Mitochondrial Haplogroup X is associated with successful aging in the Amish

Courtenay, Monique D.; Gilbert, John R.; Jiang, Lan; Cummings, Anna; Gallins, Paul J.; Caywood, Laura J.; Reinhart-Mercer, Lori; Fuzzell, Denise; Knebusch, Claire; Laux, Reneé; McCauley, Jacob L.; Jackson, Charles E.; Pericak‐Vance, Margaret A.; Haines, Jonathan L.; Scott, William K.

doi:10.1007/s00439-011-1060-3

Cited by 26 publications

(16 citation statements)

References 45 publications

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“…Takasaki (2009) 3. Courtenay et al (2012)Within G3 b X2b b Within U6a b Within HV1a b 24G15928AT b 1. Association with idiopathic repeated pregnancy loss.…”

Section: Resultsmentioning

confidence: 99%

“…Similar to the T3394C RNM, the RNM G15927A (table 2, mutation number 23) that was identified as nodal in lineages B5b, a sub-lineage of G3, a sub-lineage of U6a, a sub-lineage of HV1a, and X2b associated with longevity in the frame of two of these lineages, that is, B5b (Takasaki 2009) and X2 (Courtenay et al 2012). However, low resolution of the X2 haplogroup assignment in the latter study prevented us from drawing more conclusive phenotypic association of the G15927A variant.…”

Section: Discussionmentioning

confidence: 96%

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Functional Recurrent Mutations in the Human Mitochondrial Phylogeny: Dual Roles in Evolution and Disease

Levin

Zhidkov

Gurman

et al. 2013

Genome Biology and Evolution

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Mutations frequently reoccur in the human mitochondrial DNA (mtDNA). However, it is unclear whether recurrent mtDNA nodal mutations (RNMs), that is, recurrent mutations in stems of unrelated phylogenetic nodes, are functional and hence selectively constrained. To answer this question, we performed comprehensive parsimony and maximum likelihood analyses of 9,868 publicly available whole human mtDNAs revealing 1,606 single nodal mutations (SNMs) and 679 RNMs. We then evaluated the potential functionality of synonymous, nonsynonymous and RNA SNMs and RNMs. For synonymous mutations, we have implemented the Codon Adaptation Index. For nonsynonymous mutations, we assessed evolutionary conservation, and employed previously described pathogenicity score assessment tools. For RNA genes’ mutations, we designed a bioinformatic tool which compiled evolutionary conservation and potential effect on RNA structure. While comparing the functionality scores of nonsynonymous and RNA SNMs and RNMs with those of disease-causing mtDNA mutations, we found significant difference (P < 0.001). However, 24 RNMs and 67 SNMs had comparable values with disease-causing mutations reflecting their potential function thus being the best candidates to participate in adaptive events of unrelated lineages. Strikingly, some functional RNMs occurred in unrelated mtDNA lineages that independently altered susceptibility to the same diseases, thus suggesting common functionality. To our knowledge, this is the most comprehensive analysis of selective signatures in the mtDNA not only within proteins but also within RNA genes. For the first time, we discover virtually all positively selected RNMs in our phylogeny while emphasizing their dual role in past evolutionary events and in disease today.

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“…Takasaki (2009) 3. Courtenay et al (2012)Within G3 b X2b b Within U6a b Within HV1a b 24G15928AT b 1. Association with idiopathic repeated pregnancy loss.…”

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 96%

Functional Recurrent Mutations in the Human Mitochondrial Phylogeny: Dual Roles in Evolution and Disease

Levin

Zhidkov

Gurman

et al. 2013

Genome Biology and Evolution

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“…mtDNA common variants altered the penetrance of disease-causing mutations, such as that of Leber’s hereditary optic neuropathy (LHON; Brown et al, 2002 ; Howell et al, 2003 ; Hudson et al, 2007 ; Zhang et al, 2010 ). Association was discovered between mtDNA common variants and altered susceptibility to various types of complex diseases in humans such as type 2 diabetes ( Mohlke et al, 2005 ; Fuku et al, 2007 ; Cormio et al, 2009 ; Feder et al, 2009 ), several heart diseases ( Castro et al, 2006 ; Nishigaki et al, 2007 ; Kofler et al, 2009 ; Palacin et al, 2011 ; Strauss et al, 2013 ), a variety of neurological phenotypes ( Chinnery et al, 2000 ; Carrieri et al, 2001 ; Pyle et al, 2005 ; Amar et al, 2007 ; Jones et al, 2007 ), age related macular degeneration ( Heher and Johns, 1993 ; Jones et al, 2007 ; Canter et al, 2008 ; SanGiovanni et al, 2009 ; Udar et al, 2009 ; Mueller et al, 2012b ; Kenney et al, 2013 ; Tilleul et al, 2013 ), but also of phenotypes such as longevity ( Rose et al, 2001 ; Dato et al, 2004 ; Shlush et al, 2008 ; Cai et al, 2009 ; Dominguez-Garrido et al, 2009 ; Takasaki, 2009 ; Courtenay et al, 2012 ), and sperm motility ( Ruiz-Pesini et al, 2000 ; Montiel-Sosa et al, 2006 ). Mammalian cell lines in which the mtDNA was depleted (Rho0 cells) and repopulated with different mitochondria carrying a diverged mtDNA genetic background showed differences in production of reactive oxygen species ( Moreno-Loshuertos et al, 2006 ; Mueller et al, 2012a ; Tiao et al, 2013 ), calcium uptake ( Kazuno et al, 2006 ), OXPHOS function ( Ji et al, 2012 ), and mtDNA copy number ( Suissa et al, 2009 ).…”

Section: Introductionmentioning

confidence: 99%

Mito-nuclear co-evolution: the positive and negative sides of functional ancient mutations

et al. 2014

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Most cell functions are carried out by interacting factors, thus underlying the functional importance of genetic interactions between genes, termed epistasis. Epistasis could be under strong selective pressures especially in conditions where the mutation rate of one of the interacting partners notably differs from the other. Accordingly, the order of magnitude higher mitochondrial DNA (mtDNA) mutation rate as compared to the nuclear DNA (nDNA) of all tested animals, should influence systems involving mitochondrial-nuclear (mito-nuclear) interactions. Such is the case of the energy producing oxidative phosphorylation (OXPHOS) and mitochondrial translational machineries which are comprised of factors encoded by both the mtDNA and the nDNA. Additionally, the mitochondrial RNA transcription and mtDNA replication systems are operated by nDNA-encoded proteins that bind mtDNA regulatory elements. As these systems are central to cell life there is strong selection toward mito-nuclear co-evolution to maintain their function. However, it is unclear whether (A) mito-nuclear co-evolution befalls only to retain mitochondrial functions during evolution or, also, (B) serves as an adaptive tool to adjust for the evolving energetic demands as species’ complexity increases. As the first step to answer these questions we discuss evidence of both negative and adaptive (positive) selection acting on the mtDNA and nDNA-encoded genes and the effect of both types of selection on mito-nuclear interacting factors. Emphasis is given to the crucial role of recurrent ancient (nodal) mutations in such selective events. We apply this point-of-view to the three available types of mito-nuclear co-evolution: protein–protein (within the OXPHOS system), protein-RNA (mainly within the mitochondrial ribosome), and protein-DNA (at the mitochondrial replication and transcription machineries).

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“…Sub-haplogroup N9a has also been found to protect its carriers from diabetes type 2 and metabolic syndrome [109] therefore, the protective effects against adverse outcomes after stroke may have been indirect. Mitochondrial haplogroups J, U, K and T and the unrelated haplogroup X were consistently seen more commonly in healthy individuals over 90 than in the healthy 'younger old' [95,110,111]. Carriership of haplogroup K (common in Western Europe and the British Islands) may protect against transient ischaemic attack and ischemic stroke [112].…”

Section: Breath Of Life (And Death) -Increased Atp Production Is Assomentioning

confidence: 99%

APOE4, oxidative stress and decreased repair capacity - a no-brainer. Faulty lipid metabolism and increased levels of oxidative damage may be risk factors in the pathogenesis of late-onset dementia

Nayyar

Chakalova²

2015

Biodiscovery

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Keywords: Late-onset disease, dementia, APOE, mitochondrial DNA, individual repair capacity.Abbreviations: AD -Alzheimer's disease, APOE -apolipoprotein E, ATP -adenosine triphosphate, BER -base excision repair, CAA -cerebral amyloid angiopathy, CNS -central nervous system, FTD -frontotemporal dementia, HD -Huntington's disease, IMT -intimamedia thickness, IRC -individual repair capacity, MCI -mild cognitive impairment, MND -motor neuron disease, NER -nucleotide excision repair, NMDA -N-methyl-D-aspartate, PD -Parkinson's disease, PDAPP -PDGF promoter expressing amyloid precursor protein, ROS -reactive oxygen species; SOD -superoxide dismutase, VCI -vascular cognitive decline.* Corresponding Authors: Ashima Nayyar, email: a.nayyar@abertay.ac.uk Conflict of Interests:No potential conflict of interest was disclosed by any of the authors. AbstractDementia is very common in the elderly and its incidence increases in an age-dependent fashion. Alzheimer's disease and vascular cognitive decline are the most common cases of dementia in the elderly. Amyloid burden and increased levels of oxidative damage have been implicated to play significant roles in the pathogenesis of late-onset dementia. In this paper we propose that there are three major genetic factors that may modulate the risk for dementia in later life: carriership of APOE variant alleles, carriership of mitochondrial DNA of haplogroups associated with ineffective oxygen utilisation (specifically, haplogroup H) and carriership of genetic polymorphisms conferring subtly deficient DNA repair. All three factors are quite common in the European populations. Each of these three factors may not have significant effect on the phenotype when taken separately, but when combined in the same genotype, the effects may be cumulative. Further studies are needed in order to elucidate the genotype-phenotype relationships and provide a reliable basis for assessment of the genetic risk for sporadic late-onset dementia. Lifestyle alterations and therapies targeted at decreasing the oxidative burden to aging cells and tissues may decrease the risk for neurological decline in later life.

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Mitochondrial Haplogroup X is associated with successful aging in the Amish

Cited by 26 publications

References 45 publications

Functional Recurrent Mutations in the Human Mitochondrial Phylogeny: Dual Roles in Evolution and Disease

Functional Recurrent Mutations in the Human Mitochondrial Phylogeny: Dual Roles in Evolution and Disease

Mito-nuclear co-evolution: the positive and negative sides of functional ancient mutations

APOE4, oxidative stress and decreased repair capacity - a no-brainer. Faulty lipid metabolism and increased levels of oxidative damage may be risk factors in the pathogenesis of late-onset dementia

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