The effect of oncoprotein v-erbA on thyroid hormone-regulated genes in hepatocytes and their potential role in hepatocellular carcinoma.

Mutant forms of thyroid hormone receptor (TR) with dominant negative activity are frequently found in human hepatocellular carcinoma (HCC). Interestingly, the v-erbA oncogene, known to exert a dominant-negative effect on the expression of thyroid hormone (T3)-responsive genes, led to the development of HCC in a transgenic mouse model. Thus it is possible that the oncogenic activity of v-erbA in hepatocytes may be mediated by its dominant negative activity on T3-responsive genes. Microarray analysis was used to identify genes differentially expressed in murine hepatocytes in culture (AML12 cells) stably transfected with v-erbA and exposed to T3. The Affymetrix GeneChip Mouse Genome 430 2.0 array consisted of over 39,000 transcripts representing well-known genes. We have identified twenty T3-responsive genes that are negatively regulated by v-erbA at 3 h, and eighteen genes at 24 h, such as follistatin, activin ßC, thrombomodulin, Six1, Rasgrp3 and Ndrg2, as well as genes that are regulated by v-erbA only, such as angiopoietin 1 and Igfr2. We have identified T3 responsive genes that are dysregulated by v-erbA. These genes are known to be involved in carcinogenesis. Our studies may provide insight into the potential role of mutant forms of TR in the pathogenesis of HCC.

Retinoic acid regulates several genes in bile acid and lipid metabolism via upregulation of small heterodimer partner in hepatocytes.

Retinoic acid (RA) affects multiple aspects of development, embryogenesis and cell differentiation processes. The liver is a major organ that stores RA suggesting that retinoids play an important role in the function of hepatocytes. In our previous studies, we have demonstrated the involvement of small heterodimer partner (SHP) in RA-induced signaling in a non-transformed hepatic cell line AML 12. In the present study, we have identified several critical genes in lipid homeostasis (Apoa1, Apoa2 and ApoF) that are repressed by RA-treatment in a SHP dependent manner, in vitro and also in vivo with the use of the SHP null mice. In a similar manner, RA also represses several critical genes involved in bile acid metabolism (Cyp7a1, Cyp8b1, Mdr2, Bsep, Baat and Ntcp) via upregulation of SHP. Collectively our data suggest that SHP plays a major role in RA-induced potential changes in pathophysiology of metabolic disorders in the liver.

miR-337-3p and its targets STAT3 and RAP1A modulate taxane sensitivity in non-small cell lung cancers.

NSCLC (non-small cell lung cancer) often exhibits resistance to paclitaxel treatment. Identifying the elements regulating paclitaxel response will advance efforts to overcome such resistance in NSCLC therapy. Using in vitro approaches, we demonstrated that over-expression of the microRNA miR-337-3p sensitizes NCI-H1155 cells to paclitaxel, and that miR-337-3p mimic has a general effect on paclitaxel response in NSCLC cell lines, which may provide a novel adjuvant strategy to paclitaxel in the treatment of lung cancer. By combining in vitro and in silico approaches, we identified STAT3 and RAP1A as direct targets that mediate the effect of miR-337-3p on paclitaxel sensitivity. Further investigation showed that miR-337-3p mimic also sensitizes cells to docetaxel, another member of the taxane family, and that STAT3 levels are significantly correlated with taxane resistance in lung cancer cell lines, suggesting that endogenous STAT3 expression is a determinant of intrinsic taxane resistance in lung cancer. The identification of a miR-337-3p as a modulator of cellular response to taxanes, and STAT3 and RAP1A as regulatory targets which mediate that response, defines a novel regulatory pathway modulating paclitaxel sensitivity in lung cancer cells, which may provide novel adjuvant strategies along with paclitaxel in the treatment of lung cancer and may also provide biomarkers for predicting paclitaxel response in NSCLC.

miR-93, miR-98, and miR-197 regulate expression of tumor suppressor gene FUS1.

FUS1 is a tumor suppressor gene located on human chromosome 3p21, and expression of Fus1 protein is highly regulated at various levels, leading to lost or greatly diminished tumor suppressor function in many lung cancers. Here we show that selected microRNAs (miRNA) interact with the 3'-untranslated region (3'UTR) of FUS1, leading to down-regulation of protein expression. Using computational methods, we first predicted that FUS1 is a target of three miRNAs, miR-93, miR-98, and miR-197, and then showed that exogenous overexpression of these miRNAs inhibited Fus1 protein expression. We then confirmed that the three miRNAs target the 3'UTR region of the FUS1 transcript and that individual deletion of the three miRNA target sites in the FUS1 3'UTR restores the expression level of Fus1 protein. We further found that miR-93 and miR-98 are expressed at higher levels in small-cell lung cancer cell lines (SCLC) than in non-small-cell lung cancer cell lines (NSCLC) and immortalized human bronchial epithelial cells (HBEC), and that miR-197 is expressed at higher levels in both SCLCs and NSCLCs than in HBECs. Finally, we found that elevated miR-93 and miR-197 expression is correlated with reduced Fus1 expression in NSCLC tumor specimens. These results suggest that the three miRNAs are negative regulators of Fus1 expression in lung cancers.