A Gut Microbe Increases Risk and Severity of Sepsis
Sepsis is a state of runaway inflammation resulting from infection, in which inflammatory signaling becomes so intense that organs fail under the stress. Crudely, one might think of initiation of sepsis as a tipping point between the normal balance of initiation and suppression of inflammation versus a runaway positive feedback loop of inflammatory signaling. Here, researchers show that the composition of the gut microbiome contributes to the risk of sepsis, and one microbial species in particular is involved in pushing individuals past the tipping point. This is one of many studies identifying specific undesirable microbial species for a near future in which highly targeted therapies can eliminate the unwanted components of the gut microbiome as needed.
Host survival during sepsis depends not only on pathogen burden but also on inflammatory thresholds calibrated by the gut microbiota. Here, we show that different survival outcomes were observed in genetically equivalent female C57BL/6 mouse populations depending on their specific gut microbiota configuration. A Muribaculaceae-enriched gut microbiota, characterized by the dominance of Sangeribacter muris KT1-3, predisposed mice to fatal sepsis caused by Acinetobacter baumannii via TLR4-dependent hyperinflammation. This lethal phenotype, reproduced by colonization with S. muris strain KT1-3, was transferable by fecal microbiota transplantation and co-housing. Notably, fixed-dose lipopolysaccharide challenge and ex vivo stimulation assays demonstrated that this configuration induces a heightened TLR4-dependent inflammatory responsiveness independent of bacterial replication.
Single-cell transcriptomics revealed that these microbiota-derived factors establish a transcriptionally pre-activated macrophage state, resulting in production of excessive pro-inflammatory cytokines upon challenge. Mechanistically, S. muris strain KT1-3 releases heat-stable and low-molecular-weight metabolites that are sufficient to potentiate systemic cytokine surges under a fixed-dose endotoxin challenge in vivo, effectively lowering the host's activation threshold for TLR4-driven signaling. Tlr4-deficient mice harboring the KT1-3-enriched susceptible microbiota survived despite persistent bacterial dissemination, demonstrating that the microbiota-TLR4 axis dictates hyperinflammatory A. baumannii-induced sepsis outcomes by modulating inflammatory magnitude rather than pathogen clearance.