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miR-196b-5p–mediated downregulation of TSPAN12 and GATA6 promotes tumor progression in non-small cell lung cancer

Guang Liang, Wei Meng, Xiangjie Huang, Wangyu Zhu, Changtian Yin, Canwei Wang, Matteo Fassan, Yun Yu, Masahisa Kudo, Sisi Xiao, Chengguang Zhao, Peng Zou, Yumin Wang, Xiaokun Li, Carlo M. Croce, Ri Cui

2020Proceedings of the National Academy of Sciences182 citationsDOIOpen Access PDF

Abstract

Lung cancer is the leading cause of cancer-related deaths worldwide and non-small cell lung cancer (NSCLC) accounts for over 80% of lung cancer cases. The RNA binding protein, QKI, belongs to the STAR family and plays tumor-suppressive functions in NSCLC. QKI-5 is a major isoform of QKIs and is predominantly expressed in NSCLC. However, the underlying mechanisms of QKI-5 in NSCLC progression remain unclear. We found that QKI-5 regulated microRNA (miRNA), miR-196b-5p, and its expression was significantly up-regulated in NSCLC tissues. Up-regulated miR-196b-5p promotes lung cancer cell migration, proliferation, and cell cycle through directly targeting the tumor suppressors, GATA6 and TSPAN12. Both GATA6 and TSPAN12 expressions were down-regulated in NSCLC patient tissue samples and were negatively correlated with miR-196b-5p expression. Mouse xenograft models demonstrated that miR-196b-5p functions as a potent onco-miRNA, whereas TSPAN12 functions as a tumor suppressor in NSCLC in vivo. QKI-5 bound to miR-196b-5p and influenced its stability, resulting in up-regulated miR-196b-5p expression in NSCLC. Further analysis showed that hypomethylation in the promoter region enhanced miR-196b-5p expression in NSCLC. Our findings indicate that QKI-5 may exhibit novel anticancer mechanisms by regulating miRNA in NSCLC, and targeting the QKI5∼miR-196b-5p∼GATA6/TSPAN12 pathway may enable effectively treating some NSCLCs.

Topics & Concepts

microRNABiologyLung cancerCancer researchGATA6SuppressorDownregulation and upregulationCancerTumor progressionTranscription factorPathologyMedicineGeneGeneticsCancer-related molecular mechanisms researchMicroRNA in disease regulationRNA modifications and cancer