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MFN2 mutations cause compensatory mitochondrial DNA proliferation.

MFN2 mutations cause compensatory mitochondrial DNA proliferation.
MFN2 mutations cause compensatory mitochondrial DNA proliferation.
MFN2 and OPA1 genes encode two dynamin-like GTPase proteins involved in the fusion of the mitochondrial membrane. They have been associated with Charcot–Marie–Tooth disease type 2A and autosomal dominant optic atrophy, respectively. We report a large family with optic atrophy beginning in early childhood, associated with axonal neuropathy and mitochondrial myopathy in adult life. The clinical presentation looks like the autosomal dominant optic atrophy ‘plus’ phenotype linked to OPA1 mutations but is associated with a novel MFN2 missense mutation (c.629A>T, p.D210V). Multiple mitochondrial DNA deletions were found in skeletal muscle and this observation makes MFN2 a novel gene associated with ‘mitochondrial DNA breakage’ syndrome. Contrary to previous studies in patients with Charcot–Marie–Tooth disease type 2A, fibroblasts carrying the MFN2 mutation present with a respiratory chain deficiency, a fragmentation of the mitochondrial network and a significant reduction of MFN2 protein expression. Furthermore, we show for the first time that impaired mitochondrial fusion is responsible for a deficiency to repair stress-induced mitochondrial DNA damage. It is likely that defect in mitochondrial DNA repair is due to variability in repair protein content across the mitochondrial population and is at least partially responsible for mitochondrial DNA instability.
0006-8950
e219, 1-3; author reply e220, 1
Sitarz, Kamil S
3e3c226a-abcd-41ec-b895-6143caabb6d4
Yu-Wai-Man, Patrick
2f7cc000-40e1-4733-aded-15291731c83b
Pyle, Angela
d3062235-0f1b-4ca1-a118-c184f4cb73ca
Stewart, Joanna D
e1ec9784-39cc-48ed-9f4f-2a05d25f2106
Rautenstrauss, Bernd
ed2335dd-6906-43c5-b534-557e5e1fb69a
Seeman, Pavel
2f8083dd-0b21-4bbb-a131-bf90e4df23ef
Reilly, Mary M
f71781a7-94f1-40d0-845e-9de97f7d2ea0
Horvath, Rita
e41c9ffa-b0a0-4ebb-a44a-b98a2c6c23cd
Chinnery, Patrick F
87789d1a-5265-4815-9f11-194ed9b4ad94
Sitarz, Kamil S
3e3c226a-abcd-41ec-b895-6143caabb6d4
Yu-Wai-Man, Patrick
2f7cc000-40e1-4733-aded-15291731c83b
Pyle, Angela
d3062235-0f1b-4ca1-a118-c184f4cb73ca
Stewart, Joanna D
e1ec9784-39cc-48ed-9f4f-2a05d25f2106
Rautenstrauss, Bernd
ed2335dd-6906-43c5-b534-557e5e1fb69a
Seeman, Pavel
2f8083dd-0b21-4bbb-a131-bf90e4df23ef
Reilly, Mary M
f71781a7-94f1-40d0-845e-9de97f7d2ea0
Horvath, Rita
e41c9ffa-b0a0-4ebb-a44a-b98a2c6c23cd
Chinnery, Patrick F
87789d1a-5265-4815-9f11-194ed9b4ad94

Sitarz, Kamil S, Yu-Wai-Man, Patrick, Pyle, Angela, Stewart, Joanna D, Rautenstrauss, Bernd, Seeman, Pavel, Reilly, Mary M, Horvath, Rita and Chinnery, Patrick F (2012) MFN2 mutations cause compensatory mitochondrial DNA proliferation. Brain, 135 (1), e219, 1-3; author reply e220, 1. (doi:10.1093/brain/awr323). (PMID:22189565)

Record type: Article

Abstract

MFN2 and OPA1 genes encode two dynamin-like GTPase proteins involved in the fusion of the mitochondrial membrane. They have been associated with Charcot–Marie–Tooth disease type 2A and autosomal dominant optic atrophy, respectively. We report a large family with optic atrophy beginning in early childhood, associated with axonal neuropathy and mitochondrial myopathy in adult life. The clinical presentation looks like the autosomal dominant optic atrophy ‘plus’ phenotype linked to OPA1 mutations but is associated with a novel MFN2 missense mutation (c.629A>T, p.D210V). Multiple mitochondrial DNA deletions were found in skeletal muscle and this observation makes MFN2 a novel gene associated with ‘mitochondrial DNA breakage’ syndrome. Contrary to previous studies in patients with Charcot–Marie–Tooth disease type 2A, fibroblasts carrying the MFN2 mutation present with a respiratory chain deficiency, a fragmentation of the mitochondrial network and a significant reduction of MFN2 protein expression. Furthermore, we show for the first time that impaired mitochondrial fusion is responsible for a deficiency to repair stress-induced mitochondrial DNA damage. It is likely that defect in mitochondrial DNA repair is due to variability in repair protein content across the mitochondrial population and is at least partially responsible for mitochondrial DNA instability.

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Published date: August 2012
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Organisations: Centre for Biological Sciences
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Identifiers

Local EPrints ID: 355908
URI: http://eprints.soton.ac.uk/id/eprint/355908
DOI: doi:10.1093/brain/awr323
ISSN: 0006-8950
PURE UUID: 8323bdce-f4d8-4891-8933-54f3130ade8e
ORCID for Joanna D Stewart: ORCID iD orcid.org/0000-0002-2608-1967

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Date deposited: 04 Sep 2013 16:34
Last modified: 14 Mar 2024 14:39

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Contributors

Author: Kamil S Sitarz
Author: Patrick Yu-Wai-Man
Author: Angela Pyle
Author: Joanna D Stewart ORCID iD
Author: Bernd Rautenstrauss
Author: Pavel Seeman
Author: Mary M Reilly
Author: Rita Horvath
Author: Patrick F Chinnery

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