Browsing by Author "Macuada Alvarado, Josefa Pilar"

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    How are mitochondrial nucleoids trafficked?
    (HUMANA PRESS INC, 2025) Macuada Alvarado, Josefa Pilar; Molina Riquelme, Isidora Elvira; Eisner, Verónica
    Mitochondria harbor their own DNA (mtDNA), which codifies essential proteins of the oxidative phosphorylation (OXPHOS) system and locally feeds them to their surrounding inner mitochondrial membrane (IMM), according to the ‘sphere of influence’ theory. mtDNA is compacted into nucleoids, which are tethered to the IMM and distributed throughout the mitochondrial network. Some nucleoid subpopulations present distinct intramitochondrial positioning during fission and their correct positioning is associated with mtDNA segregation and selective degradation. This opinion article focuses on different mechanisms that could control nucleoid positioning through intramitochondrial trafficking, either by cristae reshaping or by intercompartment-driven mechanisms involving the mitochondrial membranes and extramitochondrial elements. Understanding nucleoid trafficking promises insights into mitochondrial dysfunction in pathologies with mtDNA distribution and segregation issues.
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    How are mitochondrial nucleoids trafficked?
    (Elsevier Ltd, 2025) Macuada Alvarado, Josefa Pilar; Molina Riquelme, Isidora Elvira; Eisner, Verónica
    Mitochondria harbor their own DNA (mtDNA), which codifies essential proteins of the oxidative phosphorylation (OXPHOS) system and locally feeds them to their surrounding inner mitochondrial membrane (IMM), according to the ‘sphere of influence’ theory. mtDNA is compacted into nucleoids, which are tethered to the IMM and distributed throughout the mitochondrial network. Some nucleoid subpopulations present distinct intramitochondrial positioning during fission and their correct positioning is associated with mtDNA segregation and selective degradation. This opinion article focuses on different mechanisms that could control nucleoid positioning through intramitochondrial trafficking, either by cristae reshaping or by intercompartment-driven mechanisms involving the mitochondrial membranes and extramitochondrial elements. Understanding nucleoid trafficking promises insights into mitochondrial dysfunction in pathologies with mtDNA distribution and segregation issues.
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    OPA1 and disease-causing mutants perturb mitochondrial nucleoid distribution
    (2024) Macuada Alvarado, Josefa Pilar; Molina Riquelme, Isidora Elvira; Vidal, Gonzalo; Pérez Bravo, N.; Vásquez-Trincado, C.; Aedo, G.; Lagos, D.; Horvath, R.; Rudge Timothy, James; Cartes Saavedra, Benjamín Tomas; Eisner Sagues, Verónica Raquel
    Optic atrophy protein 1 (OPA1) mediates inner mitochondrial membrane (IMM) fusion and cristae organization. Mutations in OPA1 cause autosomal dominant optic atrophy (ADOA), a leading cause of blindness. Cells from ADOA patients show impaired mitochondrial fusion, cristae structure, bioenergetic function, and mitochondrial DNA (mtDNA) integrity. The mtDNA encodes electron transport chain subunits and is packaged into nucleoids spread within the mitochondrial population. Nucleoids interact with the IMM, and their distribution is tightly linked to mitochondrial fusion and cristae shaping. Yet, little is known about the physio-pathological relevance of nucleoid distribution. We studied the effect of OPA1 and ADOA-associated mutants on nucleoid distribution using high-resolution confocal microscopy. We applied a novel model incorporating the mitochondrial context, separating nucleoid distribution into the array in the mitochondrial population and intramitochondrial longitudinal distribution. Opa1-null cells showed decreased mtDNA levels and nucleoid abundance. Also, loss of Opa1 lead to an altered distribution of nucleoids in the mitochondrial population, loss of cristae periodicity, and altered nucleoids to cristae proximity partly rescued by OPA1 isoform 1. Overexpression of WT OPA1 or ADOA-causing mutants c.870+5G>A or c.2713C>T in WT cells, showed perturbed nucleoid array in the mitochondria population associated with cristae disorganization. Opa1-null and cells overexpressing ADOA mutants accumulated mitochondria without nucleoids. Interestingly, intramitochondrial nucleoid distribution was only altered in Opa1-null cells. Altogether, our results highlight the relevance of OPA1 in nucleoid distribution in the mitochondrial landscape and at a single-organelle level and shed light on new components of ADOA etiology. The copyright holder for this preprint is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. All rights reserved. No reuse allowed without permission.