INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

LUNGS AND AIRWAYS RECEIVE the preponderance of their motor nerve supply from medullary neurons, the somata of which are located in the nucleus ambiguus complex or in the dorsal motor nucleus of the vagus (11, 12, 15, 25). These neurons are regulated by an extensive brain stem neuronal network (10, 11, 25) that integrates sensory information from respiratory mechano- and chemoreceptors, autonomic centers, and premotor inspiratory neurons into a respiratory-modulated outflow (34). Vagal motor fibers carry this outflow to the airways, where they are thought to establish obligatory synapses with an intrinsic network of parasympathetic ganglia, which in turn provide direct innervation to airway smooth muscle, glands, and blood vessels.

For such a system to be mechanically efficient, however, preganglionic inputs must reach distant regions of both lungs at approximately the same time and with similar intensity. Vagal stimulation and neuroanatomic tracing studies suggest that these requisites are met in part by a dual-innervation arrangement in which each lung receives fibers from both vagus nerves. The existence of such an arrangement has been suspected since the early neuroanatomic studies of Larsell and Mason in rabbits (16) and Honjin in mice (13) revealed that a substantial number of lung vagal preganglionic and sensory fibers do not undergo degeneration after ipsilateral cervical vagotomy. Olsen et al. (23) provided functional evidence for the presence of midline-crossing vagal fibers by showing that unilateral electrical stimulation of the vagus nerve increases the airflow resistance of both lungs in dogs and cats. More recently, using horseradish peroxidase as a retrograde neuronal tracer, Kalia and Mesulam (15) demonstrated that the right main stem bronchus of the cat receives a bilateral supply of motor fibers that originate from the nucleus ambiguus and dorsal motor nucleus of the vagus. Interestingly, the same investigators reported that the apical lobe of the right lung receives bilateral innervation only from the dorsal motor nucleus of the vagus; innervation from the nucleus ambiguus was unilateral.

The present study was designed to uncover some unexplored features of this dual-innervation arrangement in the rat. First, we assessed the size and trajectory of the contingent of vagal motor and sensory fibers that cross the midline to innervate the contralateral lung by analyzing the effects of cervical and thoracic vagotomies on the topography of neuronal labeling by the -subunit of cholera toxin (CT-) injected into the lungs. Second, we investigated whether individual vagal motor fibers are committed to the innervation of unilateral targets or divide to reach bilateral targets by determining the rate of double labeling of medullary neurons after injections of CT- and FluoroGold (FG) into opposite main stem bronchi. Finally, we elucidated the existence of intramedullary connections between vagal preganglionic centers by examining the effects of unilateral vagotomy on the retrograde transsynaptic labeling of brain stem neurons by pulmonary injections of pseudorabies virus.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

All experiments were performed in male Sprague-Dawley rats (300-400 g body wt, 10-12 wk old; Charles River, Wilmington, MA) following protocols approved by the Washington University Animal Studies Committee. The rats were housed at 23°C in a climate-controlled room with access to standard rat chow and water.

Midline Crossing by Vagal Motor and Sensory Fibers

View larger version (15K): [in this window] [in a new window]   Fig. 1.   Schematic illustration of experimental strategies. A: retrograde labeling of vagal motoneurons by injection of -subunit of cholera toxin (CT-) into right lung after right cervical vagotomy. If, as hypothesized, motor nerve fibers cross the midline caudal to the vagotomy, then only neurons on the left side of the medulla would be labeled. B: retrograde double labeling of medullary vagal motoneurons by injections of CT- (black) and FluoroGold (FG; gray) into right and left main stem bronchi, respectively. Vagal neurons innervating exclusively one bronchus would be labeled only by the corresponding marker (solid black or gray circles); in contrast, neurons that innervate both bronchi may be immunoreactive for both markers (split black and gray circles). C: input pathways between vagal nuclei by pseudorabies virus injected into the right lung after right cervical vagotomy. Because the vagotomy severs all nerve fibers originating on the right side of the medulla (A), viral infection (dark circles) of neurons in right nucleus ambiguus indicates retrograde transneuronal labeling via vagal motoneurons on the opposite side. D: right thoracic vagotomy caudal to the origin of the recurrent laryngeal nerve (RLN). Preservation of right or left lung responses to right cervical vagus stimulation (Stim) would indicate that fibers bound to the right and left lungs, respectively, exit the nerve trunk above or with this nerve. VN, vagus nerve; NG nodose ganglion.

Pulmonary injections of CT-. The rats were anesthetized with halothane (0.5-3%), which was piped initially into an induction box or, after the institution of mechanical ventilation, blended into the inspiratory limb of the ventilator's circuit. The trachea was intubated through the mouth with the help of a pediatric otoscope, and the endotracheal cannula was connected to a rodent ventilator (Harvard Apparatus, South Natick, MA). The lung, right or left, was exposed under a dissecting microscope through a lateral thoracotomy at the fourth or fifth intercostal space. A 50-µl volume of 0.1% CT- suspension (List Biological Laboratories, Campbell, CA) was then injected into the lung parenchyma with use of a Hamilton microsyringe (Reno, NV). The injectate volume was divided into 5-10 injections, each performed with the needle tip ~1-3 mm below the pleural surface while lung volume was held constant to minimize disruption of the lung tissue. After every injection, the visceral pleura was blotted with a cotton-tipped probe to minimize nonspecific neuronal labeling by leaked CT- suspension. After completion of the injections, the lung surface was washed thoroughly with normal saline and allowed to dry for 3-5 min before the thoracotomy was closed by layers. A small silicone rubber tube was left inside the chest for removal of any air remaining in the pleural space at the end of the surgery. On recovery from anesthesia, the rat was returned to the holding facility, where it remained for 9-11 days.

Cervical and thoracic vagotomies. Cervical vagotomies were carried out through a paramedial neck incision. The vagus nerve was isolated from the carotid artery, and a 0.5-cm segment of the nerve distal to the origin of the superior laryngeal nerve was removed. The incision was closed by layers. Thoracic vagotomies were performed only on the right side to minimize animal usage. The vagus nerve was visualized through a lateral thoracotomy by retracting the lung anteriorly. The entire trajectory of the nerve caudal to the origin of the recurrent laryngeal nerve was dissected from the surrounding tissues and removed. The thoracotomy was closed as described above.

Effect of unilateral vagal stimulation on lung resistance. Rats were anesthetized with pentobarbital sodium (50 mg/kg ip). The trachea and the vagus nerves were exposed through a midline neck incision, and a tracheostomy was performed at the second intercartilaginous space. A cannula made from a 6-cm section of PE-190 tubing (0.12 cm ID) tapered at the end was inserted into the trachea and secured with a tie placed around the trachea and cannula. The tracheal cannula was connected to the rodent ventilator through an ensemble consisting of a small tube with a lateral port for measurement of airway pressure (model MAP45, ±56 cmH₂O, Validyne Engineering, Northridge, CA) and a Fleisch no. 000 pneumotachograph attached to a differential pressure transducer (model MAP45, ±2.3 cmH₂O) for measurement of airway gas flow. The length of the tubing connections was adjusted to ensure that the transducer outputs were well matched dynamically and had an amplitude-frequency response appropriate for the conditions of the experiments. The transducer outputs were amplified and recorded digitally at an acquisition rate of 500 Hz.

Bilateral Innervation of Airways by Vagal Motoneurons

The rats (n = 24) were prepared as described above for the pulmonary injections. The main stem bronchus, right or left, was visualized through a lateral thoracotomy by retracting the lung anteriorly. CT- (0.1%) or FG (15% solution, Fluorochrome, Denver, CO), dissolved in a 1- to 1.5-µl volume, was injected through a glass micropipette mounted on an X-Y-Z micromanipulator (Stoelting, Wood Dale, IL) in two to five individual injections distributed over the external surface of the bronchus. The bronchial serosa was lifted slightly with the tip of the pipette before the injections to facilitate diffusion of the injectate within the subserosal space and minimize backpressure-induced leakage. Once again, the surface of the bronchus was blotted with a cotton-tipped probe after each injection, and the pleural space was washed thoroughly with normal saline before the thoracotomy was closed. The contralateral bronchus was injected with the alternative neuronal marker 24 h later after a similar procedure. The survival period before removal of the brain and spinal cord was 11-12 days.

Interconnections Between Vagal Medullary Centers: Pseudorabies Virus Injections

Pseudorabies virus was injected into the right lung of 28 rats, which were divided into 2 groups of 14 rats each, depending on whether the cervical vagotomy was on the right or left side. (Once again, no injections were performed into the left lung to minimize animal usage.) The procedure was analogous to that described above for the CT- injections. The viral suspension containing 3-4 × 10⁷ plaque-forming units of the Bartha strain of pseudorabies virus was injected in 0.3-µl aliquots to a total injection volume of 1-1.5 µl. The survival period after the injections was 5 days.

Selectivity of Neuronal Tracer Injections

The first experiment studied the distribution over time of a sample of ¹²⁵I-CT- injected into the lungs of nine rats. Radioiodination of CT- was performed as described previously (17). A standard 0.25% suspension of CT- (List Biological) was diluted 1:1 to a final volume of 200 µl with 0.1 M NaPO₄-buffered saline and incubated for 10 min with 20 µl of a solution containing 2 mCi of Na¹²⁵I (New England Nuclear, Boston, MA) in the presence of two Iodo-Beads (Pierce Chemical, Rockford, IL). After addition of 30 µl of cytochrome c (20 mg/ml; Sigma-Aldrich, St. Louis, MO) as a color label, the reaction volume was fractionated in a Sephadex G-10 column (Sigma-Aldrich). A 20- to 40-µl volume of the radiolabeled CT- fraction (specific activity ~4,600 cpm/ng, concentration 0.08%) was then injected in 10-µl aliquots into the right or the left lung following the procedure described above. After survival periods of 8 h (n = 2), 24 h (n = 3), and 7 days (n = 4), the thoracic viscera were removed. The lungs were cut in coronal slices, which were then mounted flat on a film plate along with the trachea and esophagus to obtain an autoradiographic image. Lastly, the lung tissue was homogenized, and the number of radioactive counts in representative samples from each lung was determined in a scintillation counter.

The second control experiment was aimed at establishing whether CT- suspension leaked from the injection sites may cause unintended labeling of medullary neurons innervating other organs in the thoracic cavity. We performed a small right lateral thoracotomy in six rats and instilled a 30-µl volume of a 0.1% suspension of CT- on the lung surface. The thoracotomy was then closed by layers. The survival period after the injections was 11 days.

The third control experiment compared the topographic distribution of medullary neurons labeled by concomitant injections of CT- into the lung and FG into the esophagus. This comparison was intended to identify double-labeled neurons, which would alert us of the presence of CT- leakage from lung injection sites. The injections were performed through a right thoracotomy in 13 rats. CT- (50 µl of 0.1% suspension) was injected into the right rostral and medial lobes as described above. FG (0.8 µl of a 4% solution) was injected into the right aspect of the wall of the midthoracic portion of the esophagus with a glass micropipette. The survival period was 11-13 days.

Finally, the last control experiment tested our ability to discern between neurons innervating adjacent airway targets by comparing the distribution of medullary neurons labeled by CT- and FG, each injected alternately into the extra- or intrathoracic trachea of six rats. Because innervation of the trachea appears to follow a segmental pattern (15), we predicted that these injections would label two distinct populations of parasympathetic preganglionic neurons. CT- (1 µl of 0.1% suspension) and FG (1 µl of 15% solution) were injected into the anterior or lateral wall of the trachea, which was exposed through a midline neck incision for the extrathoracic injections and through a lateral thoracotomy for the intrathoracic injections. The survival period was 11-13 days.

Preparation and Staining of Brain Tissue

The brain stems were cut into 50-µm-thick coronal sections on a freezing microtome. A 1-in-5 series of the sections was immersed in a blocking solution containing 5% donkey serum (Sigma-Aldrich) in 0.3% Triton X-100 and 0.02 M potassium phosphate buffer at room temperature for 30 min and incubated overnight, also at room temperature, with the appropriate solution of primary antiserum (Table 1). After they were rinsed thoroughly in buffered saline, the sections were placed for 3-4 h in a 1:100 dilution of biotinylated anti-IgG antiserum (single-labeling studies) or 1:50 dilutions of fluorescent-labeled (FITC or FITC and tetramethylrhodamine isothiocyanate) anti-IgG antisera (double-labeling studies) at room temperature. All the species-specific anti-IgG antibodies were raised in donkey and purchased from Jackson ImmunoResearch Laboratories (West Grove, PA). The sections treated with biotinylated antisera were washed, treated for 1 h with an avidin-horseradish peroxidase complex (Vectastain ABC kit, PK-400, Vector Laboratories, Burlingame, CA), and stained with 0.05% diaminobenzidine tetrahydrochloride in buffered saline containing 0.003% hydrogen peroxide. Staining was intensified by sequential incubation with 1.5% silver nitrate for 1 h at 56°C, 0.2% gold chloride for 15 min, and 5% sodium thiosulfate for 5 min, both at room temperature, then the sections were counterstained with 0.6% thionin in 0.2 M acetic acid buffer. The processed sections were mounted on gelatinized glass slides, covered with a buffered glycerol solution (containing 0.1% p-phenylenediamine for fluorescent-stained sections to prevent fading), and protected with coverslips.

Data Analysis

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Midline Crossing by Vagal Motor and Sensory Fibers

Characteristics of neuronal and sensory fiber labeling by lung injections of CT-. Neuronal somata and sensory fibers were labeled in the medulla of all but 3 of the 32 rats that survived the 9- to 11-day period allowed for transport of CT- from the lung injection site to the central nervous system. Deaths usually occurred within 12 h of the surgery, bearing no apparent relationship in their frequency to the side of the injection or to whether the rat had undergone a cervical vagotomy.

View larger version (33K): [in this window] [in a new window]   Fig. 2.   Effect of right or left cervical vagotomy on topographical distribution of vagal motoneurons labeled retrogradely by injections of CT- into the left or right lung of rats. Counts of neuronal somata labeled by CT- in the left (LNA) or right (RNA) nucleus ambiguus and left (LDMV) or right (RDMV) dorsal motor nucleus of the vagus are plotted at 0.5-mm intervals from 14.5 to 11.5 mm caudal to bregma (B  14.5 and B  11.5). Cervical vagotomies precluded labeling of ipsilateral vagal motoneurons but had no discernible effect on the number of labeled contralateral neurons. When the vagi were left intact, a greater number of neuronal somata was labeled by the left than by the right lung injections (P = 0.002). Shading of squares and connecting lines are used to identify each rat at various levels of the medulla.

View larger version (78K): [in this window] [in a new window]   Fig. 3.   Effects of cervical vagotomy on retrograde labeling of vagal motoneurons in the compact and external formations of the nucleus ambiguus (NA, 12.5 mm caudal to bregma) after injection of CT- into the left lung. A: vagi intact. B: right cervical vagotomy. C: left cervical vagotomy. Unilateral cervical vagotomy precluded labeling of neuronal somata in the ipsilateral nucleus (arrows point at compact formation), indicating that vagal motor nerve fibers bound for the lungs do not decussate in the brain stem. CT--labeled neurons are demonstrated with diaminobenzidine tetrahydrochloride staining. GiV, ventral division of gigantocellular reticular nucleus; LPGi, lateral paragigantocellular nucleus; RVLM, rostroventrolateral reticular nucleus. Line drawing of brain stem section is modified from Paxinos and Watson (23a).

View larger version (99K): [in this window] [in a new window]   Fig. 4.   Effect of right cervical vagotomy on anterograde labeling of vagal sensory fibers by left lung injection of CT-. Labeled fiber fields were found in the area of the commissural subnucleus (com) of the nucleus of the tractus solitarius in the caudal medulla and in the medial (med) and ventrolateral (vl) subnuclei of the same nucleus more rostrally. No sensory fibers were labeled on the side of the vagotomy, indicating that lung sensory nerves do not undergo decussation in the medulla. AP, area postrema; Cu, cuneate nucleus; DMV, dorsal motor nucleus of the vagus; gel, gelatinous subnucleus of the nucleus of the tractus solitarius; Gr, nucleus gracilis; T, tractus solitarius; XII, hypoglossal nucleus. Notations at top of photomicrographs on right indicate location of section relative to bregma (mm). CT--labeled nerve fibers are demonstrated with diaminobenzidine tetrahydrochloride staining.

Effect of unilateral vagotomy on neuronal and sensory fiber labeling. Cervical vagotomies prevented labeling of neuronal somata and sensory fibers on the ipsilateral medulla but did not affect labeling in the contralateral medulla (Figs. 2-4). The vagotomies had no apparent effect on the proportions of neuronal somata labeled in the nucleus ambiguus complex and dorsal motor nucleus of the vagus or, within the nucleus ambiguus, on the partition of labeled neurons between the compact and external formations.

Effect of thoracic vagotomy on response to vagal stimulation and CT- labeling after lung injections of CT-. Electrical stimulation of the distal stump of the cervical vagus increased the resistances opposed by both lungs to airflow (Fig. 5). The increases were maximal at stimulation frequencies of 30-40 Hz and were more pronounced in the ipsilateral than in the contralateral lung (2.1 ± 0.2 and 2.9 ± 0.7 times greater, depending on whether the left or the right vagus was stimulated) and during left than during right vagal stimulation. Interruption of the right vagus nerve caudal to the origin of the recurrent laryngeal nerve reduced the responses of both lungs to stimulation of the right cervical vagus (left lung by 75% and right lung by 59%), without changing their responses to stimulation of the left cervical vagus. The right thoracic vagotomy reduced substantially, but did not eliminate, neuronal labeling in the right nucleus ambiguus (data not shown) after right lung injections of CT-. We therefore concluded that the residual increases in airflow resistance produced by cervical vagal stimulation after thoracic vagotomy were elicited by bronchomotor fibers exiting the vagus with the recurrent laryngeal nerve or rostral to it.

View larger version (13K): [in this window] [in a new window]   Fig. 5.   Effect of unilateral midthoracic vagotomy on increases in resistance opposed by each lung to airflow during supramaximal vagal stimulation. Before vagotomy, resistances of both lungs increased in response to unilateral vagal stimulation, but increase was more pronounced in the lung ipsilateral to the stimulated vagus (P = 0.0001) and during left than during right vagal stimulation (P = 0.0001). Interruption of the right vagus caudal to the origin of the recurrent laryngeal nerve reduced but did not eliminate responses of both lungs to stimulation of the right cervical vagal trunk, suggesting that lung-bound vagal motor fibers emerge from the vagal trunk at the origin of the recurrent laryngeal nerve or rostral to this nerve.

Bilateral Innervation of Airways by Vagal Motoneurons

View larger version (29K): [in this window] [in a new window]   Fig. 6.   Retrograde labeling of vagal motoneurons in the nucleus ambiguus by separate injections of CT- and FG into the main stem bronchi. Counts of single (CT- or FG)- and double-labeled (CT- + FG) neurons in the left (LNA) and right (RNA) nucleus ambiguus are plotted at 0.5-mm intervals from 14.5 (B  14.5) to 11.5 mm (B  11.5) caudal to bregma for each of the 2 labeling schemes used in the experiment.

Double labeling (Fig. 7), indicating uptake of both markers by the same neuron, was observed in one or more sections in all the rats. Of all the neurons labeled by CT- in the nucleus ambiguus, 30% were also labeled by FG; conversely, of all the nucleus ambiguus neurons labeled by FG, 11% were also labeled by CT-.

View larger version (27K): [in this window] [in a new window]   Fig. 7.   Fluorescence-labeled neurons in the left nucleus ambiguus of a rat injected with FG (demonstrated with FITC-conjugated antiserum) into the left main stem bronchus and CT- [demonstrated with tetramethylrhodamine isothiocyanate (TRITC)-conjugated antiserum] into the right main stem bronchus. Neurons containing both markers appear yellow in this double exposure (arrowheads). Neurons labeled only by CT- and FG appear red (arrows) and green, respectively. NA, nucleus ambiguus; GiV, ventral division of gigantocellular reticular nucleus; LPGi, lateral paragigantocellular nucleus. Section is located 12.5 mm caudal to bregma. Line drawing of brain stem section is modified from Paxinos and Watson (23a).

Interconnections Between Vagal Medullary Centers

View larger version (58K): [in this window] [in a new window]   Fig. 8.   Composite chart showing distribution of virus-infected neurons (red stars) in rats that had undergone a left (n = 6) or right (n = 7) cervical vagotomy before being injected with pseudorabies virus into the right lung (incubation period after injections = 5 days). Unilateral vagotomy reduced, but did not eliminate, retrograde viral labeling in the ipsilateral nucleus ambiguus and dorsal motor nucleus of the vagus. Considered in conjunction with the information shown in Fig. 3, this finding suggests that vagal motoneurons projecting to the lungs receive inputs from the contralateral vagal centers. These inputs may help coordinate vagal outflows from both sides of the medulla. Vagotomy also had no apparent effect on distribution of second- or higher-order premotor neurons, but some of these neurons may have been infected via the sympathetic nerve supply of the lung, which was not interrupted. A5, A5 noradrenergic group; Cu, cuneate nucleus; DC, dorsal cochlear nucleus; DMV, dorsal motor nucleus of the vagus; Gi, gigantocellular reticular nucleus; GiV, ventral division of gigantocellular reticular nucleus; Gr, nucleus gracilis; KF, Kölliker-Fuse nucleus; LC, locus ceruleus; LPGi, lateral paragigantocellular nucleus; LVe, lateral vestibular nucleus; MoV, motor trigeminal nucleus; Mve, medial vestibular nucleus; NA, nucleus ambiguus; NRA, nucleus retroambigualis; NTS, nucleus of the tractus solitarius; Pr, prepositus nucleus; PT, pyramidal tract; RMg, raphe magnus nucleus; ROb, raphe obscurus nucleus; Rpa, raphe pallidus nucleus; SpV, spinal trigeminal nucleus; SC, locus subceruleus; SpVe, spinal vestibular nucleus; VII, facial nucleus; XII, hypoglossal nucleus.

Unilateral cervical vagotomies reduced but did not eliminate the presence of virus-infected neurons in the nucleus ambiguus and dorsal motor nucleus of the vagus ipsilateral to the cut vagus nerve (Fig. 9). Simultaneous staining with antibodies against choline acetyltransferase confirmed the cholinergic identity of these neurons (Fig. 10).

View larger version (68K): [in this window] [in a new window]   Fig. 9.   Virus-infected neurons identified by diaminobenzidine tetrahydrochloride staining in the medulla (bregma  12.5 mm) of a rat, the right lung of which was injected with pseudorabies virus. Although the left cervical vagus was cut, infected neurons are present in the left nucleus ambiguus (arrows). Because cervical vagotomy precludes ipsilateral labeling of preganglionic neurons after injection of CT- (see Fig. 3), the neurons stained in the left nucleus ambiguus must be infected transsynaptically via contralateral vagal motoneurons. GiV, ventral division of gigantocellular reticular nucleus; NA, nucleus ambiguus; ROb, raphe obscurus nucleus; RPa, raphe pallidus nucleus. Line drawing of brain stem section is modified from Paxinos and Watson (23a).

View larger version (78K): [in this window] [in a new window]   Fig. 10.   Infected cholinergic neurons in the rostralmost portion of the right nucleus ambiguus compact formation in a rat that underwent a right cervical vagotomy before injection of pseudorabies virus into the right lung. Left photomicrograph shows choline acetyltransferase immunoreactivity (green fluorescence with FITC-conjugated antiserum) in right ventrolateral medulla (bregma  12.5 mm). Right photomicrograph is an enlarged double exposure of the nucleus ambiguus, where virus-infected neurons appear yellow (double fluorescent staining) or red (arrows, TRITC-conjugated antiserum) depending on whether they are cholinergic or not (scale bar 100 µm). Gi, gigantocellular nucleus; LPGi, lateral paragigantocellular nucleus; NA, nucleus ambiguus; VII, facial nucleus. Line drawing of brain stem section is modified from Paxinos and Watson (23a).

Controls for Selectivity of Tracer Injections

Distribution of ¹²⁵I-CT- injected into the lung. Autoradiographic analysis confirmed that, although the injected ¹²⁵I-CT- was almost entirely removed from the lung after 7 days, within the lungs, the tracer did not migrate beyond the immediate vicinity of the injection sites (Fig. 11). No accumulation of radioactivity was found in the contralateral lung, the trachea, or the esophagus. The ratio of total lung count measured in homogenates of injected and contralateral lungs removed at 8 h to that removed at 24 h was <0.02.

View larger version (63K): [in this window] [in a new window]   Fig. 11.   Local permanence of radioactive tracer 8 h, 24 h, and 7 days after injection of 125I-CT- into 1 lung. Each rat's lungs were sectioned in the coronal plane. Lung sections (top at each time) and esophagus and trachea (small squares below lung sections) were laid out flat on a glass surface and covered with photographic film. After a 90-min exposure, the film was removed and the sections were photographed. Autoradiograph and photographic images were scanned digitally, scaled, and superimposed. The contour of the tissue was then traced over its corresponding location on the autoradiograph before the tissue image was deleted.

Labeling of vagal medullary neurons by intrapleural CT-. None of the six rats injected with CT- suspension into the pleural space exhibited labeling of neuronal somata or sensory fiber terminals in the medulla (data not shown).

Distinction between pulmonary and esophageal motoneurons. Injections of CT- into the rostral and medial lobes of the right lung and FG into the wall of the midthoracic esophagus produced concurrent labeling in the nucleus ambiguus and dorsal nucleus of the vagus in 7 of the 12 rats that survived the procedure. No double labeling was detected in any of these rats (Fig. 12). The somata of the majority of the neurons labeled by the injections of CT- into the lungs were once again distributed bilaterally between the compact and the external formations of the nucleus ambiguus in the sections located between 13.5 and 11.5 mm caudal from the bregma. The somata of the neurons labeled by the injections of FG into the esophageal wall were also found bilaterally, but they were circumscribed to the compact formation, where they were interspersed with the CT--labeled neurons. Esophageal neurons adopted a more rostral distribution than the pulmonary neurons; they were found rarely in medullary sections >12.5 mm caudal to the bregma.

View larger version (18K): [in this window] [in a new window]   Fig. 12.   Photomicrographs (top) show vagal motoneurons labeled retrogradely in the right nucleus ambiguus complex by concurrent injections of CT- into the rostral and medial lobes of the right lung (stained red with a TRITC-conjugated antiserum) and FG into the wall of the midthoracic esophagus (stained green with FITC-conjugated antiserum). Esophageal motoneurons were circumscribed to the compact formation of the nucleus and present only in the rostralmost sections; pulmonary motoneurons were distributed between the compact and external formation of the nucleus and had a wider rostrocaudal range. No double-labeled neuronal somata were found in any of the 7 rats that exhibited uptake of both neuronal tracers by medullary neurons. Bar graph (bottom) shows counts of motoneurons (horizontal line indicates median numbers, and bars indicate 10th-90th percentile ranges) labeled by pulmonary injections of CT- (red) and esophageal injections of FG (green) in the compact (CF) and external (EF) formations of the nucleus ambiguus (n = 7 rats). Line drawings of brain stem sections are modified from Paxinos and Watson (23a); distance from bregma is shown at top of each drawing. Gi, gigantocellular reticular nucleus; LPGi, lateral paragigantocellular nucleus; L Ret, lateral reticular nucleus; NA, nucleus ambiguus.

Distinction between motoneurons innervating extra- and intrathoracic trachea. Labeling by CT- and FG injected into extra- and intrathoracic segments of the trachea coexisted in all six rats included in this control experiment. We found no double-labeled neuronal somata in the nucleus ambiguus or dorsal motor nucleus of the vagus in any of these rats (Fig. 13).

View larger version (51K): [in this window] [in a new window]   Fig. 13.   Fluorescence-labeled neurons in the left nucleus ambiguus of a rat injected with FG (stained in green with FITC-conjugated antiserum) into the intrathoracic trachea and CT- (stained in red with TRITC-conjugated antiserum) into the extrathoracic trachea. No double-labeled neurons are present. NA, nucleus ambiguus; LPGi, lateral paragigantocellular nucleus. Section is located 13 mm caudal to bregma.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The autonomic innervation of bilateral organs that are functionally interdependent must contain mechanisms to prevent asymmetries in neural input from interfering with mechanical efficiency. In the case of the lungs, the mechanism appears to be based in part on a system of double innervation, whereby each lung receives supplies of motor and sensory nerve fibers from both vagus nerves. In the present study we demonstrate that 1) as many as one-half of the vagal motor fibers and a smaller, but still substantial, proportion of the sensory fibers destined for the rat's lungs cross the midline, and they do so exclusively inside the thorax; 2) at least for the main stem bronchi, a single medullary motoneuron can innervate airways on both sides of the midline; and 3) medullary vagal motoneurons that project to the lungs receive inputs from an extensive bilateral neuronal network that includes sensory relay areas in the nucleus tractus solitarius and the contralateral nucleus ambiguus and dorsal motor nucleus of the vagus.

Midline Crossing by Vagal Motor Fibers

Two additional observations of our study deserve mention in connection with the lateral distribution of vagal fibers in the lungs. First, left lung injections labeled a larger number of neurons in the nucleus ambiguus (right and left) than right lung injections. Although we did not compare the diffusion of CT- in the lungs quantitatively, we believe that this disparity is likely to have resulted from a greater spread of the neuronal tracer in the unilobar left lung than in the multilobar right lung. Second, the increases in airflow resistance elicited by unilateral vagal stimulation were greater in the ipsilateral than in the contralateral lung. To interpret this observation (or any other quantitative results obtained from vagal stimulation), it is important to consider that lung resistance increases during vagal stimulation are influenced by factors such as the geometry of the airways (24) and the effectiveness with which the electrical stimulus mimics physiological conduction in the nerve. The latter, in particular, is influenced by the proportion of myelinated and unmyelinated fibers present in each vagus. There is convincing evidence that, in the guinea pig, capsaicin-responsive fibers remain committed to the ipsilateral vagus nerve (32). Thus, at least in this species, unilateral vagal stimulation at the frequencies and pulse duration used in our experiments (32) is likely to elicit greater contraction of ipsilateral than contralateral airways. Tachykinins released antidromically by ipsilateral unmyelinated sensory fibers in response to the stimulus can be expected to sensitize local ganglia to the effects of other depolarizing stimuli (4, 21) and may cause bronchoconstriction directly (18). A similar effect would be observed if vagal motor fibers were segregated to provide preferential innervation to ipsilateral airway smooth muscle targets (as opposed to glands or blood vessels) or established a larger number of ganglionic synapses in the ipsilateral than in the contralateral airways. Such arrangements would have the advantage of allowing the vagal centers to retain individual control of the cholinergic outflow to each lung without losing the benefits of a bilateral distribution in the prevention of large asymmetries in airway tone.

Location of Lung Vagal Motoneurons and Central Afferents in the Medulla Oblongata

The participation of the compact formation of the nucleus ambiguus in the innervation of the airway and lung tissues challenges some of the views expressed by Bieger and Hopkins (5) in their authoritative analysis of the representation of the upper alimentary tract in the rat's medulla oblongata. These investigators asserted that this subdivision of the nucleus ambiguus is dedicated exclusively to the efferent innervation of striated esophageal muscle. The results of our control experiments, especially the absence of double labeling of neuronal somata by the concurrent injections of CT- into the lung and FG into the esophagus, argue against any concerns that the visualization of compact formation neurons after lung tracing experiments was an artifact caused by spread of the tracer to the adventitial surface of the esophagus. Far from negating that the nucleus ambiguus is organized in a viscerotopic fashion, the coexistence of esophageal and lung neurons in the same nuclear subdivision is, in our opinion, consistent with the common embryologic origin of the two organs and with the observation that a subpopulation of esophageal parasympathetic ganglia participates directly in the control of airway tone (6).

Kalia and Mesulam (15) were also the first to report that afferent nerve fibers from the cat's right lung end bilaterally in the nucleus of the tractus solitarius, concentrating in the ventrolateral, dorsolateral, and commissural subnuclei of the nucleus of the tractus solitarius. More recently, Haxhiu and Loewy (12), using CT- as an anterograde tracer, described a slightly different topographical termination pattern for the trachea's sensory nerves of rats, ferrets, and dogs, whereby the majority of the sensory fibers ended in the medial, ventrolateral, and commissural subnuclei of the same nucleus. These findings, which are similar to those presented here for the rat's lungs, verify that the airways and the esophagus have anatomically separate sensory relays in the nucleus of the tractus solitarius, with most of the esophageal fibers ending in the central subnucleus (1). Evidence of this separation, which had been noticed by Altschuler et al. (1) in their detailed description of the viscerotopic sensory representation of the upper alimentary tract in the rat, adds further support to the contention that CT- injected into the lung did not spread to the esophagus in our experiments.

Bilateral Innervation of Airways by Vagal Motoneurons

Clearly, a considerable number of vagal motoneurons project to both main stem bronchi. However, the observed discrepancy in the degree of neuronal labeling by CT- and FG (most likely the result of the greater tissue spread of the latter) limits our ability to draw a more quantitative estimate of the number of cells with bilateral projections. This discrepancy may reflect differences in the uptake, transport, and immunoreactive characteristics of the two markers rather than to nonspecific labeling by either of them. Except for the number of labeled neurons, the distributions of the CT-- and FG-labeled neurons were undistinguishable. Furthermore, the labeling disparity occurred, despite the use of similar injectate volumes of CT- and FG and the alternation of injection side. Finally, previous studies have shown that neither CT- nor FG is incorporated by undamaged fibers of passage (19, 27), which reduces the possibility that FG simply labeled a greater number of fibers destined for distal airways than CT-.

Interconnections Between Vagal Medullary Centers

A note of caution is pertinent in interpreting these results. Unlike some of the earlier experiments (10, 11, 25), our design did not include the interruption of the sympathetic pathways from the lung (11, 25). The obvious conclusion that preganglionic neurons receive regulatory inputs from both sides of the medulla must therefore be tempered by the possibility that some of the extensive bilateral labeling by the virus occurred through sympathetic nerves.

Nevertheless, retrograde passage via the sympathetic system is unlikely to explain the presence of the virus in the vagal nuclei. Injections of pseudorabies virus into structures such as the stellate ganglion or the adrenal gland, which are innervated by medullary sympathetic neurons, do not infect neurons in the ambigual complex or in the dorsal motor nucleus of the vagus (14). This leaves no plausible route for the infection of the vagal nuclei ipsilateral to the vagotomy other than the contralateral lung-projecting vagal motoneurons. The specific occurrence of interconnections between the nuclei ambigua is well documented by direct injections of retrograde markers into various portions of the ambiguus complex in the rat (22). Here we show that at least some of these interconnections may be involved in the coordination of vagal output to the lungs from both sides of the medulla. Our present data do not allow us to establish, however, whether the coordinating inputs are channeled through medullary interneurons, respiratory vagal motoneurons, or other vagal premotor neurons.

Perspectives