Dynamics of the most common pathogenic mtDNA variant m.3243A > G demonstrate frequency-dependency in blood and positive selection in the germline

Konstantin Popadin
OXFORD UNIV PRESS, 2022
Article

Résumé

The A-to-G point mutation at position 3243 in the human mitochondrial genome (m.3243A > G) is the most common pathogenic mtDNA variant responsible for disease in humans. It is widely accepted that m.3243A > G levels decrease in blood with age, and an age correction representing similar to 2% annual decline is often applied to account for this change in mutation level. Here we report that recent data indicate that the dynamics of m.3243A > G are more complex and depend on the mutation level in blood in a bi-phasic way. Consequently, the traditional 2% correction, which is adequate 'on average', creates opposite predictive biases at high and low mutation levels. Unbiased age correction is needed to circumvent these drawbacks of the standard model. We propose to eliminate both biases by using an approach where age correction depends on mutation level in a biphasic way to account for the dynamics of m.3243A > G in blood. The utility of this approach was further tested in estimating germline selection of m.3243A > G. The biphasic approach permitted us to uncover patterns consistent with the possibility of positive selection for m.3243A > G. Germline selection of m.3243A > G shows an 'arching' profile by which selection is positive at intermediate mutant fractions and declines at high and low mutant fractions. We conclude that use of this biphasic approach will greatly improve the accuracy of modelling changes in mtDNA mutation frequencies in the germline and in somatic cells during aging.

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Konstantin Popadin
OXFORD UNIV PRESS, 2022
Article

Résumé

Official source

https://infoscience.epfl.ch/record/296178?ln=fr

À propos de ce résultat

Concepts associés (19)

Concepts associés

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Publications associées (4)

Publications associées

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A Systematic Survey of an Intragenic Epistatic Landscape

Claudia Bank, Jeffrey David Jensen

Mutations are the source of evolutionary variation. The interactions of multiple mutations can have important effects on fitness and evolutionary trajectories. We have recently described the distribution of fitness effects of all single mutations for a nine-amino-acid region of yeast Hsp90 (Hsp82) implicated in substrate binding. Here, we report and discuss the distribution of intragenic epistatic effects within this region in seven Hsp90 point mutant backgrounds of neutral to slightly deleterious effect, resulting in an analysis of more than 1,000 double mutants. We find negative epistasis between substitutions to be common, and positive epistasis to be rare-resulting in a pattern that indicates a drastic change in the distribution of fitness effects one step away from the wild type. This can be well explained by a concave relationship between phenotype and genotype (i.e., a concave shape of the local fitness landscape), suggesting mutational robustness intrinsic to the local sequence space. Structural analyses indicate that, in this region, epistatic effects are most pronounced when a solvent-inaccessible position is involved in the interaction. In contrast, all 18 observations of positive epistasis involved at least one mutation at a solvent-exposed position. By combining the analysis of evolutionary and biophysical properties of an epistatic landscape, these results contribute to a more detailed understanding of the complexity of protein evolution.

Oxford Univ Press2015

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Genome-wide association (GWA) studies aim to dissect the relationship between genotype and phenotype. So far, the focus has been on nuclear genetic determinants as variation in the mitochondrial genome is often low in the study cohorts. Despite this observation, mitochondrial genomic variants are increasingly linked to metabolic and neurological disorders. Thus, there is much to gain from studying how mitochondrial variation interacts with nuclear variation and/or environment, and how this subsequently affects phenotypes. In my thesis I address these topics using Drosophila melanogaster as a model system, and specifically the Drosophila Genetic Reference Panel (DGRP). The DGRP consists of 200 sequenced and genetically diverse Drosophila populations and has been extensively used to study a wide-range of quantitative traits. However, in all of these studies, researchers have focussed on the influence of nuclear genetic variants in the absence of a high-resolution map of mitochondrial variants. To address this problem, we have developed a high-throughput method to specifically sequence mitochondrial DNA that enabled us to characterize mitochondrial genomic variation to an unprecedented depth. On average, each DGRP line had 25 mitochondrial variants (1 in 600 bp) and that most of the variants detected were unique for each line. However, we also found that some variants are more prevalent and show they can be used to construct mitochondrial haplotypes. We then used these haplotypes to test whether mitochondrial variation affected previously published phenotypes. We detected significant associations with 12 out of 259 publicly accessible phenotypes and found that these were mostly related to metabolism and responses to environmental cues. We selected one of the significant phenotypes, food intake in males, to verify our findings. We demonstrated the effect of mitochondrial haplotypes on the phenotype by swapping mitochondria from ¿high food intake¿ lines with mitochondria from ¿low food intake¿ lines and vice versa. We observed that, largely independent of the nuclear background, DGRP lines with a ¿high food intake mitochondria¿ consumed more food and concomitantly, DGRP lines with the ¿low food intake mitochondria¿ consumed less food. Furthermore, we investigated the influence of natural genetic variation was on the response to a high-fat diet. We designed a control and a high-fat diet and fed this to >100 DGRP lines and measured the lifespan on each diet. On average, lifespan was decreased by 48% on a high-fat diet, however this ranged from an increase of 2% to a decrease of 60% accentuating the complexity of the underlying genetic architecture. Our dataset was relatively small and limited our genome-wide and mitochondrial haplotype association analyses. Nonetheless, our GWA analysis detected variants related to genes involved in lipid metabolism and mitochondria but we did not detect significant associations with mitochondrial haplotypes. This suggests that while mitochondrial function may be important for the response to a high-fat diet, it is not dependent on the mitochondrial haplotype. Taken together, the work described in my thesis demonstrates the significance of accounting for mitochondrial haplotypes in phenotype association analyses. By doing so, it can open up new insights into genotype-to-phenotype relationships and gene regulation.

EPFL2018

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Multi-omics reveals abundant mitochondrial genomic and circadian expression variation in the Drosophila Genetic Reference Panel

Maria Litovchenko

Modern biology rapidly generates a wealth of data,which can only be analysed computationally.Despite the variety of available data types,most of them aim to provide an answer to one question: how does genotypic diversity translates into phenotypes? This question became central for this thesis where the computational analysis,via integration of genomics and transcriptomics,became the main method to unravel the full picture.Two biological processes were examined with this question in mind: mitochondrial genomics and circadian genomics and transcriptomics.First,to uncover the relationship between mitochondrial genetics and phenotypes,we produced a high quality catalogue of mitochondrial variants across 169 Drosophila Genetics Reference Panel (DGRP) lines.The high coverage and quality of the variant calls was achieved via developed mitochondrial DNA (mtDNA)-enriching method.The reliability of variant detection was supported by the low contamination rate of nuclear mitochondrial DNA fragments detected de-novo by a computational method developed in this thesis.Within the coding part of the mtDNA,231 variants were detected,most of them being SNPs.Based on the computed mitochondrial haplotypes,we revealed population structure despite common perception of its absence within the DGRP.Haplotype-phenotype associations with publicly available phenotypes showed a significant association with food intake in males which was further confirmed experimentally.At the molecular level,haplotypes did not reveal a strong association with mitochondrial protein complex quantity or activity.However,the activity showed greater variability between genotypes than haplotypes,therefore indicating a possible buffering effect.Furthermore,numerous mito-nuclear genome incompatibilities were detected computationally,but didn't affect tested phenotypes.Secondly,to determine the diversity of the circadian transcriptome across tissues and the influence of genetic diversity thereon,a vast dataset of 778 transcriptomes was produced.The first part of the dataset was an RNA-seq time series across four tissues of the w- reference fly strain.This dataset was used to reveal a high degree of tissue specificity of the circadian clock transcriptome,where the majority of the genes cycled restrictively in one tissue.Out of the 14 genes cycling in all tissues,7 weren't previously associated with the circadian rhythm.The evaluation of novel genes through the activity of flies with gene knockdowns revealed their functional relevance.Next,a cross tissue gene regulatory network indicated on a potential mechanism of tissue specific circadian expression: it is achieved through collaboration of core circadian transcription factors,such as clock,with other cycling and non-cycling TFs.The second part of the dataset consisted of static tissue specific transcriptomes of 141 DGRP lines.Tissue specific physiological time was computationally estimated and revealed a high variability across the samples suggesting underlying genetic components.For one of the samples the physiological time differed >10h from the harvesting time and displayed an abolished molecular rhythm,yet preserved its rhythmic behaviour.The genetic component underlying this observation was a newly identified cry allele disrupting the light sensing pathway.As a whole,this thesis demonstrates the utility of complex multi-omics approaches in modern biology and reveals new genetic determinants for food intake and circadian rhythm defects

EPFL2020

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Multi-omics reveals abundant mitochondrial genomic and circadian expression variation in the Drosophila Genetic Reference Panel

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