Institute of Molecular Cancer Research, University of Zurich, Zurich, Switzerland.
Department of Pathology, New York University School of Medicine, New York, New York, USA.
mBio. 2021 Feb 2;12(1):e03335-20. doi: 10.1128/mBio.03335-20.
Antibiotic exposure early in life and other practices impacting the vertical transmission and ordered assembly of a diverse and balanced gut microbiota are associated with a higher risk of immunological and metabolic disorders such as asthma and allergy, autoimmunity, obesity, and susceptibility to opportunistic infections. In this study, we used a model of perinatal exposure to the broad-spectrum antibiotic ampicillin to examine how the acquisition of a dysbiotic microbiota affects neonatal immune system development. We found that the resultant dysbiosis imprints in a manner that is irreversible after weaning, leading to specific and selective alteration of the colonic CD4 T-cell compartment. In contrast, colonic granulocyte and myeloid lineages and other mucosal T-cell compartments are unaffected. Among colonic CD4 T cells, we observed the most pronounced effects on neuropilin-negative, RORγt- and Foxp3-positive regulatory T cells, which are largely absent in antibiotic-exposed mice even as they reach adulthood. Immunomagnetically isolated dendritic cells from antibiotic-exposed mice fail to support the generation of Foxp3 regulatory T cells (Tregs) from naive T cells The perinatally acquired dysbiotic microbiota predisposes to dysregulated effector T-cell responses to or ovalbumin challenge. The transfer of the antibiotic-impacted, but not healthy, fecal microbiota into germfree recipients recapitulates the selective loss of colonic neuropilin-negative, RORγt- and Foxp3-positive Tregs. The combined data indicate that the early-life acquisition of a dysbiotic microbiota has detrimental effects on the diversity and microbial community composition of offspring that persist into adulthood and predisposes to inappropriate T-cell responses that are linked to compromised immune tolerance. The assembly of microbial communities that populate all mucosal surfaces of the human body begins right after birth. This process is prone to disruption as newborns and young infants are increasingly exposed to antibiotics, both deliberately for therapeutic purposes, and as a consequence of transmaternal exposure. We show here using a model of ampicillin administration to lactating dams during their newborn offspring's early life that such exposures have consequences that persist into adulthood. Offspring acquire their mother's antibiotic-impacted microbiota, which compromises their ability to generate a colonic pool of CD4 T cells, particularly of colonic regulatory T cells. This Treg deficiency cannot be corrected by cohousing with normal mice later and is recapitulated by reconstitution of germfree mice with microbiota harvested from antibiotic-exposed donors. As a consequence of their dysbiosis, and possibly of their Treg deficiency, antibiotic-impacted offspring generate dysregulated Th1 responses to bacterial challenge infection and develop more severe symptoms of ovalbumin-induced anaphylaxis.
生命早期接触抗生素和其他影响垂直传播和多样化、平衡肠道微生物群落有序组装的做法与免疫和代谢紊乱(如哮喘和过敏、自身免疫、肥胖和易发生机会性感染)的风险增加有关。在这项研究中,我们使用了一种围产期暴露于广谱抗生素氨苄青霉素的模型,以研究获得失调的微生物群如何影响新生儿免疫系统的发育。我们发现,这种失调在断奶后以不可逆转的方式印记,导致结肠 CD4 T 细胞区室的特异性和选择性改变。相比之下,结肠粒细胞和髓系谱系以及其他粘膜 T 细胞区室不受影响。在结肠 CD4 T 细胞中,我们观察到对神经钙黏蛋白阴性、RORγt 和 Foxp3 阳性调节性 T 细胞的影响最为显著,即使在抗生素暴露的小鼠成年后,这些细胞也基本不存在。从抗生素暴露的小鼠中免疫磁分离的树突状细胞不能支持幼稚 T 细胞向 Foxp3 调节性 T 细胞(Tregs)的生成。围产期获得的失调微生物群易导致对卵清蛋白或挑战的效应 T 细胞反应失调。将受抗生素影响但不健康的粪便微生物群转移到无菌受体中,可重现结肠神经钙黏蛋白阴性、RORγt 和 Foxp3 阳性 Tregs 的选择性丧失。综合数据表明,生命早期获得失调的微生物群会对后代的多样性和微生物群落组成产生不利影响,这种影响会持续到成年,并易导致与免疫耐受受损相关的不适当 T 细胞反应。定植于人体所有粘膜表面的微生物群落的组装始于出生后不久。由于新生儿和幼儿越来越多地接触抗生素,无论是出于治疗目的,还是由于经母体暴露,这个过程都容易受到干扰。我们在这里使用氨苄青霉素在新生后代生命早期给药给哺乳母亲的模型表明,这种暴露会产生持续到成年的后果。后代获得母亲受抗生素影响的微生物群,这会损害其产生结肠 CD4 T 细胞库的能力,特别是结肠调节性 T 细胞。这种 Treg 缺乏不能通过以后与正常小鼠共居来纠正,并且可以通过用来自抗生素暴露供体的微生物群重建无菌小鼠来重现。由于它们的失调,可能还有它们的 Treg 缺乏,受抗生素影响的后代对细菌挑战感染产生失调的 Th1 反应,并发展出更严重的卵清蛋白诱导过敏反应症状。
