NOX Enzymes and Pulmonary Disease

Abstract The primary function of the lung is to facilitate the transfer of molecular oxygen (O2; dioxygen) from the atmosphere to the systemic circulation. In addition to its essential role in aerobic metabolism, O2 serves as the physiologic terminal acceptor of electron transfer catalyzed by the NADPH oxidase (NOX) family of oxidoreductases. The evolution of the lungs and circulatory systems in vertebrates was accompanied by increasing diversification of NOX family enzymes, suggesting adaptive roles for NOX-derived reactive oxygen species in normal physiology. However, this adaptation may paradoxically carry detrimental consequences in the setting of overwhelming/persistent environmental stressors, both infectious and noninfectious, and during the process of aging. Here, we review current understanding of NOX enzymes in normal lung physiology and their pathophysiologic roles in a number of pulmonary diseases, including lung infections, acute lung injury, pulmonary arterial hypertension, obstructive lung disorders, fibrotic lung disease, and lung cancer. Antioxid. Redox Signal. 11, 2505-2516.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/78108/1/ars.2009.2599.pd

The NOX toolbox: validating the role of NADPH oxidases in physiology and disease

Reactive oxygen species (ROS) are cellular signals but also disease triggers; their relative excess (oxidative stress) or shortage (reductive stress) compared to reducing equivalents are potentially deleterious. This may explain why antioxidants fail to combat diseases that correlate with oxidative stress. Instead, targeting of disease-relevant enzymatic ROS sources that leaves physiological ROS signaling unaffected may be more beneficial. NADPH oxidases are the only known enzyme family with the sole function to produce ROS. Of the catalytic NADPH oxidase subunits (NOX), NOX4 is the most widely distributed isoform. We provide here a critical review of the currently available experimental tools to assess the role of NOX and especially NOX4, i.e. knock-out mice, siRNAs, antibodies, and pharmacological inhibitors. We then focus on the characterization of the small molecule NADPH oxidase inhibitor, VAS2870, in vitro and in vivo, its specificity, selectivity, and possible mechanism of action. Finally, we discuss the validation of NOX4 as a potential therapeutic target for indications including stroke, heart failure, and fibrosis

TOWARDS A RATIONAL DESIGN OF RESOLVING AGENTS .4. CRYSTAL PACKING ANALYSES AND MOLECULAR MECHANICS CALCULATIONS FOR 5 PAIRS OF DIASTEREOMERIC SALTS OF EPHEDRINE AND A CYCLIC PHOSPHORIC-ACID

Detailed structural studies of five pairs of diastereomeric salts of ephedrine and halogen-substituted chiral cyclic phosphoric acids indicate a correlation between the efficiency of the resolution process and the lattice energy difference between the salts of a diastereomeric pair. Attempts to model such a correlation quantitatively by lattice energy calculations with Molecular Mechanics (MM) methods have not yet been successful. The MM techniques proved unable to reproduce the crystal structures with sufficient accuracy. However, the results of the analyses qualitatively support the presumed correlation, and show that the five resolutions are directed by different acid-base interactions in the hydrophobic layers