Pioglitazone restores phagocyte mitochondrial oxidants and bactericidal capacity in chronic granulomatous disease

Background Deficient production of reactive oxygen species (ROS) by the phagocyte nicotinamide adenine dinucleotide (NADPH) oxidase in patients with chronic granulomatous disease (CGD) results in susceptibility to certain pathogens secondary to impaired oxidative killing and mobilization of other phagocyte defenses. Peroxisome proliferator–activated receptor (PPAR) γ agonists, including pioglitazone, approved for type 2 diabetes therapy alter cellular metabolism and can heighten ROS production. It was hypothesized that pioglitazone treatment of gp91 phox−/− mice, a murine model of human CGD, would enhance phagocyte oxidant production and killing of Staphylococcus aureus , a significant pathogen in patients with this disorder. Objectives We sought to determine whether pioglitazone treatment of gp91 phox−/− mice enhanced phagocyte oxidant production and host defense. Methods Wild-type and gp91 phox−/− mice were treated with the PPARγ agonist pioglitazone, and phagocyte ROS and killing of S aureus were investigated. Results As demonstrated by 3 different ROS-sensing probes, short-term treatment of gp91 phox−/− mice with pioglitazone enhanced stimulated ROS production in neutrophils and monocytes from blood and neutrophils and inflammatory macrophages recruited to tissues. Mitochondria were identified as the source of ROS. Findings were replicated in human monocytes from patients with CGD after ex vivo pioglitazone treatment. Importantly, although mitochondrial (mt)ROS were deficient in gp91 phox−/− phagocytes, their restoration with treatment significantly enabled killing of S aureus both ex vivo and in vivo . Conclusions Together, the data support the hypothesis that signaling from the NADPH oxidase under normal circumstances governs phagocyte mtROS production and that such signaling is lacking in the absence of a functioning phagocyte oxidase. PPARγ agonism appears to bypass the need for the NADPH oxidase for enhanced mtROS production and partially restores host defense in CGD.