Huntingtin aggregation impairs autophagy leading to Argonaute-2 accumulation and global microRNA dysregulation

Many neurodegenerative diseases are characterized by the presence of intracellular protein aggregates resulting in alterations in autophagy. However, the consequences of impaired autophagy on neuronal function remain poorly understood. In this study, we used cell culture and mouse models of huntingtin protein aggregation, as well as post-mortem material from patients with Huntington’s disease to demonstrate that Argonaute-2 (AGO2) accumulates in the presence of neuronal protein aggregates and that this is due to impaired autophagy. Accumulation of AGO2, a key factor of the RNA-induced silencing complex that executes microRNA functions, results in global alterations of microRNA levels and activity. Together these results demonstrate that impaired autophagy found in neurodegenerative diseases not only influences protein aggregation, but also directly contributes to global alterations of intracellular post-transcriptional networks.The work was supported by grants from the Swedish Research Council (# K2014-62X-22527-01-3 and K2014-62X-20404-08-5), the Swedish Foundation for Strategic Research (# FFL12-0074), the Swedish Brain Foundation (# FO2014-0106); the Swedish excellence project Basal Ganglia Disorders Linnaeus Consortium (Bagadilico), and the Swedish Government Initiative for Strategic Research Areas (MultiPark & StemTherapy)

Sleep and Circadian Rhythm Regulation in Early Parkinson Disease

Importance: Sleep disturbances are recognized as a common nonmotor complaint in Parkinson disease but their etiology is poorly understood. Objective: To define the sleep and circadian phenotype of patients with early-stage Parkinson disease. Design, Setting, and Participants: Initial assessment of sleep characteristics in a large population-representative incident Parkinson disease cohort (N=239) at the University of Cambridge, England, followed by further comprehensive case-control sleep assessments in a subgroup of these patients (n=30) and matched controls (n=15). Main Outcomes and Measures: Sleep diagnoses and sleep architecture based on polysomnography studies, actigraphy assessment, and 24-hour analyses of serum cortisol, melatonin, and peripheral clock gene expression (Bmal1, Per2, and Rev-Erbα). Results: Subjective sleep complaints were present in almost half of newly diagnosed patients and correlated significantly with poorer quality of life. Patients with Parkinson disease exhibited increased sleep latency (P = .04), reduced sleep efficiency (P = .008), and reduced rapid eye movement sleep (P = .02). In addition, there was a sustained elevation of serum cortisol levels, reduced circulating melatonin levels, and altered Bmal1 expression in patients with Parkinson disease compared with controls. Conclusions and Relevance: Sleep dysfunction seen in early Parkinson disease may reflect a more fundamental pathology in the molecular clock underlying circadian rhythms

TREM2, Tau and ApoE in choroid plexus in AD pathology

Background: Genetic factors that influence AD risk include mutations in TREM2 and allelic variants of Apolipoprotein-E, influencing AD pathology in the general population and in Down syndrome (DS). Evidence shows that dysfunction of the choroid plexus (CP) may compromise the blood-CSF barrier, altering secretary, transport and immune function that can affect AD pathology Objective: To investigate the genotype and phenotype of DS individuals in relation to choroid plexus damage and blood-CSF barrier leakage to identify markers that could facilitate early diagnosis of AD in DS. Methods: To assess allele frequency and haplotype associations ApoE, Tau, TREM2 and HLADR were analysed by SNP analysis in DS participants (n=47) and controls (n = 50). The corresponding plasma protein levels were measured by ELISA. Post-mortem brains from DS, AD and age matched controls were analysed by immunohistochemistry. Results: Haplotype analysis showed that individuals with Tau H1/H1 and ApoE 4 genotypes were more prevalent among DS participants with an earlier diagnosis of dementia (17%) compared to H1/H2 haplotypes (6%). Plasma TREM2 levels decreased whereas phospho-Tau levels increased with age in DS. In AD and DS brain insoluble Tau and ApoE were found to accumulate in the choroid plexus. Conclusion: Accumulation of Tau and ApoE in the choroid plexus may increase the oligomerisation rate of Aβ42 and impair Tau trafficking, leading to AD pathology. We have identified a high-risk haplotype: ApoE 4, Tau/ H1 and TREM2/T, that manifests age-related changes potentially opening a window for treatment many years prior to the manifestation of the AD dementia

Hypothalamic volume loss is associated with reduced melatonin output in Parkinson's disease.

BACKGROUND: Recent studies have suggested that melatonin-a hormone produced by the pineal gland under circadian control-contributes to PD-related sleep dysfunction. We hypothesized that degenerative changes to the neural structures controlling pineal function (especially the suprachiasmatic nuclei of the anterior hypothalamus) may be responsible for reduced melatonin output in these patients. We compared hypothalamic volumes in PD patients with matched controls and determined whether volume loss correlated with reduced melatonin output in the PD group. METHODS: A total of 12 PD patients and 12 matched controls underwent magnetic resonance imaging to determine hypothalamic volume. In addition, PD patients underwent 24-hour blood sampling in a controlled environment to determine serum melatonin concentrations using enzyme-linked immunosorbent assays. RESULTS: PD patients had significantly reduced hypothalamic gray matter volume when compared with matched controls. Melatonin levels were significantly associated with hypothalamic gray matter volume and disease severity in PD patients. CONCLUSION: Melatonin levels are associated with hypothalamic gray matter volume loss and disease severity in PD patients. This provides anatomical and physiological support for an intrinsic sleep and circadian phenotype in PD. © 2016 The Authors. Movement Disorders published by Wiley Periodicals, Inc. on behalf of International Parkinson and Movement Disorder Society.The authors would like to acknowledge the study funders: the Big Lottery Fund (C498A738) and Parkinson’s UK (J-0802). The research was supported by a National Institute of Health Research Biomedical Research Award (to Addenbrooke’s Hospital/University of Cambridge), the Wellcome Trust (103838, 100333/Z/12/Z) and a Raymond and Beverly Sackler Studentship (to DPB). We would like to thank staff at the Wellcome Trust Clinical Research Facility in Addenbrooke’s Hospital, Cambridge for performing the melatonin blood sampling.This is the final version of the article. It first appeared from Wiley via http://dx.doi.org/10.1002/mds.2659

The role of tau in the pathological process and clinical expression of Huntington's disease.

Huntington's disease is a neurodegenerative disorder caused by an abnormal CAG repeat expansion within exon 1 of the huntingtin gene HTT. While several genetic modifiers, distinct from the Huntington's disease locus itself, have been identified as being linked to the clinical expression and progression of Huntington's disease, the exact molecular mechanisms driving its pathogenic cascade and clinical features, especially the dementia, are not fully understood. Recently the microtubule associated protein tau, MAPT, which is associated with several neurodegenerative disorders, has been implicated in Huntington's disease. We explored this association in more detail at the neuropathological, genetic and clinical level. We first investigated tau pathology by looking for the presence of hyperphosphorylated tau aggregates, co-localization of tau with mutant HTT and its oligomeric intermediates in post-mortem brain samples from patients with Huntington's disease (n = 16) compared to cases with a known tauopathy and healthy controls. Next, we undertook a genotype-phenotype analysis of a large cohort of patients with Huntington's disease (n = 960) with a particular focus on cognitive decline. We report not only on the tau pathology in the Huntington's disease brain but also the association between genetic variation in tau gene and the clinical expression and progression of the disease. We found extensive pathological inclusions containing abnormally phosphorylated tau protein that co-localized in some instances with mutant HTT. We confirmed this related to the disease process rather than age, by showing it is also present in two patients with young-onset Huntington's disease (26 and 40 years old at death). In addition we demonstrate that tau oligomers (suggested to be the most likely neurotoxic tau entity) are present in the Huntington's disease brains. Finally we highlight the clinical significance of this pathology by demonstrating that the MAPT haplotypes affect the rate of cognitive decline in a large cohort of patients with Huntington's disease. Our findings therefore highlight a novel important role of tau in the pathogenic process and clinical expression of Huntington's disease, which in turn opens up new therapeutic avenues for this incurable condition.The authors thank the EHDN REGISTRY Study Group investigators (listed in the Supplementary material) for collecting the data and all participating REGISTRY patients for their time and efforts, the Cambridge Brain Bank for the post-mortem tissue which is supported by a grant to the NIHR Cambridge Biomedical Research Centre and in particular to J. Wilson and Dr D. O’ Donovan. We are grateful to S. Sawcer and M. Ban in the Neurology Unit at the University of Cambridge, for their help with the genotyping, C.H. Williams-Gray at the John van Geest Centre for Brain Repair, University of Cambridge, for her help with the statistical analyses, J. Hardy, J.L. Holton, and T. Revesz at the UCL Institute of Neurology for their helpful discussions as well as K. Strand, F. Javad and A. Posada Bórbon, at the UCL Institute of Neurology, for their support with the experimental work, R. Kayed at the University of Texas Medical Branch, Galveston, for providing the TOMA and T22 antibodies. Finally, P. Tyers, R. Raha-Chowdhury, A. Tolkovsky, B. Ossola and J. Simpson for their support and encouragement throughout this work.This is the final version of the article. It was first available from Oxford University Press viahttp://dx.doi.org/10.1093/brain/awv10

Neuroprotective Effect of TREM-2 in Aging and Alzheimer's Disease Model.

Neuroinflammation and activation of innate immunity are early events in neurodegenerative diseases including Alzheimer's disease (AD). Recently, a rare mutation in the gene Triggering receptor expressed on myeloid cells 2 (TREM2) has been associated with a substantial increase in the risk of developing late onset AD. To uncover the molecular mechanisms underlying this association, we investigated the RNA and protein expression of TREM2 in APP/PS1 transgenic mice. Our findings suggest that TREM2 not only plays a critical role in inflammation, but is also involved in neuronal cell survival and in neurogenesis. We have shown that TREM2 is a soluble protein transported by macrophages through ventricle walls and choroid plexus, and then enters the brain parenchyma via radial glial cells. TREM2 protein is essential for neuroplasticity and myelination. During the late stages of life, a lack of TREM2 protein may accelerate aging processes and neuronal cell loss and reduce microglial activity, ultimately leading to neuroinflammation. As inflammation plays a major role in neurodegenerative diseases, a lack of TREM2 could be a missing link between immunomodulation and neuroprotection.Medical Research Council (Grant ID: RNAG/254), National Institute of Health Research, The John Van Geest Foundation, Cambridgeshire and Peterborough Foundation NHS TrustThis is the author accepted manuscript. The final version is available from IOS Press via https://doi.org/10.3233/JAD-16066

Association Between Toll‐Like Receptor 4 ( TLR4 ) and Triggering Receptor Expressed on Myeloid Cells 2 ( TREM2 ) Genetic Variants and Clinical Progression of Huntington's Disease

Background: Although Huntington's disease (HD) is caused by a single dominant gene, it is clear that there are genetic modifiers that may influence the age of onset and disease progression. Objectives: We sought to investigate whether new inflammation‐related genetic variants may contribute to the onset and progression of HD. Methods: We first used postmortem brain material from patients at different stages of HD to look at the protein expression of toll‐like receptor 4 (TLR4) and triggering receptor expressed on myeloid cells 2 (TREM2). We then genotyped the TREM2 R47H gene variant and 3 TLR4 single nucleotide polymorphisms in a large cohort of HD patients from the European Huntington's Disease Network REGISTRY. Results: We found an increase in the number of cells expressing TREM2 and TLR4 in postmortem brain samples from patients dying with HD. We also found that the TREM2 R47H gene variant was associated with changes in cognitive decline in the large cohort of HD patients, whereas 2 of 3 TLR4 single nucleotide polymorphisms assessed were associated with changes in motor progression in this same group. Conclusions: These findings identify TREM2 and TLR4 as potential genetic modifiers for HD and suggest that inflammation influences disease progression in this condition. © 2019 International Parkinson and Movement Disorder Societ

Choroid Plexus Acts as Gatekeeper for TREM2, Abnormal Accumulation of ApoE, and Fibrillary Tau in Alzheimer's Disease and in Down Syndrome Dementia.

BACKGROUND: Genetic factors that influence Alzheimer's disease (AD) risk include mutations in TREM2 and allelic variants of Apolipoprotein E, influencing AD pathology in the general population and in Down syndrome (DS). Evidence shows that dysfunction of the choroid plexus may compromise the blood-cerebrospinal fluid (CSF) barrier, altering secretary, transport and immune function that can affect AD pathology. OBJECTIVE: To investigate the genotype and phenotype of DS individuals in relation to choroid plexus damage and blood-CSF barrier leakage to identify markers that could facilitate early diagnosis of AD in DS. METHODS: To assess allele frequency and haplotype associations ApoE, Tau, TREM2, and HLA-DR were analyzed by SNP analysis in DS participants (n = 47) and controls (n = 50). The corresponding plasma protein levels were measured by ELISA. Postmortem brains from DS, AD, and age-matched controls were analyzed by immunohistochemistry. RESULTS: Haplotype analysis showed that individuals with Tau H1/H1 and ApoEɛ4 genotypes were more prevalent among DS participants with an earlier diagnosis of dementia (17%) compared to H1/H2 haplotypes (6%). Plasma TREM2 levels decreased whereas phospho-tau levels increased with age in DS. In AD and DS brain, insoluble tau and ApoE were found to accumulate in the choroid plexus. CONCLUSION: Accumulation of tau and ApoE in the choroid plexus may increase the oligomerization rate of Aβ42 and impair tau trafficking, leading to AD pathology. We have identified a high-risk haplotype: ApoEɛ4, Tau/H1, and TREM2/T, that manifests age-related changes potentially opening a window for treatment many years prior to the manifestation of the AD dementia.This research was funded by Medical Research Council (MRC grant number RNAG/254), Alzheimer’s Research UK (ARUK), National Institute of Health Research (NIHR), the Down’s Syndrome Association, The John Van Geest Foundation, and the Health Foundation and Cambridgeshire and Peterborough Foundation NHS Trust, Cambridge, UK