Abstract P3080: S100A8/9 Is A Key Regulator For Normal Heart Function During Pseudomonas Aeruginosa Infection

Rationale: P. aeruginosa ( P.a ) infection can cause severe pneumonia in ICU patients that leads to cardiac inflammation and cardiac dysfunction. Growing evidence indicates that a large number of neutrophils are recruited to the site of P.a. infection and releases S100A8/9 into the microenvironment. S100A8/9 has been shown to activate both the immune system (TLR4/RAGE) and has bactericidal properties. Often, hyperactivation of the inflammatory responses by S100A8/9 causes cardiac inflammation and dysfunction. Thus, we hypothesize that excessive production of S100A8/9 restrict bacterial growth and enhances the host immune response in order to control the infection and preserve heart function.

Objective: To identify the mechanism of S100A8/9 mediated cardiac inflammation and cardiac dysfunction during P. aeruginosa infection.

Methods and Results: To investigate the role of S100A8/9 in cardiac inflammation and cardiac dysfunction, we infected wild type (WT) and S100A8/9KO mice with P.a. intranasally. We monitored bodyweight at 24h intervals and measured weight loss, survival, and bacterial burden in the lungs and heart. We performed multicolor flow cytometry on BAL cells and heart cells for immune cell phenotyping and ELISA for cytokine levels. Also, we measured cardiac electric activity (EKG) and heart function (echocardiography). We found that bacterial burden in the lungs and heart was higher in S100A8/9KO mice than in WT, which correlated with increased mortality. We found severe cardiac electrical abnormalities (second-degree AV block) in S100A8/9KO mice and left ventricular dysfunction. However, there was no significant difference in the BALF immune cell phenotypes of both S100A8/9KO and WT infected mice. Finally, the S100A8/9 inhibitor enhanced the survival of P.a. infected mice.

Conclusion: Our data demonstrate that neutrophil recruitment and release of S100A8/9 is critical to control bacterial growth in the lungs, however, uncontrolled neutrophil accumulation leads to excessive production of S100A8/9. Hyperactivation of the immune system by excessive S100A8/9 leads to systemic inflammation and bacterial dissemination of the heart. Furthermore, our studies revealed that blocking S100A8/9 receptor binding enhances the survival of mice during P.a. infection.

Human Cystic Fibrosis Macrophages Have Defective Calcium-Dependent Protein Kinase C Activation of the NADPH Oxidase, an Effect Augmented by Burkholderia cenocepacia

Macrophage intracellular pathogen killing is defective in cystic fibrosis (CF), despite abundant production of reactive oxygen species (ROS) in lung tissue. Burkholderia species can cause serious infection in CF and themselves affect key oxidase components in murine non-CF cells. However, it is unknown whether human CF macrophages have an independent defect in the oxidative burst and whether Burkholderia contributes to this defect in terms of assembly of the NADPH oxidase complex and subsequent ROS production. In this article, we analyze CF and non-CF human monocyte-derived macrophages (MDMs) for ROS production, NADPH assembly capacity, protein kinase C expression, and calcium release in response to PMA and CF pathogens. CF MDMs demonstrate a nearly 60% reduction in superoxide production after PMA stimulation compared with non-CF MDMs. Although CF MDMs generally have increased total NADPH component protein expression, they demonstrate decreased expression of the calcium-dependent protein kinase C conventional subclass α/β leading to reduced phosphorylation of NADPH oxidase components p47 ^phox and p40 ^phox in comparison with non-CF MDMs. Ingestion of B. cenocepacia independently contributes to and worsens the overall oxidative burst deficits in CF MDMs compared with non-CF MDMs. Together, these results provide evidence for inherent deficits in the CF macrophage oxidative burst caused by decreased phosphorylation of NADPH oxidase cytosolic components that are augmented by Burkholderia These findings implicate a critical role for defective macrophage oxidative responses in persistent bacterial infections in CF and create new opportunities for boosting the macrophage immune response to limit infection.