1.
A Pilot Study To Investigate the Immune-Modulatory Effects of Fasting in Steroid-Naive Mild Asthmatics.
Han, K, Nguyen, A, Traba, J, Yao, X, Kaler, M, Huffstutler, RD, Levine, SJ, Sack, MN
Journal of immunology (Baltimore, Md. : 1950). 2018;201(5):1382-1388
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Previous studies have shown that caloric restriction and fasting may modulate immune function and have positive effects in asthmatics. The aim of this pilot study was to evaluate the effects of fasting on specific inflammatory markers that might mediate such benefits. 18 mild asthmatics, 5 of whom were not on steroid inhalers, fasted for 24 hours. Lung function and immune parameters were evaluated at baseline and 2.5 hours after the first meal following the fast. There were significant differences between subjects who were and were not on steroid inhalers. Whilst one day of fasting did not affect lung function, a number of inflammatory parameters were improved by fasting in those not taking steroid inhalers, but not in those who were taking steroids. The authors conclude that caloric restriction might be considered as a strategy to improve systemic and pulmonary inflammation in asthma.
Abstract
A fasting mimetic diet blunts inflammation, and intermittent fasting has shown ameliorative effects in obese asthmatics. To examine whether canonical inflammatory pathways linked with asthma are modulated by fasting, we designed a pilot study in mild asthmatic subjects to assess the effect of fasting on the NLRP3 inflammasome, Th2 cell activation, and airway epithelial cell cytokine production. Subjects with documented reversible airway obstruction and stable mild asthma were recruited into this study in which pulmonary function testing (PFT) and PBMCextraction was performed 24 h after fasting, with repeated PFT testing and blood draw 2.5 h after refeeding. PFTs were not changed by a prolonged fast. However, steroid-naive mild asthmatics showed fasting-dependent blunting of the NLRP3 inflammasome. Furthermore, PBMCs from these fasted asthmatics cocultured with human epithelial cells resulted in blunting of house dust mite-induced epithelial cell cytokine production and reduced CD4+ T cell Th2 activation compared with refed samples. This pilot study shows that prolonged fasting blunts the NLRP3 inflammasome and Th2 cell activation in steroid-naive asthmatics as well as diminishes airway epithelial cell cytokine production. This identifies a potential role for nutrient level-dependent regulation of inflammation in asthma. Our findings support the evaluation of this concept in a larger study as well as the potential development of caloric restriction interventions for the treatment of asthma.
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Personalized Gut Mucosal Colonization Resistance to Empiric Probiotics Is Associated with Unique Host and Microbiome Features.
Zmora, N, Zilberman-Schapira, G, Suez, J, Mor, U, Dori-Bachash, M, Bashiardes, S, Kotler, E, Zur, M, Regev-Lehavi, D, Brik, RB, et al
Cell. 2018;174(6):1388-1405.e21
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Evidence regarding the efficacy of probiotics in colonising the gut mucosa are sparse. The authors investigated whether probiotics colonise the gut mucosa in mice and humans, using both gut mucosa and stool samples. They found that, in both mice and humans, results from stool samples only partially correlate with colonisation of the gut mucosa as determined through gut mucosa samples. Whilst results were fairly uniform in mice, in humans a person-specific resistance to colonisation of the gut mucosa by probiotics was observed. Inter-person variation could be predicted by the composition of the pre-probiotic microbiome and host immune features.
Abstract
Empiric probiotics are commonly consumed by healthy individuals as means of life quality improvement and disease prevention. However, evidence of probiotic gut mucosal colonization efficacy remains sparse and controversial. We metagenomically characterized the murine and human mucosal-associated gastrointestinal microbiome and found it to only partially correlate with stool microbiome. A sequential invasive multi-omics measurement at baseline and during consumption of an 11-strain probiotic combination or placebo demonstrated that probiotics remain viable upon gastrointestinal passage. In colonized, but not germ-free mice, probiotics encountered a marked mucosal colonization resistance. In contrast, humans featured person-, region- and strain-specific mucosal colonization patterns, hallmarked by predictive baseline host and microbiome features, but indistinguishable by probiotics presence in stool. Consequently, probiotics induced a transient, individualized impact on mucosal community structure and gut transcriptome. Collectively, empiric probiotics supplementation may be limited in universally and persistently impacting the gut mucosa, meriting development of new personalized probiotic approaches.