Structural optimization of non-nucleoside DNA methyltransferase inhibitor as anti-cancer agent

Bioorganic & Medicinal Chemistry Letters
Bo ZhongBin Su

Abstract

Inhibition of DNA methyltransferase 1 (DNMT1) can reverse the malignant behavior of cancer cells by restoring expression of aberrantly silenced genes that are required for differentiation, senescence, and apoptosis. Clinically used DNMT1 inhibitors decitabine and azacitidine inhibit their target by covalent trapping after incorporation into DNA as azacytidine analogs. These nucleoside compounds are prone to rapid enzymatic inactivation in blood, posing challenges to the development of purely epigenetic dosing schedules. Non-nucleoside compounds that suppress expression or function of DNMT1 may overcome this problem. Using a high-throughput PCR-based site specific chromatin condensation assay, we identified a compound that reactivated Cyclin-Dependent Kinase Inhibitor 2A (CDKN2A) in myeloma cells and suppressed expression of DNMT1 from a library of 5120 chemically diverse small molecules. Lead optimization was performed to generate 26 new analogs with lung cancer proliferation and DNMT1 expression as activity readout. Two of the new derivatives showed 2 fold improvement of growth inhibiting potency and also decreased DNMT1 protein levels in lung cancer cells.

References


❮ Previous
Next ❯

Citations

Aug 16, 2016·Ageing Research Reviews·Alexander M VaisermanAlexander K Koliada
Jun 24, 2017·Chemical Reviews·Laure KonnertEvelina Colacino
Jan 16, 2018·Biomedicine & Pharmacotherapy = Biomédecine & Pharmacothérapie·Mei YangGang Li

❮ Previous
Next ❯

Related Concepts

Related Feeds

Cancer Epigenetics & Metabolism (Keystone)

Epigenetic changes are present and dysregulated in many cancers, including DNA methylation, non-coding RNA segments and post-translational protein modifications. The epigenetic changes may or may not provide advantages for the cancer cells. This feed focuses on the relationship between cell metabolism, epigenetics and tumor differentiation.

Cancer Epigenetics and Senescence (Keystone)

Epigenetic changes are present and dysregulated in many cancers, including DNA methylation, non-coding RNA segments and post-translational protein modifications. The epigenetic changes may be involved in regulating senescence in cancer cells. This feed captures the latest research on cancer epigenetics and senescence.

Cancer Epigenetics and Chemical Tools (Keystone)

Epigenetic changes are present and dysregulated in many cancers, including DNA methylation, non-coding RNA segments and post-translational protein modifications. The epigenetic changes may or may not provide advantages for the cancer cells. Using novel chemical tools allows us to learn more about these epigenetic changes and how they impact the neoplastic process. Follow this feed to learn more about cancer epigenetics and chemical tools.

Apoptosis in Cancer

Apoptosis is an important mechanism in cancer. By evading apoptosis, tumors can continue to grow without regulation and metastasize systemically. Many therapies are evaluating the use of pro-apoptotic activation to eliminate cancer growth. Here is the latest research on apoptosis in cancer.

Apoptosis

Apoptosis is a specific process that leads to programmed cell death through the activation of an evolutionary conserved intracellular pathway leading to pathognomic cellular changes distinct from cellular necrosis

Related Papers

Reviews on Recent Clinical Trials
Yasuhiro Oki, Jean-Pierre J Issa
European Journal of Medicinal Chemistry
Beata PlittaJan Barciszewski
Nature Clinical Practice. Oncology
Stephen B Baylin
© 2022 Meta ULC. All rights reserved