Red Blood Cells Capture and Deliver Bacterial DNA to Drive Host Responses During Polymicrobial Sepsis

• Published in: The Journal of clinical investigation Vol. 135; no. 4
• Main Authors: Lam, LK Metthew, Klingensmith, Nathan J., Sayegh, Layal, Oatman, Emily, Jose, Joshua S., Cosgriff, Christopher V., Eckart, Kaitlyn A., McGinnis, John, Ranjan, Piyush, Lanza, Matthew, Yehya, Nadir, Meyer, Nuala J., Dickson, Robert P., Mangalmurti, Nilam S.
• Format: Journal Article
• Language: English
• Published: United States American Society for Clinical Investigation 15.02.2025
• Subjects: Analysis; Animals; Coinfection - immunology; Coinfection - microbiology; Development and progression; Disease Models, Animal; DNA; DNA, Bacterial - blood; DNA, Bacterial - genetics; DNA, Bacterial - immunology; Erythrocytes; Erythrocytes - immunology; Erythrocytes - metabolism; Erythrocytes - microbiology; Erythrocytes - pathology; Female; Health aspects; Humans; Immune response; Inflammation; Interleukin-6 - blood; Interleukin-6 - genetics; Interleukin-6 - immunology; Male; Mice; Mice, Knockout; Pulmonology; Sepsis; Sepsis - blood; Sepsis - genetics; Sepsis - immunology; Sepsis - microbiology; Sepsis - pathology; Toll-Like Receptor 9 - genetics; Toll-Like Receptor 9 - immunology; United States; Pulmonology; Innate immunity; Inflammation; Cytokines
• ISSN: 1558-8238; 0021-9738; 1558-8238
• DOI: 10.1172/JCI182127

Red blood cells (RBCs), traditionally recognized for their role in transporting oxygen, play a pivotal role in the body's immune response by expressing TLR9 and scavenging excess host cell-free DNA. DNA capture by RBCs leads to accelerated RBC clearance and triggers inflammation. Whether RBCs can also acquire microbial DNA during infections is unknown. Murine RBCs acquire microbial DNA in vitro, and bacterial DNA-induced (bDNA-induced) macrophage activation was augmented by WT, but not Tlr9-deleted, RBCs. In a mouse model of polymicrobial sepsis, RBC-bound bDNA was elevated in WT mice but not in erythroid Tlr9-deleted mice. Plasma cytokine analysis in these mice revealed distinct sepsis clusters characterized by persistent hypothermia and hyperinflammation in the most severely affected mice. RBC Tlr9 deletion attenuated plasma and tissue IL-6 production in the most severely affected group. Parallel findings in humans confirmed that RBCs from patients with sepsis harbored more bDNA than did RBCs from healthy individuals. Further analysis through 16S sequencing of RBC-bound DNA illustrated distinct microbial communities, with RBC-bound DNA composition correlating with plasma IL-6 in patients with sepsis. Collectively, these findings unveil RBCs as overlooked reservoirs and couriers of microbial DNA, capable of influencing host inflammatory responses in sepsis.