Abstract
Cerebral hypoxia-ischemia (HI) compromises the proteasome in a clinically relevant neonatal piglet model. Protecting and activating proteasomes could be an adjunct therapy to hypothermia. We investigated whether chymotrypsin-like proteasome activity differs regionally and developmentally in the neonatal brain. We also tested whether neonatal brain proteasomes can be modulated by oleuropein, an experimental pleiotropic neuroprotective drug, or by targeting a proteasome subunit gene using recombinant adeno-associated virus-9 (AAV). During post-HI hypothermia, we treated piglets with oleuropein, used AAV-short hairpin RNA (shRNA) to knock down proteasome activator 28γ (PA28γ), or enforced PA28γ using AAV-PA28γ with green fluorescent protein (GFP). Neonatal neocortex and subcortical white matter had greater proteasome activity than did liver and kidney. Neonatal white matter had higher proteasome activity than did juvenile white matter. Lower arterial pH 1 h after HI correlated with greater subsequent cortical proteasome activity. With increasing brain homogenate protein input into the assay, the initial proteasome activity increased only among shams, whereas HI increased total kinetic proteasome activity. OLE increased the initial neocortical proteasome activity after hypothermia. AAV drove GFP expression, and white matter PA28γ levels correlated with proteasome activity and subunit levels. However, AAV proteasome modulation varied. Thus, neonatal neocortical proteasomes can be pharmacologically activated. HI slows the initial proteasome performance, but then augments ongoing catalytic activity. AAV-mediated genetic manipulation in the piglet brain holds promise, though proteasome gene targeting requires further development.
Highlights
In a parallel setting with hypothermia, we explored the feasibility of virus-mediated manipulation of the proteasome activator 28γ (PA28γ) gene
The greater chymotrypsinlike proteasome activity in the piglet brain relative to that in the liver shows that species differences in proteasome distribution must be considered when designing and interpreting proteasome studies
Proteasome activity in white matter decreases as brain development progresses
Summary
Proteinopathy is signatory for hypothermia-resistant brain injury from hypoxia-ischemia (HI), notably in the white matter, in a well-established and clinically relevant neonatal piglet model [6]. Proteasomes normally degrade proteins damaged by oxidative stress. We found proteasome insufficiency and carbonylated and ubiquitinated protein accumulation in neonatal piglets that received hypothermia after HI. Higher levels of these damaged proteins were directly associated with myelin injury [6]. Because the proteasome response to HI and hypothermia may differ between cerebral cortex and white matter [6], understanding regional proteasome dysfunction could be pivotal for treating HI brain injury. Stress responses are compromised in humans after birth asphyxia, including a depletion in hypoxia-inducible factor 1α [11]
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