- Kelly-Scumpia, Kindra M;
- Scumpia, Philip O;
- Weinstein, Jason S;
- Delano, Matthew J;
- Cuenca, Alex G;
- Nacionales, Dina C;
- Wynn, James L;
- Lee, Pui Y;
- Kumagai, Yutaro;
- Efron, Philip A;
- Akira, Shizuo;
- Wasserfall, Clive;
- Atkinson, Mark A;
- Moldawer, Lyle L
Microbes activate pattern recognition receptors to initiate adaptive immunity. T cells affect early innate inflammatory responses to viral infection, but both activation and suppression have been demonstrated. We identify a novel role for B cells in the early innate immune response during bacterial sepsis. We demonstrate that Rag1(-/-) mice display deficient early inflammatory responses and reduced survival during sepsis. Interestingly, B cell-deficient or anti-CD20 B cell-depleted mice, but not α/β T cell-deficient mice, display decreased inflammatory cytokine and chemokine production and reduced survival after sepsis. Both treatment of B cell-deficient mice with serum from wild-type (WT) mice and repletion of Rag1(-/-) mice with B cells improves sepsis survival, suggesting antibody-independent and antibody-dependent roles for B cells in the outcome to sepsis. During sepsis, marginal zone and follicular B cells are activated through type I interferon (IFN-I) receptor (IFN-α/β receptor [IFNAR]), and repleting Rag1(-/-) mice with WT, but not IFNAR(-/-), B cells improves IFN-I-dependent and -independent early cytokine responses. Repleting B cell-deficient mice with the IFN-I-dependent chemokine, CXCL10 was also sufficient to improve sepsis survival. This study identifies a novel role for IFN-I-activated B cells in protective early innate immune responses during bacterial sepsis.