Three-Dimensional Microbiome and Metabolome Cartography of a Diseased Human Lung

Garg, Neha; Wang, Mingxun; Hyde, Embriette R.; Silva, Ricardo R. da; Melnik, Alexey V.; Protsyuk, Ivan; Bouslimani, Amina; Lim, Yan Wei; Wong, Richard L.; Humphrey, Greg; Ackermann, Gail; Spivey, Timothy; Brouha, Sharon S.; Bandeira, Nuno; Lin, Grace; Rohwer, Forest; Conrad, Douglas; Alexandrov, Theodore; Knight, Rob; Dorrestein, Pieter C.

doi:10.1016/j.chom.2017.10.001

Cited by 106 publications

(109 citation statements)

References 39 publications

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“…This allowed a better visualization for correlation between microbial and molecular penetration. These visuals also revealed that local environments within the lung vary in terms of pathogen abundance, which can affect the metabolome in unique ways (126).…”

Section: The Respiratory Microbiome and Metabolismmentioning

confidence: 96%

Lung inflammation and disease: A perspective on microbial homeostasis and metabolism

et al. 2018

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Summary It is now well appreciated that the human microbiome plays a significant role in a number of processes in the body, significantly affecting its metabolic, inflammatory and immune homeostasis. Recent research has revealed that almost every mucosal surface in the human body is associated with a resident commensal microbiome of its own. While the gut microbiome and its role in regulation of host metabolism along with its alteration in a disease state has been well studied, there is a lacuna in understanding the resident microbiota of other mucosal surfaces. Among these, the scientific information on the role of lung microbiota in pulmonary diseases is currently severely limited. Historically, lungs have been considered to be sterile and lung diseases have only been studied in the context of bacterial pathogenesis. Recently however, studies have revealed a resilient microbiome in the upper and lower respiratory tracts and there is increased evidence on its central role in respiratory diseases. Knowledge of lung microbiome and its metabolic fallout (local and systemic) is still in its nascent stages and attracting immense interest in recent times. In this review, we will provide a perspective on lung-associated metabolic disorders defined for lung diseases (e.g. COPD, Asthma, respiratory depression due to infection) and correlate it with lung microbial perturbation. Such perturbations may be due to altered biochemical or metabolic stress as well. Finally, we will draw evidence from microbiome and classical microbiology literature to demonstrate how specific lung morbidities associate with specific metabolic characteristics of the disease, and with the role of microbiome in this context.

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Section: The Respiratory Microbiome and Metabolismmentioning

confidence: 96%

Lung inflammation and disease: A perspective on microbial homeostasis and metabolism

et al. 2018

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“…Metabolomics is a promising technology that allows for simultaneous identification and relative quantitation of the major biochemicals present in cells, tissue, and/or body fluids. Information provided by metabolomics analysis regarding global metabolic alterations resulting from genetic and/or environmental exposures (eg, medications) may be used to monitor disease or treatment responses and has shown benefit in CF research . However, metabolomics, which can aid with patient stratification, and early intervention, has not been fully applied to CFTR modulator therapeutic monitoring.…”

Section: Introductionmentioning

confidence: 99%

“…Information provided by metabolomics analysis regarding global metabolic alterations resulting from genetic and/or environmental exposures (eg, medications) may be used to monitor disease or treatment responses and has shown benefit in CF research. [6][7][8][9][10][11][12][13][14][15][16][17] However, metabolomics, which can aid with patient stratification, and early intervention, has not been fully applied to CFTR modulator therapeutic monitoring. Recently, proteomics analysis (a method akin to metabolomics that focuses on protein analysis) of CF monocytes revealed monocyte function changes in response to Ivacaftor treatment, 18 suggesting the benefit of metabolite profiling after CFTR modulator initiation to determine biochemical changes.…”

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confidence: 99%

Metabolomic responses to lumacaftor/ivacaftor in cystic fibrosis

Kopp

McCulloch

Shrestha

et al. 2018

Pediatric Pulmonology

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“…It is now appreciated that increased microbial immigration to the airways and decreased mechanisms of airway clearance facilitate selective microbial growth. As there are regional differences in the rates of microbial immigration, airway clearance and environmental selective pressures, in the lower airways, the composition of the microbiota also varies regionally …”

Section: Respiratory Microbiome Researchmentioning

confidence: 99%

The contribution of respiratory microbiome analysis to a treatable traits model of care

et al. 2018

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The composition of the airway microbiome in patients with chronic airway diseases, such as severe asthma, chronic obstructive pulmonary disease (COPD), bronchiectasis and cystic fibrosis (CF), has the potential to inform a precision model of clinical care. Patients with these conditions share overlapping disease characteristics, including airway inflammation and airflow limitation. The clinical management of chronic respiratory conditions is increasingly moving away from a one‐size‐fits‐all model based on primary diagnosis, towards care targeting individual disease traits, and is particularly useful for subgroups of patients who respond poorly to conventional therapies. Respiratory microbiome analysis is an important potential contributor to such a ‘treatable traits’ approach, providing insight into both microbial drivers of airways disease, and the selective characteristics of the changing lower airway environment. We explore the potential to integrate respiratory microbiome analysis into a treatable traits model of clinical care and provide a practical guide to the application and clinical interpretation of respiratory microbiome analysis.

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Three-Dimensional Microbiome and Metabolome Cartography of a Diseased Human Lung

Cited by 106 publications

References 39 publications

Lung inflammation and disease: A perspective on microbial homeostasis and metabolism

Lung inflammation and disease: A perspective on microbial homeostasis and metabolism

Metabolomic responses to lumacaftor/ivacaftor in cystic fibrosis

The contribution of respiratory microbiome analysis to a treatable traits model of care

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