Invadopodium formation is a crucial early event of invasion and metastasis of hepatocellular carcinoma (HCC). However, the molecular mechanisms underlying regulation of invadopodia remain elusive. This study aimed to investigate the potential role of discs large homolog 5 (Dlg5) in invadopodium formation and function in HCC. We found that Dlg5 expression was significantly lower in human HCC tissues and cell lines than adjacent nontumor tissues and liver cells. Lower Dlg5 expression was associated with advanced stages of HCC, and poor overall and disease-free survival of HCC patients. Dlg5-silencing promoted epithelial-mesenchymal transition, invadopodium formation, gelatin degradation function, and invadopodium-associated invasion of HepG2 cells. In contrast, Dlg5 overexpression inhibited epithelial-mesenchymal transition, functional invadopodium formation, and invasion of SK-Hep1 cells. Both Girdin and Tks5, but not the Tks5 nonphosphorylatable mutant, were responsible for the enhanced invadopodium formation and invasion of Dlg5-silenced HepG2 cells. Furthermore, Dlg5 interacted with Girdin and interfered with the interaction of Girdin and Tks5. Dlg5 silencing promoted Girdin and Tks5 phosphorylation, which was abrogated by Girdin silencing and rescued by inducing shRNA-resistant Girdin expression. Moreover, Dlg5 overexpression significantly inhibited HCC intrahepatic and lung metastasis in vivo. Taken together, our data indicate that Dlg5 acts as a novel regulator of invadopodium-associated invasion via Girdin and by interfering with the interaction between Girdin and Tks5, which might be important for Tks5 phosphorylation in HCC cells. Conceivably, Dlg5 may act as a new biomarker for prognosis of HCC patients.
Traumatic brain injury (TBI) is an insult to the brain that results in impairments of cognitive and physical functioning. Both of human research and animal studies demonstrate that spontaneous exercise can facilitate neuronal plasticity and improve cognitive function in normal or TBI rodent models. However, the possible mechanisms underlying are still not well known. We postulated that spontaneous running wheel (RW) altered microRNA (miRNA) expressions in hippocampus of mice following TBI, which might be associated with the improvement in cognitive functions. In the present study, acquisition of spatial learning and memory retention was assessed by using the Morris water maze (MWM) test on days 15 post RW exercise. Then, microarray analyses in miRNA files were employed, and the expressional changes of miRNAs in the hippocampus of mice were detected. The results showed that spontaneous RW exercise (i) recovered the hippocampus-related cognitive deficits induced by TBI, (ii) altered hippocampal expressions of miRNAs in both of sham and TBI mice, and (iii) miR-21 or miR-34a was associated with the recovery process. The present results indicated that an epigenetic mechanism might be involved in voluntary exercise-induced cognitive improvement of mice that suffered from TBI.
Taraxasterol inhibits growth and induces apoptosis in human liver cancer cells. Taraxasterol enhances Hint1 expression by promoting demethylation in Hint1 promoter. Taraxasterol increases Hint1 levels to regulate Bax, Bcl2, and cyclinD1 expression. The effects of Taraxasterol are abrogated by Hint1 silencing in liver cancer cells. Taraxasterol inhibits the growth of subcutaneously implanted liver cancers in mice.
Recent evidences revealed that the alteration of microRNAs (miRNAs) might be associated with neuroplasticity induced by voluntary running wheel (RW) exercise in mice suffered from traumatic brain injury (TBI). In the present study, we explored the possible role of miR21 involved in the cognitive improvement following voluntary RW in TBI mice. Firstly, in situ hybridization and quantitative real-time PCR (qRT-PCR) were employed to determine the hippocampal expression and location of miR21 in TBI mice with or without spontaneous RW. Either miR21-mimics/plenti-miR21 or miR21-agomir/miR21-sponge was employed to regulate the miR21 expression in vivo and in vitro. Acquisition of spatial learning and memory retention was assessed by Morris Water Maze (MWM) test. Golgi stain was also performed to evaluate the alteration of hippocampal dendrite. Our finding confirmed that the elevated miR21 level in hippocampal post-TBI was significantly reduced by spontaneous RW. Overexpression of miR21 in TBI mice with spontaneous RW induced deteriorations in spatial learning and memory retention by significant decreases in the somata size and branch points of the hippocampus neurons. In vitro transduction with miR21 also reduced the neurite extension and the area of cultured hippocampal neuron. However, miR21 down-regulation reversed these effects. The present data strongly suggest that miR21 is an important molecule that has been involved in neuroprotection induced by voluntary RW exercise post-TBI.
MicroRNAs (miRNAs) may be important mediators of the profound molecular and cellular
changes that occur after traumatic brain injury (TBI). However, the changes and
possible roles of miRNAs induced by voluntary exercise prior to TBI are still not
known. In this report, the microarray method was used to demonstrate alterations in
miRNA expression levels in the cerebral cortex of TBI mice that were pretrained on a
running wheel (RW). Voluntary RW exercise prior to TBI: i) significantly decreased
the mortality rate and improved the recovery of the righting reflex in TBI mice, and
ii) differentially changed the levels of several miRNAs, upregulating some and
downregulating others. Furthermore, we revealed global upregulation of miR-21,
miR-92a, and miR-874 and downregulation of miR-138, let-7c, and miR-124 expression
among the sham-non-runner, TBI-non-runner, and TBI-runner groups. Quantitative
reverse transcription polymerase chain reaction data (RT-qPCR) indicated good
consistency with the microarray results. Our microarray-based analysis of miRNA
expression in mice cerebral cortex after TBI revealed that some miRNAs such as
miR-21, miR-92a, miR-874, miR-138, let-7c, and miR-124 could be involved in the
prevention and protection afforded by voluntary exercise in a TBI model.
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