A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species

Tal Benjamin-Zukerman; Gilat Shimon; Marie E. Gaine; Anwar Dakwar; Netta Peled; Mohammad Aboraya; Ashar Masri-Ismail; Rania Safadi-Safa; Meir Solomon; Varda Lev-Ram; Robert A. Rissman; Johanna E. Mayrhofer; Andrea Raffeiner; Merel O. Mol; Benney M.R. Argue; Shaylah McCool; Binh Doan; John van Swieten; Eduard Stefan; Ted Abel; Ronit Ilouz

doi:10.1093/brain/awae154

A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species

Tal Benjamin-Zukerman, Gilat Shimon, Marie E. Gaine, Anwar Dakwar, Netta Peled, Mohammad Aboraya, Ashar Masri-Ismail, Rania Safadi-Safa, Meir Solomon, Varda Lev-Ram, Robert A. Rissman, Johanna E. Mayrhofer, Andrea Raffeiner, Merel O. Mol, Benney M.R. Argue, Shaylah McCool, Binh Doan, John van Swieten, Eduard Stefan, Ted AbelRonit Ilouz

Bar-Ilan University - Azrieli Faculty of Medicine

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

Abstract

Protein kinase A (PKA) neuronal function is controlled by the interaction of a regulatory (R) subunit dimer with two catalytic subunits. Recently, the L50R variant in the gene encoding the RIβ subunit was identified in individuals with a novel neurodegenerative disease. However, the mechanisms driving the disease phenotype remained unknown. In this study, we generated a mouse model carrying the RIβ-L50R mutation to replicate the human disease phenotype and study its progression with age. We examined post-mortem brains of affected individuals as well as live cell cultures. Employing biochemical assays, immunohistochemistry and behavioural assessments, we investigated the impact of the mutation on PKA complex assembly, protein aggregation and neuronal degeneration. We reveal that RIβ is an aggregation-prone protein that progressively accumulates in wildtype and Alzheimer’s mouse models with age, while aggregation is accelerated in the RIβ-L50R mouse model. We define RIβ-L50R as a causal mutation driving an age-dependent behavioural and disease phenotype in human and mouse models. Mechanistically, this mutation disrupts RIβ dimerization, leading to aggregation of its monomers. Intriguingly, interaction with the catalytic subunit protects the RIβ-L50R from self-aggregating, in a dose-dependent manner. Furthermore, cAMP signaling induces RIβ-L50R aggregation. The pathophysiological mechanism elucidated here for a newly recognized neurodegenerative disease, in which protein aggregation is the result of disrupted homodimerization, sheds light on a remarkably under-appreciated but potentially common mechanism across several neurodegenerative diseases.

Original language	English
Pages (from-to)	3890-3905
Number of pages	16
Journal	Brain
Volume	147
Issue number	11
DOIs	https://doi.org/10.1093/brain/awae154
State	Published - 4 Nov 2024

Bibliographical note

Publisher Copyright:
© The Author(s) 2024. Published by Oxford University Press on behalf of the Guarantors of Brain.

Keywords

NLPD-PKA disease
PRKAR1B
neurodegenerative diseases
neuronal loss
protein aggregation
protein kinase A (PKA)

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1093/brain/awae154

Cite this

Benjamin-Zukerman, T., Shimon, G., Gaine, M. E., Dakwar, A., Peled, N., Aboraya, M., Masri-Ismail, A., Safadi-Safa, R., Solomon, M., Lev-Ram, V., Rissman, R. A., Mayrhofer, J. E., Raffeiner, A., Mol, M. O., Argue, B. M. R., McCool, S., Doan, B., van Swieten, J., Stefan, E., ... Ilouz, R. (2024). A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species. Brain, 147(11), 3890-3905. https://doi.org/10.1093/brain/awae154

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title = "A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species",

abstract = "Protein kinase A (PKA) neuronal function is controlled by the interaction of a regulatory (R) subunit dimer with two catalytic subunits. Recently, the L50R variant in the gene encoding the RIβ subunit was identified in individuals with a novel neurodegenerative disease. However, the mechanisms driving the disease phenotype remained unknown. In this study, we generated a mouse model carrying the RIβ-L50R mutation to replicate the human disease phenotype and study its progression with age. We examined post-mortem brains of affected individuals as well as live cell cultures. Employing biochemical assays, immunohistochemistry and behavioural assessments, we investigated the impact of the mutation on PKA complex assembly, protein aggregation and neuronal degeneration. We reveal that RIβ is an aggregation-prone protein that progressively accumulates in wildtype and Alzheimer{\textquoteright}s mouse models with age, while aggregation is accelerated in the RIβ-L50R mouse model. We define RIβ-L50R as a causal mutation driving an age-dependent behavioural and disease phenotype in human and mouse models. Mechanistically, this mutation disrupts RIβ dimerization, leading to aggregation of its monomers. Intriguingly, interaction with the catalytic subunit protects the RIβ-L50R from self-aggregating, in a dose-dependent manner. Furthermore, cAMP signaling induces RIβ-L50R aggregation. The pathophysiological mechanism elucidated here for a newly recognized neurodegenerative disease, in which protein aggregation is the result of disrupted homodimerization, sheds light on a remarkably under-appreciated but potentially common mechanism across several neurodegenerative diseases.",

keywords = "NLPD-PKA disease, PRKAR1B, neurodegenerative diseases, neuronal loss, protein aggregation, protein kinase A (PKA)",

author = "Tal Benjamin-Zukerman and Gilat Shimon and Gaine, {Marie E.} and Anwar Dakwar and Netta Peled and Mohammad Aboraya and Ashar Masri-Ismail and Rania Safadi-Safa and Meir Solomon and Varda Lev-Ram and Rissman, {Robert A.} and Mayrhofer, {Johanna E.} and Andrea Raffeiner and Mol, {Merel O.} and Argue, {Benney M.R.} and Shaylah McCool and Binh Doan and {van Swieten}, John and Eduard Stefan and Ted Abel and Ronit Ilouz",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024. Published by Oxford University Press on behalf of the Guarantors of Brain.",

year = "2024",

month = nov,

day = "4",

doi = "10.1093/brain/awae154",

language = "אנגלית",

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Benjamin-Zukerman, T, Shimon, G, Gaine, ME, Dakwar, A, Peled, N, Aboraya, M, Masri-Ismail, A, Safadi-Safa, R, Solomon, M, Lev-Ram, V, Rissman, RA, Mayrhofer, JE, Raffeiner, A, Mol, MO, Argue, BMR, McCool, S, Doan, B, van Swieten, J, Stefan, E, Abel, T & Ilouz, R 2024, 'A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species', Brain, vol. 147, no. 11, pp. 3890-3905. https://doi.org/10.1093/brain/awae154

TY - JOUR

T1 - A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species

AU - Benjamin-Zukerman, Tal

AU - Shimon, Gilat

AU - Gaine, Marie E.

AU - Dakwar, Anwar

AU - Peled, Netta

AU - Aboraya, Mohammad

AU - Masri-Ismail, Ashar

AU - Safadi-Safa, Rania

AU - Solomon, Meir

AU - Lev-Ram, Varda

AU - Rissman, Robert A.

AU - Mayrhofer, Johanna E.

AU - Raffeiner, Andrea

AU - Mol, Merel O.

AU - Argue, Benney M.R.

AU - McCool, Shaylah

AU - Doan, Binh

AU - van Swieten, John

AU - Stefan, Eduard

AU - Abel, Ted

AU - Ilouz, Ronit

PY - 2024/11/4

Y1 - 2024/11/4

N2 - Protein kinase A (PKA) neuronal function is controlled by the interaction of a regulatory (R) subunit dimer with two catalytic subunits. Recently, the L50R variant in the gene encoding the RIβ subunit was identified in individuals with a novel neurodegenerative disease. However, the mechanisms driving the disease phenotype remained unknown. In this study, we generated a mouse model carrying the RIβ-L50R mutation to replicate the human disease phenotype and study its progression with age. We examined post-mortem brains of affected individuals as well as live cell cultures. Employing biochemical assays, immunohistochemistry and behavioural assessments, we investigated the impact of the mutation on PKA complex assembly, protein aggregation and neuronal degeneration. We reveal that RIβ is an aggregation-prone protein that progressively accumulates in wildtype and Alzheimer’s mouse models with age, while aggregation is accelerated in the RIβ-L50R mouse model. We define RIβ-L50R as a causal mutation driving an age-dependent behavioural and disease phenotype in human and mouse models. Mechanistically, this mutation disrupts RIβ dimerization, leading to aggregation of its monomers. Intriguingly, interaction with the catalytic subunit protects the RIβ-L50R from self-aggregating, in a dose-dependent manner. Furthermore, cAMP signaling induces RIβ-L50R aggregation. The pathophysiological mechanism elucidated here for a newly recognized neurodegenerative disease, in which protein aggregation is the result of disrupted homodimerization, sheds light on a remarkably under-appreciated but potentially common mechanism across several neurodegenerative diseases.

AB - Protein kinase A (PKA) neuronal function is controlled by the interaction of a regulatory (R) subunit dimer with two catalytic subunits. Recently, the L50R variant in the gene encoding the RIβ subunit was identified in individuals with a novel neurodegenerative disease. However, the mechanisms driving the disease phenotype remained unknown. In this study, we generated a mouse model carrying the RIβ-L50R mutation to replicate the human disease phenotype and study its progression with age. We examined post-mortem brains of affected individuals as well as live cell cultures. Employing biochemical assays, immunohistochemistry and behavioural assessments, we investigated the impact of the mutation on PKA complex assembly, protein aggregation and neuronal degeneration. We reveal that RIβ is an aggregation-prone protein that progressively accumulates in wildtype and Alzheimer’s mouse models with age, while aggregation is accelerated in the RIβ-L50R mouse model. We define RIβ-L50R as a causal mutation driving an age-dependent behavioural and disease phenotype in human and mouse models. Mechanistically, this mutation disrupts RIβ dimerization, leading to aggregation of its monomers. Intriguingly, interaction with the catalytic subunit protects the RIβ-L50R from self-aggregating, in a dose-dependent manner. Furthermore, cAMP signaling induces RIβ-L50R aggregation. The pathophysiological mechanism elucidated here for a newly recognized neurodegenerative disease, in which protein aggregation is the result of disrupted homodimerization, sheds light on a remarkably under-appreciated but potentially common mechanism across several neurodegenerative diseases.

KW - NLPD-PKA disease

KW - PRKAR1B

KW - neurodegenerative diseases

KW - neuronal loss

KW - protein aggregation

KW - protein kinase A (PKA)

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SN - 0006-8950

VL - 147

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JO - Brain

JF - Brain

IS - 11

ER -

A mutation in the PRKAR1B gene drives pathological mechanisms of neurodegeneration across species

Abstract

Bibliographical note

Keywords

UN SDGs

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