Abstract
BACKGROUND: Cellular defenses against retrotransposable elements (RTEs) weaken with age and RTEs have been reported to contribute to Alzheimer's disease (AD) pathogenesis by promoting neuroinflammation. The mechanisms implicated include DNA damage promoted by retrotransposition and interferon system activation by RTE-derived cDNA intermediates. LINE-1 (L1) retrotransposons are of particular interest because they are the only autonomously active RTEs in the human genome. RESULTS: To investigate L1 activation and retrotransposition in AD, we performed Nanopore long-read DNA sequencing on six late-onset AD (LOAD) and six age-matched control human prefrontal cortex (PFC) samples. We developed and validated a stringent RTE insertion calling pipeline and identified two high-confidence somatic insertions, one AluY and one L1HS. We estimate that ∼1% of cells in the aged PFC have a somatic RTE insertion. AD samples were hypomethylated, and genome-wide analysis of differentially methylated regions (DMRs) supports a process of epigenetic drift in AD. DMR-associated gene sets primarily related to brain function and inflammation. To investigate L1 activation we used CpG methylation as a proxy for L1 expression. We observed decreased methylation at young L1 elements. While most reads overlapping the L1HS promoter were highly methylated (>80% methylated), 7% were <50% methylated, 1% were <25%, and the highly demethylated read fraction increased in AD. L1HS 5' UTR methylation was strongly correlated with RNA expression. CONCLUSIONS: CpG methylation-mediated repression of young RTEs is compromised in old age - our findings indicate that this is further exacerbated in AD. Amid these failing defenses, we report somatic retrotransposition events in the aging and demented brain.