Abstract
Cystic periventricular leukomalacia is commonly diagnosed in premature infants, resulting from severe hypoxic-ischemic white matter injury, and also involving some grey matter damage. Very few is known concerning the cell death pathways involved in these types of premature cerebral lesions. Excitotoxicity is a predominant mechanism of hypoxic-ischemic injury in the developing brain. Concomitantly, it has been recently shown that autophagy could be enhanced in excitotoxic conditions switching this physiological intracellular degradation system to a deleterious process. We here investigated the role of autophagy in a validated rodent model of preterm excitotoxic brain damage mimicking in some aspects cystic periventricular leukomalacia. An excitotoxic lesion affecting periventricular white and grey matter was induced by injecting ibotenate, a glutamate analogue, in the subcortical white matter (subcingulum area) of five-day old rat pups. Ibotenate enhanced autophagy in rat brain dying neurons at 24 h as shown by increased presence of autophagosomes (increased LC3-II and LC3-positive dots) and enhanced autophagic degradation (SQSTM1 reduction and increased number and size of lysosomes (LAMP1- and CATHEPSIN B-positive vesicles)). Co-injection of the pharmacological autophagy inhibitor 3-methyladenine prevented not only autophagy induction but also CASPASE-3 activation and calpain-dependent cleavage of SPECTRIN 24 h after the insult, thus providing a strong reduction of the long term brain injury (16 days after ibotenate injection) including lateral ventricle dilatation, decreases in cerebral tissue volume and in subcortical white matter thickness. The autophagy-dependent neuroprotective effect of 3-methyladenine was confirmed in primary cortical neuronal cultures using not only pharmacological but also genetic autophagy inhibition of the ibotenate-induced autophagy. Strategies inhibiting autophagy could then represent a promising neuroprotective approach in the context of severe preterm brain injuries.
Highlights
The important progress done in neonatal care constantly increases the survival rates of premature infants
The present study aims to determine the role of autophagy in excitotoxic lesions of the premature brain using a widely recognized rodent model that mimics some features of cPVL42
The injection of ibotenate (10 μg) in the subcortical white matter (WM) at the level of the right cingulum of 5-days-old rat pups causes a severe brain damage of the WM and grey matter (GM) resulting in ventricular enlargement as illustrated by cresyl-violet-stained coronal sections in Fig. 1a 24 h and 16 days after the insult
Summary
The important progress done in neonatal care constantly increases the survival rates of premature infants. Improving the outcomes for Official journal of the Cell Death Differentiation Association. Descloux et al Cell Death and Disease (2018)9:853 these severely affected babies remains a challenging health issue. Excitotoxicity consists in an excessive or prolonged activation of excitatory amino acid receptors (especially those of glutamate) due to a failure of sufficient reuptake and/or excessive release at the synaptic level. It induces a massive increase in intracellular calcium concentration and activates numerous intracellular cascades potentially leading to neuronal cell death[9,10]
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