Ancient mitochondrial DNA pathogenic variants putatively associated with mitochondrial disease

Abstract

AbstractMitochondrial DNA variants associated with diseases are widely studied in contemporary populations, but their prevalence has not yet been investigated in ancient populations. The publicly available AmtDB database contains 1443 ancient mtDNA Eurasian genomes from different periods. The objective of this study was to use this data to establish the presence of pathogenic mtDNA variants putatively associated with mitochondrial diseases in ancient populations. The clinical significance, pathogenicity prediction and contemporary frequency of mtDNA variants were determined using online platforms. The analyzed ancient mtDNAs contain six variants designated as being “confirmed pathogenic” in modern patients. The oldest of these, m.7510T>C in the MT-TS1 gene, was found in a sample from the Neolithic period dated 5800-5400 BCE. All six have well established clinical association, and their pathogenic effect is corroborated by very low population frequencies in contemporary populations. In addition, ten variants designated as possibly or likely pathogenic were detected. The oldest of these were two variants in the MT-TD gene, m.7543A>G and m.7554G>A, from Neolithic samples dated 8205-7700 BCE. A novel mutation in contemporary populations, m.4440G>A in the MT-TM gene, is established in 12 ancient mtDNA samples from different periods ranging from 2800 BCE to 920 CE. The pathogenic effect of these possibly/likely pathogenic mutations is not yet well established, and further research is warranted. All detected mutations putatively associated with mitochondrial disease in ancient mtDNA samples are in tRNA coding genes. Most of these mutations are in a mt-tRNA type (Model 2) that is characterized by loss of D-loop/T-loop interaction. Seven mutations are located in CS-Anticodon stem, 4 are located in AS-Acceptor stem, 2 in TS-TΨC stem, and single mutations are found in DL-Dihydrouridine Loop, CL-Anticodon Loop and DS-Dihydrouridine stem. Exposing pathogenic variants in ancient human populations expands our understanding of their origin.