Abstract
Severe hyperbilirubinemia is toxic during central nervous system development. Prolonged and uncontrolled high levels of unconjugated bilirubin lead to bilirubin-induced encephalopathy and eventually death by kernicterus. Despite extensive studies, the molecular and cellular mechanisms of bilirubin toxicity are still poorly defined. To fill this gap, we investigated the molecular processes underlying neuronal injury in a mouse model of severe neonatal jaundice, which develops hyperbilirubinemia as a consequence of a null mutation in the Ugt1 gene. These mutant mice show cerebellar abnormalities and hypoplasia, neuronal cell death and die shortly after birth because of bilirubin neurotoxicity. To identify protein changes associated with bilirubin-induced cell death, we performed proteomic analysis of cerebella from Ugt1 mutant and wild-type mice. Proteomic data pointed-out to oxidoreductase activities or antioxidant processes as important intracellular mechanisms altered during bilirubin-induced neurotoxicity. In particular, they revealed that down-representation of DJ-1, superoxide dismutase, peroxiredoxins 2 and 6 was associated with hyperbilirubinemia in the cerebellum of mutant mice. Interestingly, the reduction in protein levels seems to result from post-translational mechanisms because we did not detect significant quantitative differences in the corresponding mRNAs. We also observed an increase in neuro-specific enolase 2 both in the cerebellum and in the serum of mutant mice, supporting its potential use as a biomarker of bilirubin-induced neurological damage. In conclusion, our data show that different protective mechanisms fail to contrast oxidative burst in bilirubin-affected brain regions, ultimately leading to neurodegeneration.
Highlights
Despite extensive investigations in animal models and in vitro tissue culture cells, the basic mechanisms of hyperbilirubinemia neurotoxicity have not been fully clarified yet.[6,7] Unconjugated bilirubin (UCB) affects a large number of cellular functions and neurological damage appears to be the result of their concerted disruption rather than misregulation of a single pathway
The mechanisms involved in bilirubin neurotoxicity to the developing nervous system are still poorly understood, and protein changes related to functional deficits are difficult to be established
Proteomic analysis demonstrated a lower representation of Pcbp[1], DJ-1, reduced forms of Prdx[2] and Prdx[6], Sod[1], Pfdn[5], Tctp and Pebp[1] in cerebella from Ugt[1] mutant mice, and an increased representation therein of Dpysl[2], Dihydropyrimidinase-related Q3TT92 protein 3 (Dpysl3), 14-3-3e, Vat[1], Atp6v1a and Eno[2]
Summary
Despite extensive investigations in animal models and in vitro tissue culture cells, the basic mechanisms of hyperbilirubinemia neurotoxicity have not been fully clarified yet.[6,7] UCB affects a large number of cellular functions and neurological damage appears to be the result of their concerted disruption rather than misregulation of a single pathway. The aim of this study was to get a deeper unbiased insight into the molecular processes underlying bilirubin-induced neurodegeneration in vivo by using a mouse model of neonatal hyperbilirubinemia that shows early lethality because of bilirubin-induced neurological damage.[19] Previous experiments conducted by our lab showed that the cerebellum of the Ugt1a− / − mouse is the most vulnerable region of the brain to bilirubin toxicity.[19,20] Cerebellar susceptibility to bilirubin resulted in important alterations of its architecture, being the external germinal layer (EGL) and the Purkinje cell layer (PCL) the most affected regions, associated with an increase of terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick end labeling (TUNEL)-positive cells.[19,20]. Our data point to an impairment of enzymatic antioxidant processes as important intracellular mechanisms involved in the onset of bilirubin-induced neurotoxicity in vivo
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