Kauffman Henk F
Clinic for Internal Medicine, Department of Allergology, University Medical Centre Groningen, The Netherlands.
Clin Rev Allergy Immunol. 2006 Apr;30(2):129-40. doi: 10.1385/criai:30:2:129.
Aero-allergens, including plant pollens, house dust mite particles, fungal spores, and mycelium fragments, are continuously inhaled and deposited on the airway mucosa. These particles and their soluble components actively interact with innate recognition systems present in the mucosal layer (e.g., surfactant proteins) and with various receptors present on a diversity of cells in the airways. Deposited particles are first removed by active transportation, the rate of which is either enhanced or inhibited by components present in the inhaled substances. Cleaning further depends on innate recognition, beginning with (a) soluble factors released into the mucosal surface layer that bind different bio-organic components; (b) innate receptors on phagocytic cells, alveolar macrophages, and dendritic monocytes; and (c) innate receptors on airway epithelial cells. Different innate receptor families (Toll-like receptors [TLRs], nucleotide-binding oligomerization domain receptors, and protein-activated receptors [PARs]) have been demonstrated on airway cells, including alveolar macrophages, monocytes, dendritic cells, and airway tissue cells (e.g., epithelial cells and mast cells). However, although the functional role of these receptors has been studied for infectious diseases, the functional role for reaction of airways to inhaled bio-organic substances, including allergens, is largely unexplored. Indirect evidence for functional interactions has come from in vivo animal studies, as well as in vitro studies with monocytes, macrophages, and epithelial cells, which have demonstrated release of cytokines and chemokines after contact with allergens such as house dust mite, cat, pollen, and fungi. Most allergens show direct activation of airway epithelial cells, suggesting a role for the innate receptors. However, the role of TLRs, PARs, and other receptors was studied for only a limited number of allergens. Current studies indicate synergistic interactions between members of the same receptor family (TLRs) as well as synergistic interactions between members of different families (TLRs, PARs, and nucleotide-binding oligomerization domain receptors), modulating responses into feed-forward or inhibitory actions. Study of these synergistic interactions and their genetic variations will provide insight regarding how the innate immune system determines the inflammatory reactions of the airways and the outcome of the T-helper-1- and T-helper-2-type responses to inhaled allergens.
空气过敏原,包括植物花粉、屋尘螨颗粒、真菌孢子和菌丝体片段,会持续被吸入并沉积在气道黏膜上。这些颗粒及其可溶性成分会与黏膜层中存在的固有识别系统(如表面活性蛋白)以及气道中多种细胞上存在的各种受体发生积极相互作用。沉积的颗粒首先通过主动运输被清除,其速率会受到吸入物质中成分的增强或抑制。进一步的清除取决于固有识别,首先是(a)释放到黏膜表层并结合不同生物有机成分的可溶性因子;(b)吞噬细胞、肺泡巨噬细胞和树突状单核细胞上的固有受体;以及(c)气道上皮细胞上的固有受体。在气道细胞,包括肺泡巨噬细胞、单核细胞、树突状细胞和气道组织细胞(如上皮细胞和肥大细胞)上,已经证实存在不同的固有受体家族(Toll样受体[TLRs]、核苷酸结合寡聚化结构域受体和蛋白激活受体[PARs])。然而,尽管这些受体在传染病中的功能作用已得到研究,但它们在气道对吸入生物有机物质(包括过敏原)反应中的功能作用在很大程度上尚未被探索。功能相互作用的间接证据来自体内动物研究以及对单核细胞、巨噬细胞和上皮细胞的体外研究,这些研究表明在接触屋尘螨、猫、花粉和真菌等过敏原后会释放细胞因子和趋化因子。大多数过敏原显示出对气道上皮细胞的直接激活,这表明固有受体发挥了作用。然而,仅对有限数量的过敏原研究了TLRs、PARs和其他受体的作用。目前的研究表明,同一受体家族(TLRs)成员之间存在协同相互作用,不同家族(TLRs、PARs和核苷酸结合寡聚化结构域受体)成员之间也存在协同相互作用,这些相互作用将反应调节为前馈或抑制作用。对这些协同相互作用及其基因变异的研究将有助于深入了解固有免疫系统如何决定气道的炎症反应以及对吸入过敏原的辅助性T细胞1型和辅助性T细胞2型反应的结果。
