Abstract
A role of the mitochondrial dynamin-related protein (Drp1) on gut microbiome composition and intestinal barrier function after hemorrhagic shock has not been identified previously and thus addressed in this study. Here, we used a combination of 16S rRNA gene sequencing and mass spectrometry-based metabolomics profiling in WT and Drp1 KO mouse models to examine the functional impact of activated Drp1 on the gut microbiome as well as mitochondrial metabolic regulation after hemorrhagic shock. Our data showed that changes in mitochondrial Drp1 activity participated in the regulation of intestinal barrier function after hemorrhagic shock. Activated Drp1 significantly perturbed gut microbiome composition in the Bacteroidetes phylum. The abundance of short-chain fatty acid (SCFA) producing microbes, such as Bacteroides, Butyricimonas and Odoribacter, was markedly decreased in mice after shock, and was inversely correlated with both the distribution of the tight junction protein ZO1 and intestinal permeability. Together, these data suggest that Drp1 activation perturbs the gut microbiome community and SCFA production in a ROS-specific manner and thereby substantially disturbs tight junctions and intestinal barrier function after hemorrhagic shock. Our findings provide novel insights for targeting Drp1-mediated mitochondrial function as well as the microbiome in the treatment of intestinal barrier dysfunction after shock.
Highlights
The intestinal barrier is composed of tight junctions between intestinal epithelial cells (IECs), which is critical to resist the invasion of harmful substances into the body [1]
Gut microbiome is the biological barrier of intestinal mucosa, which is closely related to the maintenance of intestinal homeostasis and intestinal barrier function
It is reported that mitochondria originate from symbiotic bacteria in primitive eukaryotic cells, indicating high homology between mitochondria and gut microbiome [25, 26]
Summary
The intestinal barrier is composed of tight junctions between intestinal epithelial cells (IECs), which is critical to resist the invasion of harmful substances into the body [1]. In ischemic-hypoxic injury or hemorrhagic shock, the redistribution of body blood volume markedly reduces the blood flow through the intestinal mucosa to optimize the blood supply for vital organs such as the heart and brain [2]. Another consequence of hypoxic-ischemic injury to IECs is ATP reduction and tight junction rupture, which further induce intestinal barrier dysfunction [3]. Studies have shown that dinitrophenolinduced mitochondrial dysfunction in IECs may lead to intestinal barrier dysfunction [6], suggesting that the stability of mitochondria is critical to maintaining tight junction integrity and intestinal barrier function
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