Effective host defense requires coordinated regulation of immune activation, metabolism, and redox balance, yet how these processes are integrated remains unclear. Here, we identify dipeptidyl peptidase 3 (Dpp3) as a regulator of immune activation thresholds during bacterial infection. Dpp3-/- mice display enhanced resistance to Klebsiella pneumoniae, with early divergence in bacterial burden, improved survival, preserved tissue architecture, and reduced systemic inflammation. Adoptive transfer experiments demonstrate that Dpp3-deficient immune cells are sufficient to confer protection, indicating a cell-intrinsic effect. Mechanistically, Dpp3 deficiency impairs inducible Nrf2 stabilization, resulting in amplified ROS accumulation and enhanced NF-κB-associated responses. Integrated metabolomic, bioenergetic, and proteomic analyses reveal coordinated mitochondrial remodeling and activation of inflammatory signaling networks, consistent with a metabolically primed immune state. Collectively, these findings establish Dpp3 as a systems-level regulator integrating redox control and immunometabolism to calibrate antimicrobial responses during infection.
Dipeptidyl peptidase 3 sets the threshold for immune activation and survival during experimental bacterial infection / A. Facoetti, L.L.. - In: NATURE COMMUNICATIONS. - ISSN 2041-1723. - (2026 Jul 06), pp. 1-49. [Epub ahead of print] [10.1038/s41467-026-74740-3]
Dipeptidyl peptidase 3 sets the threshold for immune activation and survival during experimental bacterial infection
D. Mostosi;A. Bandera;Y. Torrente;B. Cassani
Ultimo
2026
Abstract
Effective host defense requires coordinated regulation of immune activation, metabolism, and redox balance, yet how these processes are integrated remains unclear. Here, we identify dipeptidyl peptidase 3 (Dpp3) as a regulator of immune activation thresholds during bacterial infection. Dpp3-/- mice display enhanced resistance to Klebsiella pneumoniae, with early divergence in bacterial burden, improved survival, preserved tissue architecture, and reduced systemic inflammation. Adoptive transfer experiments demonstrate that Dpp3-deficient immune cells are sufficient to confer protection, indicating a cell-intrinsic effect. Mechanistically, Dpp3 deficiency impairs inducible Nrf2 stabilization, resulting in amplified ROS accumulation and enhanced NF-κB-associated responses. Integrated metabolomic, bioenergetic, and proteomic analyses reveal coordinated mitochondrial remodeling and activation of inflammatory signaling networks, consistent with a metabolically primed immune state. Collectively, these findings establish Dpp3 as a systems-level regulator integrating redox control and immunometabolism to calibrate antimicrobial responses during infection.| File | Dimensione | Formato | |
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