Syndromic parkinsonism and dementia associated with <scp><i>OPA</i></scp><i>1</i> missense mutations

Carelli, Valerio; Musumeci, Olimpia; Caporali, Leonardo; Zanna, Claudia; Morgia, Chiara La; Dotto, Valentina Del; Porcelli, Anna Maria; Rugolo, Michela; Valentino, Maria Lucia; Iommarini, Luisa; Maresca, Alessandra; Barboni, Piero; Carbonelli, Michele; Trombetta, C. J.; Valente, Enza Maria; Patergnani, Simone; Giorgi, Carlotta; Pinton, Paolo; Rizzo, Giovanni; Tonon, Caterina; Lodi, Raffaele; Avoni, Patrizia; Liguori, Rocco; Baruzzi, Agostino; Toscano, Antonio; Zeviani, Massimo

doi:10.1002/ana.24410

Cited by 150 publications

(105 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Instead, our data suggest that a late defect in complex I may account for the reduction of electron transport across the respiratory chain as evidenced by the decreased maximal respiration in mutant neurons and the reduction of complex I levels and activity. Functional changes in complex I were previously reported in fibroblasts with OPA1 haploinsufficiency18 or the p.G488R mutation9 and in models of acute OPA1 depletion, where respiratory efficiency was impaired when mitochondria were energized specifically with the complex I substrates, glutamate/malate 17. Therefore, in human iPSC‐derived neurons, OPA1 levels are important for the maintenance of oxidative phosphorylation, at least partly, by regulating the stability of complex I.…”

Section: Discussionmentioning

confidence: 94%

“…Our initial whole‐exome analysis did not identify a secondary mutation of known pathogenicity, but does not exclude the contribution of multiple minor genetic determinants such as effects on autophagy, which is activated in cells carrying a mutant OPA1 allele9, 25 or microtubule‐associated transport, which is important for axonal mitochondrial motility. This withstanding, our finding that key cellular phenotypes are reproduced in vitro suggests, for the first time, that syndromic disease may arise from genetic modifiers that exacerbate the mitochondrial defect, which, at least in dopaminergic neurons, manifested as OPA1‐mediated mitochondrial fragmentation.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Stem cell modeling of mitochondrial parkinsonism reveals key functions of OPA1

Jonikas

Madill

Mathy

et al. 2018

Annals of Neurology

View full text Add to dashboard Cite

ObjectiveDefective mitochondrial function attributed to optic atrophy 1 (OPA1) mutations causes primarily optic atrophy and, less commonly, neurodegenerative syndromes. The pathomechanism by which OPA1 mutations trigger diffuse loss of neurons in some, but not all, patients is unknown. Here, we used a tractable induced pluripotent stem cell (iPSC)‐based model to capture the biology of OPA1 haploinsufficiency in cases presenting with classic eye disease versus syndromic parkinsonism.MethodsiPSCs were generated from 2 patients with OPA1 haploinsufficiency and 2 controls and differentiated into dopaminergic neurons. Metabolic profile was determined by extracellular flux analysis, respiratory complex levels using immunoblotting, and complex I activity by a colorimetric assay. Mitochondria were examined by transmission electron microscopy. Mitochondrial DNA copy number and deletions were assayed using long‐range PCR. Mitochondrial membrane potential was measured by tetramethylrhodamine methyl ester uptake, and mitochondrial fragmentation was assessed by confocal microscopy. Exome sequencing was used to screen for pathogenic variants.ResultsOPA1 haploinsufficient iPSCs differentiated into dopaminergic neurons and exhibited marked reduction in OPA1 protein levels. Loss of OPA1 caused a late defect in oxidative phosphorylation, reduced complex I levels, and activity without a significant change in the ultrastructure of mitochondria. Loss of neurons in culture recapitulated dopaminergic degeneration in syndromic disease and correlated with mitochondrial fragmentation.InterpretationOPA1 levels maintain oxidative phosphorylation in iPSC‐derived neurons, at least in part, by regulating the stability of complex I. Severity of OPA1 disease associates primarily with the extent of OPA1‐mediated fusion, suggesting that activation of this mechanism or identification of its genetic modifiers may have therapeutic or prognostic value. Ann Neurol 2018;83:915–925

show abstract

Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Stem cell modeling of mitochondrial parkinsonism reveals key functions of OPA1

Jonikas

Madill

Mathy

et al. 2018

Annals of Neurology

View full text Add to dashboard Cite

show abstract

“…Other rare associations of OPA1 mutations in adults have been reported with spastic paraplegia (Yu-Wai-Man et al, 2010a), with the multiple sclerosis-like syndrome (Yu-Wai-Man et al, 2010a;Verny et al, 2008), with the Behr-like syndrome (Marelli et al, 2011) and, more recently, with syndromic parkinsonism and dementia (Carelli et al, 2015a).…”

Section: Diversity Of the Clinical Spectrum Of Opa1 Mutationsmentioning

confidence: 98%

OPA1-related disorders: Diversity of clinical expression, modes of inheritance and pathophysiology

Barca

Prunier-Mirebeau

Amati‐Bonneau

et al. 2016

Neurobiology of Disease

View full text Add to dashboard Cite

“…This optic neuropathy is characterized by a destruction of retinal ganglion cells and the optic nerve, resulting in progressive vision loss. Although OPA1 is highly expressed in the retina, it is broadly expressed throughout the body and this might reflect the multiple disorders that have presented themselves in patients harboring heterozygous mutations of OPA1, including deafness and dementia (Carelli et al, 2015). Until recently, all OPA1 mutations found in patients have been identified as heterozygous, with the only homozygous OPA1 mutation causing early-onset encephalomyopathy, cardiomyopathy and death during infancy (Spiegel et al, 2016).…”

Section: Opa1 and Fusion Of The Inner Membranementioning

confidence: 99%

OPA1 processing in cell death and disease – the long and short of it

MacVicar

Langer

2016

Journal of Cell Science

308

291

View full text Add to dashboard Cite

The regulation of mitochondrial dynamics by the GTPase OPA1, which is located at the inner mitochondrial membrane, is crucial for adapting mitochondrial function and preserving cellular health. OPA1 governs the delicate balance between fusion and fission in the dynamic mitochondrial network. A disturbance of this balance, often observed under stress and pathologic conditions, causes mitochondrial fragmentation and can ultimately result in cell death. As discussed in this Commentary, these morphological changes are regulated by proteolytic processing of OPA1 by the inner-membrane peptidases YME1L (also known as YME1L1) and OMA1. Long, membrane-bound forms of OPA1 are required for mitochondrial fusion, but their processing to short, soluble forms limits fusion and can facilitate mitochondrial fission. Excessive OPA1 processing by the stress-activated protease OMA1 promotes mitochondrial fragmentation and, if persistent, triggers cell death and tissue degeneration in vivo. The prevention of OMA1-mediated OPA1 processing and mitochondrial fragmentation might thus offer exciting therapeutic potential for human diseases associated with mitochondrial dysfunction.

show abstract

Syndromic parkinsonism and dementia associated with OPA1 missense mutations

Cited by 150 publications

References 53 publications

Stem cell modeling of mitochondrial parkinsonism reveals key functions of OPA1

Stem cell modeling of mitochondrial parkinsonism reveals key functions of OPA1

OPA1-related disorders: Diversity of clinical expression, modes of inheritance and pathophysiology

OPA1 processing in cell death and disease – the long and short of it

Contact Info

Product

Resources

About