Moderate overexpression of Opa1, the master regulator of mitochondrial cristae morphology, significantly improved mitochondrial damage induced by drugs, surgical denervation, or oxidative phosphorylation (OXPHOS) defects due to specific impairment of a single mitochondrial respiratory chain complex. Here, we investigated the effectiveness of this approach in the Mpv17−/− mouse, characterized by profound, multisystem mitochondrial DNA (mtDNA) depletion. After the crossing with Opa1tg mice, we found a surprising anticipation of the severe, progressive focal segmental glomerulosclerosis, previously described in Mpv17−/− animals as a late-onset clinical feature (after 12–18 months of life). In contrast, Mpv17−/− animals from this new “mixed” strain died at 8–9 weeks after birth because of severe kidney failure However, Mpv17−/−::Opa1tg mice lived much longer than Mpv17−/− littermates and developed the kidney dysfunction much later. mtDNA content and OXPHOS activities were significantly higher in Mpv17−/−::Opa1tg than in Mpv17−/− kidneys and similar to those for wild-type (WT) littermates. Mitochondrial network and cristae ultrastructure were largely preserved in Mpv17−/−::Opa1tg versus Mpv17−/− kidney and isolated podocytes. Mechanistically, the protective effect of Opa1 overexpression in this model was mediated by a block in apoptosis due to the stabilization of the mitochondrial cristae. These results demonstrate that strategies aiming at increasing Opa1 expression or activity can be effective against mtDNA depletion syndromes.
Opa1 Overexpression Protects from Early-Onset Mpv17−/−-Related Mouse Kidney Disease / M. Luna-Sanchez, C. Beninca, R. Cerutti, G. Brea-Calvo, A. Yeates, L. Scorrano, M. Zeviani, C. Viscomi. - In: MOLECULAR THERAPY. - ISSN 1525-0016. - 28:8(2020 Aug 05), pp. 1918-1930. [10.1016/j.ymthe.2020.06.010]
Opa1 Overexpression Protects from Early-Onset Mpv17−/−-Related Mouse Kidney Disease
R. Cerutti;C. Viscomi
Ultimo
2020
Abstract
Moderate overexpression of Opa1, the master regulator of mitochondrial cristae morphology, significantly improved mitochondrial damage induced by drugs, surgical denervation, or oxidative phosphorylation (OXPHOS) defects due to specific impairment of a single mitochondrial respiratory chain complex. Here, we investigated the effectiveness of this approach in the Mpv17−/− mouse, characterized by profound, multisystem mitochondrial DNA (mtDNA) depletion. After the crossing with Opa1tg mice, we found a surprising anticipation of the severe, progressive focal segmental glomerulosclerosis, previously described in Mpv17−/− animals as a late-onset clinical feature (after 12–18 months of life). In contrast, Mpv17−/− animals from this new “mixed” strain died at 8–9 weeks after birth because of severe kidney failure However, Mpv17−/−::Opa1tg mice lived much longer than Mpv17−/− littermates and developed the kidney dysfunction much later. mtDNA content and OXPHOS activities were significantly higher in Mpv17−/−::Opa1tg than in Mpv17−/− kidneys and similar to those for wild-type (WT) littermates. Mitochondrial network and cristae ultrastructure were largely preserved in Mpv17−/−::Opa1tg versus Mpv17−/− kidney and isolated podocytes. Mechanistically, the protective effect of Opa1 overexpression in this model was mediated by a block in apoptosis due to the stabilization of the mitochondrial cristae. These results demonstrate that strategies aiming at increasing Opa1 expression or activity can be effective against mtDNA depletion syndromes.
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