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Journal Article

Citation

Getnet D, Gautam A, Kumar R, Hoke A, Cheema AK, Rossetti F, Schultz CR, Hammamieh R, Lumley LA, Jett M. Appl. Environ. Microbiol. 2018; 84(21): ePub.

Affiliation

Integrative Systems Biology Program, US Army Center for Environmental Health Research, Fort Detrick, Maryland marti.jett-tilton.civ@mail.mil.

Copyright

(Copyright © 2018, American Society for Microbiology)

DOI

10.1128/AEM.00978-18

PMID

30217846

Abstract

The experimental pathophysiology of organophosphorus (OP) chemical exposure has been extensively reported. Here, we describe an altered fecal bacterial biota and urine metabolome that follows intoxication with soman, a lipophilic G class chemical warfare nerve agent. Non-anaesthetized Sprague-Dawley male rats were subcutaneously administered soman at 0.8 (sub-seizurogenic) or 1.0 (seizurogenic) of the median lethal dose (LD50) and evaluated for signs of toxicity. Animals were stratified based on seizing activity to evaluate effects of soman exposure on fecal bacterial biota and urine metabolites. Soman exposure reshaped fecal bacterial biota by altering Facklamia, Rhizobium, Bilophila, Enterobacter, and Morganella genera of the Firmicutes and Proteobacteria phyla, some of which are known to hydrolyze OPs. However, analogous changes were not observed in the bacterial biota of the ileum, which remained the same irrespective of dose or seizing status of animals after soman intoxication. However, at 75 days post soman exposure, bacterial biota stabilized and no differences were observed between groups. Interestingly, when considering just the seizing status of animals, we found that the urine metabolome was markedly different. Leukotriene C4, kynurenic acid, 5-hydroxyindoleacetic acid, norepinephrine, and aldosterone were excreted at much higher rates at 72 hrs in seizing animals, consistent with early multi-organ involvement during soman poisoning. These findings demonstrate the feasibility of using the dysbiosis of fecal bacterial biota in combination with urine metabolome alterations as forensic evidence for pre-symptomatic OP exposure temporally to enable administration of neuroprotective therapies of the future.Importance: The paucity of assays to determine physiologically relevant OP exposure presents an opportunity to explore the use of fecal bacteria as sentinels in combination with urine to assess changes in the exposed host. Recent advances in sequencing technologies and computational approaches have enabled researchers to survey large community level changes of gut bacterial biota and metabolomic changes in various biospecimens. Here, we profiled changes in fecal bacterial biota and urine metabolome following a chemical warfare nerve agent exposure. The significance of this work is a proof-of-concept that fecal bacterial biota and urine metabolites are two separate biospecimens rich in surrogate indicators suitable for monitoring OP exposure. The larger value of such an approach is that assays developed around these observations can be deployed at any setting with a moderate clinical chemistry and microbiology capability. This can enable estimation of the affected radius or to screen, triage, or rule out suspected cases of exposures in mass casualty scenarios, transportation accidents involving hazmats, refugee movements, humanitarian missions, and training settings when coupled to an established and validated decision-tree with clinical features.


Language: en

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