Mitochondrial Disease Sequence Data Resource (MSeqDR): A global grass-roots consortium to facilitate deposition, curation, annotation, and integrated analysis of genomic data for the mitochondrial disease clinical and research communities

Falk, Marni J.; Shen, Lishuang; Gonzalez, Michael; Leipzig, Jeremy; Lott, Marie T.; Stassen, Alphons P. M.; Diroma, Maria Angela; Navarro-Gómez, Daniel; Yeske, Philip E.; Bai, Renkui; Boles, Richard G.; Brilhante, Virginia; Ralph, David; DaRe, Jeana T.; Shelton, Robert; Terry, Sharon F.; Zhang, Zhe; Copeland, William C.; Oven, Mannis van; Prokisch, Holger; Wallace, Douglas C.; Attimonelli, Marcella; Krotoski, Danuta; Züchner, Stephan; Gai, Xiaowu; Bale, Sherri J.; Bedoyan, Jirair K.; Behar, Doron M.; Bonnen, Penelope E.; Brooks, Lisa; Calabrese, Claudia; Calvo, Sarah E.; Chinnery, Patrick F.; Christodoulou, John; Church, Deanna M.; Clima, Rosanna; Cohen, Bruce H.; Cotton, Richard G.H.; Coo, I.F.M. de; Derbenevoa, Olga; Dunnen, Johan T. den; Dimmock, David; Enns, Gregory M.; Gasparre, Giuseppe; Goldstein, Amy; Gonzalez, Iris L.; Gwinn, Katrina; Hahn, Sihoun; Haas, Richard; Hákonarson, Hákon; Hirano, Michio; Kerr, Douglas S.; Liu, Dong; Lvova, Maria; Macrae, Finley; Maglott, Donna; McCormick, Elizabeth; Mitchell, Grant; Mootha, Vamsi K.; Okazaki, Yasushi; Pujol, Aurora; Parisi, Melissa A.; Perín, Juan C.; Pierce, Eric A.; Procaccio, Vincent; Rahman, Shamima; Honey, Reddi; Rehm, Heidi L.; Riggs, Erin Rooney; Rodenburg, Richard J.; Rubinstein, Yaffa; Saneto, Russell P.; Santorsola, Mariangela; Scharfe, Curt; Sheldon, Claire A.; Shoubridge, Eric A.; Simone, Domenico; Smeets, Boudewijn J. J.; Smeitink, Jan A.M.; Stanley, Christine M.; Suomalainen, Anu; Tarnopolsky, Mark A.; Thiffault, Isabelle; Thorburn, David R.; Hove, Johan Van; Wolfe, Lynne A.; Wong, Lee Jun

doi:10.1016/j.ymgme.2014.11.016

Cited by 78 publications

(61 citation statements)

References 21 publications

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“…Furthermore, both mitochondrial dysfunction and downregulation of PGC-1α are present in Huntington's disease, Alzheimer's disease, and Parkinson's disease, providing further support for a relationship between mitochondrial function and PGC-1α (Miraglia et al, 2015;Rice et al, 2015). Although a mitochondrial origin for these diseases has been proposed (Falk et al, 2015), regulation of mitochondrial biogenesis in the context of these diseases has not been extensively studied. In this study, we established cell lines in which PGC-1α was overexpressed or knocked down to investigate the signaling pathways by which PGC-1α could influence cell growth.…”

Section: Discussionmentioning

confidence: 99%

PGC-1α regulates the cell cycle through ATP and ROS in CH1 cells

Yao

et al. 2016

J. Zhejiang Univ. Sci. B

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Abstract:Peroxisome proliferator-activated receptor-γ coactivator 1α (PGC-1α) is a transcriptional co-activator involved in mitochondrial biogenesis, respiratory capacity, and oxidative phosphorylation (OXPHOS). PGC-1α plays an important role in cellular metabolism and is associated with tumorigenesis, suggesting an involvement in cell cycle progression. However, the underlying mechanisms mediating its involvement in these processes remain unclear. To elucidate the signaling pathways involved in PGC-1α function, we established a cell line, CH1 PGC-1α, which stably overexpresses PGC-1α. Using this cell line, we found that over-expression of PGC-1α stimulated extra adenosine triphosphate (ATP) and reduced reactive oxygen species (ROS) production. These effects were accompanied by up-regulation of the cell cycle checkpoint regulators CyclinD1 and CyclinB1. We hypothesized that ATP and ROS function as cellular signals to regulate cyclins and control cell cycle progression. Indeed, we found that reduction of ATP levels down-regulated CyclinD1 but not CyclinB1, whereas elevation of ROS levels down-regulated CyclinB1 but not CyclinD1. Furthermore, both low ATP levels and elevated ROS levels inhibited cell growth, but PGC-1α was maintained at a constant level. Together, these results demonstrate that PGC-1α regulates cell cycle progression through modulation of CyclinD1 and CyclinB1 by ATP and ROS. These findings suggest that PGC-1α potentially coordinates energy metabolism together with the cell cycle.

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Section: Discussionmentioning

confidence: 99%

PGC-1α regulates the cell cycle through ATP and ROS in CH1 cells

Yao

et al. 2016

J. Zhejiang Univ. Sci. B

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“…These studies are possible because mtDNA is transmitted as a nonrecombining unit through maternal lineages, provides an exceptional record of mutations over time (Ingman et al 2000;Meyer et al 1999;Tamura 2000), and is present in numerous copies in each cell, and because databases of entire human mtDNA sequences are readily available for comparison (Falk et al 2015;Shokolenko and Alexeyev 2015).…”

Section: Background Mitochondrial Dnamentioning

confidence: 99%

Genetic Affiliation of Pre-Hispanic and Contemporary Mayas through Maternal Linage

Ochoa-Lugo¹,

Muñoz²,

Pérez-Ramírez³

et al. 2016

Human Biology

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Maya civilization developed in Mesoamerica and encompassed the Yucatan Peninsula, Guatemala, Belize, part of the Mexican states of Tabasco and Chiapas, and the western parts of Honduras and El Salvador. This civilization persisted approximately 3,000 years and was one of the most advanced of its time, possessing the only known full writing system at the time, as well as art, sophisticated architecture, and mathematical and astronomical systems. This civilization reached the apex of its power and influence during the Preclassic period, from 2000 BCE to 250 CE. Genetic variation in the pre-Hispanic Mayas from archaeological sites in the Mexican states of Yucatan, Chiapas, Quintana Roo, and Tabasco and their relationship with the contemporary communities in these regions have not been previously studied. Consequently, the principal aim of this study was to determine mitochondrial DNA (mtDNA) variation in the pre-Hispanic Maya population and to assess the relationship of these individuals with contemporary Mesoamerican Maya and populations from Asia, Beringia, and North, Central, and South America. Our results revealed interactions and gene flow between populations in the different archaeological sites assessed in this study. The mtDNA haplogroup frequency in the pre-Hispanic Maya population (60.53%, 34.21%, and 5.26% for haplogroups A, C, and D, respectively) was similar to that of most Mexican and Guatemalan Maya populations, with haplogroup A exhibiting the highest frequency. Haplogroup B most likely arrived independently and mixed with populations carrying haplogroups A and C based on its absence in the pre-Hispanic Mexican Maya populations and low frequencies in most Mexican and Guatemalan Maya populations, although this also may be due to drift. Maya and Ciboneys sharing haplotype H10 belonged to haplogroup C1 and haplotype H4 of haplogroup D, suggesting shared regional haplotypes. This may indicate a shared genetic ancestry, suggesting more regional interaction between populations in the circum-Caribbean region than previously demonstrated. Haplotype sharing between the pre-Hispanic Maya and the indigenous populations from Asia, the Aleutian Islands, and North, Maternal Lineage in Pre-Hispanic and Contemporary Mayas ■ 137Central, and South America provides evidence for gene flow from the ancestral Amerindian population of the pre-Hispanic Maya to Central and South America.

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“…These “canonical criteria” are as follows: (1) the mutation is not a known neutral polymorphism; (2) the mutation must be in an evolutionarily conserved site, suggesting a functional role for the SNP; (3) the mutation is usually heteroplasmic; (4) for heteroplasmic variants, the degree of heteroplasmy should correlate clinically with a phenotype; and (5) the mutation can be corroborated biochemically using tissue samples (initially described with muscle biopsy). With respect to determining whether a particular variant is novel or not, several databases exist, including dbSNP [25], MITOMAP [26], mtDB [27], PhyloTree [28] and MSeqDR [29]. We currently refer to mtDB and MSeqDR for most applications.…”

Section: Mitochondrial Geneticsmentioning

confidence: 99%

The Complex Interaction of Mitochondrial Genetics and Mitochondrial Pathways in Psychiatric Disease

et al. 2018

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While accounting for only 2% of the body’s weight, the brain utilizes up to 20% of the body’s total energy. Not surprisingly, metabolic dysfunction and energy supply-and-demand mismatch have been implicated in a variety of neurological and psychiatric disorders. Mitochondria are responsible for providing the brain with most of its energetic demands, and the brain uses glucose as its exclusive energy source. Exploring the role of mitochondrial dysfunction in the etiology of psychiatric disease is a promising avenue to investigate further. Genetic analysis of mitochondrial activity is a cornerstone in understanding disease pathogenesis related to metabolic dysfunction. In concert with neuroimaging and pathological study, genetics provides an important bridge between biochemical findings and clinical correlates in psychiatric disease. Mitochondrial genetics has several unique aspects to its analysis, and corresponding special considerations. Here, we review the components of mitochondrial genetic analysis – nuclear DNA, mitochondrial DNA, mitochondrial pathways, pseudogenes, nuclear-mitochondrial mismatch, and microRNAs – that could contribute to an observable clinical phenotype. Throughout, we highlight psychiatric diseases that can arise due to dysfunction in these processes, with a focus on schizophrenia and bipolar disorder.

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Mitochondrial Disease Sequence Data Resource (MSeqDR): A global grass-roots consortium to facilitate deposition, curation, annotation, and integrated analysis of genomic data for the mitochondrial disease clinical and research communities

Cited by 78 publications

References 21 publications

PGC-1α regulates the cell cycle through ATP and ROS in CH1 cells

PGC-1α regulates the cell cycle through ATP and ROS in CH1 cells

Genetic Affiliation of Pre-Hispanic and Contemporary Mayas through Maternal Linage

The Complex Interaction of Mitochondrial Genetics and Mitochondrial Pathways in Psychiatric Disease

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