Substance P relaxes rat bronchial smooth muscle via epithelial prostanoid synthesis

Regulation of smooth muscle contractility by the epithelium in rat tracheas: role of prostaglandin E2 induced by the neurotransmitter acetylcholine

Background

Previous studies have suggested the involvement of epithelium in modulating the contractility of neighboring smooth muscle cells. However, the mechanism underlying epithelium-derived relaxation in airways remains largely unclear. This study aimed to investigate the mechanism underlying epithelium-dependent smooth muscle relaxation mediated by neurotransmitters.

Methods

The contractile tension of Sprague-Dawley (SD) rat tracheal rings were measured using a mechanical recording system. Intracellular Ca²⁺ level was measured using a Ca²⁺ fluorescent probe Fluo-3 AM, and the fluorescence signal was recorded by a laser scanning confocal imaging system. The prostaglandin E₂ (PGE₂) content was measured using an enzyme-linked immunosorbent assay kit.

Results

We observed that the neurotransmitter acetylcholine (ACh) restrained the electric field stimulation (EFS)-induced contraction in the intact but not epithelium-denuded rat tracheal rings. After inhibiting the muscarinic ACh receptor (mAChR) or cyclooxygenase (COX), a critical enzyme in prostaglandin synthesis, the relaxant effect of ACh was attenuated. Exogenous PGE₂ showed a similar inhibitory effect on the EFS-evoked contraction of tracheal rings. Moreover, ACh triggered phospholipase C (PLC)-coupled Ca²⁺ release from intracellular Ca²⁺ stores and stimulated COX-dependent PGE₂ production in primary cultured rat tracheal epithelial cells.

Conclusions

Collectively, this study demonstrated that ACh induced rat tracheal smooth muscle relaxation by promoting PGE₂ release from tracheal epithelium, which might provide valuable insights into the cross-talk among neurons, epithelial cells and neighboring smooth muscle cells in airways.

Distribution of Substance P Receptor (Neurokinin-1 Receptor) in Normal Ovine Lung and During the Progression of Bronchopneumonia in Sheep

Substance P contributes to the physiological homeostasis of pulmonary airways and vasculature. During pneumonia, alterations in substance P production and receptor expression can influence bronchoconstriction and vascular perfusion. The distribution of substance P receptor [neurokinin-1 receptor (NK-1R)] in lungs of normal sheep and sheep with acute (1 day), subacute (15 days), and chronic (45 days) bronchopneumonia caused by Mannheimia haemolytica was determined by immunohistochemistry (IHC). Three rabbit polyclonal antibodies generated to the same cytosolic C-terminal portion of NK-1R (residues 393-407) were tested. NK-1R immunoreactivity was traced in digital images and quantified with IPLAB software. There were no significant differences in NK-1R protein density between normal and infected lambs. Antibody 1 had the broadest distribution and intensity, and stained alveolar septae, smooth muscle cells of airways and vessels, epithelial cells of airways and alveoli, and submucosal glands. When all animals from the study were included, there was a trend towards decreased NK-1R immunoreactivity over time. The work suggests that (a) the density of NK-1R does not change during progression of bacterial ( M. haemolytica) bronchopneumonia, (b) NK-1R is widely distributed in ovine lung and decreases with age, and (c) antibodies to the same NK-1R cytosolic region can vary in specificity and affinity.

Influenza A infection attenuates relaxation responses of mouse tracheal smooth muscle evoked by acrolein

The airway epithelium is an important source of relaxant mediators, and damage to the epithelium caused by respiratory tract viruses may contribute to airway hyperreactivity. The aim of this study was to determine whether influenza A-induced epithelial damage would modulate relaxation responses evoked by acrolein, a toxic and prevalent component of smoke. Male BALB/c mice were inoculated intranasally with influenza A/PR-8/34 (VIRUS-infected) or allantoic fluid (SHAM-infected). On day 4 post-inoculation, isometric tension recording studies were conducted on carbachol pre-contracted tracheal segments isolated from VIRUS and SHAM mice. Relaxant responses to acrolein (30 μM) were markedly smaller in VIRUS segments compared to SHAM segments (2 ± 1% relaxation vs. 28 ± 5%, n=14, p<0.01). Similarly, relaxation responses of VIRUS segments to the neuropeptide substance P (SP) were greatly attenuated (1 ± 1% vs. 47 ± 6% evoked by 1 nM SP, n=14, p<0.001). Consistent with epithelial damage, PGE2 release in response to both acrolein and SP were reduced in VIRUS segments (>35% reduction, n=6, p<0.01), as determined using ELISA. In contrast, exogenous PGE2 was 2.8-fold more potent in VIRUS relative to SHAM segments (-log EC50 7.82 ± 0.14 vs. 7.38 ± 0.05, n=7, p<0.01) whilst responses of VIRUS segments to the β-adrenoceptor agonist isoprenaline were similar to SHAM segments. In conclusion, relaxation responses evoked by acrolein were profoundly diminished in tracheal segments isolated from influenza A-infected mice. The mechanism through which influenza A infection attenuates this response appears to involve reduced production of PGE2 in response to SP due to epithelial cell loss, and may provide insight into the airway hyperreactivity observed with influenza A infection.

Prostaglandin involvement in lung C-fiber activation by substance P in guinea pigs

Airway hyperresponsiveness is a cardinal feature of asthma. Lung C-fiber activation induces central and local defense reflexes that may contribute to airway hyperresponsiveness. Initial studies show that substance P (SP) activates C fibers even though it is produced and released by these same C fibers. SP may induce release of other endogenous mediators. Bradykinin (BK) is an endogenous mediator that activates C fibers. The hypothesis was tested that SP activates C fibers via BK release. Guinea pigs were anesthetized, and C-fiber activity (FA), pulmonary insufflation pressure (PIP), heart rate, and arterial blood pressure were monitored before and after intravenous injection of capsaicin (Cap), SP, and BK. Identical agonist challenges were repeated after infusion of an antagonist cocktail of des-Arg9-[Leu8]-BK (10(-3) M, B1 antagonist), and HOE-140 (10(-4) M, B2 antagonist). After antagonist administration, BK increased neither PIP nor FA. Increases in neither PIP nor FA were attenuated after Cap or SP challenge. In a second series of experiments, Cap and SP were injected before and after infusion of indomethacin (1 mg/kg iv) to determine whether either agent activates C fibers through release of arachidonic acid metabolites. Indomethacin administration decreased the effect of SP challenge on FA but not PIP. The effect of Cap on FA or PIP was not altered by indomethacin. In subsequent experiments, C fibers were activated by prostaglandin E2 and F2alpha. Therefore, exogenously applied SP stimulates an indomethacin-sensitive pathway leading to C-fiber activation.

Targeting tachykinins for the treatment of obstructive airways disease

The tachykinin family of peptides are distributed throughout the nervous system and are thought to play a critical role in inflammation and immunomodulation. Tachykinins have been implicated in the pathogenesis of many diseases and disease processes including inflammatory pain, emesis, depression, Parkinson's disease and inflammatory bowel syndrome. In the airways of animals, substance P and neurokinin A are released from a subset of airway sensory nerves, and evoke vasodilatation, bronchoconstriction, mucus secretion, leukocyte recruitment, airways hyperreactivity and cough. These observations have led to suggestions that tachykinins may also be viable targets for the treatment of obstructive airways disease. Clinical trials in humans assessing the utility of tachykinin receptor antagonists such as nepadutant and saredutant for the treatment of asthma are limited, and the results for the most part have been inconclusive. Several new tachykinin receptor antagonists have been recently designed to target multiple tachykinin receptor subtypes and to readily penetrate into the central nervous system. Future clinical trials with these compounds should help to shed some light on the role of tachykinins in obstructive airways disease.