Restoring mitofusin balance prevents axonal degeneration in a Charcot-Marie-Tooth type 2A model
Yueqin Zhou, Sharon Carmona, A.K.M.G. Muhammad, Shaughn Bell, Jesse Landeros, Michael Vazquez, Ritchie Ho, Antonietta Franco, Bin Lu, Gerald W. Dorn II, Shaomei Wang, Cathleen M. Lutz, Robert H. Baloh
Yueqin Zhou, Sharon Carmona, A.K.M.G. Muhammad, Shaughn Bell, Jesse Landeros, Michael Vazquez, Ritchie Ho, Antonietta Franco, Bin Lu, Gerald W. Dorn II, Shaomei Wang, Cathleen M. Lutz, Robert H. Baloh
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Research Article Neuroscience

Restoring mitofusin balance prevents axonal degeneration in a Charcot-Marie-Tooth type 2A model

Abstract

Mitofusin-2 (MFN2) is a mitochondrial outer-membrane protein that plays a pivotal role in mitochondrial dynamics in most tissues, yet mutations in MFN2, which cause Charcot-Marie-Tooth disease type 2A (CMT2A), primarily affect the nervous system. We generated a transgenic mouse model of CMT2A that developed severe early onset vision loss and neurological deficits, axonal degeneration without cell body loss, and cytoplasmic and axonal accumulations of fragmented mitochondria. While mitochondrial aggregates were labeled for mitophagy, mutant MFN2 did not inhibit Parkin-mediated degradation, but instead had a dominant negative effect on mitochondrial fusion only when MFN1 was at low levels, as occurs in neurons. Finally, using a transgenic approach, we found that augmenting the level of MFN1 in the nervous system in vivo rescued all phenotypes in mutant MFN2R94Q-expressing mice. These data demonstrate that the MFN1/MFN2 ratio is a key determinant of tissue specificity in CMT2A and indicate that augmentation of MFN1 in the nervous system is a viable therapeutic strategy for the disease.

Authors

Yueqin Zhou, Sharon Carmona, A.K.M.G. Muhammad, Shaughn Bell, Jesse Landeros, Michael Vazquez, Ritchie Ho, Antonietta Franco, Bin Lu, Gerald W. Dorn II, Shaomei Wang, Cathleen M. Lutz, Robert H. Baloh

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Figure 5

Phenotypic rescue of MFN2R94Q mice by augmenting MFN1 expression in the nervous system.

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Phenotypic rescue of MFN2R94Q mice by augmenting MFN1 expression in the ...
(A) Schematic of the Prp-MFN1 transgene. The expression of human MFN1 (N terminus tagged with Flag) in brain and spinal cord is driven by the murine Prp gene promoter. Prp-MFN1 transgenic mice were crossed with Thy1.2-MFN2R94Q transgenic mice to generate Thy1.2-MFN2R94Q:Prp-MFN1 double-transgenic mice. (B) Representative image of a 20-week-old MFN2R94Q:MFN1 double-transgenic mouse compared with a MFN2R94Q mutant mouse and an nTg control. (C) MFN1 and/or MFN2R94Q transgene expression detected by immunoblotting. Lysates of 14-month-old mouse brain and spinal cord. Expression levels of the 2 MFN transgenes were comparable. Note low level of endogenous Mfn1 expression in the mouse brain and spinal cord. n = 3 mice/genotype. (D) Flag immunostaining of MFN1 transgenic protein in 7-week-old mouse spinal cord showing punctate cytoplasmic staining consistent with mitochondria. DAPI stains nuclei. Scale bar: 100 μM. n = 3 mice/genotype. (E) Body weight. Data are represented as mean ± SEM. nTg (n = 8–32 per time point), MFN2R94Q (n = 24–63 per time point), and MFN2R94Q:MFN1 (n = 17–31 per time point). Two-way ANOVA with Tukey’s multiple comparisons test. *P < 0.05; ****P < 0.0001. MFN2R94Q vs. MFN2R94Q:MFN1 (asterisks in black). nTg vs. MFN2R94Q:MFN1 (asterisks in gray). (F) Survival curve. nTg (n = 8–32 per time point), MFN2R94Q (n = 24–63 per time point), and MFN2R94Q:MFN1 (n = 17–31 per time point). log-rank test with Bonferroni’s correction. nTg vs. MFN2R94Q, P < 0.01; MFN2R94Q vs. MFN2R94Q:MFN1, P < 0.01. nTg vs. MFN2R94Q:MFN1, P > 0.05 (not significant). (G) Open-field test (rearing). nTg (n = 5), MFN2R94Q (n = 5), and MFN2R94Q:MFN1 (n = 10). (H) Rotarod testing. nTg (n = 3–5), MFN2R94Q (n = 3–5), and MFN2R94Q:MFN1 (n = 3–10). (I) Grip-strength testing (all paws). nTg (n = 3–5), MFN2R94Q (n = 3–5), and MFN2R94Q:MFN1 (n = 3–10). (J) Visual acuity measured by OKR. nTg (n = 6), MFN2R94Q (n = 7), and MFN2R94Q:MFN1 (n = 4). In GJ, data are represented as mean ± SEM. Two-way ANOVA with Tukey’s test was used for multiple comparison. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001.