Author: Jr, Ivan R Corrêa ; Dai, Nan ; Chen, Qin ; Zhang, Xing ; Hardikar, Swanand ; Cheng, Xiaodong ; Yu, Meigen ; Chen, Taiping ; Kondo, Kimie ; Estecio, Marcos R

Abstract:

DNA methylation alterations, including hypermethylation and silencing of tumor suppressor genes, contribute to cancer formation and progression. The FDA-approved nucleoside analogs azacytidine and decitabine are effective demethylating agents for hematologic malignancies but their general use has been limited by their toxicity and ineffectiveness against solid tumors. GSK-3484862, a dicyanopyridine-containing, DNMT1-selective inhibitor and degrader, offers a promising lead for developing novel demethylating therapeutics. Here, we demonstrate that GSK-3484862 treatment upregulates DNMT3B expression in lung cancer cell lines (A549 and NCI-H1299). Disrupting DNMT3B in NCI-H1299 sensitizes these cells to GSK-3484862, enhancing its inhibitory effects on cell viability and growth. GSK-3484862 treatment induces demethylation at DNMT3B regulatory elements including a candidate enhancer located ∼10 kb upstream of the DNMT3B transcription start site, as well as at the promoter of TERT (telomerase reverse transcriptase), a potential activator of DNMT3B expression. These demethylation events correlate with upregulation of DNMT3B expression. These findings suggest that combining inhibitors targeting DNMT1, the maintenance methyltransferase, with those targeting DNMT3A/3B, the de novo methyltransferases, or using pan-DNMT inhibitors, could enhance anticancer efficacy and reduce resistance.

13 Feb 2025·JOURNAL OF MEDICINAL CHEMISTRY

Structure–Activity Relationship Studies of DNA Methyltransferase 1 Monovalent Degraders

Article

Author: Cheng, Xiaodong ; Xiong, Yan ; Kaniskan, H. Ümit ; Jin, Jian ; Han, Yulin ; Rothbart, Scott ; Chen, Qin ; Xie, Ling ; Hrit, Joel ; Zhong, Yue ; Zhou, Jujun ; Qian, Chao ; Chen, Xian ; Lee, Youngeun

DNA methyltransferase 1 (DNMT1), which catalyzes maintenance methylation of hemimethylated DNA during DNA replication, is overexpressed in cancer. Recently, the first-in-class DNMT1-selective noncovalent small-molecule inhibitors, GSK3484862 and GSK3685032, were discovered. These inhibitors were also reported to degrade DNMT1. However, structure-activity relationship (SAR) studies of these monovalent DNMT1 degraders are lacking. Here, we report our SAR studies of this scaffold on degrading DNMT1, which led to the discovery of multiple lead degraders, including compound 4 (MS9024). Compound 4 potently and selectively degraded DNMT1 in multiple cancer cell lines in a concentration-, time-, and proteasome-dependent manner without altering DNMT1 transcription. Further mechanism-of-action studies suggest that the DNMT1 degradation induced by 4 was not mediated by lysosome or cullin RING E3 ligases but could potentially be mediated by HECT E3 ligases and/or UHRF1. Collectively, these studies pave the way for further developing DNMT1 monovalent degraders as potential therapeutics and useful chemical tools.

01 Sep 2024·Journal of Oral Biosciences

Exploring the role of DNMT1 in dental papilla cell fate specification during mouse tooth germ development through integrated single-cell transcriptomics and bulk RNA sequencing

Article

Author: Chung, Ung-Il ; Hojo, Hironori ; Tanaka, Junichi ; Mishima, Kenji ; Suzuki, Yutaka ; Seki, Masahide ; Eldeeb, Dahlia ; Ohba, Shinsuke ; Okada, Hiroyuki

OBJECTIVES:

This study aimed to investigate the regulatory mechanisms governing dental mesenchymal cell commitment during tooth development, focusing on odontoblast differentiation and the role of epigenetic regulation in this process.

METHODS:

We performed single-cell RNA sequencing (scRNA-seq) of dental cells from embryonic day 14.5 (E14.5) mice to understand the heterogeneity of developing tooth germ cells. Computational analyses including gene regulatory network (GRN) assessment were conducted. We validated our findings using immunohistochemistry (IHC) and in vitro loss-of-function analyses using the DNA methyltransferase 1 (DNMT1) inhibitor Gsk-3484862 in primary dental mesenchymal cells (DMCs) isolated from E14.5 mouse tooth germs. Bulk RNA-seq of Gsk-3484862-treated DMCs was performed to identify potential downstream targets of DNMT1.

RESULTS:

scRNA-seq analysis revealed diverse cell populations within the tooth germs, including epithelial, mesenchymal, immune, and muscle cells. Using single-cell regulatory network inference and clustering (SCENIC), we identified Dnmt1 as a key regulator of early odontoblast development. IHC analysis showed the ubiquitous expression of DNMT1 in the dental papilla and epithelium. Bulk RNA-seq of cultured DMCs showed that Gsk-3484862 treatment upregulated odontoblast-related genes, whereas genes associated with cell division and the cell cycle were downregulated. Integrated analysis of bulk RNA-seq data with scRNA-seq SCENIC profiles was used to identify the potential Dnmt1 target genes.

CONCLUSIONS:

Dnmt1 may negatively affect odontoblast commitment and differentiation during tooth development. These findings contribute to a better understanding of the molecular mechanisms underlying tooth development and future development of hard-tissue regenerative therapies.

100 Deals associated with GSK-3484862

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Indication	Highest Phase	Country/Location	Organization	Date
Neoplasms	Preclinical	United States	GSK Plc	-
Neoplasms	Preclinical	United Kingdom	Manchester Cancer Research Centre	-

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