In vivo lung microbiome alterations from burn pit emissions and/or sand inhalation exposures.
In-theater inhalation exposure to burn pit emissions (BPEs) and sand has been linked to respiratory issues, prompting a study to identify molecular alterations and potential biomarkers related to exposure and outcomes.
Using a complex in vivo exposure scenario to mimic in-theater inhalation exposures, Sprague-Dawley rats were exposed to clean air (Control), BPEs, Sand, or a combination of BPE + Sand via whole-body exposure chambers. After euthanasia, bronchoalveolar lavage fluid was collected at 4 days and 90 days post-exposure, and bacterial amplicon sequence variants were identified using genomic DNA extraction and 16S rRNA gene sequencing.
Both BPE and BPE + Sand exposures significantly altered the lung microbiome, demonstrating increased mean alpha diversity and the highest number of unique ASVs. These changes in the lung microbiome began as early as 4 days post-exposure and continued throughout 90 days post-exposure. BPE and BPE + Sand groups had increased levels of Bradyrhizobium and Methylobacterium and decreased levels of Pseudomonas compared to the Control and Sand groups. The genera most associated with the differences at 4 days post-exposure between the BPE vs. Control and BPE + Sand vs. Control groups were Corynebacterium, Geobacillus, Sphingomonas, and Streptococcus. Interestingly, the lung microbiome from the Sand or Control groups was not significantly altered based on alpha or beta diversity and shared the most abundant genera.
These data indicate that BPE exposure significantly alter the lung microbiome, whereas sand inhalation exposures alone did not seem to cause significant changes, nor did they provide an additive effect when combined with BPE. While the sub-chronic exposure study design led to more subtle molecular alterations in the lung tissue than expected, BPE exposures resulted in distinct and significant microbiome compositional changes in the lung. The observed population shift provided a signature specific to the type of inhalation exposure. Further efforts could lead to an understanding of the role of individual lung microbiomes in inhalation exposure risks and outcomes.
Using a complex in vivo exposure scenario to mimic in-theater inhalation exposures, Sprague-Dawley rats were exposed to clean air (Control), BPEs, Sand, or a combination of BPE + Sand via whole-body exposure chambers. After euthanasia, bronchoalveolar lavage fluid was collected at 4 days and 90 days post-exposure, and bacterial amplicon sequence variants were identified using genomic DNA extraction and 16S rRNA gene sequencing.
Both BPE and BPE + Sand exposures significantly altered the lung microbiome, demonstrating increased mean alpha diversity and the highest number of unique ASVs. These changes in the lung microbiome began as early as 4 days post-exposure and continued throughout 90 days post-exposure. BPE and BPE + Sand groups had increased levels of Bradyrhizobium and Methylobacterium and decreased levels of Pseudomonas compared to the Control and Sand groups. The genera most associated with the differences at 4 days post-exposure between the BPE vs. Control and BPE + Sand vs. Control groups were Corynebacterium, Geobacillus, Sphingomonas, and Streptococcus. Interestingly, the lung microbiome from the Sand or Control groups was not significantly altered based on alpha or beta diversity and shared the most abundant genera.
These data indicate that BPE exposure significantly alter the lung microbiome, whereas sand inhalation exposures alone did not seem to cause significant changes, nor did they provide an additive effect when combined with BPE. While the sub-chronic exposure study design led to more subtle molecular alterations in the lung tissue than expected, BPE exposures resulted in distinct and significant microbiome compositional changes in the lung. The observed population shift provided a signature specific to the type of inhalation exposure. Further efforts could lead to an understanding of the role of individual lung microbiomes in inhalation exposure risks and outcomes.
Authors
Frey Frey, Grogg Grogg, Hoisington Hoisington, Wong Wong, Mumy Mumy, Mauzy Mauzy
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