The Snail transcription factor plays as a master regulator of epithelial mesenchymal transition (EMT), one of the steps of tumor metastasis. Snail enhances expressions of a lot of mesenchymal genes including the matrix degradation enzyme matrix metalloproteinases 9 (MMP9) and the EMT transcription factor zinc finger E-box binding homeobox 1 (ZEB1), however, the underlying mechanisms are not clarified. Herein, we investigated how Snail upregulated transcription of ZEB1 and MMP9 induced by the tumor promoter 12-O-tetradecanoyl-phorbol 13-acetate (TPA) in hepatoma cell HepG2. According to deletion mapping and site directed mutagenesis analysis, the TPA-responsive elements on both MMP9 and ZEB1 promoters locate on a putative EGR1 and SP1 overlapping region coupled with an upstream proposed Snail binding motif TCACA. Consistently, chromatin immunoprecipitation (ChIP) assay showed TPA triggered binding of Snail, EGR1 and SP1 on MMP9 and ZEB1 promoters. Double ChIP further indicated TPA induced association of Snail with EGR1 and SP1 on both promoters. Also, electrophoresis mobility shift assay revealed TPA enhanced binding of Snail with a MMP9 promoter fragment. According to shRNA techniques, Snail was essential for gene expression of both ZEB1 and MMP9. In conclusion, Snail transactivates genes involved in tumor progression via direct binding to a specific promoter region.
Snail is a multifunctional transcriptional factor that has been described as a repressor in many different contexts. It is also proposed as an activator in a few cases relevant to tumor progression and cell‐cycle arrest. This study investigated the detailed mechanisms by which Snail upregulates gene expression of the CDK inhibitor p15INK4b in HepG2 induced by the tumor promoter tetradecanoyl phorbol acetate (TPA). Using deletion mapping, the TPA‐responsive element on the p15INK4b promoter was located between 77 and 228 bp upstream of the transcriptional initiation site, within which the putative binding regions of early growth response gene 1 (EGR‐1) and stimulatory protein 1 (SP‐1) were found. Gene expression of EGR‐1, Snail and SP‐1 can be induced by TPA within 0.5–6 h. In addition, basal levels of SP‐1, but not of the other two transcriptional factors, were observed. Blockade of TPA‐induced gene expression of Snail, EGR‐1 or SP‐1 suppressed activation of the p15–pro228 reporter plasmid harboring the TPA‐responsive element. More detailed deletion mapping and site‐directed mutagenesis further concluded that the overlapping EGR‐1/SP‐1‐binding site was required for TPA‐induced p15–pro228 activation. In an EMSA, a DNA–protein complex was elevated by TPA, which can be blocked by antibodies against EGR‐1, SP‐1 or Snail at 6 h. Immunoprecipitation/western blotting demonstrated that TPA could trigger the association of EGR‐1 with Snail or SP‐1. Furthermore, a double chromatin immunoprecipitation assay verified that EGR‐1 could form a complex with Snail or SP‐1 on the TPA‐responsive element after treatment with TPA for 2–6 h. Finally, we demonstrated a novel Snail‐target region which could be bound by Snail and was also required for TPA‐induced p15–pro228 activation. In conclusion, Snail associates with EGR‐1 and SP‐1 to mediate TPA‐induced transcriptional upregulation of p15INK4b in HepG2. Structured digital abstract http://mint.bio.uniroma2.it/mint/search/interaction.do?interactionAc=MINT-7384899: Snail (uniprotkb:http://www.uniprot.org/uniprot/O95863?format=text&ascii) physically interacts (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0915) with EGR‐1 (uniprotkb:http://www.uniprot.org/uniprot/P18146?format=text&ascii) by anti bait coimmunoprecipitation (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0006) http://mint.bio.uniroma2.it/mint/search/interaction.do?interactionAc=MINT-7384908: SP‐1 (uniprotkb:http://www.uniprot.org/uniprot/P08047?format=text&ascii) physically interacts (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0915) with EGR‐1 (uniprotkb:http://www.uniprot.org/uniprot/P18146?format=text&ascii) by anti bait coimmunoprecipitation (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0006)
One of the signaling components involved in hepatocellular carcinoma (HCC) progression is the focal adhesion adaptor paxillin. Hydrogen peroxide inducible clone-5 (Hic-5), one of the paralogs of paxillin, exhibits many biological functions distinct from paxillin, but may cooperate with paxillin to trigger tumor progression. Screening of Hic-5 in 145 surgical HCCs demonstrated overexpression of Hic-5 correlated well with intra- and extra-hepatic metastasis. Hic-5 highly expressed in the patient derived HCCs with high motility such as HCC329 and HCC353 but not in the HCCs with low motility such as HCC340. Blockade of Hic-5 expression prevented constitutive migration of HCC329 and HCC353 and HGF-induced cell migration of HCC340. HCC329Hic-5(−), HCC353Hic-5(−), HCC372Hic-5(−), the HCCs stably depleted of Hic-5, exhibited reduced motility compared with each HCC expressing Scramble shRNA. Moreover, intra/extrahepatic metastasis of HCC329Hic-5(−) in SCID mice greatly decreased compared with HCC329Scramble. On the other hand, ectopic Hic-5 expression in HCC340 promoted its progression. Constitutive and HGF-induced Hic-5 expression in HCCs were suppressed by the reactive oxygen species (ROS) scavengers catalase and dithiotheritol and c-Jun N-terminal kinase (JNK) inhibitor SP600125. On the contrary, depletion of Hic-5 blocked constitutive and HGF-induced ROS generation and JNK phosphorylation in HCCs. Also, ectopic expression of Hic-5 enhanced ROS generation and JNK phosphorylation. These highlighted that Hic-5 plays a central role in the positive feedback ROS-JNK signal cascade. Finally, the Chinese herbal derived anti-HCC peptide LZ-8 suppressed constitutive Hic-5 expression and JNK phosphorylation. In conclusion, Hic-5 mediates ROS-JNK signaling and may serve as a therapeutic target for prevention of HCC progression.
Snail was recently highlighted as a critical transcriptional factor for tumor metastasis. Real time RT/PCR and Western blot analysis demonstrated that Snail mRNA and protein, respectively, were induced by 12-O-tetradecanoylphorbol-13-acetate (TPA) in hepatoma cell HepG2. Blockade of gene expression of Snail by antisense oligodeoxynucleotide and/or siRNA technique can prevent not only the TPA-triggered EMT/cell migration and growth inhibition of HepG2 but also TPA-induced down-regulation of E-cadherin and up-regulation of p15(INK4b). Moreover, the TPA-triggered promoter activation of p15(INK4b) was also prevented. On the other hand, two of the HepG2 clone over-expressing Snail, namely S7 and S15, had a scattered fibroblastic morphology and acquired higher motility than parental HepG2. Also, the proportion of G0/G1 phase of S7 and S15 was higher than that of parental HepG2, consistent with the longer doubling time of both cells. Semiquantitative RT/PCR analysis demonstrated a greatly elevated gene expression of Snail accompanied with decreased E-cadherin and increased p15(INK4b) in both Snail-overexpressing cells. On the transcriptional level, p15(INK4b) promoter activity was 2.6-fold higher in S7 as compared with parental HepG2. Furthermore, electrophoretic mobility of DNA fragments encompassing proximal p15(INK4b) promoter can be retarded by incubation of nuclear extract of S7. Our results demonstrated that Snail play diverse trans-regulatory roles in HepG2. Notably, we suggested that Snail may upregulate p15(INK4b) gene expression by directly activating its promoter.
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