TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy

Li Zhang; Felicia Dietsche; Bruno Seitaj; Liliana Rojas-Charry; Nadina Latchman; Dhanendra Tomar; Rob Ci Wüst; Alexander Nickel; Katrin Bm Frauenknecht; Benedikt Schoser; Sven Schumann; Michael J. Schmeisser; Johannes Vom Berg; Thorsten Buch; Stefanie Finger; Philip Wenzel; Christoph Maack; John W. Elrod; Jan B. Parys; Geert Bultynck; Axel Methner

doi:10.26508/lsa.202201478

TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy

Li Zhang, Felicia Dietsche, Bruno Seitaj, Liliana Rojas-Charry, Nadina Latchman, Dhanendra Tomar, Rob Ci Wüst, Alexander Nickel, Katrin Bm Frauenknecht, Benedikt Schoser, Sven Schumann, Michael J. Schmeisser, Johannes Vom Berg, Thorsten Buch, Stefanie Finger, Philip Wenzel, Christoph Maack, John W. Elrod, Jan B. Parys, Geert BultynckAxel Methner

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Ion fluxes across the inner mitochondrial membrane control mitochondrial volume, energy production, and apoptosis. TMBIM5, a highly conserved protein with homology to putative pH-dependent ion channels, is involved in the maintenance of mitochondrial cristae architecture, ATP production, and apoptosis. Here, we demonstrate that overexpressed TMBIM5 can mediate mitochondrial calcium uptake. Under steady-state conditions, loss of TMBIM5 results in increased potassium and reduced proton levels in the mitochondrial matrix caused by attenuated exchange of these ions. To identify the in vivo consequences of TMBIM5 dysfunction, we generated mice carrying a mutation in the channel pore. These mutant mice display increased embryonic or perinatal lethality and a skeletal myopathy which strongly correlates with tissue-specific disruption of cristae architecture, early opening of the mitochondrial permeability transition pore, reduced calcium uptake capability, and mitochondrial swelling. Our results demonstrate that TMBIM5 is an essential and important part of the mitochondrial ion transport system machinery with particular importance for embryonic development and muscle function.

Original language	English
Article number	e202201478
Pages (from-to)	1-15
Number of pages	15
Journal	Life science alliance
Volume	5
Issue number	10
Early online date	17 Jun 2022
DOIs	https://doi.org/10.26508/lsa.202201478
Publication status	Published - Oct 2022

Bibliographical note

Publisher Copyright:
© 2022 Zhang et al.

Funding

This work was funded by the Deutsche Forschungsgemeinschaft (DFG) to A Methner (ME1922/17-1), P Wenzel (DFG INST 371/47-1 FUGG) and C Maack (MA2528/7-1; SFB 894). We thank Marion Silies for excellent proofreading and discussions.

Funders	Funder number
Deutsche Forschungsgemeinschaft	MA2528/7-1, ME1922/17-1, DFG INST 371/47-1 FUGG, SFB 894

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Zhang, L., Dietsche, F., Seitaj, B., Rojas-Charry, L., Latchman, N., Tomar, D., Wüst, R. C., Nickel, A., Frauenknecht, K. B., Schoser, B., Schumann, S., Schmeisser, M. J., Vom Berg, J., Buch, T., Finger, S., Wenzel, P., Maack, C., Elrod, J. W., Parys, J. B., ... Methner, A. (2022). TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy. Life science alliance, 5(10), 1-15. Article e202201478. https://doi.org/10.26508/lsa.202201478

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title = "TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy",

abstract = "Ion fluxes across the inner mitochondrial membrane control mitochondrial volume, energy production, and apoptosis. TMBIM5, a highly conserved protein with homology to putative pH-dependent ion channels, is involved in the maintenance of mitochondrial cristae architecture, ATP production, and apoptosis. Here, we demonstrate that overexpressed TMBIM5 can mediate mitochondrial calcium uptake. Under steady-state conditions, loss of TMBIM5 results in increased potassium and reduced proton levels in the mitochondrial matrix caused by attenuated exchange of these ions. To identify the in vivo consequences of TMBIM5 dysfunction, we generated mice carrying a mutation in the channel pore. These mutant mice display increased embryonic or perinatal lethality and a skeletal myopathy which strongly correlates with tissue-specific disruption of cristae architecture, early opening of the mitochondrial permeability transition pore, reduced calcium uptake capability, and mitochondrial swelling. Our results demonstrate that TMBIM5 is an essential and important part of the mitochondrial ion transport system machinery with particular importance for embryonic development and muscle function.",

author = "Li Zhang and Felicia Dietsche and Bruno Seitaj and Liliana Rojas-Charry and Nadina Latchman and Dhanendra Tomar and W{\"u}st, {Rob Ci} and Alexander Nickel and Frauenknecht, {Katrin Bm} and Benedikt Schoser and Sven Schumann and Schmeisser, {Michael J.} and {Vom Berg}, Johannes and Thorsten Buch and Stefanie Finger and Philip Wenzel and Christoph Maack and Elrod, {John W.} and Parys, {Jan B.} and Geert Bultynck and Axel Methner",

note = "Publisher Copyright: {\textcopyright} 2022 Zhang et al.",

year = "2022",

month = oct,

doi = "10.26508/lsa.202201478",

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Zhang, L, Dietsche, F, Seitaj, B, Rojas-Charry, L, Latchman, N, Tomar, D, Wüst, RC, Nickel, A, Frauenknecht, KB, Schoser, B, Schumann, S, Schmeisser, MJ, Vom Berg, J, Buch, T, Finger, S, Wenzel, P, Maack, C, Elrod, JW, Parys, JB, Bultynck, G & Methner, A 2022, 'TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy', Life science alliance, vol. 5, no. 10, e202201478, pp. 1-15. https://doi.org/10.26508/lsa.202201478

TY - JOUR

T1 - TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy

AU - Zhang, Li

AU - Dietsche, Felicia

AU - Seitaj, Bruno

AU - Rojas-Charry, Liliana

AU - Latchman, Nadina

AU - Tomar, Dhanendra

AU - Wüst, Rob Ci

AU - Nickel, Alexander

AU - Frauenknecht, Katrin Bm

AU - Schoser, Benedikt

AU - Schumann, Sven

AU - Schmeisser, Michael J.

AU - Vom Berg, Johannes

AU - Buch, Thorsten

AU - Finger, Stefanie

AU - Wenzel, Philip

AU - Maack, Christoph

AU - Elrod, John W.

AU - Parys, Jan B.

AU - Bultynck, Geert

AU - Methner, Axel

PY - 2022/10

Y1 - 2022/10

N2 - Ion fluxes across the inner mitochondrial membrane control mitochondrial volume, energy production, and apoptosis. TMBIM5, a highly conserved protein with homology to putative pH-dependent ion channels, is involved in the maintenance of mitochondrial cristae architecture, ATP production, and apoptosis. Here, we demonstrate that overexpressed TMBIM5 can mediate mitochondrial calcium uptake. Under steady-state conditions, loss of TMBIM5 results in increased potassium and reduced proton levels in the mitochondrial matrix caused by attenuated exchange of these ions. To identify the in vivo consequences of TMBIM5 dysfunction, we generated mice carrying a mutation in the channel pore. These mutant mice display increased embryonic or perinatal lethality and a skeletal myopathy which strongly correlates with tissue-specific disruption of cristae architecture, early opening of the mitochondrial permeability transition pore, reduced calcium uptake capability, and mitochondrial swelling. Our results demonstrate that TMBIM5 is an essential and important part of the mitochondrial ion transport system machinery with particular importance for embryonic development and muscle function.

AB - Ion fluxes across the inner mitochondrial membrane control mitochondrial volume, energy production, and apoptosis. TMBIM5, a highly conserved protein with homology to putative pH-dependent ion channels, is involved in the maintenance of mitochondrial cristae architecture, ATP production, and apoptosis. Here, we demonstrate that overexpressed TMBIM5 can mediate mitochondrial calcium uptake. Under steady-state conditions, loss of TMBIM5 results in increased potassium and reduced proton levels in the mitochondrial matrix caused by attenuated exchange of these ions. To identify the in vivo consequences of TMBIM5 dysfunction, we generated mice carrying a mutation in the channel pore. These mutant mice display increased embryonic or perinatal lethality and a skeletal myopathy which strongly correlates with tissue-specific disruption of cristae architecture, early opening of the mitochondrial permeability transition pore, reduced calcium uptake capability, and mitochondrial swelling. Our results demonstrate that TMBIM5 is an essential and important part of the mitochondrial ion transport system machinery with particular importance for embryonic development and muscle function.

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TMBIM5 loss of function alters mitochondrial matrix ion homeostasis and causes a skeletal myopathy

Abstract

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