Increased Cytochrome c–Mediated DNA Fragmentation and Cell Death in Manganese–Superoxide Dismutase–Deficient Mice After Exposure to Subarachnoid Hemolysate

Abstract

Background and Purpose —We sought to investigate the mechanisms for oxidative injury caused by subarachnoid hemolysate, a pro-oxidant. Methods —Injection of 50 μL of subarachnoid hemolysate or saline was performed in CD1 mice (n=75), mutant mice deficient in Mn–superoxide dismutase ( Sod2 +/−; n=23), and their wild-type littermates (n=23). Subcellular location of cytochrome c was studied by immunocytochemistry, immunofluorescence, and immunoblotting of cellular fractions. DNA fragmentation was assessed though DNA laddering and terminal deoxynucleotidyl transferase–mediated dUTP-biotin nick end-labeling (TUNEL). Cell death was examined through basic histology. Results —Cytochrome c immunoreactivity was present in the cytosol of neurons at 2 hours after hemolysate injection and increased by 4 hours compared with saline-injected animals ( P c was more abundant in Sod2 +/− mutants. DNA fragmentation was evident at 24 hours, but not 4 hours, after hemolysate injection as determined by DNA laddering and TUNEL staining ( P c and iron. In Sod2 +/− mutants, the extent of fragmentation was increased as determined by TUNEL staining (52% increase; P P Sod2 +/− mutants, cell death was increased by 51% compared with wild-type littermates ( P Conclusions —These results demonstrate that subarachnoid blood products are associated with the presence of cytochrome c in the cytosol and subsequent cell death in neurons. It appears that Mn–superoxide dismutase plays a role in preventing cell death after exposure to subarachnoid blood products.