ABSTRACT
The interaction between microbes and the human immune system has long been a focus in biomedical research. Next-generation sequencing has revealed that in addition to gut microbiota, the respiratory tract also harbors microbial communities, forming an interconnected network with the gut microbiota through immune cells and active factors. This review aims to explore how the gut and lung microbiota regulate immune responses, including their roles in local and systemic immune modulation. It also delineates the immunological connections along the gut-lung axis. Further elucidating the influence of microbes on the immune system holds important clinical significance for understanding diseases and exploring novel diagnostic and therapeutic strategies.
ABSTRACT
Bronchial asthma is a common chronic respiratory disease in children.With the development of high-throughput sequencing technology, it has been found that the occurrence and development of asthma is closely related to the dysbiosis of human microbiome.Studies have shown that the changes of respiratory microbiota can significantly affect the mucosal immune system of the host.Respiratory microbiota may be involved in pathophysiological processes such as airway inflammation, airway hyperresponsiveness and airway remodeling through specific mechanisms in asthma.This review focuses on the relationships between the respiratory microbiota and mucosal immunity, as well as their effects on the pathogenesis of asthma.
ABSTRACT
Human respiratory tract is colonized with microbial communities. In recent years, high-throughput DNA sequencing technology has subverted the traditional understanding of pulmonary sterility by proving that there are bacteria in the lungs. As research progresses, it is discovered that there is a connection between the gut and respiratory microbiota, known as the " gut-lung axis" . The gut microbiota can influence lung immunity, and lung inflammation can affect the gut microbiota and cause disease. An in-depth understanding of the " gut-lung axis" has given us a deeper understanding of mucosal immunity. The respiratory microbiota may play an important role in the structural maturation of the host airway, the formation of local immunity and the development of the system, and also has an important impact on the occurrence and development of respiratory diseases in children. In recent years, many achievements have been made in microbiological research around respiratory diseases. Attempts to apply microbe-directed therapies (including probiotics, prebiotics and antibiotics and even vaccines) to restore the healthy homeostasis of the respiratory microbiota in diseased states may be an important target for the prevention and treatment of respiratory diseases in the future. The assumption of applying " omics" such as metagenomics, metabolomics, metatranscriptomics and metaproteomics for experimental research may help to gain a deeper understanding of the impact of the respiratory microbiota on respiratory health and disease, and to better understand the function of the respiratory microbiota and causality. Actively searching for novel probiotics or microbiota with anti-inflammatory properties will be a potential candidate approach for improving airway inflammation in the future; further discovery of novel metabolites with immunomodulatory potential as well as the metabolites of purified microorganisms (such as short-chain fatty acids) will provide promising candidates for the treatment of respiratory diseases. This article summarized the progress in this field in recent years.