CSP alpha reduces aggregates and rescues striatal dopamine release in alpha-synuclein transgenic mice

alpha-Synuclein aggregation at the synapse is an early event in Parkinson's disease and is associated with impaired striatal synaptic function and dopaminergic neuronal death. The cysteine string protein (CSP alpha) and alpha-synuclein have partially overlapping roles in maintaining synaptic function and mutations in each cause neurodegenerative diseases. CSP alpha is a member of the DNAJ/HSP40 family of co-chaperones and like alpha-synuclein, chaperones the SNARE complex assembly and controls neurotransmitter release. alpha-Synuclein can rescue neurodegeneration in CSP alpha KO mice. However, whether alpha-synuclein aggregation alters CSP alpha expression and function is unknown. Here we show that alpha-synuclein aggregation at the synapse is associated with a decrease in synaptic CSP alpha and a reduction in the complexes that CSP alpha forms with HSC70 and STG alpha. We further show that viral delivery of CSP alpha rescues in uitro the impaired vesicle recycling in PC12 cells with alpha-synuclein aggregates and in uiuo reduces synaptic alpha-synuclein aggregates increasing monomeric alpha-synuclein and restoring normal dopamine release in 1-120h alpha Syn mice. These novel findings reveal a mechanism by which alpha-synuclein aggregation alters CSP alpha at the synapse, and show that CSP alpha rescues alpha-synuclein aggregation-related phenotype in 1-120h alpha Syn mice similar to the effect of alpha-synuclein in CSP alpha KO mice. These results implicate CSP alpha as a potential therapeutic target for the treatment of earlystage Parkinson's disease

Alpha Synuclein only Forms Fibrils In Vitro when Larger than its Critical Size of 70 Monomers

Funder: UK Dementia Research Institute; Id: http://dx.doi.org/10.13039/501100017510Funder: DRI Ltd.Funder: UK Medical Research CouncilFunder: Alzheimer's SocietyFunder: Alzheimer's Research UKFunder: Royal Society; Id: http://dx.doi.org/10.13039/501100000288Funder: Herchel Smith Postdoctoral Research FellowshipAbstract: The aggregation of α‐synuclein into small soluble aggregates and then fibrils is important in the development and spreading of aggregates through the brain in Parkinson's disease. Fibrillar aggregates can grow by monomer addition and then break into fragments that could spread into neighboring cells. The rate constants for fibril elongation and fragmentation have been measured but it is not known how large an aggregate needs to be before fibril formation is thermodynamically favorable. This critical size is an important parameter controlling at what stage in an aggregation reaction fibrils can form and replicate. We determined this value to be approximately 70 monomers using super‐resolution and atomic force microscopy imaging of individual α‐synuclein aggregates formed in solution over long time periods. This represents the minimum size for a stable α‐synuclein fibril and we hypothesis the formation of aggregates of this size in a cell represents a tipping point at which rapid replication occurs

In vivo rate-determining steps of tau seed accumulation in Alzheimer's disease.

[Figure: see text].We acknowledge funding from Sidney Sussex College Cambridge (GM) and the European Research Council Grant Number 669237 (to D.K.) and the Royal Society (to D.K.). The Cambridge Brain Bank is supported by the NIHR Cambridge Biomedical Research Centre

Super-resolution imaging reveals α-synuclein seeded aggregation in SH-SY5Y cells

Funder: Royal Society; doi: https://doi.org/10.13039/501100000288Funder: UK Dementia Research InstituteAbstract: Aggregation of α-synuclein (α-syn) is closely linked to Parkinson’s disease (PD) and the related synucleinopathies. Aggregates spread through the brain during the progression of PD, but the mechanism by which this occurs is still not known. One possibility is a self-propagating, templated-seeding mechanism, but this cannot be established without quantitative information about the efficiencies and rates of the key steps in the cellular process. To address this issue, we imaged the uptake and seeding of unlabeled exogenous α-syn fibrils by SH-SY5Y cells and the resulting secreted aggregates, using super-resolution microscopy. Externally-applied fibrils very inefficiently induced self-assembly of endogenous α-syn in a process accelerated by the proteasome. Seeding resulted in the increased secretion of nanoscopic aggregates (mean 35 nm diameter), of both α-syn and Aβ. Our results suggest that cells respond to seed-induced disruption of protein homeostasis predominantly by secreting nanoscopic aggregates; this mechanism may therefore be an important protective response by cells to protein aggregation

Super-resolution imaging reveals α-synuclein seeded aggregation in SH-SY5Y cells.

Funder: Royal Society; doi: https://doi.org/10.13039/501100000288Funder: UK Dementia Research InstituteAggregation of α-synuclein (α-syn) is closely linked to Parkinson's disease (PD) and the related synucleinopathies. Aggregates spread through the brain during the progression of PD, but the mechanism by which this occurs is still not known. One possibility is a self-propagating, templated-seeding mechanism, but this cannot be established without quantitative information about the efficiencies and rates of the key steps in the cellular process. To address this issue, we imaged the uptake and seeding of unlabeled exogenous α-syn fibrils by SH-SY5Y cells and the resulting secreted aggregates, using super-resolution microscopy. Externally-applied fibrils very inefficiently induced self-assembly of endogenous α-syn in a process accelerated by the proteasome. Seeding resulted in the increased secretion of nanoscopic aggregates (mean 35 nm diameter), of both α-syn and Aβ. Our results suggest that cells respond to seed-induced disruption of protein homeostasis predominantly by secreting nanoscopic aggregates; this mechanism may therefore be an important protective response by cells to protein aggregation.This work was supported by the UK Dementia Research Institute which receives its funding from DRI Ltd., funded by the UK Medical Research Council, Alzheimer’s Society and Alzheimer’s Research UK, and by the European Research Council Grant Number 669237 and the Royal Society

Super-resolution imaging reveals α-synuclein seeded aggregation in SH-SY5Y cells.

Aggregation of α-synuclein (α-syn) is closely linked to Parkinson's disease (PD) and the related synucleinopathies. Aggregates spread through the brain during the progression of PD, but the mechanism by which this occurs is still not known. One possibility is a self-propagating, templated-seeding mechanism, but this cannot be established without quantitative information about the efficiencies and rates of the key steps in the cellular process. To address this issue, we imaged the uptake and seeding of unlabeled exogenous α-syn fibrils by SH-SY5Y cells and the resulting secreted aggregates, using super-resolution microscopy. Externally-applied fibrils very inefficiently induced self-assembly of endogenous α-syn in a process accelerated by the proteasome. Seeding resulted in the increased secretion of nanoscopic aggregates (mean 35 nm diameter), of both α-syn and Aβ. Our results suggest that cells respond to seed-induced disruption of protein homeostasis predominantly by secreting nanoscopic aggregates; this mechanism may therefore be an important protective response by cells to protein aggregation

Accurate digital quantification of tau pathology in progressive supranuclear palsy

Acknowledgements: We would like to thank the people who kindly donated their brains for this study, and their families. The Cambridge Bank is supported by the NIHR Cambridge Biomedical Research Centre (NIHR203312).Funder: Progressive Supranuclear Palsy Association; doi: http://dx.doi.org/10.13039/501100008177Funder: Lundbeck Foundation; doi: http://dx.doi.org/10.13039/501100003554AbstractThe development of novel treatments for Progressive Supranuclear Palsy (PSP) is hindered by a knowledge gap of the impact of neurodegenerative neuropathology on brain structure and function. The current standard practice for measuring postmortem tau histology is semi-quantitative assessment, which is prone to inter-rater variability, time-consuming and difficult to scale. We developed and optimized a tau aggregate type-specific quantification pipeline for cortical and subcortical regions, in human brain donors with PSP. We quantified 4 tau objects (‘neurofibrillary tangles’, ‘coiled bodies’, ‘tufted astrocytes’, and ‘tau fragments’) using a probabilistic random forest machine learning classifier. The tau pipeline achieved high classification performance (F1-score &gt; 0.90), comparable to neuropathologist inter-rater reliability in the held-out test set. Using 240 AT8 slides from 32 postmortem brains, the tau burden was correlated against the PSP pathology staging scheme using Spearman’s rank correlation. We assessed whether clinical severity (PSP rating scale, PSPRS) score reflects neuropathological severity inferred from PSP stage and tau burden using Bayesian linear mixed regression. Tufted astrocyte density in cortical regions and coiled body density in subcortical regions showed the highest correlation to PSP stage (r = 0.62 and r = 0.38, respectively). Using traditional manual staging, only PSP patients in stage 6, not earlier stages, had significantly higher clinical severity than stage 2. Cortical tau density and neurofibrillary tangle density in subcortical regions correlated with clinical severity. Overall, our data indicate the potential for highly accurate digital tau aggregate type-specific quantification for neurodegenerative tauopathies; and the importance of studying tau aggregate type-specific burden in different brain regions as opposed to overall tau, to gain insights into the pathogenesis and progression of tauopathies.</jats:p

CSPα reduces aggregates and rescues striatal dopamine release in α-synuclein transgenic mice.

α-Synuclein aggregation at the synapse is an early event in Parkinson's disease and is associated with impaired striatal synaptic function and dopaminergic neuronal death. The cysteine string protein (CSPα) and α-synuclein have partially overlapping roles in maintaining synaptic function and mutations in each cause neurodegenerative diseases. CSPα is a member of the DNAJ/HSP40 family of co-chaperones and like α-synuclein, chaperones the SNARE complex assembly and controls neurotransmitter release. α-Synuclein can rescue neurodegeneration in CSPαKO mice. However, whether α-synuclein aggregation alters CSPα expression and function is unknown. Here we show that α-synuclein aggregation at the synapse is associated with a decrease in synaptic CSPα and a reduction in the complexes that CSPα forms with HSC70 and STGa. We further show that viral delivery of CSPα rescues in vitro the impaired vesicle recycling in PC12 cells with α-synuclein aggregates and in vivo reduces synaptic α-synuclein aggregates increasing monomeric α-synuclein and restoring normal dopamine release in 1-120hαSyn mice. These novel findings reveal a mechanism by which α-synuclein aggregation alters CSPα at the synapse, and show that CSPα rescues α-synuclein aggregation-related phenotype in 1-120hαSyn mice similar to the effect of α-synuclein in CSPαKO mice. These results implicate CSPα as a potential therapeutic target for the treatment of early-stage Parkinson's disease.MJ Fox Foundation, Cure PD trust, Parkinson’s UK, UK Dementia Research Institute (funded by MRC, Alz Soc., ARUK)

A computational suite for the structural and functional characterization of amyloid aggregates

We developed the Aggregate Characterisation Toolkit (ACT); a fully automated computational suite based on existing and widely used core algorithms to measure the number, size and permeabilizing activity of recombinant and human-derived aggregates imaged with diffraction-limited and super-resolution microscopy methods at high throughput. We have validated ACT on simulated ground-truth images of aggregates mimicking those from diffraction-limited and super-resolution microscopies and showcased its use in characterising protein aggregates from Alzheimer’s disease. ACT is developed for high-throughput, batch processing of images collected from multiple samples and is available as an open-source code. Given its accuracy, speed and accessibility, ACT is expected to be a fundamental tool in studying human and non-human amyloid intermediates, developing early disease stage diagnostics and screening for antibodies that bind toxic and heterogeneous human amyloid aggregates

Super-resolution imaging unveils the self-replication of tau aggregates upon seeding.

Tau is a soluble protein interacting with tubulin to stabilize microtubules. However, under pathological conditions, it becomes hyperphosphorylated and aggregates, a process that can be induced by treating cells with exogenously added tau fibrils. Here, we employ single-molecule localization microscopy to resolve the aggregate species formed in early stages of seeded tau aggregation. We report that entry of sufficient tau assemblies into the cytosol induces the self-replication of small tau aggregates, with a doubling time of 5 h inside HEK cells and 1 day in murine primary neurons, which then grow into fibrils. Seeding occurs in the vicinity of the microtubule cytoskeleton, is accelerated by the proteasome, and results in release of small assemblies into the media. In the absence of seeding, cells still spontaneously form small aggregates at lower levels. Overall, our work provides a quantitative picture of the early stages of templated seeded tau aggregation in cells.This work was supported by the UK Dementia Research Institute, which receives its funding from DRI Ltd., funded by the UK Medical Research Council, Alzheimer’s Society, and Alzheimer’s Research. T.K. and W.A.M. have received funding from the Innovative Medicines Initiative 2 Joint Undertaking under grant agreement 116060 (IMPRiND). This Joint Undertaking receives support from the European Union’s Horizon 2020 Research and Innovation Program and EFPIA. This work is supported by the Swiss State Secretariat for Education, Research, and Innovation (SERI) under contract 17.00038. WAM was funded by a Sir Henry Dale Fellowship jointly funded by the Wellcome Trust and the Royal Society (Grant Number 206248/Z/17/Z) and by the Lister Institute for Preventative Medicine. During this work E.D. was funded by a Deutsche Forschungsgemeinschaft Research Fellowship (426806622) and an EMBO Fellowship (ALTF 173-2019). J.Y.L.L. is supported by the Croucher Foundation Limited (Hong Kong)