Parkinson's disease and multiple system atrophy patient iPSC-derived oligodendrocytes exhibit alpha-synuclein-induced changes in maturation and immune reactive properties.

SignificanceOur results demonstrate the existence of early cellular pathways and network alterations in oligodendrocytes in the alpha-synucleinopathies Parkinson's disease and multiple system atrophy. They further reveal the involvement of an immune component triggered by alpha-synuclein protein, as well as a connection between (epi)genetic changes and immune reactivity in multiple system atrophy. The knowledge generated in this study could be used to devise novel therapeutic approaches to treat synucleinopathies.

Upregulation of APP endocytosis by neuronal aging drives amyloid-dependent synapse loss.

Neuronal aging increases the risk of late-onset Alzheimer's disease. During normal aging, synapses decline, and ß-amyloid (Aß) accumulates intraneuronally. However, little is known about the underlying cell biological mechanisms. We studied neuronal aging using normal-aged brain and aged mouse primary neurons that accumulate lysosomal lipofuscin and show synapse loss. We identified the upregulation of amyloid precursor protein (APP) endocytosis as a neuronal aging mechanism that potentiates APP processing and Aß production in vitro and in vivo. The increased APP endocytosis may contribute to the early endosome enlargement observed in the aged brain. Mechanistically, we showed that clathrin-dependent APP endocytosis requires F-actin and that clathrin and endocytic F-actin increase with neuronal aging. Finally, Aß production inhibition reverts synaptic decline in aged neurons, whereas Aß accumulation, promoted by endocytosis upregulation in younger neurons, recapitulates aging-related synapse decline. Overall, we identify APP endocytosis upregulation as a potential mechanism of neuronal aging and, thus, a novel target to prevent late-onset Alzheimer's disease. This article has an associated First Person interview with the first author of the paper.

APOE4 Affects Basal and NMDAR-Mediated Protein Synthesis in Neurons by Perturbing Calcium Homeostasis.

Apolipoprotein E (APOE), one of the primary lipoproteins in the brain has three isoforms in humans, APOE2, APOE3, and APOE4. APOE4 is the most well-established risk factor increasing the predisposition for Alzheimer's disease (AD). The presence of the APOE4 allele alone is shown to cause synaptic defects in neurons and recent studies have identified multiple pathways directly influenced by APOE4. However, the mechanisms underlying APOE4-induced synaptic dysfunction remain elusive. Here, we report that the acute exposure of primary cortical neurons or synaptoneurosomes to APOE4 leads to a significant decrease in global protein synthesis. Primary cortical neurons were derived from male and female embryos of Sprague Dawley (SD) rats or C57BL/6J mice. Synaptoneurosomes were prepared from P30 male SD rats. APOE4 treatment also abrogates the NMDA-mediated translation response indicating an alteration of synaptic signaling. Importantly, we demonstrate that both APOE3 and APOE4 generate a distinct translation response which is closely linked to their respective calcium signature. Acute exposure of neurons to APOE3 causes a short burst of calcium through NMDA receptors (NMDARs) leading to an initial decrease in protein synthesis which quickly recovers. Contrarily, APOE4 leads to a sustained increase in calcium levels by activating both NMDARs and L-type voltage-gated calcium channels (L-VGCCs), thereby causing sustained translation inhibition through eukaryotic translation elongation factor 2 (eEF2) phosphorylation, which in turn disrupts the NMDAR response. Thus, we show that APOE4 affects basal and activity-mediated protein synthesis responses in neurons by affecting calcium homeostasis.SIGNIFICANCE STATEMENT Defective protein synthesis has been shown as an early defect in familial Alzheimer's disease (AD). However, this has not been studied in the context of sporadic AD, which constitutes the majority of cases. In our study, we show that Apolipoprotein E4 (APOE4), the predominant risk factor for AD, inhibits global protein synthesis in neurons. APOE4 also affects NMDA activity-mediated protein synthesis response, thus inhibiting synaptic translation. We also show that the defective protein synthesis mediated by APOE4 is closely linked to the perturbation of calcium homeostasis caused by APOE4 in neurons. Thus, we propose the dysregulation of protein synthesis as one of the possible molecular mechanisms to explain APOE4-mediated synaptic and cognitive defects. Hence, the study not only suggests an explanation for the APOE4-mediated predisposition to AD, it also bridges the gap in understanding APOE4-mediated pathology.

Sphingosine 1-Phoshpate Receptors are Located in Synapses and Control Spontaneous Activity of Mouse Neurons in Culture.

Sphingosine-1-phosphate (S1P) is best known for its roles as vascular and immune regulator. Besides, it is also present in the central nervous system (CNS) where it can act as neuromodulator via five S1P receptors (S1PRs), and thus control neurotransmitter release. The distribution of S1PRs in the active zone and postsynaptic density of CNS synapses remains unknown. In the current study, we investigated the localization of S1PR1-5 in synapses of the mouse cortex. Cortical nerve terminals purified in a sucrose gradient were endowed with all five S1PRs. Further subcellular fractionation of cortical nerve terminals revealed S1PR2 and S1PR4 immunoreactivity in the active zone of presynaptic nerve terminals. Interestingly, only S1PR2 and S1PR3 immunoreactivity was found in the postsynaptic density. All receptors were present outside the active zone of nerve terminals. Neurons in the mouse cortex and primary neurons in culture showed immunoreactivity against all five S1PRs, and Ca2+ imaging revealed that S1P inhibits spontaneous neuronal activity in a dose-dependent fashion. When testing selective agonists for each of the receptors, we found that only S1PR1, S1PR2 and S1PR4 control spontaneous neuronal activity. We conclude that S1PR2 and S1PR4 are located in the active zone of nerve terminals and inhibit neuronal activity. Future studies need to test whether these receptors modulate stimulation-induced neurotransmitter release.

Correlative imaging to resolve molecular structures in individual cells: Substrate validation study for super-resolution infrared microspectroscopy.

Light microscopy has been a favorite tool of biological studies for almost a century, recently producing detailed images with exquisite molecular specificity achieving spatial resolution at nanoscale. However, light microscopy is insufficient to provide chemical information as a standalone technique. An increasing amount of evidence demonstrates that optical photothermal infrared microspectroscopy (O-PTIR) is a valuable imaging tool that can extract chemical information to locate molecular structures at submicron resolution. To further investigate the applicability of sub-micron infrared microspectroscopy for biomedical applications, we analyzed the contribution of substrate chemistry to the infrared spectra acquired from individual neurons grown on various imaging substrates. To provide an example of correlative immunofluorescence/O-PTIR imaging, we used immunofluorescence to locate specific organelles for O-PTIR measurement, thus capturing molecular structures at the sub-cellular level directly in cells, which is not possible using traditional infrared microspectroscopy or immunofluorescence microscopy alone.

Neuronal spreading and plaque induction of intracellular Aß and its disruption of Aß homeostasis.

The amyloid-beta peptide (Aß) is thought to have prion-like properties promoting its spread throughout the brain in Alzheimer's disease (AD). However, the cellular mechanism(s) of this spread remains unclear. Here, we show an important role of intracellular Aß in its prion-like spread. We demonstrate that an intracellular source of Aß can induce amyloid plaques in vivo via hippocampal injection. We show that hippocampal injection of mouse AD brain homogenate not only induces plaques, but also damages interneurons and affects intracellular Aß levels in synaptically connected brain areas, paralleling cellular changes seen in AD. Furthermore, in a primary neuron AD model, exposure of picomolar amounts of brain-derived Aß leads to an apparent redistribution of Aß from soma to processes and dystrophic neurites. We also observe that such neuritic dystrophies associate with plaque formation in AD-transgenic mice. Finally, using cellular models, we propose a mechanism for how intracellular accumulation of Aß disturbs homeostatic control of Aß levels and can contribute to the up to 10,000-fold increase of Aß in the AD brain. Our data indicate an essential role for intracellular prion-like Aß and its synaptic spread in the pathogenesis of AD.

Amyloid Structural Changes Studied by Infrared Microspectroscopy in Bigenic Cellular Models of Alzheimer's Disease.

Alzheimer's disease affects millions of lives worldwide. This terminal disease is characterized by the formation of amyloid aggregates, so-called amyloid oligomers. These oligomers are composed of ß-sheet structures, which are believed to be neurotoxic. However, the actual secondary structure that contributes most to neurotoxicity remains unknown. This lack of knowledge is due to the challenging nature of characterizing the secondary structure of amyloids in cells. To overcome this and investigate the molecular changes in proteins directly in cells, we used synchrotron-based infrared microspectroscopy, a label-free and non-destructive technique available for in situ molecular imaging, to detect structural changes in proteins and lipids. Specifically, we evaluated the formation of ß-sheet structures in different monogenic and bigenic cellular models of Alzheimer's disease that we generated for this study. We report on the possibility to discern different amyloid signatures directly in cells using infrared microspectroscopy and demonstrate that bigenic (amyloid-ß, α-synuclein) and (amyloid-ß, Tau) neuron-like cells display changes in ß-sheet load. Altogether, our findings support the notion that different molecular mechanisms of amyloid aggregation, as opposed to a common mechanism, are triggered by the specific cellular environment and, therefore, that various mechanisms lead to the development of Alzheimer's disease.

APP depletion alters selective pre- and post-synaptic proteins.

The normal role of Alzheimer's disease (AD)-linked amyloid precursor protein (APP) in the brain remains incompletely understood. Previous studies have reported that lack of APP has detrimental effects on spines and electrophysiological parameters. APP has been described to be important in synaptic pruning during development. The effect of APP knockout on mature synapses is complicated by this role in development. We previously reported on differential changes in synaptic proteins and receptors in APP mutant AD transgenic compared to wild-type neurons, which revealed selective decreases in levels of pre- and post-synaptic proteins, including of surface glutamate receptors. In the present study, we undertook a similar analysis of synaptic composition but now in APP knockout compared to wild-type mouse neurons. Here we demonstrate alterations in levels of selective pre- and post-synaptic proteins and receptors in APP knockout compared to wild-type mouse primary neurons in culture and brains of mice in youth and adulthood. Remarkably, we demonstrate selective increases in levels of synaptic proteins, such as GluA1, in neurons with APP knockout and with RNAi knockdown, which tended to be opposite to the reductions seen in AD transgenic APP mutant compared to wild-type neurons. These data reinforce that APP is important for the normal composition of synapses.

Prion-like seeding and nucleation of intracellular amyloid-ß.

Alzheimer's disease (AD) brain tissue can act as a seed to accelerate aggregation of amyloid-ß (Aß) into plaques in AD transgenic mice. Aß seeds have been hypothesized to accelerate plaque formation in a prion-like manner of templated seeding and intercellular propagation. However, the structure(s) and location(s) of the Aß seeds remain unknown. Moreover, in contrast to tau and α-synuclein, an in vitro system with prion-like Aß has not been reported. Here we treat human APP expressing N2a cells with AD transgenic mouse brain extracts to induce inclusions of Aß in a subset of cells. We isolate cells with induced Aß inclusions and using immunocytochemistry, western blot and infrared spectroscopy show that these cells produce oligomeric Aß over multiple replicative generations. Further, we demonstrate that cell lysates of clones with induced oligomeric Aß can induce aggregation in previously untreated N2a APP cells. These data strengthen the case that Aß acts as a prion-like protein, demonstrate that Aß seeds can be intracellular oligomers and for the first time provide a cellular model of nucleated seeding of Aß.

ESCRTs regulate amyloid precursor protein sorting in multivesicular bodies and intracellular amyloid-ß accumulation.

Intracellular amyloid-ß (Aß) accumulation is a key feature of early Alzheimer's disease and precedes the appearance of Aß in extracellular plaques. Aß is generated through proteolytic processing of amyloid precursor protein (APP), but the intracellular site of Aß production is unclear. APP has been localized to multivesicular bodies (MVBs) where sorting of APP onto intraluminal vesicles (ILVs) could promote amyloidogenic processing, or reduce Aß production or accumulation by sorting APP and processing products to lysosomes for degradation. Here, we show that APP localizes to the ILVs of a subset of MVBs that also traffic EGF receptor (EGFR), and that it is delivered to lysosomes for degradation. Depletion of the endosomal sorting complexes required for transport (ESCRT) components, Hrs (also known as Hgs) or Tsg101, inhibited targeting of APP to ILVs and the subsequent delivery to lysosomes, and led to increased intracellular Aß accumulation. This was accompanied by dramatically decreased Aß secretion. Thus, the early ESCRT machinery has a dual role in limiting intracellular Aß accumulation through targeting of APP and processing products to the lysosome for degradation, and promoting Aß secretion.

Plaque formation and the intraneuronal accumulation of ß-amyloid in Alzheimer's disease.

Amyloid plaques and neurofibrillary tangles (NFTs) in the brain are the neuropathological hallmarks of Alzheimer's disease (AD). Amyloid plaques are composed of ß-amyloid peptides (Aß), while NFTs contain hyperphosphorylated tau proteins. Patients with familial AD who have mutations in the amyloid precursor protein (APP) gene have either increased production of Aß or generate more aggregation-prone forms of Aß. The findings of familial AD mutations in the APP gene suggest that Aß plays a central role in the pathophysiology of AD. Aß42, composed of 42 amino acid residues, aggregates readily and is considered to form amyloid plaque. However, the processes of plaque formation are still not well known. It is generally thought that Aß is secreted into the extracellular space and aggregates to form amyloid plaques. Aß as extracellular aggregates and amyloid plaques are thought to be toxic to the surrounding neurons. The intraneuronal accumulation of Aß has more recently been demonstrated and is reported to be involved in synaptic dysfunction, cognitive impairment, and the formation of amyloid plaques in AD. We herein provide an overview of the process of the intraneuronal accumulation of Aß and plaque formation, and discuss its implications for the pathology, early diagnosis, and therapy of AD.

ADAM10 and BACE1 are localized to synaptic vesicles.

Synaptic degeneration and accumulation of the neurotoxic amyloid ß-peptide (Aß) in the brain are hallmarks of Alzheimer disease. Aß is produced by sequential cleavage of the amyloid precursor protein (APP), by the ß-secretase ß-site APP cleaving enzyme 1 (BACE1) and γ-secretase. However, Aß generation is precluded if APP is cleaved by the α-secretase ADAM10 instead of BACE1. We have previously shown that Aß can be produced locally at the synapse. To study the synaptic localization of the APP processing enzymes we used western blotting to demonstrate that, compared to total brain homogenate, ADAM10 and BACE1 were greatly enriched in synaptic vesicles isolated from rat brain using controlled-pore glass chromatography, whereas Presenilin1 was the only enriched component of the γ-secretase complex. Moreover, we detected ADAM10 activity in synaptic vesicles and enrichment of the intermediate APP-C-terminal fragments (APP-CTFs). We confirmed the western blotting findings using in situ proximity ligation assay to demonstrate close proximity of ADAM10 and BACE1 with the synaptic vesicle marker synaptophysin in intact mouse primary hippocampal neurons. In contrast, only sparse co-localization of active γ-secretase and synaptophysin was detected. These results indicate that the first step of APP processing occurs in synaptic vesicles whereas the final step is more likely to take place elsewhere.

The inside-out amyloid hypothesis and synapse pathology in Alzheimer's disease.

Cumulative evidence in brains and cultured neurons of Alzheimer's disease (AD) transgenic mouse models, as well as in human postmortem AD brains, highlights that age-related increases in ß-amyloid peptide (Aß), particularly in endosomes near synapses, are involved in early synapse dysfunction. Our immunoelectron microscopy and high-resolution immunofluorescence microscopy studies show that this early subcellular Aß accumulation leads to progressive Aß aggregation and pathology, particularly within dystrophic neurites and synapses. These studies confirm that neuritic/synaptic Aß accumulation is the nidus of plaque formation. Aß-dependent synapse pathology in AD models is modulated by synaptic activity and is plaque independent. The amyloid precursor protein (APP) is normally transported down neurites and appears to be preferentially processed to Aß at synapses. Synapses are sites of early Aß accumulation and aberrant tau phosphorylation in AD, which alter the synaptic composition at early stages of the disease. Elucidating the normal role of APP, and potentially of Aß, at synapses should provide important insights into the mechanism(s) of Aß-induced synapse dysfunction in AD and how to therapeutically mitigate these dysfunctions.

Cerebral Aß deposition precedes reduced cerebrospinal fluid and serum Aß42/Aß40 ratios in the AppNL-F/NL-F knock-in mouse model of Alzheimer's disease.

BACKGROUND: Aß42/Aß40 ratios in cerebrospinal fluid (CSF) and blood are reduced in preclinical Alzheimer's disease (AD), but their temporal and correlative relationship with cerebral Aß pathology at this early disease stage is not well understood. In the present study, we aim to investigate such relationships using App knock-in mouse models of preclinical AD. METHODS: CSF, serum, and brain tissue were collected from 3- to 18-month-old AppNL-F/NL-F knock-in mice (n = 48) and 2-18-month-old AppNL/NL knock-in mice (n = 35). The concentrations of Aß42 and Aß40 in CSF and serum were measured using Single molecule array (Simoa) immunoassays. Cerebral Aß plaque burden was assessed in brain tissue sections by immunohistochemistry and thioflavin S staining. Furthermore, the concentrations of Aß42 in soluble and insoluble fractions prepared from cortical tissue homogenates were measured using an electrochemiluminescence immunoassay. RESULTS: In AppNL-F/NL-F knock-in mice, Aß42/Aß40 ratios in CSF and serum were significantly reduced from 12 and 16 months of age, respectively. The initial reduction of these biomarkers coincided with cerebral Aß pathology, in which a more widespread Aß plaque burden and increased levels of Aß42 in the brain were observed from approximately 12 months of age. Accordingly, in the whole study population, Aß42/Aß40 ratios in CSF and serum showed a negative hyperbolic association with cerebral Aß plaque burden as well as the levels of both soluble and insoluble Aß42 in the brain. These associations tended to be stronger for the measures in CSF compared with serum. In contrast, no alterations in the investigated fluid biomarkers or apparent cerebral Aß plaque pathology were found in AppNL/NL knock-in mice during the observation time. CONCLUSIONS: Our findings suggest a temporal sequence of events in AppNL-F/NL-F knock-in mice, in which initial deposition of Aß aggregates in the brain is followed by a decline of the Aß42/Aß40 ratio in CSF and serum once the cerebral Aß pathology becomes significant. Our results also indicate that the investigated biomarkers were somewhat more strongly associated with measures of cerebral Aß pathology when assessed in CSF compared with serum.

Apolipoprotein E intersects with amyloid-ß within neurons.

Apolipoprotein E4 (ApoE4) is the most important genetic risk factor for Alzheimer's disease (AD). Among the earliest changes in AD is endosomal enlargement in neurons, which was reported as enhanced in ApoE4 carriers. ApoE is thought to be internalized into endosomes of neurons, whereas ß-amyloid (Aß) accumulates within neuronal endosomes early in AD. However, it remains unknown whether ApoE and Aß intersect intracellularly. We show that internalized astrocytic ApoE localizes mostly to lysosomes in neuroblastoma cells and astrocytes, whereas in neurons, it preferentially localizes to endosomes-autophagosomes of neurites. In AD transgenic neurons, astrocyte-derived ApoE intersects intracellularly with amyloid precursor protein/Aß. Moreover, ApoE4 increases the levels of endogenous and internalized Aß42 in neurons. Taken together, we demonstrate differential localization of ApoE in neurons, astrocytes, and neuron-like cells, and show that internalized ApoE intersects with amyloid precursor protein/Aß in neurons, which may be of considerable relevance to AD.

Proteomic analysis across patient iPSC-based models and human post-mortem hippocampal tissue reveals early cellular dysfunction and progression of Alzheimer's disease pathogenesis.

The hippocampus is a primary region affected in Alzheimer's disease (AD). Because AD postmortem brain tissue is not available prior to symptomatic stage, we lack understanding of early cellular pathogenic mechanisms. To address this issue, we examined the cellular origin and progression of AD pathogenesis by comparing patient-based model systems including iPSC-derived brain cells transplanted into the mouse brain hippocampus. Proteomic analysis of the graft enabled the identification of pathways and network dysfunction in AD patient brain cells, associated with increased levels of Aß-42 and ß-sheet structures. Interestingly, the host cells surrounding the AD graft also presented alterations in cellular biological pathways. Furthermore, proteomic analysis across human iPSC-based models and human post-mortem hippocampal tissue projected coherent longitudinal cellular changes indicative of early to end stage AD cellular pathogenesis. Our data showcase patient-based models to study the cell autonomous origin and progression of AD pathogenesis.

Impaired ß-amyloid secretion in Alzheimer's disease pathogenesis.

A central question in Alzheimer's disease (AD) research is what role ß-amyloid peptide (Aß) plays in synaptic dysfunction. Synaptic activity increases Aß secretion, potentially inhibiting synapses, but also decreases intraneuronal Aß, protecting synapses. We now show that levels of secreted Aß fall with time in culture in neurons of AD-transgenic mice, but not wild-type mice. Moreover, the ability of synaptic activity to elevate secreted Aß and reduce intraneuronal Aß becomes impaired in AD-transgenic but not wild-type neurons with time in culture. We demonstrate that synaptic activity promotes an increase in the Aß-degrading protease neprilysin at the cell surface and a concomitant increase in colocalization with Aß42. Remarkably, AD-transgenic but not wild-type neurons show reduced levels of neprilysin with time in culture. This impaired ability to secrete Aß and reduce intraneuronal Aß has important implications for the pathogenesis and treatment of AD.

High-resolution 3D reconstruction reveals intra-synaptic amyloid fibrils.

ß-Amyloid (Aß) accumulation and aggregation are hallmarks of Alzheimer's disease (AD). High-resolution three-dimensional (HR-3D) volumetric imaging allows for better analysis of fluorescence confocal microscopy and 3D visualization of Aß pathology in brain. Early intraneuronal Aß pathology was studied in AD transgenic mouse brains by HR-3D volumetric imaging. To better visualize and analyze the development of Aß pathology, thioflavin S staining and immunofluorescence using antibodies against Aß, fibrillar Aß, and structural and synaptic neuronal proteins were performed in the brain tissue of Tg19959, wild-type, and Tg19959-YFP mice at different ages. Images obtained by confocal microscopy were reconstructed into three-dimensional volumetric datasets. Such volumetric imaging of CA1 hippocampus of AD transgenic mice showed intraneuronal onset of Aß42 accumulation and fibrillization within cell bodies, neurites, and synapses before plaque formation. Notably, early fibrillar Aß was evident within individual synaptic compartments, where it was associated with abnormal morphology. In dendrites, increasing intraneuronal thioflavin S correlated with decreases in neurofilament marker SMI32. Fibrillar Aß aggregates could be seen piercing the cell membrane. These data support that Aß fibrillization begins within AD vulnerable neurons, leading to disruption of cytoarchitecture and degeneration of spines and neurites. Thus, HR-3D volumetric image analysis allows for better visualization of intraneuronal Aß pathology and provides new insights into plaque formation in AD.

Intraneuronal Aß accumulation, amyloid plaques, and synapse pathology in Alzheimer's disease.

BACKGROUND: ß-Amyloid (Aß) plaques are a pathological hallmark of Alzheimer's disease (AD) and multiple lines of evidence have linked Aß with AD. However, synapse loss is known as the best pathological correlate of cognitive impairment in AD, and intraneuronal Aß accumulation has been shown to precede plaque pathology. The progression of Aß accumulation to synapse loss and plaque formation remains incomplete. The objective is to investigate the progression of intraneuronal Aß accumulation in the brain. METHODS: To visualize and analyze the development of Aß pathology we perform immunohistochemistry and immunofluorescence microscopy using antibodies against different Aß conformations, synaptic proteins and structural neuronal proteins in brain tissue of AD transgenic mouse models. RESULTS: Our results show the intraneuronal onset of Aß42 accumulation in AD mouse brains with aging. We observe an inverse correlation of Aß and amyloid fibrils with structural proteins within neurites. Images reveal aggregated amyloid within selective pyramidal neurons, neurites and synapses in AD transgenic mice as plaques arise. CONCLUSION: The data support that Aß42 accumulation and aggregation begin within AD-vulnerable neurons in the brain. Progressive intraneuronal Aß42 aggregation disrupts the normal cytoarchitecture of neurites.

Monitoring the interactions between alpha-synuclein and Tau in vitro and in vivo using bimolecular fluorescence complementation.

Parkinson's disease (PD) and Alzheimer's disease (AD) are characterized by pathological accumulation and aggregation of different amyloidogenic proteins, α-synuclein (aSyn) in PD, and amyloid-ß (Aß) and Tau in AD. Strikingly, few PD and AD patients' brains exhibit pure pathology with most cases presenting mixed types of protein deposits in the brain. Bimolecular fluorescence complementation (BiFC) is a technique based on the complementation of two halves of a fluorescent protein, which allows direct visualization of protein-protein interactions. In the present study, we assessed the ability of aSyn and Tau to interact with each other. For in vitro evaluation, HEK293 and human neuroblastoma cells were used, while in vivo studies were performed by AAV6 injection in the substantia nigra pars compacta (SNpc) of mice and rats. We observed that the co-expression of aSyn and Tau led to the emergence of fluorescence, reflecting the interaction of the proteins in cell lines, as well as in mouse and rat SNpc. Thus, our data indicates that aSyn and Tau are able to interact with each other in a biologically relevant context, and that the BiFC assay is an effective tool for studying aSyn-Tau interactions in vitro and in different rodent models in vivo.