REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy

Andrea Bock; Mona Schurig; Miles Willoughby; Andrea Mirecki; Eric Seemann; Kateryna Lohachova; Istvan Katona; Sonnhild Mittag; Lutz Liebmann; Patricia Franzka; Mehdi Heidari Horestani; Mukhran Khundadze; Thorsten Mosler; Timothy Louie; Marianne de Visser; Marian A. J. Weterman; Michael Kiehntopf; Christian Beetz; Sandor Nietzsche; Otmar Huber; Joachim Weis; Michael M. Kessels; Ramachandra M. Bhaskara; Britta Qualmann; Ivan Đikić; Christian A. Hübner

doi:10.1002/advs.202511483

REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy

Andrea Bock
, Mona Schurig
, Miles Willoughby
, Andrea Mirecki
, Eric Seemann
, Kateryna Lohachova
, Istvan Katona
, Sonnhild Mittag
, Lutz Liebmann
, Patricia Franzka
, Mehdi Heidari Horestani
, Mukhran Khundadze
, Thorsten Mosler
, Timothy Louie
, Marianne de Visser
, Marian A. J. Weterman
, Michael Kiehntopf
, Christian Beetz
, Sandor Nietzsche
, Otmar Huber

Joachim Weis, Michael M. Kessels, Ramachandra M. Bhaskara, Britta Qualmann, Ivan Đikić, Christian A. Hübner^*

^*Corresponding author for this work

Friedrich Schiller University Jena
Goethe University Frankfurt
RWTH Aachen University
Houston Methodist
Swift Institute – Vein and Neurology
Amsterdam UMC - University of Amsterdam
Leiden University

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

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Abstract

REEP1 contributes to the shaping of the endoplasmic reticulum (ER) through conserved transmembrane hairpins and a long C-terminal amphipathic helix. REEP1 loss-of-function causes hereditary spastic paraplegia due to degeneration of cortical motoneuron axons. Patients with deletion of REEP1 exon5 (Δexon5), which deletes part of its amphipathic helix, however, develop muscle atrophy due to degeneration of spinal motoneuron axons (distal hereditary motor neuropathy/dHMN). It is known that REEP1 knockout mice exhibit simplified ER structures in cortical motoneurons. Here, we show that these neurons are progressively lost while spinal motoneurons remain intact. Conversely, Δexon5 knockin (KI) mice lose spinal motoneurons preceded by ER fragmentation, whereas cortical motoneurons remain intact. Mechanistically, REEP1 undergoes ubiquitination and proteasomal degradation, a process compromised in the Δexon5 variant due to impaired ubiquitination, which thus accumulates in peripheral nerves. Proteomic analysis identifies HUWE1 as the E3 ligase responsible for REEP1 turnover. Modeling and liposome shaping assays reveal that the Δexon5 variant retains its capacity to induce membrane curvature. Consistently, other REEP1 variants associated with dHMN also show compromised ubiquitination and preserved transmembrane hairpins. Therefore, it is proposed that accumulation of shaping-competent REEP1 variants in the ER drives ER fragmentation and spinal motoneuron degeneration in dHMN.

Original language	English
Journal	Advanced Science
Early online date	2025
DOIs	https://doi.org/10.1002/advs.202511483
Publication status	E-pub ahead of print - 2025

Keywords

HSP
REEP1
dHMN
endoplasmic reticulum
membrane shaping
ubiquitination

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Reep1-accumulation-disrupts-er-integrity-and-drives-spinal-motoneuron-degeneration-in-distal-hereditary-motor-neuropathy.pdfFinal published version, 10.4 MBLicence: CC BY

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Bock, A., Schurig, M., Willoughby, M., Mirecki, A., Seemann, E., Lohachova, K., Katona, I., Mittag, S., Liebmann, L., Franzka, P., Heidari Horestani, M., Khundadze, M., Mosler, T., Louie, T., de Visser, M., Weterman, M. A. J., Kiehntopf, M., Beetz, C., Nietzsche, S., ... Hübner, C. A. (2025). REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy. Advanced Science. Advance online publication. https://doi.org/10.1002/advs.202511483

@article{f68fa9b81b5947d0a6a6fe040a901d9c,

title = "REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy",

abstract = "REEP1 contributes to the shaping of the endoplasmic reticulum (ER) through conserved transmembrane hairpins and a long C-terminal amphipathic helix. REEP1 loss-of-function causes hereditary spastic paraplegia due to degeneration of cortical motoneuron axons. Patients with deletion of REEP1 exon5 (Δexon5), which deletes part of its amphipathic helix, however, develop muscle atrophy due to degeneration of spinal motoneuron axons (distal hereditary motor neuropathy/dHMN). It is known that REEP1 knockout mice exhibit simplified ER structures in cortical motoneurons. Here, we show that these neurons are progressively lost while spinal motoneurons remain intact. Conversely, Δexon5 knockin (KI) mice lose spinal motoneurons preceded by ER fragmentation, whereas cortical motoneurons remain intact. Mechanistically, REEP1 undergoes ubiquitination and proteasomal degradation, a process compromised in the Δexon5 variant due to impaired ubiquitination, which thus accumulates in peripheral nerves. Proteomic analysis identifies HUWE1 as the E3 ligase responsible for REEP1 turnover. Modeling and liposome shaping assays reveal that the Δexon5 variant retains its capacity to induce membrane curvature. Consistently, other REEP1 variants associated with dHMN also show compromised ubiquitination and preserved transmembrane hairpins. Therefore, it is proposed that accumulation of shaping-competent REEP1 variants in the ER drives ER fragmentation and spinal motoneuron degeneration in dHMN.",

keywords = "HSP, REEP1, dHMN, endoplasmic reticulum, membrane shaping, ubiquitination",

author = "Andrea Bock and Mona Schurig and Miles Willoughby and Andrea Mirecki and Eric Seemann and Kateryna Lohachova and Istvan Katona and Sonnhild Mittag and Lutz Liebmann and Patricia Franzka and \{Heidari Horestani\}, Mehdi and Mukhran Khundadze and Thorsten Mosler and Timothy Louie and \{de Visser\}, Marianne and Weterman, \{Marian A. J.\} and Michael Kiehntopf and Christian Beetz and Sandor Nietzsche and Otmar Huber and Joachim Weis and Kessels, \{Michael M.\} and Bhaskara, \{Ramachandra M.\} and Britta Qualmann and Ivan {\D}iki{\'c} and H{\"u}bner, \{Christian A.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Science published by Wiley-VCH GmbH.",

year = "2025",

doi = "10.1002/advs.202511483",

language = "English",

journal = "Advanced Science",

issn = "2198-3844",

publisher = "Wiley-VCH Verlag",

}

Bock, A, Schurig, M, Willoughby, M, Mirecki, A, Seemann, E, Lohachova, K, Katona, I, Mittag, S, Liebmann, L, Franzka, P, Heidari Horestani, M, Khundadze, M, Mosler, T, Louie, T, de Visser, M, Weterman, MAJ, Kiehntopf, M, Beetz, C, Nietzsche, S, Huber, O, Weis, J, Kessels, MM, Bhaskara, RM, Qualmann, B, Đikić, I & Hübner, CA 2025, 'REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy', Advanced Science. https://doi.org/10.1002/advs.202511483

TY - JOUR

T1 - REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy

AU - Bock, Andrea

AU - Schurig, Mona

AU - Willoughby, Miles

AU - Mirecki, Andrea

AU - Seemann, Eric

AU - Lohachova, Kateryna

AU - Katona, Istvan

AU - Mittag, Sonnhild

AU - Liebmann, Lutz

AU - Franzka, Patricia

AU - Heidari Horestani, Mehdi

AU - Khundadze, Mukhran

AU - Mosler, Thorsten

AU - Louie, Timothy

AU - de Visser, Marianne

AU - Weterman, Marian A. J.

AU - Kiehntopf, Michael

AU - Beetz, Christian

AU - Nietzsche, Sandor

AU - Huber, Otmar

AU - Weis, Joachim

AU - Kessels, Michael M.

AU - Bhaskara, Ramachandra M.

AU - Qualmann, Britta

AU - Đikić, Ivan

AU - Hübner, Christian A.

PY - 2025

Y1 - 2025

N2 - REEP1 contributes to the shaping of the endoplasmic reticulum (ER) through conserved transmembrane hairpins and a long C-terminal amphipathic helix. REEP1 loss-of-function causes hereditary spastic paraplegia due to degeneration of cortical motoneuron axons. Patients with deletion of REEP1 exon5 (Δexon5), which deletes part of its amphipathic helix, however, develop muscle atrophy due to degeneration of spinal motoneuron axons (distal hereditary motor neuropathy/dHMN). It is known that REEP1 knockout mice exhibit simplified ER structures in cortical motoneurons. Here, we show that these neurons are progressively lost while spinal motoneurons remain intact. Conversely, Δexon5 knockin (KI) mice lose spinal motoneurons preceded by ER fragmentation, whereas cortical motoneurons remain intact. Mechanistically, REEP1 undergoes ubiquitination and proteasomal degradation, a process compromised in the Δexon5 variant due to impaired ubiquitination, which thus accumulates in peripheral nerves. Proteomic analysis identifies HUWE1 as the E3 ligase responsible for REEP1 turnover. Modeling and liposome shaping assays reveal that the Δexon5 variant retains its capacity to induce membrane curvature. Consistently, other REEP1 variants associated with dHMN also show compromised ubiquitination and preserved transmembrane hairpins. Therefore, it is proposed that accumulation of shaping-competent REEP1 variants in the ER drives ER fragmentation and spinal motoneuron degeneration in dHMN.

AB - REEP1 contributes to the shaping of the endoplasmic reticulum (ER) through conserved transmembrane hairpins and a long C-terminal amphipathic helix. REEP1 loss-of-function causes hereditary spastic paraplegia due to degeneration of cortical motoneuron axons. Patients with deletion of REEP1 exon5 (Δexon5), which deletes part of its amphipathic helix, however, develop muscle atrophy due to degeneration of spinal motoneuron axons (distal hereditary motor neuropathy/dHMN). It is known that REEP1 knockout mice exhibit simplified ER structures in cortical motoneurons. Here, we show that these neurons are progressively lost while spinal motoneurons remain intact. Conversely, Δexon5 knockin (KI) mice lose spinal motoneurons preceded by ER fragmentation, whereas cortical motoneurons remain intact. Mechanistically, REEP1 undergoes ubiquitination and proteasomal degradation, a process compromised in the Δexon5 variant due to impaired ubiquitination, which thus accumulates in peripheral nerves. Proteomic analysis identifies HUWE1 as the E3 ligase responsible for REEP1 turnover. Modeling and liposome shaping assays reveal that the Δexon5 variant retains its capacity to induce membrane curvature. Consistently, other REEP1 variants associated with dHMN also show compromised ubiquitination and preserved transmembrane hairpins. Therefore, it is proposed that accumulation of shaping-competent REEP1 variants in the ER drives ER fragmentation and spinal motoneuron degeneration in dHMN.

KW - HSP

KW - REEP1

KW - dHMN

KW - endoplasmic reticulum

KW - membrane shaping

KW - ubiquitination

UR - https://www.scopus.com/pages/publications/105022611907

U2 - 10.1002/advs.202511483

DO - 10.1002/advs.202511483

M3 - Article

C2 - 41268727

SN - 2198-3844

JO - Advanced Science

JF - Advanced Science

ER -

REEP1 Accumulation Disrupts ER Integrity and Drives Spinal Motoneuron Degeneration in Distal Hereditary Motor Neuropathy

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Keywords

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