Untargeted Metabolomics Showed Accumulation of One-Carbon Metabolites to Facilitate DNA Methylation During Extracellular Matrix Detachment of Cancer Cells

Overview

Journal Metabolites

Publisher MDPI

Date 2022 Mar 24

PMID 35323710

Authors

Suza Mohammad Nur

Mohammed Razeeth Shait Mohammed

Mazin A Zamzami

Hani Choudhry

Aamir Ahmad

Bushra Ateeq

Irfan A Rather

Mohammad Imran Khan

Affiliations

Soon will be listed here.

Abstract

Tumor cells detached from the extracellular matrix (ECM) undergo anoikis resistance and metabolic reprogramming to facilitate cancer cell survival and promote metastasis. During ECM detachment, cancer cells utilize genomic methylation to regulate transcriptional events. One-carbon (1C) metabolism is a well-known contributor of SAM, a global substrate for methylation reactions, especially DNA methylation. DNA methylation-mediated repression of NK cell ligands MICA and MICB during ECM detachment has been overlooked. In the current work, we quantitated the impact of ECM detachment on one-carbon metabolites, expression of 1C regulatory pathway genes, and total methylation levels. Our results showed that ECM detachment promotes the accumulation of one-carbon metabolites and induces regulatory pathway genes and total DNA methylation. Furthermore, we measured the expression of well-known targets of DNA methylation in NK cell ligands in cancer cells, namely, MICA/B, during ECM detachment and observed low expression compared to ECM-attached cancer cells. Finally, we treated the ECM-detached cancer cells with vitamin C (a global methylation inhibitor) and observed a reduction in the promoter methylation of NK cell ligands, resulting in MICA/B re-expression. Treatment with vitamin C was also found to reduce global DNA methylation levels in ECM-detached cancer cells.

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