Investigating Mitonuclear Genetic Interactions Through Machine Learning: A Case Study on Cold Adaptation Genes in Human Populations From Different European Climate Regions

Overview

Journal Front Physiol

Date 2020 Dec 2

PMID 33262703

Citations 1

Authors

Alena Kalyakulina

Vincenzo Iannuzzi

Marco Sazzini

Paolo Garagnani

Sarika Jalan

Claudio Franceschi

Mikhail Ivanchenko

Cristina Giuliani

Affiliations

Soon will be listed here.

Abstract

Cold climates represent one of the major environmental challenges that anatomically modern humans faced during their dispersal out of Africa. The related adaptive traits have been achieved by modulation of thermogenesis and thermoregulation processes where nuclear (nuc) and mitochondrial (mt) genes play a major role. In human populations, mitonuclear genetic interactions are the result of both the peculiar genetic history of each human group and the different environments they have long occupied. This study aims to investigate mitonuclear genetic interactions by considering all the mitochondrial genes and 28 nuclear genes involved in brown adipose tissue metabolism, which have been previously hypothesized to be crucial for cold adaptation. For this purpose, we focused on three human populations (i.e., Finnish, British, and Central Italian people) of European ancestry from different biogeographical and climatic areas, and we used a machine learning approach to identify relevant nucDNA-mtDNA interactions that characterized each population. The obtained results are twofold: (i) at the methodological level, we demonstrated that a machine learning approach is able to detect patterns of genetic structure among human groups from different latitudes both at single genes and by considering combinations of mtDNA and nucDNA loci; (ii) at the biological level, the analysis identified population-specific nuclear genes and variants that likely play a relevant biological role in association with a mitochondrial gene (such as the "obesity gene" in Finnish people). Further studies are needed to fully elucidate the evolutionary dynamics (e.g., migration, admixture, and/or local adaptation) that shaped these nucDNA-mtDNA interactions and their functional role.

Citing Articles

Analysis of human mitochondrial genome co-occurrence networks of Asian population at varying altitudes.

Verma R, Kalyakulina A, Giuliani C, Shinde P, Kachhvah A, Ivanchenko M Sci Rep. 2021; 11(1):133.

PMID: 33420243 PMC: 7794584. DOI: 10.1038/s41598-020-80271-8.

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