The pea plastocyanin promoter directs cell-specific but not full light-regulated expression in transgenic tobacco plants

A series of 5′ deletions of the pea plastocyanin gene (petE) promoter fused to the β-glucuronidase (GUS) reporter gene has been examined for expression in transgenic tobacco plants. Strong positive and negative cis-elements which modulate quantitative expression of the transgene in the light and the dark have been detected within the petE promoter. Disruption of a negative regulatory element at ?784 bp produced the strongest photosynthesis-gene promoter so far described. Histochemical analysis demonstrated that all petE-GUS constructs directed expression in chloroplast-containing cells, and that a region from ?176 bp to +4 bp from the translation start site was sufficient for such cell-specific expression. The petE-promoter fusions were expressed at high levels in etiolated transgenic tobacco seedlings but there was no marked induction of GUS activity in the light. The endogenous tobacco plastocyanin genes and the complete pea plastocyanin gene in transgenic tobacco plants were also expressed in the dark, but showed a three- to sevenfold increase in the light. This indicates a requirement for sequences 3′ to the promoter for the full light response of the petE gene.     

Isolation and Characterization of OsGSTL1 Promoter from Rice

OsGSTL1 gene was isolated from the rice genomic library. Semi-quantitative RT-PCR analysis demonstrated that the expression of the OsGSTL1 in rice was not induced by chlorsulfuron, ethylene, abscisic acid, salicylic acid, and methyl jasmonate. In order to investigate the cis-elements of OsGSTL1 promoter, the promoter regions with different lengths were fused to the β-glucuronidase (GUS) reporter gene. All constructs were transformed into onion epidermal cells or A. thaliana plants to detect the expression patterns. In onion epidermal cells, the 160 bp fragment and longer ones were functional for directing GUS expression. In transgenic A. thaliana, the 2?155 bp upstream region of OsGSTL1 gene directed the GUS expression only in cotyledon after germination, but not in the root of young seedlings. In the later seedling, the 2?155 bp upstream region of OsGSTL1 gene directed GUS expression in roots, stems, and leaves. However, the GUS gene directed by a 1?224 bp upstream fragment is expressed in all the checked tissues. These results suggest that the spatiotemporal expression response elements of OsGSTL1 existed in the 5′-upstream region between −2?155 and −1?224 bp.     

Function of the wheat TaSIP gene in enhancing drought and salt tolerance in transgenic Arabidopsis and rice

Microarray analysis of a salt-tolerant wheat mutant identified a gene of unknown function that was induced by exposure to high levels of salt and subsequently denoted TaSIP (Triticum aestivum salt-induced protein). Quantitative PCR analysis revealed that TaSIP expression was induced not only by salt, but also by drought, abscisic acid (ABA), and other environmental stress factors. Transgenic rice plants that expressed an RNA interference construct specific for a rice gene homologous to TaSIP was more susceptible to salt stress than wild-type rice plants. Subcellular localization studies showed that the TaSIP localized to the cell membrane. Under conditions of salt and drought stress, transgenic Arabidopsis plants that overexpressed TaSIP showed superior physiological properties compared with control plants, including lower Na⁺ content and upregulation of several stress resistance genes. Staining of transgenic tissues with β-glucuronidase (GUS) failed to indicate tissue-specific activity of the full-length TaSIP promoter. Quantitative analysis of GUS fluorescence in transgenic plants treated with ABA or salt stress revealed that the region 1,176–1,410 bp from the start codon contained an ABA-responsive element and that the region 579–1,176 bp from the start codon upstream of the exon contained a salt-stress-responsive element. Based on these results, we conclude that the key part of the TaSIP gene is the region of its promoter involved in salt tolerance.     

Nuclear factors GT-1 and 3AF1 interact with multiple sequences within the promoter of the Tdc gene from Madagascar periwinkle: GT-1 is involved in UV light-induced expression

Plant secondary metabolites of the terpenoid indole alkaloid (TIA) class comprise several compounds with pharmaceutical applications. A key step in the TIA biosynthetic pathway is catalysed by the enzyme tryptophan decarboxylase (TDC), which channels the primary metabolite tryptophan into TIA metabolism. In Catharanthus roseus (Madagascar periwinkle), the Tdc gene is expressed throughout plant development. Moreover, Tdc gene expression is induced by external stress signals, such as fungal elicitor and UV light. In a previous study of Tdc promoter architecture in transgenic tobacco it was shown that the ?538 to ?112 region is a quantitative determinant for the expression level in different plant organs. Within this sequence one particular region (?160 to ?99) was identified as the major contributor to basal expression and another region (?99 to ?37) was shown to be required for induction by fungal elicitor. Here, the in vitro binding of nuclear factors to the ?572 to ?37 region is described. In extracts from tobacco and C. roseus, two binding activities were detected that could be identified as the previously described nuclear factors GT-1 and 3AF1, based on their mobility and binding characteristics. Both factors appeared to interact with multiple regions in the Tdc promoter. Mutagenesis of GT-1 binding sites in the Tdc promoter did not affect the basal or elicitor-induced expression levels. However, induction of the Tdc promoter constructs by UV light was significantly lower, thereby demonstrating a functional role for GT-1 in the induction of Tdc expression by UV light.     

White Lupin (Lupinus albus) response to phosphorus stress: evidence for complex regulation of LaSAP1

Proteoid roots are a unique adaptation that allow white lupin (Lupinus albus L. var Ultra) to survive under extreme phosphorus (P) deficient conditions. The cascade of events that signals P-deficiency induced gene expression in proteoid roots remains unknown. Through promoter::GUS analysis we showed that expression of acid phosphatase (LaSAP1) in P-deficient proteoid roots depends on DNA located from ?465 bp to ?345 bp 5′ of the ATG start codon and that the P1BS (PHR1 Binding Site) element, located at ?160 bp, also contributes regulatory control. DNA located within the ?414 bp to ?250 bp region of the LaSAP1 promoter was bound by nuclear proteins isolated from P-sufficient normal roots in electrophoretic mobility shift assays (EMSA), suggesting negative regulation. Competition experiments were performed with unlabeled oligonucleotides to further delineate the region of the LaSAP1 promoter bound by P-sufficient normal root nuclear proteins to a motif spanning ?361 bp to ?346 bp. The promoter motif characterized through EMSA spanning ?361 bp to ?345 bp was used as “bait” in a yeast one-hybrid (Y1H) experiment and 31 putative DNA binding proteins were isolated. Taken together, our results increase understanding of P-deficiency signaling by identifying regulatory regions and putative regulatory proteins for LaSAP1 expression.     

Cloning and characterization of a cold inducible Pal promoter from Fagopyrum tataricum

Phenylalanine ammonia-lyase (PAL) catalyzes the first reaction in biosynthesis pathway of flavonoids and plays an important role in plant stress resistance. In this study, the 5’ flanking region of phenylalanine ammonia-lyase gene was isolated from Fagopyrum tataricum by thermal asymmetric interlaced PCR method, named PFtPal (GenBank: KF463139). To investigate the functional properties of PFtPal, we constructed a series of plant expression vectors that contained different promoter fragments resulting from nest deletions and had successfully transformed them into tobacco leaves by Agrobacterium tumefaciens. Histochemical assay of GUS suggested that PFtPal could drive GUS gene expression in leaves and roots, while GUS activity was not detected in the stem. In addition, the region of ?274 bp to ?1 bp was enough to drive normal expression of GUS gene. Low temperature treatment of transgenic tobacco plants demonstrated that PFtPal conferred cold-induced expression. Taken together, our study will help to better understand the Pal promoter, and provides a candidate promoter for molecular breeding in Fagopyrum plants.     

Gonadotrope-Specific Expression and Regulation of Ovine Follicle Stimulating Hormone Beta: Transgenic and Adenoviral Approaches Using Primary Murine Gonadotropes

The beta subunit of follicle stimulating hormone (FSHB) is expressed specifically in pituitary gonadotropes in vertebrates. Transgenic mouse studies have shown that enhancers in the proximal promoter between −172/−1 bp of the ovine FSHB gene are required for gonadotrope expression of ovine FSHB. These enhancers are associated with regulation by activins and gonadotropin releasing hormone (GnRH). Additional distal promoter sequence between −4741/−750 bp is also required for expression. New transgenic studies presented here focus on this distal region and narrow it to 1116 bp between −1866/−750 bp. In addition, adenoviral constructs were produced to identify these critical distal sequences using purified primary mouse gonadotropes as an in vitro model system. The adenoviral constructs contained −2871 bp, −750 bp or −232 bp of the ovine FSHB promoter. They all showed gonadotrope-specific regulation since they were induced only in purified primary gonadotropes by activin A (50 ng/ml) and inhibited by GnRH (100 nM) in the presence of activin (except −232FSHBLuc). However, basal expression of all three viral constructs (in the presence of follistatin to block cellular induction by activin) was relatively high in pituitary non-gonadotropes as well as gonadotropes. Thus, gonadotrope-specific regulation associated with the proximal promoter was observed as expected, but the model was blind to distal promoter elements between −2871/−750 necessary for gonadotrope-specific expression of ovine FSHB in vivo. The new adenoviral-based in vitro technique did detect, however, a novel GnRH response element between −750 bp and −232 bp of the ovine FSHB promoter. We conclude that adenoviral-based studies in primary gonadotropes can adequately recognize regulatory elements on the ovine FSHB promoter associated with gonadotrope-specific regulation/expression, but that more physiologically based techniques, such as transgenic studies, will be needed to identify sequences between −1866/−750 bp of the ovine FSHB promoter that are also required for tissue/cell specific expression in vivo.