Targeted bisulfite sequencing analysis of candidate genes associated with Alzheimer's disease.

Abstract

The histopathological changes in Alzheimer's disease (AD), including extensive deposits of amyloid β plaques and neurofibrillary tangles occur many years before the onset of clinical symptoms and epigenetic processes such as DNA methylation may contribute to this delay. Recent epigenome-wide association studies (EWAS) have identified a number of loci in specific genes that show robust and reproducible alterations in DNA methylation changes in AD brain samples. However, the technologies used for these studies only assess a limited number of methylation sites in each gene and further analysis of methylation changes across the entire gene are required to determine the exact extent and pattern of methylation changes in disease. In this study we have performed targeted bisulfite sequencing and RNA sequencing in the Brains for Dementia Research (BDR) tissue sample resource, which is a highly characterised cohort containing tissue with a high degree of standardised pathological, clinical and administrative data available to allow comparative studies. Prefrontal cortex brain samples from 96 individuals were selected from the BDR cohort and grouped by Braak stage (Control 0-II; mild cognitive impairment III-IV; AD V-VI). DNA and RNA was simultaneously extracted before next generation RNA-seq was performed on all 96 samples to analyse the AD transcriptome and data extracted for 30 genomic regions of interest identified from previous EWAS. Concurrently for the DNA, Agilent Sure Select target baits captured the same 30 target genomic regions that were bisulfite sequenced for a subset of 60 samples, allowing analysis of differentially methylated positions (DMPs). The exact location of DMPs within the targeted genomic regions were identified and compared between each group. Similarly, differential expression of mRNA transcripts encoded by these genes were also identified and related to methylation levels. This study builds on previous work that identified differential methylation in several genomic regions that were associated with Braak stage. By identifying the exact positions that are subjected to differential methylation and the potential impact these changes have on gene expression this work provides further evidence that dysregulation of methylation is associated with pathological changes in AD prefrontal cortex.