Clonal expansion of mitochondrial DNA deletions is a private mechanism of aging in long‐lived animals

Lakshmanan, Lakshmi Narayanan; Yee, Zhuangli; Ng, Li Fang; Halliwell, Barry; Gruber, Jan

doi:10.1111/acel.12814

Cited by 33 publications

(24 citation statements)

References 59 publications

(129 reference statements)

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“…Further downstream sources of mitochondrial heterogeneity, such as translation errors, have also been shown to have physiological consequences in budding yeast (Suhm et al, 2018). The age-related functional decline of mitochondria in shorter-lived animals (Itsara et al, 2014; Brandt et al, 2017) might not be explained directly by mtDNA mutations (Vermulst et al, 2007; Lakshmanan et al, 2018) (see also recent, contrasting, results in Drosophila ; Kauppila T.E. et al, 2018; Samstag et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…Deletion mutations have been associated with local fiber atrophy and breakage in mice (Wanagat et al, 2001; Khrapko and Vijg, 2009) and rhesus monkeys (Aiken et al, 2002) (although the causative role of mtDNA mutations in aging for shorter-lived animals is contested; Vermulst et al, 2007; Kauppila T.E. et al, 2018; Lakshmanan et al, 2018). It is noteworthy that mitochondrial dysfunction in a particular tissue is able to induce stress responses in distal tissues through the mitochondrial unfolded protein response (Zhao et al, 2002; Durieux et al, 2011; Zhang et al, 2018) and other hormonal signaling pathways (Tyynismaa et al, 2010; Khan et al, 2017), suggesting potential organism-wide consequences of focal mitochondrial mutations.…”

Section: Genetic Sources Of Mitochondrial Heterogeneitymentioning

confidence: 99%

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Mitochondrial Heterogeneity

2019

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Cell-to-cell heterogeneity drives a range of (patho)physiologically important phenomena, such as cell fate and chemotherapeutic resistance. The role of metabolism, and particularly of mitochondria, is increasingly being recognized as an important explanatory factor in cell-to-cell heterogeneity. Most eukaryotic cells possess a population of mitochondria, in the sense that mitochondrial DNA (mtDNA) is held in multiple copies per cell, where the sequence of each molecule can vary. Hence, intra-cellular mitochondrial heterogeneity is possible, which can induce inter-cellular mitochondrial heterogeneity, and may drive aspects of cellular noise. In this review, we discuss sources of mitochondrial heterogeneity (variations between mitochondria in the same cell, and mitochondrial variations between supposedly identical cells) from both genetic and non-genetic perspectives, and mitochondrial genotype-phenotype links. We discuss the apparent homeostasis of mtDNA copy number, the observation of pervasive intra-cellular mtDNA mutation (which is termed “microheteroplasmy”), and developments in the understanding of inter-cellular mtDNA mutation (“macroheteroplasmy”). We point to the relationship between mitochondrial supercomplexes, cristal structure, pH, and cardiolipin as a potential amplifier of the mitochondrial genotype-phenotype link. We also discuss mitochondrial membrane potential and networks as sources of mitochondrial heterogeneity, and their influence upon the mitochondrial genome. Finally, we revisit the idea of mitochondrial complementation as a means of dampening mitochondrial genotype-phenotype links in light of recent experimental developments. The diverse sources of mitochondrial heterogeneity, as well as their increasingly recognized role in contributing to cellular heterogeneity, highlights the need for future single-cell mitochondrial measurements in the context of cellular noise studies.

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Section: Discussionmentioning

confidence: 99%

Section: Genetic Sources Of Mitochondrial Heterogeneitymentioning

confidence: 99%

Mitochondrial Heterogeneity

2019

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“…Over the course of an individual's lifespan, mtDNA mutations and deletions accumulate within cells and tissues; in some instances, mutant mtDNA propagates at an even faster rate than its wild-type counterparts (Trifunovic et al 2004;Lakshmanan et al 2018). It has been suggested that such age-related increases in mtDNA heteroplasmy may contribute to the onset and progression of various diseases (Cortopassi et al 1992;Chen et al 2011).…”

Section: Ddmdm To Quantify Common Mtdna Deletions: a Pilot Study In Cmentioning

confidence: 99%

Quantitative mitochondrial DNA copy number determination using droplet digital PCR with single-cell resolution

et al. 2019

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Mitochondria are involved in a number of diverse cellular functions, including energy production, metabolic regulation, apoptosis, calcium homeostasis, cell proliferation, and motility, as well as free radical generation. Mitochondrial DNA (mtDNA) is present at hundreds to thousands of copies per cell in a tissue-specific manner. mtDNA copy number also varies during aging and disease progression and therefore might be considered as a biomarker that mirrors alterations within the human body. Here, we present a new quantitative, highly sensitive droplet digital PCR (ddPCR) method, droplet digital mitochondrial DNA measurement (ddMDM), to measure mtDNA copy number not only from cell populations but also from single cells. Our developed assay can generate data in as little as 3 h, is optimized for 96-well plates, and also allows the direct use of cell lysates without the need for DNA purification or nuclear reference genes. We show that ddMDM is able to detect differences between samples whose mtDNA copy number was close enough as to be indistinguishable by other commonly used mtDNA quantitation methods. By utilizing ddMDM, we show quantitative changes in mtDNA content per cell across a wide variety of physiological contexts including cancer progression, cell cycle progression, human T cell activation, and human aging.

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“…MtDNA damage was assessed using Real Time-qPCR according to the published method. (Cristina et al, 2009;Lakshmanan et al, 2018) The pair of primers (Forward: GTTTATGCTGCTGTAGCGTG, Reverse: CTGTTAAAGCAAGTGGACGAG) were used to normalize the mitochondrial genome. The results were normalized to genomic DNA using primer pairs specific for ama-1(Forward: TGGAACTCTGGAGTCACACC, Reverse: CATCCTCCTTCATTGAACGG).…”

Section: Methodsmentioning

confidence: 99%

Mitochondria surveillance systems trigger innate immune responses to bacterial pathogens via AMPK pathway inC. elegans

Chen

Wang

et al. 2020

Preprint

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Pathogen recognition and triggering pattern of host innate immune system is critical to understanding pathogen-host interaction. It is generally accepted that the microbial infection can be recognized by host via pattern-triggered immunity (PTI) or effector-triggered immunity (ETI) responses. Recently, non-PRR-mediated cellular surveillance systems have been reported as an important supplement strategy to PTI and ETI responses. However, the mechanism of how surveillance systems sense pathogens and trigger innate immune responses is largely unknown. In the present study, using Bacillus thuringiensis-Caenorhabditis elegans as a model, we found a new approach for surveillance systems to sense the pathogens through no-PPRs patterns. We reported C. elegans can monitor intracellular energy status through the mitochondrial surveillance system to triggered innate immune responses against pathogenic attack via AMP-activated protein kinase (AMPK). Consider that the mitochondria surveillance systems and AMPK are conserved components from worms to mammals, our study suggests that disrupting mitochondrial homeostasis to activate the immune system through AMPK-dependent pathways may widely existing in animals.

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Clonal expansion of mitochondrial DNA deletions is a private mechanism of aging in long‐lived animals

Cited by 33 publications

References 59 publications

Mitochondrial Heterogeneity

Mitochondrial Heterogeneity

Quantitative mitochondrial DNA copy number determination using droplet digital PCR with single-cell resolution

Mitochondria surveillance systems trigger innate immune responses to bacterial pathogens via AMPK pathway inC. elegans

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