Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice

Joe Yasa; Claudia E. Reed; Adam M. Bournazos; Frances J. Evesson; Ignatius Pang; Mark E. Graham; Jesse R. Wark; Brunda Nijagal; Kim H. Kwan; Thomas Kwiatkowski; Rachel Jung; Noah Weisleder; Sandra T. Cooper; Frances A. Lemckert

doi:10.1186/s40478-022-01473-x

Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice

Joe Yasa, Claudia E. Reed, Adam M. Bournazos, Frances J. Evesson, Ignatius Pang, Mark E. Graham, Jesse R. Wark, Brunda Nijagal, Kim H. Kwan, Thomas Kwiatkowski, Rachel Jung, Noah Weisleder, Sandra T. Cooper, Frances A. Lemckert

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4 Scopus citations

Abstract

Dysferlin is a Ca²⁺-activated lipid binding protein implicated in muscle membrane repair. Recessive variants in DYSF result in dysferlinopathy, a progressive muscular dystrophy. We showed previously that calpain cleavage within a motif encoded by alternatively spliced exon 40a releases a 72 kDa C-terminal minidysferlin recruited to injured sarcolemma. Herein we use CRISPR/Cas9 gene editing to knock out murine Dysf exon 40a, to specifically assess its role in membrane repair and development of dysferlinopathy. We created three Dysf exon 40a knockout (40aKO) mouse lines that each express different levels of dysferlin protein ranging from ~ 90%, ~ 50% and ~ 10–20% levels of wild-type. Histopathological analysis of skeletal muscles from all 12-month-old 40aKO lines showed virtual absence of dystrophic features and normal membrane repair capacity for all three 40aKO lines, as compared with dysferlin-null BLAJ mice. Further, lipidomic and proteomic analyses on 18wk old quadriceps show all three 40aKO lines are spared the profound lipidomic/proteomic imbalance that characterises dysferlin-deficient BLAJ muscles. Collective results indicate that membrane repair does not depend upon calpain cleavage within exon 40a and that ~ 10–20% of WT dysferlin protein expression is sufficient to maintain the muscle lipidome, proteome and membrane repair capacity to crucially prevent development of dysferlinopathy.

Original language	English
Article number	15
Journal	Acta neuropathologica communications
Volume	11
Issue number	1
DOIs	https://doi.org/10.1186/s40478-022-01473-x
State	Published - Dec 2023

Bibliographical note

Publisher Copyright:
© 2023, The Author(s).

Funding

We would like to acknowledge the contribution of Dr. Laura Rufibach in editing the first draft of this manuscript. Electron Microscopy was performed at the Westmead Scientific Platforms, which are supported by the Westmead Research Hub, the Cancer Institute New South Wales, the National Health and Medical Research Council and the Ian Potter Foundation. This work was supported through a National Health and Medical Research Council (NHMRC) Project Grant APP1103618 (STC) and Jain Foundation grant (FL). Sandra T. Cooper is supported by a NHMRC of Australia Senior Research Fellowship APP1136197.

Funders	Funder number
Cancer Institute NSW
Ian Potter Foundation
Australian National Health and Medical Research Council	1103618, APP1103618, 1136197
Jain Foundation	APP1136197

ASJC Scopus subject areas

Pathology and Forensic Medicine
Clinical Neurology
Cellular and Molecular Neuroscience

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10.1186/s40478-022-01473-x

Cite this

Yasa, J., Reed, C. E., Bournazos, A. M., Evesson, F. J., Pang, I., Graham, M. E., Wark, J. R., Nijagal, B., Kwan, K. H., Kwiatkowski, T., Jung, R., Weisleder, N., Cooper, S. T., & Lemckert, F. A. (2023). Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice. Acta neuropathologica communications, 11(1), Article 15. https://doi.org/10.1186/s40478-022-01473-x

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title = "Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice",

abstract = "Dysferlin is a Ca2+-activated lipid binding protein implicated in muscle membrane repair. Recessive variants in DYSF result in dysferlinopathy, a progressive muscular dystrophy. We showed previously that calpain cleavage within a motif encoded by alternatively spliced exon 40a releases a 72 kDa C-terminal minidysferlin recruited to injured sarcolemma. Herein we use CRISPR/Cas9 gene editing to knock out murine Dysf exon 40a, to specifically assess its role in membrane repair and development of dysferlinopathy. We created three Dysf exon 40a knockout (40aKO) mouse lines that each express different levels of dysferlin protein ranging from \textasciitilde{} 90\%, \textasciitilde{} 50\% and \textasciitilde{} 10–20\% levels of wild-type. Histopathological analysis of skeletal muscles from all 12-month-old 40aKO lines showed virtual absence of dystrophic features and normal membrane repair capacity for all three 40aKO lines, as compared with dysferlin-null BLAJ mice. Further, lipidomic and proteomic analyses on 18wk old quadriceps show all three 40aKO lines are spared the profound lipidomic/proteomic imbalance that characterises dysferlin-deficient BLAJ muscles. Collective results indicate that membrane repair does not depend upon calpain cleavage within exon 40a and that \textasciitilde{} 10–20\% of WT dysferlin protein expression is sufficient to maintain the muscle lipidome, proteome and membrane repair capacity to crucially prevent development of dysferlinopathy.",

author = "Joe Yasa and Reed, \{Claudia E.\} and Bournazos, \{Adam M.\} and Evesson, \{Frances J.\} and Ignatius Pang and Graham, \{Mark E.\} and Wark, \{Jesse R.\} and Brunda Nijagal and Kwan, \{Kim H.\} and Thomas Kwiatkowski and Rachel Jung and Noah Weisleder and Cooper, \{Sandra T.\} and Lemckert, \{Frances A.\}",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = dec,

doi = "10.1186/s40478-022-01473-x",

language = "English",

volume = "11",

number = "1",

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Yasa, J, Reed, CE, Bournazos, AM, Evesson, FJ, Pang, I, Graham, ME, Wark, JR, Nijagal, B, Kwan, KH, Kwiatkowski, T, Jung, R, Weisleder, N, Cooper, ST & Lemckert, FA 2023, 'Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice', Acta neuropathologica communications, vol. 11, no. 1, 15. https://doi.org/10.1186/s40478-022-01473-x

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T1 - Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice

AU - Yasa, Joe

AU - Reed, Claudia E.

AU - Bournazos, Adam M.

AU - Evesson, Frances J.

AU - Pang, Ignatius

AU - Graham, Mark E.

AU - Wark, Jesse R.

AU - Nijagal, Brunda

AU - Kwan, Kim H.

AU - Kwiatkowski, Thomas

AU - Jung, Rachel

AU - Weisleder, Noah

AU - Cooper, Sandra T.

AU - Lemckert, Frances A.

PY - 2023/12

Y1 - 2023/12

N2 - Dysferlin is a Ca2+-activated lipid binding protein implicated in muscle membrane repair. Recessive variants in DYSF result in dysferlinopathy, a progressive muscular dystrophy. We showed previously that calpain cleavage within a motif encoded by alternatively spliced exon 40a releases a 72 kDa C-terminal minidysferlin recruited to injured sarcolemma. Herein we use CRISPR/Cas9 gene editing to knock out murine Dysf exon 40a, to specifically assess its role in membrane repair and development of dysferlinopathy. We created three Dysf exon 40a knockout (40aKO) mouse lines that each express different levels of dysferlin protein ranging from ~ 90%, ~ 50% and ~ 10–20% levels of wild-type. Histopathological analysis of skeletal muscles from all 12-month-old 40aKO lines showed virtual absence of dystrophic features and normal membrane repair capacity for all three 40aKO lines, as compared with dysferlin-null BLAJ mice. Further, lipidomic and proteomic analyses on 18wk old quadriceps show all three 40aKO lines are spared the profound lipidomic/proteomic imbalance that characterises dysferlin-deficient BLAJ muscles. Collective results indicate that membrane repair does not depend upon calpain cleavage within exon 40a and that ~ 10–20% of WT dysferlin protein expression is sufficient to maintain the muscle lipidome, proteome and membrane repair capacity to crucially prevent development of dysferlinopathy.

AB - Dysferlin is a Ca2+-activated lipid binding protein implicated in muscle membrane repair. Recessive variants in DYSF result in dysferlinopathy, a progressive muscular dystrophy. We showed previously that calpain cleavage within a motif encoded by alternatively spliced exon 40a releases a 72 kDa C-terminal minidysferlin recruited to injured sarcolemma. Herein we use CRISPR/Cas9 gene editing to knock out murine Dysf exon 40a, to specifically assess its role in membrane repair and development of dysferlinopathy. We created three Dysf exon 40a knockout (40aKO) mouse lines that each express different levels of dysferlin protein ranging from ~ 90%, ~ 50% and ~ 10–20% levels of wild-type. Histopathological analysis of skeletal muscles from all 12-month-old 40aKO lines showed virtual absence of dystrophic features and normal membrane repair capacity for all three 40aKO lines, as compared with dysferlin-null BLAJ mice. Further, lipidomic and proteomic analyses on 18wk old quadriceps show all three 40aKO lines are spared the profound lipidomic/proteomic imbalance that characterises dysferlin-deficient BLAJ muscles. Collective results indicate that membrane repair does not depend upon calpain cleavage within exon 40a and that ~ 10–20% of WT dysferlin protein expression is sufficient to maintain the muscle lipidome, proteome and membrane repair capacity to crucially prevent development of dysferlinopathy.

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Minimal expression of dysferlin prevents development of dysferlinopathy in dysferlin exon 40a knockout mice

Abstract

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Funding

ASJC Scopus subject areas

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