Characterization of free radical generation by xanthine oxidase. Evidence for hydroxyl radical generation

Xanthine oxidase has been hypothesized to be an important source of biological free radical generation. The enzyme generates the superoxide radical, .O2- and has been widely applied as a .O2- generating system; however, the enzyme may also generate other forms of reduced oxygen. We have applied electron paramagnetic resonance (EPR) spectroscopy using the spin trap 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) to characterize the different radical species generated by xanthine oxidase along with the mechanisms of their generation. Upon reaction of xanthine with xanthine oxidase equilibrated with air, both DMPO-OOH and DMPO-OH radicals are observed. In the presence of ethanol or dimethyl sulfoxide, alpha-hydroxyethyl or methyl radicals are generated, respectively, indicating that significant DMPO-OH generation occurred directly from OH rather than simply from the breakdown of DMPO-OOH. Superoxide dismutase totally scavenged the DMPO-OOH signal but not the DMPO-OH signal suggesting that .O2- was not required for .OH generation. Catalase markedly decreased the DMPO-OH signal, while superoxide dismutase + catalase totally scavenged all radical generation. Thus, xanthine oxidase generates .OH via the reduction of O2 to H2O2, which in turn is reduced to .OH. In anaerobic preparations, the enzyme reduces H2O2 to .OH as evidenced by the appearance of a pure DMPO-OH signal. The presence of the flavin in the enzyme is required for both .O2- and .OH generation confirming that the flavin is the site of O2 reduction. The ratio of .O2- and .OH generation was affected by the relative concentrations of dissolved O2 and H2O2. Thus, xanthine oxidase can generate the highly reactive .OH radical as well as the less reactive .O2- radical. The direct production of .OH by xanthine oxidase in cells and tissues containing this enzyme could explain the presence of oxidative cellular damage which is not prevented by superoxide dismutase.     

A prawn transglutaminase: Molecular characterization and biochemical properties

In this study, we report the bioinformatics characterization, gene expression, transglutaminase activity and coagulation assays of transglutaminase (TGase) of freshwater prawn Macrobrachium rosenbergii identified from the constructed cDNA library by GS FLX™ technology. Even though, TGase have sequence similarity, they differ extensively in their substrate specificity and are thought to play an important in variety of functions such as development, tissue differentiation and immune responses etc. Gene expression studies show that MrTGase is widely distributed in the tissues such as heart, muscle, intestine, brain, etc., but higher amounts are found in hemocyte. Results of TGase mRNA relative expression in hemocyte, before and after infected with white spot syndrome baculovirus (WSBV) and Vibrio harveyi show that the gene expression initially increases up to 24 h and then it falls down. Coagulation assay results showed that the endogenous TGase is involved in the rapid assembly of a specific, plasma clotting protein. Structural studies show that MrTGase contains a typical TGc domain between 323 and 424, and two putative integrin-binding motifs at Arg¹⁸⁰–Gly¹⁸¹–Asp¹⁸² and Arg²⁶⁹–Gly²⁷⁰–Asp²⁷¹. The predicted 3D model of MrTGase contains 47.04% coils (366 amino acid residues), 26.74% extended strand (208 residues), 21.72% α-helix (169 residues) and 4.5% beta turns (35 residues). BLASTp analysis of MrTGase exhibited high sequence similarities with other crustacean TGase, with the highest observed in white shrimp (77.1%). Moreover, the phylogenetic analysis also showed that MrTGase clustered with the other members of crustacean TGase. Overall, these results suggested that MrTGase is a major and functional TGase of M. rosenbergii for haemolymph coagulation and also in spread of infection.     

Hypoxic constriction and reactive oxygen species in porcine distal pulmonary arteries

To determine whether reactive oxygen species (ROS) play an essential role in hypoxic pulmonary vasoconstriction (HPV) and the cellular locus of ROS production and action during HPV, we measured internal diameter (ID) at constant transmural pressure, lucigenin-derived chemiluminescence (LDCL), and electron paramagnetic resonance (EPR) spin adduct spectra in small distal porcine pulmonary arteries, and dichlorofluorescein (DCF) fluorescence in myocytes isolated from these arteries. Hypoxia (4% O2) decreased ID, increased DCF fluorescence, tended to increase LDCL, and in some preparations produced EPR spectra consistent with hydroxyl and alkyl radicals. Superoxide dismutase (SOD, 150 U/ml) or SOD + catalase (CAT, 200 U/ml) did not alter ID during normoxia but reduced or abolished the constriction induced by hypoxia. SOD also blocked HPV in endothelium-denuded arteries after restoration of the response by exposure to 10-10 M endothelin-1. Confocal fluorescence microscopy demonstrated that labeled SOD and CAT entered pulmonary arterial myocytes. SOD, SOD + CAT, and CAT blocked the increase in DCF fluorescence induced by hypoxia, but SOD + CAT and CAT also caused a stable increase in fluorescence during normoxia, suggesting that CAT diminished efflux of DCF from cells or oxidized the dye directly. We conclude that HPV required increased concentrations of ROS produced by and acting on pulmonary arterial smooth muscle rather than endothelium.     

Nitric oxide protects cardiac sarcolemmal membrane enzyme function and ion active transport against ischemia-induced inactivation

Nitric oxide (NO.) generated from nitric oxide synthase (NOS) isoforms bound to cellular membranes may serve to modulate oxidative stresses in cardiac muscle and thereby regulate the function of key membrane-associated enzymes. Ischemia is known to inhibit the function of sarcolemmal enzymes, including the (Na+ + K+)-ATPase, but it is unknown whether concomitant injury to sarcolemma (SL)-associated NOS isoforms may contribute to this process by reducing the availability of locally generated NO. Here we report that nNOS, as well as eNOS (SL NOSs), are tightly associated with cardiac SL membranes in several different species. In isolated perfused rat hearts, global ischemia caused a time-dependent irreversible injury to cardiac SL NOSs and a disruption of SL NO. generation. Pretreatment with low concentrations of the NO. donor 1-hydroxy-2-oxo-3-(N-3-methyl-aminopropyl)-3-methyl-1-triazene (NOC-7) markedly protected both SL NOS and (Na+ + K+)-ATPase functions against ischemia-induced inactivation. Moreover, ischemia impaired SL Na+/K+ binding, and NOC-7 significantly prevented ischemic injury to the ion binding sites on (Na+ + K+)-ATPase. These novel findings indicate that NO. can protect cardiac SL NOSs and (Na+ + K+)-ATPase against ischemia-induced inactivation and suggest that locally generated NO. may serve to regulate SL Na+/K+ ion active transport in the heart.     

In vivo imaging of free radicals: applications from mouse to man

Free radicals and other paramagnetic species, play an important role in cellular injury and pathophysiology. EPR spectroscopy and imaging has emerged as an important tool for non-invasive in vivo measurement and spatial mapping of free radicals in biological tissues. Extensive applications have been performed in small animals such as mice and recently applications in humans have been performed. Spatial EPR imaging enables 3D mapping of the distribution of a given free radical while spectral-spa-tial EPR imaging enables mapping of the spectral information at each spatial position, and, from the observed line width, the localized tissue oxygenation can be determined. A variety of spatial, and spectral-spatial EPR imaging applications have been performed. These techniques, along with the use of biocompatible paramagnetic probes including particulate suspensions and soluble nitroxide radicals, enable spatial imaging of the redox state and oxygenation in a variety of biomedical applications. With spectral-spatial EPR imaging, oxygenation was mapped within the gastrointestinal (GI) tract of living mice, enabling measurement of the oxygen gradient from the proximal to the distal GI tract. Using spatial EPR imaging, the distribution and metabolism of nitroxide radicals within the major organs of the body of living mice was visualized and anatomically co-registered by proton MRI enabling in vivo mapping of the redox state and radical clearance. EPR imaging techniques have also been applied to non-invasively measure the distribution and metabolism of topically applied nitroxide redox probes in humans, providing information regarding the penetration of the label through the skin and measurement of its redox clearance. Thus, EPR spectroscopy and imaging has provided important information in a variety of applications ranging from small animal models of disease to topical measurement of redox state in humans.     

Polynitroxyl-albumin (PNA) plus tempol attenuate lung capillary leak elicited by prolonged intestinal ischemia and reperfusion(1)

Stable nitroxyl radicals (nitroxides) are potential antioxidant drugs, and we have previously reported that linking nitroxide to biological macromolecules can improve therapeutic activity in at least two ways. First, polynitroxylated compounds such as polynitroxyl human serum albumin (PNA) are a novel class of high molecular weight, extracellular antioxidants. Second, compounds such as PNA can prolong the half-life of free (unbound, low molecular weight) nitroxides such as 4-hydroxy-2,2,6, 6-tetramethylpiperidine-N-oxyl (Tempol) in vivo. Unlike PNA, Tempol can readily access the intracellular compartment. Thus PNA can act alone in the extracellular compartment, or in concert with Tempol, to provide additional antioxidant protection within cells. In this study, we compared the abilities of PNA, Tempol, and the combination of PNA + Tempol to prevent lung microvascular injury secondary to prolonged gut ischemia (I, 120 min) and reperfusion (R, 20 min) in the rat. Pulmonary capillary filtration coefficient (K(f,c)) and lung neutrophil retention (tissue myeloperoxidase activity, MPO) were measured in normal, isolated rat lungs perfused with blood harvested from I/R rats. Blood donor rats were treated with drug during ischemia. Gut I/R resulted in a marked increase in pulmonary capillary coefficient and lung MPO. PNA + Tempol, but not PNA alone or Tempol alone, at the doses used, prevented the development of lung leak. None of the treatments had an effect on lung neutrophil retention. Anti-inflammatory therapeutic activity appeared to correlate with blood Tempol level: in the presence of PNA, blood Tempol levels were maintained in the 50-100 microM range vs. essentially undetectable levels shortly after Tempol was administered alone. In this model of lung injury secondary to prolonged gut I/R, lung capillary leak was prevented when the membrane-permeable compound Tempol was maintained in its active, free radical state by PNA.     

A comparative evaluation of EPR and OxyLite oximetry using a random sampling of pO(2) in a murine tumor

Methods currently available for the measurement of oxygen concentrations (oximetry) in viable tissues differ widely from each other in their methodological basis and applicability. The goal of this study was to compare two novel methods, particulate-based electron paramagnetic resonance (EPR) and OxyLite oximetry, in an experimental tumor model. EPR oximetry uses implantable paramagnetic particulates, whereas OxyLite uses fluorescent probes affixed on a fiber-optic cable. C3H mice were transplanted with radiation-induced fibrosarcoma (RIF-1) tumors in their hind limbs. Lithium phthalocyanine (LiPc) microcrystals were used as EPR probes. The pO(2) measurements were taken from random locations at a depth of approximately 3 mm within the tumor either immediately or 48 h after implantation of LiPc. Both methods revealed significant hypoxia in the tumor. However, there were striking differences between the EPR and OxyLite readings. The differences were attributed to the volume of tissue under examination and the effect of needle invasion at the site of measurement. This study recognizes the unique benefits of EPR oximetry in terms of robustness, repeatability and minimal invasiveness.     

Glucagon signalling in the dorsal vagal complex is sufficient and necessary for high‐protein feeding to regulate glucose homeostasis in vivo

High‐protein feeding acutely lowers postprandial glucose concentration compared to low‐protein feeding, despite a dichotomous rise of circulating glucagon levels. The physiological role of this glucagon rise has been largely overlooked. We here first report that glucagon signalling in the dorsal vagal complex (DVC) of the brain is sufficient to lower glucose production by activating a Gcgr–PKA–ERK–K_ATP channel signalling cascade in the DVC of rats in vivo. We further demonstrate that direct blockade of DVC Gcgr signalling negates the acute ability of high‐ vs. low‐protein feeding to reduce plasma glucose concentration, indicating that the elevated circulating glucagon during high‐protein feeding acts in the brain to lower plasma glucose levels. These data revise the physiological role of glucagon and argue that brain glucagon signalling contributes to glucose homeostasis during dietary protein intake.