Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes

Cristina T. Vicente; Tejasvi Niranjan; Elise Coopman; Júlia Faura; Sara Alidadiani; Claudia Schrauwen; Billie J. Matchett; Bavo Heeman; Marleen Van den Broeck; Wouter De Coster; Thuy Nguyen; Julie S. Lau; Saurabh Baheti; Tim de Pooter; Peter De Rijk; Mojca Strazisar; Matt Baker; Mariely DeJesus-Hernandez; Ni Cole A. Finch; Cyril Pottier; Marka van Blitterswijk; Yan Asmann; Melissa E. Murray; Leonard Petrucelli; Andrew King; Claire Troakes; Safa Al-Sarraj; Robert A. Rissman; Annie Hiniker; Margaret Flanagan; Bret M. Evers; Charles L. White; Carlos Cruchaga; Rudolph Castellani; Jeroen G.J. van Rooij; Merel O. Mol; Harro Seelaar; John C. van Swieten; Björn Oskarsson; Robert Ross Reichard; Aivi T. Nguyen; Keith A. Josephs; Ronald C. Petersen; Nilüfer Ertekin-Taner; Bradley F. Boeve; Neill R. Graff-Radford; Sarah Weckhuysen; Dennis W. Dickson; Rosa Rademakers

doi:10.1186/s13024-025-00869-2

Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes

Cristina T. Vicente
, Tejasvi Niranjan
, Elise Coopman
, Júlia Faura
, Sara Alidadiani
, Claudia Schrauwen
, Billie J. Matchett
, Bavo Heeman
, Marleen Van den Broeck
, Wouter De Coster
, Thuy Nguyen
, Julie S. Lau
, Saurabh Baheti
, Tim de Pooter
, Peter De Rijk
, Mojca Strazisar
, Matt Baker
, Mariely DeJesus-Hernandez
, Ni Cole A. Finch
, Cyril Pottier

Marka van Blitterswijk, Yan Asmann, Melissa E. Murray, Leonard Petrucelli, Andrew King, Claire Troakes, Safa Al-Sarraj, Robert A. Rissman, Annie Hiniker, Margaret Flanagan, Bret M. Evers, Charles L. White, Carlos Cruchaga, Rudolph Castellani, Jeroen G.J. van Rooij, Merel O. Mol, Harro Seelaar, John C. van Swieten, Björn Oskarsson, Robert Ross Reichard, Aivi T. Nguyen, Keith A. Josephs, Ronald C. Petersen, Nilüfer Ertekin-Taner, Bradley F. Boeve, Neill R. Graff-Radford, Sarah Weckhuysen, Dennis W. Dickson, Rosa Rademakers

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

Abstract

Background: In the last decade, the importance of DNA methylation in the functioning of the central nervous system has been highlighted through associations between methylation changes and differential expression of key genes involved in aging and neurodegenerative diseases. In frontotemporal lobar degeneration (FTLD), aberrant methylation has been reported in causal disease genes including GRN and C9orf72; however, the genome-wide contribution of epigenetic changes to the development of FTLD remains largely unexplored. Methods: We performed reduced representation bisulfite sequencing of matched pairs of post-mortem tissue from frontal cortex (FCX) and cerebellum (CER) from pathologically confirmed FTLD patients with TDP-43 pathology (FTLD-TDP) further divided into five subtypes and including both sporadic and genetic forms (N = 25 pairs per group), and neuropathologically normal controls (N = 42 pairs). Case-control differential methylation analyses were performed, both at the individual CpG level, and in regions of grouped CpGs (differentially methylated regions; DMRs), either including all genomic locations or only gene promoters. Gene Ontology (GO) analyses were then performed using all differentially methylated genes in each group of sporadic patients. Finally, additional datasets were queried to prioritize candidate genes for follow-up. Results: Using the largest FTLD-TDP DNA methylation dataset generated to date, we identified thousands of differentially methylated CpGs (FCX = 6,520; CER = 7,134) and several hundred DMRs in FTLD-TDP brains (FCX = 134; CER = 219). Of these, less than 10% are shared between pathological subgroups. Combining additional datasets, we identified, validated and replicated hypomethylation of CAMTA1 in TDP-A potentially also impacting additional genes in the locus. GO analysis further implicated DNA methylation in myelination and developmental processes, as well as important disease-relevant mechanisms with subtype specificity such as protein phosphorylation and DNA damage repair in TDP-A, cholesterol biosynthesis in TDP-B, and protein localization in TDP-C. Conclusions: We identify methylation changes in all FTLD-TDP patient groups and show that most changes are unique to a specific pathological FTLD-TDP subtype, suggesting that these subtypes not only have distinct transcriptomic and genetic signatures, but are also epigenetically distinct. Our study constitutes an invaluable resource to the community and highlights the need for further studies to profile additional epigenetic layers within each FTLD-TDP pathological subtype.

Original language	English
Article number	80
Journal	Molecular neurodegeneration
Volume	20
Issue number	1
DOIs	https://doi.org/10.1186/s13024-025-00869-2
State	Published - Dec 2025

Keywords

Brain
DNA methylation
Epigenetics
FTLD
FTLD-TDP
Frontotemporal lobar degeneration
Methylome
Neurodegeneration
Pathological subtypes
TDP-43

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10.1186/s13024-025-00869-2

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Vicente, C. T., Niranjan, T., Coopman, E., Faura, J., Alidadiani, S., Schrauwen, C., Matchett, B. J., Heeman, B., Van den Broeck, M., De Coster, W., Nguyen, T., Lau, J. S., Baheti, S., de Pooter, T., De Rijk, P., Strazisar, M., Baker, M., DeJesus-Hernandez, M., Finch, N. C. A., ... Rademakers, R. (2025). Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes. Molecular neurodegeneration, 20(1), Article 80. https://doi.org/10.1186/s13024-025-00869-2

@article{cd01bfe055684eb59bdf81caa8192926,

title = "Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes",

abstract = "Background: In the last decade, the importance of DNA methylation in the functioning of the central nervous system has been highlighted through associations between methylation changes and differential expression of key genes involved in aging and neurodegenerative diseases. In frontotemporal lobar degeneration (FTLD), aberrant methylation has been reported in causal disease genes including GRN and C9orf72; however, the genome-wide contribution of epigenetic changes to the development of FTLD remains largely unexplored. Methods: We performed reduced representation bisulfite sequencing of matched pairs of post-mortem tissue from frontal cortex (FCX) and cerebellum (CER) from pathologically confirmed FTLD patients with TDP-43 pathology (FTLD-TDP) further divided into five subtypes and including both sporadic and genetic forms (N = 25 pairs per group), and neuropathologically normal controls (N = 42 pairs). Case-control differential methylation analyses were performed, both at the individual CpG level, and in regions of grouped CpGs (differentially methylated regions; DMRs), either including all genomic locations or only gene promoters. Gene Ontology (GO) analyses were then performed using all differentially methylated genes in each group of sporadic patients. Finally, additional datasets were queried to prioritize candidate genes for follow-up. Results: Using the largest FTLD-TDP DNA methylation dataset generated to date, we identified thousands of differentially methylated CpGs (FCX = 6,520; CER = 7,134) and several hundred DMRs in FTLD-TDP brains (FCX = 134; CER = 219). Of these, less than 10\% are shared between pathological subgroups. Combining additional datasets, we identified, validated and replicated hypomethylation of CAMTA1 in TDP-A potentially also impacting additional genes in the locus. GO analysis further implicated DNA methylation in myelination and developmental processes, as well as important disease-relevant mechanisms with subtype specificity such as protein phosphorylation and DNA damage repair in TDP-A, cholesterol biosynthesis in TDP-B, and protein localization in TDP-C. Conclusions: We identify methylation changes in all FTLD-TDP patient groups and show that most changes are unique to a specific pathological FTLD-TDP subtype, suggesting that these subtypes not only have distinct transcriptomic and genetic signatures, but are also epigenetically distinct. Our study constitutes an invaluable resource to the community and highlights the need for further studies to profile additional epigenetic layers within each FTLD-TDP pathological subtype.",

keywords = "Brain, DNA methylation, Epigenetics, FTLD, FTLD-TDP, Frontotemporal lobar degeneration, Methylome, Neurodegeneration, Pathological subtypes, TDP-43",

author = "Vicente, \{Cristina T.\} and Tejasvi Niranjan and Elise Coopman and J{\'u}lia Faura and Sara Alidadiani and Claudia Schrauwen and Matchett, \{Billie J.\} and Bavo Heeman and \{Van den Broeck\}, Marleen and \{De Coster\}, Wouter and Thuy Nguyen and Lau, \{Julie S.\} and Saurabh Baheti and \{de Pooter\}, Tim and \{De Rijk\}, Peter and Mojca Strazisar and Matt Baker and Mariely DeJesus-Hernandez and Finch, \{Ni Cole A.\} and Cyril Pottier and \{van Blitterswijk\}, Marka and Yan Asmann and Murray, \{Melissa E.\} and Leonard Petrucelli and Andrew King and Claire Troakes and Safa Al-Sarraj and Rissman, \{Robert A.\} and Annie Hiniker and Margaret Flanagan and Evers, \{Bret M.\} and White, \{Charles L.\} and Carlos Cruchaga and Rudolph Castellani and \{van Rooij\}, \{Jeroen G.J.\} and Mol, \{Merel O.\} and Harro Seelaar and \{van Swieten\}, \{John C.\} and Bj{\"o}rn Oskarsson and Reichard, \{Robert Ross\} and Nguyen, \{Aivi T.\} and Josephs, \{Keith A.\} and Petersen, \{Ronald C.\} and Nil{\"u}fer Ertekin-Taner and Boeve, \{Bradley F.\} and Graff-Radford, \{Neill R.\} and Sarah Weckhuysen and Dickson, \{Dennis W.\} and Rosa Rademakers",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1186/s13024-025-00869-2",

language = "English",

volume = "20",

journal = "Molecular neurodegeneration",

issn = "1750-1326",

number = "1",

}

Vicente, CT, Niranjan, T, Coopman, E, Faura, J, Alidadiani, S, Schrauwen, C, Matchett, BJ, Heeman, B, Van den Broeck, M, De Coster, W, Nguyen, T, Lau, JS, Baheti, S, de Pooter, T, De Rijk, P, Strazisar, M, Baker, M, DeJesus-Hernandez, M, Finch, NCA, Pottier, C, van Blitterswijk, M, Asmann, Y, Murray, ME, Petrucelli, L, King, A, Troakes, C, Al-Sarraj, S, Rissman, RA, Hiniker, A, Flanagan, M, Evers, BM, White, CL, Cruchaga, C, Castellani, R, van Rooij, JGJ, Mol, MO, Seelaar, H, van Swieten, JC, Oskarsson, B, Reichard, RR, Nguyen, AT, Josephs, KA, Petersen, RC, Ertekin-Taner, N, Boeve, BF, Graff-Radford, NR, Weckhuysen, S, Dickson, DW & Rademakers, R 2025, 'Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes', Molecular neurodegeneration, vol. 20, no. 1, 80. https://doi.org/10.1186/s13024-025-00869-2

TY - JOUR

T1 - Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes

AU - Vicente, Cristina T.

AU - Niranjan, Tejasvi

AU - Coopman, Elise

AU - Faura, Júlia

AU - Alidadiani, Sara

AU - Schrauwen, Claudia

AU - Matchett, Billie J.

AU - Heeman, Bavo

AU - Van den Broeck, Marleen

AU - De Coster, Wouter

AU - Nguyen, Thuy

AU - Lau, Julie S.

AU - Baheti, Saurabh

AU - de Pooter, Tim

AU - De Rijk, Peter

AU - Strazisar, Mojca

AU - Baker, Matt

AU - DeJesus-Hernandez, Mariely

AU - Finch, Ni Cole A.

AU - Pottier, Cyril

AU - van Blitterswijk, Marka

AU - Asmann, Yan

AU - Murray, Melissa E.

AU - Petrucelli, Leonard

AU - King, Andrew

AU - Troakes, Claire

AU - Al-Sarraj, Safa

AU - Rissman, Robert A.

AU - Hiniker, Annie

AU - Flanagan, Margaret

AU - Evers, Bret M.

AU - White, Charles L.

AU - Cruchaga, Carlos

AU - Castellani, Rudolph

AU - van Rooij, Jeroen G.J.

AU - Mol, Merel O.

AU - Seelaar, Harro

AU - van Swieten, John C.

AU - Oskarsson, Björn

AU - Reichard, Robert Ross

AU - Nguyen, Aivi T.

AU - Josephs, Keith A.

AU - Petersen, Ronald C.

AU - Ertekin-Taner, Nilüfer

AU - Boeve, Bradley F.

AU - Graff-Radford, Neill R.

AU - Weckhuysen, Sarah

AU - Dickson, Dennis W.

AU - Rademakers, Rosa

PY - 2025/12

Y1 - 2025/12

N2 - Background: In the last decade, the importance of DNA methylation in the functioning of the central nervous system has been highlighted through associations between methylation changes and differential expression of key genes involved in aging and neurodegenerative diseases. In frontotemporal lobar degeneration (FTLD), aberrant methylation has been reported in causal disease genes including GRN and C9orf72; however, the genome-wide contribution of epigenetic changes to the development of FTLD remains largely unexplored. Methods: We performed reduced representation bisulfite sequencing of matched pairs of post-mortem tissue from frontal cortex (FCX) and cerebellum (CER) from pathologically confirmed FTLD patients with TDP-43 pathology (FTLD-TDP) further divided into five subtypes and including both sporadic and genetic forms (N = 25 pairs per group), and neuropathologically normal controls (N = 42 pairs). Case-control differential methylation analyses were performed, both at the individual CpG level, and in regions of grouped CpGs (differentially methylated regions; DMRs), either including all genomic locations or only gene promoters. Gene Ontology (GO) analyses were then performed using all differentially methylated genes in each group of sporadic patients. Finally, additional datasets were queried to prioritize candidate genes for follow-up. Results: Using the largest FTLD-TDP DNA methylation dataset generated to date, we identified thousands of differentially methylated CpGs (FCX = 6,520; CER = 7,134) and several hundred DMRs in FTLD-TDP brains (FCX = 134; CER = 219). Of these, less than 10% are shared between pathological subgroups. Combining additional datasets, we identified, validated and replicated hypomethylation of CAMTA1 in TDP-A potentially also impacting additional genes in the locus. GO analysis further implicated DNA methylation in myelination and developmental processes, as well as important disease-relevant mechanisms with subtype specificity such as protein phosphorylation and DNA damage repair in TDP-A, cholesterol biosynthesis in TDP-B, and protein localization in TDP-C. Conclusions: We identify methylation changes in all FTLD-TDP patient groups and show that most changes are unique to a specific pathological FTLD-TDP subtype, suggesting that these subtypes not only have distinct transcriptomic and genetic signatures, but are also epigenetically distinct. Our study constitutes an invaluable resource to the community and highlights the need for further studies to profile additional epigenetic layers within each FTLD-TDP pathological subtype.

AB - Background: In the last decade, the importance of DNA methylation in the functioning of the central nervous system has been highlighted through associations between methylation changes and differential expression of key genes involved in aging and neurodegenerative diseases. In frontotemporal lobar degeneration (FTLD), aberrant methylation has been reported in causal disease genes including GRN and C9orf72; however, the genome-wide contribution of epigenetic changes to the development of FTLD remains largely unexplored. Methods: We performed reduced representation bisulfite sequencing of matched pairs of post-mortem tissue from frontal cortex (FCX) and cerebellum (CER) from pathologically confirmed FTLD patients with TDP-43 pathology (FTLD-TDP) further divided into five subtypes and including both sporadic and genetic forms (N = 25 pairs per group), and neuropathologically normal controls (N = 42 pairs). Case-control differential methylation analyses were performed, both at the individual CpG level, and in regions of grouped CpGs (differentially methylated regions; DMRs), either including all genomic locations or only gene promoters. Gene Ontology (GO) analyses were then performed using all differentially methylated genes in each group of sporadic patients. Finally, additional datasets were queried to prioritize candidate genes for follow-up. Results: Using the largest FTLD-TDP DNA methylation dataset generated to date, we identified thousands of differentially methylated CpGs (FCX = 6,520; CER = 7,134) and several hundred DMRs in FTLD-TDP brains (FCX = 134; CER = 219). Of these, less than 10% are shared between pathological subgroups. Combining additional datasets, we identified, validated and replicated hypomethylation of CAMTA1 in TDP-A potentially also impacting additional genes in the locus. GO analysis further implicated DNA methylation in myelination and developmental processes, as well as important disease-relevant mechanisms with subtype specificity such as protein phosphorylation and DNA damage repair in TDP-A, cholesterol biosynthesis in TDP-B, and protein localization in TDP-C. Conclusions: We identify methylation changes in all FTLD-TDP patient groups and show that most changes are unique to a specific pathological FTLD-TDP subtype, suggesting that these subtypes not only have distinct transcriptomic and genetic signatures, but are also epigenetically distinct. Our study constitutes an invaluable resource to the community and highlights the need for further studies to profile additional epigenetic layers within each FTLD-TDP pathological subtype.

KW - Brain

KW - DNA methylation

KW - Epigenetics

KW - FTLD

KW - FTLD-TDP

KW - Frontotemporal lobar degeneration

KW - Methylome

KW - Neurodegeneration

KW - Pathological subtypes

KW - TDP-43

UR - https://www.scopus.com/pages/publications/105009972622

U2 - 10.1186/s13024-025-00869-2

DO - 10.1186/s13024-025-00869-2

M3 - Article

C2 - 40619440

AN - SCOPUS:105009972622

SN - 1750-1326

VL - 20

JO - Molecular neurodegeneration

JF - Molecular neurodegeneration

IS - 1

M1 - 80

ER -

Methylome analysis of FTLD patients with TDP-43 pathology identifies epigenetic signatures specific to pathological subtypes

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