DNA sequence variation within the beta-glucuronidase gene complex among inbred strains of mice

Tightly linked to the gene that encodes murine beta-glucuronidase (GUS) are three GUS-specific regulatory elements. Together, these elements define the GUS gene complex. Specific alleles of each regulatory element are associated with a specific GUS structural allele. These associations define the three common forms (haplotypes) of the GUS gene complex, designated A, B, and H. As an initial step in defining the DNA determinants of each regulatory element and to develop DNA markers for the common haplotypes, we have identified several DNA variants by blot hybridization analysis of restricted genomic DNA using GUS-specific cDNA probes. Of 30 tested restriction endonucleases, 24 reveal DNA polymorphisms that distinguish B- and H-haplotype DNA from that of the A haplotype. Of these 24, 18 uncover a restriction fragment length polymorphism in which the polymorphic fragment of A-haplotype DNA is 200-300 bp larger than the corresponding fragment of B- or H-haplotype DNA. DNA sequence analysis of this polymorphic region reveals the presence of a short, interspersed repetitive element of the B2 family within A-haplotype DNA which is absent in DNAs of B- or H-haplotype mice. None of the DNA variations revealed by these analyses can be associated at this time with variation in the regulatory or structural properties of GUS among the common haplotypes. Nevertheless, they do provide useful haplotype-specific markers within the GUS gene complex which are of critical importance for DNA transfer experiments in transgenic mice and in cultured cells.     

Regulation of BN115, a low-temperature-responsive gene from winter Brassica napus.

The genomic clone for BN115, a low-temperature-responsive gene, was isolated from winter Brassica napus and its sequence was determined. A 1.2-kb fragment of the 5' regulatory region (from bp -1107 to +100) was fused to the beta-glucuronidase (GUS) reporter gene and BN115-promoted GUS expression was observed in green tissues of transgenic B. napus plants only after incubation at 2 degrees C. No expression was observed after incubation at 22 degrees C, either in the presence or the absence of ABA. Microprojectile bombardment of winter B. napus leaves with a BN115 promoter/GUS construct yielded similar results and was used to analyze a series of deletions from the 5' end of the promoter. Results obtained from transient expression studies showed that the low-temperature regulation of BN115 expression involves a possible enhancer region between bp -1107 and -802 and a second positive regulatory region located between bp -302 and -274. Deletion analyses and results from replacement with a truncated cauliflower mosaic virus 35S promoter suggest that the minimal size required for any maintenance of low-temperature GUS expression is a -300-bp fragment. Within this fragment are two 8-bp elements with the sequence TGGCCGAC, which are identical to those present in the positive regulatory region of the promoter of the homologous Arabidopsis cor15a gene and to a 5-bp core sequence in the low-temperature- and dehydration-responsive elements identified in the promoter regions of several cold-responsive Arabidopsis thaliana genes.     

Developmental regulation of peach ACC oxidase promoter--GUS fusions in transgenic tomato fruits

A genomic DNA sequence (PpACO1) encoding 1-aminocyclopropane-1-carboxylic acid oxidase (ACO) from peach (Prunus persica L. Batsch cv. Loring) was isolated. It has four exons interrupted by three introns and 2.9 kb of flanking region 5' of the translational start codon. Previous work with the cDNA demonstrated that accumulation of the peach ACO message correlated with increasing amounts of ethylene synthesized by the fruit as they ripened. To identify regulatory elements in the peach ACC oxidase gene, chimeric fusions between 403, 610, 901, 1319, 2141, and 2919 bp of the 5' flanking region of the PpACO1 sequence and the beta-glucuronidase (GUS) coding sequence were constructed and used to transform tomato (Lycopersicon esculentum [Mill] cv. Pixie). Fruits from the various promoter lines were analysed for GUS expression by histochemical GUS staining, GUS quantitative enzyme activity determination, and measuring the relative amounts of GUS mRNA. Constructs with the smallest promoter of 403 bp had significant GUS expression in fruit, but not in other tissues, indicating the presence of a region that affects tissue-specific expression. An increase in GUS expression was observed with promoters longer than 901 bp, indicating an enhancer region between -1319 and -901. The full-length promoter of 2919 bp directed GUS expression in the green stage of fruit development, and increased GUS expression as fruit matured, indicating a regulatory region between -2919 and -2141 that controls the temporal expression of the gene in fruit. Only the full-length promoter sequence demonstrated responsiveness to ethylene.     

毛白杨PtLFY基因启动子的克隆及其瞬时表达分析

为了研究毛白杨LEAFY同源基因PtLFY的表达调控规律,利用PCR技术从毛白杨基因组DNA中克隆出PtLFY基因上游一段1575 bp的序列。经PLACE、PlantCARE在线软件分析表明,该序列含有TATA-BOX、CAAT-BOX等启动子基本元件,另外,还包含干旱诱导的MYB结合位点、脱落酸(ABA)响应元件、光响应元件等其他一些调控序列。因此,PtLFY的表达可能受干旱、ABA、光照等因子的调控。利用FootPrinter在线软件对毛白杨等6个物种的LFY同源基因启动子进行比对,发现不同物种的启动子相对保守,但也存在差异,说明LFY基因在功能上具有相似性,但存在一定差异。在序列分析的基础上,构建由PtLFY启动子驱动GUS报告基因的植物表达载体,命名为PtLFYp1304。通过农杆菌介导的方法转化烟草,对该启动子进行瞬时表达研究,结果表明PtLFY启动子可以驱动GUS基因在烟草根、茎、叶和花器官中表达,但在根、茎、叶中仅微弱表达,表达强度明显低于CaMV35S启动子,而在花萼和雄蕊中表达强烈。     

棉纤维蔗糖合酶基因SS3上游调控序列的克隆及其表达分析

棉纤维蔗糖合酶基因SS3在棉纤维发育过程中起着重要作用.采用YADE技术克隆了该基因5′上游1717bp的调控区,该调控区含有典型的启动子核心元件TATA box ,以及TATC box、G box、GCN4 -motif、Prolamin box、Skn 1 likemotif、TCA element、HSE和O2 site等各种顺式调控元件和其他一些反应元件.将此序列和报告基因GUS融合在烟草、棉花中表达.组织化学分析结果显示棉花SuSyR序列启动GUS基因在烟草的子房、胎座、种子以及在棉花花蕾与棉铃中表达.在棉花花蕾蕾长为3mm、6mm、9mm和15mm花蕾中表达主要存在于雄蕊及雄蕊管、胎座等器官;在棉铃中,1DPA棉铃的花柱、花药、子房及胚珠中出现了蓝色,6DPA棉铃的子房及胚珠被染成蓝色,在2 0DPA的棉铃中蓝色只出现在胚珠及其纤维中、在胚珠中只有珠心被染成蓝色,在4 0DPA胚珠中只有纤维呈蓝色.研究结果揭示,棉花的SuSyR调控序列启动GUS基因主要在子房、胚珠和纤维等器官和主叶脉、茎微管束等输导组织中表达,在棉花中尤为明显,表明棉纤维蔗糖合酶基因SS3除参与棉花蕾铃发育、纤维素的合成外,还参与了光合产物的运输与分配过程.     

Androgen responsiveness of the murine beta-glucuronidase gene is associated with nuclease hypersensitivity, protein binding, and haplotype-specific sequence diversity within intron 9.

The tissue specificity and genetic variability of the murine beta-glucuronidase (GUS) response to androgen provide useful markers for identifying elements which underlie this responsiveness. While GUS is expressed constitutively in all examined cell types, kidney epithelial cells uniquely exhibit a manyfold yet slow rise in GUS mRNA and enzyme levels when stimulated by androgens. Three major phenotypes of this androgen response have been described among inbred strains of mice: (i) a strong response in strains of the Gusa haplotype, (ii) a reduced response in strains of the Gusb and Gush haplotypes, and (iii) no response, as observed in Gusor mice. These response variants define a cis-active element(s) which is tightly linked to the GUS structural gene. Nuclease hypersensitivity scans of kidney chromatin within and surrounding the structural gene revealed an androgen-inducible hypersensitive site in intron 9 of the gene in Gusa but not in Gusor mice. When a radiolabeled fragment of Gusa DNA containing this hypersensitive site was incubated with kidney nuclear extracts and then subjected to gel electrophoresis, two shifted bands were observed whose levels were dramatically higher in extracts of androgen-treated than in those of untreated Gusa mice. The shifted bands reflect binding of a kidney-specific factor(s) to a 57-bp region of complex dyad symmetry in Gusa and Gusor mice which is partially deleted in Gusb and Gush mice. This binding site is located approximately 130 bp downstream of a glucocorticoid response element sequence motif which is totally deleted in [Gus]or mice. Taken together, our results suggest that the androgen responsiveness of GUS in murine kidney epithelial cells is controlled by elements within the proximal end of intron 9 of the GUS structural gene.     

Developmental regulation of two tomato lipoxygenase promoters in transgenic tobacco and tomato

Two lipoxygenase (LOX) genes (tomloxA and tomloxB) are expressed in ripening tomato fruit, and tomloxA is also expressed in germinating seedlings [12]. The 5'-upstream regions of these genes were isolated to study the regulatory elements involved in coordinating tomlox gene expression. Sequence analysis of the promoters did not reveal any previously characterized regulatory elements except for TATA and CAAT boxes. However, the sequence motif GATAcAnnAAtnTGATG was found in both promoters. Chimeric gene fusions of each tomlox promoter with the -glucuronidase reporter gene (gus) were introduced into tobacco and tomato plants via Agrobacterium-mediated transformation. GUS activity in tomloxA-gus plants during seed germination peaked at day 5 and was enhanced by methyl jasmonate (MeJa) treatment. No GUS activity was detected in tomloxB-gus seedlings. Neither wounding nor abscisic acid (ABA) treatment of transgenic seedlings modified the activity of either promoter. During fruit development, GUS expression in tomloxA-gus tobacco fruit increased 5 days after anthesis (DAA) and peaked at 20 DAA. In tomloxB-gus tobacco fruit, GUS activity increased at 10 DAA and peaked at 20 DAA. In transgenic tomato fruit, tomloxA-gus expression was localized to the outer pericarp during fruit ripening, while tomloxB-gus expression was localized in the outer pericarp and columella. These data demonstrate that the promoter regions used in these experiments contain cis-acting regulatory elements required for proper regulation of tomlox expression during development and for MeJa-responsiveness.