Analysis of the promoter region of the gene encoding mouse cholesterol side-chain cleavage enzyme

The cholesterol side-chain cleavage enzyme (SCC) catalyzes the initial and rate-limiting step in the synthesis of steroid hormones. The mouse gene encoding SCC was cloned and the nucleotide sequence of its 5'-flanking region determined. This sequence includes an AP-1 motif at -319 and two motifs, AGGTCA at -70 and AGCCTTG at -40, that match elements proposed to be important in the expression of steroid 21-hydroxylase. When transfected into mouse Y1 adrenocortical tumor cells, 1.5 kilobase pairs of 5'-flanking region of the SCC gene directed high levels of expression of a growth hormone reporter gene; treatment of the transfected Y1 cells with 8-bromo-cAMP increased this expression by 5-fold. In contrast, transfected mouse MA-10 Leydig cells showed appreciably lower expression, suggesting that SCC expression in Leydig cells requires additional elements not contained in the 5'-flanking region of the SCC gene used in these experiments. Deletion experiments showed that 424 base pairs of 5'-flanking sequences were sufficient for regulated expression in Y1 cells and mapped two regulatory regions: one from -424 to -327 and a second from -219 to -77. DNase I footprinting and gel mobility shift analyses of these 424 base pairs defined several interactions between nuclear proteins and the SCC promoter, including footprints centered over the AP-1 motif, over a sequence at -120, and over the sequences (-70 and -40) that resemble 21-hydroxylase promoter elements. Finally, site-selected mutagenesis of the potential elements at -40, -70, or -120 decreased SCC promoter activity in transfected Y1 adrenocortical cells, thus establishing their importance in SCC expression.     

Human beta-interferon gene expression is regulated by an inducible enhancer element

We have localized the regulatory sequence required for viral or poly(I)-poly(C) activation of human beta-interferon gene expression to a region located between -37 and -77 from the mRNA cap site. This sequence has the characteristics of an inducible enhancer element: it can act upstream or downstream of the beta-interferon gene regardless of its orientation, and at distances up to approximately 1 kilobase from its normal location. Moreover, this element can confer inducibility on a heterologous promoter. Further analysis has identified a minimal regulatory element of 14 base pairs within this enhancer. Sequences closely related to this element are present five times within the 5'-flanking regions of both the alpha- and beta-interferon genes. The number of these minimal regulatory elements required for maximal beta-interferon gene expression appears to differ in different cell lines.     

Pem homeobox gene regulatory sequences that direct androgen-dependent developmentally regulated gene expression in different subregions of the epididymis

The epididymis is a useful model system to understand the mechanisms that govern region-specific gene expression, as many gene products display spatially restricted expression within this organ. However, surprisingly little is known about how this regulation is achieved. Here, we report regulatory sequences from the Pem homeobox gene that drive expression in different subregions of the mouse epididymis in vivo. We found that the 0.3-kb 5'-flanking sequence (region I) from the Pem proximal promoter (Pem Pp) was sufficient to confer androgen-dependent and developmentally regulated expression in the caput region of the epididymis. Expression was restricted to the normal regions of expression of Pem in the caput (segments 2-4), but there was also aberrant expression in the corpus region. This corpus misexpression was extinguished when 0.6 kb of Pem Pp 5'-flanking sequence was included in the transgene, indicating that one or more negative regulatory elements exist between 0.6 and 0.3 kb upstream of the Pem Pp start site (region II). When heterologous sequences were introduced upstream of the Pem Pp, expression was further restricted, mainly to caput segment 3, implying that the Pem Pp has segment-specific regulatory elements. To our knowledge, the regulatory regions we have identified are the shortest so far defined that dictate regionally localized expression in the epididymis in vivo. They may be useful for identifying the factors that regulate region-specific expression in the epididymis, for expressing and conditionally knocking out genes in different subregions of the epididymis, for treating male infertility, and for generating novel methods of male contraception.     

Cooperativity of sequence elements mediates tissue specificity of the rat insulin II gene.

The 5'-flanking region of the rat insulin II gene (-448 to +50) is sufficient for tissue-specific expression. To further determine the tissue-specific cis-acting element(s), important sequences defined by linker-scanning mutagenesis were placed upstream of a heterologous promoter and transfected into insulin-producing and -nonproducing cells. Rat insulin promoter element 3 (RIPE3), which spans from -125 to -86, was shown to confer beta-cell-specific expression in either orientation. However, two subregions of RIPE3, RIPE3a and RIPE3b (defined by linker-scanning mutations), displayed only marginal activities. These results suggest that the two subregions cooperate to confer tissue specificity, presumably via their cognate binding factors.     

Roles of IFN consensus sequence binding protein and PU.1 in regulating IL-18 gene expression.

IL-18 is expressed from a variety of cell types. Two promoters located upstream of exon 1 (5'-flanking region) and upstream of exon 2 (intron 1) regulate its expression. Both promoter regions were cloned into pCAT-Basic plasmid to yield p1-2686 for the 5'-flanking promoter and p2-2.3 for the intron 1 promoter. Both promoters showed basal constitutive activity and LPS inducibility when transfected into RAW 264.7 macrophages. To learn the regulatory elements of both promoters, 5'-serial deletion and site-directed mutants were prepared. For the activity of the p1-2686 promoter, the IFN consensus sequence binding protein (ICSBP) binding site between -39 and -22 was critical. EMSA using an oligonucleotide probe encompassing the ICSBP binding site showed that LPS treatment increased the formation of DNA binding complex. In addition, when supershift assays were performed, retardation of the protein-DNA complex was seen after the addition of anti-ICSBP Ab. For the activity of the p2-2.3 promoter, the PU.1 binding site between -31 and -13 was important. EMSA using a PU.1-specific oligonucleotide demonstrated that LPS treatment increased PU.1 binding activity. The addition of PU.1-specific Ab to LPS-treated nuclear extracts resulted in the formation of a supershifted complex. Furthermore, cotransfection of ICSBP or PU.1 expression vector increased p1 promoter activity or IL-18 expression, respectively. Taken together, these results indicate that ICSBP and PU.1 are critical elements for IL-18 gene expression.     

丁酸钠至少部分通过NF-Y 依赖的TXNIP 表达诱导人肺癌细胞A549死亡

组蛋白去乙酰化酶（HDACs）抑制剂丁酸钠调节细胞分化、增殖和抑制肿瘤发生。硫氧还蛋白相互作用蛋白( thioredoxin-interacting protein,TXNIP)通过负性调控硫氧还蛋白的活性,调控细胞内的氧化还原平衡,抑制细胞生长。本研究证明,丁酸钠可通过激活依赖于转录因子NF-Y的TXNIP 表达,诱导人非小细胞肺癌细胞A549死亡。MTT法显示,5 mmol/L丁酸钠处理A549 细胞72 h可显著诱导其死亡;流式细胞分析发现,其中大部分细胞以凋亡形式死亡。表达芯片分析表明,在丁酸钠处理的A549 细胞中,TXNIP 的mRNA 水平显著提高30～50倍;实时定量PCR、免疫细胞化学和蛋白质印迹结果进一步证明,丁酸钠可显著上调TXNIP 表达。荧光素酶报告基因分析证明,与对照细胞比较,丁酸钠刺激的细胞内报告酶活性可提高约10 倍,提示丁酸钠可激活TXNIP 启动子的转录活性。TXNIP 启动子删除突变分析显示,删除NF-Y 结合的DNA 序列显著降低丁酸钠对TXNIP 启动子的激活能力, 表明NF-Y转录因子参与丁酸钠介导的TXNIP基因转录激活。为分析TXNIP 在A549 细胞中的定位和部分功能,在A549细胞 中过表达GFP TXNIP 融合蛋白及其截短突变体融合蛋白;结果显示,野生型和保留N 端1-281aa的截短突变体定位在细胞核,而删除N 端1-200aa 时,其定位在细胞核和细胞质,提示N 端1 200aa 可调节该蛋白质的定位。然而,丁酸钠刺激未发现表达的GFP TXNIP在细胞内定位改变。以上结果表明,丁酸钠可通过激活转录因子NF YC 依赖的TXNIP激活,诱导A549 细胞死亡,但不能改变TXNIP蛋白在细胞内的定位。上述结果还提示,TXNIP 的N 端1-200aa 可能在调节TXNIP 的细胞定位中发挥作用。是否丁酸钠刺激TXNIP表达导致的细胞死亡系通过改变细胞氧化压力,以及TXNIP在细胞中定位的详尽调节机制尚待进一步研究证明。     

与人PC-1同源的鼠PC-1基因的启动子的分子克隆和特性分析

为了鉴定鼠mPC-1基因表达的调控元件,克隆并分析了该基因的启动子.构建了一系列mPC-1基因启动子的截短序列.通过荧光素酶报道基因,分析了它们在前列腺癌细胞和其它细胞中的表达.结果表明,在AR阳性细胞系中,mPC-1基因启动子活性远远高于SV40和p61-PSA 启动子,mPC-1基因启动子 599 bp 至449bp 可能含有一个负调控元件; mPC-1 1.1 kb 启动子控制的表达主要在前列腺癌细胞系中; 雄激素可调控mPC-1 1.1kb 启动子表达.mPC-1 1.1kb 序列是一个有前列腺癌细胞特异性和较强的启动子,经过进一步的修饰有可能作为一种有用的前列腺癌基因治疗元件.