Corneal endothelial integrity in mice lacking extracellular superoxide dismutase.

PURPOSE: To evaluate corneal endothelial morphology in mice without secreted extracellular superoxide dismutase (SOD) in normal ageing and in a lipopolysaccharide (LPS)-induced inflammation model and to measure the contents of SOD isoenzymes in the mouse cornea and the superoxide radical concentrations in corneas with and without extracellular SOD. METHODS: The central corneal endothelium of wild-type and extracellular SOD-null mice were studied in micrographs at eight different ages and after a unilateral intravitreal injection of LPS, with the contralateral eye serving as the control. The activities of the SOD isoenzymes in the mouse cornea were determined with a direct assay, the superoxide radical concentration was assessed by lucigenin-induced chemiluminescence, and the extracellular SOD distribution was mapped with immunohistochemistry. RESULTS: The activities of the cytosolic Cu- and Zn-containing SOD, the mitochondrial Mn-containing SOD and extracellular SOD were 4300, 15, and 340 U/g wet weight, respectively. Extracellular SOD was found in the epithelium, stroma, and endothelium. The concentration of extracellular superoxide radicals was doubled in extracellular SOD-null corneas, and the endothelial cell density decreased more with age in extracellular SOD-null than in wild-type control corneas. In the LPS-induced inflammation model, the cell density decreased more, and the cells became more irregular in extracellular SOD-null than in wild-type corneas. CONCLUSIONS: In the mouse cornea, absence of extracellular SOD leads to a higher concentration of extracellular superoxide radicals, an enhancement in the spontaneous age-related loss of endothelial cells, and an increased susceptibility to acute inflammatory endothelial damage. Extracellular SOD is likely to have a protective role in the corneal endothelium.

In vitro photochemical cataract in mice lacking copper-zinc superoxide dismutase.

We here evaluate cataract formation in mice lacking the cytosolic copper-zinc superoxide dismutase (CuZn-SOD) in an in vitro model using irradiation with visible light and riboflavin as a photosensitizing agent. Isolated, cultured lenses from wild-type and CuZn-SOD-null mice were irradiated for 1.5 h by a daylight fluorescent light after preincubation with 10 microM riboflavin for 24 h. Cataract formation was evaluated daily with digital image analysis and ocular staging, and after 5 d 86Rb uptake and water contents of the lenses were determined. Basal superoxide concentrations in freshly isolated lenses from wild-type and CuZn-SOD-null mice were determined with lucigenin-derived chemiluminescense, and enzymatic activities of all three SOD isoenzymes in the murine lens were determined with a direct spectrophotometric method. The cytosolic CuZn-SOD accounts for 90% of the total SOD activity of the murine lens. CuZn-SOD-null lenses showed a doubled basal superoxide concentration, and were more prone to develop photochemical cataract in the present model with more opacification, more hydration, and less 86Rb uptake than lenses from wild-type mice. We conclude that CuZn-SOD is an important superoxide scavenger in the lens, and that it may have a protective role against cataract formation.

Extracellular superoxide dismutase deficiency and atherosclerosis in mice.

Lipoprotein peroxidation in the arterial wall has been implicated in atherogenesis. The superoxide radical is formed in arteries and can induce such oxidation. Extracellular superoxide dismutase (EC-SOD) occurs in high concentration in the vascular wall interstitium, and in this study, we examined the importance of the enzyme in atherogenesis. On an apolipoprotein E-null background, the limited aortic lesions induced by a 1-month atherogenic diet were larger in EC-SOD wild-type mice than in EC-SOD-null mice, whereas there were no differences between the EC-SOD genotypes in the larger lesions seen after 3 months on the diet or after 8 months on normal chow. Despite smaller or equal lesions in the EC-SOD-null mice, their cholesterol levels were somewhat higher. Also, on a wild-type background, there were no effects produced by the absence or presence of EC-SOD on atherogenic diet-induced aortic root lesions. The urinary excretion of the lipid peroxidation biomarker 8-isoprostaglandin F(2alpha) was related to the rates of atherogenesis in the mice but was not influenced by the EC-SOD genotype. Likewise, the EC-SOD status had no effect on the staining for oxidized low density lipoprotein epitopes in aortic root sections. Our findings suggest that EC-SOD has little influence on atherogenesis in mice.

Enhanced alloxan-induced beta-cell damage and delayed recovery from hyperglycemia in mice lacking extracellular-superoxide dismutase.

Alloxan is a diabetogenic agent which apparently acts through formation of superoxide radicals formed by redox cycling. Superoxide radicals are also formed by a variety of mechanisms in hyperglycemia. We exposed extracellular-superoxide dismutase (EC-SOD) null mutant and wild-type mice to alloxan, and followed up both the initial diabetes induction and the long-term course of the hyperglycemia. The null mutant mice responded with a modestly enhanced hyperglycemia compared to the wild type controls. In the long-term follow-up all mice eventually regained glycemic control, although it took longer for individuals with higher initial hyperglycemia. This delaying effect of the hyperglycemia was much more pronounced in the null mutant mice. These data suggest that the difference in initial diabetes induction between the groups is due to interception by EC-SOD of extracellular superoxide radicals produced by alloxan. The delayed recovery in the null mutant mice suggests that superoxide radicals released as a result of hyperglycemia impair beta-cell regeneration and that EC-SOD provides some protection. Mouse islets were found to contain little EC-SOD, whereas the content of the cytosolic Cu- and Zn-containing SOD was very high. This low EC-SOD activity may contribute to the high alloxan susceptibility of beta-cells, and may also cause a high susceptibility to superoxide radicals produced by activated inflammatory leukocytes and in hyperglycemia.