Extracellular superoxide dismutase deficiency worsens outcome from focal cerebral ischemia in the mouse.

The role of endogenous extracellular superoxide dismutase (EC-SOD) was examined in a murine model of transient focal cerebral ischemia. Homozygous EC-SOD deficient (EC-SOD-/-; n = 18) and wild type (EC-SOD+/+; n = 19) littermates were anesthetized with halothane and subjected to 50 min of intraluminal middle cerebral artery occlusion with pericranial temperature maintained at 37.0 degrees C. After 24 h of reperfusion, resultant hemiparesis and cerebral infarct size were measured. Total infarct volume was 81% greater (P = 0.03) and hemiparesis was more severe (P = 0.01) in EC-SOD-/- versus EC-SOD+/+ mice. The worsened ischemic outcome observed in EC-SOD-/- mice is consistent with prior work which found transgenic EC-SOD overexpressing mice to exhibit enhanced tolerance to focal ischemia. The results suggest that endogenous antioxidant activity in the extracellular compartment plays an important role in the histologic/neurologic response to focal cerebral ischemia.

Nitric oxide inhalation transiently elevates pulmonary levels of cGMP, iNOS mRNA, and TNF-alpha.

The initial pulmonary vasodilation that occurs during nitric oxide (. NO) inhalation does not appear to be maintained chronically in many cases. . NO may acutely relax vascular smooth muscle by increasing levels of guanosine 3',5'-cyclic monophosphate (cGMP), tumor necrosis factor (TNF)-alpha, and inducible nitric oxide synthase (iNOS) while decreasing levels of lipid peroxidation. It was hypothesized that the acute . NO-induced changes in cGMP, TNF-alpha, iNOS, and lipid peroxidation, all of which may mediate vasodilation, are transient rather than sustained. Lungs from rats kept in chambers containing 6 parts/million . NO for 1 h, 1 day, or 1 wk were analyzed for levels of . NO-induced vasodilatory mediators. Pulmonary cGMP, iNOS mRNA, and TNF-alpha were increased 1 h after . NO exposure but decreased to control values at later times. Levels of malonyl dialdehyde, an indicator of lipid peroxidation, were decreased at all times during . NO inhalation. As a whole, the data suggest that in lungs the vasodilatory mediators cGMP, iNOS, and TNF-alpha are only acutely and transiently elevated during inhalation of . NO, consistent with the initially positive clinical response to inhaled . NO that deteriorates over time.

Oxidative stress in toxicology: established mammalian and emerging piscine model systems.

Interest in the toxicological aspects of oxidative stress has grown in recent years, and research has become increasingly focused on the mechanistic aspects of oxidative damage and cellular responses in biological systems. Toxic consequences of oxidative stress at the subcellular level include lipid peroxidation and oxidative damage to DNA and proteins. These effects are often used as end points in the study of oxidative stress. Typically, mammalian species have been used as models to study oxidative stress and to elucidate the mechanisms underlying cellular damage and response, largely because of the interest in human health issues surrounding oxidative stress. However, it is becoming apparent that oxidative stress also affects aquatic organisms exposed to environmental pollutants. Research in fish has demonstrated that mammalian and piscine systems exhibit similar toxicological and adaptive responses to oxidative stress. This suggests that piscine models, in addition to traditional mammalian models, may be useful for further understanding the mechanisms underlying the oxidative stress response.

Isolation, purification, and structural characterization of flunixin glucuronide in the urine of greyhound dogs.

A urinary metabolite of flunixin in greyhound dogs was isolated and purified by a gradient-elution solid-phase extraction technique. The purified metabolite was shown to be hydrolyzed to free flunixin by strong base and by beta-glucuronidase, suggesting the presence of a C1-beta-glucuronide ester of flunixin. The metabolite was further characterized by positive-ion, tandem MS with electrospray ionization. Mass spectral data showed the presence of a protonated molecular ion (M+1) at m/z 473, which was consistent with the molecular weight of protonated flunixin glucuronide, and a product ion at m/z 297, which was consistent with the molecular weight of protonated flunixin. Collisionally induced dissociation of the m/z 297 product ion showed a fragmentation pattern consistent with that of standard flunixin. These data support the contention that this metabolite of flunixin in greyhound urine is the C1-beta-glucuronide of flunixin. Acyl glucuronide metabolites of some organic acid drugs have been shown to bind covalently to tissue proteins in vitro, in vivo, and ex vivo. The presence of this metabolite may, therefore, have pharmacokinetic and pharmacodynamic implications for flunixin in greyhound dogs, as well as in other animal species in which the acyl glucuronide of flunixin is a metabolite.

Molecular manipulations of extracellular superoxide dismutase: functional importance for learning.

Extracellular superoxide dismutase (EC-SOD) controls the availability of extracellular superoxide (O2.-), which is important for a variety of physiological pathways, including the primary means of inactivating nitric oxide (NO). The role of EC-SOD in neurobehavioral function has been until now unexplored. In the current studies, the phenotypic expression of genotypic alterations of EC-SOD production in mice were characterized for spatial learning and memory. Dramatic impairments in spatial learning in the win-shift 8-arm radial maze were seen in both EC-SOD knockout mice and EC-SOD overexpressing mice. The EC-SOD overexpressing mice were further characterized as having significant deficits in a repeated acquisition task in the radial-arm maze, which permitted the dissociation of long and short-term learning. Long-term learning was significantly impared by EC-SOD overexpression, whereas short-term learning was not significantly affected by EC-SOD overexpression. No systems have been shown to be importantly involved in learning and memory. This may be important in the current studies because EC-SOD has primary control over the inactivation of NO. We found that EC-SOD overexpressing mice were resistant to the cognitive effects of L-NAME (NG-nitro-L-arginine methyl ester hydrochloride), an NO synthase inhibitor. Decreased NO catabolism in these mice may have served to counter the effects of NOS inhibition by L-NAME. The current finding that EC-SOD levels that were either higher or lower than controls impaired learning demonstrates that the proper control of brain extracellular O2.- may be more vital than merely reduction of brain extracellular O2.- in maintaining adequate learning function.

Extracellular superoxide dismutase is upregulated with inducible nitric oxide synthase after NF-kappa B activation.

Inflammatory cytokines have been shown to upregulate secretion of the antioxidant enzyme extracellular superoxide dismutase (EC-SOD) in dermal fibroblasts and, in other cells, to stimulate production of nitric oxide (.NO). Because superoxide rapidly scavenges .NO, forming the injurious peroxynitrite anion (OONO-), we hypothesize that stimulated cells upregulate EC-SOD expression concurrently with .NO release. To test for coregulation of EC-SOD and .NO within the same cell, the timing of inducible nitric oxide synthase (iNOS) and EC-SOD transcription was measured after exposure of a rate type II pneumocyte analog, the L2 cell line, to a combination of interferon-gamma (IFN-gamma) and tumor necrosis factor-alpha (TNF-alpha). Upregulation of iNOS and EC-SOD transcription occurred after 6 h of exposure, and transcription of both genes was linked by activation of the transcription factor nuclear factor-kappa B. Both EC-SOD and iNOS were elevated in rat lung homogenates 24 h after intratracheal instillation with IFN-gamma and TNF-alpha. The observation that EC-SOD and iNOS are temporally coregulated after cytokine exposure suggests the possibility of a critical mechanism by which cells might protect .NO and avoid the formation of OONO- during inflammation.

Detection of flunixin in greyhound urine by a kinetic enzyme-linked immunosorbent assay.

A two-step kinetic enzyme-linked immunosorbent assay was developed to detect the presence of flunixin in the urine of greyhound dogs. The assay system was developed using polyclonal antiflunixin antisera, a rabbit albumin-flunixin conjugate adsorbed onto polystyrene microtiter strips, and flunixin reference standards for calibration. The assay parameters were optimized and the performance characteristics were determined. The quantitative intra- and inter-run precisions (%CV) of the analysis of replicate (n = 10) flunixin-spiked urine samples were 9.9-12.5% and 10.2-13.6%, respectively. The linear dynamic range was 1-100 ng/mL, and the quantitative accuracy, as determined by calculation of percent error of measured flunixin in flunixin-spiked drug-free greyhound urine, was -16% to +14% over this range. The I50 of the ELISA was 17.3 ng/mL. The limit of detection was 25 ng/mL in greyhound urine. The reactivity in the assay system relative to flunixin (100%) was 147% for flunixin glucuronide, 25% for clonixin, and 5% for niflumic acid. The ELISA was capable of detecting total flunixin for up to 72 h in dogs administered flunixin at 0.55 mg/kg orally and up to 96 h in a dog that was administered flunixin at 1.0 mg/kg orally.