A novel wound-responsive cis-element, VWRE, of the vascular system-specific expression of a tobacco peroxidase gene, tpoxN1

The wound-induced expression of tpoxN1, encoding a tobacco peroxidase, is unique because of its vascular system-specific expression and insensitivity to known wound-signal compounds such as jasmonic acid, ethylene, and plant hormones [Sasaki et al. (2002) Plant Cell Physiol 43:108–117]. To study the mechanism of expression, the 2-kbp tpoxN1 promoter region and successive 5′-deletion of the promoter were introduced as GUS fusion genes into tobacco plants. Analysis of GUS activity in transgenic plants indicated that a vascular system-specific and wound-responsive cis-element (VWRE) is present at the −239/−200 region of the promoter. Gel mobility shift assays suggested that a nuclear factor(s) prepared from wounded tobacco stems binds a 14-bp sequence (−229/−215) in the −239/−200 region in a sequence-specific manner. A mutation in this 14-bp region of the −239 promoter fragment resulted in a considerable decrease in wound-responsive GUS activity in transgenic plants. An 11-bp sequence, which completely overlaps with the 14-bp sequence, was found in the 5′ distal region (−420/−410) and is thought to contribute to the wound-induced expression together with the 14-bp. The −114-bp core promoter of the tpoxN1 gene was indispensable for wound-induced expression, indicating that the 14-bp region is a novel wound-responsive cis-element VWRE, which may work cooperatively with other factors in the promoter.     

Abscisic acid-regulated Glb1 transient expression in cultured maize P3377 cells

In a study of the 5′-flanking sequence of the Zea mays L. (maize) Glb1 gene in vitro, serial promoter deletions were generated and linked with the β-glucuronidase (GUS) reporter gene. The promoter deletion-GUS fusions were introduced into the maize P3377 cell line by particle bombardment. GUS assays indicated that treatment of the maize cultured cells with abscisic acid (ABA) was required for Glb1-driven GUS transient expression, and that the –272-bp sequence of the Glb1 promoter was sufficient for ABA-regulated expression of GUS. The longest undeleted sequence used, –1391 GUS, showed relatively low expression which could be indicative of an upstream silencer element in the Glb1 promoter between –1391 and –805. Further studies show that the Glb1-driven GUS activity of bombarded maize P3377 cells increases with increasing ABA concentration (up to 100–300 μm). Site-directed mutagenesis of a putative ABA response element, Em1a, abolished GUS expression in P3377 cells. This observation indicated that the Em1a sequence in the Glb1 5′ regulatory region is responsible for the positive ABA regulation of gene expression. Received: 9 May 1997 / Revision received: 9 November 1997 / Accepted: 8 December 1997     

Identification of trophoblast-specific binding sites for GATA-2 that are essential for rat placental lactogen-I gene expression

We identified a 3.4-kb 5′-flanking region of the rPL-I gene and examined its promoter activity using rat trophoblast Rcho-1 cells. A regulatory element between base pairs (bp) −2,487 and −2,310 in the 5′-flanking region was essential for maximum promoter activity of the rPL-I gene. This regulatory element was further characterized between bp −2,443 to −2,415 and −2,374 to −2,345. Electrophoretic mobility shift analysis showed that the interaction of nuclear extract proteins from differentiated Rcho-1 cells was inhibited by competition with a GATA-like sequence in the promoter, but not by a mutated GATA sequence. Moreover, the promoter activity of 2487 eLuc containing two novel GATA sites was significantly elevated by co-transfection of a GATA-2 expression vector in proliferating Rcho-1 cells. Our results demonstrate that GATA-2 is involved in multiple promoter regions to activate the specific expression of the rPL-I gene in placental tissue. Gon-Sup Kim and Yeoung-Gyu Ko are contributed equally to this work.     

Functional characterization of a cotton late embryogenesis-abundant D113 gene promoter in transgenic tobacco

Previous studies have shown that mRNA and protein encoded by late embryogenesis-abundant (LEA) gene D113 from Gossypium hirsutum L. accumulate at high levels in mature seeds and also in response to abscisic acid (ABA) in young embryo. In this study, we studied the expression of four promoter 5′ deletion constructs (−1383, −974, −578 and −158) of the LEA D113 gene fused to beta-glucuronidase (GUS). GUS activity analysis revealed that the −578 promoter fragment was necessary to direct seed-specific GUS expression in transgenic tobacco plants (Nicotiana tabacum L.). To further investigate the expression pattern of LEA D113 promoter under environmental stresses, 2-week-old transgenic tobacco seedlings were exposed to ABA, dehydration, high salinity and cold treatments. GUS activity in the seedlings was quantified fluorimetrically, and expression was also observed by histochemical staining. An apparent increase in GUS activity was found in plants harboring constructs −1383, −974 and −578 after 24 h of ABA or high-salinity treatments, as well as after 10 days of dehydration. By contrast, only a slight increase was observed in all the three lines after cold treatment. Virtually no change in expression was found in construct −158 in response to dehydration, salinity and cold, but there was a moderate response to ABA, suggesting that the region between −574 and −158 was necessary for dehydration- and salinity-dependent expression, whereas ABA-responsive cis-acting elements might be located in the −158 region of the promoter.     

Isolation of the maize <Emphasis Type="Italic">Zpu1</Emphasis> gene promoter and its functional analysis in transgenic tobacco plants

By screening a genomic library of maize, a 2.2 kb 5′ flanking fragment of Zpu1 gene, encoding the pullulanase-type starch debranching enzyme, was isolated. Promoter fragments of various lengths, including the full 5′ flanking sequence (−2267 to −1) (Z1), a 3′ deletion (−2267 to −513) (Z5) and three 5′ deletions extending to −1943 (Z2), −1143 (Z3) and −516 (Z4) upstream of the translational initiation codon (ATG), were fused to the GUS reporter gene and introduced into tobacco. When these constructs were tested in transgenic tobacco plants, seed-preferred GUS activity was observed in pZ1-transgenic lines. In pZ2-transgenic lines, the GUS activity was not only restricted to seeds, but was also detected in calyxes, petals, stamens and mature leaves. At the same time, negligible GUS activity was detected in roots, stems, young leaves, stigmas and ovaries from the transgenic tobacco plants, which had integrated the full isolated sequence of Zpu1 promoter or its deletions. Deletion analysis indicated that the promoter contained a putative positive cis-regulatory element and the proximal region (−516 to −1) was essential for directing the expression of gus reporter gene. Analysis of GUS activity during the fruit development and seed germination suggested that Zpu1 promoter is active both in starch anabolism and in starch catabolism, which is consistent with the function of the endogenous gene in maize. GUS activity in leaves under light and darkness confirmed that Zpu1 promoter functions in the starch degradation of photosynthetic tissues in the dark phase of the diurnal cycle.     

Functional Characterisation of the Oil Palm Type 3 Metallothionein-like Gene (<Emphasis Type="Italic">MT3-B</Emphasis>) Promoter

In silico analysis showed that the differentially expressed type 3 oil palm metallothionein-like genes MT3-A and MT3-B share at least 11 common putative promoter regulatory elements. The identified motifs include W-boxes, TATCCA element, binding element for cytokinin response regulators and pollen-specific elements. A high degree of conservation was observed in their genomic organisation where the coding regions are divided at two identical positions in both genes by two AT-rich introns. Promoter activity of the MT3-B gene was analysed using a transient assay by bombarding oil palm tissue slices with a β-glucuronidase (GUS) gene construct and a stable reporter assay by analysing GUS expression in transformed Arabidopsis thaliana plants. Transient expression analysis revealed MT3-B promoter activity in oil palm root tissues but not in fruit mesocarp at 12 weeks after anthesis and spear leaves. The T3 homozygous transgenic Arabidopsis plants, harbouring the MT3-B promoter/GUS construct, showed reporter activity in cotyledons and mature leaves with lower expression levels in root tissues. The expression levels in the roots of the T3 homozygous transgenic plants increased five- and 2.5-folds when treated with 80 μM of Zn²⁺ and Fe²⁺, respectively. Altogether, these results indicate that the MT3-A and MT3-B promoter activities may be regulated by a variety of abiotic factors and MT3-B promoter may potentially be manipulated for use in plant genetic engineering for induced synthesis of gene product.     

Pollen-Specific Expression of <Emphasis Type="Italic">Oryza sativa Indica</Emphasis> Pollen Allergen Gene (<Emphasis Type="Italic">OSIPA</Emphasis>) Promoter in Rice and <Emphasis Type="Italic">Arabidopsis</Emphasis> Transgenic Systems

Earlier, a pollen-specific Oryza sativa indica pollen allergen gene (OSIPA), coding for expansins/pollen allergens, was isolated from rice, and its promoter—upon expression in tobacco and Arabidopsis—was found active during the late stages of pollen development. In this investigation, to analyze the effects of different putative regulatory motifs of OSIPA promoter, a series of 5′ deletions were fused to β-glucuronidase gene (GUS) which were stably introduced into rice and Arabidopsis. Histochemical GUS analysis of the transgenic plants revealed that a 1631 bp promoter fragment mediates maximum GUS expression at different stages of anther/pollen development. Promoter deletions to −1272, −966, −617, and −199 bp did not change the expression profile of the pollen specificity. However, the activity of promoter was reduced as the length of promoter decreased. The region between −1567 and −199 bp was found adequate to confer pollen-specific expression in both rice and Arabidopsis systems. An approximate 4-fold increase in the GUS activity was observed in the pollen of rice when compared to that of Arabidopsis. As such, the OSIPA promoter seems promising for generation of stable male-sterile lines required for the production of hybrids in rice and other crop plants.     

Characterization of a pollen-preferential gene, BAN102, from Chinese cabbage

We isolated and characterized a pollen-preferential gene, BAN102, from Chinese cabbage and analyzed the activity of its promoter. There were three or four copies of the BAN102 gene in the Chinese cabbage genome that specifically expressed in pollen and pollen tube. There were 2137 bp of BAN102 genomic clone comprising 186 bp of protein coding region, and 1178 bp of 5′ and 773 bp of 3′ non-coding regions. TATA box were located at 1071 nt of the promoter region while the polyadenylation signal and polyadenylation site were at 1470 and 1486 nt of the 3′ non-coding region. BLAST search of BAN102 sequence showed that coding region of BAN102 gene was the greatest percent similarity with arabinogalactan protein (AGP23) gene from Arabidopsis thaliana. Promoter analysis using GUS gene as a reporter showed that the pollen-specificity of BAN102 resided within the −112 to −44 bp of proximal promoter from the transient expression in tobacco and Chinese cabbage plants.     

Several cis-elements including a palindrome involved in pollen-specific activity of SBgLR promoter

SBgLR (Solanum tuberosum genomic lysine-rich) is a pollen-specific gene cloned from potato (Solanum tuberosum L.). The region from −269 to −9 (The A of translation start site “ATG” as +1) of the SBgLR promoter was identified as critical for gene specific expression in pollen grains. Sequence analysis indicates a palindromic sequence “TTTCTATTATAATAGAAA” in the −227 to −209 region, in which two pollen-specific motifs TTTCT and AGAAA surround a unique putative TATA box. Moreover, nine putative pollen-specific motifs are located in the region between the TATA box and ATG. We placed the −227 to −9 region (reserving the palindrome) and the −222 to −9 region (breaking the palindrome) downstream of the CaMV35S enhancer, respectively, to construct two fusion promoters. Histochemical assays in transgenic plants demonstrated that the region from −222 to −9 is necessary and sufficient for pollen-specific expression of the uidA gene. However, the region of −227 to −9 is incapable of driving GUS expression in pollen grains and parts of vegetative tissues. A series of 5′ deletions from −269 to −9 of SBgLR promoter were constructed. A transient expression assay indicated that the region from the −227 to −9 suppressed gfp gene expression in pollen, and a positive regulatory element was present in the region of −253 to −227. The function of the palindromic sequence as a repressor inhibiting gene expression in pollen was further confirmed by the mutated promoter, breaking the palindrome by substituting its 3′-flanking five base pairs, which resumes the reporter gene expression in mature pollen.     

Isolation and functional analysis of the Catharanthus roseus deacetylvindoline-4-O-acetyltransferase gene promoter

Madagascar periwinkle (Catharanthus roseus) produces many therapeutically valuable terpenoid indole alkaloids (TIAs), such as vinblastine and vincristine derived from the monomers vindoline and catharanthine. Deacetylvindoline-4-O-acetyltransferase (DAT) is a key enzyme for the terminal step of vindoline biosynthesis. In this research, the DAT gene promoter was cloned, sequenced, and analyzed. An approximately 1,773 bp genomic DNA fragment of DAT promoter was obtained. Sequence analysis revealed that DAT promoter contained several potential regulatory elements which were involved in the regulation of gene expression. To investigate its function, the promoter fragments with 5′ deletions and gain-of-function deletions were fused to GUS reporter gene, and their expressions were analyzed by transient expression in C. roseus cell suspensions. The regulatory activity of DAT promoter was identified with fluorescence quantitative assays. Three TGACG motifs and one inverted motif (CGTCA) between −808 and −1,086 bp in the DAT promoter were found to be involved in methyljasmonate signal transduction pathway.     

SNPs of the PSMA6 gene: Investigation of possible association with myocardial infarction and type 2 diabetes mellitus

In our preceding studies, we have identified microsatellite polymorphisms inside the PSMA6 gene and in its 5′ upstream region. Following the observed associations of microsatellite polymorphisms with non-insulin dependent diabetes mellitus and Graves’ disease, we extended the evaluation of PSMA6 genetic variations to cardiovascular disorders and non-insulin dependent diabetes mellitus. New polymorphisms in the promoter region and exon 6 of the gene were identified by direct sequencing of the promoter region and all seven exons of the gene in 30 individuals of the European descent. Two SNPs at positions −110 and −8 from the translation start, in the promoter region and 5′ UTR, respectively, were analyzed. Neither polymorphism was associated with the risk of myocardial infarction. No significant association of the polymorphisms with plasma lipid levels or BMI was observed. A borderline association of both polymorphisms with diastolic blood pressure was observed in the control group. Genotype −8CG was significantly more frequent in type 2 diabetes patients, and haplotype C⁻¹¹⁰/G⁻⁸, compared to C⁻¹¹⁰/G⁻⁸ was associated with a higher risk of NIDDM. The text was submitted by the authors in English.     

Role of the Ring Methyl Groups in Abscisic Acid Activity in Erucic Acid Accumulation in Oilseed Rape (Brassica napus L.)

Modification of the structure of abscisic acid (ABA) has been reported to result in modification of its physiologic activity. In this study we tested the effect of removing methyl groups from the ring and of chirality of ABA on activity in microspore-derived embryos of oilseed rape (Brassica napus L.). The natural (+)-ABA molecule induced growth inhibition and an increase in the amount of erucic acid accumulated in the oil at medium concentrations less than 1 μm. (−)-ABA showed similar effects. Removing the 7′-methyl group resulted in a dramatic decrease in activity: (+)-7′-demethyl-ABA retained some activity as a growth inhibitor; a 10–100 μm concentration of this compound was needed for a response, and (−)-7′-demethyl-ABA was almost completely inactive. Similar effects were observed with regard to elongase activity, which catalyzes erucic acid biosynthesis from oleic acid. Removal of the 8′- and 9′-methyl groups resulted in a more complex response. These compounds all showed intermediate activity; for growth inhibition, the presence of the 9′-methyl was the more important determinant, whereas chirality dominated the response on erucic acid accumulation, with the (+)-enantiomers being more active. Received July 25, 1997; accepted October 31, 1997     

The mannopine synthase promoter contains vectorial cis-regulatory elements that act as enhancers and silencers

A 479-bp bi-directional promoter controls the expression of two genes (mas1′ and mas2′) that encode enzymes for the synthesis of the opine mannopine in plant tissues infected with Agrobacterium tumefaciens. This 5′ regulatory region (mas promoter) contains all the cis-acting elements involved in mediating the complex regulatory properties of these genes in plants. Using different mas promoter regions fused to a minimal 35S promoter (35SΔ108), we found that the regulatory properties of these divergent promoters result from the presence of orientation-dependent negative and positive regulatory regions. Some of these elements have the unusual property of acting as enhancers in one orientation and as silencers in the other. Using electrophoretic mobility shift analysis (EMSA), we showed that the functional mas promoter regions identified by fluorometric and histochemical assays for reporter gene activity in transgenic plants have the ability specifically to bind nuclear protein factors from Nicotiana tabacum, Phaseolus vulgaris, Solanum tuberosum, and Arabidopsis thaliana. Received: 7 May 1999 / Accepted: 5 August 1999