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.In mammalian brain, the striatum plays a critical role for planning and executing voluntary movements and is also involved in cognitive processes (1). The striatum makes use of a complex network architecture connecting specialized anatomical structures to achieve these highly integrated tasks. It receives projections from primary sensory and motor cortices as well as motor thalamic nuclei and sends projections to downstream basal ganglia structures, thereby influencing the control of cortical and brainstem motor systems (2). In this context, communication within and between brain structures appears as a key element for brain functioning. For cell-to-cell communication, secreted proteins play a pivotal regulatory role. To enter the secretory pathway, it has been long assumed that an N-terminal signal peptide sequence is strictly required. However, recent studies have shown that endoplasmic reticulum- and Golgi-independent or non-classical mechanisms may be responsible for protein secretion (3). The extracellular medium is thus more complex than previously suspected, and its characterization has gained a special interest (4, 5). In silico analyses suggest that mature proteins secreted via classical and non-classical mechanisms share common physicochemical properties (6). In this respect, proteomics is a powerful approach for systematically analyzing proteins present in the extracellular medium (7–9). For neurochemical monitoring of the secretome within the brain, only a few tools provide an appropriate insight into its spatial and temporal dynamics. Microdialysis, in particular, has been shown to be a powerful tool for exploring the extracellular content of the brain in vivo (10–12) and for obtaining vital physiological information that cannot be gleaned from in vitro experiments. The combination of this sampling method with mass spectrometry facilitates investigation of the brain secretome in vivo. However, because of the low concentration of proteins in dialysate, which makes investigations challenging in terms of sensitivity, few studies have combined in vivo brain microdialysis and proteomics/peptidomics analysis (13–16).In this study, to investigate both proteins and peptides secreted in rat striatum, we performed mass spectrometry analysis of microdialysis fluids. Microdialysis of small and large proteins was carried out using various cutoff probes, and the samples were analyzed through proteomics and peptidomics approaches. In addition, we used spectrum counting (17, 18) to measure the relative abundance of secreted proteins and their processed peptides and to study the modulation of these abundances during neuronal depolarization. This approach allowed us to point out the secretion of new neuropeptides, including neurotransmitters.