活化素抑制大鼠垂体GH_3细胞中人生长激素基因启动子的活性

本研究旨在探讨活化素(activin)对大鼠垂体GH3细胞中人生长激素(hGH)基因启动子活性的影响及其可能的调节机制。采用荧光素酶报告基因方法。首先建立含hGH基因启动子(-484～+30bp)和荧光素酶融合基因的稳定转染GH3细胞株,然后加入活化素或同时加入活化素与相关信号转导途径的激动剂,通过检测细胞培养液和细胞裂解液中GH的含量,以及GH3细胞内荧光素酶的变化,反映活化素对GH分泌、合成和hGH基因启动子活性的影响。将含不同长度hGH基因启动子序列的荧光素酶表达质粒分别转染GH3细胞,观察它们对活化素的反应,寻找活化素影响hGH基因启动子活性的关键DNA序列。结果表明,活化素(5,50nmol/L)能抑制大鼠垂体GH3细胞中GH的分泌和合成,活化素(5,50nmol/L)还能够抑制GH3细胞中hGH基因启动子的活性,使之仅达对照组的77%和69%;在胞内信号转导激动剂中,丝裂原活化蛋白激酶激酶(MAPKK/MEK)特异性激动剂C6ceramide(1μmol/L)完全取消了活化素对hGH基因启动子活性的抑制作用;活化素发挥抑制作用所需要的hGH基因启动子关键序列位于-132～-66bp之间。上述研究表明,活化素能抑制大鼠垂体GH3中hGH基因启动子的活性,它可能是通过抑制细胞内依赖MAPK的信号转导途径来完成的,同时hGH启动子上-132～-66bp的序列在其中发挥重要的作用。     

Inhibition of rat growth hormone promoter activity by site-specific DNA methylation

The effect of methylation on rat growth hormone (rGH) promoter activity was determined in GH3 cells by measuring rGH-Neo and rGH-CAT fusion gene expression with or without prior in vitro treatment with the site-specific DNA methyltransferases, M-BsuE and M-HhaI. To assay for rGH-promoter-specific effects of DNA methylation, RSV-Neo and RSV-CAT activities with or without M-BsuE, M-HhaI and M-HpaII treatment were measured in parallel cultures of GH3 cells. GH1-Neo and RSV-Neo fusion gene expression was inhibited by in vitro methylation from 44 to 83% as measured by the number of Geneticin-resistant GH3 cell colonies. Methylation of the GH1 promoter by M-BsuE exhibited some selective inhibition of Neo expression as determined by colony numbers, although extensive methylation of non-promoter DNA in GH1-Neo and RSV-Neo by M-HhaI and M-HpaII also inhibited Neo expression. Southern blot analysis of genomic DNA isolated from the Geneticin-resistant GH3 cells indicated that Geneticin-resistance was accompanied by demethylation of the BsuE (ThaI) sites in stably incorporated GH1-Neo DNA but not RSV-Neo DNA. Transient expression of the CAT gene in GH3 cells was selectively inhibited by 60% upon methylation of two BsuE (ThaI) sites in the GH1 promoter of GH1-CAT by M-BsuE. The data demonstrate, for the first time, to our knowledge, a direct effect of DNA methylation on the activity of the rat growth hormone promoter.     

IFN-gamma increases the hGH gene promoter activity in rat GH3 cells

AIM: To study the effect(s) of interferon gamma (IFN-gamma) on the activity of human growth hormone (hGH) gene promoter in rat pituitary GH3 cells and the molecular mechanism underlying the effect(s). METHODS: Cell transfection and luciferase reporter gene were used. RESULTS: IFN-gamma (10(2) and 10(3) U/ml) increased the activity of hGH in GH3 cells. The addition of the mitogen-activated protein kinase inhibitor PD98059 (40 micromol/l) to the cells blocked the stimulatory effect of IFN-gamma. Neither overexpression of Pit-1 nor inhibiting Pit-1 expression affected IFN-gamma induction of hGH promoter activity. To identify the DNA sequence that mediated the effect of IFN-gamma, four deletion constructs of hGH gene promoter were created. The stimulatory effect of IFN-gamma was abolished following deletion of the -250 to -132 fragment. CONCLUSIONS: IFN-gamma increases the activity of hGH gene promoter in rat pituitary GH3 cells. This stimulatory effect of IFN-gamma appears to require the intracellular mitogen-activated protein kinase-dependent signaling pathway. The effect of IFN-gamma requires the promoter sequence that spans the -250 to -132 fragment of the gene, but is unrelated to Pit-1 protein.     

Priming affects the activity of a specific region of the promoter of the human beta interferon gene.

Treatment of Daudi or HeLa cells with human interferon (IFN) alpha 8 before induction with either poly(I)-poly(C) or Sendai virus resulted in an 8- to 100-fold increase in IFN production. The extent of priming in Daudi cells paralleled the increase in the intracellular content of IFN-beta mRNA. IFN-alpha mRNA remained undetectable in poly(I)-poly(C)-treated Daudi cells either before or after priming. An IFN-resistant clone of Daudi cells was found to produce 4- to 20-fold more IFN after priming, indicating that priming was unrelated to the phenotype of IFN sensitivity. IFN treatment of either Daudi or HeLa cells transfected with the human IFN-beta promoter (-282 to -37) linked to the chloramphenicol acetyltransferase (CAT) gene resulted in an increase in CAT activity after induction with poly(I)-poly(C) or Sendai virus. A synthetic double-stranded oligonucleotide corresponding to an authentic 30-base-pair (bp) region of the human IFN-beta promoter between positions -91 and -62 was found to confer virus inducibility upon the reporter CAT gene in HeLa cells. IFN treatment of HeLa cells transfected with this 30-bp region of the IFN-beta promoter in either the correct or reversed orientation also increased CAT activity upon subsequent induction. IFN treatment alone had no detectable effect on the activity of either the 30-bp region or the complete human IFN promoter.     

The homeodomain protein, Pit-1/GHF-1, is capable of binding to and activating cell-specific elements of both the growth hormone and prolactin gene promoters

Studies were conducted to determine whether the trans-acting protein Pit-1/GHF-1 can bind to and activate promoter elements in both the GH and PRL genes that are necessary for cell-specific expression. Four pituitary cell lines that differentially express the endogenous GH and PRL genes were examined for their ability to activate GH and PRL promoter constructs containing sequences necessary for cell-specific expression (CSEs). Plasmids containing one CSE, -96 PRL and -104 GH, were similarly expressed in each of the four cell lines. Of the plasmids containing two CSEs, -173 PRL was always activated to a greater extent than -145 GH, with this relative activation being stronger in GC and GH1 cells than in 235-1 and GH4C1 cells. Protein-DNA binding assays were used to show that the GH and PRL CSEs specifically bound two highly abundant nuclear proteins (31 and 33 kDa). The two proteins were present at similar levels in all four pituitary cell lines and were recognized by a Pit-1/GHF-1 antibody. In contrast, HeLa and Rat2 cells did not activate transfected GH or PRL plasmids and did not contain nuclear proteins that specifically bound to the GH and PRL CSEs. However, cotransfection of these cells with the expression vector RSV-Pit-1/GHF-1 resulted in the activation of -173 PRL and -145 GH (PRL greater than GH). HeLa cells transfected with RSV-Pit-1/GHF-1 also contained 31- and 33-kDa nuclear proteins that bound to the GH and PRL CSEs. These results show that Pit-1/GHF-1 is present at levels in pituitary cell lines that are sufficient to activate the minimal elements in both the GH and PRL promoters necessary for cell-specific expression of these genes.     

NR4A1 (Nur77) mediates thyrotropin-releasing hormone-induced stimulation of transcription of the thyrotropin β gene: analysis of TRH knockout mice

Thyrotropin-releasing hormone (TRH) is a major stimulator of thyrotropin-stimulating hormone (TSH) synthesis in the anterior pituitary, though precisely how TRH stimulates the TSHβ gene remains unclear. Analysis of TRH-deficient mice differing in thyroid hormone status demonstrated that TRH was critical for the basal activity and responsiveness to thyroid hormone of the TSHβ gene. cDNA microarray and K-means cluster analyses with pituitaries from wild-type mice, TRH-deficient mice and TRH-deficient mice with thyroid hormone replacement revealed that the largest and most consistent decrease in expression in the absence of TRH and on supplementation with thyroid hormone was shown by the TSHβ gene, and the NR4A1 gene belonged to the same cluster as and showed a similar expression profile to the TSHβ gene. Immunohistochemical analysis demonstrated that NR4A1 was expressed not only in ACTH- and FSH- producing cells but also in thyrotrophs and the expression was remarkably reduced in TRH-deficient pituitary. Furthermore, experiments in vitro demonstrated that incubation with TRH in GH4C1 cells increased the endogenous NR4A1 mRNA level by approximately 50-fold within one hour, and this stimulation was inhibited by inhibitors for PKC and ERK1/2. Western blot analysis confirmed that TRH increased NR4A1 expression within 2 h. A series of deletions of the promoter demonstrated that the region between bp -138 and +37 of the TSHβ gene was responsible for the TRH-induced stimulation, and Chip analysis revealed that NR4A1 was recruited to this region. Conversely, knockdown of NR4A1 by siRNA led to a significant reduction in TRH-induced TSHβ promoter activity. Furthermore, TRH stimulated NR4A1 promoter activity through the TRH receptor. These findings demonstrated that 1) TRH is a highly specific regulator of the TSHβ gene, and 2) TRH mediated induction of the TSHβ gene, at least in part by sequential stimulation of the NR4A1-TSHβ genes through a PKC and ERK1/2 pathway.     

A role for A/T-rich sequences and Pit-1/GHF-1 in a distal enhancer located in the human growth hormone locus control region with preferential pituitary activity in culture and transgenic mice.

A region located remotely upstream of the human pituitary GH (GH-N) gene and required for efficient GH-N gene expression in the pituitary of transgenic mice was cloned as a 1.6-kb Bg/II (1.6G) fragment. The 1.6G fragment in the forward or reverse orientation increased -496GH-N promoter activity significantly in pituitary GC and GH3 cells after gene transfer. The 1.6G fragment was also able to stimulate activity from a minimal thymidine kinase (TK) promoter which, unlike -496GH-N, lacked any Pit-1/GHF-1 element. Enhancer activity was localized by deletion analysis to a 203-bp region in the 3'-end of the 1.6G fragment and was characterized by the presence of a diffuse 136-bp nuclease-protected site, observed with pituitary (GC) but not nonpituitary (HeLa) cell nuclear protein. A major low-mobility complex was observed by electrophoretic mobility shift assay (EMSA) with GC cell nuclear protein, and the pattern was distinct from that seen with a HeLa cell extract. The nuclease-protected region contains three A/T-rich Pit-1/ GHF-1-like elements, and their disruption, in the context of the 203-bp region fused to the TK promoter, reduced enhancer activity significantly in pituitary cells in culture. A mutation in this region was also shown to decrease enhancer activity in transgenic mice and correlated with a decrease in the 203-bp enhancer region complex observed by EMSA. The participation of Pit-1/GHF-1 in this complex is indicated by competition studies with Pit-1/GHF-1 elements and antibodies, and direct binding of Pit-1/GHF-1 to the A/T-rich sequences was shown by EMSA using recombinant protein. These studies link the A/T-rich sequences to the distal enhancer activity associated with the GH locus control region in vitro and in vivo.