright-field optics using a Polyvarmicroscope, drawn with a camera lucida, and photographed usingblack and white films (Kodak T-Max). For some brainstem structures,anatomical landmarks were determined using adjacent counterstainedsections. Criteria used to select specific sections for quantificationincluded (1) identification of the nucleus or subnucleus of intereston the section; (2) the absence of artifacts in the area; and(3) the same rostrocaudal level for sections from different animals.Fos-positive cell counting was performed with a Zeiss microscopeand a video-scanning system (C2400, Hamamatsu) coupled to a Macintoshcomputer using appropriate software to digitize images (DigitalVision) and evaluate grain density (Biolab/Piclab). Automaticcounts were based on the average density of Fos-positive cellnuclei relative to a given threshold. The appropriate thresholdproviding the best discrimination of target cells from backgroundwas set up from the first digitized image of the series. Thenthe same threshold was used for counting immunoreactive cellsin the remaining digitized images, i.e., obtained from sectionsprocessed in parallel during immunocytochemistry. For the threecats stimulated unilaterally, cell counting was performed bilaterallyin various brainstem structures. For each nucleus or subnucleus,four different sections were used to count FLI in both ipsi- andcontralateral sides. For the remaining animals (coughing catsstimulated bilaterally, control, codeine-treated, and stimulated-treated),cell counting was performed unilaterally. An average number ofFos-positive cells per section of 50 µm was calculated in eachstructure from counts done from four different sections, exceptfor two animals in which only three sections were available forthe area postrema and the interstitial subdivision of the nTS.Mean values and SDs, expressed as mean ± SD, were calculated forthe various brainstem structures in each group. Nomenclature followsthat of Kalia and Mesulam (1980) for the subdivisions of the nTSand that of Berman (1968) for the other pontomedullary structures.

Statistical evaluations. Statistical evaluation of our results was performed using computer software (Graphpad Instat). Toassess the efficacy of the antitussive treatment with codeine,we compared the numbers of FC induced during 45 min of bilateralSLN stimulation in coughing (n = 2) and stimulated-treated (n= 5) cats using the Mann-Whitney test. Results are expressed asmean ± SD. Histological data from unilaterally stimulated catswere collected with respect to the section number and laterality(ipsi- or contralateral to the stimulation). The numbers of Fos-positivecells induced in ipsi- versus contralateral brainstem structureswere compared using a nonparametric paired test (Wilcoxon two-tailed).Because a different batch of antibodies was used to perform immunocytochemistryon brainstem sections from unilaterally stimulated cats, statisticalcomparisons with results from animals of the other groups werenot possible. Instead, a one-way ANOVA was used for the latterto determine whether significant differences exist between meannumbers of Fos-positive cells counted in given brainstem areas.Post hoc analysis was used to determine which groups differed;p values were corrected (Bonferroni method) to compensate formultiple comparisons. Differences were considered significantat p < 0.05.

RESULTS

Elicitation of fictive coughing
Because in some animals SLN stimulation was interrupted for a few minutes when FC became difficult to elicit, the mean rateof FC production was calculated by dividing the total number ofevoked FCs by the real duration of stimulation (i.e., $<=$ 30-40min, $<=$ 45 min, or $<=$ 90 min). In three cats, stimulation of theright SLN for 30-40 min elicited 57 ± 9.9 FC (range, 49-68), givinga mean rate of 1.5 ± 0.2 FC/min. In three other cats, bilateralstimulation of SLN applied for three 30 min periods elicited 267± 139 FC (range, 132-411), giving a mean rate of 3.5 ± 1.4 FC/min.In two additional cats, bilateral SLN stimulation applied continuouslyfor 45 min elicited 142 and 116 FC (129 ± 18.4), correspondingto a mean rate of 3.2 ± 0.7 coughs/min (Fig. 1A). Codeine wasadministered in five other cats before bilateral SLN stimulationwas applied continuously for 45 min. The incidence of FC (8.8± 11.1 FC; range, 0-27; mean rate of 0.3 ± 0.3 FC/min) in codeine-treatedanimals was significantly less (p < 0.001) than in noncodeine-treatedanimals stimulated similarly (Figs. 1B, Fig. 2).
Fig. 2. Antitussive effect of codeine on SLN-induced cough. Codeine significantly reduced the elicitation of FC.
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In addition to FC, other reflexes were observed transiently at the onset of SLN stimulation, e.g., an increase in arterialblood pressure (20-30 mm Hg above the control pressure) and aweak bronchoconstriction (increase in tracheal pressure). Salivationand occasional buccopharyngeal stages of swallowing were alsoelicited throughout the stimulation period. Codeine treatmentdid not affect salivation (data not shown), the transient changesin blood and tracheal pressures, and swallowing (Fig. 1B).

Brainstem distribution of FLI
Fos-like expression appeared within the nuclei of immunoreactive neurons as a blue-violet staining of variable intensity.Figure 3 illustrates the distribution of FLI in the brainstemof control, coughing, codeine-control, and stimulated-treatedanimals.
Fig. 3. Distribution of brainstem FLI in transverse standardized hemisections through different rostrocaudal levels of control (unstimulated),coughing (262 SLN-induced coughs), codeine-control, and stimulated-treated(11 SLN-induced coughs) animals. Antitussive effect of codeinewas associated with a decrease in FLI in dorsal, medial, and ventrolateralmedulla and pons of the stimulated-treated animal. Each squarerepresents one Fos-positive neuron. Rostrocaudal position relativeto obex is indicated at top of drawing of each hemisection. 12,Hypoglossal nucleus; 5SP, 5ST, alaminar spinal trigeminal nucleusand tract; AMB, para-ambigual region; BC, brachium conjonctivum;CAE, locus caeruleus; CE, central canal; CUC, CUR, CUX, caudal,rostral, and external cuneate nucleus; DMV, dorsal motor nucleusof the vagus; FTL, lateral tegmental field; IOM, IOD, medial anddorsal accessory inferior olive; IOP, principal nucleus of theinferior olive; KF, Kölliker-Fuse nucleus; LRI, LRX, internaland external divisions of the lateral reticular nucleus; NPBL,NPBM, lateral and medial divisions of the parabrachial nucleus;RA, nucleus retroambiguus; RFN, retrofacial nucleus; TS, tractussolitarius; dnTS, mnTS, n.com, ni, vlnTS, dorsal, medial, commissural,interstitial, and ventrolateral subdivisions of the nucleus tractussolitarius (nTS); VIN, VMN, inferior and medial vestibular nuclei;V4, fourth ventricle.
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FLI in control animals In control cats (sham-operated unstimulated animals, n = 5), intense FLI was detected in the medial and inferior vestibularnuclei (VN), and in the ventral part of the alaminar spinal trigeminalnucleus, i.e., the infratrigeminal nucleus (5SP). Sparse labelingwas encountered in other regions throughout the rostrocaudal axis.A few labeled neurons were distributed within the nTS, typicallyconfined to its dorsal division. Scattered labeled cells werealso observed in the lateral tegmental field (FTL), the lateralreticular nucleus (LRN), the retroambiguus nucleus (RA), and thepara-ambigual region (AMB). In the pons, a few neurons exhibitinga faint immunoreactivity were observed in the lateral parabrachialnucleus, the Kölliker-Fuse nucleus (KF), and the locus caeruleus(CAE).
FLI in coughing animals: effect of unilateral SLN stimulation Intense FLI was detected bilaterally throughout the brainstem of animals whose right laryngeal afferents were stimulated.However, no Fos-labeled neurons were observed in the hypoglossaland facial nuclei. Medullary FLI extended mainly from 2.5 mm caudalto 4.5 mm rostral to the obex and included both dorsal and ventralareas, whereas FLI in the pons was restricted to the medial andlateral parabrachial nuclei (NPBM and NPBL, respectively), CAE,and KF. In the dorsal and lateral medulla, dense clusters of FLIwere seen in nTS, VN, and 5SP. Figure 4 illustrates the differentdistributions and numbers of Fos-positive cells within the dorsalmedulla, contralateral (Fig. 4A) and ipsilateral (Fig. 4B) tothe stimulated (right) SLN. Ventrally, numerous labeled cellswere distributed bilaterally along a radial axis extending fromFTL, through the AMB to LRN, from 2.5 mm caudal to 2.6 mm rostralto the obex. FLI was most prominent in the medial part of FTL,dorsomedial to AMB. Only scattered Fos-positive nuclei were observedwithin multipolar cells of the nucleus ambiguus, whereas numeroussmall and round labeled cells were distributed ventromediallyin the AMB. Between AMB and the ventral surface, FLI was restrictedmainly to the internal division of LRN, i.e., the magnocellularpart of LRN as identified by Ramon y Cajal (1909) or Brodal (1943).In addition, the retrofacial nucleus (RFN) exhibited dense Fos-positivecells; its ventral part (i.e., the sub-RFN) contained a clusterof immunoreactive cells from 2.8 to 3.4 mm rostral to the obex,whereas sparse Fos-positive cells were observed in its dorsalaspect. A compact core of Fos-positive neurons was present inthe dorsal or the ventral part of the medial accessory inferiorolive (IOM) from 1.5 mm caudal to 2.2 mm rostral to the obex.Caudally, RA displayed densely labeled cells.
Fig. 4. Bright-field photomicrographs illustrating patterns of FLI induced in the left (A) and right (B) dorsal vagal complex afterFC elicited by stimulation of the right SLN. A and B are fromthe same transverse section. C and D are schematic drawings delineatingdorsal medullary nuclei shown in A and B, respectively. Note theincrease in the number of Fos-positive cells in the ipsilateralnTS (B) as opposed to the contralateral nTS (A). Scale bar, 280µm. Abbreviations are defined in legend to Figure 3.
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The results of quantitative analysis of FLI within 15 brainstem structures, both ipsi- and contralateral to the stimulatedSLN, are presented in Table 1. Stimulation of the right SLN resultedin more Fos-positive cells within ipsilateral nTS subdivisionsand the ipsilateral IOM. In contrast, no differences were detectedbetween the levels of FLI in the ipsi- and contralateral sidesfor the other brainstem regions (Table 1).

Table 1. Bilateral FLI counts in 15 brainstem structures of coughing cats in which electrical stimulation was applied only to the rightSLN

Unilateral Stimulation of the right SLN

Ipsi Contra

(n = 3)

VN 61 ± 35 64 ± 31

5SP 27 ± 9 27 ± 11

IOM 98 ± 37^* 18 ± 7

FTL 6 ± 3 6 ± 4

nTS total 201 ± 25^** 127 ± 34

n.com 62 ± 34^* 44 ± 26

dnTS 37 ± 10^** 21 ± 8

mnTS 42 ± 16 31 ± 11

ni 33 ± 9^** 13 ± 6

vlnTS 28 ± 12^** 18 ± 7

AP 4 ± 4 2 ± 2

DMV 6 ± 3 4 ± 4

LRN 18 ± 5 18 ± 6

RA 11 ± 3 10 ± 2

AMB 19 ± 10 16 ± 9

RFN 28 ± 11 27 ± 11

CAE 20 ± 7 22 ± 9

KF 50 ± 26 57 ± 16

NPBL 32 ± 14 33 ± 11

NPBM 9 ± 2 9 ± 4

Values are expressed as mean ± SD and correspond to mean numbers of labeled cells per structure and per hemisection. Significantp values are represented by asterisks (* p < 0.05; ^** p < 0.01) and indicate increases in FLI in medullary nuclei ipsilateral to the stimulated nerve compared with the correspondingcontralateral structures.

FLI in coughing animals: effect of bilateral SLN stimulation We observed no differences between the distribution of FLI in coughing cats whose SLN afferents were bilaterally stimulatedfor three 30 min periods (n = 3) or for a single 45 min period(n = 2). Both patterns are thus described together. However, intwo of the five coughing cats stimulated bilaterally (one foreach stimulation paradigm), Fos-positive neurons were detectedin the pallidus and obscurus raphe nuclei, but are not presentedbecause of the inconstancy of this labeling. Representative distributionsof Fos-positive neurons within the nTS of control and coughingcats are depicted in Figures 5 and 6. The amount of FLI in thewhole nTS was significantly greater (p < 0.05) than in controls(see Fig. 9). The most caudal division of the nTS, the commissuralnucleus (n.com), contained numerous labeled neurons distributedmainly on both sides of the central canal from 2.5 mm caudal tothe obex (Figs. 3, 5). FLI was enhanced in the dorsal aspect ofthe nTS (dnTS) but did not differ in its medial division (mnTS).Furthermore, neurons in the margin of the interstitial nucleus(ni) and within the ventrolateral division (vlnTS) of the nTSexhibited enhanced labeling (Fig. 6B). FLI increased in the IOM(Fig. 3). In contrast, no differences between control and coughinganimals were observed in the VN, 5SP, area postrema (AP), anddorsal motor nucleus of the vagus (DMV). Enhancement of FLI wasalso observed in FTL, RA, AMB, and LRN (Figs. 3, 7). Interestingly,FLI within these nuclei had the same distribution as that in unilaterallystimulated cats (see above). The mean numbers of labeled neuronsin the whole RFN increased (p < 0.001) compared with values obtainedin control cats (see Fig. 9). In the pons, FLI was detected atthe level of NPBL, NPBM, and KF between 9.5 and 11 mm rostralto the obex. In these pontine regions, the expression of Fos-likeproteins was enhanced (Fig. 8B). No differences between controland coughing animals were observed in CAE. No Fos-labeled cellswere detected in the pontine reticular formation. In the spinalcords of two coughing cats, we observed FLI in laminae I and IIof the dorsal horn (C2-C5), but no FLI was detected in the phrenicmotor nucleus (Lamina IX in C4-C6).
Fig. 5. Bright-field photomicrographs of transverse sections illustrating FLI in the left (A, C) and right (B, D) commissural subdivision(n com) of the nTS. Control (A), coughing (B), codeine-control(C), and stimulated-treated (D) cats. FLI was induced in n.comof the two cats subjected to SLN stimulation whether or not theywere treated with codeine (arrows in B and D). Codeine induceda few Fos-positive neurons in the dorsal motor nucleus of thevagus nerve (DMV) (arrowheads in C and D). E, F, G, and H areschematic drawings of dorsal medullary nuclei shown in A, B, C,and D, respectively. Outlined structures indicate selected areasin which labeled cells were counted. Scale bar, 220 µm. CE, Centralcanal; XII, hypoglossal nucleus.
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Fig. 6. Bright-field photomicrographs of transverse sections illustrating FLI in the dorsal vagal complex (nTS, AP, and DMV) of medulla.Control (A), coughing (B), codeine-control (C), and stimulated-treated(D) cats. Note dense labeling in the interstitial (ni, curvedarrow) and ventrolateral (arrowhead) subdivisions of the nTS observedonly in B. Codeine induced sparse Fos-positive neurons in AP,DMV (three small arrows), and mnTS of codeine-control cat (C).Similar FLI was also observed in AP and DMV of the stimulated-treated(D) cat, associated with an increase in Fos-like expression inthe dnTS and mnTS. E, F, G, and H are schematic drawings of dorsalmedullary nuclei shown in A, B, C, and D, respectively. Outlinedstructures indicate selected areas in which labeled cells werecounted. Scale bar, 300 µm. Abbreviations are defined in legendto Figure 3.
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Fig. 9. Numbers of Fos-like immunoreactive neurons for the four groups in various brainstem nuclei: A, dorsal vagal complex; B, nTSsubnuclei; C, ventral medulla; D, other medullary regions; andE, pons. Histograms represent mean numbers of Fos-positive neuronswith superimposed SD. Asterisks indicate significant (*p < 0.05and **p < 0.01) increases of Fos-positive neurons in coughingcats versus both control and stimulated-treated animals. Abbreviationsare defined in legend to Figure 3.
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Fig. 7. Bright-field photomicrographs of transverse sections illustrating FLI distribution in the ventral medulla overlapping theAMB and the nucleus ambiguus. Control (A), coughing (B), codeine-control(C), and stimulated-treated (D) cats. Open arrows point to thenucleus ambiguus. Arrows indicate the dorsal (d) and lateral (l)directions. Note in B dense labeling ventromedial to the nucleusambiguus. E and F are schematic drawings delineating the para-ambigualregion (AMB) (hatched line), including the nucleus ambiguus (NA)(continuous line) shown in A and B, respectively. Similarly, Eand F also match C and D. Outlined structures indicate selectedareas in which labeled cells were counted. Scale bar, 200 µm.Abbreviations are defined in legend to Figure 3.
[View Larger Version of this Image (100K GIF file)]

Fig. 8. Bright-field photomicrographs of transverse sections depicting FLI distribution in the dorsolateral pons. Control (A), coughing(B), codeine-control (C), and stimulated-treated (D) cats. SLNstimulation induced dense FLI in NPBL (large arrows) and KF nucleus(arrowhead) of the two stimulated cats (B, D). FLI evoked in NPBM(two small arrows) of coughing cat (B) decreased after codeineadministration (D). E, F, G, and H are schematic drawings of pontinenuclei shown in A, B, C, and D, respectively. Outlined structuresindicate selected areas in which labeled cells were counted. Scalebar, 600 µm. Abbreviations are defined in legend to Figure 3.
[View Larger Version of this Image (80K GIF file)]

FLI in codeine-control cats In addition to FLI already described in the brainstem of untreated control animals, all codeine-control cats exhibited enhancedFLI in the dorsal vagal complex (Figs. 3, 5C, 6C). Although morelabeled neurons were detected in three nTS divisions (n.com, dnTS,and mnTS), FLI increased significantly only in AP (p < 0.05) andDMV (p < 0.01) (Fig. 9). Values obtained from other brainstemareas did not differ from those in untreated control cats (Fig.9).
FLI in stimulated-treated cats: comparison with codeine-control animals Compared with codeine-treated (unstimulated) cats, the mean number of Fos-positive neurons in the dorsal vagal complex didnot change in AP or DMV. However, FLI increased in the total nTS(Fig. 9A), reflecting increases in n.com (p < 0.01), dnTS (p <0.05), and mnTS (p < 0.05), but not in the ni and vlnTS (Fig.9B). In ventral medullary regions, mean numbers of Fos-positiveneurons in RA, AMB, and LRN were low, similar to those in codeine-controlanimals (Fig. 7D), but greater in RFN (p < 0.01) (Fig. 9C). Inthe other medullary regions, FLI was enhanced in IOM (p < 0.05)and FTL (p < 0.05). In 5SP and VN, the mean numbers of labeledneurons were similar (Fig. 9D). In the pons, numerous labeledcells were observed (Fig. 8D), and the mean numbers increasedin NPBL (p < 0.01) and KF (p < 0.05), but were similar in NPBMand CAE (Fig. 9E).
FLI in stimulated-treated cats: comparison with coughing animals Compared with coughing animals, FLI was less in ni (p < 0.05) and vlnTS (p < 0.01) (Figs. 6, 9B), similar in n.com (Fig. 5),and greater in the other two nTS subdivisions (dnTS and mnTS,p < 0.05) (Figs. 6, 9B). FLI was less in all nuclei of the ventralmedulla (p < 0.01 for RA, AMB, and LRN, and p < 0.05 for RFN)(Fig. 9C). Nevertheless, the cluster of FLI in the ventral aspectof RFN was still observed in stimulated-treated cats (Fig. 3).In the other medullary regions, the level of FLI was similar inIOM but reduced (p < 0.01) in FTL (Fig. 9D). In the pons, meannumbers of labeled cells were similar in NPBL, KF and CAE, butless (p < 0.01) in NPBM (Fig. 9E).

DISCUSSION
This is the first study to identify brainstem neurons exhibiting Fos-like expression after FC elicited by stimulation of laryngealafferents. Electrical stimulation of SLN, unlike mechanical stimulationof upper airways (Korpas and Tomori, 1979), elicits repeated andfrequent coughs. In addition, use of decerebrate, paralyzed ventilatedcats avoids Fos-like expression induced by sensory feedback, stressand/or arousal mechanisms, or modifications caused by anestheticagents. However, as a general limitation of the method, all neuronsactivated during a given motor act do not necessarily expressFos (Hunt et al., 1987). This is obvious in our study becausehypoglossal and phrenic motoneurons did not exhibit FLI.

FLI patterns in coughing versus control animals
FLI was observed in the brainstem of both control and coughing cats but was greatly enhanced in selective nuclei of the latter.In control animals, a low level of FLI was detected in most brainstemregions. Nevertheless, all animals exhibited robust FLI in VNand 5SP, a result similar to that reported in decerebrate catsby Miller and Ruggiero (1994), possibly resulting from surgicallyinduced nociceptive inputs (Bereiter et al., 1994).

FC caused large increases in FLI in various areas, including several nTS subdivisions and regions of the ventrolateral medulla.Results from unilateral stimulation, demonstrating an enhancementof FLI in the ipsilateral nTS, are in good agreement with a prominentipsilateral projection of laryngeal afferents in the dorsal medulla(Kalia and Mesulam, 1980; Lucier et al., 1986). A close correspondencewas observed between the FLI pattern within the nTS and the establishedprojection sites of SLN sensory fibers. Thus, Fos-positive nTSneurons can be viewed as second-order neurons of the cough reflexarc. Although some SLN afferents project to 5SP (Lucier et al.,1986), we failed to find enhanced FLI in 5SP after SLN stimulation.

Laryngeal afferents do not project directly to the bulbar reticular formation, the ventrolateral medulla, or the pons. Fos-positiveneurons overlapping these areas were thus likely polysynapticallyactivated and may correspond to higher-order neurons in the coughnetwork. Because all of these areas exhibited a bilateral (andnot enhanced ipsilateral) FLI after unilateral SLN stimulation,our results suggest that second-order nTS neurons distributedintegrated information to both sides of the medial and ventralmedulla. This may be achieved by axon collaterals, as demonstratedanatomically for some nTS neurons in the cat (Otake et al., 1989).In contrast, FLI in IOM may be explained by a heavy ipsilateralprojection from laryngeal afferents via a pauci-synaptic pathway.However, the functional role of the neuronal activation of IOMis unclear.

Significance of reduced FLI in stimulated-treated cats
Both FC and FLI decreased in stimulated-treated animals. Reductions in FLI were especially evident in ni, vlnTS, the reticularformation (FTL and LRN), the ambigual complex (RA, AMB, and RFN)and NPBM. Tentatively, one can ascribe this FLI reduction to codeine-inducedblockade of neurons forming the cough network. However, otheropioid agonists, such as morphine, can reduce Fos-like expressionin the CNS after nociceptive stimuli (Presley et al., 1990; Gogaset al., 1991; Hammond et al., 1992; Abbadie and Besson, 1993;Tölle et al., 1994; Ebersberger et al., 1995). If nociceptiveSLN afferents had been activated and evoked FLI in coughing cats,the analgesic properties of codeine could explain this FLI reduction.Although we cannot exclude a contribution of pain pathways ininduction of FLI in coughing cats, our results do not supportthis hypothesis. No differences were seen between levels of FLIin 5SP induced in the ipsilateral as opposed to the contralateralside in unilaterally stimulated cats, and in the control unstimulatedanimals compared with the stimulated ones. Because FLI inductionin 5SP did not exceed that in controls, presumably nociceptivelaryngeal afferents terminating in 5SP (Lucier et al., 1986) mayhave not been activated by SLN stimulation. In addition, codeinefailed to reduce FLI in brainstem nuclei implicated in pain integration(5SP, n.com, and NPBL) (Lantéri-Minet et al., 1994). Thus, themarked FLI reduction observed in stimulated-treated cats likelyresulted from the antitussive properties of codeine rather thanits analgesic properties.

In codeine-control cats, FLI was enhanced in the dorsal vagal complex. Codeine may have induced FLI via a blood-borne route.An overdose of codeine activates the emetic reflex via AP (Borison,1989). FLI in the DMV could have been caused by central activationof preganglionic vagal neurons by codeine (Kromer, 1988). Alternatively,hypotension resulting from intravenous injection of codeine (Cox,1994) could explain FLI observed in the dorsal vagal complex (Chanand Sawchenko, 1994; Li and Dampney, 1994).

Codeine treatment before SLN stimulation selectively decreased FC, yet marked FLI was still induced within n.com, mnTS, dnTS,IOM, the ventral part of RFN, KF, and NPBL. Although the latterstructures may be involved in FC generation, FLI in stimulated-treatedcats likely results from apnea, swallowing, salivation, or transientchanges in vaso- and bronchomotor tones persisting after codeineadministration. Hypertension can evoke FLI within the dorsomedialand caudal aspects of the nTS, the rostral ventrolateral medulla,the NPBL, and the KF of other species (Li and Dampney, 1992; Gierobaand Blessing, 1994; Miura et al., 1994). In addition, laryngealafferents triggering swallowing terminate in various nTS subdivisions,and their activation could have reinforced the level of FLI inthese subnuclei. However, none of the above reflexes elicitedin stimulated-treated cats (Fig. 1B) induce a level of FLI comparableto that observed in coughing animals.

Brainstem areas involved in FC generation
The most striking result of our study was the different pattern of FLI evoked in coughing animals compared with that in stimulated-treatedones. The selective Fos-like expression induced in discrete brainstemnuclei of coughing cats mapped neurons that could be involvedin FC generation. In the dorsal medulla of coughing cats, FLIwas enhanced in ni and vlnTS. We recently reported that inspiratoryneurons in the vlnTS, i.e., the dorsal respiratory group (Bianchiet al., 1995), exhibit sustained activation during the inspiratoryphase of FC (Gestreau et al., 1996). In addition, neurons in thevlnTS and ni are monosynaptically activated by laryngeal afferents(Bellingham and Lipski, 1992; Jiang and Lipski, 1992; Mifflin,1993). Thus, both vlnTS and ni neurons may process laryngeal inputscausing FC. Reduced FLI in the ni and vlnTS subdivisions alsosuggests that codeine exerts its antitussive action by preventingthe activation by laryngeal afferents of the second-order neuronsof the cough reflex.

In the ventral medulla, FLI selectively induced in coughing cats overlapped the ventral respiratory group (VRG), a columnof neurons associated with the RA, AMB, and RFN. All three nucleicontain many respiratory neurons distributing the central respiratorydrive to both upper airway and thoracoabdominal respiratory-relatedmuscles (Bianchi et al., 1995). VRG expiratory and inspiratoryneurons, including interneurons and premotoneurons, fire duringeither the diaphragmatic or abdominal phases of coughing (or FC)with a higher frequency than during breathing (Jakus et al., 1985,1987; Shannon et al., 1992; Oku et al., 1994). Therefore, activationof VRG neurons may explain the widespread FLI within the ventralmedullary regions of coughing cats. Whether pharyngeal and laryngealmotoneurons form part of the VRG labeled neurons cannot be ascertained.

In the pons, a few Fos-positive neurons were observed in NPBM of coughing cats. This nucleus has been referred to as the pneumotaxiccenter, which promotes inspiratory termination (Bianchi et al.,1995). Direct projections from n.com to NPBM (Otake et al., 1992)could explain FLI induced in this pontine area.

Finally, the medial part of FTL and the internal division of LRN exhibited FLI after FC. Interestingly, these discrete partsof the medullary reticular formation are usually not associatedwith the respiratory central pattern generator (CPG). Fung etal. (1995) reported the recruitment of nonrespiratory-relatedunits in the FTL during the aspiration reflex, a phenomenon possiblyoccurring during FC. A very similar pattern of FLI is presentin the cat's reticular formation after vocalization (Jüergensand Lu, 1994), emesis (Miller and Ruggiero, 1994), and sneezing(Wallois et al., 1995); all of these motor activities involvethe contraction of respiratory-related muscles. Therefore, activationof reticular neurons, as demonstrated by Fos immunocytochemistry,may be necessary for the motor program associated with cough andother nonrespiratory behaviors. However, the precise role of reticularneurons during cough remains to be investigated.

In conclusion, FC evokes a selective FLI in several brainstem areas, suggesting a crucial role for these structures in coughgeneration. This FLI overlapped not only dorsal and ventral brainstemareas containing dense populations of respiratory neurons butalso the medial part of FTL and the internal division of LRN.Neurons of these reticular nuclei may be a necessary part of thecough CPG because they seem to be generally activated in otherstereotyped behaviors involving respiratory muscles.

FOOTNOTES

Received May 27, 1997; revised Sept. 11, 1997; accepted Sept. 16, 1997.

We thank Drs. Myriem Yousfi-Malki and Jean-Jacques Puizillout for their help in developing histological technique, Dr. FedericoPortillo for his involvement in preliminary experiments, JuliettePio, Jocelyne Roman, and Michel Manneville for their technicalassistance, and Drs. M. Roux and R. Shannon for their helpfulsuggestions.

Correspondence should be addressed to Dr. Christian Gestreau, Département de Physiologie et Neurophysiologie, Case 351, Facultédes Sciences Saint Jérôme, 13397 Marseille cedex 20, France.

REFERENCES

Abbadie C, Besson J-M (1993) Effects of morphine and naloxone on basal and evoked Fos-like immunoreactivity in lumbar spinal cord neurons of arthritic rats. Pain 52:29-39[ISI][Medline].
Bellingham MC, Lipski J (1992) Morphology and electrophysiology of superior laryngeal nerve afferents and post-synaptic neurons in the medulla oblongata of the cat. Neuroscience 48:205-216[ISI][Medline].
Bereiter DA, Hathaway CB, Benetti AP (1994) Caudal portions of the spinal trigeminal complex are necessary for autonomic responses and display Fos-like immunoreactivity after corneal stimulation in the cat. Brain Res 657:73-82[ISI][Medline].
Berman AL (1968) In: The brainstem of the cat: a cytoarchitectonic atlas with stereotaxic coordinates. Milwaukee: University of Wisconsin.
Bianchi AL, Denavit-Saubié M, Champagnat J (1995) Central control of breathing in mammals: neuronal circuitry, membrane properties, and neurotransmitters. Physiol Rev 75:1-46[Free Full Text].
Boissonade FM, Davison JS (1996) Effects of vagal and splanchnic nerve section on Fos expression in ferret after emetic stimuli. Am J Physiol 271:R228-R236[Abstract/Free Full Text].
Bolser D (1991) Fictive cough in the cat. J Appl Physiol 71:2325-2331[Abstract/Free Full Text].
Bonaz B, Plourde V, Taché Y (1994) Abdominal surgery induces Fos immunoreactivity in the rat brain. J Comp Neurol 349:212-222[ISI][Medline].
Borison HL (1989) Area postrema: chemoreceptor circumventricular organ of the medulla oblongata. Prog Neurobiol 32:351-390[ISI][Medline].
Brodal A (1943) The cerebellar connections of the nucleus reticularis lateralis (nucleus funiculi lateralis) in rabbit and cat: experimental investigations. Acta Psychiatr Neurol Scand 18:171-233.
Bucher K (1958) Pathophysiology and pharmacology of cough. Pharmacol Rev 10:43-58[Free Full Text].
Chan RKW, Sawchenko PE (1994) Spatially and temporally differentiated patterns of c-fos expression in brainstem catecholaminergic cell groups induced by cardiovascular challenges in the rat. J Comp Neurol 348:433-460[ISI][Medline].
Cox RG (1994) Hypoxaemia and hypotension after intravenous codeine phosphate. Can J Anaesth 41:1211-1213[Abstract/Free Full Text].
Dragunow M, Faull R (1989) The use of c-fos as a metabolic marker in neuronal pathway tracing. J Neurosci Methods 29:261-265[ISI][Medline].
Ebersberger A, Anton F, Tölle TR, Zieglgänsberger W (1995) Morphine, 5-HT2 and 5-HT3 receptor antagonists reduce c-fos expression in the trigeminal nuclear complex following noxious chemical stimulation of the rat nasal mucosa. Brain Res 676:336-342[ISI][Medline].
Erickson JT, Millhorn DE (1991) Fos-like protein is induced in neurons of the medulla oblongata after stimulation of the carotid sinus nerve in awake and anesthetized rats. Brain Res 567:11-24[ISI][Medline].
Fung ML, Tomori Z, St-John WM (1995) Medullary neuronal activities in gasping induced by pharyngeal stimulation and hypoxia. Resp Physiol 100:195-202[ISI][Medline].
Gestreau C, Portillo F, Yousfi M, Puizillout JJ, Grélot L (1994) Brainstem distribution of c-Fos immunoreactivity following repetitive coughing in the decerebrate cat. Eur J Neurosci [Suppl 7] Abstr 95-01.
Gestreau C, Milano S, Bianchi AL, Grélot L (1996) Activity of dorsal respiratory group inspiratory neurons during laryngeal-induced fictive coughing and swallowing in decerebrate cats. Exp Brain Res 108:247-256[ISI][Medline].
Gieroba ZJ, Blessing WW (1994) Fos-containing neurons in medulla and pons after unilateral stimulation of the afferent abdominal vagus in conscious rabbits. Neuroscience 59:851-858[ISI][Medline].
Gogas KR, Presley RW, Levine JD, Basbaum AI (1991) The antinociceptive action of supraspinal opioids results from an increase in descending inhibitory control: correlation of nociceptive behavior and c-fos expression. Neuroscience 42:617-628[ISI][Medline].
Grélot L, Milano S (1991) Diaphragmatic and abdominal muscle activity during coughing in the decerebrate cat. NeuroReport 2:165-168[ISI][Medline].
Hammond DL, Presley R, Gogas KR, Basbaum AI (1992) Morphine or U-50,488 suppresses Fos protein-like immunoreactivity in the spinal cord and nucleus tractus solitarii evoked by a noxious visceral stimuli. J Comp Neurol 315:244-253[ISI][Medline].
Herdegen T, Kovary K, Leah J, Bravo R (1991) Specific temporal and spatial distribution of JUN, FOS, and Krox-24 proteins in spinal neurons following noxious transsynaptic stimulation. J Comp Neurol 313:178-191[ISI][Medline].
Hunt PS, Pini A, Evan G (1987) Induction of c-fos-like protein in spinal cord neurons following sensory stimulation. Nature 328:632-634[Medline].
Jakus J, Tomori Z, Stránsky A (1985) Activity of bulbar respiratory neurones during cough and other respiratory tract reflexes in cats. Physiol Bohemoslov 34:127-136.
Jakus J, Tomori Z, Stránsky A, Boselova L (1987) Bulbar respiratory activity during defensive airway reflexes. Acta Physiol Hungarica 70:245-254[ISI][Medline].
Jiang C, Lipski J (1992) Synaptic inputs to medullary respiratory neurons from superior laryngeal afferents in the cat. Brain Res 584:197-206[ISI][Medline].
Jüergens U, Lu C-L (1994) C-fos expression in the brain of a new world monkey (Saguinus Fuscicollis) during long-lasting vocalization. Eur J Neurosci [Suppl 7] Abstr 97-30.
Kalia M, Mesulam MM (1980) Brain stem projections of sensory and motor components of the vagus complex in the cat: II. Laryngeal, tracheobronchial, pulmonary, cardiac, and gastrointestinal branches. J Comp Neurol 193:467-508[ISI][Medline].
Kasé Y (1980) Antitussive agents and their sites of action. Trends Pharmacol Sci 1:237-239.
Kasé Y, Wakita Y, Kito G, Miyama T, Yuizono T, Kataoka M (1970) Centrally-induced coughs in the cat. Life Sci 9:49-59[ISI][Medline].
Korecky B, Palecek F (1964) The assessment of respiratory response curves to carbon dioxide in drug evaluation. In: Drugs and respiration, Vol 11 (Aviado DM, Palecek F, eds), p 241. Oxford: Pergamon.
Korpas J, Tomori Z (1979) Cough and other respiratory reflexes. In: Progress in respiratory research, Vol 12 (Herzog H, ed), pp 1-336. Basel: Karger.
Kromer W (1988) Endogenous and exogenous opioids in the gastro-intestinal motility and secretion. Pharmacol Rev 40:121-162[ISI][Medline].
Lantéri-Minet M, Weil-Fugazza J, De Pommery J, Ménétrey D (1994) Hindbrain structures involved in pain processing as revealed by the expression of c-Fos and other immediate early gene proteins. Neuroscience 58:287-298[ISI][Medline].
Li Y-M, Dampney RAL (1992) Expression of c-fos protein in the medulla oblongata of conscious rabbits in response to baroreceptor activation. Neurosci Lett 144:70-74[ISI][Medline].
Li Y-M, Dampney RAL (1994) Expression of Fos-like protein in brain following sustained hypertension and hypotension in conscious rabbits. Neuroscience 61:613-634[ISI][Medline].
Lucier GE, Egizii R, Dostrovsky JO (1986) Projections of the internal branch of the superior laryngeal nerve of the cat. Brain Res Bull 16:713-721[ISI][Medline].
Mifflin SW (1993) Laryngeal afferent inputs to the nucleus of the solitary tract. Am J Physiol 265:R269-R276[Abstract/Free Full Text].
Miller AD, Ruggiero DA (1994) Emetic reflex arc revealed by expression of the immediate-early gene c-fos in the cat. J Neurosci 14:871-888[Abstract].
Miura M, Takayama K, Okada J (1994) Neuronal expression of Fos protein in the rat brain after baroreceptor stimulation. J Auton Nerv Syst 50:31-43[ISI][Medline].
Morgan JI, Curran T (1991) Stimulus-transcription coupling in the nervous system: involvement of the inducible proto-oncogenes fos and jun. Annu Rev Neurosci 14:421-451[ISI][Medline].
Otake K, Sasaki H, Ezure K, Manabe M (1989) Axonal trajectory and terminal distribution of inspiratory neurons of the dorsal respiratory group in the cat's medulla. J Comp Neurol 286:218-230[ISI][Medline].
Otake K, Ezure K, Lipski J, Wong She RB (1992) Projections from the commissural subnucleus of the nucleus of the solitary tract: an anterograde tracing study in the cat. J Comp Neurol 324:365-378[ISI][Medline].
Oku Y, Tanaka I, Ezure K (1994) Activity of bulbar respiratory neurons during fictive coughing and swallowing in the decerebrate cat. J Physiol (Lond) 480:309-324[ISI][Medline].
Pozzeto H, Traimer J (1962) Physiologie et physiopathologie de la toux. Poumon Coeur 18:393-406.
Presley RW, Menetrey D, Levine JD, Basbaum AI (1990) Systemic morphine suppresses noxious stimulus-evoked Fos protein-like immunoreactivity in the rat spinal cord. J Neurosci 10:323-335[Abstract].
Ramon y Cajal S (1909) Histologie du système nerveux de l'homme et des vertébrés. Reprint (Azoulay L, translator). Madrid: Intituto Ramón Y Cajal.
Shannon R, Morris KE, Lindsey BG (1992) Medullary ventral respiratory group (VRG) neurons responses during fictive coughing. Soc Neurosci Abstr 58.6.
Soulier V, Gestreau C, Borghini N, Dalmaz Y, Cottet-Emard JM, Péquignot JM (1997) Peripheral chemosensitivity and central integration: neuroplasticity of catecholaminergic cells under hypoxia. Comp Biochem Physiol 78-86.
Tölle TR, Schadrack J, Castro-Lopes JM, Evan G, Roques BP, Zieglgänsberger W (1994) Effects of Kelatorphan and morphine before and after noxious stimulation immediate-early gene expression in rat spinal cord neurons. Pain 5:103-112.
Wallois F, Gros F, Masmoudi K, Larnicol N (1995) C-fos-like immunoreactivity in the cat brainstem evoked by sneeze-inducing air puff stimulation of the nasal mucosa. Brain Res 687:143-154[ISI][Medline].
Yousfi-Malki M, Puizillout JJ (1994) Induction of Fos-like protein in neurons of the medulla oblongata after electrical stimulation of the vagus nerve in anesthetized rabbit. Brain Res 635:317-322[ISI][Medline].

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