Outer membrane vesicles derived from heatstroke-associated intestinal microbiota promote multiple organ injury in mice.

Abstract

Multiple organ injury is a common issue in heatstroke (HS); however, the underlying pathogenesis remains unclear. As an early event in HS, intestinal injury is an active participant that drives organ injury. Outer membrane vesicles (OMVs), a group of vesicles shed by unbalanced intestinal microbiota as "danger signals," mediate different functional cargo transport in cells and modulate varying biological events in distant target cells. However, the role of OMVs in HS-mediated organ damage remains unclear. Therefore, this study examined OMV production in HS and explored the effect of regulating multiple organ injury. To construct a mouse model, animals were exposed to hyperthermia. OMVs from the intestinal microbiota of HS and control mice were extracted by standardized differential ultracentrifugation. Thereafter, OMVs were characterized and infused into recipient mice via the tail vein. Cl-amidine (a pan-peptidylarginine deiminase inhibitor and OMV production inhibitor) was injected intraperitoneally (2mg/kg) 2h before HS treatment, and the absorption of HS OMVs by different organs was tracked. The effect of OMVs on inducing organ pathological changes, inflammatory infiltration, inflammatory cytokine expression, and serum organ injury biomarkers was demonstrated. HS increased OMV production by intestinal microbiota; OMVs were absorbed by different organs in vivo, and were especially enriched in the liver and lung. Compared to control OMVs, infusion with HS OMVs induced significant organ pathological changes, elevated inflammatory cell (macrophages and neutrophil) infiltration, inflammatory cytokine (TNF-ɑ, IL-1β, IL-6) expression, as well as serum biomarkers of organ injury. Similarly, inhibition of endogenous OMVs alleviated these organ injury indicators induced by HS. To our knowledge, the present study is the first to illustrate that OMVs induce acute organ impairment during severe HS, offering a foundation for subsequent studies and providing novel therapeutic targets.