Neuroinflammatory and behavioural changes in the Atp7B mutant mouse model of Wilson\'s disease. Terwel D, Löschmann YN, Schmidt HH, Schöler HR, Cantz T, Heneka MT Journal of neurochemistry
118
105-12. doi
2010
Show Abstract
Wilson\'s disease (WD) is caused by mutations in the copper transporting ATPase 7B (Atp7b). Patients present with liver pathology or behavioural disturbances. Studies on rodent models for WD so far mainly focussed on liver, not brain. The effect of knockout of atp7b on sensori-motor and cognitive behaviour, as well as neuronal number, inflammatory markers, copper and synaptic proteins in brain were studied in so-called toxic milk mice. Copper accumulated in striatum and hippocampus of toxic milk mice, but not in cerebral cortex. Inflammatory markers were increased in striatum and corpus callosum, but not in cerebral cortex and hippocampus, whereas neuronal numbers were unchanged. Toxic milk mice were mildly impaired in the rotarod and cylinder test and unable to acquire spatial memory in the Morris water maze. Despite the latter observation only synaptophysin of a number of synaptic proteins, was altered in the hippocampus of toxic milk mice. In addition to disturbances in neuronal signalling by increased brain copper, inflammation and inflammatory signalling from the periphery to the brain might add to the behavioural disturbances in the toxic milk mice. These mice can be used to evaluate therapeutic strategies to alleviate behavioural disturbances and cerebral pathology observed in WD.© 2011 The Authors. Journal of Neurochemistry © 2011 International Society for Neurochemistry. | 21517843
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Pilocapine alters NMDA receptor expression and function in hippocampal neurons: NADPH oxidase and ERK12 mechanisms. Di Maio R, Mastroberardino PG, Hu X, Montero L, Greenamyre JT Neurobiology of disease
42
482-95. Epub 2011 Mar 17.
2010
Show Abstract
The molecular basis for epileptogenesis remains poorly defined, but repeated or prolonged seizures can cause altered hippocampal N-methyl d-aspartate receptor (NMDAR) stoichiometry, loss of hippocampal neurons, and aberrant mossy fiber sprouting. Using the muscarinic receptor 1 (m1R) agonist, pilocarpine (PILO), in hippocampal cell cultures we explored the early sequence of molecular events that occur within 24h of the initial insult and result in altered neuronal function during epileptogenesis. Our findings show that PILO-induced, m1R-mediated, inositol 1,4,5-trisphosphate (IP3) synthesis constitutes an early, crucial biochemical event required for NMDAR hyperactivation and subsequent NADPH oxidase (NOX) activation and NMDAR-independent ERK1/2 phoshorylation. Together, but not separately, NOX activation and ERK1/2 phosphorylation induce alterations in NMDAR stoichiometry through the upregulation of NR1 and NR2B subunits. Lastly, we demonstrated that PILO-mediated oxidative stress alters NMDAR function through the redox modulation of cysteine residues. The in vitro results related to thiol oxidation, NOX activation, ERK1/2 phosphorylation and NMDAR upregulation were confirmed in vivo, 24h after treatment of adult rats with PILO. These results obtained in PILO-treated primary hippocampal neurons - and confirmed in vivo at the same time-point after PILO - provide a better understanding of the early cellular responses during epileptogenesis and identify potential therapeutic targets to prevent development of chronic epilepsy.Copyright © 2011 Elsevier Inc. All rights reserved. | 21397025
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