NCF1-dependent production of ROS protects against lupus by regulating plasmacytoid dendritic cell development and functions
Huqiao Luo, Vilma Urbonaviciute, Amir Ata Saei, Hezheng Lyu, Massimiliano Gaetani, Ákos Végvári, Yanpeng Li, Roman A. Zubarev, Rikard Holmdahl
Huqiao Luo, Vilma Urbonaviciute, Amir Ata Saei, Hezheng Lyu, Massimiliano Gaetani, Ákos Végvári, Yanpeng Li, Roman A. Zubarev, Rikard Holmdahl
View: Text | PDF
Research Article

NCF1-dependent production of ROS protects against lupus by regulating plasmacytoid dendritic cell development and functions

Abstract

Low capacity to produce ROS because of mutations in neutrophil cytosolic factor 1 (NCF1/p47phox), a component of NADPH oxidase 2 (NOX2) complex, is strongly associated with systemic lupus erythematosus in both humans and mouse models. Here, we aimed to identify the key immune cell type(s) and cellular mechanisms driving lupus pathogenesis under the condition of NCF1-dependent ROS deficiency. Using cell-specific Cre-deleter, human NCF1-339 variant knockin, and transgenic mouse strains, we show that low ROS production in plasmacytoid dendritic cells (pDCs) exacerbated both pristane-induced lupus and a potentially new Y-linked autoimmune accelerating locus–related spontaneous model by promoting pDC accumulation in multiple organs during lupus development, accompanied by elevated IFN-α levels and expression of IFN-stimulated genes. Mechanistic studies revealed that ROS deficiency enhanced pDC generation through the AKT/mTOR pathway and CCR2-mediated migration to tissues, which together with hyperactivation of the redox-sensitive stimulator of interferon genes/IFN-α/JAK1/STAT1 cascade further augmented type I IFN responses. More importantly, by suppressing these pathways, restoration of NOX2-derived ROS specifically in pDCs protected against lupus. These discoveries explain the causative effect of dysfunctional NCF1 in lupus and demonstrate the protective role of pDC-derived ROS in disease development driven by NCF1-dependent ROS deficiency.

Authors

Huqiao Luo, Vilma Urbonaviciute, Amir Ata Saei, Hezheng Lyu, Massimiliano Gaetani, Ákos Végvári, Yanpeng Li, Roman A. Zubarev, Rikard Holmdahl

×

Figure 2

ROS deficiency in Mrp8+ cells, mainly neutrophils, does not affect PIL development.

Options: View larger image (or click on image) Download as PowerPoint
ROS deficiency in Mrp8+ cells, mainly neutrophils, does not affect PIL d...
(A) Oxidative burst in neutrophils and monocytes within peripheral blood from naive B6N.Q (n = 4), B6N.Q.Ncf1m1j/m1j (n = 5), Mrp8-Cre.TN3 (n = 5), and Mrp8-Cre+.TN3 mice (n = 4). Oxidative burst in macrophages and DCs within spleen from naive B6N.Q, B6N.Q.Ncf1m1j/m1j, Mrp8-Cre.TN3, and Mrp8-Cre+.TN3 (of each n = 3). (B) Extracellular ROS in BM neutrophils from naive B6N.Q, B6N.Q.Ncf1m1j/m1j, Mrp8-Cre.TN3, and Mrp8-Cre+.TN3 mice (of each n = 3). AUCs are calculated and plotted. (C) Serum levels of autoantibodies against dsDNA and nucleosomes in Mrp8-Cre+.TN3 (n = 10) and Mrp8-Cre.TN3 mice (n = 8) at different time points after pristane injection. (D) Urinary protein concentrations and (E) frequency and numbers of CD45+ cells within kidneys from Mrp8-Cre+.TN3 (n = 10) and Mrp8-Cre.TN3 mice (n = 8) at 6 MPI. Statistical analysis is done by 1-way ANOVA with Tukey’s multiple-comparison test (A and B), 2-way ANOVA with Holm-Šídák multiple-comparison test (C), and 2-tailed Mann-Whitney U test (D and E). ****P < 0.0001. DHR, dihydrorhodamine 123.