Labeling of vagal motoneurons and central afferents after injection of cholera toxin B into the airway lumen.

We tested the hypothesis that application of the subunit B of cholera toxin (CTB) to the airway mucosa would produce labeling of neuronal somata and sensory fibers in the medulla oblongata. Using (125)I-CTB as a tracer, we demonstrated first that CTB is transported across the tracheal epithelium, but once in the airway wall, it remains confined to the subepithelial space and lamina propria. Despite the rarity of intrinsic neurons in these areas, intraluminal CTB labeled approximately 10-60 neurons/rat in the nucleus ambiguus and a smaller number of neurons in the dorsal motor nucleus of the vagus. Well-defined sensory fiber terminals were also labeled in the commissural, medial, and ventrolateral subnuclei of the nucleus of the tractus solitarius. Approximately 50 and 90% of the neurons labeled by intraluminal CTB were also labeled by injections of FluoroGold into the tracheal adventitia and lung parenchyma, respectively. These findings demonstrate that a substantial number of medullary vagal motoneurons innervate targets in the vicinity of the airway epithelium. These neurons do not appear to be segregated anatomically from vagal motoneurons that project to deeper layers of the airway wall or lung parenchyma.

Bilateral distribution of vagal motor and sensory nerve fibers in the rat's lungs and airways.

This study combined single and transneuronal labeling to define the origin of midline-crossing vagal fibers projecting to the rat's lungs. Injections of the beta-subunit of cholera toxin (CT-beta) into the lungs labeled similar numbers of neuronal somata in the nucleus ambiguus and dorsal motor nucleus of the vagus on both sides of the medulla, even though vagal stimulation increased lung resistance 50% less in the contralateral than in the ipsilateral lung. Unilateral cervical vagotomy prevented CT-beta labeling of ipsilateral neuronal somata and sensory fibers, indicating that lung-bound vagal fibers undergo decussation only inside the thorax. Injections of CT-beta and FluoroGold into opposite main stem bronchi double labeled 30% and 11% of all neuronal somata immunoreactive for CT-beta and FluoroGold, respectively, showing that one single vagal motoneuron can innervate airways on both sides. Injections of pseudorabies virus into the right lung revealed a bilateral network of infected neurons, even after unilateral vagotomy. The latter did not prevent infection of the ipsilateral vagal nuclei. These findings demonstrate that vagal motoneurons that project to the lungs receive contralateral inputs from the airway premotor network and vagal bronchomotor centers.

Substance P and neurokinin-1 receptor expression by intrinsic airway neurons in the rat.

Tachykinins and their receptors are involved in the amplification of inflammation in the airways. We analyzed the expression of preprotachykinin-A (PPT-A) and neurokinin-1 (NK-1) receptor genes by intrinsic airway neurons in the rat. We also tested the hypothesis that PPT-A-encoded peptides released by these neurons fulfill the requisite role of substance P in immune complex injury of the lungs. We found that ganglion neurons in intact and denervated airways or in primary culture coexpress PPT-A and NK-1 receptor mRNAs and their protein products. Denervated ganglia from tracheal xenografts (nu/nu mice) or syngeneic lung grafts had increased PPT-A mRNA contents, suggesting preganglionic regulation. Formation of immune complexes in the airways induced comparable inflammatory injuries in syngeneic lung grafts, which lack peptidergic sensory fibers, and control lungs. The injury was attenuated in both cases by pretreatment with the NK-1 receptor antagonist LY-306740. We conclude that tachykinins released by ganglia act as a paracrine or autocrine signal in the airways and may contribute to NK-1 receptor-mediated amplification of immune injury in the lungs.

Increased type I procollagen mRNA in airways and pulmonary vessels after vagal denervation in rats.

To test the hypothesis that increased airway strain resulting from lung denervation initiates a fibroproliferative response in the airways, we compared the transcriptional expressions of alpha1(I)-procollagen and tropoelastin in the lungs of rats subjected to unilateral vagal denervation, unilateral vagal denervation combined with ipsilateral phrenectomy, or thoracotomy without denervation (controls). We found increases in alpha1(I)-procollagen messenger ribonucleic acids (mRNAs) in the submucosa of the airways and the adventitia of airways and pulmonary vessels of the denervated lungs in 31% of the rats subjected to unilateral denervation (with and without phrenectomy), and in none of the controls. The increased transcripts were associated with collagen deposition in the peribronchial and perivascular tissue, and occasionally with cell proliferation leading to occlusion of the airway and vascular lumina. Unilateral phrenectomy did not decrease the frequency with which production of Type I procollagen was upregulated, suggesting that the upregulation was not entirely dependent on airway strain. Tropoelastin expression was not influenced by denervation. Our results indicate that the autonomic nervous system has a previously unsuspected trophic influence on collagen synthesis in the airways and pulmonary vessels. Abolition of this influence by denervation may lead to structural changes analogous to those observed in bronchiolitis obliterans after lung transplantation.

Neuroanatomic organization of the parasympathetic bronchomotor system in developing sheep.

We applied two complementary retrograde labeling techniques to characterize the organization of the brain stem neuronal network responsible for the vagal innervation of the trachealis muscle in developing sheep. Single neuronal labeling produced by injections of the beta-subunit of cholera toxin into the muscle in newborn lambs showed that airway vagal preganglionic neurons are located exclusively in the nucleus ambiguous and nucleus of the solitary tract. Transneuronal labeling produced by similar injections of the Bartha strain of the pseudorabies virus in sheep fetuses demonstrated that these airway vagal preganglionic neurons receive inputs from a small number of neurons in brain stem areas known to participate in premotor control of the respiratory muscles (ventral respiratory group), chemoreception (nucleus of the solitary tract and ventral medullary surface), and cardiovascular and respiratory regulation (raphe nuclei, ventrolateral medulla, and noradrenergic groups of the medulla and pons). We conclude that the vagal preganglionic neurons that project to airway smooth muscle are already integrated in the control of breathing before birth in sheep.