Rescue of striatal long-term depression by chronic mGlu5 receptor negative allosteric modulation in distinct dystonia models.

An impairment of long-term synaptic plasticity is considered as a peculiar endophenotype of distinct forms of dystonia, a common, disabling movement disorder. Among the few therapeutic options, broad-spectrum antimuscarinic drugs are utilized, aimed at counteracting abnormal striatal acetylcholine-mediated transmission, which plays a crucial role in dystonia pathophysiology. We previously demonstrated a complete loss of long-term synaptic depression (LTD) at corticostriatal synapses in rodent models of two distinct forms of isolated dystonia, resulting from mutations in the TOR1A (DYT1), and GNAL (DYT25) genes. In addition to anticholinergic agents, the aberrant excitability of striatal cholinergic cells can be modulated by group I metabotropic glutamate receptor subtypes (mGlu1 and 5). Here, we tested the efficacy of the negative allosteric modulator (NAM) of metabotropic glutamate 5 (mGlu) receptor, dipraglurant (ADX48621) on striatal LTD. We show that, whereas acute treatment failed to rescue LTD, chronic dipraglurant rescued this form of synaptic plasticity both in DYT1 mice and GNAL rats. Our analysis of the pharmacokinetic profile of dipraglurant revealed a relatively short half-life, which led us to uncover a peculiar time-course of recovery based on the timing from last dipraglurant injection. Indeed, striatal spiny projection neurons (SPNs) recorded within 2 h from last administration showed full expression of synaptic plasticity, whilst the extent of recovery progressively diminished when SPNs were recorded 4-6 h after treatment. Our findings suggest that distinct dystonia genes may share common signaling pathway dysfunction. More importantly, they indicate that dipraglurant might be a potential novel therapeutic agent for this disabling disorder.

Localization and targeting of SCG10 to the trans-Golgi apparatus and growth cone vesicles.

SCG10 is a membrane-associated, microtubule-destabilizing protein of neuronal growth cones. Using immunoelectron microscopy, we show that in the developing cortex of mice, SCG10 is specifically localized to the trans face Golgi complex and apparently associated with vesicular structures in putative growth cones. Consistent with this, subcellular fractionation of rat forebrain extracts demonstrates that the protein is enriched in the fractions containing the Golgi apparatus and growth cone particles. In isolated growth cone particles, SCG10 was found to be particularly concentrated in the growth cone vesicle fraction. To evaluate the molecular determinants of the specific targeting of SCG10 to growth cones, we have transfected PC12 cells and primary neurons in culture with mutant and fusion cDNA constructs. Deletion of the amino-terminal domain or mutations within this domain that prevented palmitoylation at cysteines 22 and 24 abolished Golgi localization as well as growth cone targeting, suggesting that palmitoylation of the amino-terminal domain is a necessary signal for Golgi sorting and possibly transport of SCG10 to growth cones. Fusion proteins consisting of the amino-terminal domain of SCG10 and the cytosolic proteins stathmin or glutathione-S-transferase colocalized with a Golgi marker, alpha-mannosidase II, and accumulated in growth cones of both axons and dendrites. These results reveal a novel axonal/dendritic growth cone targeting sequence that involves palmitoylation.

Identification of in vitro phosphorylation sites in the growth cone protein SCG10. Effect Of phosphorylation site mutants on microtubule-destabilizing activity.

SCG10 is a neuron-specific, membrane-associated protein that is highly concentrated in growth cones of developing neurons. Previous studies have suggested that it is a regulator of microtubule dynamics and that it may influence microtubule polymerization in growth cones. Here, we demonstrate that in vivo, SCG10 exists in both phosphorylated and unphosphorylated forms. By two-dimensional gel electrophoresis, two phosphoisoforms were detected in neonatal rat brain. Using in vitro phosphorylated recombinant protein, four phosphorylation sites were identified in the SCG10 sequence. Ser-50 and Ser-97 were the target sites for protein kinase A, Ser-62 and Ser-73 for mitogen-activated protein kinase and Ser-73 for cyclin-dependent kinase. We also show that overexpression of SCG10 induces a disruption of the microtubule network in COS-7 cells. By expressing different phosphorylation site mutants, we have dissected the roles of the individual phosphorylation sites in regulating its microtubule-destabilizing activity. We show that nonphosphorylatable mutants have increased activity, whereas mutants in which phosphorylation is mimicked by serine-to-aspartate substitutions have decreased activity. These data suggest that the microtubule-destabilizing activity of SCG10 is regulated by phosphorylation, and that SCG10 may link signal transduction of growth or guidance cues involving serine/threonine protein kinases to alterations of microtubule dynamics in the growth cone.

Purification, characterization, and in vitro phosphorylation of the neuron-specific membrane-associated protein SCG10.

SCG10 is a neuron-specific, developmentally regulated protein which is highly enriched in growth cones. Sequence homology indicates that it is related to the phosphoprotein stathmin or Op18, an in vitro and in vivo substrate for several serine/threonine kinases which are involved in a variety of signaling pathways. As a first step to examine the biochemical properties of SCG10, the protein was expressed in Escherichia coli and purified to apparent homogeneity. The purified protein was used in in vitro phosphorylation assays. SCG10 was phosphorylated by MAP kinase, cAMP-dependent protein kinase, cGMP-dependent protein kinase, p34cdc2 kinase, DNA-dependent protein kinase, Ca2+/calmodulin kinase II, and casein kinase II. The protein was not a substrate for casein kinase I and protein kinase C. SCG10 was phosphorylated by src tyrosine kinase, which demonstrates that the protein can be phosphorylated in vitro on a tyrosine residue. Our data suggest that SCG10 is a phosphoprotein which might be involved in signal transduction in neurons.

Expression, purification, and characterization of a highly soluble N-terminal-truncated form of the neuron-specific membrane-associated phosphoprotein SCG10.

SCG10 is a neuron-specific growth-associated protein with high sequence homology to the ubiquitous phosphoprotein stathmin/Op18. The main structural difference between the two proteins is the 34-amino-acid N-terminal extension of SCG10, which is responsible for the membrane attachment. Full length SCG10 has been purified and shows limited solubility, in contrast to stathmin, which is a highly soluble protein. In order to obtain a more soluble form of SCG10 which would be better suited for biochemical and structural studies, we deleted the N-terminal extension and expressed the C-terminal portion of the protein. Two forms of N-terminal-truncated SCG10 (delta SCG10 and delta SCG10r) were purified to homogeneity in a four-step purification procedure. delta SCG10 starts at amino acid 35 and delta SCG10r at amino acid 48 in the SCG10 sequence, giving proteins of 16,899 and 15,189 kDa, respectively. The truncated SCG10 was highly soluble up to concentrations of 20 mg/ml. The proteins were like the full length SCG10 substrate for serine/threonine protein kinases, including MAP kinase, PKA, and p34cdc2 kinase. With these highly soluble forms of SCG10 biochemical and structural studies of this multiphosphoprotein become feasible.

Targeting of SCG10 to the area of the Golgi complex is mediated by its NH2-terminal region.

SCG10 is a neuronal growth-associated protein that is concentrated in the growth cones of developing neurons. SCG10 shows a high degree of sequence homology to the ubiquitous phosphoprotein stathmin, which has been recently identified as a factor that destabilizes microtubules by increasing their catastrophe rate. Whereas stathmin is a soluble cytosolic protein, SCG10 is membrane-associated, indicating that the protein acts in a distinct subcellular compartment. Identifying the precise intracellular distribution of SCG10 as well as the mechanisms responsible for its specific targeting will contribute to elucidating its function. The main structural feature distinguishing the two proteins is that SCG10 contains an NH2-terminal extension of 34 amino acids. In this study, we have examined the intracellular distribution of SCG10 in PC12 cells and in transfected COS-7 cells and the role of the NH2-terminal domain in membrane-binding and intracellular targeting. SCG10 was found to be localized to the Golgi complex region. We show that the NH2-terminal region (residues 1-34) was necessary for membrane targeting and Golgi localization. Fusion proteins consisting of the NH2-terminal 34 amino acids of SCG10 and the related protein stathmin or the unrelated protein, beta-galactosidase, accumulated in the Golgi, demonstrating that this sequence was sufficient for Golgi localization. Biosynthetic labeling of transfected COS-7 cells with [3H]palmitic acid revealed that two cysteine residues contained within the NH2-terminal domain were sites of palmitoylation.

Regulation of microtubule dynamics by the neuronal growth-associated protein SCG10.

Dynamic assembly and disassembly of microtubules is essential for cell division, cell movements, and intracellular transport. In the developing nervous system, microtubule dynamics play a fundamental role during neurite outgrowth, elongation, and branching, but the molecular mechanisms involved are unknown. SCG10 is a neuron-specific protein that is membrane-associated and highly enriched in growth cones. Here we show that SCG10 binds to microtubules, inhibits their assembly, and can induce microtubule disassembly. We also show that SCG10 overexpression enhances neurite outgrowth in a stably transfected neuronal cell line. These data identify SCG10 as a key regulator of neurite extension through regulation of microtubule instability.

Differential distribution of stathmin and SCG10 in developing neurons in culture.

The neuron-specific protein SCG10 and the ubiquitous protein stathmin are two members of a family of microtubule-destabilizing factors that may regulate microtubule dynamics in response to extracellular signals. To gain insight into the function of these proteins in the nervous system, we have compared their intracellular distribution in cortical neurons developing in culture. We have used double-immunofluorescence microscopy with specific antibodies for stathmin and SCG10 in combination with antibodies for axonal, microtubule, and synaptic marker proteins. Stathmin and SCG10 were coexpressed in individual neurons. While both proteins were highly expressed in developing cultures during differentiation, their subcellular localization was strikingly different. Stathmin showed a cytosolic distribution, mainly in cell bodies, whereas SCG10 strongly labeled the growth cones of axons and dendrites. During neurite outgrowth, SCG10 appeared as a single concentrated spot in a region of the growth cone where the microtubules are known to be particularly dynamic. Disassembly of labile microtubules by nocodazole caused a dispersal of the SCG10 staining into punctate structures, indicating that its subcellular localization is microtubule-dependent. Upon maturation and synapse formation, the levels of both stathmin and SCG10 decreased to become undetectable. These observations demonstrate that the expression of both proteins is associated with neurite outgrowth and suggest that they perform their roles in this process in distinct subcellular compartments.