Thoracic vagus section distal to the recurrent laryngeal nerve reduces substance. P-immunoreactive innervation in the rat bronchial tree

Histamine-induced changes in rat tracheal goblet cell mucin store and mucosal edema

The pathology of chronic asthma in human and mouse is characterized by inflammation and remodeling of airway tissues. As a result of repeated inflammatory insults to the lower airways, smooth muscle thickening, mucin secretion and airway hyperreactivity may develop. In ovalbumin (OVA)-sensitized mice with repeated challenges with OVA to the lower airways, the trachea and bronchi are characterized by goblet cell hyperplasia and mucus hypersecretion from goblet cells. Previous study reports that intravenous (i.v.) application of a high dose of capsaicin releases tachykinin from capsaicin-sensitive nerves, producing acute plasma leakage and mucosal edema formation and causing depletion of mucin granules in goblet cells that results in a reduction in the number and size of Alcian blue (AB)-positive goblet cells in the rat trachea within a few minute after capsaicin application. Histamine is an important non-neural mediator of asthma from mast cells. The present study investigated whether i.v. application of a high dose of histamine (18 μmol/ml/kg) could result in these acute changes and the similar time-course changes in rat trachea. The tracheal whole mounts stained with chloroacetate esterase reagent and AB and tracheal methacrylate sections stained with AB and periodic acid-Schiff reagent were used for evaluation of histological and cellular changes. At 5 min after histamine application, mucosal leaky venules were numerous and subepithelial edema ratio (% of length of edema along the mucosal epithelial circumference of tracheal cross section) was found to be 48.2 ± 4.9, which was greater (P < 0.01) than saline-treated rats. But, the number of AB-positive goblet cells, 2,030 ± 170/mm(2) of mucosal surface epithelium, was similar to saline-treated group (P > 0.05). One day later, edema ratio remained large and the number of AB-positive goblet cells was 1,140 ± 150/mm(2) epithelium, reduced to half the number of the group at 5 min after histamine (P < 0.01). It is suggested that mucus hypersecretion occurred at this time point. At 3 or 5 days after histamine, edema ratio gradually decreased. The number of AB-positive goblet cells continued to remain small on day 3. On day 5 after histamine, the number of AB-positive goblet cells restored to the level of rat group at 5 min after histamine application. At 7 days after histamine, edema ratio returned to the level of saline-treated group. It is concluded that degranulation and thinning of tracheal goblet cells and mucus hypersecretion lagged behind histamine-induced acute plasma leakage and edema, and restoration of mucin store in goblet cells was associated with remission of mucosal edema.

Prophylactic proopiomelanocortin expression alleviates capsaicin-induced neurogenic inflammation in rat trachea

Neurogenic inflammation frequently causes acute plasma leakage in airways and life-threatening pulmonary edema. However, limited strategies are available to alleviate neurogenic inflammation. Proopiomelanocortin (POMC) is the precursor of anti-inflammatory melanocortins, which have been proposed of therapeutic potential for various inflammatory diseases. The present study aimed to evaluate whether peripheral POMC expression ameliorated capsaicin-induced acute neurogenic inflammation in rat trachea. Prophylactic POMC expression was achieved by intravenous injection of adenovirus encoding POMC (Ad-POMC), which led to POMC expression in livers and elevated plasma adrenocorticotropin levels for approximately 60 days. After gene delivery for 7 days, neurogenic inflammation was induced in rats by capsaicin injection. The extent of capsaicin-evoked plasma leakage in trachea was alleviated in Ad-POMC-treated rats compared with animals of control groups (P < 0.01). Moreover, the number of endothelial gaps in tracheal venules was also significantly decreased in Ad-POMC-treated animals (P < 0.01). Prophylactic POMC expression, however, did not alter the basal substance P (SP) expression or the capsaicin-induced SP elevation in trachea and circulation. Instead, cell cultures studies revealed that POMC overexpression or application of POMC-derived melanocortins potently inhibited the SP-induced migration of endothelial cells (P < 0.01), thereby possibly contributing to the attenuation of endothelial gap formation and plasma leakage. The present study indicates that the anti-inflammatory POMC gene vector or melanocortins may constitute a therapeutic alternative for neurogenic inflammation.

Dimethylthiourea pretreatment inhibits endotoxin-induced compound exocytosis in goblet cells and plasma leakage of rat small intestine

Intravenous application of a high dose of endotoxin, also called lipopoly-saccharide (LPS), results in endotoxemia in animals, that induces production of cytokines and free radicals, systemic inflammation and mucin discharge from mucous tissues. The present study was to investigate (1) whether LPS application increased goblet cell secretion by compound exocytotic activity in mucosal villi and crypts of rat small intestine, and (2) whether hydroxyl radicals were involved in LPS-induced compound exocytosis in goblet cells and plasma leakage. Scanning electron microscopy showed that the numbers of goblet cells undergoing compound exocytosis (cavitated goblet cells) per mm(2) of ileal villus epithelium in rats 5 and 30 min after LPS (15 mg kg(-1)) were 693 +/- 196 (N = 6) and 547 +/- 213 (N = 6), respectively, which were 5.1 and 8.4 times (P < 0.05) the number of saline control. The percentage of villus cavitated goblet cell numbers, in both duodenum and ileum 5 min after LPS and in the ileum 30 min after LPS, increased significantly (P < 0.05). Pretreatment with dimethylthiourea (DMTU), a hydroxyl radical scavenger, decreased the number of cavitated goblet cells to saline control (P > 0.05). Morphometric analysis showed that the percentage of crypt epithelial area in the duodenum and ileum occupied by goblet cell mucin stores in the duodenum and ileum 30 min after LPS were 3.8 +/- 0.2% (N = 6) and 6.9 +/- 0.5 (N = 6), respectively reducing to one half the amount of control (P < 0.01). When DMTU was given prior to LPS the crypt goblet cell mucin stores and the amount of plasma leakage returned to the level of control. It is concluded that hydroxyl radicals were involved in the LPS-induced increase in compound exocytotic activity of goblet cells and the increase in plasma leakage during acute phases of inflammatory response in rat small intestine.

Differentiation of neuronal from non-neuronal Substance P

Substance P (SP) originally found as a neuropeptide in capsaicin-sensitive sensory neurons, had more recently been identified in non-neuronal cells, especially under pathological conditions. Neuronal and non-neuronal SP may perform distinct functions. A simple technique to differentiate different SP sources is currently unavailable. Herein, we describe a two-step sequential acetic acid extraction to differentiate SP source. The efficiency of this two-step extraction in differentiating SP in capsaicin-sensitive neurons was verified by using capsaicin as a tool to deplete SP in sensory neurons. Specifically, Balb-c mice were treated with high dose capsaicin (200 mg/kg). Skin was removed two weeks after treatment. In a separate experiment, lung and skin tissues from control animals (untreated) were incubated in-vitro with capsaicin, and sequential acetic acid extraction was performed. Following capsaicin treatment, both in-vivo and in-vitro, SP recovered in first extraction decreased significantly in lung and skin. Lastly, presence of capsaicin solvent (10% methanol and 10% Tween 80) or protease inhibitor cocktail in solution altered SP EIA test, yielding false positive results. These results demonstrated that SP in capsaicin sensitive sensory neurons was extracted in initial extraction of 15 min while non-neuronal SP was present in second extraction. Because SP in non-neuronal tissues may possibly be more important in pathological conditions, this technique could be useful in determining effects of various treatments on neuronal and non-neuronal SP levels and their consequences.

Vagotomy enhances experimental metastases of 4THMpc breast cancer cells and alters substance P level

We have previously demonstrated that inactivation of capsaicin-sensitive sensory neurons enhances lung and heart metastases of breast carcinoma. Because a significant part of sensory innervation of lung tissue is supplied by the vagus nerve, we here examined the effects of unilateral mid-cervical vagotomy in the metastases of 4THMpc breast carcinoma and tissue Substance P (SP) levels. Balb-c mice were injected orthotopically with 4THMpc cells 1 week after vagotomy. Animals were sacrificed 27-30 days after injection of 4THMpc cells and the extent of metastases was determined. Unilateral vagotomy, right or left significantly increased the lung, liver and kidney metastases without altering the growth rate of the primary tumor. Heart metastases were increased only following left vagotomy. The changes in SP levels were somewhat surprising such that vagotomy actually increased while sham-operation decreased SP levels in lung. The effect of sham-operation was reversed by unilateral vagotomy demonstrating that vagal activity decreases total SP levels in the lung. Increased SP levels might be due to decreased degradation of the peptide. Presence of the tumor markedly increased SP level in the lung, which was more prominent in vagotomized animals. These results provide evidence that vagal activity may protect against metastatic disease.

Thoracic Vagal Efferent Nerve Stimulation Evokes Substance P-Induced Early Airway Bronchonstriction and Late Proinflammatory and Oxidative Injury in the Rat Respiratory Tract

Electrical stimulation of efferent thoracic vagus nerve (TVN) evoked neurogenic inflammation in respiratory tract of atropine-treated rats by an undefined mechanism. We explored whether efferent TVN stimulation via substance P facilitates neurogenic inflammation via action of nuclear factor-kappaB (NF-kappaB) activation and reactive oxygen species (ROS) production. Our results showed that increased frequency of TVN stimulation concomitantly increased substance P-enhanced hypotension, and bronchoconstriction (increases in smooth muscle electromyographic activity and total pulmonary resistance). The enhanced SP release evoked the appearance of endothelial gap in silver-stained leaky venules, India-ink labeled extravasation, and accumulations of inflammatory cells in the respiratory tract, contributing to trachea plasma extravasation as well as increases in blood O (2)(-) and H(2)O(2) ROS amount. L-732138 (NK(1) receptor antagonist), SR-48968 (NK(2) receptor antagonist), dimethylthiourea (H(2)O(2) scavenger) or catechins (O (2)(-) and H(2)O(2) scavenger) pretreatment reduced efferent TVN stimulation-enhanced hypotension, bronchoconstriction, and plasma extravasation. Increased frequency of TVN stimulation significantly upregulated the expression of nuclear factor-kappaB (NF-kappaB) in nuclear protein and intercellular adhesion molecule-1 (ICAM-1) in total protein of the lower respiratory tract tissue. The upregulation of NF-kappaB and ICAM-1 was attenuated by NK receptor antagonist and antioxidants. In conclusion, TVN efferent stimulation increases substance P release to trigger NF-kappaB mediated ICAM-1 expression and O (2)(-) and H(2)O(2) ROS production in the respiratory tract.

Spontaneous remission of edema and regranulation of goblet cells in rat tracheae after capsaicin-induced acute inflammation

Previous studies have investigated the short-term effect of capsaicin on edema formation and goblet-cell secretion in the trachea. The present study sought to investigate the long-term effect of a high dose of capsaicin (90 micro g/ml/kg), administered intravenously, on changes in the formation of endothelial gaps among venular endothelial cells, mucosal tissue edema and the secretory activity of goblet cells, including the number and size of goblet cells, and the mucus score and secretory ratio of goblet-cell mucus secretion in the trachea of rats. The tracheal whole mounts with silver staining, those stained with chloroacetate esterase reagent and Alcian blue and tracheal tissue sections stained with Alcian blue and periodic acid-Schiff reagent were used for evaluation. Formation of endothelial gaps occurred a few min after administration of capsaicin, and gaps almost closed within 12 min after capsaicin injection. Five min after capsaicin, the leaky blood vessels were numerous and the subepithelial edema ratio (% of length of edema along the inner circumference of tracheal cross section) was found to be 57.8+/-3.0% ( n=6). The number of Alcian blue-positive goblet cells (1,090+/-220 per mm(2) of mucosal surface) was reduced to half the number of goblet cells in the vehicle-treated rats (2,200+/-230). The mucus score of goblet cell secretion was not changed. The secretory ratio was greatly increased. One day after capsaicin, the edema ratio remained large and the number of Alcian blue-positive goblet cells was also small. The mucus score was also not changed. The secretory ratio was still large. On day 3, the edema ratio remained large, but the number of Alcian blue-positive goblet cells was increased to the level of the controls. The mucus score and secretory ratio returned to the control level. On day 5, the edema ratio was greatly decreased, but it was still significantly larger than that of the controls. The mucus score and secretory ratio remained at the baseline level. Seven days after capsaicin, the edema ratio was similar to the controls. The number of goblet cells was even larger than controls. It is concluded that capsaicin-induced acute inflammation in the rat trachea involves formation of endothelial gaps, extensive plasma extravasation and edema formation, and depletion of goblet-cell secretory granules. Spontaneous gradual remission of edema was accompanied by regranulation of goblet cells with gradual mucogenesis for several days.

Local capsaicin application to the stellate ganglion and stellatectomy attenuate neurogenic inflammation in rat bronchi

The present study investigated the contributions of vagal and nonvagal sensory nerve fibers on neurogenic inflammation in rat bronchial airways. A surgical procedure was developed via the rat mediastinum ventral intercostal space to prepare an intercostal opening without causing pneumothorax for performing stellate ganglionectomy alone, thoracic vagus nerve section alone, and stellatectomy plus thoracic vagotomy, and for injecting capsaicin (2 microl, 10 mg/ml) and 6-hydroxydopamine (2 microl, 50 mg/ml) into the ganglion. One week later in our procedure, we investigated if neurogenic inflammation induced by an intravenous injection of capsaicin (300 nmol/ml/kg) and innervation density of substance P-immunoreactive sensory axons could be decreased after chronic denervation in the rat lower airways. The major findings were that surgical removal of the right stellate ganglion and local capsaicin application resulted in a significant attenuation of neurogenic plasma extravasation in the right bronchial tree evoked by systemic capsaicin application. Reduction of neurogenic plasma extravasation was totally abolished by combined stellatectomy and thoracic vagotomy. The number of substance P-containing axons was also greatly decreased following these surgical and capsaicin treatments. It is concluded that sensory nerve fibers from both vagal source and nonvagal (spinal) source, which associated with the stellate ganglion, contributed significantly to neurogenic inflammation in the bronchial airways with a slightly higher contribution from the vagus nerve.

Neurophysiological effects of recurrent laryngeal and thoracic vagus nerves on mediating the neurogenic inflammation of the trachea, bronchi, and esophagus of rats

The present study aims to investigate the neurophysiological effects of recurrent laryngeal nerve and thoracic vagus nerve on the non-cholinergic regulation of neurogenic plasma extravasation of the rat trachea, bronchi, and esophagus. Through thoracotomy, three nerve components, the right thoracic vagal trunk, thoracic vagus nerve, and recurrent laryngeal nerve, were identified. The experiment was sequentially conducted in four steps. First, the individual nerve component was electrically stimulated and the induced inflammatory responses, as quantified by the area density of India ink-labelled blood vessels in the trachea, bronchial trees and esophagus, were compared. Second, we assessed the relative importance of medial and lateral side of the right thoracic vagus nerve in inducing the inflammatory responses by alternative stimulation of one side with simultaneous severance of the other side of this nerve. Third, we examined the effects of transection of the lateral half of the right thoracic vagus nerve on the degeneration of axon fibers located at the following three sites: the nerve segment proximal to cutting site, bronchial and esophageal nerve branches. Finally, we directly observed the inflammatory histopathology of the right lower trachea after stimulation of the medial half of the right thoracic vagus nerve with transection of its lateral half. In this study, we found that the right recurrent laryngeal nerve was predominant in mediating the neurogenic inflammatory responses of upper and dorsal portions of trachea, whereas the right thoracic vagus nerve was predominant in mediating those of the right lower ventral wall of trachea, right main bronchus, and right lobar bronchial trees. The axon fibers of the right thoracic vagus nerve responsible for mediating the neurogenic inflammatory responses of the right lower ventral trachea were mainly accumulated in the medial half, whereas those innervating the right main bronchus, right lobar bronchial trees, and lower esophagus were largely in the lateral half of this nerve. Transection of the lateral half of the right thoracic vagus nerve resulted in significant degeneration of myelinated fibers in its bronchial and esophageal nerve branches. Histopathological examination of the right lower trachea after electrical stimulation of the medial half of thoracic vagus nerve demonstrated the silver-stained leaky venules with accumulations of inflammatory cells. We thus concluded that afferent C-fibers to upper and dorsal portions of trachea were mainly from recurrent laryngeal nerve. In contrast, the neurogenic inflammatory responses of the right lower trachea were predominantly mediated by the medial half of the right thoracic vagus nerve, and those of the right main bronchus, bronchial trees and lower esophagus were largely by the lateral half of this nerve.