David Pacheu-Grau scite author profile

Mitochondrial respiratory-chain complexes assemble from subunits of dual genetic origin assisted by specialized assembly factors. Whereas core subunits are translated on mitochondrial ribosomes, others are imported after cytosolic translation. How imported subunits are ushered to assembly intermediates containing mitochondria-encoded subunits is unresolved. Here, we report a comprehensive dissection of early cytochrome c oxidase assembly intermediates containing proteins required for normal mitochondrial translation and reveal assembly factors promoting biogenesis of human respiratory-chain complexes. We find that TIM21, a subunit of the inner-membrane presequence translocase, is also present in the major assembly intermediates containing newly mitochondria-synthesized and imported respiratory-chain subunits, which we term MITRAC complexes. Human TIM21 is dispensable for protein import but required for integration of early-assembling, presequence-containing subunits into respiratory-chain intermediates. We establish an unexpected molecular link between the TIM23 transport machinery and assembly of respiratory-chain complexes that regulate mitochondrial protein synthesis in response to their assembly state.

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Unmasking the causes of multifactorial disorders: OXPHOS differences between mitochondrial haplogroups

Gómez-Durán

et al. 2010

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Many epidemiologic studies have associated human mitochondrial haplogroups to rare mitochondrial diseases like Leber's hereditary optic neuropathy or to more common age-linked disorders such as Parkinson's disease. However, cellular, biochemical and molecular-genetic evidence that is able to explain these associations is very scarce. The etiology of multifactorial diseases is very difficult to sort out because such diseases are due to a combination of genetic and environmental factors that individually only contribute in small part to the development of the illness. Thus, the haplogroup-defining mutations might behave as susceptibility factors, but they could have only a small effect on oxidative phosphorylation (OXPHOS) function. Moreover, these effects would be highly dependent on the 'context' in which the genetic variant is acting. To homogenize this 'context' for mitochondrial DNA (mtDNA) mutations, a cellular approach is available that involves the use of what is known as 'cybrids'. By using this model, we demonstrate that mtDNA and mtRNA levels, mitochondrial protein synthesis, cytochrome oxidase activity and amount, normalized oxygen consumption, mitochondrial inner membrane potential and growth capacity are different in cybrids from the haplogroup H when compared with those of the haplogroup Uk. Thus, these inherited basal differences in OXPHOS capacity can help to explain why some individuals more quickly reach the bioenergetic threshold below which tissue symptoms appear and progress toward multifactorial disorders. Hence, some population genetic variants in mtDNA contribute to the genetic component of complex disorders. The existence of mtDNA-based OXPHOS differences opens possibilities for the existence of a new field, mitochondrial pharmacogenomics. New sequence accession nos: HM103354-HM103363.

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MICOS assembly controls mitochondrial inner membrane remodeling and crista junction redistribution to mediate cristae formation

et al. 2020

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Mitochondrial function is critically dependent on the folding of the mitochondrial inner membrane into cristae; indeed, numerous human diseases are associated with aberrant crista morphologies. With the MICOS complex, OPA1 and the F 1 F o ‐ATP synthase, key players of cristae biogenesis have been identified, yet their interplay is poorly understood. Harnessing super‐resolution light and 3D electron microscopy, we dissect the roles of these proteins in the formation of cristae in human mitochondria. We individually disrupted the genes of all seven MICOS subunits in human cells and re‐expressed Mic10 or Mic60 in the respective knockout cell line. We demonstrate that assembly of the MICOS complex triggers remodeling of pre‐existing unstructured cristae and de novo formation of crista junctions (CJs) on existing cristae. We show that the Mic60‐subcomplex is sufficient for CJ formation, whereas the Mic10‐subcomplex controls lamellar cristae biogenesis. OPA1 stabilizes tubular CJs and, along with the F 1 F o ‐ATP synthase, fine‐tunes the positioning of the MICOS complex and CJs. We propose a new model of cristae formation, involving the coordinated remodeling of an unstructured crista precursor into multiple lamellar cristae.

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Impaired lysosomal acidification triggers iron deficiency and inflammation in vivo

Yambire¹,

et al. 2019

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Lysosomal acidification is a key feature of healthy cells. Inability to maintain lysosomal acidic pH is associated with aging and neurodegenerative diseases. However, the mechanisms elicited by impaired lysosomal acidification remain poorly understood. We show here that inhibition of lysosomal acidification triggers cellular iron deficiency, which results in impaired mitochondrial function and non-apoptotic cell death. These effects are recovered by supplying iron via a lysosome-independent pathway. Notably, iron deficiency is sufficient to trigger inflammatory signaling in cultured primary neurons. Using a mouse model of impaired lysosomal acidification, we observed a robust iron deficiency response in the brain, verified by in vivo magnetic resonance imaging. Furthermore, the brains of these mice present a pervasive inflammatory signature associated with instability of mitochondrial DNA (mtDNA), both corrected by supplementation of the mice diet with iron. Our results highlight a novel mechanism linking impaired lysosomal acidification, mitochondrial malfunction and inflammation in vivo.

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