Mitochondrial network state scales mtDNA genetic dynamics

Aryaman, Juvid; Bowles, Charlotte; Jones, Nick; Johnston, Iain G.

doi:10.1101/409128

Cited by 15 publications

(31 citation statements)

References 92 publications

(203 reference statements)

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“…Previous work in plants, where mtDNA recombination produces diverse cellular mtDNA admixtures of potentially different selfishnesses, has shown that multilevel intra- or intercellular selection provides a way of combatting selfish proliferation ( 36 ). The pronounced role for mitochondrial dynamics in imposing intra-cellular quality control ( 30 ), captured by many of these models ( 50–54 , 75 ), suggests that tissue-specific mitochondrial dynamics may play an important role in this multilevel selection and mitigation of selfish proliferation ( 32 , 80 ).…”

Section: Discussionmentioning

confidence: 99%

MtDNA sequence features associated with ‘selfish genomes’ predict tissue-specific segregation and reversion

Røyrvik

Johnston

2020

Nucleic Acids Research

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Mitochondrial DNA (mtDNA) encodes cellular machinery vital for cell and organism survival. Mutations, genetic manipulation, and gene therapies may produce cells where different types of mtDNA coexist in admixed populations. In these admixtures, one mtDNA type is often observed to proliferate over another, with different types dominating in different tissues. This ‘segregation bias’ is a long-standing biological mystery that may pose challenges to modern mtDNA disease therapies, leading to substantial recent attention in biological and medical circles. Here, we show how an mtDNA sequence’s balance between replication and transcription, corresponding to molecular ‘selfishness’, in conjunction with cellular selection, can potentially modulate segregation bias. We combine a new replication-transcription-selection (RTS) model with a meta-analysis of existing data to show that this simple theory predicts complex tissue-specific patterns of segregation in mouse experiments, and reversion in human stem cells. We propose the stability of G-quadruplexes in the mtDNA control region, influencing the balance between transcription and replication primer formation, as a potential molecular mechanism governing this balance. Linking mtDNA sequence features, through this molecular mechanism, to cellular population dynamics, we use sequence data to obtain and verify the sequence-specific predictions from this hypothesis on segregation behaviour in mouse and human mtDNA.

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Section: Discussionmentioning

confidence: 99%

MtDNA sequence features associated with ‘selfish genomes’ predict tissue-specific segregation and reversion

Røyrvik

Johnston

2020

Nucleic Acids Research

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“…Mitochondrial network fragmentation is intimately involved in the mechanisms of mitophagy and may also enhance the breakdown of mtDNA (2,12). Altering the levels of the endogenous regulators of mitochondrial network architecture, including Drp1, Opa1 and Mfn1/2 (11), may therefore also impose changes to the mtDNA copy number.…”

Section: Tools and Techniques For Perturbing Mtdna Copy Numbermentioning

confidence: 99%

“…Mitochondrial DNA (mtDNA) encodes a variety of proteins, peptides, transfer RNAs and ribosomal RNAs that support the functions of mitochondria, and is thereby central to numerous physiological and pathophysiological processes including development, disease and ageing (1). Both the number of mtDNAs in a cell (mtDNA copy number) and the sequences of mtDNAs are important phenotypic determinants (2). Mutations of mtDNA can cause a spectrum of mitochondrial diseases where the clinical expression depends on the specific mutation and the degree of heteroplasmy (the proportion of mutated mtDNA in a single cell) between wild-type and mutant mtDNA (3,4).…”

Section: Introductionmentioning

confidence: 99%

“…Nucleoids contain complexes of mtDNA with proteins and other factors that comprise the machinery required for regulated transcription (8)(9)(10). The abundance and sequence of mtDNA can affect mitochondrial function while the mitochondrial network, which is regulated by dynamic fission and fusion events (11), can impact upon the turnover and copy number of mtDNA (2,12).…”

Section: Introductionmentioning

confidence: 99%

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Visualizing, quantifying, and manipulating mitochondrial DNA in vivo

Prole

Chinnery

Jones

2020

Journal of Biological Chemistry

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Mitochondrial DNA (mtDNA) encodes proteins and RNAs that support the functions of mitochondria and thereby numerous physiological processes. Mutations of mtDNA can cause mitochondrial diseases and are implicated in ageing. The mtDNA within cells is organized into nucleoids within the mitochondrial matrix, but how mtDNA nucleoids are formed and regulated within cells remains incompletely resolved. Visualization of mtDNA within cells is a powerful means by which mechanistic insight can be gained. Manipulation of the amount, and sequence of, mtDNA within cells is important experimentally and for developing therapeutic interventions to treat mitochondrial disease. This review details recent developments and opportunities for improvements in the experimental tools and techniques that can be used to visualize, quantify and manipulate the properties of mtDNA within cells.

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“…Our work establishes that mitochondrial deletions can expand in muscle fibres without a replicative advantage and, surprisingly, even if mutants are preferentially eliminated from the system. Despite being subject to higher rates of mitophagy -something that finds experimental support [36,37,38,39,40,41] -mutants can come to dominate zones of the fibres. We also predict that the expansion of deletions takes place through a travelling wave of mutants propagating in the muscle fibres.…”

Section: Introductionmentioning

confidence: 99%

Stochastic survival of the densest and mitochondrial DNA clonal expansion in ageing

Insalata

Hoitzing

Aryaman

et al. 2020

Preprint

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The expansion of deleted mitochondrial DNA (mtDNA) molecules has been linked to ageing, particularly in skeletal muscle fibres; its mechanism has remained unclear for three decades. Previous accounts assigned a replicative advantage to the deletions, but there is evidence that cells can, instead, selectively remove defective mtDNA. We present a spatial model that, without a replicative advantage, but instead through a combination of enhanced density for mutants and noise, produces a wave of expanding mutations with wave speed consistent with experimental data, unlike a standard model based on replicative advantage. We provide a formula that predicts that the wave speed drops with copy number, in agreement with experimental data. Crucially, our model yields travelling waves of mutants even if mutants are preferentially eliminated. Justified by this exemplar of how noise, density and spatial structure affect muscle ageing, we introduce the mechanism of stochastic survival of the densest, an alternative to replicative advantage, that may underpin other phenomena, like the evolution of altruism.

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Mitochondrial network state scales mtDNA genetic dynamics

Cited by 15 publications

References 92 publications

MtDNA sequence features associated with ‘selfish genomes’ predict tissue-specific segregation and reversion

MtDNA sequence features associated with ‘selfish genomes’ predict tissue-specific segregation and reversion

Visualizing, quantifying, and manipulating mitochondrial DNA in vivo

Stochastic survival of the densest and mitochondrial DNA clonal expansion in ageing

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