Dimeric structures of α-synuclein bind preferentially to lipid membranes

There is substantial evidence which implicates α-synuclein and its ability to aggregate and bind vesicle membranes as critical factors in the development of Parkinson's disease. In order to investigate the interaction between α-synuclein wild type (Wt) and its familial mutants, A53T and A30P with lipid membranes, we developed a novel lipid binding assay using surface enhanced laser desorption/ionisation-time of flight-mass spectrometry (SELDI-TOF MS). Wt and A53T exhibited similar lipid binding profiles; monomeric species and dimers bound with high relative affinity to the lipid surface, the latter of which exhibited preferential binding. Wt and A53T trimers and tetramers were also detected on the lipid surface. A30P exhibited a unique lipid binding profile; monomeric A30P bound with a low relative affinity, however, the dimeric species of A30P exhibited a higher binding ability. Larger order A30P oligomers were not detected on the lipid surface. Tapping mode atomic force microscopy (AFM) imaging was conducted to further examine the α-synuclein-lipid interaction. AFM analysis revealed Wt and its familial mutants can penetrate lipid membranes or disrupt the lipid and bind the hydrophobic alkyl self-assembled monolayer (SAM) used to form the lipid layer. The profile of these studied proteins revealed the presence of ‘small features’ consistent with the presence of monomeric and dimeric forms of the protein. These data collectively indicate that the dimeric species of Wt and its mutants can bind and cause membrane perturbations.     

Association of alpha-synuclein and mutants with lipid membranes: spin-label ESR and polarized IR

Alpha-synuclein is a presynaptic protein, the A53T and A30P mutants of which are linked independently to early-onset familial Parkinson's disease. The association of wild-type alpha-synuclein with lipid membranes was characterized previously by electron spin resonance (ESR) spectroscopy with spin-labeled lipids [Ramakrishnan, M., Jensen, P. H., and Marsh, D. (2003) Biochemistry 42, 12919-12926]. Here, we study the interaction of the A53T and A30P alpha-synuclein mutants and a truncated form that lacks the acidic C-terminal domain with phosphatidylglycerol bilayer membranes, using anionic phospholipid spin labels. The strength of the interaction with phosphatidylglycerol membranes lies in the order: wild type approximately truncated > A53T > A30P > fibrils approximately 0, and only the truncated form interacts with phosphatidylcholine membranes. The selectivity of the interaction of the mutant alpha-synucleins with different spin-labeled lipid species is reduced considerably, relative to the wild-type protein, whereas that of the truncated protein is increased. Polarized infrared (IR) spectroscopy is used to study the interactions of the wild-type and truncated proteins with aligned lipid membranes and additionally to characterize the fibrillar form. Wild-type alpha-synuclein is natively unfolded in solution and acquires secondary structure upon binding to membranes containing phosphatidylglycerol. Up to 30-40% of the amide I band intensity of the membrane-bound wild-type and truncated proteins is attributable to beta-sheet structure, at the surface densities used for IR spectroscopy. The remainder is alpha-helix and residual unordered structure. Fibrillar alpha-synuclein contains 62% antiparallel beta-sheet and is oriented on the substrate surface but does not interact with deposited lipid membranes. The beta-sheet secondary-structural elements of the wild-type and truncated proteins are partially oriented on the surface of membranes with which they interact.     

alpha-Synuclein-synaptosomal membrane interactions: implications for fibrillogenesis.

alpha-Synuclein exists in two different compartments in vivo-- correspondingly existing as two different forms: a membrane-bound form that is predominantly alpha-helical and a cytosolic form that is randomly structured. It has been suggested that these environmental and structural differences may play a role in aggregation propensity and development of pathological lesions observed in Parkinson's disease (PD). Such effects may be accentuated by mutations observed in familial PD kindreds. In order to test this hypothesis, wild-type and A53T mutant alpha-synuclein interactions with rat brain synaptosomal membranes were examined. Previous data has demonstrated that the A30P mutant has defective lipid binding and therefore was not examined in this study. Electron microscopy demonstrated that wild-type alpha-synuclein fibrillogenesis is accelerated in the presence of synaptosomal membranes whereas the A53T alpha-synuclein fibrillogenesis is inhibited under the same conditions. These results suggested that subtle sequence changes in alpha-synuclein could significantly alter interaction with membrane bilayers. Fluorescence and absorption spectroscopy using environment sensitive probes demonstrated variations in the inherent lipid properties in the presence and absence of alpha-synuclein. Addition of wild-type alpha-synuclein to synaptosomes did not significantly alter the membrane fluidity at either the fatty acyl chains or headgroup space, suggesting that synaptosomes have a high capacity for alpha-synuclein binding. In contrast, synaptosomal membrane fluidity was decreased by A53T alpha-synuclein binding with concomitant packing of the lipid headgroups. These results suggest that alterations in alpha-synuclein-lipid interactions may contribute to physiological changes detected in early onset PD.     

Defective membrane interactions of familial Parkinson's disease mutant A30P alpha-synuclein.

alpha-Synuclein (alpha-Syn) is an abundant presynaptic protein of unknown function, which has been implicated in the pathogenesis of Parkinson's disease. Alpha-Syn has been suggested to play a role in lipid transport and synaptogenesis, and growing evidence suggests that alpha-Syn interactions with cellular membranes are physiologically important. In the current study, we demonstrate that the familial Parkinson's disease-linked A30P mutant alpha-Syn is defective in binding to phospholipid vesicles in vitro as determined by vesicle ultracentrifugation, circular dichroism spectroscopy, and low-angle X-ray diffraction. Interestingly, our data also suggest that alpha-Syn may bind to the lipid vesicles as a dimer, which suggest that this species could be a physiologically relevant and functional entity. In contrast, the naturally occurring murine A53T substitution, which is also linked to Parkinson's disease, displayed a normal membrane-binding activity that was comparable to wild-type alpha-Syn. A double mutant A53T/A30P alpha-Syn showed defective membrane binding similar to the A30P protein, indicating that the proline mutation is dominant in terms of impairing the membrane-binding activity. With these observations, we suggest that the A53T and A30P mutants may have different physiological consequences in vivo and could possibly contribute to early onset Parkinson's disease via unique mechanisms.     

Effect of familial Parkinson's disease point mutations A30P and A53T on the structural properties, aggregation, and fibrillation of human alpha-synuclein

Parkinson's disease involves the loss of dopaminergic neurons in the substantia nigra, leading to movement disorders. The pathological hallmark of Parkinson's disease is the presence of Lewy bodies and Lewy neurites, which are intracellular inclusions consisting primarily of alpha-synuclein. Although essentially all cases of sporadic and early-onset Parkinson's disease are of unknown etiology, two point mutations (A53T and A30P) in the alpha-synuclein gene have been identified in familial early-onset Parkinson's disease. Previous reports have shown that mutant alpha-synuclein may form fibrils more rapidly than wild-type protein. To determine the underlying molecular basis for the enhanced fibrillation of the mutants, the structural properties, responses to changes in the environment, and propensity to aggregate of wild-type, A30P, and A53T alpha-synucleins were systematically investigated. A variety of biophysical methods, including far-UV circular dichroism, FTIR, small-angle X-ray scattering, and light scattering, were employed. Neither the natively unfolded nor the partially folded intermediate conformations are affected by the familial Parkinson's disease point mutations. However, both mutants underwent self-association more readily than the wild type (i.e., at much lower protein concentration and more rapidly). We attribute this effect to the increased propensity of their partially folded intermediates to aggregate, rather than to any changes in the monomeric natively unfolded species. This increased propensity of these mutants to aggregate, relative to wild-type alpha-synuclein, would account for the correlation of these mutations with Parkinson's disease.     

Familial mutants of alpha-synuclein with increased neurotoxicity have a destabilized conformation

A30P and A53T mutations of the presynaptic protein alpha-synuclein are associated with familial forms of Parkinson disease. NMR spectroscopy demonstrates that Parkinsonism-linked mutations greatly perturb specific tertiary interactions essential for the native state of alpha-synuclein. However, alpha-synuclein is not completely unfolded but exhibits structural fluctuations on the time scale of secondary structure formation and loses its native conformation gradually when protein stability decreases. The redistribution of the ensemble of alpha-synuclein conformers may underlie toxic gain-of-function by fostering self-association and altered binding affinity to ligands and receptors.     

A combinatorial code for the interaction of alpha-synuclein with membranes

Considerable genetic and pathological evidence has implicated the small, soluble protein alpha-synuclein in the pathogenesis of familial and sporadic forms of Parkinsons disease (PD). However, the precise role of alpha-synuclein in the disease process as well as its normal function remain poorly understood. We recently found that an interaction with lipid rafts is crucial for the normal, pre-synaptic localization of alpha-synuclein. To understand how alpha-synuclein interacts with lipid rafts, we have now developed an in vitro binding assay to rafts purified from native membranes. Recapitulating the specificity observed in vivo, recombinant wild type but not PD-associated A30P mutant alpha-synuclein binds to lipid rafts isolated from cultured cells and purified synaptic vesicles. Proteolytic digestion of the rafts does not disrupt the binding of alpha-synuclein, indicating an interaction with lipid rather than protein components of these membranes. We have also found that alpha-synuclein binds directly to artificial membranes whose lipid composition mimics that of lipid rafts. The binding of alpha-synuclein to these raft-like liposomes requires acidic phospholipids, with a preference for phosphatidylserine (PS). Interestingly, a variety of synthetic PS with defined acyl chains do not support binding when used individually. Rather, the interaction with alpha-synuclein requires a combination of PS with oleic (18:1) and polyunsaturated (either 20:4 or 22:6) fatty acyl chains, suggesting a role for phase separation within the membrane. Furthermore, alpha-synuclein binds with higher affinity to artificial membranes with the PS head group on the polyunsaturated fatty acyl chain rather than on the oleoyl side chain, indicating a stringent combinatorial code for the interaction of alpha-synuclein with membranes.     

alpha-Synuclein membrane interactions and lipid specificity

With the discovery of missense mutations (A53T and A30P) in alpha-synuclein (alpha-Syn) in several families with early onset familial Parkinson's disease, alpha-Syn aggregation and fibril formation have been thought to play a role in the pathogenesis of alpha-synucleinopathies, such as Parkinson's disease, dementia with Lewy bodies, and multiple system atrophy. As previous reports have suggested that alpha-Syn plays a role in lipid transport and synaptic membrane biogenesis, we investigated whether alpha-Syn binds to a specific lipid ligand using thin layer chromatography overlay and examined the changes in its secondary structure using circular dichroism spectroscopy. alpha-Syn was found to bind to acidic phospholipid vesicles and this binding was significantly augmented by the presence of phosphatidylethanolamine, a neutral phospholipid. We further examined the interaction of alpha-Syn with lipids by in situ atomic force microscopy. The association of soluble wild-type alpha-Syn with planar lipid bilayers resulted in extensive bilayer disruption and the formation of amorphous aggregates and small fibrils. The A53T mutant alpha-Syn disrupted the lipid bilayers in a similar fashion but at a slower rate. These results suggest that alpha-Syn membrane interactions are physiologically important and the lipid composition of the cellular membranes may affect these interactions in vivo.     

Helical alpha-synuclein forms highly conductive ion channels

Alpha-synuclein (alphaS) is a cytosolic protein involved in the etiology of Parkinson's disease (PD). Disordered in an aqueous environment, alphaS develops a highly helical conformation when bound to membranes having a negatively charged surface and a large curvature. It exhibits a membrane-permeabilizing activity that has been attributed to oligomeric protofibrillar forms. In this study, monomeric wild-type alphaS and two mutants associated with familial PD, E46K and A53T, formed ion channels with well-defined conductance states in membranes containing 25-50% anionic lipid and 50% phosphatidylethanolamine (PE) in the presence of a trans-negative potential. Another familial mutant, A30P, known to have a lower membrane affinity, did not form ion channels. Ca2+ prevented channel formation when added to membranes before alphaS and decreased channel conductance when added to preformed channels. In contrast to the monomer, membrane permeabilization by oligomeric alphaS was not characterized by formation of discrete channels, a requirement for PE lipid, or a membrane potential. Channel activity, alpha-helical content, thermal stability of membrane-bound alphaS determined by far-UV CD, and lateral mobility of alphaS bound to planar membranes measured by fluorescence correlation spectroscopy were correlated. It was inferred that discrete ion channels with well-defined conductance states were formed in the presence of a membrane potential by one or several molecules of monomeric alphaS in an alpha-helical conformation and that such channels may have a role in the normal function and/or pathophysiology of the protein.     

Inhibition of fibrillization and accumulation of prefibrillar oligomers in mixtures of human and mouse alpha-synuclein

Parkinson's disease (PD) is a neurodegenerative disorder attributed to the loss of dopaminergic neurons from the substantia nigra. Some surviving neurons are characterized by cytoplasmic Lewy bodies, which contain fibrillar alpha-synuclein. Two mutants of human alpha-synuclein (A53T and A30P) have been linked to early-onset, familial PD. Oligomeric forms of these mutants accumulate more rapidly and/or persist for longer periods of time than oligomeric, human wild-type alpha-synuclein (WT), suggesting a link between oligomerization and cell death. The amino acid sequences of the mouse protein and WT differ at seven positions. Mouse alpha-synuclein, like A53T, contains a threonine residue at position 53. We have assessed the conformational properties and fibrillogenicity of the murine protein. Like WT and the two PD mutants, mouse alpha-synuclein adopts a "natively unfolded" or disordered structure. However, at elevated concentrations, the mouse protein forms amyloid fibrils more rapidly than WT, A53T, or A30P. The fibrillization of mouse alpha-synuclein is slowed by WT and A53T. Inhibition of fibrillization leads to the accumulation of nonfibrillar, potentially toxic oligomers. The results are relevant to the interpretation of the phenotypes of transgenic animal models of PD and suggest a novel approach for testing the cause and effect relationship between fibrillization and neurodegeneration.     

Mutation E46K increases phospholipid binding and assembly into filaments of human alpha-synuclein

Missense mutations (A30P and A53T) in alpha-synuclein and the overproduction of the wild-type protein cause familial forms of Parkinson's disease and dementia with Lewy bodies. Alpha-synuclein is the major component of the filamentous Lewy bodies and Lewy neurites that define these diseases at a neuropathological level. Recently, a third missense mutation (E46K) in alpha-synuclein was described in an inherited form of dementia with Lewy bodies. Here, we have investigated the functional effects of this novel mutation on phospholipid binding and filament assembly of alpha-synuclein. When compared to the wild-type protein, the E46K mutation caused a significantly increased ability of alpha-synuclein to bind to negatively charged liposomes, unlike the previously described mutations. The E46K mutation increased the rate of filament assembly to the same extent as the A53T mutation. Filaments formed from E46K alpha-synuclein often had a twisted morphology with a cross-over spacing of 43 nm. The observed effects on lipid binding and filament assembly may explain the pathogenic nature of the E46K mutation in alpha-synuclein.     

GM1 specifically interacts with alpha-synuclein and inhibits fibrillation

The aggregation of alpha-synuclein is believed to be a key step in the etiology of Parkinson's disease. Alpha-synuclein is found in the cytosol and is associated with membranes in the presynaptic region of neurons and has recently been reported to be associated with lipid rafts and caveolae. We examined the interactions between several brain sphingolipids and alpha-synuclein and found that alpha-synuclein specifically binds to ganglioside GM1-containing small unilamellar vesicles (SUVs). This results in the induction of substantial alpha-helical structure and inhibition or elimination of alpha-synuclein fibril formation, depending on the amount of GM1 present. SUVs containing total brain gangliosides, gangliosides GM2 or GM3, or asialo-GM1 had weak inhibitory effects on alpha-synuclein fibrillation and induced some alpha-helical structure, while all other sphingolipids studied showed negligible interaction with alpha-synuclein. alpha-Synuclein binding to GM1-containing SUVs was accompanied by formation of oligomers of alpha-synuclein. The familial mutant A53T alpha-synuclein interacted with GM1-containing SUVs in an analogous manner to wild type, whereas the A30P mutant showed minimal interaction. This is the first detailed report showing a direct association between GM1 and alpha-synuclein, which is attributed to specific interaction between helical alpha-synuclein and both the sialic acid and carbohydrate moieties of GM1. The recruitment of alpha-synuclein by GM1 to caveolae and lipid raft regions in membranes could explain alpha-synuclein's localization to presynaptic membranes and raises the possibility that perturbation of GM1/raft association could induce changes in alpha-synuclein that contribute to the pathogenesis of PD.     

Defects in very long chain fatty acid synthesis enhance alpha-synuclein toxicity in a yeast model of Parkinson's disease

We identified three S. cerevisiae lipid elongase null mutants (elo1Δ, elo2Δ, and elo3Δ) that enhance the toxicity of alpha-synuclein (α-syn). These elongases function in the endoplasmic reticulum (ER) to catalyze the elongation of medium chain fatty acids to very long chain fatty acids, which is a component of sphingolipids. Without α-syn expression, the various elo mutants showed no growth defects, no reactive oxygen species (ROS) accumulation, and a modest decrease in survival of aged cells compared to wild-type cells. With (WT, A53T or E46K) α-syn expression, the various elo mutants exhibited severe growth defects (although A30P had a negligible effect on growth), ROS accumulation, aberrant protein trafficking, and a dramatic decrease in survival of aged cells compared to wild-type cells. Inhibitors of ceramide synthesis, myriocin and FB1, were extremely toxic to wild-type yeast cells expressing (WT, A53T, or E46K) α-syn but much less toxic to cells expressing A30P. The elongase mutants and ceramide synthesis inhibitors enhance the toxicity of WT α-syn, A53T and E46K, which transit through the ER, but have a negligible effect on A30P, which does not transit through the ER. Disruption of ceramide-sphingolipid homeostasis in the ER dramatically enhances the toxicity of α-syn (WT, A53T, and E46K).     

Trypsin disrupts the trafficking of the human dopamine transporter by alpha-synuclein and its A30P mutant

Alpha-synuclein modulates dopamine homeostasis in dopamine-producing neurons of substantia nigra, partly through regulation of human dopamine transporter (hDAT) activity. To identify the underlying mechanisms, we disrupted the modulation of hDAT activity by wild-type (wt) alpha-synuclein, and its familial Parkinson's disease linked mutants A30P and A53T, by mild trypsinization (0.1%, 30 s) of Ltk(-) cotransfected cells. Trypsin completely reversed the attenuation of hDAT function mediated by wt and the A30P mutant. In A53T coexpressing cells, where DAT activity is not downregulated, trypsinization did not induce any changes. These effects of trypsin were mimicked by collagenase I and Dispase (0.1%, 1 min each) but not by chymotrypsin, Pronase, or papain (0.1%, up to 2 min each). Trypsin increased dopamine uptake in rat primary mesencephalic neurons, suggesting that DAT activity is also subjected to modulation by alpha-synuclein in these neurons that endogenously coexpress both proteins. In trypsinized cells, dopamine accelerated both production of reactive oxygen species and cell death in hDAT and wt or A30P, but not A53T, coexpressing cells, compared to nontrypsinized cells. Paradoxically, trypsin increased the protein-protein interactions between the synuclein variants and hDAT, without any noticeable proteolysis of these proteins. hDAT-alpha-synuclein protein-protein interactions occurred through residues 58-107 (NAC domain) of the alpha-synuclein variants and residues 598-620 of the carboxy-terminal tail of hDAT, in both trypsinized and nontrypsinized cells. Confocal microscopy and biotinylation studies show that, in cells expressing the wt or A30P variants, but not the A53T mutant, hDAT is sequestered away from the plasma membrane into the cytoplasm, an effect that is reversed by trypsin. These results show that alpha-synuclein modulates hDAT function through trafficking of the transporter in a process that can be disrupted by trypsin.     

Vesicle permeabilization by protofibrillar alpha-synuclein is sensitive to Parkinson's disease-linked mutations and occurs by a pore-like mechanism

Two mutations in the protein alpha-synuclein (A30P and A53T) are linked to an autosomal dominant form of Parkinson's disease. Both mutations accelerate the formation of prefibrillar oligomers (protofibrils) in vitro, but the mechanism by which they promote toxicity is unknown. Protofibrils of wild-type alpha-synuclein bind and permeabilize acidic phospholipid vesicles. This study examines the relative membrane permeabilizing activities of the wild type, mutant, and mouse variants of protofibrillar alpha-synuclein and the mechanism of membrane permeabilization. Protofibrillar A30P, A53T, and mouse variants were each found to have greater permeabilizing activities per mole than the wild-type protein. The leakage of vesicular contents induced by protofibrillar alpha-synuclein exhibits a strong preference for low-molecular mass molecules, suggesting a pore-like mechanism for permeabilization. Under conditions in which the vesicular membrane is less stable (lack of calcium as a phospholipid counterion), protofibril permeabilization is less size-selective and monomeric alpha-synuclein can permeabilize via a detergent-like mechanism. We conclude that the pathogenesis of Parkinson's disease may involve membrane permeabilization by protofibrillar alpha-synuclein, the extent of which will be strongly dependent on the in vivo conditions.     

Alpha-synuclein can function as an antioxidant preventing oxidation of unsaturated lipid in vesicles

Alpha-synuclein, a presynaptic protein associated with Parkinson's disease, is found as both soluble cytosolic and membrane-bound forms. Although the function of alpha-synuclein is unknown, several observations suggest that its association with membranes is important. In the present study we investigated the effect of alpha-synuclein on lipid oxidation in membranes containing phospholipids with unsaturated fatty acids. The kinetics of lipid oxidation were monitored by the change in fluorescence intensity of the dye C11-BODIPY. We find that monomeric alpha-synuclein efficiently prevented lipid oxidation, whereas fibrillar alpha-synuclein had no such effect. Our data suggest that the prevention of unsaturated lipid oxidation by alpha-synuclein requires that it bind to the lipid membrane. The antioxidant function of alpha-synuclein is attributed to its facile oxidation via the formation of methionine sulfoxide, as shown by mass spectrometry. These findings suggest that the inhibition of lipid oxidation by alpha-synuclein may be a physiological function of the protein.     

Mapping the interaction between murine IgA and murine secretory component carrying epitope substitutions reveals a role of domains II and III in covalent binding to IgA.

We have identified sites for epitope insertion in the murine secretory component (SC) by replacing individual surface-exposed loops in domains I, II, and III with the FLAG sequence (Crottet, P., Peitsch, M. C., Servis, C., and Corthésy, B. (1999) J. Biol. Chem. 274, 31445-31455). We had previously shown that epitope-carrying SC reassociated with dimeric IgA (IgA(d)) can serve as a mucosal delivery vehicle. When analyzing the capacity of SC mutants to associate with IgA(d), we found that all domain II and III mutants bound specifically with immobilized IgA(d), and their affinity for IgA(d) was comparable to that of the wild type protein (IC(50) approximately 1 nM). We conclude that domains II and III in SC are permissive to local mutation and represent convenient sites to antigenize the SC molecule. No mutant bound to monomeric IgA. SC mutants exposing the FLAG at their surface maintained this property once bound to IgA(d), thereby defining regions not required for high affinity binding to IgA(d). Association of IgA(d) with SC mutants carrying a buried FLAG did not expose de novo the epitope, consistent with limited, local changes in the SC structure upon binding. Only wild type and two mutant SCs bound covalently to IgA(d), thus implicating domains II and III in the correct positioning of the reactive cysteine in SC. This establishes that the integrity of murine SC domains II and III is not essential to preserve specific IgA(d) binding but is necessary for covalency to take place. Finally, SC mutants existing in the monomeric and dimeric forms exhibited the same IgA(d) binding capacity as monomeric wild type SC known to bind with a 1:1 stoichiometry.     

Familial Parkinson mutant alpha-synuclein causes dopamine neuron dysfunction in transgenic Caenorhabditis elegans

Mutations in alpha-synuclein gene cause familial form of Parkinson disease, and deposition of wild-type alpha-synuclein as Lewy bodies occurs as a hallmark lesion of sporadic Parkinson disease and dementia with Lewy bodies, implicating alpha-synuclein in the pathogenesis of Parkinson disease and related neurodegenerative diseases. Dopamine neurons in substantia nigra are the major site of neurodegeneration associated with alpha-synuclein deposition in Parkinson disease. Here we establish transgenic Caenorhabditis elegans (TG worms) that overexpresses wild-type or familial Parkinson mutant human alpha-synuclein in dopamine neurons. The TG worms exhibit accumulation of alpha-synuclein in the cell bodies and neurites of dopamine neurons, and EGFP labeling of dendrites is often diminished in TG worms expressing familial Parkinson disease-linked A30P or A53T mutant alpha-synuclein, without overt loss of neuronal cell bodies. Notably, TG worms expressing A30P or A53T mutant alpha-synuclein show failure in modulation of locomotory rate in response to food, which has been attributed to the function of dopamine neurons. This behavioral abnormality was accompanied by a reduction in neuronal dopamine content and was treatable by administration of dopamine. These phenotypes were not seen upon expression of beta-synuclein. The present TG worms exhibit dopamine neuron-specific dysfunction caused by accumulation of alpha-synuclein, which would be relevant to the genetic and compound screenings aiming at the elucidation of pathological cascade and therapeutic strategies for Parkinson disease.     

Relationships between the sequence of alpha-synuclein and its membrane affinity, fibrillization propensity, and yeast toxicity

To investigate the alpha-synuclein protein and its role in Parkinson's disease, we screened a library of random point mutants both in vitro and in yeast to find variants in an unbiased way that could help us understand the sequence-phenotype relationship. We developed a rapid purification method that allowed us to screen 59 synuclein mutants in vitro and discovered two double-point mutants that fibrillized slowly relative to wild-type, A30P, and A53T alpha-synucleins. The yeast toxicity of all of these proteins was measured, and we found no correlation with fibrillization rate, suggesting that fibrillization is not necessary for synuclein-induced yeast toxicity. We found that beta-synuclein was of intermediate toxicity to yeast, and gamma-synuclein was non-toxic. Co-expression of Parkinson's disease-related genes DJ-1, parkin, Pink1, UCH-L1, or synphilin, with synuclein, did not affect synuclein toxicity. A second screen, of several thousand library clones in yeast, identified 25 non-toxic alpha-synuclein sequence variants. Most of these contained a mutation to either proline or glutamic acid that caused a defect in membrane binding. We hypothesize that yeast toxicity is caused by synuclein binding directly to membranes at levels sufficient to non-specifically disrupt homeostasis.     

Cytosolic proteins regulate alpha-synuclein dissociation from presynaptic membranes

Intracellular accumulation of insoluble alpha-synuclein in Lewy bodies is a key neuropathological trait of Parkinson disease (PD). Neither the normal function of alpha-synuclein nor the biochemical mechanisms that cause its deposition are understood, although both are likely influenced by the interaction of alpha-synuclein with vesicular membranes, either for a physiological role in vesicular trafficking or as a pathological seeding mechanism that exacerbates the propensity of alpha-synuclein to self-assemble into fibrils. In addition to the alpha-helical form that is peripherally-attached to vesicles, a substantial portion of alpha-synuclein is freely diffusible in the cytoplasm. The mechanisms controlling alpha-synuclein exchange between these compartments are unknown and the possibility that chronic dysregulation of membrane-bound and soluble alpha-synuclein pools may contribute to Lewy body pathology led us to search for cellular factors that can regulate alpha-synuclein membrane interactions. Here we reveal that dissociation of membrane-bound alpha-synuclein is dependent on brain-specific cytosolic proteins and insensitive to calcium or metabolic energy. Two PD-linked mutations (A30P and A53T) significantly increase the cytosol-dependent alpha-synuclein off-rate but have no effect on cytosol-independent dissociation. These results reveal a novel mechanism by which cytosolic brain proteins modulate alpha-synuclein interactions with intracellular membranes. Importantly, our finding that alpha-synuclein dissociation is up-regulated by both familial PD mutations implicates cytosolic cofactors in disease pathogenesis and as molecular targets to influence alpha-synuclein aggregation.