Noverr Mairi C, Noggle Rachael M, Toews Galen B, Huffnagle Gary B
Division of Pulmonary and Critical Care Medicine, Department of Internal Medicine, University of Michigan Medical School, Ann Arbor, MI 48109-0642, USA.
Infect Immun. 2004 Sep;72(9):4996-5003. doi: 10.1128/IAI.72.9.4996-5003.2004.
Over the past four decades, there has been a significant increase in allergy and asthma in westernized countries, which correlates with alterations in fecal microbiota (microflora) and widespread use of antibiotics (the "hygiene hypothesis"). Antibiotics also lead to overgrowth of the yeast Candida albicans, which can secrete potent prostaglandin-like immune response modulators. We have developed a mouse model of antibiotic-induced microbiota disruption that includes stable increases in gastrointestinal (GI) enteric bacteria and GI Candida levels with no introduction of microbes into the lungs. Mice are treated for 5 days with cefoperazone in the drinking water, followed by a single oral gavage of C. albicans. This results in alterations of GI bacterial populations and increased yeast numbers in the GI microbiota for at least 2 to 3 weeks and can drive the development of a CD4 T-cell-mediated allergic airway response to subsequent mold spore (Aspergillus fumigatus) exposure in immunocompetent mice without previous systemic antigen priming. The allergic response in the lungs is characterized by increased levels of eosinophils, mast cells, interleukin-5 (IL-5), IL-13, gamma interferon, immunoglobulin E, and mucus-secreting cells. In the absence of antibiotics, mice exposed to Aspergillus spores do not develop an allergic response in the airways. This study provides the first experimental evidence to support a role for antibiotics and fungal microbiota in promoting the development of allergic airway disease. In addition, these studies also highlight the concept that events in distal mucosal sites such as the GI tract can play an important role in regulating immune responses in the lungs.
在过去的四十年里,西方国家的过敏和哮喘显著增加,这与粪便微生物群(微生物区系)的改变以及抗生素的广泛使用有关(“卫生假说”)。抗生素还会导致白色念珠菌过度生长,这种真菌能分泌强效的前列腺素样免疫反应调节剂。我们建立了一种抗生素诱导的微生物群破坏小鼠模型,该模型在不向肺部引入微生物的情况下,胃肠道(GI)肠道细菌和GI念珠菌水平持续稳定增加。给小鼠饮用含头孢哌酮的水5天,随后单次口服白色念珠菌。这导致GI细菌种群发生改变,GI微生物群中的酵母数量增加,且至少持续2至3周,并能促使免疫功能正常且未经过全身抗原致敏的小鼠在随后接触霉菌孢子(烟曲霉)时发生CD4 T细胞介导的过敏性气道反应。肺部的过敏反应表现为嗜酸性粒细胞、肥大细胞、白细胞介素-5(IL-5)、IL-13、γ干扰素、免疫球蛋白E和黏液分泌细胞水平升高。在不使用抗生素的情况下,接触烟曲霉孢子的小鼠不会在气道中发生过敏反应。这项研究提供了首个实验证据,支持抗生素和真菌微生物群在促进过敏性气道疾病发展中所起的作用。此外,这些研究还突出了这样一个概念,即胃肠道等远端黏膜部位的事件在调节肺部免疫反应中可发挥重要作用。