Browsing by keyword "Protein aggregation"
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PFN1 phosphorylation marks protein aggregation and white matter pathology in ALSAmyotrophic lateral sclerosis (ALS), also known as Lou Gehrig’s disease is the most common form of motor neuron disease. In familial ALS, Multiple mutations of, PFN1 gene a well-known actin-binding protein have been linked to ALS disease recently. Phosphorylation in many degenerative conditions plays an important role in disease mechanism but its potential role in ALS remains not fully understood. We sought to look further into not previously studied phosphorylation of PFN1 as a potential contributor to aggregation and toxicity in ALS. Using different histochemistry and cytochemistry and molecular biology approaches, we observed that phosphorylation on Profilin shows a very distinctive pattern in PFN1C71G andSOD1G93A disease models. This modification is abundantly found in both astrocytes and white matter which latter indeed marks a staining pattern that is indistinguishable between two ALS mice model compared to controls. Interestingly, pPFN1 reactive areas colocalized with Myelin in the spinal cord are frequently found in the proximity of CD68 positive macrophages. Moreover, biochemical fractionation using ultracentrifugation detects endogenous pPFN1 in the highly insoluble fraction of protein lysate from both PFN1C71G andSOD1G93A model. Finally, a similar staining pattern to the ALS mice model was also observed in human sporadic ALS cases. Overall, our results suggest for the first time a role for phosphorylation of PFN1 in protein aggregation and white matter pathology in ALS that will shed more light on the mechanism of disease and developing potential therapeutics in near future.
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Protein citrullination marks myelin protein aggregation and disease progression in mouse ALS modelsIncreased protein citrullination (PC) and dysregulated protein arginine deiminase (PAD) activity have been observed in several neurodegenerative diseases. PC is a posttranslational modification catalyzed by the PADs. PC converts peptidyl-arginine to peptidyl-citrulline, thereby reducing the positive charges and altering structure and function of proteins. Of the five PADs, PAD2 is the dominant isoform in the central nervous system (CNS). Abnormal PC and PAD dysregulation are associated with numerous pathological conditions, including inflammatory diseases and neurodegeneration. Animal model studies have shown therapeutic efficacy from inhibition of PADs, thus suggesting a role of PC in pathogenesis. To determine whether PC contribute to amyotrophic lateral sclerosis (ALS), a deadly neurodegenerative disease characterized by loss of motor neurons, paralysis, and eventual death, we investigated alterations of PC and PAD2 in two different transgenic mouse models of ALS expressing human mutant SOD1G93A and PFN1C71G, respectively. PC and PAD2 expression are altered dynamically in the spinal cord during disease progression in both models. PC and PAD2 increase progressively in astrocytes with the development of reactive astrogliosis, while decreasing in neurons. Importantly, in the spinal cord white matter, PC accumulates in protein aggregates that contain the myelin proteins PLP and MBP. PC also accumulates progressively in insoluble protein fractions during disease progression. Finally, increased PC and PAD2 expression spatially correlate with areas of the CNS with the most severe motor neuron degeneration. These results suggest that altered PC is an integral part of the neurodegenerative process and potential biomarkers for disease progression in ALS. Moreover, increased PC may contribute to disease-associated processes such as myelin protein aggregation, myelin degeneration, and astrogliosis.
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RNA binding proteins co-localize with small tau inclusions in tauopathyThe development of insoluble, intracellular neurofibrillary tangles composed of the microtubule-associated protein tau is a defining feature of tauopathies, including Alzheimer's disease (AD). Accumulating evidence suggests that tau pathology co-localizes with RNA binding proteins (RBPs) that are known markers for stress granules (SGs). Here we used proteomics to determine how the network of tau binding proteins changes with disease in the rTg4510 mouse, and then followed up with immunohistochemistry to identify RNA binding proteins that co-localize with tau pathology. The tau interactome networks revealed striking disease-related changes in interactions between tau and a multiple RBPs, and biochemical fractionation studies demonstrated that many of these proteins including hnRNPA0, EWSR1, PABP and RPL7 form insoluble aggregates as tau pathology develops. Immunohistochemical analysis of mouse and human brain tissues suggest a model of evolving pathological interaction, in which RBPs co-localize with pathological phospho-tau but occur adjacent to larger pathological tau inclusions. We suggest a model in which tau initially interacts with RBPs in small complexes, but evolves into isolated aggregated inclusions as tau pathology matures.
