Nucleoporin-93 overexpression overcomes multiple nucleocytoplsamic trafficking bottlenecks to permit robust metastasis

Abstract To identify genetic events driving breast cancer progression, we performed multi-omics integrated analyses that identified overexpression of nucleoporin-93, a nuclear pore component. Here we show that NUP93 overexpression enhances trans-endothelial migration and matrix invasion in vitro, along with metastasis in animal models. These findings were supported by analyses of naturally occurring activating NUP93 mutations and inactivating nephrotic syndrome mutations. Mechanistically, NUP93 activation enhanced the ultimate nuclear transport step shared by multiple signaling pathways, including TGF-beta/SMAD, EGF/ERK and TNF/NF-κB. Likewise, NUP93 can boost nuclear transport of beta-catenin, as well as elevate expression and inhibit degradation of this co-activator. The emerging addiction to nuclear transport exposes vulnerabilities of tumors overexpressing NUP93. Congruently, we report that myristoylated peptides corresponding to the nuclear translocation signals of SMAD and ERK inhibited growth and metastasis. Our study illuminates a previously unappreciated hallmark of advanced tumors, which derive benefit from unblocking a set of nucleocytoplasmic bottlenecks.