一种测量镇静大鼠气道反应性的非侵入式新方法

将腹腔注射地西泮而镇静的ＳＤ大鼠,置于体积描记器,测定其自主呼吸变化。吸入氯化乙酰甲胆碱和氯化乙酰胆碱气雾对呼吸幅度无明显影响,可深度依赖性地增加呼吸频率,且两药的作用强度相似,但ＭＣｈ作用维持１１ｍｉｎ,Ａｃｈ仅维持３ｍｉｎ。乌拉坦麻醉可抑制呼吸和对ＭＣｈ的反应;硫酸阿托品,硫酸沙丁胺醇和氨茶碱抑制ＭＣｈ引起的频率增快;吸入抗原气雾后６ｈ能增强致敏大鼠对ＭＣｈ的敏感性。     

气道高反应动物模型的建立与指标检测

目的 通过重新评价卵蛋白致小鼠哮喘模型,寻找一种简便易行的气道高反应动物模型和相应的检测指标,为研发治疗本类疾病药物和研究气道高反应发病机制提供新的实验手段.方法 小鼠采用卵白蛋白（OVA）致敏;致敏后（15～21）d给予10% OVA雾化吸入激发哮喘,在末次激发24 h内测量小鼠辣椒素引咳的半数有效浓度,处死小鼠取肺组织测定匀浆中NO、IL-13、ET-1的含量.结果 卵蛋白致敏模型小鼠随辣椒素浓度的升高其咳嗽反应阳性率、咳嗽次数明显增加（与对照组相比较P〈0.01）.模型组辣椒素引咳的半数有效浓度为89.39 μmol/L,对照组、地塞米松组分别为204.84、220.02 μmol/L;小鼠肺匀浆NO、ET-1、IL-13含量均明显增加,地塞米松可明显抑制NO的升高（与对照组相比较P〈0.01）.结论小鼠经卵蛋白致敏并连续激发7 d与临床气道高反应性（AHR）的多种特征相似,操作简便易行,稳定性高,故可作为气道高反应性的模型.辣椒素引咳阈值的测定、动物肺组织中NO、IL-13、ET-1含量的变化,可作为评价模型严重程度的指标.     

Inflammatory and mechanical factors of allergen-induced bronchoconstriction in mild asthma and rhinitis.

We studied whether different bronchial responses to allergen in asthma and rhinitis are associated with different bronchial inflammation and remodeling or airway mechanics. Nine subjects with mild asthma and eight with rhinitis alone underwent methacholine and allergen inhalation challenges. The latter was preceded and followed by bronchoalveolar lavage and bronchial biopsy. The response to methacholine was positive in all asthmatic but in only two rhinitic subjects. The response to allergen was positive in all asthmatic and most, i.e., five, rhinitic subjects. No significant differences between groups were found in airway inflammatory cells or basement membrane thickness either at baseline or after allergen. The ability of deep inhalation to dilate methacholine-constricted airways was greater in rhinitis than in asthma, but it was progressively reduced in rhinitis during allergen challenge. We conclude that 1) rhinitic subjects may develop similar airway inflammation and remodeling as the asthmatic subjects do and 2) the difference in bronchial response to allergen between asthma and rhinitis is associated with different airway mechanics.     

Effects of airway inflammation on cough response in the guinea pig

We have developed a guinea pig model for coughrelated to allergic airway inflammation. Unanesthetized animals wereexposed to capsaicin aerosols for 10 min, and cough frequency wascounted during this period. The cough evaluation was performed by the following three methods: visual observation, acoustic analysis, andmonitoring of pressure changes in the body chamber. These analysesclearly differentiated a cough from a sneeze. To elucidate therelationship between cough response and airway inflammation, animalswere immunosensitized and multiple challenged. Sensitized guinea pigspresented no specific changes microscopically, but multiple-challengedanimals showed an increased infiltration of inflammatory cells into theairway. Cough number in response to capsaicin increased significantlyfrom 4.7 ± 1.4 coughs/10 min in normal animals to 10.6 ± 2.0 coughs/10 min in sensitized animals and further to 22.8 ± 1.3 coughs/10 min in multiple-challenged animals. This augmentedcough frequency was significantly inhibited by the inhalation oftachykinin-receptor antagonists and by oral ingestion, but notinhalation, of codeine phosphate. The results suggest that airwayinflammation potentiates an elevation of cough sensitivity in this model.

     

Airway nitric oxide release is reduced after PBS inhalation in asthma.

Exhaled nitric oxide (NO) is elevated in asthma, but the underlying mechanisms remain poorly understood. Recent results in subjects with asthma have reported a decrease in exhaled breath pH and ammonia, as well as altered expression and activity of glutaminase in both alveolar and airway epithelial cells. This suggests that pH-dependent nitrite conversion to NO may be a source of exhaled NO in the asthmatic airway epithelium. However, the anatomic location (i.e., airway or alveolar region) of this pH-dependent NO release has not been investigated and could impact potential therapeutic strategies. We quantified airway (proximal) and alveolar (peripheral) contributions to exhaled NO at baseline and then after PBS inhalation in stable (mild-intermittent to severe) asthmatic subjects (20-44 yr old; n = 9) and healthy controls (22-41 yr old; n = 6). The mean (SD) maximum airway wall flux (pl/s) and alveolar concentration (ppb) at baseline in asthma subjects and healthy controls was 2,530 (2,572) and 5.42 (7.31) and 1,703 (1,567) and 1.88 (1.29), respectively. Compared with baseline, there is a significant decrease in the airway wall flux of NO in asthma as early as 15 min and continuing for up to 60 min (maximum -28% at 45 min) after PBS inhalation without alteration of alveolar concentration. Healthy control subjects did not display any changes in exhaled NO. We conclude that elevated airway NO at baseline in asthma is reduced by inhaled PBS. Thus airway NO may be, in part, due to nitrite conversion to NO and is consistent with airway pH dysregulation in asthma.     

Lysophosphatidic acid enhances contractility of isolated airway smooth muscle

Toews, M. L., E. E. Ustinova, and H. D. Schultz.Lysophosphatidic acid enhances contractility of isolated airwaysmooth muscle. J. Appl. Physiol.83(4): 1216-1222, 1997.The effects of the simple phospholipidmediator lysophosphatidic acid (LPA) on the contractile responsivenessof isolated tracheal rings from rabbits and cats were assessed. In bothspecies, LPA increased the contractile response to the muscarinicagonist methacholine, but LPA did not induce contraction on its own.Conversely, LPA decreased the relaxation response to the-adrenergic-agonist isoproterenol in both species. Concentrations ofLPA as low as 10⁸ M wereeffective, and the effects of LPA were rapidly reversed on washing.Phosphatidic acid was much less effective, requiring higherconcentrations and producing only a minimal effect. Contractions induced by serotonin and by substance P also were enhanced by LPA, butKCl-induced contractions were unaffected. LPA inhibited theisoproterenol-induced relaxation of KCl-precontracted rings, similar toits effects on methacholine-precontracted rings, and relaxation inducedby the direct adenylyl cyclase activator forskolin was inhibited in amanner similar to that induced by isoproterenol. Epithelium removal didnot alter the contraction-enhancing effect of LPA. The ability of LPAto both enhance contraction and inhibit relaxation of airway smoothmuscle suggests that LPA could contribute to airway hypercontractilityin asthma, airway inflammation, or other types of lung injury.

     

Lovastatin inhibits bronchial hyperresponsiveness by reducing RhoA signaling in rat allergic asthma

Recent studies revealed an importance of a monomeric GTP-binding protein, RhoA, in contraction of bronchial smooth muscle (BSM). RhoA and its downstream have been proposed as a new target for the treatment of airway hyperresponsiveness in asthma. Statins are known to inhibit the functional activation of RhoA via the depletion of geranylgeranylpyrophosphate. To determine the beneficial effects of statins on the airway hyperresponsiveness in allergic bronchial asthma, we investigated the effects of systemic treatment with lovastatin on the augmented BSM contraction and activation of RhoA in rats with allergic bronchial asthma. Rats were sensitized and repeatedly challenged with 2,4-dinitrophenylated Ascaris suum antigen. Animals were also treated with lovastatin (4 mg kg(-1) day(-1) ip) once a day before and during the antigen inhalation period. Repeated antigen inhalation caused a marked BSM hyperresponsiveness to ACh with the increased expression and translocation of RhoA. Lovastatin treatments significantly attenuated both the augmented contraction and RhoA translocation to the plasma membrane. Lovastatin also reduced the increased cell number in bronchoalveolar lavage fluids and histological changes induced by antigen exposure, whereas the levels of immunoglobulin E in sera and interleukins-4, -6, and -13 in bronchoalveolar lavage fluids were not significantly changed. These findings suggest that lovastatin ameliorates antigen-induced BSM hyperresponsiveness, an important factor of airway hyperresponsiveness in allergic asthmatics, probably by reducing the RhoA-mediated signaling.     

The roles of autotaxin/lysophosphatidic acid in immune regulation and asthma

Lysophosphatidic acid (LPA) species are present in almost all organ systems and play diverse roles through its receptors. Asthma is an airway disease characterized by chronic allergic inflammation where various innate and adaptive immune cells participate in establishing Th2 immune response. Here, we will review the contribution of LPA and its receptors to the functions of immune cells that play a key role in establishing allergic airway inflammation and aggravation of allergic asthma.     

Airway contractility and smooth muscle Ca(2+) signaling in lung slices from different mouse strains.

To investigate the hypothesis that altered Ca2+ signaling in airway smooth muscle cells (SMCs) is responsible for airway hyperreactivity, we compared, with the use of confocal and phase-contrast microscopy, the airway contractility and Ca2+ changes in SMCs induced by acetylcholine (ACh) in lung slices from different mouse strains (A/J, Balb/C, and C3H/ HeJ). The airways from each mouse strain displayed a concentration-dependent contraction to ACh. The contractile response of the airways of the C3H/HeJ mice was found, in contrast to earlier studies, to be much greater and faster than that of A/J and Balb/C mice. This difference in airway reactivity can be, in part, attributable to halothane, a volatile anesthetic that was previously used during in vivo measurements of airway reactivity but found here to significantly alter the ACh contractile response of airways in lung slices. The ACh-induced Ca2+ response of the airway SMCs in all of the various mouse strains was also concentration dependent. The magnitude of the initial Ca2+ increase and the frequency of the subsequent Ca2+ oscillations induced by ACh increased with ACh concentration. However, no differences in the Ca2+ responses to ACh could be distinguished between the mouse strains. These results suggest that the mechanism responsible for airway hyperreactivity in different mouse strains resides with the Ca2+ sensitivity of the contractile apparatus of the SMCs rather than with the Ca2+ signaling itself.     

Involvement of thromboxane A(2) in airway mucous cells in asthma-related cough.

The aim of this study was to elucidate the role of thromboxane A(2) (TxA(2)) on asthma-related cough in guinea pigs. Animals were immunosensitized and repeatedly challenged with ovalbumin as an antigen. Coughs were induced by the inhalation of 10(-5) M capsaicin solution for 10 min. Thromboxane synthetase (TxS) inhibitor OKY-046 and thromboxane-receptor antagonist AA-2414 significantly inhibited cough responses in repeatedly challenged animals. Inhalation of TxA(2) mimic STA-2- potentiated cough responses in normal and immunosensitized animals but not in repeatedly challenged ones. Moreover, STA-2-potentiated coughs were inhibited by administration of neurokinin-receptor antagonist FK-224. In repeatedly challenged animals, concentration of TxB(2) in airway lavage fluid, expression of TxS mRNA in tracheal epithelia, and the immunostaining intensity against TxS in mucous cells of the epithelium significantly increased compared with normal and sensitized animals. These results suggest that TxA(2) derived from mucous cells potentiated cough responses to capsaicin in allergic airway inflammation.     

The mechanism of ciliary stimulation by acetylcholine: roles of calcium, PKA, and PKG

Stimulation of ciliary cells through muscarinic receptors leads to a strong biphasic enhancement of ciliary beat frequency (CBF). The main goal of this work is to delineate the chain of molecular events that lead to the enhancement of CBF induced by acetylcholine (ACh). Here we show that the Ca(2+), cGMP, and cAMP signaling pathways are intimately interconnected in the process of cholinergic ciliary stimulation. ACh induces profound time-dependent increase in cGMP and cAMP concentrations mediated by the calcium-calmodulin complex. The initial strong CBF enhancement in response to ACh is mainly governed by PKG and elevated calcium. The second phase of CBF enhancement induced by ACh, a stable moderately elevated CBF, is mainly regulated by PKA in a Ca(2+)-independent manner. Inhibition of either guanylate cyclase or of PKG partially attenuates the response to ACh of [Ca(2+)](i), but completely abolishes the response of CBF. Inhibition of PKA moderately attenuates and significantly shortens the responses to ACh of both [Ca(2+)](i) and CBF. In addition, PKA facilitates the elevation in [Ca(2+)](i) and cGMP levels induced by ACh, whereas an unimpeded PKG activity is essential for CBF enhancement mediated by either Ca(2+) or PKA.     

Role of macrophages in virus-induced airway hyperresponsiveness and neuronal M2 muscarinic receptor dysfunction

Viral infections exacerbate asthma. One of the pathways by which viruses trigger bronchoconstriction and hyperresponsiveness is by causing dysfunction of inhibitory M(2) muscarinic receptors on the airway parasympathetic nerves. These receptors normally limit acetylcholine (ACh) release from the parasympathetic nerves. Loss of M(2) receptor function increases ACh release, thereby increasing vagally mediated bronchoconstriction. Because viral infection causes an influx of macrophages into the lungs, we tested the role of macrophages in virus-induced airway hyperresponsiveness and M(2) receptor dysfunction. Guinea pigs infected with parainfluenza virus were hyperresponsive to electrical stimulation of the vagus nerves but not to intravenous ACh, indicating that hyperresponsiveness was due to increased release of ACh from the nerves. In addition, the muscarinic agonist pilocarpine no longer inhibited vagally induced bronchoconstriction, indicating M(2) receptor dysfunction. Treating animals with liposome-encapsulated dichloromethylene-diphosphonate depleted macrophages as assessed histologically. In these animals, viral infection did not cause airway hyperresponsiveness or M(2) receptor dysfunction. These data suggest that macrophages mediate virus-induced M(2) receptor dysfunction and airway hyperresponsiveness.     

Nitrogen dioxide enhances allergic airway inflammation and hyperresponsiveness in the mouse

In addition to being an air pollutant, NO2 is a potent inflammatory oxidant generated endogenously by myeloperoxidase and eosinophil peroxidase. In these studies, we sought to determine the effects of NO2 exposure on mice with ongoing allergic airway disease pathology. Mice were sensitized and challenged with the antigen ovalbumin (OVA) to generate airway inflammation and subsequently exposed to 5 or 25 ppm NO2 for 3 days or 5 days followed by a 20-day recovery period. Whereas 5 ppm NO2 elicited no pathological changes, inhalation of 25 ppm NO2 alone induced acute lung injury, which peaked after 3 days and was characterized by increases in protein, LDH, and neutrophils recovered by BAL, as well as lesions within terminal bronchioles. Importantly, 25 ppm NO2 was also sufficient to cause AHR in mice, a cardinal feature of asthma. The inflammatory changes were ameliorated after 5 days of inhalation and completely resolved after 20 days of recovery after the 5-day inhalation. In contrast, in mice immunized and challenged with OVA, inhalation of 25 ppm NO2 caused a marked augmentation of eosinophilic inflammation and terminal bronchiolar lesions, which extended significantly into the alveoli. Moreover, 20 days postcessation of the 5-day 25 ppm NO2 inhalation regimen, eosinophilic and neutrophilic inflammation, pulmonary lesions, and AHR were still present in mice immunized and challenged with OVA. Collectively, these observations suggest an important role for NO2 in airway pathologies associated with asthma, both in modulation of degree and duration of inflammatory response, as well as in induction of AHR.     

Muscarinic receptors involved in airway vascular leakage induced by experimental gastro-oesophageal reflux

Gastro-oesophageal acid reflux may cause airway responses such as cough, bronchoconstriction and inflammation in asthmatic patients. Studies in humans or in animals have suggested that these responses involve cholinergic nerves. The purpose of this study was to investigate the role of the efferent vagal component on airway microvascular leakage induced by instillation of hydrochloric acid (HCl) into the oesophagus of guinea-pigs and the subtype of muscarinic receptors involved. Airway microvascular leakage induced by intra-oesophageal HCl instillation was abolished by bilateral vagotomy or by the nicotinic receptor antagonist, hexamethonium. HCl-induced leakage was inhibited by pretreatment with atropine, a non-specific muscarinic receptor antagonist, and also by pretreatment with either pirenzepine, a muscarinic M(1) receptor antagonist, or 4-DAMP, a muscarinic M(3) receptor antagonist. Pirenzepine was more potent than atropine and 4-DAMP. These antagonists were also studied on airway microvascular leakage or bronchoconstriction induced by intravenous administration of acetylcholine (ACh). Atropine, pirenzepine and 4-DAMP inhibited ACh-induced airway microvascular leakage with similar potencies. In sharp contrast, 4-DAMP and atropine were more potent inhibitors of ACh-induced bronchoconstriction than pirenzepine. Methoctramine, a muscarinic M(2) receptor antagonist, was ineffective in all experimental conditions. These results suggest that airway microvascular leakage caused by HCl intra-oesophageal instillation involves ACh release from vagus nerve terminals and that M(1) and M(3) receptors play a major role in cholinergic-mediated microvascular leakage, whereas M(3) receptors are mainly involved in ACh-induced bronchoconstriction.     

咳嗽变异性哮喘（CVA）与小气道功能相关性分析

目的：探讨咳嗽变异性哮喘（CVA）患者小气道功能检查对其诊断,治疗的意义。方法：对254例以慢性咳嗽为主的患者行肺功能检查并行支气管激发试验,回顾性分析小气道病变及气道高反应性检查结果与咳嗽变异性哮喘（CVA）的相关性。结果：有小气道功能障碍者接受吸入乙酰甲胆碱激发试验,气道反应性明显增高。有小气道功能障碍确诊咳嗽变异性哮喘（CVA）组起始阻力、反应阈值及阻力上升度与非哮喘组相比差异有统计学意义（P〈0.01）。结论：检查小气道功能障碍有助于哮喘的诊断,治疗及预后随访。     

Down-regulation of the non-neuronal acetylcholine synthesis and release machinery in acute allergic airway inflammation of rat and mouse

Acetylcholine (ACh), derived both from nerve fibres and from non-neuronal sources such as epithelial cells, is a major regulator of airway function. There is evidence that dysfunction of the neuronal cholinergic system is involved in the pathogenesis of asthma. Here, we asked whether the pulmonary non-neuronal ACh-synthesis and release machinery is altered in a rat and a mouse model of allergic airway disease. Animals were sensitized against ovalbumin, challenged by allergen inhalation, and sacrificed 24 or 48 h later. Targets of investigation were the high-affinity choline transporter-1 (CHT1), that mediates cellular uptake of choline, the ACh-synthesizing enzyme choline acetyltransferase (ChAT), the vesicular ACh transporter (VAChT), and the polyspecific organic cation transporters (OCT1-3), which are able to translocate choline and ACh across the plasma membrane. With cell-type specific distribution patterns, immunohistochemistry identified these proteins in airway epithelial cells and alveolar macrophages. Real-time RT-PCR revealed significant decreases in ChAT-, CHT1-, VAChT-, OCT-mRNA in the lung of sensitized and allergen challenged animals. These data were supported by immunohistochemistry, demonstrating reduced labeling intensity of airway epithelial cells. ChAT-, CHT1-, VAChT-, and OCT1-mRNA were also significantly reduced in cells recovered by bronchoalveolar lavage from sensitized and challenged rats. In conclusion, the pulmonary non-neuronal cholinergic system is down-regulated in acute allergic airway inflammation. In view of the role of ACh in maintenance of cell-cell-contacts, stimulation of fluid-secretion and of ciliary beat frequency, this down-regulation may contribute to epithelial shedding and ciliated cell dysfunction that occur in this pathological condition.     

Handgrip-induced airway dilation in asthmatic patients with bronchoconstriction induced by MCh inhalation.

We investigated the effects of static and rhythmic handgrip on the time course of recovery of airway resistance measured with the interrupter technique (Rint) following bronchoconstriction induced by methacholine (MCh) inhalation in 17 asthmatic patients. On three separate occasions, a 100 +/- 5% increase in baseline Rint was induced by MCh inhalation. Subsequently, patients either rested [control trials (CTs)] or performed 3-min bouts of static or rhythmic handgrip. Respiratory and cardiovascular variables were continuously monitored. Rint changes were assessed at 1-min intervals for 30 min after rest and both types of handgrip. Plasma catecholamine concentrations were also determined at scheduled intervals. Bronchoconstriction increased ventilation (P < 0.01) but did not affect cardiovascular variables and plasma catecholamine concentrations. Handgrip provoked an increase in cardiovascular variables (P < 0.01) and plasma norepinephrine concentrations (P < 0.05) but caused no additional changes in ventilation. Rint only partially recovered within 30 min after CTs, whereas it consistently decreased 1 min after both handgrip paradigms and remained lower than after CTs (P always <0.01) for the whole 30-min observation period. Sympathetic activation and withdrawal of cholinergic input to the airway smooth muscle reflexly induced by activation of skeletal muscle and carotid sinus receptors may be the primary events accounting for the bronchodilator response induced by handgrip. Mediators co-released in response to sympathetic activation may also have contributed.