AI Article Synopsis
- Modern humans have mixed genetically with archaic hominins, particularly Denisovans, contributing up to 5% of Papuans' genome from these ancient relatives.
- Researchers examined 56 Papuan genomes to understand the effects of Denisovan and Neanderthal genetic variants in various cell types and functional elements, finding that archaic alleles are enriched in areas related to gene regulation and immune functions.
- They identified thousands of Denisovan and Neanderthal variants that could influence gene activity, validating the functional impact of some variants through experiments, which suggests archaic DNA plays a significant role in shaping modern human genetics and phenotypic traits, especially in non-African populations.
Article Abstract
Modern humans have admixed with multiple archaic hominins. Papuans, in particular, owe up to 5% of their genome to Denisovans, a sister group to Neanderthals whose remains have only been identified in Siberia and Tibet. Unfortunately, the biological and evolutionary significance of these introgression events remain poorly understood. Here we investigate the function of both Denisovan and Neanderthal alleles characterised within a set of 56 genomes from Papuan individuals. By comparing the distribution of archaic and non-archaic variants we assess the consequences of archaic admixture across a multitude of different cell types and functional elements. We observe an enrichment of archaic alleles within cis-regulatory elements and transcribed regions of the genome, with Denisovan variants strongly affecting elements active within immune-related cells. We identify 16,048 and 10,032 high-confidence Denisovan and Neanderthal variants that fall within annotated cis-regulatory elements and with the potential to alter the affinity of multiple transcription factors to their cognate DNA motifs, highlighting a likely mechanism by which introgressed DNA can impact phenotypes. Lastly, we experimentally validate these predictions by testing the regulatory potential of five Denisovan variants segregating within Papuan individuals, and find that two are associated with a significant reduction of transcriptional activity in plasmid reporter assays. Together, these data provide support for a widespread contribution of archaic DNA in shaping the present levels of modern human genetic diversity, with different archaic ancestries potentially affecting multiple phenotypic traits within non-Africans.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9731433 | PMC |
| http://dx.doi.org/10.1371/journal.pgen.1010470 | DOI Listing |
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