Abstract
BRCA1 and BRCA2 (BRCA) play essential roles in maintaining genome stability. BRCA germline pathogenic variants increase cancer risk. However, the evolutionary origin of human BRCA pathogenic variants remains largely elusive. We tested the 2,972 human BRCA1 and 3,652 human BRCA2 pathogenic variants from ClinVar database in 100 vertebrates across eight clades, but failed to find evidence to show cross-species evolution conservation as the origin; we searched the variants in 2,792 ancient human genome data, and identified 28 BRCA1 and 22 BRCA2 pathogenic variants in 44 cases dated from 45,000 to 300 yr ago; we analyzed the haplotype-dated human BRCA pathogenic founder variants, and observed that they were mostly arisen within the past 3,000 yr; we traced ethnic distribution of human BRCA pathogenic variants, and found that the majority were present in single or a few ethnic populations. Based on the data, we propose that human BRCA pathogenic variants were highly likely arisen in recent human history after the latest out-of-Africa migration, and the expansion of modern human population could largely increase the variation spectrum.
Highlights
Repairing the damaged DNA by environmental and metabolic factors is vital for all lives on earth
We identified a total of 6,624 BRCA PLP variants (2,972 in BRCA1 and 3,652 in BRCA2) from the ClinVar database for the study (Tables 1 and S2)
We identified 172 (5.8%) human BRCA1 PLP variants shared with 69 species, and 312 (8.6%) human BRCA2 PLP variants shared with 90 species (Figs 1, 2, and S1A and Tables S3 and S4)
Summary
Repairing the damaged DNA by environmental and metabolic factors is vital for all lives on earth. In eukaryotes, this is achieved by the DNA damage repair system composed of multiple pathways to repair different types of DNA damage (Jeggo et al, 2016). The positive selection likely resulted in the new function of BRCA gained in these three species, such as promoting immunity to counter viral infection (Lou et al, 2014), regulating gene expression and metabolism (Rosen et al, 2006; Chen et al, 2020), enhancing neural development (Pao et al, 2014), and increasing reproduction (Smith et al, 2013)
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