ALS-associated mutation FUS-R521C causes DNA damage and RNA splicing defects
Haiyan Qiu, Sebum Lee, Yulei Shang, Wen-Yuan Wang, Kin Fai Au, Sherry Kamiya, Sami J. Barmada, Steven Finkbeiner, Hansen Lui, Caitlin E. Carlton, Amy A. Tang, Michael C. Oldham, Hejia Wang, James Shorter, Anthony J. Filiano, Erik D. Roberson, Warren G. Tourtellotte, Bin Chen, Li-Huei Tsai, Eric J. Huang
Haiyan Qiu, Sebum Lee, Yulei Shang, Wen-Yuan Wang, Kin Fai Au, Sherry Kamiya, Sami J. Barmada, Steven Finkbeiner, Hansen Lui, Caitlin E. Carlton, Amy A. Tang, Michael C. Oldham, Hejia Wang, James Shorter, Anthony J. Filiano, Erik D. Roberson, Warren G. Tourtellotte, Bin Chen, Li-Huei Tsai, Eric J. Huang
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Research Article Neuroscience

ALS-associated mutation FUS-R521C causes DNA damage and RNA splicing defects

Abstract

Autosomal dominant mutations of the RNA/DNA binding protein FUS are linked to familial amyotrophic lateral sclerosis (FALS); however, it is not clear how FUS mutations cause neurodegeneration. Using transgenic mice expressing a common FALS-associated FUS mutation (FUS-R521C mice), we found that mutant FUS proteins formed a stable complex with WT FUS proteins and interfered with the normal interactions between FUS and histone deacetylase 1 (HDAC1). Consequently, FUS-R521C mice exhibited evidence of DNA damage as well as profound dendritic and synaptic phenotypes in brain and spinal cord. To provide insights into these defects, we screened neural genes for nucleotide oxidation and identified brain-derived neurotrophic factor (Bdnf) as a target of FUS-R521C–associated DNA damage and RNA splicing defects in mice. Compared with WT FUS, mutant FUS-R521C proteins formed a more stable complex with Bdnf RNA in electrophoretic mobility shift assays. Stabilization of the FUS/Bdnf RNA complex contributed to Bdnf splicing defects and impaired BDNF signaling through receptor TrkB. Exogenous BDNF only partially restored dendrite phenotype in FUS-R521C neurons, suggesting that BDNF-independent mechanisms may contribute to the defects in these neurons. Indeed, RNA-seq analyses of FUS-R521C spinal cords revealed additional transcription and splicing defects in genes that regulate dendritic growth and synaptic functions. Together, our results provide insight into how gain-of-function FUS mutations affect critical neuronal functions.

Authors

Haiyan Qiu, Sebum Lee, Yulei Shang, Wen-Yuan Wang, Kin Fai Au, Sherry Kamiya, Sami J. Barmada, Steven Finkbeiner, Hansen Lui, Caitlin E. Carlton, Amy A. Tang, Michael C. Oldham, Hejia Wang, James Shorter, Anthony J. Filiano, Erik D. Roberson, Warren G. Tourtellotte, Bin Chen, Li-Huei Tsai, Eric J. Huang

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Figure 1

Early onset motor behavioral deficits and postnatal lethality in FUS-R521C transgenic mice.

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Early onset motor behavioral deficits and postnatal lethality in FUS-R52...
(A) A schematic diagram showing our strategy for generating transgenic mice that express human FUS-R521C mutant proteins using the Syrian hamster prion promoter. (B and C) The majority of N1F1 FUS-R521C mice show growth retardation, spastic paraplegia, and severe muscle wasting. (D and E) In addition, the FUS-R521C mice also exhibit prolonged hind limb clasping on tail-suspension test. (F) In a 2-minute period, FUS-R521C mice spend approximately 100 seconds with hind limbs clasped together, whereas nontransgenic control mice exhibit similar clasping phenotype for less than 10 seconds. 2-tailed Student’s t test, P < 0.001. (G and H) Due to the spastic paraplegia, FUS-R521C mice show reduced distance between hind paws during tandem walk tests. 2-tailed Student’s t test, P < 0.001. (I) The gait and motor coordination defects in FUS-R521C mice are further verified using computerized catwalk measurements. (J) In addition to the gait abnormalities, FUS-R521C N1F1 mice show poor performance and motor learning on rotarod tests.