Both preischemic hyperglycemia and suppression of SOD2 activity aggravate ischemic brain damage. This study was undertaken to assess the effect of SOD2 mutation on ischemic brain damage and its relation to the factors involved in autophagy regulation in hyperglycemic wild-type (WT) and heterozygous SOD2 knockout (SOD2(-/+)) mice subjected to 30-min transient focal ischemia. The brain samples were analyzed at 5 and 24 h after recirculation for ischemic lesion volume, superoxide production, and oxidative DNA damage and protein levels of Beclin 1, damage-regulated autophagy modulator (DRAM), and microtubule-associated protein 1 light chain 3 (LC3). The results revealed a significant increase in infarct volume in hyperglycemic SOD2(-/+) mice, and this was accompanied with an early (5 h) significant rise in superoxide production and reduced SOD2 activity in SOD2(-/+) mice as compared to WT mice. The superoxide production is associated with oxidative DNA damage as indicated by colocalization of the dihydroethidium (DHE) signal with 8-OHdG fluorescence in SOD2(-/+) mice. In addition, while ischemia in WT hyperglycemics increased the levels of autophagy markers Beclin 1, DRAM, and LC3, ischemia in hyperglycemic, SOD2-deficient mice suppressed the levels of autophagy stimulators. These results suggest that SOD2 knockdown exacerbates ischemic brain damage under hyperglycemic conditions via increased oxidative stress and DNA oxidation. Such effect is associated with suppression of autophagy regulators.

Macroautophagy (autophagy) is a process wherein bulk cytosolic proteins and damaged organelles are sequestered and degraded via the lysosome. Alterations in autophagy-associated proteins have been shown to cause neural tube closure defects, neurodegeneration, and tumor formation. Normal lysosome function is critical for autophagy completion and when altered may lead to an accumulation of autophagic vacuoles (AVs) and caspase activation. The tumor suppressor p53 is highly expressed in neural precursor cells (NPCs) and has an important role in the regulation of both autophagy and apoptosis. We hypothesized that altered lysosome function would lead to NPC death via an interaction between autophagy- and apoptosis-associated proteins. To test our hypothesis, we utilized FGF2-expanded NPCs and the neural stem cell line, C17.2, in combination with the lysosomotropic agent chloroquine (CQ) and the vacuolar ATPase inhibitor bafilomycin A1 (Baf A1). Both CQ and Baf A1 caused concentration- and time-dependent AV accumulation, p53 phosphorylation, increased damage regulator autophagy modulator levels, caspase-3 activation, and cell death. Short hairpin RNA knockdown of Atg7, but not Beclin1, expression significantly inhibited CQ- and Baf A1-induced cell death, indicating that Atg7 is an upstream mediator of lysosome dysfunction-induced cell death. Cell death and/or caspase-3 activation was also attenuated by protein synthesis inhibition, p53 deficiency, or Bax deficiency, indicating involvement of the intrinsic apoptotic death pathway. In contrast to lysosome dysfunction, starvation-induced AV accumulation was inhibited by either Atg7 or Beclin1 knockdown, and Atg7 knockdown had no effect on starvation-induced death. These findings indicate that Atg7- and Beclin1-induced autophagy plays a cytoprotective role during starvation but that Atg7 has a unique pro-apoptotic function in response to lysosome dysfunction.