Identification of the histamine H1 receptor gene as a differentially repressed target of the human TR2 orphan receptor

We have identified a DNA response element (TR2RE-HR) in the 3 flanking region of the human histamine H1 receptor gene as a target for the TR2 orphan receptor, a member of the steroid/thyroid hormone receptor superfamily. The application of both tetracycline inducible and improved differential display systems has allowed us to isolate a cDNA fragment differentially regulated by the expression of the TR2 orphan receptor. Northern blot and sequencing analysis demonstrated that the expression of the human histamine H1 receptor gene was differentially repressed by the TR2 orphan receptor. Electrophoretic mobility shift assay further revealed a specific binding (dissociation constant = 26.2 nM) between the TR2 orphan receptor and the wildtype TR2RE-HR, but not the mutant TR2RE-HR. In addition, reporter gene expression assay indicated that the TR2 orphan receptor may suppress the expression of luciferase activities in a dose-dependent manner via the TR2RE-HR in HeLa cells. Our results demonstrate that the histamine H1 receptor gene could represent one of the target genes directly regulated by the human TR2 orphan receptor.     

Modulation of the retinoic acid-induced cell apoptosis and differentiation by the human TR4 orphan nuclear receptor

In our previous studies, the TR4 orphan nuclear receptor (TR4) has been demonstrated to suppress retinoic acid (RA)-induced transactivation via a negative feedback control mechanism and in situ analysis showed that TR4 is extensively expressed in mouse brain, especially in regions where the cells are proliferating. To further study the potential roles of TR4 during cell differentiation, a tetracycline-inducible system with anti-sense TR4 in teratocarcinoma P19 cell lines was generated to analyze the retinoic acid-induced differentiation of these cells. The results indicated that the expression of TR4 reduced by doxycycline anti-sense TR4 would alter the retinoic acid-induced differentiation pathway that results in the changes of cell morphology and cell cycle profile. Unexpectedly, our data further indicated that the RA-induced apoptosis, judging by DNA fragmentation, could also be altered by the induction of anti-sense TR4. Together, these findings provide the first in vivo evidence that an orphan nuclear receptor, such as TR4, may play major roles in the RA-mediated apoptosis or differentiation in P19 cells.     

孤儿受体TR3在小鼠睾丸中的定位和表达

本文采用原位杂交和免疫组织化学技术,观察孤儿受体ＴＲ３及其ｍＲＮＡ在小鼠睾丸中的表达及细胞定位。结果表明,在小鼠睾丸中有显著量的孤儿受体ＴＲ３ ｍＲＮＡ和蛋白表达,其表达量在不同曲细精管有明显的差异;孤儿受体ＴＲ３蛋白主要定位于生精细胞,其ｍＲＮＡ在生精细胞特异表达,主要在精原细胞和发育早期的初级精母细胞表达,提示孤儿受体ＴＲ３在小鼠曲细精管精子发生的早期阶段中起着调控作用。     

核孤儿受体TR3/nur77与一种新细胞凋亡机制

核孤儿受体TR3/nur77是一种立刻早期基因（immediate-early gene）的产物,与固醇类激素受体结构相似,是核受体超家族的重要成员之一,可被多种生长因子或凋亡诱导剂诱导表达,具有复杂的生物学功能,涉及细胞增殖、分化发育和凋亡过程.最近对其诱导凋亡机制的研究取得了重大进展,发现当细胞受到凋亡诱导剂刺激后,TR3基因表达升高,其产物从细胞核移位至线粒体膜,引起细胞色素c释放,从而导致细胞凋亡.即TR3的转录激活功能和诱导凋亡功能是由其不同的亚细胞定位结合所决定的,其诱导凋亡过程与其对基因的反式激活功能无关.核转录因子p53也具有类似情况.这种核转录因子由细胞核移位至细胞浆并发挥生物学功能的调控方式是一种新模式,可能具有重要的生物学意义.     

Increased Chemosensitivity via Targeting Testicular Nuclear Receptor 4 (TR4)-Oct4-Interleukin 1 Receptor Antagonist (IL1Ra) Axis in Prostate Cancer CD133+ Stem/Progenitor Cells to Battle Prostate Cancer

Prostate cancer (PCa) stem/progenitor cells are known to have higher chemoresistance than non-stem/progenitor cells, but the underlying molecular mechanism remains unclear. We found the expression of testicular nuclear receptor 4 (TR4) is significantly higher in PCa CD133⁺ stem/progenitor cells compared with CD133⁻ non-stem/progenitor cells. Knockdown of TR4 levels in the established PCa stem/progenitor cells and the CD133⁺ population of the C4-2 PCa cell line with lentiviral TR4 siRNA led to increased drug sensitivity to the two commonly used chemotherapeutic drugs, docetaxel and etoposide, judging from significantly reduced IC₅₀ values and increased apoptosis in the TR4 knockdown cells. Mechanism dissection studies found that suppression of TR4 in these stem/progenitor cells led to down-regulation of Oct4 expression, which, in turn, down-regulated the IL-1 receptor antagonist (IL1Ra) expression. Neutralization experiments via adding these molecules into the TR4 knockdown PCa stem/progenitor cells reversed the chemoresistance, suggesting that the TR4-Oct4-IL1Ra axis may play a critical role in the development of chemoresistance in the PCa stem/progenitor cells. Together, these studies suggest that targeting TR4 may alter chemoresistance of PCa stem/progenitor cells, and this finding provides the possibility of targeting TR4 as a new and better approach to overcome the chemoresistance problem in PCa therapeutics.     

Stage dependent and androgen inductive expression of orphan receptor TR4 in rat testis

In this study, we investigated the expression of TR4 in different stages of seminiferous tubules and the relationship between TR4 and androgen in rat testis. We found that TR4 was stage-dependently expressed in rat seminiferous tubules, T withdrawal induced by high doses of testosterone undecanoate and ethane dimethane sulfonate inhibit TR4 expression in rat testis, and testosterone induced TR4 expression in co-cultured primary germ/Sertoli cells. Furthermore, we demonstrated that androgen receptor could enhance TR4-mediated transactivation activity in testis cells in the presence of testosterone. Together, these data indicate that the expression of TR4 in rat testis is stage dependent and androgen inductive, and suggest the important role of orphan receptor TR4 in spermatogenesis.     

Spermatogenesis and testis development are normal in mice lacking testicular orphan nuclear receptor 2

Early in vitro cell culture studies suggested that testicular orphan nuclear receptor 2 (TR2), a member of the nuclear receptor superfamily, may play important roles in the control of several pathways including retinoic acids, vitamin D, thyroid hormones, and ciliary neurotrophic factor. Here we report the surprising results showing that mice lacking TR2 are viable and have no serious developmental defects. Male mice lacking TR2 have functional testes, including normal sperm number and motility, and both male and female mice lacking TR2 are fertile. In heterozygous TR2(+/-) male mice we found that beta-galactosidase, the indicator of TR2 protein expression, was first detected at the age of 3 weeks and its expression pattern was restricted mainly in the spermatocytes and round spermatids. These protein expression patterns were further confirmed with Northern blot analysis of TR2 mRNA expression. Together, results from TR2-knockout mice suggest that TR2 may not play essential roles in spermatogenesis and normal testis development, function, and maintenance. Alternatively, the roles of TR2 may be redundant and could be played by other close members of the nuclear receptor superfamily such as testicular orphan receptor 4 (TR4) or unidentified orphan receptors that share many similar functions with TR2. Further studies with double knockouts of both orphan nuclear receptors, TR2 and TR4, may reveal their real physiological roles.     

A functional NR4A nuclear receptor DNA‐binding domain is required for organ development in Caenorhabditis elegans

NR4A nuclear receptors are a diverse group of orphan nuclear receptors with critical roles in regulating cell proliferation and cell differentiation. The ortholog of the NR4A nuclear receptor in Caenorhabditis elegans, NHR‐6, also has a role in cell proliferation and cell differentiation during organogenesis of the spermatheca. Here we show that NHR‐6 is able to bind the canonical NR4A monomer response element and can transactivate from this site in mammalian HEK293 cells. Using a functional GFP‐tagged NHR‐6 fusion, we also demonstrate that NHR‐6 is nuclear localized during development of the spermatheca. Mutation of the DNA‐binding domain of NHR‐6 abolishes its activity in genetic rescue assays, demonstrating a requirement for the DNA‐binding domain. This study represents the first genetic demonstration of an in vivo requirement for an NR4A nuclear receptor DNA‐binding domain in a whole organism. genesis 48:485–491, 2010. © 2010 Wiley‐Liss, Inc.