Transgene Expression in the Vegetative Tissues of Apple Driven by the Vascular-specific rolC and CoYMV Promoters

The ability of the heterologous promoters, rolCP and CoYMVP, to drive expression of the gusA reporter gene in the vegetative tissues of apple (Malus pumila Mill.) has been studied using transgenic plants produced by Agrobacterium-mediated transformation. Replicate plants of each transgenic clone were propagated in soil to a uniform size and samples of leaf, petiole, stem, and root were taken for the measurement of -glucuronidase (GUS) activity by fluorometric assay. The levels of expression were compared with those in tissues of a representative clone containing the CaMV 35S promoter. These quantitative GUS data were related to the copy number of transgene loci assessed by Southern blotting. The CoYMV promoter was slightly more active than the rolC promoter, although both expressed gusA at a lower level than the CaMV 35S promoter. In clones containing the rolC promoter with multiple transgene loci, expression values were generally among the highest or lowest in the range. The precise location of GUS activity in each tissue was identified by staining of whole leaves and tissue sections with a chromogenic substrate. This analysis demonstrated that with both the rolC and CoYMV promoters the reporter gene activity was primarily localised to vascular tissues, particularly the phloem. Our results indicate that both promoters would be suitable to drive the expression of transgenes to combat pests and diseases of apple that are dependent on interaction with the phloem.     

Tissue specific expression of β-glucuronidase gene driven by heterologous promoters in transgenic cauliflower plants

In this paper we compare five heterologous promoters fused to β-glucuronidase gene in their influence on localization of GUS activity in cauliflower (Brassica oleracea var. botrytis) tissues: roots, leaves, petioles and curds. A constitutive promoter CaMV 35S and four tissue specific promoters were used: extAP from rape, PsMTAP from pea, RBCS3CP from tomato and SRS1P from soybean, and introduced into cauliflower seedling explants using Agrobacterium rhizogenes mediated transformation. Quantitative and histochemical GUS assays confirmed tissue specific gus expression. It was found that extAP promoter was the most active in petioles but also caused a significant gus expression in curds. GUS activity was hardly observed in curd and restricted only to its epidermis when PsMTAP promoter drove the gene. RBCS3CP and SRS1P promoters controlled similar expression of the gus gene throughout the plant except for curd where RBCS3CP was almost inactive.     

The Brassica napus extA promoter: a novel alternative promoter to CaMV 35S for directing transgene expression to young stem tissues and load bearing regions of transgenic apple trees (Malus pumila Mill.)

The Brassica napus extensin A gene is highly expressed in root tissue of oilseed rape. In an attempt to identify an effective root-specific promoter for biotechnological applications, we have examined the ability of the –940 extA promoter to drive expression of the gusA reporter gene in the vegetative tissues of apple (Malus pumila Mill cv. Greensleeves). Transgenic apple lines were produced by Agrobacterium tumefaciens-mediated transformation and GUS activity was analysed both quantitatively and qualitatively. The extA promoter was active in all tissues of young plants in all 15 clones examined. However Southern blot data suggested that only a proportion of the population contained the entire promoter and that others had suffered deletions of unknown length. This may have contributed to the variation seen in the quantitative and qualitative expression of GUS. Specific GUS activity was highest in the stems where it approached, and in some clones, exceeded that using the constitutive CaMV 35S promoter. Histochemical analysis confirmed that GUS was localised to tissues involved in structural support of the stem. Staining was particularly intense at nodal junctions where high tensile stress is exerted on the tissues. Maturing phloem tissues showed localisation of expression to the phloem parenchyma cells and phloem fibres. Transverse sections of the root revealed staining of primary procambial tissues including the young endodermis but no staining was seen in the cortex. Although the –940 extA promoter is clearly not root-specific in apple, it is likely to have useful biotechnological applications in tree species.     

Effect of an enhanced CaMV 35S promoter and a fruit-specific promoter on uida gene expression in transgenic tomato plants

Summary Two different promoters, a cauliflower mosaic virus (CaMV) 35S promoter with a 5′-untranslated leader sequence from alfalfa mosaic virus RNA4 (designated as CaMV 35S/AMV) and an E-8 fruit-ripening-specific promoter, were compared to evaluate their effects on expression of the uidA reporter gene in transgenic tomato plants. In order to generate sufficient numbers of transgenic tomato plants, both a reliable regeneration system and an efficient Agrobacterium transformation protocol were developed using 8-d-old cotyledons of tomato (Lycopersicon ecsulentum Mill. cv. Swifty Belle). Two sets of constructs, both derivatives of the binary vector pBI121, were used in transformation of tomato whereby the uidA gene was driven either by the CaMV 35S/AMV or the E-8 fruit-ripening-specific promoter. Southern blot hybridization confirmed the stable integration of the chimeric uidA gene into the tomato genome. Fruit and leaf tissues were collected from T₀ and T₁ plants, and assayed for β-glucuronidase (GUS) enzyme activity. As expected, both vegetative and fruit tissues of transgenic plants carrying the uidA gene under the control of CaMV 35S/AMV showed varying levels of GUS activity, while no expression was observed in vegetative tissues of transgenic plants carrying the uidA gene driven by the E-8 promoter. All fruits from transgenic plants produced with both sets of constructs displayed expression of the uidA gene. However, when this reporter gene was driven by the CaMV 35S/AMV, GUS activity levels were significantly higher than when it was driven by the E-8 fruit-specific promoter. The presence/absence of the uidA gene in T₁ plants segregated in a 3∶1 Mendelian ratio.     

Tissue specificity and expression level of gusA under rolD, mannopine synthase and translation elongation factor 1 subunit a promoters in transgenic Gladiolus plants

Transgenic plants of Gladiolus cv. Jenny Lee were developed that contain the bargusA fusion gene under either the mannopine synthase 2 (mas2), translation elongation factor 1 subunit α (EF-1α), rolD, or the cauliflower mosaic virus 35S (CaMV 35S) promoters. The relative level of gusA expression in leaves of five to ten independently transformed, in-vitro-grown plants representing each promoter was similar for transgenic plants containing the rolD and CaMV 35S promoter and 2.0-fold and 3.3-fold higher than the level for the mas2 and EF-1α promoters, respectively. The maximum level of gusA specific activity by leaves was 135–173 nmol 4-methylumbelliferone (4-MU)/h per milligram protein for plants containing either CaMV 35S or rolD as compared to only 27–38 nmol 4-MU/h per milligram protein for plants with either mas2 or EF-1α. Histochemical staining confirmed the relatively high level of gusA expression throughout the length of the older, 6-cm-long leaves of plants that contained bargusA under rolD, whereas gusA expression was infrequently observed throughout the older leaves of plants containing either the mas2 or EF-1α promoters. In contrast to the older leaves, staining showed that strong gusA expression was frequently observed throughout young leaves of plants with either the mas2, EF-1α, or rolD promoters. Roots of plants with the rolD and EF-1α promoters showed strong gusA expression specifically in 93% and 68%, respectively, of the root tips. Roots of the plants with the mas2 promoter showed strong gusA expression throughout the entire length of the root. Received: 7 May 1998 / Revision received: 1 December 1998 / Accepted: 17 December 1998     

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.     

The effects of promoter on transient expression in conifer cell lines

Summary Protoplasts from suspension cultures of somatic embryos of white spruce (Picea glauca Moench Voss) were electroporated with plasmids containing the chimeric genes for chloramphenicol acetyl transferase (CAT) or -glucuronidase (GUS), under control of one of three promoters. Transient CAT gene expression of approximately equal magnitude resulted when the CAT gene was fused to either the cauliflower mosaic virus (CaMV) 35S promoter or the nopaline synthase (NOS) promoter. When the CAT gene was fused to a tandem repeat CaMV 35S promoter (pPBI-363), CAT enzyme activity compared to NOS or 35S promoters increased up to eightfold (cell line WS-34), and were up to 100-fold greater than control (electroporated without plasmid). Comparatively, protoplasts of black spruce (Picea mariana Mill) and jack pine (Pinus banksiana Lamb.), electroporated with pPBI-363, produced increases in CAT activity compared to control of 90-fold and 70-fold, respectively. White spruce (WS-34) protoplasts were subsequently electroporated with the GUS gene fused to the tandem repeat CaMV 35S promoter. Comparatively, GUS enzyme activity increased up to tenfold compared to GUS fused to a CaMV 35S promoter. The results indicated that transient expression of the CAT and GUS genes was influenced by the type of promoter and cell line used, as well as by electroporation conditions.NRCC No. 30498     

Activation of the Pathogen-Inducible Gst1 Promoter of Potato after Elicitation by Venturia inaequalis and Erwinia amylovora in Transgenic Apple (Malus × Domestica)

Rather than using a constitutive promoter to drive transgenes for resistance against fungal and bacterial diseases in genetic engineering of apple (Malus × domestica) cultivars, a promoter induced only after infection was preferred. The ability of the Pgst1 promoter from potato (Solanum tuberosum L.) to drive expression of the gusA reporter gene was determined in two genotypes of apple: the fruit cultivar Royal Gala and the M.26 rootstock. β-glucuronidase activity in the transgenic lines grown in a growth chamber was determined quantitatively using fluorometric assays and compared to the activity in Cauliflower Mosaic Virus (CaMV) 35S promoter-driven transgenic lines. In both apple genotypes, the Pgst1 promoter exhibited a low level of expression after bacterial and fungal inoculation compared to the level obtained with the PCaMV35S promoter (15% and 8% respectively). The Pgst1 promoter was systematically activated in apple at the site of infection with a fungal pathogen. It was also activated after treatment with salicylic acid, but not after wounding. Taken together, these data show that, although the Pgst1 promoter is less active than the PCaMV35S promoter in apple, its pathogen responsiveness could be useful in driving the expression of transgenes to promote bacterial and fungal disease resistance.     

A maize α-zein promoter drives an endosperm-specific expression of transgene in rice

An alpha-zein promoter isolated from maize containing P-box, E motif sequence TGTAAAGT, opaque-2 box and TATA box was studied for its tissue-specific expression in rice. A 1,098 bp promoter region of alpha-zein gene, fused to the upstream of gusA reporter gene was used for transforming rice immature embryos (ASD 16 or IR 64) via the particle bombardment-mediated method. PCR analysis of putative transformants demonstrated the presence of transgenes (the zein promoter, gusA and hpt). Nineteen out of 37 and two out of five events generated from ASD 16 and IR 64 were found to be GUS-positive. A histological staining analysis performed on sections of mature T₁ seeds revealed that the GUS expression was limited to the endosperm and not to the pericarp or the endothelial region. GUS expression was observed only in the following seed development stages : milky (14–15 DAF), soft dough (17–18 DAF), hard dough (20–23 DAF), and mature stages (28–30 DAF) of zein-gusA transformed (T₀) plants. On the contrary a constitutive expression of GUS was evident in CaMV35S-gusA plants. PCR and Southern blotting analyses on T₁ plants demonstrated a stable integration and inheritance of transgene in the subsequent T₁ generation. GUS assay on T₂ seeds revealed that the expression of gusA gene driven by alpha-zein promoter was stable and tissue-specific over two generations. Results suggest that this alpha-zein promoter could serve as an alternative promoter to drive endosperm-specific expression of transgenes in rice and other cereal transformation experiments.     

Inheritance of gusA and neo genes in transgenic rice

Inheritance of foreign genes neo and gusA in rice (Oryza sativa L. cv. IR54 and Radon) has been investigated in three different primary (T₀) transformants and their progeny plants. T₀ plants were obtained by co-transforming protoplasts from two different rice suspension cultures with the neomycin phosphotransferase II gene [neo or aph (3) II] and the -glucuronidase gene (uidA or gusA) residing on separate chimeric plasmid constructs. The suspension cultures were derived from callus of immature embryos of indica variety IR54 and japonica variety Radon. One transgenic line of Radon (AR2) contained neo driven by the CaMV 35S promoter and gusA driven by the rice actin promoter. A second Radon line (R3) contained neo driven by the CaMV 35S promoter and gusA driven by a promoter of the rice tungro bacilliform virus. The third transgenic line, IR54-1, contained neo driven by the CaMV 35S promoter and gusA driven by the CaMV 35S.Inheritance of the transgenes in progeny of the transgenic rice was investigated by Southern blot analysis and enzyme assays. Southern blot analysis of genomic DNA showed that, regardless of copy numbers of the transgenes in the plant genome and the fact that the two transgenes resided on two different plasmids before transformation, the introduced gusA and neo genes were stably transmitted from one generation to another and co-inherited together in transgenic rice progeny plants derived from self-pollination. Analysis of GUS and NPT II activities in T₁ to T₂ plants provided evidence that inheritance of the gusA and neo genes was in a Mendelian fashion in one plant line (AR2), and in an irregular fashion in the two other plant lines (R3 and IR54-1). Homozygous progeny plants expressing the gusA and neo genes were obtained in the T₂ generation of AR2, but the homozygous state was not found in the other two lines of transgenic rice.     

Differential activation of H+-ATPase genes by an arbuscular mycorrhizal fungus in root cells of transgenic tobacco

In arbuscular mycorrhizas, H⁺-ATPase is active in the plant membrane around arbuscules but absent from plant mutants defective in arbuscule development (Gianinazzi-Pearson et al. 1995, Can J Bot 73: S526–S532). The proton-pumping H⁺-ATPase is encoded by a family of genes in plants. Immunocytochemical studies and promoter-gusA fusion assays were performed in transgenic tobacco (Nicotiana tabacum L.) to determine whether the periarbuscular enzyme activity results from de-novo activation of plant genes by an arbuscular mycorrhizal fungus. The H⁺-ATPase protein was localized in the plant membrane around arbuscule hyphae. The enzyme was absent from non-colonized cortical cells. Regulation of seven H⁺-ATPase genes (pma) was compared in non-mycorrhizal and mycorrhizal roots by histochemical detection of β-glucuronidase (GUS) activity. Two genes (pma2, pma4) were induced in arbuscule-containing cells of mycorrhizal roots but not in non-mycorrhizal cortical tissues or senescent mycorrhiza. It is concluded that de-novo H⁺-ATPase activity in the periarbuscular membrane results from selective induction of two H⁺-ATPase genes, which can have diverse roles in plant-fungal interactions at the symbiotic interface. Received: 23 October 1999 / Accepted: 7 February 2000     

Promoterless gus gene shows leaky β-glucuronidase activity during transformation of tomato with bspA gene for drought tolerance

Transformation of tomato (Lycopersicon esculentum Mill.) was carried out using disarmed Agrobacterium tumefaciens strain EHA 105 harboring a binary vector pBIG-HYG-bspA. The plasmid contains the bspA (boiling stable protein of aspen) gene under the control of a CaMV35S promoter and nopaline synthase (NOS) terminator, hygromycin phosphotransferase gene (hpt) driven by nopaline synthase promoter and polyadenylation signal of Agrobacterium gene7 as terminator and a promoterless gus gene. Very strong β-glucuronidase (GUS) expression was observed in transformed tomato plants but never in non-transformed (control). Since GUS expression was observed only in transformed plants, the possibility of the presence of endogenous GUS enzymes was ruled out. Possibility of false GUS positives was also ruled out because the GUS positive explants reacted positively to polymerase chain reaction (PCR) and PCR-Southern tests carried out for the presence of bspA gene, which indicated the integration of T-DNA in tomato genome. The promoterless GUS expression was hypothesized either due to leaky NOS termination signal of bspA gene or due to different cryptic promoters of plant origin. It was concluded that GUS expression was observed in the putative transgenics either due to the read through mechanism by the strong CaMV35S promoter or due to several cryptic promoters driving the gus gene in different transgenic lines.     

Transient expression of β-glucuronidase in plastids of various plant cells and tissues delivered by a pneumatic particle gun

Chloroplast expression plasmids pTRBCL-GUS (tobaccorbcL promoter-gusA-tobaccorbcL terminator) and pHHU3004 (spinach ‘x gene’ promoter-gusA-spinachrbcL terminator) and a control nuclear expression plasmid pBI221 (CaMV 35S promoter-gusA-NOS terminator) were introduced separately into cultured cells and tissues of tobacco andArabidopsis thaliana, as well as into cultured cells of the lower land plants liverwort and hornwort by a pneumatic particle gun. The pTRBCL-GUS and pHHU3004 plasmids produced many blue spots in the BY-2 cells and the roots ofArabidopsis thaliana, but not in any of the green cells or tissues. The results suggest that the pTRBCL-GUS and pHHU3004 plasmids are expressed more in proplastids and amyloplasts than in chloroplasts. GUS activities of the BY-2 cells bombarded with pTRBCL-GUS and pHHU3004 were insensitive to α-amanitin treatment (10 and 50 μg/ml), while that of the cells with pBI221 greatly decreased by the same treatment. Hence, it is likely that the pTRBCL-GUS and pHHU3004 plasmids were substantially expressed in the proplastids.     

The integrative expression of GUS gene driven by FCP promoter in the seaweed Laminaria japonica (Phaeophyta)

In this study, the background activity of β-glucuronidase (GUS) was analyzed histochemically and fluorometrically in the negative control of Laminaria japonica (Phaeophyta) thalli, showing low level of activity. GUS gene transformation without selectable gene in L. japonica was performed using four different promoters, i.e., Cauliflower mosaic virus 35S promoter (CaMV35S) from cauliflower mosaic virus, ubiquitin promoter (UBI) from maize, adenine-methyl transfer enzyme gene promoter (AMT) from virus in green alga Chlorella, and fucoxanthin chlorophyll a/c-binding protein gene promoter (FCP) from diatom Phaeodactylum tricornutum. The GUS transient activity was determined fluorometrically after bombarding sliced parthenogenetic sporophytes explants, and it was found that the activity resulting from CaMV35S and FCP promoters (in 114.3 and 80.6 pmol MU min⁻¹ (mg protein)⁻¹, respectively) was higher than for the other two promoters. The female gametophytes were bombarded and regenerated parthenogenetic sporophytes. FCP was the only promoter that resulted in detectable GUS chimeric expression activity during histochemical staining and polymerase chain reaction. Results of Southern blot showed that GUS gene was integrated with the L. japonica genome.     

Effects of tissue type and promoter strength on transient GUS expression in sugarcane following particle bombardment

Effects of tissue type and promoter strength on transient GUS expression in the sugarcane (Saccharum spp. hybrids) cultivar NCo 310 were evaluated following microprojectile bombardment of leaf explants. GUS expression was histochemically or fluorometrically measured 48 h after delivery of the uidA gene. High levels of GUS expression were obtained in leaf segments isolated from young, expanding sugarcane leaves cultured for 1, 3, or 6 d prior to bombardment. The promoter derived from the maize ubiquitin 1 gene (Ubi-1) produced significantly more GUS foci and higher GUS activity levels compared to the recombinant Emu, rice actin 1 (Act1), and CaMV 35S promoters. Our transient expression system should facilitate efforts to identify promoters and elements which will regulate desired gene expression patterns in sugarcane and aid in development of an efficient stable transformation system.Abbreviations Act1 rice actin 1 gene - CaMV cauliflower mosaic virus - GUS ß-glucuronidase - Ubi-1 maize ubiquitin 1 gene - uidA GUS gene - X-Glu 5-bromo-4-chloro-3-indoylglucuronide