Recent studies have highlighted a potential role of genetic and epigenetic variation in the development of Alzheimer’s disease. Application of the CRISPR‐Cas genome‐editing platform has enabled investigation of the functional impact that Alzheimer’s disease‐associated gene mutations have on gene expression. Moreover, recent advances in the technology have led to the generation of CRISPR‐Cas–based tools that allow for high‐throughput interrogation of different risk variants to elucidate the interplay between genomic regulatory features, epigenetic modifications, and chromatin structure. In this review, we examine the various iterations of the CRISPR‐Cas system and their potential application for exploring the complex interactions and disruptions in gene regulatory circuits that contribute to Alzheimer’s disease.
Background Differentially methylated positions (DMPs) identified by Epigenome‐wide association studies (EWAS) of Alzheimer’s disease (AD) were modified by the CRISPR‐Cas9 system to investigate the role of epigenetic alterations in AD pathogenesis. Method Cell lines of neuronal phenotype (SH‐SY5Y) and microglial phenotype (IHM‐SV40) were used to explore the functional consequence of loci demethylation, where removal of the methyl groups was achieved by the modified CRISPR‐dCas9 system. Lentiviral delivery of the dCas9‐TET1CD demethylase tool and guide RNA (gRNA) constructs targeting the CpG sites associated with differential expression of ANK1 and BIN1 in AD was validated by fluorescence‐activated cell sorting (FACS). Bisulphite pyrosequencing was applied to confirm the DNA methylation edit. Result High transduction efficiencies were observed during FACS of SH‐SY5Y cells transduced with CRISPR‐dCas9 constructs targeting the BIN1 locus and IHM‐SV40 cells with constructs against the ANK1 locus. Methylation analysis of these target regions in the modified cell lines demonstrated a reduction in methylation when compared to the untreated control cells. This modification was maintained over a three‐week period. Conclusion Delivery and activity of our CRISPR‐dCas9 fusion constructs was demonstrated in cell line models of AD. In the future, we intend to profile the epigenome and transcriptome of these modified cell lines to identify any off‐target effects of the CRISPR‐dCas9 system and determine differences in mRNA transcript variant levels of our target genes.
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