Long non-coding RNA HOTTIP is frequently up-regulated in hepatocellular carcinoma and is targeted by tumour suppressive miR-125b.

BACKGROUND & AIMS: Hepatocellular carcinoma (HCC) is one of the most common human cancers. Recently, emerging evidence has suggested the role of long non-coding RNAs (lncRNAs) in human carcinogenesis. In this study, we aimed to investigate the expression and functional implications of lncRNAs in human HCC. METHODS: Eighty-eight well-annotated lncRNAs were profiled in primary HCC by quantitative RT-PCR. Functional relevance of lncRNAs was elucidated in HCC cell lines and nude mice models. The regulatory relationship between miRNA and lncRNA was predicted in silico and further validated by luciferase reporter assay and expression analysis. RESULTS: In our profiling study, HOTTIP was identified as the most significantly up-regulated lncRNA in human HCCs, even in early stage of HCC formation. Functionally, knock-down of HOTTIP attenuated HCC cell proliferation in vitro and markedly abrogated tumourigenicity in vivo. In addition, knock-down of HOTTIP also inhibited migratory ability of HCC cells and significantly abrogated lung metastasis in orthotopic implantation model in nude mice. HOTTIP is an antisense lncRNA mapped to the distal end of the HOXA gene cluster. Knock-down of HOTTIP significantly suppressed the expression of a number of HOXA genes. Furthermore, we identified miR-125b as a post-transcriptional regulator of HOTTIP. Ectopic expression of miR-125b reduced HOTTIP-coupled luciferase activity and suppressed the endogenous level of HOTTIP. Moreover, in human HCCs, HOTTIP expression negatively correlated with that of miR-125b. CONCLUSIONS: HOTTIP is a novel oncogenic lncRNA, which negatively regulated by miR-125b. Overexpression of HOTTIP contributes to hepatocarcinogenesis by regulating the expression of its neighbouring protein-coding genes.

Monitor Tumor pHe and Response Longitudinally during Treatment Using CEST MRI-Detectable Alginate Microbeads.

Imaging pHe of the tumor microenvironment has paramount importance for characterizing aggressive, invasive tumors, as well as therapeutic responses. Here, a robust approach to image pH changes in the tumor microenvironment longitudinally and during sodium bicarbonate treatment was reported. The pH-sensing microbeads were designed and prepared based on materials approved for clinical use, i.e., alginate microbead-containing computed tomography (CT) contrast-agent (iopamidol)-loaded liposomes (Iop-lipobeads). This Iop-lipobead prepared using a customized microfluidic device generated a CEST contrast of 10.6% at 4.2 ppm at pH 7.0, which was stable for 20 days in vitro. The CEST contrast decreased by 11.8% when the pH decreased from 7.0 to 6.5 in vitro. Optimized Iop-lipobeads next to tumors showed a significant increase of 19.7 ± 6.1% (p < 0.01) in CEST contrast at 4.2 ppm during the first 3 days of treatment and decreased to 15.2 ± 4.8% when treatment stopped. Notably, percentage changes in Iop-lipobeads were higher than that of amide CEST (11.7% and 9.1%) in tumors during and after treatment. These findings demonstrated that the Iop-lipobead could provide an independent and sensitive assessment of the pHe changes for a noninvasive and longitudinal monitoring of the treatment effects using multiple CEST contrast.