Liu Chong-hai, Yang Xi-qiang, Liu Chun-hua, He Yun, Wang Li-jia
Department of Immunology, Children's Hospital, Chongqing Medical University, Chongqing 400014, China.
Zhonghua Er Ke Za Zhi. 2007 Jun;45(6):450-4.
Over the past several decades, there has been a significant increase in allergy and asthma in the world, which correlates with alterations in microflora and widespread use of antibiotics. The authors have developed a mouse model of antibiotics-induced microbiota disruption. In that model, mice were challenged by intranasal exposure to Aspergillus fumigatus allergens to explore the relation of allergic airway response and intestinal microflora disruption.
Sixty female BALB/c mice were divided at random into 6 groups with 10 mice in each. (1) First antibiotic therapy group: the mice were given oral cefoperazone for 7 days, on day 7, mice were inoculated with Candida albicans (10(9)/ml, 50 microl) orally. (2) First control group: the mice were treated as first antibiotic therapy group, but cefoperazone and Candida albicans were replaced by saline. The mice in groups (1) and (2) were sacrificed on day 8, and cecal contents were collected for quantitative analysis of the intestinal bacterial flora. (3) Antibiotic therapy and challenge group: the mice were treated as the first antibiotic therapy group, then challenged (day 9 and 16) by intranasal exposure to Aspergillus fumigatus allergen. (4) Second antibiotic therapy group: the mice were treated as the first antibiotic therapy group, then challenged (day 9 and 16) by intranasal exposure to saline. (5) Challenge group: the mice were treated as the first control group, then challenged (day 9 and 16) by intranasal exposure to Aspergillus fumigatus allergen. (6) Second control group: the mice were treated as the first control group, then challenged (day 9 and 16) by intranasal exposure to saline. The mice in (3) - (6) group were killed for analysis of allergic airway response on day 19.
The quantity of Enterobacteriaceae, Enterococcus, Bifidobacterium and Lactobacillus in first antibiotic therapy group was significantly lower than that in the first control group, the quantity of Candida albicans increased in the first antibiotic therapy group as compared with the first control group. Mice intestinal microflora were disrupted with weight reduction and increased moisture in feces. After challenging with Aspergillus fumigatus allergens via intranasal inhalation, the total cell count, eosinophils, lymphocytes and neutrophils increased in BALF, especially in bronchoalveolar lavage fluid (BALF) from the mice in antibiotic therapy and challenge groups. IL-4 level in BALF from antibiotic therapy and challenge group (45.35 +/- 2.36) pg/ml was higher than that in the second control group (35.32 +/- 2.53) pg/ml. The expression of GATA-3 mRNA in the mice lung tissue (0.569 +/- 0.023) was higher than that in the second control group (0.410 +/- 0.020), and the ratios of T-bet/GATA-3 (0.578 +/- 0.021) decreased as compared with that in the second control group (0.804 +/- 0.035). IFN-gamma level in BALF from any group was not significantly different. In the absence of antibiotics, mice exposed to Aspergillus fumigatus allergen did not develop an allergic response in the airways.
The allergic (Th2) immune response can be induced by airway challenge with Aspergillus fumigatus allergen in the mice in which the intestinal microflora disruption resulted from antibiotic therapy, this result suggests that the intestinal microflora disruption resulted from antibiotic therapy is a risk factor for allergy and asthma.
在过去几十年间,全球过敏和哮喘发病率显著上升,这与微生物群的改变以及抗生素的广泛使用有关。作者建立了抗生素诱导的微生物群破坏小鼠模型。在该模型中,通过鼻内暴露于烟曲霉过敏原对小鼠进行激发,以探讨过敏性气道反应与肠道微生物群破坏之间的关系。
60只雌性BALB/c小鼠随机分为6组,每组10只。(1)首次抗生素治疗组:小鼠口服头孢哌酮7天,在第7天,小鼠口服接种白色念珠菌(10⁹/ml,50微升)。(2)首次对照组:小鼠的处理方式同首次抗生素治疗组,但用生理盐水替代头孢哌酮和白色念珠菌。第8天处死(1)和(2)组小鼠,收集盲肠内容物用于肠道菌群的定量分析。(3)抗生素治疗与激发组:小鼠的处理方式同首次抗生素治疗组,然后(第9天和第16天)通过鼻内暴露于烟曲霉过敏原进行激发。(4)第二次抗生素治疗组:小鼠的处理方式同首次抗生素治疗组,然后(第9天和第16天)通过鼻内暴露于生理盐水进行激发。(5)激发组:小鼠的处理方式同首次对照组,然后(第9天和第16天)通过鼻内暴露于烟曲霉过敏原进行激发。(6)第二次对照组:小鼠的处理方式同首次对照组,然后(第9天和第16天)通过鼻内暴露于生理盐水进行激发。第19天处死(3)至(6)组小鼠,分析过敏性气道反应。
首次抗生素治疗组中肠杆菌科、肠球菌、双歧杆菌和乳酸杆菌的数量显著低于首次对照组,首次抗生素治疗组中白色念珠菌的数量相比于首次对照组增加。小鼠肠道微生物群被破坏,体重减轻,粪便水分增加。经鼻内吸入烟曲霉过敏原激发后,支气管肺泡灌洗液(BALF)中的总细胞数、嗜酸性粒细胞、淋巴细胞和中性粒细胞增加,尤其是抗生素治疗与激发组小鼠的BALF。抗生素治疗与激发组BALF中的IL-4水平(45.35±2.36)pg/ml高于第二次对照组(35.32±2.53)pg/ml。小鼠肺组织中GATA-3 mRNA的表达(0.569±0.023)高于第二次对照组(0.410±0.020),与第二次对照组(0.804±0.035)相比,T-bet/GATA-3的比值(0.578±0.021)降低。任何组BALF中的IFN-γ水平均无显著差异。在未使用抗生素的情况下,暴露于烟曲霉过敏原的小鼠气道未发生过敏反应。
在因抗生素治疗导致肠道微生物群破坏的小鼠中,气道用烟曲霉过敏原激发可诱导过敏性(Th2)免疫反应,这一结果表明抗生素治疗导致的肠道微生物群破坏是过敏和哮喘的一个危险因素。
