PROSER1 Modulates DNA Demethylation through Dual Mechanisms to Prevent Syndromic Developmental Malformations

Anna Fleming; Elena V. Knatko; Xiang Li; Ansgar Zoch; Zoe Heckhausen; Stephanie Stransky; Alejandro Brenes Murillo; Simone Sidoli; Petra Hajkova; Dónal O'Carroll; Kasper Rasmussen

doi:10.1101/2024.07.31.606086

PROSER1 Modulates DNA Demethylation through Dual Mechanisms to Prevent Syndromic Developmental Malformations

Anna Fleming, Elena V. Knatko, Xiang Li, Ansgar Zoch, Zoe Heckhausen, Stephanie Stransky, Alejandro Brenes Murillo, Simone Sidoli, Petra Hajkova, Dónal O'Carroll, Kasper Rasmussen (Lead / Corresponding author)

Research output: Working paper/Preprint › Preprint

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Abstract

The link between DNA methylation and neurodevelopmental disorders is well established. However, how DNA methylation is fine-tuned – ensuring precise gene expression and developmental fidelity – remains poorly understood. PROSER1, a known TET2 interactor, was recently linked to a severe neurodevelopmental disorder. Here, we demonstrate that PROSER1 interacts with all TET enzymes and stabilizes chromatin-bound TET-OGT-PROSER1-DBHS (TOPD) complexes, which regulate DNA demethylation and developmental gene expression. Surprisingly, we find that PROSER1 also sequesters TET enzymes, preventing widespread demethylation and transposable element de-repression. Our findings identify PROSER1 as a key factor which both positively and negatively regulates DNA demethylation essential for mammalian neurodevelopment.

Original language	English
Publisher	BioRxiv
Number of pages	34
DOIs	https://doi.org/10.1101/2024.07.31.606086
Publication status	Published - 2 Aug 2024

Keywords

TET1
TET2
TET3
DNA methylation
TOPD
Development
Neurodevelopmental disorder

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10.1101/2024.07.31.606086Licence: CC BY

Preprint VersionSubmitted manuscript, 4.53 MBLicence: CC BY

1 Active

Aberrant DNA Methylation and its Impact in Blood Cancer Development (Career Development Fellowship)
Owen-Hughes, T. (Investigator) & Rasmussen, K. (Investigator)
1/06/19 → 31/05/25
Project: Research

1 Article

PROSER1 modulates DNA demethylation through dual mechanisms to prevent syndromic developmental malformations
Fleming, A., Knatko, E. V., Li, X., Zoch, A., Heckhausen, Z., Stransky, S., Brenes, A. J., Sidoli, S., Hajkova, P., O'Carroll, D. & Rasmussen, K. (Lead / Corresponding author), Dec 2024, In: Genes & Development. 38, p. 952-964 13 p.
Research output: Contribution to journal › Article › peer-review

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abstract = "The link between DNA methylation and neurodevelopmental disorders is well established. However, how DNA methylation is fine-tuned – ensuring precise gene expression and developmental fidelity – remains poorly understood. PROSER1, a known TET2 interactor, was recently linked to a severe neurodevelopmental disorder. Here, we demonstrate that PROSER1 interacts with all TET enzymes and stabilizes chromatin-bound TET-OGT-PROSER1-DBHS (TOPD) complexes, which regulate DNA demethylation and developmental gene expression. Surprisingly, we find that PROSER1 also sequesters TET enzymes, preventing widespread demethylation and transposable element de-repression. Our findings identify PROSER1 as a key factor which both positively and negatively regulates DNA demethylation essential for mammalian neurodevelopment.",

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AB - The link between DNA methylation and neurodevelopmental disorders is well established. However, how DNA methylation is fine-tuned – ensuring precise gene expression and developmental fidelity – remains poorly understood. PROSER1, a known TET2 interactor, was recently linked to a severe neurodevelopmental disorder. Here, we demonstrate that PROSER1 interacts with all TET enzymes and stabilizes chromatin-bound TET-OGT-PROSER1-DBHS (TOPD) complexes, which regulate DNA demethylation and developmental gene expression. Surprisingly, we find that PROSER1 also sequesters TET enzymes, preventing widespread demethylation and transposable element de-repression. Our findings identify PROSER1 as a key factor which both positively and negatively regulates DNA demethylation essential for mammalian neurodevelopment.

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KW - TET2

KW - TET3

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KW - TOPD

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PROSER1 Modulates DNA Demethylation through Dual Mechanisms to Prevent Syndromic Developmental Malformations

Abstract

Keywords

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Projects

Aberrant DNA Methylation and its Impact in Blood Cancer Development (Career Development Fellowship)

Research output

PROSER1 modulates DNA demethylation through dual mechanisms to prevent syndromic developmental malformations

Cite this