Critical determinants of estrogen receptor -mediated agonist activity

Exogenous ligands that bind to the estrogen receptor (ER) exhibit unique pharmacologies distinct from that observed with the endogenous hormone, 17β-estradiol (ED. Differential activity among ER ligands has been observed at the level of receptor binding, promoter interaction and transcriptional activation. Furthermore, xenoestrogens can display tissue-specific agonist activity on the cellular level, functioning as an agonist in one tissue and as an antagonist in another. That the same ligand, functioning through the same receptor, can produce differing agonist responses on the cellular level indicates that there are tissue-specific determinants of agonist activity. In these studies critical molecular determinants of agonist activity were characterized for several cell types. In the normal and neoplastic myometrium a proliferative response was dependent upon activation of AF2 of the ER, functioning as a determinant of agonism in this cell type. Progesterone receptor (PR) ligands transdominantly suppressed ER-mediated transcription and proliferation in uterine leiomyoma cells, indicating that ER/PR cross-talk can modulate agonist activity in a myometrial cell background. In the breast, the agonist response to ER ligands was investigated by employing a functional genomics approach to generate gene expression profiles. Treatment of breast cancer cells with the selective estrogen receptor modulator tamoxifen largely recapitulated the expression profile induced by treatment with the agonist E2, despite the well-characterized antiproliferative effects produced by tamoxifen in this cell type. While the expression of many genes involved in regulating cell cycle progression, including fos, myc, cdc25a, stk15 and cyclin A, were induced by both E2 and tamoxifen in breast cells, treatment with the agonist E2 specifically induced the expression of cyclin D1, fra-1 , and uracil DNA glycosylase. These results suggest that the inability of tamoxifen to transactivate expression of only a few key genes, functioning as cellular gatekeepers, prevent tamoxifen-treated breast cells from entering the cell cycle. Thus, the expression of these agonist-specific marker genes is a potential determinant of agonist activity at the cellular level in the breast. Collectively, studies in the breast and uterine myometrium have identified several mechanisms whereby ER ligands modulate ER-mediated signaling and provide insights into the biology of tissue-specific agonist activity in hormone-responsive tissues. ^

Roles of p38 mitogen-activated protein kinase pathway in the regulation of SOX9 activity and chondrogenesis

Sox9 is a master transcription factor in chondrocyte differentiation. Several lines of evidence suggest that the p38 mitogen-activated protein kinase (MAPK) pathway is involved in chondrocyte differentiation. In the present study, we examined the roles of p38 in the regulation of SOX9 activity and chondrogenesis. ^ COS7 cells were transfected with a SOX9 expression vector and 4x48-p89, a luciferase construction harboring four tandem copies of a SOX9-dependent 48-bp enhancer in Col2a1. Coexpression of MKK6EE, a constitutively active mutant of MKK6, a MAPKK that specifically activates p38, further increased the activity of the SOX9-dependent 48-bp enhancer about 5-fold, and SOX9 protein levels were not increased under these conditions. This increase in enhancer activity was not observed in a mutant enhancer construct harboring mutations that abolish SOX9 binding. These data strongly suggested that activation of the p38 pathway results in increased activity of SOX9. In addition, the increase of the activity of the SOX9-dependent 48-bp enhancer by MKK6EE was also observed in primary chondrocytes, and this increase was abolished by coexpression of a p38 phosphatase, MKP5, and p38 specific inhibitors. Furthermore, treatment of primary chondrocytes with p38 inhibitors decreased the expression of Col2a1, a downstream target of Sox9, without affecting Sox9 RNA levels, further supporting the hypothesis that p38 plays a role in regulating Sox9 activity in chondrocytes. ^ To further study the role of the p38 MAPK pathway in chondrogenesis, we generated transgenic mice that express MKK6EE in chondrocytes under the control of the Col2a1 promoter/intron regulatory sequences. These mice showed a dwarf phenotype characterized by reduced chondrocyte proliferation and a delay in the formation of primary and secondary ossification centers. Histological analysis using in situ hybridization showed reduced expression of Indian hedgehog, PTH/PTHrP receptor, cyclin D1 and increased expression of p21. In addition, consistent with the notion that Sox9 activity was increased in these mice, transgenic mice that express MKK6EE in chondrocytes showed phenotypes similar to those of mice that overexpress SOX9 in chondrocytes. Therefore, our study provides in vivo evidence for the role of p38 in chondrocyte differentiation and suggests that Sox9 is a downstream target of the p38 MAPK pathway. ^

Breast cancer -specific activation of topoisomerase IIalpha and its application in the tumor -targeting gene therapy

To ensure the success of systemic gene therapy, it is critical to enhance the tumor specificity and activity of the promoter. In the current study, we identified the breast cancer-specific activity of the topoisomerase IIα promoter. We further showed that cdk2 and cyclin A activate topoisomerase IIα promoter in a breast cancer-specific manner. An element containing an inverted CCAAT box (ICB) was shown to respond this signaling. When the ICB-harboring topoisomerase IIα minimal promoter was linked with an enhancer sequence from the cytomegalovirus immediate early gene promoter (CMV promoter), this composite promoter, CT90, exhibited activity comparable to or higher than the CMV promoter in breast cancer cells in vitro and in vivo, yet expresses much lower activity in normal cell lines and normal organs than the CMV promoter. A CT90-driven construct expressing BikDD, a potent pro-apoptotic gene, was shown to selectively kill breast cancer cells in vitro and to suppress mammary tumor development in an animal model of intravenously administrated, liposome-delivered gene therapy. Expression of BikDD was readily detectable in the tumors but not in the normal organs of CT90-BikDD-treated animals. Finally, we demonstrated that CT90-BikDD treatment potentially enhanced the sensitivity of breast cancer cells to chemotherapeutic agents, especially doxorubicin and taxol. The results indicate that liposomal CT90-BikDD is a novel and effective systemic breast cancer-targeting gene therapy, and its combination with chemotherapy may further improve the current adjuvant therapy for breast cancer. ^