Neuronal aging causes mislocalization of splicing proteins and unchecked cellular stress

Kevin Rhine; Rachel Li; Hema M. Kopalle; Katherine Rothamel; Xuezhen Ge; Elle Epstein; Orel Mizrahi; Assael A. Madrigal; Hsuan Lin Her; Trent A. Gomberg; Anita Hermann; Joshua L. Schwartz; Amanda J. Daniels; Uri Manor; John Ravits; Robert A.J. Signer; Eric J. Bennett; Gene W. Yeo

doi:10.1038/s41593-025-01952-z

Neuronal aging causes mislocalization of splicing proteins and unchecked cellular stress

Kevin Rhine
, Rachel Li
, Hema M. Kopalle
, Katherine Rothamel
, Xuezhen Ge
, Elle Epstein
, Orel Mizrahi
, Assael A. Madrigal
, Hsuan Lin Her
, Trent A. Gomberg
, Anita Hermann
, Joshua L. Schwartz
, Amanda J. Daniels
, Uri Manor
, John Ravits
, Robert A.J. Signer
, Eric J. Bennett
, Gene W. Yeo

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

16 Scopus citations

Abstract

Aging is one of the most prominent risk factors for neurodegeneration, yet the molecular mechanisms underlying the deterioration of old neurons are mostly unknown. To efficiently study neurodegeneration in the context of aging, we transdifferentiated primary human fibroblasts from aged healthy donors directly into neurons, which retained their aging hallmarks, and we verified key findings in aged human and mouse brain tissue. Here we show that aged neurons are broadly depleted of RNA-binding proteins, especially spliceosome components. Intriguingly, splicing proteins—like the dementia- and ALS-associated protein TDP-43—mislocalize to the cytoplasm in aged neurons, which leads to widespread alternative splicing. Cytoplasmic spliceosome components are typically recruited to stress granules, but aged neurons suffer from chronic cellular stress that prevents this sequestration. We link chronic stress to the malfunctioning ubiquitylation machinery, poor HSP90α chaperone activity and the failure to respond to new stress events. Together, our data demonstrate that aging-linked deterioration of RNA biology is a key driver of poor resiliency in aged neurons.

Original language	English (US)
Pages (from-to)	1174-1184
Number of pages	11
Journal	Nature neuroscience
Volume	28
Issue number	6
DOIs	https://doi.org/10.1038/s41593-025-01952-z
State	Published - Jun 2025
Externally published	Yes

ASJC Scopus subject areas

General Neuroscience

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10.1038/s41593-025-01952-z

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Rhine, K., Li, R., Kopalle, H. M., Rothamel, K., Ge, X., Epstein, E., Mizrahi, O., Madrigal, A. A., Her, H. L., Gomberg, T. A., Hermann, A., Schwartz, J. L., Daniels, A. J., Manor, U., Ravits, J., Signer, R. A. J., Bennett, E. J., & Yeo, G. W. (2025). Neuronal aging causes mislocalization of splicing proteins and unchecked cellular stress. Nature neuroscience, 28(6), 1174-1184. https://doi.org/10.1038/s41593-025-01952-z

Rhine, K, Li, R, Kopalle, HM, Rothamel, K, Ge, X, Epstein, E, Mizrahi, O, Madrigal, AA, Her, HL, Gomberg, TA, Hermann, A, Schwartz, JL, Daniels, AJ, Manor, U, Ravits, J, Signer, RAJ, Bennett, EJ & Yeo, GW 2025, 'Neuronal aging causes mislocalization of splicing proteins and unchecked cellular stress', Nature neuroscience, vol. 28, no. 6, pp. 1174-1184. https://doi.org/10.1038/s41593-025-01952-z

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title = "Neuronal aging causes mislocalization of splicing proteins and unchecked cellular stress",

abstract = "Aging is one of the most prominent risk factors for neurodegeneration, yet the molecular mechanisms underlying the deterioration of old neurons are mostly unknown. To efficiently study neurodegeneration in the context of aging, we transdifferentiated primary human fibroblasts from aged healthy donors directly into neurons, which retained their aging hallmarks, and we verified key findings in aged human and mouse brain tissue. Here we show that aged neurons are broadly depleted of RNA-binding proteins, especially spliceosome components. Intriguingly, splicing proteins—like the dementia- and ALS-associated protein TDP-43—mislocalize to the cytoplasm in aged neurons, which leads to widespread alternative splicing. Cytoplasmic spliceosome components are typically recruited to stress granules, but aged neurons suffer from chronic cellular stress that prevents this sequestration. We link chronic stress to the malfunctioning ubiquitylation machinery, poor HSP90α chaperone activity and the failure to respond to new stress events. Together, our data demonstrate that aging-linked deterioration of RNA biology is a key driver of poor resiliency in aged neurons.",

author = "Kevin Rhine and Rachel Li and Kopalle, \{Hema M.\} and Katherine Rothamel and Xuezhen Ge and Elle Epstein and Orel Mizrahi and Madrigal, \{Assael A.\} and Her, \{Hsuan Lin\} and Gomberg, \{Trent A.\} and Anita Hermann and Schwartz, \{Joshua L.\} and Daniels, \{Amanda J.\} and Uri Manor and John Ravits and Signer, \{Robert A.J.\} and Bennett, \{Eric J.\} and Yeo, \{Gene W.\}",

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doi = "10.1038/s41593-025-01952-z",

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AU - Rhine, Kevin

AU - Li, Rachel

AU - Kopalle, Hema M.

AU - Rothamel, Katherine

AU - Ge, Xuezhen

AU - Epstein, Elle

AU - Mizrahi, Orel

AU - Madrigal, Assael A.

AU - Her, Hsuan Lin

AU - Gomberg, Trent A.

AU - Hermann, Anita

AU - Schwartz, Joshua L.

AU - Daniels, Amanda J.

AU - Manor, Uri

AU - Ravits, John

AU - Signer, Robert A.J.

AU - Bennett, Eric J.

AU - Yeo, Gene W.

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AB - Aging is one of the most prominent risk factors for neurodegeneration, yet the molecular mechanisms underlying the deterioration of old neurons are mostly unknown. To efficiently study neurodegeneration in the context of aging, we transdifferentiated primary human fibroblasts from aged healthy donors directly into neurons, which retained their aging hallmarks, and we verified key findings in aged human and mouse brain tissue. Here we show that aged neurons are broadly depleted of RNA-binding proteins, especially spliceosome components. Intriguingly, splicing proteins—like the dementia- and ALS-associated protein TDP-43—mislocalize to the cytoplasm in aged neurons, which leads to widespread alternative splicing. Cytoplasmic spliceosome components are typically recruited to stress granules, but aged neurons suffer from chronic cellular stress that prevents this sequestration. We link chronic stress to the malfunctioning ubiquitylation machinery, poor HSP90α chaperone activity and the failure to respond to new stress events. Together, our data demonstrate that aging-linked deterioration of RNA biology is a key driver of poor resiliency in aged neurons.

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Neuronal aging causes mislocalization of splicing proteins and unchecked cellular stress

Abstract

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