Amphiphysin I phosphorylation on residue threonine 260 in a pentylenetetrazole-induced seizure model.

A method to evaluate kinase inhibitor action was reported [L. Morgan, S.J. Neame, H. Child, R. Chung, B. Shah, L. Barden, J.M. Staddon, T.R. Patel, Development of a pentylenetetrazole-induced seizure model to evaluate kinase inhibitor efficacy in the central nervous system, Neurosci. Lett. 395 (2006) 143-148]. In this, acute administration of the GABA antagonist pentylenetetrazole triggers seizures through glutamate-dependent pathways. Under such conditions, activation of the c-Jun N-terminal kinase (JNK) pathway was detected in hippocampal extracts. Phosphorylation of the upstream JNK kinase MKK4 was also revealed through use of a phospho-MKK4-specific antibody. Here, this antibody is shown to also react with a protein of approximately 125 kDa which underwent increased phosphorylation in response to pentylenetetrazole treatment. The present study aimed to identify the approximately 125 kDa protein as it may provide novel insight into signalling, neuronal activity and seizures. Using chromatographic methods and mass spectrometry, the protein was identified as amphiphysin I. This was confirmed by 2D gel analysis and immunoblot with amphiphysin I-specific antibodies. Although the phospho-MKK4 antibody was raised against an MKK4-specific peptide, partial sequence homology between this sequence and a region of amphiphysin was discerned. New antibodies raised against the phospho-threonine 260-amphiphysin-specific sequence detected increased phosphorylation in response to pentylenetetrazole treatment. This particular phosphorylation site does not seem to have been described before, possibly reflecting a novel regulatory aspect of amphiphysin biology. As amphiphysin is involved in the regulation of endocytosis, phosphorylation at this site may play a role in the regulated re-uptake of synaptic vesicles after neurotransmitter release.

Development of a pentylenetetrazole-induced seizure model to evaluate kinase inhibitor efficacy in the central nervous system.

c-Jun N-terminal kinases (JNKs) are implicated in cell death in neurodegenerative disorders. Therefore, JNK inhibitors could act as neuroprotective agents. To evaluate potential candidates, reproducible and quantitative CNS in vivo models are required. To that end, a pentylenetetrazole-induced seizure model was explored. c-Jun phosphorylation was detected in hippocampal extracts by blotting c-Jun immunoprecipitates with phosphorylation-specific antibodies. Pentylenetetrazole administration induced rapid and reproducible increases in c-Jun phosphorylation. However, special attention had to be paid to the composition of the extraction buffer to ensure stabilization of protein phosphorylation, as demonstrated using internal standards of phosphorylated recombinant c-Jun. As JNK and its upstream activator MKK4 are activated by phosphorylation, these events were also evaluated. In principle, kinase inhibitors could act at the level of JNK or upstream kinases to inhibit c-Jun phosphorylation. MKK4 phosphorylation was dramatically increased in response to pentylenetetrazole but, again, only when appropriate phosphatase inhibitors were in the extraction buffer. In contrast, JNK was found to be constitutively phosphorylated and unaltered upon pentylenetetrazole treatment. The JNK inhibitor SP600125 was shown to inhibit c-Jun phosphorylation without affecting MKK4 phosphorylation. Our procedures enable analysis of JNK pathway signalling in a CNS model and, also, should be applicable to that of other protein phosphorylation events in vivo.