Real-time non-invasive fluorescence imaging of gut commensal bacteria to detect dynamic changes in the microbiome of live mice

In mammals, gut commensal microbiota interact extensively with the host, and the same interactions can be dysregulated in diseased states. Animal imaging is a powerful technique that is widely used to diagnose, measure, and track biological changes in model organisms such as laboratory mice. Several...

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Veröffentlicht in:	Cell chemical biology 2022-12, Vol.29 (12), p.1721-1728.e5
Hauptverfasser:	Apostolos, Alexis J, Chordia, Mahendra D, Kolli, Sree H, Dalesandro, Brianna E, Rutkowski, Melanie R, Pires, Marcos M
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container_end_page	1728.e5
container_issue	12
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container_title	Cell chemical biology
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creator	Apostolos, Alexis J Chordia, Mahendra D Kolli, Sree H Dalesandro, Brianna E Rutkowski, Melanie R Pires, Marcos M
description	In mammals, gut commensal microbiota interact extensively with the host, and the same interactions can be dysregulated in diseased states. Animal imaging is a powerful technique that is widely used to diagnose, measure, and track biological changes in model organisms such as laboratory mice. Several imaging techniques have been discovered and adopted by the research community that provide dynamic, non-invasive assessment of live animals, but these gains have not been universal across all fields of biology. Herein, we describe a method to non-invasively image commensal bacteria based on the specific metabolic labeling of bacterial cell walls to illuminate the gut bacteria of live mice. This tagging strategy may additionally provide unprecedented insight into cell wall turnover of gut commensals, which has implications for bacterial cellular growth and division, in a live animal.
doi_str_mv	10.1016/j.chembiol.2022.11.010
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title	Real-time non-invasive fluorescence imaging of gut commensal bacteria to detect dynamic changes in the microbiome of live mice
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