Anisowicz A, Sotiropoulou G, Sager R
Division of Cancer Genetics, Dana-Farber Cancer Institute, Harvard Medical School, Boston, Massachusetts, USA.
Mol Med. 1999 Aug;5(8):526-41.
Invasive tumor cells are characterized by multiple phenotypic changes as a result of the large number of cDNAs being differentially expressed in tumor cells compared to normal progenitors. Expression genetics focuses on changes at the RNA level with the aim of identifying functionally important genes whose aberrant expression in cancer cells is regulated at the level of transcription. These genes were named class II genes and are distinguished from class I genes, which are characterized by genomic mutations, deletions, or other alterations. Reversal of the tumor cell phenotype accompanying normalization of the expression of such genes may be exploited therapeutically if gene expression can be specifically modulated by drugs or other treatments. Considering that genes are coordinately regulated in complex networks, it is likely that the expression of multiple genes can be simultaneously modulated in tumor cells by drugs acting on the signal transduction pathway that regulates their expression. The SPR1 gene is associated with differentiation and its expression is down-regulated or inactivated in malignant cells. Analysis of the SPR1 promoter showed that down-regulation of SPR1 expression in breast tumor cells occurs at the level of transcription. SPR1 presents an example of class II genes, since its expression was up-regulated in tumor cells by phorbol 12-myristate 13-acetate (PMA) or by ultraviolet (UV) irradiation.
The SPR1 gene was identified by differential display on the basis of its reduced or absent expression in human breast tumor cell lines compared to normal mammary epithelial cell strains. Differential expression was confirmed by Northern blot analysis employing multiple normal and tumor cell lines. The promoter region -619 to +15 of the SPR1 gene was sequenced and analyzed by CAT assays, deletion analysis, and mutagenesis. Up-regulation of SPR1 expression by PMA and UV irradiation was monitored by Northern analysis and analyzed by CAT assays.
The mechanism of down-regulation of SPR1 expression in breast tumor cells was investigated. It was found that the -619 to +15 upstream promoter region is sufficient for SPR1 expression in normal breast cells, but it is transcriptionally silent in most breast tumor cell lines. By deletion analysis and mutagenesis, two upstream cis-acting promoter elements were identified. Our data indicate that the AP-1 element located between -139 and -133 acts as a major enhancer of SPR1 transcription only in normal mammary epithelial cells but not in corresponding tumor cells, whereas the sequences flanking the AP-1 site do not affect its promoter enhancing activity. In addition, a transcriptional repressor was identified that binds unknown factor(s) and is active in both normal and tumor breast cells. Inhibitor function was mapped to a 35-bp element located from -178 to -139 upstream of the human SPR1 mRNA start site. The expression of SPR1 could be induced in the 21MT-2 metastatic breast tumor cell line by PMA treatment or by short UV irradiation via a transcriptional mechanism. AP-1 is the cis element mediating the transcriptional activation of SPR1 by PMA, which induces the expression of AP-1 factors in 21MT-2 cells. Mutation of the AP-1 site abolishes the induction of SPR1 expression by PMA.
Our results demonstrate that loss of SPR1 expression in breast tumor cells results from impaired transactivation through the AP-1 site in the SPR1 promoter, as well as from the presence of a negative regulatory element active in both normal and tumor cells. Furthermore, our results provide a basis for therapeutic manipulation of down-regulated genes, such as SPR1, in human cancers.
侵袭性肿瘤细胞具有多种表型变化,这是由于与正常祖细胞相比,肿瘤细胞中有大量的互补DNA(cDNA)差异表达。表达遗传学关注RNA水平的变化,目的是鉴定功能上重要的基因,其在癌细胞中的异常表达在转录水平受到调控。这些基因被称为II类基因,与以基因组突变、缺失或其他改变为特征的I类基因相区别。如果基因表达可以通过药物或其他治疗方法进行特异性调节,那么伴随此类基因表达正常化的肿瘤细胞表型逆转可能具有治疗价值。考虑到基因在复杂网络中是协同调控的,通过作用于调节其表达的信号转导途径的药物,可能同时调节肿瘤细胞中多个基因的表达。SPR1基因与分化相关,其在恶性细胞中的表达下调或失活。对SPR1启动子的分析表明,乳腺肿瘤细胞中SPR1表达的下调发生在转录水平。SPR1是II类基因的一个例子,因为其在肿瘤细胞中的表达可被佛波酯12 - 肉豆蔻酸酯13 - 乙酸酯(PMA)或紫外线(UV)照射上调。
基于与正常乳腺上皮细胞系相比,其在人乳腺肿瘤细胞系中表达降低或缺失,通过差异显示鉴定出SPR1基因。采用多个正常和肿瘤细胞系,通过Northern印迹分析证实差异表达。对SPR1基因的启动子区域 -619至 +15进行测序,并通过氯霉素乙酰转移酶(CAT)分析、缺失分析和诱变进行分析。通过Northern分析监测PMA和UV照射对SPR1表达的上调,并通过CAT分析进行分析。
研究了乳腺肿瘤细胞中SPR1表达下调的机制。发现 -619至 +15的上游启动子区域足以使SPR1在正常乳腺细胞中表达,但在大多数乳腺肿瘤细胞系中该区域转录沉默。通过缺失分析和诱变,鉴定出两个上游顺式作用启动子元件。我们的数据表明,位于 -139至 -133之间的AP - 1元件仅在正常乳腺上皮细胞中作为SPR1转录的主要增强子起作用,而在相应的肿瘤细胞中不起作用,而AP - 1位点两侧的序列不影响其启动子增强活性。此外,鉴定出一种转录抑制因子,它与未知因子结合,在正常和肿瘤乳腺细胞中均有活性。抑制功能定位于人类SPR1 mRNA起始位点上游 -178至 -139的一个35碱基对元件。通过转录机制,PMA处理或短时间UV照射可在21MT - 2转移性乳腺肿瘤细胞系中诱导SPR1表达。AP - 1是介导PMA对SPR1转录激活的顺式元件,PMA可诱导21MT - 2细胞中AP - 1因子的表达。AP - 1位点的突变消除了PMA对SPR1表达的诱导作用。
我们的结果表明,乳腺肿瘤细胞中SPR1表达的丧失是由于通过SPR1启动子中的AP - 1位点的反式激活受损,以及由于在正常和肿瘤细胞中均有活性的负调控元件的存在。此外,我们的结果为人类癌症中下调基因(如SPR1)的治疗性操作提供了基础。
