Dysfunctional mitochondria accumulate in a skeletal muscle knockout model of Smn1, the causal gene of spinal muscular atrophy

Francesco Chemello; Michela Pozzobon; Lorenza Iolanda Tsansizi; Tatiana Varanita; Rubèn Quintana-Cabrera; Daniele Bonesso; Martina Piccoli; Gerolamo Lanfranchi; Marta Giacomello; Luca Scorrano; Camilla Bean

doi:10.1038/s41419-023-05573-x

Dysfunctional mitochondria accumulate in a skeletal muscle knockout model of Smn1, the causal gene of spinal muscular atrophy

Francesco Chemello, Michela Pozzobon, Lorenza Iolanda Tsansizi, Tatiana Varanita, Rubèn Quintana-Cabrera, Daniele Bonesso, Martina Piccoli, Gerolamo Lanfranchi, Marta Giacomello, Luca Scorrano, Camilla Bean

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

The approved gene therapies for spinal muscular atrophy (SMA), caused by loss of survival motor neuron 1 (SMN1), greatly ameliorate SMA natural history but are not curative. These therapies primarily target motor neurons, but SMN1 loss has detrimental effects beyond motor neurons and especially in muscle. Here we show that SMN loss in mouse skeletal muscle leads to accumulation of dysfunctional mitochondria. Expression profiling of single myofibers from a muscle specific Smn1 knockout mouse model revealed down-regulation of mitochondrial and lysosomal genes. Albeit levels of proteins that mark mitochondria for mitophagy were increased, morphologically deranged mitochondria with impaired complex I and IV activity and respiration and that produced excess reactive oxygen species accumulated in Smn1 knockout muscles, because of the lysosomal dysfunction highlighted by the transcriptional profiling. Amniotic fluid stem cells transplantation that corrects the SMN knockout mouse myopathic phenotype restored mitochondrial morphology and expression of mitochondrial genes. Thus, targeting muscle mitochondrial dysfunction in SMA may complement the current gene therapy.

Original language	English (US)
Article number	162
Journal	Cell Death and Disease
Volume	14
Issue number	2
DOIs	https://doi.org/10.1038/s41419-023-05573-x
State	Published - Feb 2023
Externally published	Yes

ASJC Scopus subject areas

Immunology
Cellular and Molecular Neuroscience
Cell Biology
Cancer Research

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Chemello, F., Pozzobon, M., Tsansizi, L. I., Varanita, T., Quintana-Cabrera, R., Bonesso, D., Piccoli, M., Lanfranchi, G., Giacomello, M., Scorrano, L., & Bean, C. (2023). Dysfunctional mitochondria accumulate in a skeletal muscle knockout model of Smn1, the causal gene of spinal muscular atrophy. Cell Death and Disease, 14(2), Article 162. https://doi.org/10.1038/s41419-023-05573-x

Chemello, F, Pozzobon, M, Tsansizi, LI, Varanita, T, Quintana-Cabrera, R, Bonesso, D, Piccoli, M, Lanfranchi, G, Giacomello, M, Scorrano, L & Bean, C 2023, 'Dysfunctional mitochondria accumulate in a skeletal muscle knockout model of Smn1, the causal gene of spinal muscular atrophy', Cell Death and Disease, vol. 14, no. 2, 162. https://doi.org/10.1038/s41419-023-05573-x

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title = "Dysfunctional mitochondria accumulate in a skeletal muscle knockout model of Smn1, the causal gene of spinal muscular atrophy",

abstract = "The approved gene therapies for spinal muscular atrophy (SMA), caused by loss of survival motor neuron 1 (SMN1), greatly ameliorate SMA natural history but are not curative. These therapies primarily target motor neurons, but SMN1 loss has detrimental effects beyond motor neurons and especially in muscle. Here we show that SMN loss in mouse skeletal muscle leads to accumulation of dysfunctional mitochondria. Expression profiling of single myofibers from a muscle specific Smn1 knockout mouse model revealed down-regulation of mitochondrial and lysosomal genes. Albeit levels of proteins that mark mitochondria for mitophagy were increased, morphologically deranged mitochondria with impaired complex I and IV activity and respiration and that produced excess reactive oxygen species accumulated in Smn1 knockout muscles, because of the lysosomal dysfunction highlighted by the transcriptional profiling. Amniotic fluid stem cells transplantation that corrects the SMN knockout mouse myopathic phenotype restored mitochondrial morphology and expression of mitochondrial genes. Thus, targeting muscle mitochondrial dysfunction in SMA may complement the current gene therapy.",

author = "Francesco Chemello and Michela Pozzobon and Tsansizi, {Lorenza Iolanda} and Tatiana Varanita and Rub{\`e}n Quintana-Cabrera and Daniele Bonesso and Martina Piccoli and Gerolamo Lanfranchi and Marta Giacomello and Luca Scorrano and Camilla Bean",

note = "Funding Information: We thank Drs F. Caicci and F. Boldrin (EM Facility, Department of Biology, University of Padova) for electron microscopy samples preparation; Dr. C. Millino and Dr. B. Pacchioni (Microarray Service MicroCribi, University of Padova) for the help with microarray experiments; S. Schiavon and Dr. G. Covello (HiTS@uniPD Facility, Department of Biology, University of Padova) for High Content Imaging; Foundation Umberto Veronesi for supporting TV; Dr. R. Cerutti for help with histochemical assay; and Prof. I. Szabo for providing reagents. This work was supported by AFM-Telethon2013/Project 16662 (to CB); and by CARIPARO Project 13/04 and 27/01 (to MP). This work contributes to the COST Action CA17116 “International Network for Translating Research on Perinatal Derivatives into Therapeutic Approaches” (SPRINT; to MP). Publisher Copyright: {\textcopyright} 2023, The Author(s).",

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doi = "10.1038/s41419-023-05573-x",

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AU - Chemello, Francesco

AU - Pozzobon, Michela

AU - Tsansizi, Lorenza Iolanda

AU - Varanita, Tatiana

AU - Quintana-Cabrera, Rubèn

AU - Bonesso, Daniele

AU - Piccoli, Martina

AU - Lanfranchi, Gerolamo

AU - Giacomello, Marta

AU - Scorrano, Luca

AU - Bean, Camilla

N1 - Funding Information: We thank Drs F. Caicci and F. Boldrin (EM Facility, Department of Biology, University of Padova) for electron microscopy samples preparation; Dr. C. Millino and Dr. B. Pacchioni (Microarray Service MicroCribi, University of Padova) for the help with microarray experiments; S. Schiavon and Dr. G. Covello (HiTS@uniPD Facility, Department of Biology, University of Padova) for High Content Imaging; Foundation Umberto Veronesi for supporting TV; Dr. R. Cerutti for help with histochemical assay; and Prof. I. Szabo for providing reagents. This work was supported by AFM-Telethon2013/Project 16662 (to CB); and by CARIPARO Project 13/04 and 27/01 (to MP). This work contributes to the COST Action CA17116 “International Network for Translating Research on Perinatal Derivatives into Therapeutic Approaches” (SPRINT; to MP). Publisher Copyright: © 2023, The Author(s).

PY - 2023/2

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N2 - The approved gene therapies for spinal muscular atrophy (SMA), caused by loss of survival motor neuron 1 (SMN1), greatly ameliorate SMA natural history but are not curative. These therapies primarily target motor neurons, but SMN1 loss has detrimental effects beyond motor neurons and especially in muscle. Here we show that SMN loss in mouse skeletal muscle leads to accumulation of dysfunctional mitochondria. Expression profiling of single myofibers from a muscle specific Smn1 knockout mouse model revealed down-regulation of mitochondrial and lysosomal genes. Albeit levels of proteins that mark mitochondria for mitophagy were increased, morphologically deranged mitochondria with impaired complex I and IV activity and respiration and that produced excess reactive oxygen species accumulated in Smn1 knockout muscles, because of the lysosomal dysfunction highlighted by the transcriptional profiling. Amniotic fluid stem cells transplantation that corrects the SMN knockout mouse myopathic phenotype restored mitochondrial morphology and expression of mitochondrial genes. Thus, targeting muscle mitochondrial dysfunction in SMA may complement the current gene therapy.

AB - The approved gene therapies for spinal muscular atrophy (SMA), caused by loss of survival motor neuron 1 (SMN1), greatly ameliorate SMA natural history but are not curative. These therapies primarily target motor neurons, but SMN1 loss has detrimental effects beyond motor neurons and especially in muscle. Here we show that SMN loss in mouse skeletal muscle leads to accumulation of dysfunctional mitochondria. Expression profiling of single myofibers from a muscle specific Smn1 knockout mouse model revealed down-regulation of mitochondrial and lysosomal genes. Albeit levels of proteins that mark mitochondria for mitophagy were increased, morphologically deranged mitochondria with impaired complex I and IV activity and respiration and that produced excess reactive oxygen species accumulated in Smn1 knockout muscles, because of the lysosomal dysfunction highlighted by the transcriptional profiling. Amniotic fluid stem cells transplantation that corrects the SMN knockout mouse myopathic phenotype restored mitochondrial morphology and expression of mitochondrial genes. Thus, targeting muscle mitochondrial dysfunction in SMA may complement the current gene therapy.

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Dysfunctional mitochondria accumulate in a skeletal muscle knockout model of Smn1, the causal gene of spinal muscular atrophy

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