Alzheimer's disorder (AD) is a neurodegenerative disease characterized by progressive cognitive deterioration affecting in excess of 25 million people worldwide. In addition to the characteristic dementia seen in AD, many patients exhibit a range of non-cognitive symptoms that include depression, aggression, delusions and hallucinations. Whilst the neuropathological changes associated with AD have been well characterized in post-mortem brain tissue, little is known about either the underlying etiology of the disorder or the precise mechanisms behind disease progression. In this project we propose to look beyond the traditional genetic and neuropathological etiological approaches to AD by testing the hypothesis that epigenetic phenomena play a crucial role in the development of the disorder. Using a highly-powered sequential replication design and two complementary methylomic profiling methodologies, we aim to identify epigenetic dysfunction associated with the disorder across multiple brain regions in the largest sample of well-characterized post-mortem AD brains yet investigated. We also plan to determine whether specific epigenomic signatures are associated with AD+psychosis and AD+depression clinical subtypes using a unique collection of post-mortem brains from individuals for whom detailed clinical data has been collected prior to death. Where verified promoter DNA methylation changes are consistently observed, the expression of downstream genes will be assessed using RNA obtained from the same tissue source. In addition, other epigenetic modifications linked to transcriptional regulation will be investigated using gene- specific chromatin immunoprecipitation (ChIP) to further investigate loci nominated by the genome-wide methylomic screen. Furthermore, we will utilize laser capture microdissection of affected brain tissue to investigate whether observed epigenetic changes are a consequence of the neurodegenerative processes associated with AD (i.e. differential cell death and gliosis) or the result of epigenomic changes in the remaining neurones. The final stage of our project will be to test verified epimutations, detected in our screen of post-mortem brain tissue, in peripheral blood DNA samples obtained from the same individuals prior to their death, and subsequently in a large independent collection of blood DNA samples obtained from ongoing clinical cohort studies. Our goals of identifying a) molecular changes in the brain associated with AD and associated neuropsychiatric co-morbidities, and b) peripheral epigenetic biomarkers correlated with the changes occurring in the brain has the potential to impact greatly upon the clinical diagnosis, prognosis and future treatment of AD. Given the potential reversibility of epigenetic phenomena, and previous data highlighting ways in which drugs can affect epigenetic processing in the brain, it is hoped that our analyses will highlight novel pathways for the development of therapeutic interventions for AD and the neuropsychiatric symptoms associated with the disease. Public Health Relevance: Alzheimer's disorder is a neurodegenerative disease characterized by progressive cognitive deterioration affecting in excess of 25 million people worldwide, with the total yearly treatment and care costs estimated to be ~$250 billion. In addition to the characteristic dementia seen in Alzheimer's disorder, many patients exhibit a range of non-cognitive symptoms that include depression, aggression, delusions and hallucinations;these neuropsychiatric syndromes affect >80% of patients, impacting greatly upon the manifestation, treatment and prognosis of the disorder. Increasing our understanding about the causes of the disorder is thus of great public health importance, particularly given the aging trajectory of the population. This study aims to transform our understanding about the etiology of Alzheimer's disorder by uncovering evidence for epigenetic disruption in post-mortem brain tissue and peripheral cells obtained from affected individuals.

Public Health Relevance

Alzheimer's disorder is a neurodegenerative disease characterized by progressive cognitive deterioration affecting in excess of 25 million people worldwide, with the total yearly treatment and care costs estimated to be ~$250 billion. In addition to the characteristic dementia seen in Alzheimer's disorder, many patients exhibit a range of non-cognitive symptoms that include depression, aggression, delusions and hallucinations;these neuropsychiatric syndromes affect >80% of patients, impacting greatly upon the manifestation, treatment and prognosis of the disorder. Increasing our understanding about the causes of the disorder is thus of great public health importance, particularly given the aging trajectory of the population. This study aims to transform our understanding about the etiology of Alzheimer's disorder by uncovering evidence for epigenetic disruption in post-mortem brain tissue and peripheral cells obtained from affected individuals.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Research Project (R01)
Project #
5R01AG036039-02
Application #
7934592
Study Section
Special Emphasis Panel (ZRG1-GGG-M (53))
Program Officer
Petanceska, Suzana
Project Start
2009-09-30
Project End
2013-08-31
Budget Start
2010-09-01
Budget End
2011-08-31
Support Year
2
Fiscal Year
2010
Total Cost
$487,698
Indirect Cost
Name
King's College London
Department
Type
DUNS #
231876178
City
London
State
Country
United Kingdom
Zip Code
WC2 -2LS
Viana, Joana; Hannon, Eilis; Dempster, Emma et al. (2017) Schizophrenia-associated methylomic variation: molecular signatures of disease and polygenic risk burden across multiple brain regions. Hum Mol Genet 26:210-225
Smith, Adam R; Smith, Rebecca G; Condliffe, Daniel et al. (2016) Increased DNA methylation near TREM2 is consistently seen in the superior temporal gyrus in Alzheimer's disease brain. Neurobiol Aging 47:35-40
Hannon, Eilis; Spiers, Helen; Viana, Joana et al. (2016) Methylation QTLs in the developing brain and their enrichment in schizophrenia risk loci. Nat Neurosci 19:48-54
Devall, Matthew; Roubroeks, Janou; Mill, Jonathan et al. (2016) Epigenetic regulation of mitochondrial function in neurodegenerative disease: New insights from advances in genomic technologies. Neurosci Lett 625:47-55
Hannon, Eilis; Dempster, Emma; Viana, Joana et al. (2016) An integrated genetic-epigenetic analysis of schizophrenia: evidence for co-localization of genetic associations and differential DNA methylation. Genome Biol 17:176
Marzi, Sarah J; Meaburn, Emma L; Dempster, Emma L et al. (2016) Tissue-specific patterns of allelically-skewed DNA methylation. Epigenetics 11:24-35
Bakulski, Kelly M; Halladay, Alycia; Hu, Valerie W et al. (2016) Epigenetic Research in Neuropsychiatric Disorders: the ""Tissue Issue"". Curr Behav Neurosci Rep 3:264-274
Lunnon, Katie; Hannon, Eilis; Smith, Rebecca G et al. (2016) Variation in 5-hydroxymethylcytosine across human cortex and cerebellum. Genome Biol 17:27
Fisher, Helen L; Murphy, Therese M; Arseneault, Louise et al. (2015) Methylomic analysis of monozygotic twins discordant for childhood psychotic symptoms. Epigenetics 10:1014-23
Lunnon, Katie; Smith, Rebecca G; Cooper, Itzik et al. (2015) Blood methylomic signatures of presymptomatic dementia in elderly subjects with type 2 diabetes mellitus. Neurobiol Aging 36:1600.e1-4

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