DNA methylation-based analysis reveals accelerated epigenetic aging in giant cell-enriched adult-type glioblastoma
DNA methylation-based analysis reveals accelerated epigenetic aging in giant cell-enriched adult-type glioblastoma
BACKGROUND: Giant cell (gc)-enriched glioblastoma (gcGB) represents a distinct histological variant of isocitrate dehydrogenase wild-type adult-type glioblastoma with notable enlarged mono- or multinuclear tumor cells. While some studies suggest a survival advantage for gcGB patients, the underlying causes remain elusive. GcGBs are associated with TP53 mutations, and gcs were shown to accumulate DNA double-strand breaks and show deficient mitosis, potentially triggering cellular senescence programs. Epigenetic clocks have emerged as valuable tools for assessing tumor-induced age acceleration (DNAMethAgeAcc), which has lately proved itself as prognostic biomarker in glioblastoma. Our study aimed to comprehensively analyze the methylome and key metabolic proteins of gcGBs, hypothesizing that they undergo cellular aging programs compared to non-gcGBs.
RESULTS: A total of 310 epigenetically classified GBs, including 26 gcGBs, and nine adults with malignant gliomas allocating to pediatric high-grade glioma molecular subclasses (summarized as "pediatric GB") were included. DNAMethAgeAcc was computed by subtraction of chronological patient ages from DNA methylome-derived age estimations and its increase was associated with better survival within gcGB and non-gcGB. GcGBs were significantly more often allocated to the subgroup with increased DNAMethAgeAcc and demonstrated the highest DNAMethAgeAcc. Hypothetical senescence/aging-induced changes of the tumor microenvironment were addressed by tumor deconvolution, which was able to identify a cluster enriched for tumors with increased DNAMethAgeAcc. Key metabolic protein expression did not differ between gcGB and non-gcGB and tumor with versus without increased DNAMethAgeAcc but for elevated levels of one single mitochondrial marker, anti-mitochondrial protein MT-C02, in gcGBs.
CONCLUSIONS: With its sped-up epigenetic aging, gcGB presented as the epigenetic oldest GB variant in our cohort. Whereas the correlation between accelerated tumor-intrinsic epigenetic aging and cellular senescence in gcGB stays elusive, fostering epigenetic aging programs in GB might be of interest for future exploration of alternative treatment options in GB patients.
Humans, Glioblastoma/genetics, Epigenesis, Genetic/genetics, DNA Methylation/genetics, Adult, Female, Male, Brain Neoplasms/genetics, Middle Aged, Aged, Cellular Senescence/genetics, Isocitrate Dehydrogenase/genetics
179
Cakmak, Pinar
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Jurmeister, Philipp
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Divé, Iris
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Zeiner, Pia S
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Steinbach, Joachim P
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Fenton, Tim R
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Plate, Karl H
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Czabanka, Marcus
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Harter, Patrick N
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Weber, Katharina J
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11 December 2024
Cakmak, Pinar
cb05bc42-50f0-4be0-aee1-b57fff15d193
Jurmeister, Philipp
5ba5fe9c-51b8-46ed-aa3b-d31a24f2d2df
Divé, Iris
e2e1a421-4df4-4972-b170-db2a776c0070
Zeiner, Pia S
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Steinbach, Joachim P
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Fenton, Tim R
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Plate, Karl H
cb47d772-5b70-4293-a392-ce19246b7e0c
Czabanka, Marcus
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Harter, Patrick N
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Weber, Katharina J
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Cakmak, Pinar, Jurmeister, Philipp, Divé, Iris, Zeiner, Pia S, Steinbach, Joachim P, Fenton, Tim R, Plate, Karl H, Czabanka, Marcus, Harter, Patrick N and Weber, Katharina J
(2024)
DNA methylation-based analysis reveals accelerated epigenetic aging in giant cell-enriched adult-type glioblastoma.
Clinical Epigenetics, 16 (1), .
(doi:10.1186/s13148-024-01793-w).
Abstract
BACKGROUND: Giant cell (gc)-enriched glioblastoma (gcGB) represents a distinct histological variant of isocitrate dehydrogenase wild-type adult-type glioblastoma with notable enlarged mono- or multinuclear tumor cells. While some studies suggest a survival advantage for gcGB patients, the underlying causes remain elusive. GcGBs are associated with TP53 mutations, and gcs were shown to accumulate DNA double-strand breaks and show deficient mitosis, potentially triggering cellular senescence programs. Epigenetic clocks have emerged as valuable tools for assessing tumor-induced age acceleration (DNAMethAgeAcc), which has lately proved itself as prognostic biomarker in glioblastoma. Our study aimed to comprehensively analyze the methylome and key metabolic proteins of gcGBs, hypothesizing that they undergo cellular aging programs compared to non-gcGBs.
RESULTS: A total of 310 epigenetically classified GBs, including 26 gcGBs, and nine adults with malignant gliomas allocating to pediatric high-grade glioma molecular subclasses (summarized as "pediatric GB") were included. DNAMethAgeAcc was computed by subtraction of chronological patient ages from DNA methylome-derived age estimations and its increase was associated with better survival within gcGB and non-gcGB. GcGBs were significantly more often allocated to the subgroup with increased DNAMethAgeAcc and demonstrated the highest DNAMethAgeAcc. Hypothetical senescence/aging-induced changes of the tumor microenvironment were addressed by tumor deconvolution, which was able to identify a cluster enriched for tumors with increased DNAMethAgeAcc. Key metabolic protein expression did not differ between gcGB and non-gcGB and tumor with versus without increased DNAMethAgeAcc but for elevated levels of one single mitochondrial marker, anti-mitochondrial protein MT-C02, in gcGBs.
CONCLUSIONS: With its sped-up epigenetic aging, gcGB presented as the epigenetic oldest GB variant in our cohort. Whereas the correlation between accelerated tumor-intrinsic epigenetic aging and cellular senescence in gcGB stays elusive, fostering epigenetic aging programs in GB might be of interest for future exploration of alternative treatment options in GB patients.
Text
s13148-024-01793-w
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Accepted/In Press date: 24 November 2024
Published date: 11 December 2024
Additional Information:
© 2024. The Author(s).
Keywords:
Humans, Glioblastoma/genetics, Epigenesis, Genetic/genetics, DNA Methylation/genetics, Adult, Female, Male, Brain Neoplasms/genetics, Middle Aged, Aged, Cellular Senescence/genetics, Isocitrate Dehydrogenase/genetics
Identifiers
Local EPrints ID: 496582
URI: http://eprints.soton.ac.uk/id/eprint/496582
ISSN: 1868-7075
PURE UUID: 243bacd6-47c9-4dda-a290-41cc2b623d5e
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Date deposited: 19 Dec 2024 17:45
Last modified: 20 Dec 2024 03:02
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Author:
Pinar Cakmak
Author:
Philipp Jurmeister
Author:
Iris Divé
Author:
Pia S Zeiner
Author:
Joachim P Steinbach
Author:
Karl H Plate
Author:
Marcus Czabanka
Author:
Patrick N Harter
Author:
Katharina J Weber
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