AI Article Synopsis
- Most existing methods for identifying identity by descent (IBD) segments only provide basic data without assessing the uncertainty of segment endpoints and lengths.
- We introduce a new method that estimates the probability distribution of IBD segment endpoints, factoring in issues like genotype errors and mutations, and is suitable for large datasets.
- Our findings indicate that this method improves the accuracy of identifying regions with recent natural selection, effectively filtering out false signals and aligning with previous studies on selection.
Article Abstract
Most methods for fast detection of identity by descent (IBD) segments report identity by state segments without any quantification of the uncertainty in the endpoints and lengths of the IBD segments. We present a method for determining the posterior probability distribution of IBD segment endpoints. Our approach accounts for genotype errors, recent mutations, and gene conversions which disrupt DNA sequence identity within IBD segments, and it can be applied to large cohorts with whole-genome sequence or SNP array data. We find that our method's estimates of uncertainty are well calibrated for homogeneous samples. We quantify endpoint uncertainty for 77.7 billion IBD segments from 408,883 individuals of white British ancestry in the UK Biobank, and we use these IBD segments to find regions showing evidence of recent natural selection. We show that many spurious selection signals are eliminated by the use of unbiased estimates of IBD segment endpoints and a pedigree-based genetic map. Eleven of the twelve regions with the greatest evidence for recent selection in our scan have been identified as selected in previous analyses using different approaches. Our computationally efficient method for quantifying IBD segment endpoint uncertainty is implemented in the open source ibd-ends software package.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7553009 | PMC |
| http://dx.doi.org/10.1016/j.ajhg.2020.09.010 | DOI Listing |
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