Department of Pharmacy

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S-nitrosylation of EZH2 alters PRC2 assembly, methyltransferase activity, and EZH2 stability to maintain endothelial homeostasis
(Springer Nature, 2025-04) Sundriyal, Sandeep; Chowdhury, Shibasish; Majumder, Syamantak
Nitric oxide (NO), a versatile bio-active molecule modulates cellular functions through diverse mechanisms including S-nitrosylation of proteins. Herein, we report S-nitrosylation of selected cysteine residues of EZH2 in endothelial cells, which interplays with its stability and functions. We detect a significant reduction in H3K27me3 upon S-nitrosylation of EZH2 as contributed by the early dissociation of SUZ12 from the PRC2. Moreover, S-nitrosylation of EZH2 causes its cytosolic translocation, ubiquitination, and degradation. Further analysis reveal S-nitrosylation of cysteine 329 induces EZH2 instability, whereas S-nitrosylation of cysteine 700 abrogates its catalytic activity. We further show that S-nitrosylation-dependent regulation of EZH2 maintains endothelial homeostasis in both physiological and pathological settings. Molecular dynamics simulation reveals the inability of SUZ12 to efficiently bind to the SAL domain of EZH2 upon S-nitrosylation. Taken together, our study reports S-nitrosylation-dependent regulation of EZH2 and its associated PRC2 complex, thereby influencing the epigenetics of endothelial homeostasis.
S-nitrosylation of EZH2 at C329 and C700 interplay with PRC2 complex assembly, methyltransferase activity, and EZH2 stability to regulate endothelial functions
(2024) Sundriyal, Sandeep; Chowdhury, Shibasish; Majumder, Syamantak
Nitric oxide (NO), a versatile bio-active molecule modulates cellular function through diverse mechanisms including S-nitrosylation of proteins. However, the role of this post-translational modification in regulating epigenetic pathways was very limitedly explored. Herein, we report that NO causes S-nitrosylation of selected cysteine residues of EZH2 in endothelial cells (EC) resulting in SUZ12 dissociation from EZH2 bound PRC2 complex, reduced methyltransferase activity, and diminished nuclear localization eventually hampering its stability. We detected a significant reduction in H3K27me3 upon exposure to NO as contributed by the early dissociation of SUZ12 from the PRC2 complex. Longer exposure to NO donors caused EZH2 cytosolic translocation, its ubiquitination, and further degradation primarily through the autophagosome-lysosome pathway. Through in silico S-nitrosylation prediction analysis and site-directed mutagenesis assay, we identified three cysteine residues namely at locations 260, 329, and 700 in EZH2 and further determined that S-nitrosylation of cysteine 329 induced EZH2 instability while S-nitrosylation of cysteine 700 abrogated EZH2’s catalytic activity. A double mutant of EZH2 containing mutations at Cysteine 329 and 700 remained undeterred to NO exposure. Furthermore, reinforcing H3K27me3 in NO exposed EC through the use of an inhibitor of H3K27me3 demethylase, we confirmed a significant contribution of the EZH2-H3K27me3 axis in defining NO-mediated regulation of endothelial gene expression and migration. Molecular dynamics simulation study revealed SUZ12’s inability in efficiently binding to the SAL domain of EZH2 upon S-nitrosylation of C329 and C700. Taken together, our study for the first-time reports that S-nitrosylation dependent regulation of EZH2 and its associated PRC2 complex influences endothelial homeostasis.