Rab7 induces clearance of α-synuclein aggregates.

Parkinson's disease can be caused by mutations in the α-synuclein gene and is characterized by aggregates of α-synuclein protein. Aggregates are degraded by the autophago-lysosomal pathway. Since Rab7 has been shown to regulate trafficking of late endosomes and autophagosomes, we hypothesized that over-expressing Rab7 might be beneficial in Parkinson's disease. To test this hypothesis, we expressed the pathogenic A53T mutant of α-synuclein in HEK293 cells and Drosophila melanogaster. In HEK293 cells, EGFP-Rab7-decorated vesicles contain α-synuclein. Rab7 over-expression reduced the percentage of cells with α-synuclein particles and the amount of α-synuclein protein. Time-lapse microscopy confirmed that particles frequently disappeared with Rab7 over-expression. Clearance of α-synuclein is explained by the increased occurrence of acidified α-synuclein vesicles with Rab7 over-expression, presumably representing autolysosomes. Rab7 over-expression reduced apoptosis and the percentage of dead cells in trypan blue staining. In the fly model, Rab7 rescued the locomotor deficit induced by neuronal expression of A53T-α-synuclein. These beneficial effects were not produced by Rab7 missense mutations causing Charcot Marie Tooth neuropathy, or by the related GTPases Rab5, Rab9, or Rab23. Using mass spectrometry, we identified Rab7 in neuromelanin granules purified from human substantia nigra, indicating that Rab7 might be involved in the biogenesis of these possibly protective, autophagosome-like organelles in dopaminergic neurons. Taken together, Rab7 increased the clearance of α-synuclein aggregates, reduced cell death, and rescued the phenotype in a fly model of Parkinson's disease. These findings indicate that Rab7 is rate-limiting for aggregate clearance, and that Rab7 activation may offer a therapeutic strategy for Parkinson's disease. Cells over-expressing aggregation-prone A53T alpha-synuclein develop cytoplasmic aggregates mimicking changes observed in Parkinson's disease. When following cells in time-lapse microscopy, some few cells are able to remove these aggregates (Opazo et al. 2008). We now show that the percentage of cells clearing all aggregates from their cytosol is greatly increased with Rab7 over-expression, indicating that availability of Rab7 is rate-limiting for autophagic clearance of aggregates. The functional significance of this effect in neurons was confirmed in a Drosophila melanogaster model of Parkinson's disease.

Proteomic Characterization of Synaptosomes from Human Substantia Nigra Indicates Altered Mitochondrial Translation in Parkinson's Disease.

The pathological hallmark of Parkinson's disease (PD) is the loss of neuromelanin-containing dopaminergic neurons within the substantia nigra pars compacta (SNpc). Additionally, numerous studies indicate an altered synaptic function during disease progression. To gain new insights into the molecular processes underlying the alteration of synaptic function in PD, a proteomic study was performed. Therefore, synaptosomes were isolated by density gradient centrifugation from SNpc tissue of individuals at advanced PD stages (N = 5) as well as control subjects free of pathology (N = 5) followed by mass spectrometry-based analysis. In total, 362 proteins were identified and assigned to the synaptosomal core proteome. This core proteome comprised all proteins expressed within the synapses without regard to data analysis software, gender, age, or disease. The differential analysis between control subjects and PD cases revealed that CD9 antigen was overrepresented and fourteen proteins, among them Thymidine kinase 2 (TK2), mitochondrial, 39S ribosomal protein L37, neurolysin, and Methionine-tRNA ligase (MARS2) were underrepresented in PD suggesting an alteration in mitochondrial translation within synaptosomes.

Proteomic characterization of neuromelanin granules isolated from human substantia nigra by laser-microdissection.

Neuromelanin is a complex polymer pigment found primarily in the dopaminergic neurons of human substantia nigra. Neuromelanin pigment is stored in granules including a protein matrix and lipid droplets. Neuromelanin granules are yet only partially characterised regarding their structure and function. To clarify the exact function of neuromelanin granules in humans, their enrichment and in-depth characterization from human substantia nigra is necessary. Previously published global proteome studies of neuromelanin granules in human substantia nigra required high tissue amounts. Due to the limited availability of human brain tissue we established a new method based on laser microdissection combined with mass spectrometry for the isolation and analysis of neuromelanin granules. With this method it is possible for the first time to isolate a sufficient amount of neuromelanin granules for global proteomics analysis from ten 10 µm tissue sections. In total 1,000 proteins were identified associated with neuromelanin granules. More than 68% of those proteins were also identified in previously performed studies. Our results confirm and further extend previously described findings, supporting the connection of neuromelanin granules to iron homeostasis and lysosomes or endosomes. Hence, this method is suitable for the donor specific enrichment and proteomic analysis of neuromelanin granules.

Proteomics in neurodegenerative diseases: Methods for obtaining a closer look at the neuronal proteome.

The analysis of brain function in normal aging and neurodegenerative, psychiatric, and neurological diseases has long been a subject of interest and has historically been investigated through descriptive analysis of macroscopic or microscopic observations. It is now possible to characterize brain cells, such as neurons and glial cells, or even their subcellular components, at the molecular level. This ability enables researchers to more closely examine brain cell specific molecular pathways to elucidate distinct brain functions. Furthermore, the analysis of neuronal maintenance and disease-causing effects is a central component of neurological investigations, which include proteomic approaches. Proteomics allows the identification of thousands of proteins through descriptive and comparative analyses and can provide a detailed overview of a distinct cellular state. Such analyses often require the isolation of individual cell types or subcellular components to investigate specific questions. This review provides an overview of the currently applied state-of-the-art prefractionation strategies in this field.