Lower respiratory tract microbiome composition and community interactions in smokers

Michael Campos; Trevor Cickovski; Mitch Fernandez; Melita Jaric; Adam Wanner; Gregory Holt; Elio Donna; Eliana Mendes; Eugenia Silva-Herzog; Lisa Schneper; Jonathan Segal; David Moraga Amador; Juan Daniel Riveros; Vanessa Aguiar-Pulido; Santanu Banerjee; Matthias Salathe; Kalai Mathee; Giri Narasimhan

doi:10.1099/acmi.0.000497.v3

Lower respiratory tract microbiome composition and community interactions in smokers

Michael Campos, Trevor Cickovski, Mitch Fernandez, Melita Jaric, Adam Wanner, Gregory Holt, Elio Donna, Eliana Mendes, Eugenia Silva-Herzog, Lisa Schneper, Jonathan Segal, David Moraga Amador, Juan Daniel Riveros, Vanessa Aguiar-Pulido, Santanu Banerjee, Matthias Salathe, Kalai Mathee, Giri Narasimhan

Department of Molecular and Precision Medicine

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

The lung microbiome impacts on lung function, making any smoking-induced changes in the lung microbiome potentially sig-nificant. The complex co-occurrence and co-avoidance patterns between the bacterial taxa in the lower respiratory tract (LRT) microbiome were explored for a cohort of active (AS), former (FS) and never (NS) smokers. Bronchoalveolar lavages (BALs) were collected from 55 volunteer subjects (9 NS, 24 FS and 22 AS). The LRT microbiome composition was assessed using 16S rRNA amplicon sequencing. Identification of differentially abundant taxa and co-occurrence patterns, discriminant analysis and biomarker inferences were performed. The data show that smoking results in a loss in the diversity of the LRT microbiome, change in the co-occurrence patterns and a weakening of the tight community structure present in healthy microbiomes. The increased abundance of the genus Ralstonia in the lung microbiomes of both former and active smokers is significant. Partial least square discriminant and DESeq2 analyses suggested a compositional difference between the cohorts in the LRT micro-biome. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS. The linear discriminant analysis effect size (LEfSe) analyses identified several bacterial taxa as potential biomarkers of smoking status. Network-based clustering analysis highlighted different co-occurring and co-avoiding microbial taxa in the three groups. The analysis found a cluster of bacterial taxa that co-occur in smokers and non-smokers alike. The clusters exhibited tighter and more significant associations in NS compared to FS and AS. Higher degree of rivalry between clusters was observed in the AS. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS.

Original language	English (US)
Article number	000497.v3
Journal	Access Microbiology
Volume	5
Issue number	3
DOIs	https://doi.org/10.1099/acmi.0.000497.v3
State	Published - 2023

All Science Journal Classification (ASJC) codes

Microbiology
Microbiology (medical)

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10.1099/acmi.0.000497.v3

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Campos, M., Cickovski, T., Fernandez, M., Jaric, M., Wanner, A., Holt, G., Donna, E., Mendes, E., Silva-Herzog, E., Schneper, L., Segal, J., Amador, D. M., Riveros, J. D., Aguiar-Pulido, V., Banerjee, S., Salathe, M., Mathee, K., & Narasimhan, G. (2023). Lower respiratory tract microbiome composition and community interactions in smokers. Access Microbiology, 5(3), Article 000497.v3. https://doi.org/10.1099/acmi.0.000497.v3

@article{5886e997b0e844cca51ae4834722ea10,

title = "Lower respiratory tract microbiome composition and community interactions in smokers",

abstract = "The lung microbiome impacts on lung function, making any smoking-induced changes in the lung microbiome potentially sig-nificant. The complex co-occurrence and co-avoidance patterns between the bacterial taxa in the lower respiratory tract (LRT) microbiome were explored for a cohort of active (AS), former (FS) and never (NS) smokers. Bronchoalveolar lavages (BALs) were collected from 55 volunteer subjects (9 NS, 24 FS and 22 AS). The LRT microbiome composition was assessed using 16S rRNA amplicon sequencing. Identification of differentially abundant taxa and co-occurrence patterns, discriminant analysis and biomarker inferences were performed. The data show that smoking results in a loss in the diversity of the LRT microbiome, change in the co-occurrence patterns and a weakening of the tight community structure present in healthy microbiomes. The increased abundance of the genus Ralstonia in the lung microbiomes of both former and active smokers is significant. Partial least square discriminant and DESeq2 analyses suggested a compositional difference between the cohorts in the LRT micro-biome. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS. The linear discriminant analysis effect size (LEfSe) analyses identified several bacterial taxa as potential biomarkers of smoking status. Network-based clustering analysis highlighted different co-occurring and co-avoiding microbial taxa in the three groups. The analysis found a cluster of bacterial taxa that co-occur in smokers and non-smokers alike. The clusters exhibited tighter and more significant associations in NS compared to FS and AS. Higher degree of rivalry between clusters was observed in the AS. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS.",

author = "Michael Campos and Trevor Cickovski and Mitch Fernandez and Melita Jaric and Adam Wanner and Gregory Holt and Elio Donna and Eliana Mendes and Eugenia Silva-Herzog and Lisa Schneper and Jonathan Segal and Amador, {David Moraga} and Riveros, {Juan Daniel} and Vanessa Aguiar-Pulido and Santanu Banerjee and Matthias Salathe and Kalai Mathee and Giri Narasimhan",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors.",

year = "2023",

doi = "10.1099/acmi.0.000497.v3",

language = "English (US)",

volume = "5",

journal = "Access Microbiology",

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Campos, M, Cickovski, T, Fernandez, M, Jaric, M, Wanner, A, Holt, G, Donna, E, Mendes, E, Silva-Herzog, E, Schneper, L, Segal, J, Amador, DM, Riveros, JD, Aguiar-Pulido, V, Banerjee, S, Salathe, M, Mathee, K & Narasimhan, G 2023, 'Lower respiratory tract microbiome composition and community interactions in smokers', Access Microbiology, vol. 5, no. 3, 000497.v3. https://doi.org/10.1099/acmi.0.000497.v3

TY - JOUR

T1 - Lower respiratory tract microbiome composition and community interactions in smokers

AU - Campos, Michael

AU - Cickovski, Trevor

AU - Fernandez, Mitch

AU - Jaric, Melita

AU - Wanner, Adam

AU - Holt, Gregory

AU - Donna, Elio

AU - Mendes, Eliana

AU - Silva-Herzog, Eugenia

AU - Schneper, Lisa

AU - Segal, Jonathan

AU - Amador, David Moraga

AU - Riveros, Juan Daniel

AU - Aguiar-Pulido, Vanessa

AU - Banerjee, Santanu

AU - Salathe, Matthias

AU - Mathee, Kalai

AU - Narasimhan, Giri

PY - 2023

Y1 - 2023

N2 - The lung microbiome impacts on lung function, making any smoking-induced changes in the lung microbiome potentially sig-nificant. The complex co-occurrence and co-avoidance patterns between the bacterial taxa in the lower respiratory tract (LRT) microbiome were explored for a cohort of active (AS), former (FS) and never (NS) smokers. Bronchoalveolar lavages (BALs) were collected from 55 volunteer subjects (9 NS, 24 FS and 22 AS). The LRT microbiome composition was assessed using 16S rRNA amplicon sequencing. Identification of differentially abundant taxa and co-occurrence patterns, discriminant analysis and biomarker inferences were performed. The data show that smoking results in a loss in the diversity of the LRT microbiome, change in the co-occurrence patterns and a weakening of the tight community structure present in healthy microbiomes. The increased abundance of the genus Ralstonia in the lung microbiomes of both former and active smokers is significant. Partial least square discriminant and DESeq2 analyses suggested a compositional difference between the cohorts in the LRT micro-biome. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS. The linear discriminant analysis effect size (LEfSe) analyses identified several bacterial taxa as potential biomarkers of smoking status. Network-based clustering analysis highlighted different co-occurring and co-avoiding microbial taxa in the three groups. The analysis found a cluster of bacterial taxa that co-occur in smokers and non-smokers alike. The clusters exhibited tighter and more significant associations in NS compared to FS and AS. Higher degree of rivalry between clusters was observed in the AS. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS.

AB - The lung microbiome impacts on lung function, making any smoking-induced changes in the lung microbiome potentially sig-nificant. The complex co-occurrence and co-avoidance patterns between the bacterial taxa in the lower respiratory tract (LRT) microbiome were explored for a cohort of active (AS), former (FS) and never (NS) smokers. Bronchoalveolar lavages (BALs) were collected from 55 volunteer subjects (9 NS, 24 FS and 22 AS). The LRT microbiome composition was assessed using 16S rRNA amplicon sequencing. Identification of differentially abundant taxa and co-occurrence patterns, discriminant analysis and biomarker inferences were performed. The data show that smoking results in a loss in the diversity of the LRT microbiome, change in the co-occurrence patterns and a weakening of the tight community structure present in healthy microbiomes. The increased abundance of the genus Ralstonia in the lung microbiomes of both former and active smokers is significant. Partial least square discriminant and DESeq2 analyses suggested a compositional difference between the cohorts in the LRT micro-biome. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS. The linear discriminant analysis effect size (LEfSe) analyses identified several bacterial taxa as potential biomarkers of smoking status. Network-based clustering analysis highlighted different co-occurring and co-avoiding microbial taxa in the three groups. The analysis found a cluster of bacterial taxa that co-occur in smokers and non-smokers alike. The clusters exhibited tighter and more significant associations in NS compared to FS and AS. Higher degree of rivalry between clusters was observed in the AS. The groups were sufficiently distinct from each other to suggest that cessation of smoking may not be sufficient for the lung microbiota to return to a similar composition to that of NS.

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Lower respiratory tract microbiome composition and community interactions in smokers

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