Expression analysis of four<Emphasis Type="Italic"> Pinus radiata</Emphasis> male cone promoters in the heterologous host<Emphasis Type="Italic"> Arabidopsis</Emphasis>

Four male cone-specific promoters were isolated from the genome of Pinus radiata D. Don, fused to the -glucuronidase (GUS) reporter gene and analysed in the heterologous host Arabidopsis thaliana (L.) Heynh. The temporal and spatial activities of the promoters PrCHS1, PrLTP2, PrMC2 and PrMALE1 during seven anther developmental stages are described in detail. The two promoters PrMC2 and PrMALE1 confer an identical GUS expression pattern on Arabidopsis anthers. DNA sequence analysis of the PrMC2 and PrMALE1 promoters revealed an 88% sequence identity over 276 bp and divergence further upstream (<40% sequence identity). GUS expression driven by a 276-bp PrMALE1 promoter fragment showed the same pattern in Arabidopsis anthers as observed for the full-length PrMALE1 promoter. Within the 276-bp promoter fragment a region of high homology to a previously described 16-bp anther-box was identified. In gain-of-function experiments the putative PrMALE1 anther-box was fused upstream of a 90-bp CaMV 35S minimal promoter, as a single copy in the sense direction and as an inverted repeat. No GUS expression was conferred to Arabidopsis anthers by either of these two constructs. In a loss-of-function experiment a 226-bp PrMALE1 deletion construct, which did not contain the putative PrMALE1 anther-box, still maintained the originally observed PrMALE1 GUS expression pattern. Hence, gain-of-function as well as loss-of-function experiments consistently showed that the putative anther-box of the PrMALE1 promoter is non-functional in the Arabidopsis genetic background. For the analysis of the four full-length pine promoters PrCHS1, PrLTP2, PrMC2 and PrMALE1, transformation vectors based on pCAMBIA2200 and pCAMBIA1302 were used. It will also be demonstrated in this article that sequences within the T-DNA borders of these vectors caused a characteristic histological background expression in Arabidopsis, with staining observed in vascular tissue of leaves, sepals, roots, filaments of stamens and in stems and pistils.Abbreviation GUS -glucuronidaseGenBank accession numbers for the analysed promoters: AF 337656 (PrCHS1), AF 337655 (PrLTP2), AF 337657 (PrMC2) and AF 337658 (PrMALE1).     

Cloning of the promoter region of plasma membrane aquaporin<Emphasis Type="Italic">BnPIP1</Emphasis> from<Emphasis Type="Italic">Brassica napus</Emphasis> and its functional analysis

A 1.6 kb upstream regulatory sequence (GenBank accession no. AF472487) of plasma membrane aquaporinBnPIP1 gene fromBrassica napus was obtained by genomic walking based on ligation-mediated PCR method. Sequence analysis indicated that this fragment contained seed germination specific and vascular specific sequences. The 1.6 kb upstream sequence and various 5′ end deleted sequences were fused withuidA gene and constructed into plant expression vectors which were used for tobacco transformation. GUS histochemical assay showed that the 1.6 kb fragment had high levels of promoter activity and the GUS staining was mainly distributed in vascular systems and tissues with rapid expanding and proliferating cells. Promoter deletion analysis showed that the deletion of -1610 — -1030 bp resulted in a dramatic reduction in GUS activity. It was assumed that there might be cis-acting element(s) existing in this region. Whereas, the region located at -1030 — -902 bp strongly inhibited the expression ofgus and probably contained negative regulatory element(s). The fragment of -902 — -19 bp could also directgus expression at high level.     

Genetic transformation of Eucalyptus globulus using the vascular-specific EgCCR as an alternative to the constitutive CaMV35S promoter

Strong constitutive promoters, such as CaMV35S, are widely used for plant transformation, but undesirable phenotypic changes have been reported when used to drive biotic stress tolerance and/or for modifying lignin content. The promoter of the eucalyptus cinnamoyl CoA reductase (CCR), a key enzyme of the lignin biosynthetic pathway, was shown to be preferentially expressed in vascular tissues both in herbaceous and woody transgenic plants but not eucalyptus. In this work, we transformed Eucalyptus globulus with the EgCCR promoter governing both β-glucuronidase (GUS) and GFP activity patterns. No statistical differences were found between the survival rate and percentage of GUS positive shoots between eucalyptus transformed with either the constitutive CaMV35S or with the EgCCR promoter. The EgCCR transformed plantlets exhibited high GUS expression levels associated with the vascular tissues opening the possibility of targeting vascular-associated traits such as lignin content or vascular pathogen resistance in adult elite plants of eucalyptus while avoiding the undesirable pleiotropic effects caused by strong constitutive promoters.     

The seasonal activity and the effect of mechanical bending and wounding on the PtCOMT promoter in Betula pendula Roth

In this study, 900-bp (signed as p including nucleotides –1 to –886) and partly deleted (signed as dp including nucleotides –1 to –414) COMT (caffeate/5-hydroxyferulate O-methyltransferase) promoters from Populus tremuloides Michx. were fused to the GUS reporter gene, and the tissue-specific expression patterns of the promoters were determined in Betula pendula Roth along the growing season, and as a response to mechanical bending and wounding. The main activity of the PtCOMTp- and PtCOMTdp-promoters, determined by the histochemical GUS assay, was found in the developing xylem of stems during the 8th–13th week and in the developing xylem of roots in the 13th week of the growing season. The GUS expression patterns did not differ among the xylem cell types. The PtCOMT promoter-induced GUS expression observed in phloem fibres suggests a need for PtCOMT expression and thus syringyl (S) lignin synthesis in fibre lignification. However, the PtCOMTdp-promoter induced GUS expression in stem trichomes, which may contribute to the biosynthesis of phenylpropanoid pathway-derived compounds other than lignin. Finally, a strong GUS expression was induced by the PtCOMT promoters in response to mechanical stem bending but not to wounding. The lack of major differences between the PtCOMTp- and PtCOMTdp-promoters suggests that the deleted promoter sequence (including nucleotides −415 to −886) did not contain a significant regulatory element contributing to the GUS expression in young B. pendula trees.     

Effects of the polyubiquitin gene Ubi.U4 leader intron and first ubiquitin monomer on reporter gene expression in Nicotiana tabacum

We have previously shown by RNA gel blot analyses that the tobacco polyubiquitin-encoding gene Ubi.U4 is expressed in a complex pattern during plant development (Genschik et al., 1994). In order to study its tissue-specific expression, we cloned the fragment containing the –263 bp proximal promoter of the gene, the leader intron and the first ubiquitin monomer in front of the reporter GUS gene. Histochemical analyses for GUS activity during tobacco plant development revealed that the gene is expressed at variable amounts in many plant tissues with high levels in metabolically active and/or dividing cells and in the vascular tissues of the plant. We also analysed the expression pattern of constructs in which either the intron or the intron together with the first ubiquitin monomer were deleted. Our results indicate that the ubiquitin leader intron is not only a quantitative determinant of gene expression but may also influence the tissue-specific expression pattern.     

Isolation of the Chinese rose sHSP gene promoter and its differential regulation analysis in transgenic Arabidopsis plants

In our previous study, we identified a Rosa chinensis heat shock protein (HSP) gene, RcHSP17.8, which was induced by abiotic stresses, such as high temperature and osmotic stress. To analyze the expression of RcHSP17.8 and the function of cis-acting elements in the promoter region, a 1,910 bp fragment of the upstream sequence of the RcHSP17.8 translation initiation codon and five promoter deletion fragments were fused to a β-glucuronidase (GUS) report gene. These plasmids were transferred to Arabidopsis thaliana via Agrobacterium. GUS staining was seen in all the organs, especially in the vascular tissues after heat treatment. In transgenic Arabidopsis, GUS expression driven by the full length promoter was significantly higher under heat shock, but no GUS activity was detected under other abiotic stresses. Deletion analysis indicated that the region from −178 to −771 was essential for the promoter’s response to high temperature.     

Isolation and Functional Analysis of the Poplar RbcS Gene Promoter

A tissue-specific promoter, Pt-RbcS, from Populus was isolated and cloned based on alignment of AtRBCS-2B cDNA with genomic Populus sequences. Sequence analysis of Pt-RbcS revealed cis-acting regulatory elements in the promoter region, including an ATCT-motif, BoxI, GAG-motif, I-box, G-box, BoxII, GATA-motif, and TCT-motif, which are involved in light responses. In transgenic tobacco lines carrying the β-glucuronidase (GUS) gene driven by the Pt-RbcS promoter, GUS expression was detected in leaves and stems, but not in roots. Transgenic poplar lines harboring constructs carrying the GUS gene driven by truncated Pt-RbcS promoters revealed distinctive expression patterns for five different promoter constructs. The Pt-RbcS promoter was expressed preferentially in photosynthetic tissues such as leaves and stems. Moreover, deletion analysis of the 1,547 bp Pt-RbcS promoter region revealed that a 927-bp DNA segment is critical for expression of Pt-RbcS in green tissues. Overall, our study suggests that the Pt-RbcS promoter from Populus could be applied to genetically improve the photosynthetic efficiency of woody plants.     

Comparative expression of β-glucuronidase with five different promoters in transgenic carrot (<Emphasis Type="Italic">Daucus carota</Emphasis> L.) root and leaf tissues

Tissue-specific patterns and levels of protein expression were characterized in transgenic carrot plants transformed with the β-glucuronidase (GUS) gene driven by one of five promoters: Cauliflower mosaic virus 35S (35S) and double 35S (D35S), Arabidopsis ubiquitin (UBQ3), mannopine synthase (mas2) from Agrobacterium tumefaciens or the rooting loci promoter (rolD) from A. rhizogenes. Five independently transformed carrot lines of each promoter construct were assessed for GUS activity. In leaves, activity was highest in plants with the D35S, 35S and UBQ3 promoters, while staining was weak in plants with the mas2 promoter, and only slight visual staining was present in the leaf veins of plants containing rolD promoter . Strong staining was seen in the lateral roots, including root tips, hairs and the vascular tissues of plants expressing the 35S, D35S and UBQ3. Lateral roots of plants containing the rolD construct also showed staining in these tissues while the mas2 promoter exhibited heightened staining in the root tips. Relatively strong GUS staining was seen throughout the tap root with all the promoters tested.. When GUS expression was quantified, the UBQ3 promoter provided the highest activity in roots of mature plants, while plants with the D35S and 35S promoter constructs had higher activity in the leaves. Although plants containing the mas2 promoter had higher levels of activity compared to the rolD plants, these two promoters were significantly weaker than D35S, 35S and UBQ3. The potential for utilization of specific promoters to target expression of desired transgenes in carrot tissues is demonstrated.     

Expression of three <Emphasis Type="Italic">Arabidopsis</Emphasis> cytokinin oxidase/dehydrogenase promoter::GUS chimeric constructs in tobacco: response to developmental and biotic factors

Expression patterns of three Arabidopsis thaliana cytokinin oxidase/dehydrogenase promoter::GUS reporter fusions were investigated in tobacco plants. While cytokinin oxidase/dehydrogenase promoter 2 showed no expression in tobacco, the cytokinin oxidase/dehydrogenase promoters 3 and 4 were active in various tissues throughout development of the tobacco. Recently, the 1452 bp promoter region of AtCKX3 was reported as almost inactive in Arabidopsis. In contrast, the 1627 bp DNA fragment preceding the AtCKX3 coding region drove expression of the reporter GUS gene in various tobacco tissues. The promoter was mainly expressed in tobacco leaves and roots during early stages of development but also later in young flower buds as well as in pollen grains. The construct was particularly active before (hypocotyl region) and during (vascular system) lateral root initiation, supporting the idea of an inhibitory role of active cytokinins in the process of root initiation. The cytokinin oxidase/dehydrogenase promoter 4::GUS fusion in tobacco was shown to share some common (but weaker) expression patterns with promoter 3, namely in the leaves and pollen, but also conferred specific expression in tobacco root cap cells and trichomes. In addition, the response of cytokinin oxidase/dehydrogenase promoter::GUS reporter fusions to infection with the leafy gall-forming bacteria Rhodococcus fascians was examined. While an avirulent strain of R. fascians did not induce expression of any of the cytokinin oxidase/dehydrogenase promoters, the cytokinin oxidase/dehydrogenase promoter 3::GUS fusion was specifically induced at the site of infection when plants were challenged with a virulent strain of R. fascians, providing a possible explanation for the lack of significantly elevated cytokinin concentrations in tissues infected with virulent strains of R. fascians.This revised version was published online in August 2005 with some black and white figures replaced by coloured figures.     

The nitrate reductase promoter of birch directs differential reporter gene expression in tissues of transgenic tobacco

A 1535 bp promoter of the nitrate reductase gene (nia) from birch (Betula pendula) and a series of 5′ deletions were fused to the β-glucuronidase (GUS) gene and introduced into Nicotiana plumbaginifolia. In transgenic plants the NR promoter sequences directed strong GUS expression in the root epidermal hair cells, and in phloem cells of leaf and stem vascular tissue. The NR promoter confers also a significant stimulation of the GUS gene expression by nitrate. These findings might indicate that nitrate flow is one of the signals involved into tissue and cell specific expression of the NR promoter GUS fusions. This revised version was published online in June 2006 with corrections to the Cover Date.     

The Triticum aestivum non-specific lipid transfer protein (TaLtp) gene family: comparative promoter activity of six TaLtp genes in transgenic rice

Plant non-specific lipid transfer proteins (nsLTPs) are encoded by a multigene family and support physiological functions, which remain unclear. We adapted an efficient ligation-mediated polymerase chain reaction (LM-PCR) procedure that enabled isolation of 22 novel Triticum aestivum nsLtp (TaLtp) genes encoding types 1 and 2 nsLTPs. A phylogenetic tree clustered the wheat nsLTPs into ten subfamilies comprising 1–7 members. We also studied the activity of four type 1 and two type 2 TaLtp gene promoters in transgenic rice using the β-Glucuronidase reporter gene. The activities of the six promoters displayed both overlapping and distinct features in rice. In vegetative organs, these promoters were active in leaves and root vascular tissues while no β-Glucuronidase (GUS) activity was detected in stems. In flowers, the GUS activity driven by the TaLtp7.2a, TaLtp9.1a, TaLtp9.2d, and TaLtp9.3e gene promoters was associated with vascular tissues in glumes and in the extremities of anther filaments whereas only the TaLtp9.4a gene promoter was active in anther epidermal cells. In developing grains, GUS activity and GUS immunolocalization data evidenced complex patterns of activity of the TaLtp7.1a, TaLtp9.2d, and TaLtp9.4a gene promoters in embryo scutellum and in the grain epicarp cell layer. In contrast, GUS activity driven by TaLtp7.2a, TaLtp9.1a, and TaLtp9.3e promoters was restricted to the vascular bundle of the embryo scutellum. This diversity of TaLtp gene promoter activity supports the hypothesis that the encoded TaLTPs possess distinct functions in planta.     

A seed coat outer integument-specific promoter for Brassica napus

In search for seed coat-specific promoters for canola (Brassica napus), transgenic plants carrying a 2,121 bp fragment of Arabidopsis thaliana At4g12960 promoter (AtGILTpro) fused to the uidA reporter gene (GUS) were generated. Out of 7 independent events in transgenic canola plants raised, 2 exhibited GUS activity exclusively in the outer integument of the seed coat. GUS activity in other tissues was also observed in the remaining five transformants. Therefore, the AtGILT promoter can be used as a canola seed coat outer integument-specific promoter after the generation and selection of desired transformants from several transgenic lines.     

Distinct repressing modules on the distal region of the <Emphasis Type="Italic">SBP2</Emphasis> promoter contribute to its vascular tissue-specific expression in different vegetative organs

The Glycine max sucrose binding protein (GmSBP2) promoter directs vascular tissue-specific expression of reporter genes in transgenic tobacco. Here we showed that an SBP2-GFP fusion protein under the control of the GmSBP2 promoter accumulates in the vascular tissues of vegetative organs, which is consistent with the proposed involvement of SBP in sucrose transport-dependent physiological processes. Through gain-of-function experiments we confirmed that the tissue-specific determinants of the SBP2 promoter reside in the distal cis-regulatory domain A, CRD-A (position −2000 to −700) that is organized into a modular configuration to suppress promoter activity in tissues other than vascular tissues. The four analyzed CRD-A sub-modules, designates Frag II (−1785/−1508), Frag III (−1507/−1237), Frag IV (−1236/−971) and Frag V (−970/−700), act independently to alter the constitutive pattern of −92pSBP2-mediated GUS expression in different organs. Frag V fused to −92pSBP2-GUS restored the tissue-specific pattern of the full-length promoter in the shoot apex, but not in other organs. Likewise, Frag IV confined GUS expression to the vascular bundle of leaves, whereas Frag II mediated vascular specific expression in roots. Strong stem expression-repressing elements were located at positions −1485 to −1212, as Frag III limited GUS expression to the inner phloem. We have also mapped a procambium silencer to the consensus sequence CAGTTnCaAccACATTcCT which is located in both distal and proximal upstream modules. Fusion of either repressing element-containing module to the constitutive −92pSBP2 promoter suppresses GUS expression in the elongation zone of roots. Together our results demonstrate the unusual aspect of distal sequences negatively controlling tissue-specificity of a plant promoter.