Targeting DRP1 with Mdivi-1 to correct mitochondrial abnormalities in ADOA+ syndrome
Yan Lin, Dongdong Wang, Busu Li, Jiayin Wang, Ling Xu, Xiaohan Sun, Kunqian Ji, Chuanzhu Yan, Fuchen Liu, Yuying Zhao
Yan Lin, Dongdong Wang, Busu Li, Jiayin Wang, Ling Xu, Xiaohan Sun, Kunqian Ji, Chuanzhu Yan, Fuchen Liu, Yuying Zhao
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Research Article Neuroscience Ophthalmology

Targeting DRP1 with Mdivi-1 to correct mitochondrial abnormalities in ADOA+ syndrome

Abstract

Autosomal dominant optic atrophy plus (ADOA+) is characterized by primary optic nerve atrophy accompanied by a spectrum of degenerative neurological symptoms. Despite ongoing research, no effective treatments are currently available for this condition. Our study provided evidence for the pathogenicity of an unreported c.1780T>C variant in the OPA1 gene through patient-derived skin fibroblasts and an engineered HEK293T cell line with OPA1 downregulation. We demonstrate that OPA1 insufficiency promoted mitochondrial fragmentation and increased DRP1 expression, disrupting mitochondrial dynamics. Consequently, this disruption enhanced mitophagy and caused mitochondrial dysfunction, contributing to the ADOA+ phenotype. Notably, the Drp1 inhibitor, mitochondrial division inhibitor-1 (Mdivi-1), effectively mitigated the adverse effects of OPA1 impairment. These effects included reduced Drp1 phosphorylation, decreased mitochondrial fragmentation, and balanced mitophagy. Thus, we propose that intervening in DRP1 with Mdivi-1 could correct mitochondrial abnormalities, offering a promising therapeutic approach for managing ADOA+.

Authors

Yan Lin, Dongdong Wang, Busu Li, Jiayin Wang, Ling Xu, Xiaohan Sun, Kunqian Ji, Chuanzhu Yan, Fuchen Liu, Yuying Zhao

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Figure 2

Effect of OPA1 knockdown on mitochondrial proteins, ROS production, and respiratory function.

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Effect of OPA1 knockdown on mitochondrial proteins, ROS production, and ...
(A) Western blot analysis of mitochondrial respiratory complex subunits (ND2, CYB, CO4) in siRNA-mediated OPA1 knockdown (siOPA1) cells compared with scramble siRNA (siScramble) treated cells; decreased protein levels were noted after OPA1 silencing. The results are derived from the same samples run on different but concurrent blots. (B) Mitochondrial membrane potential assessed by JC-1 dye in siOPA1 and siScramble cells. Analysis of pre- and post-FCCP treatments demonstrates significantly reduced membrane potential in siOPA1 cells, as indicated by a corresponding decrease in red/green fluorescence ratio. (C) Flow cytometric analysis, using DCFDA in siOPA1 and siScramble cells, revealed increased ROS levels in OPA1-deficient cells. (D) Fluorescence microscopy images showing mitochondrial network (MitoTracker), mitochondrial ROS production (MitoSOX), and nuclear staining (Hoechst) in siOPA1 and siScramble cells; merged images indicate colocalization. Data quantification in the right panel shows increased MitoSOX intensity in siOPA1 cells. Scale bar: 50 µm. (E) ATP assays indicated a significant reduction in ATP levels in siOPA1 cells compared with siScramble cells. (F) Cell viability assays indicated decreased viability in siOPA1 cells relative to siScramble cells. (G) Quantitative analysis of mitochondrial respiratory complex enzymes (citrate Synthase, complex I, complex II, complex IV) showed decreased Complex I and IV levels in siOPA1 cells. (H) Seahorse analysis of oxygen consumption rate (OCR) in siOPA1 and siScramble cells under various metabolic states induced by oligomycin, FCCP, and antimycin A. siOPA1 cells showed reduced basal, ATP-linked, and maximal respiration rates. (I) Seahorse OCR measurements following treatment with specific respiratory complex inhibitors (rotenone, antimycin A, and ascorbate, and TMPD) showed reduced OCR, particularly in Complex I–, II–, and IV–driven respiration in siOPA1 cells. Statistical analysis was by unpaired, 2-tailed t test. *P < 0.05; **P < 0.01; ***P < 0.001 (AI).