jMutations in the leucine-rich repeat kinase 2 gene (LRRK2) are associated with familial and sporadic Parkinson's disease (PD). LRRK2 is a complex protein that consists of multiple domains, including predicted C-terminal WD40 repeats. In this study, we analyzed functional and molecular features conferred by the WD40 domain. Electron microscopic analysis of the purified LRRK2 C-terminal domain revealed doughnut-shaped particles, providing experimental evidence for its WD40 fold. We demonstrate that LRRK2 WD40 binds and sequesters synaptic vesicles via interaction with vesicle-associated proteins. In fact, a domain-based pulldown approach combined with mass spectrometric analysis identified LRRK2 as being part of a highly specific protein network involved in synaptic vesicle trafficking. In addition, we found that a C-terminal sequence variant associated with an increased risk of developing PD, G2385R, correlates with a reduced binding affinity of LRRK2 WD40 to synaptic vesicles. Our data demonstrate a critical role of the WD40 domain within LRRK2 function. Parkinson's disease (PD) is the second most common age-related neurodegenerative disease and is clinically characterized by movement impairments, bradykinesia, rigidity, and resting tremor and pathologically by the progressive loss of dopaminergic neurons in the substantia nigra and the formation of Lewy bodies (1, 2). Although the majority of cases are sporadic, mutations in the leucine-rich repeat kinase 2 (LRRK2) gene (PARK8; Online Mendelian Inheritance in Man [OMIM] accession number 609007) had been unequivocally linked to late-onset autosomal dominant PD. LRRK2 mutations account for up to 13% of familial PD cases compatible with dominant inheritance and are also found in 1 to 2% of sporadic PD patients (62-64). LRRK2 is a complex 286-kDa protein that consists of multiple domains, including (in order, from the amino to carboxyl terminus) armadillo, ankyrin, and the namesake leucine-rich repeats (LRRs), followed by an ROC (Ras of complex proteins) GTPase domain, a COR (C-terminal of ROC) dimerization domain, a kinase domain, and a predicted C-terminal WD40 repeat domain (4-6). Several single-nucleotide alterations have been identified in LRRK2, but only five missense mutations within the ROC, COR, and kinase domains clearly segregate with PD in large family studies (7,8). It has recently been shown that the WD40 domain is required to stabilize the LRRK2 dimer and to execute LRRK2-associated kinase activity as well as neurotoxicity (9, 10), but the role of this domain within LRRK2 physiological and pathological function has not yet been completely defined. The beta-propellerforming WD40 domains are among the 10 most abundant domain types across eukaryotic proteomes (11) and constitute platforms where multiprotein complexes assemble reversibly (12). Here, we systematically analyzed the protein-protein interactions conferred by the LRRK2 WD40 domain. The nature of the LRRK2 WD40 interactors and the finding that the LRRK2 WD40 domain is able to bind to synaptic...
Leucine-rich repeat kinase 2 (LRRK2) is a causative gene for Parkinson's disease but the physiological function and the mechanism(s) by which the cellular activity of LRRK2 is regulated are poorly understood. Here, we identified p21-activated kinase 6 (PAK6) as a novel interactor of the GTPase/ROC domain of LRRK2. PAKs are serine-threonine kinases that serve as targets for the small GTP binding proteins Cdc42 and Rac1 and have been implicated in different morphogenetic processes through remodeling of the actin cytoskeleton such as synapse formation and neuritogenesis. Using an in vivo neuromorphology assay, we show that PAK6 is a positive regulator of neurite outgrowth and that LRRK2 is required for this function. Analyses of post-mortem brain tissue from idiopathic and LRRK2 G2019S carriers reveal an increase in PAK6 activation state, whereas knock-out LRRK2 mice display reduced PAK6 activation and phosphorylation of PAK6 substrates. Taken together, these results support a critical role of LRRK2 GTPase domain in cytoskeletal dynamics in vivo through the novel interactor PAK6, and provide a valuable platform to unravel the mechanism underlying LRRK2-mediated pathophysiology.
Mutations in Leucine-rich repeat kinase 2 gene (LRRK2) are associated with familial and sporadic Parkinson's disease (PD). LRRK2 is a complex protein that consists of multiple domains executing several functions, including GTP hydrolysis, kinase activity, and protein binding. Robust evidence suggests that LRRK2 acts at the synaptic site as a molecular hub connecting synaptic vesicles to cytoskeletal elements via a complex panel of protein-protein interactions. Here we investigated the impact of pharmacological inhibition of LRRK2 kinase activity on synaptic function. Acute treatment with LRRK2 inhibitors reduced the frequency of spontaneous currents, the rate of synaptic vesicle trafficking and the release of neurotransmitter from isolated synaptosomes. The investigation of complementary models lacking LRRK2 expression allowed us to exclude potential off-side effects of kinase inhibitors on synaptic functions. Next we studied whether kinase inhibition affects LRRK2 heterologous interactions. We found that the binding among LRRK2, presynaptic proteins and synaptic vesicles is affected by kinase inhibition. Our results suggest that LRRK2 kinase activity influences synaptic vesicle release via modulation of LRRK2 macro-molecular complex.
A complex and still not comprehensively resolved panel of transmembrane proteins regulates the outgrowth and the subsequent morphological and functional development of neuronal processes. In order to gain a more detailed description of these events at the molecular level, we have developed a cell surface biotinylation assay to isolate, detect, and quantify neuronal membrane proteins. When we applied our assay to investigate neuron maturation in vitro, we identified 439 differentially expressed proteins, including 20 members of the immunoglobulin superfamily. Among these candidates, we focused on Negr1, a poorly described cell adhesion molecule. We demonstrated that Negr1 controls the development of neurite arborization in vitro and in vivo. Given the tight correlation existing among synaptic cell adhesion molecules, neuron maturation, and a number of neurological disorders, our assay results are a useful tool that can be used to support the understanding of the molecular bases of physiological and pathological brain function. Genetic analysis indicates that 20% to 30% of the total open reading frame encodes for integral membrane proteins (1). Although less abundant than cytosolic proteins, membrane-passing proteins contribute to the regulation of all major cell processes and signaling pathways. In particular, membrane proteins play an important role in the establishment of functional neuronal circuitries during development. This process initially entails the growth, guidance, and stabilization of neuronal processes (axons and dendrites) in a timely, ordered manner involving cell surface molecules that sense the extracellular surroundings and activate signaling cascades (2).Then, specialized cell-to-cell connections, the synapses, are formed. These connections allow information to flow from one neuron to another and relay the precise juxtaposition and interactions between the pre-and postsynaptic membrane proteins to support their final functional establishment. Several families of synaptic transmembrane or membrane proteins, such as semaphorin, neuroligin, neurexin, and the immunoglobulin superfamily (IgSF), 1 are implicated in neurite formation and synapse establishment (3). However, the picture of membrane proteins expressed in neurons is still far from being completely resolved, and it is expected that many other key molecules are awaiting identification (4). Thus, uncovering the nature of the dynamic multiprotein complexes expressed at the plasma membrane will possibly strongly support the understanding of the mechanism controlling structural and functional neuron development. Here, we describe a biochemical approach to isolate and quantify proteins exposed at the extracellular side of the plasma membrane. Our assay utilized affinity purification on streptavidin resin of biotinylated membrane proteins extracted from a crude synaptosomal preparation. We combined this cell surface biotinylation assay with MS/MS analysis and label-free quantification to investigate protein patterns characterizing immature and m...
The GABAergic medium-size spiny neuron (MSN), the striatal output neuron, may be classified into striosome, also known as patch, and matrix, based on neurochemical differences between the two compartments. At this time, little is known regarding the regulation of the development of the two compartments. Nr4a1, primarily described as a nuclear receptor/immediate early gene involved in the homeostasis of the dopaminergic system, is a striosomal marker. Using Nr4a1-overexpressing and Nr4a1-null mice, we sought to determine whether Nr4a1 is necessary and/or sufficient for striosome development. We report that in vivo and in vitro, Nr4a1 and Oprm1 mRNA levels are correlated. In the absence of Nr4a, there is a decrease in the percentage of striatal surface area occupied by striosomes. Alterations in Nr4a1 expression leads to dysregulation of multiple mRNAs of members of the dopamine receptor D1 signal transduction system. Constitutive overexpression of Nr4a1 decreases both the induction of phosphorylation of ERK after a single cocaine exposure and locomotor sensitization following chronic cocaine exposure. Nr4a1 overexpression increases MSN excitability but reduces MSN long-term potentiation. In the resting state, type 5 adenylyl cyclase (AC5) activity is normal, but the ability of AC5 to be activated by Drd1 G-protein-coupled receptor inputs is decreased. Our results support a role for Nr4a1 in determination of striatal patch/matrix structure and in regulation of dopaminoceptive neuronal function.
Parkinson’s disease is characterized by the progressive degeneration of dopaminergic neurons within the substantia nigra pars compacta and the presence of protein aggregates in surviving neurons. The LRRK2 G2019S mutation is one of the major determinants of familial Parkinson’s disease cases and leads to late-onset Parkinson’s disease with pleomorphic pathology, including α-synuclein accumulation and deposition of protein inclusions. We demonstrated that LRRK2 phosphorylates N-ethylmaleimide sensitive factor (NSF). We observed aggregates containing NSF in basal ganglia specimens from patients with Parkinson’s disease carrying the G2019S variant, and in cellular and animal models expressing the LRRK2 G2019S variant. We found that LRRK2 G2019S kinase activity induces the accumulation of NSF in toxic aggregates. Of note, the induction of autophagy cleared NSF aggregation and rescued motor and cognitive impairment observed in aged hG2019S bacterial artificial chromosome (BAC) mice. We suggest that LRRK2 G2019S pathological phosphorylation impacts on NSF biochemical properties, thus causing the formation of cytotoxic protein inclusions.
Levodopa (L-DOPA)-induced dyskinesias (LIDs) represent the major side effect in Parkinson’s disease (PD) therapy. Leucine-rich repeat kinase 2 (LRRK2) mutations account for up to 13 % of familial cases of PD. LRRK2 N-terminal domain encompasses several serine residues that undergo phosphorylation influencing LRRK2 function. This work aims at investigating whether LRRK2 phosphorylation/function may be involved in the molecular pathways downstream D1 dopamine receptor leading to LIDs. Here we show that LRRK2 phosphorylation level at serine 935 correlates with LIDs induction and that inhibition of LRRK2 induces a significant increase in the dyskinetic score in L-DOPA treated parkinsonian animals. Our findings support a close link between LRKK2 functional state and L-DOPA-induced abnormal motor behaviour and highlight that LRRK2 phosphorylation level may be implicated in LIDs, calling for novel therapeutic strategies.
Background Similar to some monogenic forms of dystonia, levodopa‐induced dyskinesia is a hyperkinetic movement disorder with abnormal nigrostriatal dopaminergic neurotransmission. Molecularly, it is characterized by hyper‐induction of phosphorylation of extracellular signal‐related kinase in response to dopamine in medium spiny neurons of the direct pathway. Objectives The objective of this study was to determine if mouse models of monogenic dystonia exhibit molecular features of levodopa‐induced dyskinesia. Methods Western blotting and quantitative immunofluorescence was used to assay baseline and/or dopamine‐induced levels of the phosphorylated kinase in the striatum in mouse models of DYT1, DYT6, and DYT25 expressing a reporter in dopamine D1 receptor‐expressing projection neurons. Cyclic adenosine monophosphate (cAMP) immunoassay and adenylyl cyclase activity assays were also performed. Results In DYT1 and DYT6 models, blocking dopamine reuptake with cocaine leads to enhanced extracellular signal‐related kinase phosphorylation in dorsomedial striatal medium spiny neurons in the direct pathway, which is abolished by pretreatment with the N‐methyl‐d‐aspartate antagonist MK‐801. Phosphorylation is decreased in a model of DYT25. Levels of basal and stimulated cAMP and adenylyl cyclase activity were normal in the DYT1 and DYT6 mice and decreased in the DYT25 mice. Oxotremorine induced increased abnormal movements in the DYT1 knock‐in mice. Conclusions The increased dopamine induction of extracellular signal‐related kinase phosphorylation in 2 genetic types of dystonia, similar to what occurs in levodopa‐induced dyskinesia, and its decrease in a third, suggests that abnormal signal transduction in response to dopamine in the postsynaptic nigrostriatal pathway might be a point of convergence for dystonia and other hyperkinetic movement disorders, potentially offering common therapeutic targets. © 2021 International Parkinson and Movement Disorder Society
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