The effect of neonatal maternal separation on short-chain fatty acids and airway inflammation in adult asthma mice

Main Article Content

L. Qian
L. Lu
L. Huang
Q. Wen
J. Xie
W. Jin
H. Li
L. Jiang

Keywords

Early life stress, Neonatal maternal separation, Intestinal microflora, Asthma

Abstract

Background: To investigate neonatal maternal separation (NMS) effects on airway inflammation of asthma and potential mechanism using a mouse model.
Methods: 80 Balb/c neonatal male mice were randomly assigned to NMS and non-NMS groups. Feces were collected on PND21, 28, 35 and 42 to analyze microbiota and short-chain fatty acids (SCFAs). Non-NMS group were then divided into control (group A) and asthma groups (group B), while NMS group was assigned to NMS + asthma (group C) and NMS + SCFAs + asthma groups (group D). Inflammatory cells and eosinophils (EOS) in bronchoalveolar lavage fluid (BALF) were assessed. Pathological changes and cytokines in lung tissue were observed. Protein expression of Occludin and E-cadherin in airway epithelial was examined.
Results: The number of S′, diversity index H′ and dominance index D′, as well as content butyric acid in NMS group C were significantly lower than non-NMS group B (p < 0.05). Mice in group C had a higher level of inflammatory cells and EOS compared with group A, B and D. EOS moderate infiltration was found in mice of group B, C and D. Mice in group C had significantly higher levels of cytokines and showed slightly increased bronchial epithelium goblet cells and a small amount of visceral secretions. Occludin and E-cadherin expression in lung in B, C and D groups was depressed, and protein level in group C was significantly lower than group B and D.
Conclusions: NMS is associated with exacerbated inflammation of adult asthma by changing intestinal microflora resulting in butanoic acid decline and airway epithelial barrier damage.

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