Discovering new bioactive neuropeptides in the striatum secretome using in vivo microdialysis and versatile proteomics.

The striatum, a major component of the brain basal nuclei, is central for planning and executing voluntary movements and undergoes lesions in neurodegenerative disorders such as Huntington disease. To perform highly integrated tasks, the striatum relies on a complex network of communication within and between brain regions with a key role devoted to secreted molecules. To characterize the rat striatum secretome, we combined in vivo microdialysis together with proteomics analysis of trypsin digests and peptidomics studies of native fragments. This versatile approach, carried out using different microdialysis probes and mass spectrometer devices, allowed evidencing with high confidence the expression of 88 proteins and 100 processed peptides. Their secretory pathways were predicted by in silico analysis. Whereas high molecular weight proteins were mainly secreted by the classical mode (94%), low molecular weight proteins equally used classical and non-classical modes (53 and 47%, respectively). In addition, our results suggested alternative secretion mechanisms not predicted by bioinformatics tools. Based on spectrum counting, we performed a relative quantification of secreted proteins and peptides in both basal and neuronal depolarization conditions. This allowed detecting a series of neuropeptide precursors and a 6-fold increase for neurosecretory protein VGF and proenkephalin (PENK) levels. A focused investigation and a long peptide experiment led to the identification of new secreted non-opioid PENK peptides, referred to as PENK 114-133, PENK 239-260, and PENK 143-185. Moreover we showed that injecting synthetic PENK 114-133 and PENK 239-260 into the striatum robustly increased glutamate release in this region. Thus, the combination of microdialysis and versatile proteomics methods shed new light on the secreted protein repertoire and evidenced novel neuropeptide transmitters.

Pre-synaptic glutamate-induced activation of DA release in the striatum after partial nigral lesion.

The present experiments aimed at understanding the functional link between dopamine (DA) and glutamate (GLU) during the compensatory processes taking place after partial DA denervation. Lesion of the lateral part of substantia nigra in rats using 6-hydroxydopamine resulted in DA denervation of the lateral region of the ipsilateral caudate/putamen complex (CPc) whereas the medial CPc was spared. In vivo voltammetry revealed a large increase of extracellular dopamine (DA(ext)) in the medial CPc both ipsilateral and contralateral to the lesion. In addition, in vivo microdialysis and HPLC-ED revealed a concomitant increase of extracellular glutamate (GLU(ext)) in the ipsilateral medial CPc. Post-lesion chronic treatment with the putative neuroprotectors amantadine, memantine, and riluzole counteracted the tonic increases of DA(ext) and GLU(ext), revealing a possible role of GLU neurotransmission in the DA over-expression. Finally, acute low doses of GBR12909 had no effect on the DA(ext) in sham- operated animals, but dramatically increased DA(ext) in lesioned animals. The data suggest that a partial unilateral nigral lesion induces a bilateral increase of DA turn-over in the non-denervated striata through GLU afferences to the DA terminals.