Abstract
The gut microbiota is often mentioned as a “forgotten organ” or “metabolic organ”, given its profound impact on host physiology, metabolism, immune function and nutrition. A healthy diet is undoubtedly a major contributor for promoting a “good” microbial community that turns out to be crucial for a fine-tuned symbiotic relationship with the host. Both microbial-derived components and produced metabolites elicit the activation of downstream cascades capable to modulate both local and systemic immune responses. A balance between host and gut microbiota is crucial to keep a healthy intestinal barrier and an optimal immune homeostasis, thus contributing to prevent disease occurrence. How dietary habits can impact gut microbiota and, ultimately, host immunity in health and disease has been the subject of intense study, especially with regard to metabolic diseases. Only recently, these links have started to be explored in relation to lung diseases. The objective of this review is to address the current knowledge on how diet affects gut microbiota and how it acts on lung function. As the immune system seems to be the key player in the cross-talk between diet, gut microbiota and the lungs, involved immune interactions are discussed. There are key nutrients that, when present in our diet, help in gut homeostasis and lead to a healthier lifestyle, even ameliorating chronic diseases. Thus, with this review we hope to incite the scientific community interest to use diet as a valuable non-pharmacological addition to lung diseases management. First, we talk about the intestinal microbiota and interactions through the intestinal barrier for a better understanding of the following sections, which are the main focus of this article: the way diet impacts the intestinal microbiota and the immune interactions of the gut–lung axis that can explain the impact of diet, a key modifiable factor influencing the gut microbiota in several lung diseases.
Highlights
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The adult human gut is predominantly colonised by two bacterial phyla, FirmiThe adult human gut is predominantly colonised by two bacterial phyla, Firmicutes cutes and Bacteroidetes, that comprise over 90% of the total gut microbial communiand Bacteroidetes, that comprise over 90% of the total gut microbial communities, ties, followed by other subdominant phyla such as Actinobacteria, Proteobacteria and followed by other subdominant phyla such as Actinobacteria, Proteobacteria and Verrucomicrobia [7,18] (Figure 1)
Even though there is a vast density of microbial cells in the gut, it is unusual for commensal bacteria to breach the intestinal barrier, avoiding tissue inflammation and microbial translocation and maintaining the mutualistic relationship between host and the gut microbiota
Summary
The human microbiota aggregates an estimate of 100 trillion (1014 ) microbial cells that reside or colonise all body surfaces and cavities exposed to the external environment, namely, skin, eyes, the urogenital system, and the epithelial surfaces of the respiratory system and gastrointestinal tract (GIT) [1,2,3,4]. The intestinal barrier is home to presumably the largest pool of the immune cells in the human body This is expected as this is a place to encounter a vast community of microbes, toxins, metabolites and dietary components [5,24,25]. Even though there is a vast density of microbial cells in the gut, it is unusual for commensal bacteria to breach the intestinal barrier, avoiding tissue inflammation and microbial translocation and maintaining the mutualistic relationship between host and the gut microbiota. Dendritic cells that have sampled commensal microbes can home to the mesenteric lymph nodes and originate a local immune response but are not able to penetrate further to reach central systemic lymphoid structures (“immune firewall”) [27,44]. A wide range of factors can compromise intestinal homeostasis and increase the permeability of the barrier that includes the presence of pathogens, environmental stress, high-fat/high-sugar diets, drugs and antibiotics, among others [48]
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