Schraufstätter I U, Revak S D, Cochrane C G
J Clin Invest. 1984 Apr;73(4):1175-84. doi: 10.1172/JCI111303.
We have examined various biochemical parameters of pulmonary inflammation in experimental animals. Intrabronchial instillation of glucose oxidase-glucose (GO/G) to produce oxidants or formylated norleu-leu-phe (FNLP) or phorbol myristate acetate (PMA) as leukocytic stimuli induced severe acute pulmonary injury in New Zealand white rabbits. PMA also induced inflammation when administered intravenously. Each stimulus induced transudation of protein from the vascular space into the pulmonary tissues, and an influx of leukocytes during the 4-6 h period of the experiment. Pathophysiologic changes were measured by edema formation (transudation of 125I-bovine serum albumin), and histologic examination. Biochemical analysis was performed by measuring concentrations of potentially injurious agents in bronchoalveolar lavage (BAL) fluid. Increased acid protease and myeloperoxidase levels were found in the BAL fluid after administration of either of the stimuli. Evidence of oxidant generation in vivo was obtained in two different ways. In the first, specific activities for catalase were measured in the BAL fluid in the presence or absence of 3-amino, 1,2,4 triazole (AT), injected at intervals before obtaining BAL fluid. In the presence of AT, specific activities for catalase dropped to 0.22 after a double instillation of FNLP and to 0.15 in the presence of GO/G. In neutrophil-depleted FNLP animals, catalase was not greatly inhibited by AT (sp act 0.90). In the second, intracellular levels of total glutathione (GSH + GSSG) in whole lung tissue and alveolar macrophages decreased when stimuli of neutrophils were administered. Intrabronchially instilled PMA, e.g., caused a drop of glutathione in whole lung tissue from the control value of 2.3 mumol GSH equivalent/100 mg dry wt to 0.54 mumol GSH equivalent/100 mg dry wt at 4 h. Neutrophil depletion and superoxide dismutase protected from this effect. From these results, we conclude that O-2 or its metabolites can initiate severe pulmonary injury as shown by the effect of GO/G and that, during development of pulmonary injury, stimulated neutrophils generate oxidants and release proteolytic enzymes into the surrounding tissues.
我们检测了实验动物肺部炎症的各种生化参数。向支气管内滴注葡萄糖氧化酶-葡萄糖(GO/G)以产生氧化剂,或滴注甲酰化去甲亮氨酸-亮氨酸-苯丙氨酸(FNLP)或佛波酯(PMA)作为白细胞刺激物,可在新西兰白兔中诱发严重的急性肺损伤。静脉注射PMA也可诱发炎症。在实验的4-6小时期间,每种刺激物均诱导蛋白质从血管腔渗出到肺组织中,并使白细胞流入。通过水肿形成(125I-牛血清白蛋白的渗出)和组织学检查来测量病理生理变化。通过测量支气管肺泡灌洗(BAL)液中潜在损伤因子的浓度进行生化分析。给予任何一种刺激物后,在BAL液中均发现酸性蛋白酶和髓过氧化物酶水平升高。通过两种不同的方法获得了体内氧化剂生成的证据。第一种方法是,在获取BAL液之前,间隔注射3-氨基-1,2,4-三唑(AT),然后测量BAL液中过氧化氢酶的比活性。在存在AT的情况下,经两次滴注FNLP后,过氧化氢酶的比活性降至0.22,在存在GO/G的情况下降至0.15。在中性粒细胞减少的FNLP动物中,AT对过氧化氢酶的抑制作用不大(比活性为0.90)。第二种方法是,当给予中性粒细胞刺激物时,全肺组织和肺泡巨噬细胞中的总谷胱甘肽(GSH + GSSG)细胞内水平降低。例如,支气管内滴注PMA可使全肺组织中的谷胱甘肽在4小时时从对照值2.3 μmol GSH当量/100 mg干重降至0.5 μmol GSH当量/100 mg干重。中性粒细胞减少和超氧化物歧化酶可防止这种效应。从这些结果中,我们得出结论,如GO/G 的作用所示,O-2或其代谢产物可引发严重的肺损伤,并且在肺损伤的发展过程中,受刺激的中性粒细胞会产生氧化剂并将蛋白水解酶释放到周围组织中。
