A comprehensive study of tandem repeat variation as a cause of Alzheimer's disease - Tandem Repeat Expansions (TREs), most commonly of triplet repeats such as poly(CAG), are known to underlie >40 different human neurological diseases. While the majority of TREs identified to date have been found in late-onset neuro-degenerative disorders such as hereditary ataxias and Huntington disease, TREs have been identified in patients with AD and certain types of dementia. In addition to these expansions of short tandem repeats (STRs, with motif sizes between 1 and 6 base pairs), copy number variation of larger repeats with motifs ≥10bp, also known as Variable Number of Tandem Repeats (VNTRs), has recently been linked to risk of AD. However, despite this evidence that variation in tandem repeat (TR) sequences can act as the causative mutations in some cases of AD and dementia, there have been no concerted efforts in AD cohorts to either systematically screen for novel TREs, or to genotype VNTR copy numbers. Newly developed bioinformatic approaches that can be applied to analyze Whole Genome Sequencing (WGS) data now provide an opportunity to fill this knowledge gap. Utilizing the expertise and knowledge that we have gained working on other large datasets, we propose to apply these approaches to analyze ~62,000 genomes sequenced by the Alzheimer's Disease Sequencing Project that are available to the community, in addition to a further ~48,000 control genomes from TOPMed, and will use these data to investigate two major hypotheses: 1. We hypothesize that some cases of AD are caused by rare, highly penetrant pathogenic TREs. Using novel bioinformatic tools that can identify TREs, we will search for rare TREs that are observed only in AD samples, or which show significant enrichment in AD cases compared to controls, and thus are likely causative for AD. Potentially pathogenic TREs will then be validated by PCR or long-read sequencing in available DNA samples. 2. We hypothesize that common polymorphic copy number variation of TRs of all motif sizes can act as genetic risk factors for AD. Short tandem repeats (STRs) with motif sizes 1-6bp will be genotyped with hipSTR. VNTRs will be genotyped using read depth to estimate diploid copy number. We will analyze available WGS data from ~20,000 sporadic late-onset AD samples and ~90,000 unrelated controls, generating copy number estimates for >1 million STRs and ~150,000 VNTRs genome-wide, which will be used to perform association analysis of TR copy number with AD status in a case:control study. Given that TREs, and polymorphic variation in STRs and VNTRs, both represent established mutational mechanisms that contribute to a variety of late-onset neuro-degenerative conditions, we believe that the study of TRs in AD represents a logical step that has a high likelihood of uncovering novel genetic causes of AD.
