Natural disease course and genotype‐phenotype correlations in Complex I deficiency caused by nuclear gene defects: what we learned from 130 cases

Koene, Saskia; Rodenburg, Richard J.; Knaap, Marjo S. van der; Willemsen, MA; Sperl, Wolfgang; Laugel, Vincent; Østergaard, Elsebet; Tarnopolsky, Mark A.; Martín, Miguel; Nesbitt, Victoria; Fletcher, Janice M.; Edvardson, Simon; Procaccio, Vincent; Slama, Abdelhamid; Heuvel, L.P.W.J. van den; Smeitink, Jan A.M.

doi:10.1007/s10545-012-9492-z

Cited by 112 publications

(148 citation statements)

References 73 publications

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“…Each OXPHOS complex comprises multiple subunits and requires the assistance of proteinaceous assembly factors to catalyze its biogenesis (Acin-Perez and Enriquez, 2014;Nouws et al, 2012). Mutations in structural subunits or assembly chaperones induce mitochondrial disease in humans (Koene et al, 2012;Loeffen et al, 2000;van den Heuvel and Smeitink, 2001). Inherited complex-I deficiencies are the most common OXPHOS disorders (Bénit et al, 2009), whereas myopathy has been linked to an off-target effect of statins on complex III (Schirris et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Acute stimulation of glucose influx upon mitoenergetic dysfunction requires LKB1, AMPK, Sirt2 and mTOR–RAPTOR

Liemburg-Apers

Wagenaars

Smeitink

et al. 2016

Journal of Cell Science

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Mitochondria play a central role in cellular energy production, and their dysfunction can trigger a compensatory increase in glycolytic flux to sustain cellular ATP levels. Here, we studied the mechanism of this homeostatic phenomenon in C2C12 myoblasts. Acute (30 min) mitoenergetic dysfunction induced by the mitochondrial inhibitors piericidin A and antimycin A stimulated Glut1-mediated glucose uptake without altering Glut1 (also known as SLC2A1) mRNA or plasma membrane levels. The serine/threonine liver kinase B1 (LKB1; also known as STK11) and AMP-activated protein kinase (AMPK) played a central role in this stimulation. In contrast, ataxiatelangiectasia mutated (ATM; a potential AMPK kinase) and hydroethidium (HEt)-oxidizing reactive oxygen species (ROS; increased in piericidin-A-and antimycin-A-treated cells) appeared not to be involved in the stimulation of glucose uptake. Treatment with mitochondrial inhibitors increased NAD + and NADH levels (associated with a lower NAD + :NADH ratio) but did not affect the level of Glut1 acetylation. Stimulation of glucose uptake was greatly reduced by chemical inhibition of Sirt2 or mTOR-RAPTOR. We propose that mitochondrial dysfunction triggers LKB1-mediated AMPK activation, which stimulates Sirt2 phosphorylation, leading to activation of mTOR-RAPTOR and Glut1-mediated glucose uptake.

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Section: Introductionmentioning

confidence: 99%

Acute stimulation of glucose influx upon mitoenergetic dysfunction requires LKB1, AMPK, Sirt2 and mTOR–RAPTOR

Liemburg-Apers

Wagenaars

Smeitink

et al. 2016

Journal of Cell Science

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“…This suggests that the cellular aberrations in the fibroblast model correlate with the clinical phenotype. Conversely, analysis of a cohort of 130 patients with CI deficiency (14 of which displayed an Ndufs4 mutation) revealed no correlation between the AOO/ AOD of the patients and residual CI activity in the patient fibroblasts (15). This suggests that sole analysis of residual CI activity is not predictive of disease prognosis in CI deficient patients.…”

Section: Mutations: Patient Fibroblastsmentioning

confidence: 94%

“…Since then, several other recessive Ndufs4 mutations have been identified resulting in CI deficiency (OMIM 252010): a single base deletion at position 289/290 in exon 3, a C316T transition in the same exon, a G44A nonsense mutation in exon 1, and a nonsense mutation (IVS1nt -1) in intron 1 of the NDUFS4 gene, all of which result in the absence of the NDUFS4 protein. In total, 14 NDUFS4 patients have currently been described in the literature (14,15). Clinically, these patients develop Leigh(-like) syndrome (LS) (6,15,16).…”

Section: Mutations: Patient Fibroblastsmentioning

confidence: 99%

“…In total, 14 NDUFS4 patients have currently been described in the literature (14,15). Clinically, these patients develop Leigh(-like) syndrome (LS) (6,15,16). LS is a multisystemic progressive neurodegenerative disorder of infancy.…”

Section: Mutations: Patient Fibroblastsmentioning

confidence: 99%

“…CI activity in fibroblasts from identified NDUFS4 patients analyzed so far ranges from 15% up to 75% enzyme activity of the lowest control value (15,22). During recent years, our group has focused on determining the cellular consequences of mutations in nDNA-encoded CI subunits, including NDUFS4 (2,6,25).…”

Section: Mutations: Patient Fibroblastsmentioning

confidence: 99%

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Cellular and animal models for mitochondrial complex I deficiency: A focus on the NDUFS4 subunit

et al. 2013

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To allow the rational design of effective treatment strategies for human mitochondrial disorders, a proper understanding of their biochemical and pathophysiological aspects is required. The development and evaluation of these strategies require suitable model systems. In humans, inherited complex I (CI) deficiency is one of the most common deficiencies of the mitochondrial oxidative phosphorylation system. During the last decade, various cellular and animal models of CI deficiency have been presented involving mutations and/or deletion of the Ndufs4 gene, which encodes the NDUFS4 subunit of CI. In this review, we discuss these models and their validity for studying human CI deficiency.

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Near-Identical Segregation of mtDNA Heteroplasmy in Blood, Muscle, Urinary Epithelium, and Hair Follicles in Twins With Optic Atrophy, Ptosis, and Intractable Epilepsy

et al. 2013

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Structured Abstract Importance Mitochondrial DNA (mtDNA) disorders have emerged as major cause of inherited neurological disease. Despite being well recognized for over two decades, the clinical presentation continues to broaden. The phenotypic heterogeneity is partly due to different percentage levels of mutant mtDNA heteroplasmy in different tissues, but the factors influencing this are poorly understood. Observations A case report describing monozygotic male twins with ptosis, optic atrophy, and recent onset intractable myoclonic epilepsy. The assessment of respiratory chain enzyme activities in muscle from one twin revealed a severe and isolated defect involving mitochondrial complex I. MtDNA sequencing revealed a pathogenic m.14487T>C MTND6 mutation, which was present at very high levels of heteroplasmy (84%) in muscle, and lower levels in blood (15%), urinary epithelium (75%), and buccal mucosa (58%). Of particular interest, his identical twin was found to harbor very similar levels of the m.14487T>C mutation in his blood, urine, buccal mucosa and hair follicle DNA samples, whilst the presence of low levels in the mother’s tissues confirmed maternal transmission. Conclusions and relevance m14487T>C can also cause the unusual combination of optic atrophy, ptosis, and encephalomyopathy leading to intractable seizures. Near-identical heteroplasmy levels in different tissues in both siblings supports a nuclear genetic mechanism controlling the tissue segregation of mtDNA mutations.

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Natural disease course and genotype‐phenotype correlations in Complex I deficiency caused by nuclear gene defects: what we learned from 130 cases

Cited by 112 publications

References 73 publications

Acute stimulation of glucose influx upon mitoenergetic dysfunction requires LKB1, AMPK, Sirt2 and mTOR–RAPTOR

Acute stimulation of glucose influx upon mitoenergetic dysfunction requires LKB1, AMPK, Sirt2 and mTOR–RAPTOR

Cellular and animal models for mitochondrial complex I deficiency: A focus on the NDUFS4 subunit

Near-Identical Segregation of mtDNA Heteroplasmy in Blood, Muscle, Urinary Epithelium, and Hair Follicles in Twins With Optic Atrophy, Ptosis, and Intractable Epilepsy

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