An ATM/TRIM37/NEMO axis counteracts genotoxicity by activating nuclear-to-cytoplasmic NF-{kappa}B signaling

Blocking genotoxic stress-induced NF-κB activation would substantially enhance the anti-cancer efficiency of genotoxic chemotherapy. Unlike the well-established classical NF-κB pathway, the genotoxic agents-induced 'nuclear-to-cytoplasmic' NF-κB pathway is initiated from the nucleus and transferred to the cytoplasm. However, the mechanism linking nuclear DNA damage signalling to cytoplasmic IKK activation remains unclear. Here we report that TRIM37, a novel E3 ligase, plays a vital role in genotoxic activation of NF-κB via monoubiquitination of NEMO at K309 in the nucleus, consequently resulting in nuclear export of NEMO and IKK/NF-κB activation. Clinicallly, TRIM37 levels correlated positively with levels of activated NF-κB and expression of Bcl-xl and XIAP in esophageal cancer specimens, which also associated positively with clinical stage and tumor-node-metastasis classification and associated inversely with overall and relapse-free survival in patients with esophageal cancer. Overexpression of TRIM37 conferred resistance to the DNA-damaging anticancer drug cisplatin in vitro and in vivo through activation of the NF-κB pathway. Genotoxic stress-activated ATM kinase directly interacted with and phosphorylated TRIM37 in the cytoplasm, which induced translocation of TRIM37 into the nucleus where it formed a complex with NEMO and TRAF6 via a TRAF6-binding motif (TBM). Importantly, blocking the ATM/TRIM37/NEMO axis via cell-penetrating TAT-TBM peptide abrogated genotoxic agent-induced NEMO monoubiquitination and NF-κB activity, resulting in hypersensitivity of cancer cells to genotoxic drugs. Collectively, our results unveil a pivotal role for TRIM37 in genotoxic stress and shed light on mechanisms of inducible chemotherapy resistance in cancer.

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