A comprehensive, unbiased inventory of synuclein forms present in Lewy bodies from patients with dementia with Lewy bodies was carried out using two-dimensional immunoblot analysis, novel sandwich enzyme-linked immunosorbent assays with modification-specific synuclein antibodies, and mass spectroscopy. The predominant modification of ␣-synuclein in Lewy bodies is a single phosphorylation at Ser-129. In addition, there is a set of characteristic modifications that are present to a lesser extent, including ubiquitination at Lys residues 12, 21, and 23 and specific truncations at Asp-115, Asp-119, Asn-122, Tyr-133, and Asp-135. No other modifications are detectable by tandem mass spectrometry mapping, except for a ubiquitous N-terminal acetylation. Small amounts of Ser-129 phosphorylated and Asp-119-truncated ␣-synuclein are present in the soluble fraction of both normal and disease brains, suggesting that these Lewy body-associated forms are produced during normal metabolism of ␣-synuclein. In contrast, ubiquitination is only detected in Lewy bodies and is primarily present on phosphorylated synuclein; it therefore likely occurs after phosphorylated synuclein has deposited into Lewy bodies. This invariant pattern of specific phosphorylation, truncation, and ubiquitination is also present in the detergent-insoluble fraction of brain from patients with familial Parkinson's disease (synuclein A53T mutation) as well as multiple system atrophy, suggesting a common pathogenic pathway for both genetic and sporadic Lewy body diseases. These observations are most consistent with a model in which preferential accumulation of normally produced Ser-129 phosphorylated ␣-synuclein is the key event responsible for the formation of Lewy bodies in various Lewy body diseases.A number of neurodegenerative diseases, including Parkinson disease (PD), 4 dementia with Lewy bodies (DLB), and multiple system atrophy (MSA) are defined histologically by the presence of Lewy bodies (LBs), intracellular protein aggregates that have a range of morphologies, from cytoplasmic spheres to neuritic threads also referred to as Lewy neurites (LNs). A number of proteins have been identified in LBs largely by immunohistochemical staining of brain, although the two most common are ubiquitin and ␣-synuclein (1-4). The invariable presence of ␣-synuclein in LBs suggests that it plays a key role in the etiology of such diseases ("synucleinopathies"). Point mutations in the synuclein gene as well as multiplication of the gene in familial cases of PD lead to autosomally dominant familial forms of PD (5-9). As in sporadic PD, LBs are also found in the brains of individuals with familial PD suggesting that clues about the pathogenic role of synuclein lie within the LB.Because ␣-synuclein is a relatively abundant neuronal protein, and LBs are found in diseased brain, we hypothesized that the formation of the abnormal LB structures results from specific modifications to this protein. We therefore analyzed the specific forms of ␣-synuclein that are found in LBs is...
Abnormal folding of alpha-synuclein (alpha-syn) is thought to lead to neurodegeneration and the characteristic symptoms of Lewy body disease (LBD). Since previous studies suggest that immunization might be a potential therapy for Alzheimer's disease, we hypothesized that immunization with human (h)alpha-syn might have therapeutic effects in LBD. For this purpose, halpha-syn transgenic (tg) mice were vaccinated with halpha-syn. In mice that produced high relative affinity antibodies, there was decreased accumulation of aggregated halpha-syn in neuronal cell bodies and synapses that was associated with reduced neurodegeneration. Furthermore, antibodies produced by immunized mice recognized abnormal halpha-syn associated with the neuronal membrane and promoted the degradation of halpha-syn aggregates, probably via lysosomal pathways. Similar effects were observed with an exogenously applied FITC-tagged halpha-syn antibody. These results suggest that vaccination is effective in reducing neuronal accumulation of halpha-syn aggregates and that further development of this approach might have a potential role in the treatment of LBD.
Background: α-Synuclein has been directly linked to Parkinson’s disease etiology by mutations in and multiplication of its gene that result in a familial form of Parkinson’s disease. α-Synuclein has been detected in blood, and was found to be elevated in the blood of those individuals with the α-synuclein gene multiplication. Objective: A complete analysis of the level of α-synuclein in blood has not been performed. In this report, we determine the quantitative distribution of α-synuclein in the plasma and different cellular fractions of human blood. The levels of α-synuclein in human and mouse blood are compared. Methods: α-Synuclein levels in the different fractions of blood were quantified by a sandwich ELISA with purified recombinant α-synuclein as an assay standard. Samples were further characterized by Western immunoblot analysis. Results: More than 99% of the α-synuclein resides in the red blood cells (RBCs) with less than 1% of the total detected in the plasma, platelets and peripheral blood mononuclear cells. Conclusions: More than 99% of the α-synuclein in human blood is present in the peripheral blood cells, with the remainder in plasma. Fractionation of peripheral blood cells from human blood and quantification of α-synuclein revealed that only a very small amount of the total α-synuclein is present in peripheral blood mononuclear cells, and platelets, with the majority of α-synuclein in blood being present in RBCs. Considering the abundance and fragility of RBCs, α-synuclein levels in these other blood fractions or other bodily fluids such as cerebrospinal fluid may be artificially elevated by contamination with intact or lysed RBCs.
vaccines are a critical tool for controlling the ongoing global pandemic. The Food and Drug Administration (FDA) has issued Emergency Use Authorizations for three COVID-19 vaccines for use in the United States.* In large, randomized-controlled trials, each vaccine was found to be safe and efficacious in preventing symptomatic, laboratoryconfirmed . Despite the high level of vaccine efficacy, a small percentage of fully vaccinated persons (i.e. received all recommended doses of an FDA-authorized COVID-19 vaccine) will develop symptomatic or asymptomatic infections with SARS-CoV-2, the virus that causes .CDC is working with state and territorial health departments to investigate SARS-CoV-2 infections among persons who are fully vaccinated and to monitor trends in case characteristics and SARS-CoV-2 variants identified from persons with these infections. For this surveillance, a vaccine breakthrough infection is defined as the detection of SARS-CoV-2 RNA or antigen in a respiratory specimen collected from a person ≥14 days after receipt of all recommended doses of an FDAauthorized COVID-19 vaccine. State health departments voluntarily report vaccine breakthrough infections to CDC. † When possible, genomic sequencing is performed on respiratory specimens that test positive for SARS-CoV-2 RNA (9). A total of 10,262 SARS-CoV-2 vaccine breakthrough infections had been reported from 46 U.S. states and territories as of April 30, 2021. Among these cases, 6,446 (63%) occurred in females, and the median patient age was 58 years (interquartile range = 40-74 years). Based on preliminary data, 2,725 (27%) vaccine breakthrough infections were asymptomatic, 995 (10%) patients were known to be hospitalized, and 160 (2%) patients died. Among the 995 hospitalized patients, 289 (29%) were asymptomatic or hospitalized for a reason unrelated to COVID-19. The median age of patients who died was 82 years (interquartile range = 71-89 years); 28 (18%) decedents were asymptomatic or died from a cause unrelated to COVID-19. Sequence data were available from 555 (5%) reported cases, 356 (64%) of which were identified as SARS-CoV-2 variants of
Several neurological diseases, includingThe importance of ␣-synuclein to the pathogenesis of Parkinson disease (PD) 4 and the related disorder, dementia with Lewy bodies (DLB), is suggested by its association with Lewy bodies and Lewy neurites, the inclusions that characterize these diseases (1)(2)(3), and demonstrated by the existence of mutations that cause syndromes mimicking sporadic PD and DLB (4 -6). Furthermore, three separate mutations cause early onset forms of PD and DLB. It is particularly telling that duplications or triplications of the gene (7-9), which increase levels of ␣-synuclein with no alteration in sequence, also cause PD or DLB.␣-Synuclein has been reported to be phosphorylated on serine residues, at Ser-87 and Ser-129 (10), although to date only the Ser-129 phosphorylation has been identified in the central nervous system (11,12). Phosphorylation at tyrosine residues has been observed by some investigators (13,14) but not by others (10 -12). Phosphorylation at Ser-129 (p-Ser-129) is of particular interest because the majority of synuclein in Lewy bodies contains this modification (15). In addition, p-Ser-129 was found to be the most extensive and consistent modification in a survey of synuclein in Lewy bodies (11). Results have been mixed from studies investigating the function of phosphorylation using S129A and S129D mutations to respectively block and mimic the modification. Although the phosphorylation mimic was associated with pathology in studies in Drosophila (16) and in transgenic mouse models (17, 18), studies using adeno-associated virus vectors to overexpress ␣-synuclein in rat substantia nigra found an exacerbation of pathology with the S129A mutation, whereas the S129D mutation was benign, if not protective (19). Interpretation of these studies is complicated by a recent study showing that the S129D and S129A mutations themselves have effects on the aggregation properties of ␣-synuclein independent of their effects on phosphorylation, with the S129A mutation stimulating fibril formation (20). Clearly, determination of the role of p-Ser-129 phosphorylation would be helped by identification of the responsible kinase. In addition, identification will provide a pathologically relevant way to increase phosphorylation in a cell or animal model.Several kinases have been proposed to phosphorylate ␣-synuclein, including casein kinases 1 and 2 (10, 12, 21) and members of the G-protein-coupled receptor kinase family (22). In this report, we offer evidence that a member of the polo-like kinase (PLK) family, PLK2 (or serum-inducible kinase, SNK), functions as an ␣-synuclein kinase. The ability of PLK2 to directly phosphorylate ␣-synuclein at Ser-129 is established by overexpression in cell culture and by in vitro reaction with the purified kinase. We show that PLK2 phosphorylates ␣-synuclein in cells, including primary neuronal cultures, using a series of kinase inhibitors as well as inhibition of expression with RNA interference. In addition, inhibitor and knock-out studies in mouse brai...
. Differential involvement of MMP-2 and VEGF during muscle stretch-versus shear stress-induced angiogenesis.
We have developed a cost-effective and portable graphene-enabled biosensor to detect Zika virus with a highly specific immobilized monoclonal antibody. Field Effect Biosensing (FEB) with monoclonal antibodies covalently linked to graphene enables real-time, quantitative detection of native Zika viral (ZIKV) antigens. The percent change in capacitance in response to doses of antigen (ZIKV NS1) coincides with levels of clinical significance with detection of antigen in buffer at concentrations as low as 450pM. Potential diagnostic applications were demonstrated by measuring Zika antigen in a simulated human serum. Selectivity was validated using Japanese Encephalitis NS1, a homologous and potentially cross-reactive viral antigen. Further, the graphene platform can simultaneously provide the advanced quantitative data of nonclinical biophysical kinetics tools, making it adaptable to both clinical research and possible diagnostic applications. The speed, sensitivity, and selectivity of this first-of-its-kind graphene-enabled Zika biosensor make it an ideal candidate for development as a medical diagnostic test.
α-synuclein is the major component of filamentous Lewy bodies found in the brains of patients diagnosed with Parkinson’s disease. Recent studies demonstrate that, in addition to the wild-type sequence, α-synuclein is found in several modified forms, including truncated and phosphorylated species. Although the mechanism by which the neuronal loss in Parkinson’s disease occurs is unknown, aggregation and fibril formation of α-synuclein is considered to be a key pathological feature. In this study we analyze the rates of fibril formation and the monomer-fibril equilibrium for eight disease-associated truncated and phosphorylated α-synuclein variants. Comparison of the relative rates of aggregation reveals a strong monotonic relationship between the C-terminal charge of α-synuclein and the lag time prior to the observation of fibril formation, with truncated species exhibiting the fastest aggregation rates. Moreover, we find that a decrease in C-terminal charge shifts the equilibrium to favor the fibrillar species. An analysis of these findings in the context of linear growth theories suggests that the loss of the charge-mediated stabilization of the soluble state is responsible for the enhanced aggregation rate and increased extent of fibril fraction. Therefore, C-terminal charge is kinetically and thermodynamically protective against α-synuclein polymerization and may provide a target for the treatment of Parkinson’s Disease.
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