Targeted DNA Methylation Editing Using an All-in-One System Establishes Paradoxical Activation of EBF3

Targeted DNA Methylation Editing Using an All-in-One System Establishes Paradoxical Activation of EBF3

Cutaneous melanoma is rapidly on the rise globally, surpassing the growth rate of other cancers, with metastasis being the primary cause of death in melanoma patients. Consequently, understanding the mechanisms behind this metastatic process and exploring innovative treatments is of paramount import...

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Bibliographic Details
Published in:Cancers Vol. 16; no. 5; p. 898
Main Authors: Banerjee, Rakesh, Ajithkumar, Priyadarshana, Keestra, Nicholas, Smith, Jim, Gimenez, Gregory, Rodger, Euan J, Eccles, Michael R, Antony, Jisha, Weeks, Robert J, Chatterjee, Aniruddha
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 23-02-2024
MDPI
Subjects:
Bisulfite
Cancer
Cell culture
Cloning
CRISPR
Demethylation
DNA methylation
Editing
Epigenetics
Gene expression
Gene silencing
Genomes
Malignancy
Melanoma
Metastases
Metastasis
Penicillin
Plasmids
Signal transduction
Transcription activation
Tumors
United States > US
RNA-sequencing
DNA methylation
epigenomic editing
melanoma
paradoxical role
All-in-one CRISPR system
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Summary:Cutaneous melanoma is rapidly on the rise globally, surpassing the growth rate of other cancers, with metastasis being the primary cause of death in melanoma patients. Consequently, understanding the mechanisms behind this metastatic process and exploring innovative treatments is of paramount importance. Recent research has shown promise in unravelling the role of epigenetic factors in melanoma progression to metastasis. While DNA hypermethylation at gene promoters typically suppresses gene expression, we have contributed to establishing the newly understood mechanism of paradoxical activation of genes via DNA methylation, where high methylation coincides with increased gene activity. This mechanism challenges the conventional paradigm that promoter methylation solely silences genes, suggesting that, for specific genes, it might actually activate them. Traditionally, altering DNA methylation in vitro has involved using global demethylating agents, which is insufficient for studying the mechanism and testing the direct consequence of gene methylation changes. To investigate promoter hypermethylation and its association with gene activation, we employed a novel approach utilising a CRISPR-SunTag All-in-one system. Here, we focused on editing the DNA methylation of a specific gene promoter segment ( ) in melanoma cells using the All-in-one system. Using bisulfite sequencing and qPCR with RNA-Seq, we successfully demonstrated highly effective methylation and demethylation of the promoter, with subsequent gene expression changes, to establish and validate the paradoxical role of DNA methylation. Further, our study provides novel insights into the function of the gene, which remains largely unknown. Overall, this study challenges the conventional view of methylation as solely a gene-silencing mechanism and demonstrates a potential function of in IFN pathway signalling, potentially uncovering new insights into epigenetic drivers of malignancy and metastasis.
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ISSN:2072-6694
2072-6694
DOI:10.3390/cancers16050898