In planta analysis of the Agrobacterium tumefaciens T-cyt gene promoter: identification of an upstream region essential for promoter activity in leaf,stem and root cells of transgenic tobacco

The promoter region of the Agrobacterium tumefaciens T-cyt gene was fused to a -glucuronidase (gusA) reporter gene and introduced into tobacco plants. Detection of gusA expression in transgenic F1 progeny revealed that the T-cyt promoter is active in many, if not all, cell types in leaves, stems and roots of fully developed plants. Developmental stage-dependent promoter activity was observed in seedlings. Analysis of 5-deleted promoter fragments showed that sequences located between positions–185 and –139 with respect to the T-cyt translational start codon are essential for T-cyt promoter activity in transfected tobacco protoplasts as well as in transformed tobacco plants.     

Developmental,hormonal, and pathogenesis-related regulation of the tobacco class I β-1,3-glucanase B promoter

The class I -1,3-glucanases are antifungal vacuolar proteins implicated in plant defense that show developmental, hormonal, and pathogenesis-related regulation. The tobacco enzymes are encoded by a small gene family with members derived from ancestors related to the present-day species Nicotiana sylvestris and N. tomentosiformis. We studied the expression in transgenic tobacco plants of a chimeric -glucuronidase (GUS) reporter gene fused to 1.6 kb of upstream sequence of the tobacco class I -1,3-glucanase B (GLB) gene, which is of N. tomentosiformis origin. Expression of the GUS reporter gene and the accumulation of class I -1,3-glucanase and its mRNA showed very similar patterns of regulation. In young seedlings the reporter gene was expressed in the roots. In mature tobacco plants it was preferentially expressed in lower leaves and roots and was induced in leaves by ethylene treatment and by infection with tobacco mosaic virus (TMV). Furthermore, it was down-regulated in cultured leaf discs by combinations of the hormones auxin and cytokinin. Histological studies of GUS activity showed that the GLB promoter shows highly localized expression in roots of seedlings. It is also expressed in a ring of cells around necrotic lesions induced by TMV infection, but not in cells immediately adjacent to the lesions or in the lesions themselves. The results of deletion analyses suggest that multiple positive and negative elements in the GLB promoter regulate its activity. The region from –1452 to –1193 containing two copies of the heptanucleotide AGCCGCC, which is highly conserved in plant-stress and defense-related genes, is necessary for high level expression in leaves. Additional regions important for organ-specific and regulated expression were: –568 to –402 for ethylene induction of leaves; –402 to –211 for expression in lower leaves and cultured leaf discs and for TMV induction of leaves; and –211 to –60 for expression in roots.     

Analysis of kafirin promoter activity in transgenic tobacco seeds

Sequences corresponding to 855 bp of 5 promoter region and the transit peptide from GK.1, a genomic clone encoding a 22 kDa -kafirin seed protein from sorghum, were translationally fused to a cloned -glucuronidase (GUS) coding sequence from uidA and transferred to tobacco via Agrobacterium tumefaciens-mediated transformation. No GUS expression was detectable at any stage of growth in stems or leaves of these plants. However, GUS expression was detected in both embryo and endosperm tissues of resulting tobacco seeds 10–15 days after flowering. Dissected tissues indicate endosperm expression was localized within the bulk endosperm and not within the parenchyma cell layer underlying the integument. These studies also demonstrate that within dissected tobacco embryos, expression from the kafirin promoter was restricted to the mesocotyl region.     

Deletion analysis of a 2S seed storage protein promoter of Brassica napus in transgenic tobacco

The promoter and upstream region of the Brassica napus 2S storage protein napA gene were studied to identify cis-acting sequences involved in developmental seed-specific expression. Fragments generated by successive deletions of the 5 control region of the napA gene were fused to the reporter gene -glucuronidase (GUS). These constructs were used to transform tobacco leaf discs. Analyses of GUS activities in mature seeds from the transformed plants indicated that there were both negatively and positively acting sequences in the napin gene promoter. Deletion of sequences between –1101 and –309 resulted in increased GUS activity. In contrast, deletion of sequences between –309 and –211 decreased the expression. The minimum sequence required for seed-specific expression was a 196 bp fragment between –152 and +44. Further 5 deletion of the fragment to –126 abolished this activity. Sequence comparison showed that a G box-like sequence and two sequence motifs conserved between 2S storage protein genes are located between –148 to –120. Histochemical and fluorometric analysis of tobacco seeds showed that the spatial and developmental expression pattern was retained in the deletion fragments down to –152. However, the expression in tobacco seeds differed from the spatial and temporal expression in B. napus. In tobacco, the napA promoter directed GUS activity early in the endosperm before any visible activity could be seen in the heart-shaped embryo. Later, during the transition from heart to torpedo stages, the main expression of GUS was localized to the embryo. No significant GUS activity was found in either root or leaf.     

Excision of a Ds-like maize transposable element (AcΔ) in a transient assay in Petunia is enhanced by a truncated coding region of the transposable element Ac

Summary The excision of a Ds-like transposable element (Ac) is mediated in trans by the transposable element Ac or its derivatives in Petunia protoplasts cotransfected with two plasmid DNAs. Excision restores the activity of the -glucuronidase (GUS) gene that is otherwise shut off by the presence of Ac in its leader sequence. A transient expression assay (histochemical test) is used to detect the -glucuronidase activity at the protoplast level. The number of blue-stained protoplasts is a measure of the excision frequency. With Ac alone a near-zero background of GUS activity is detected, which is weakly enhanced by the presence, in trans, of either the wild-type Ac or the coding region (ORF_a) transcribed from the 2 promoter of Agrobacterium tumefaciens TR-DNA. A strong enhancement is observed when a truncated Ac coding region, also under the control of the 2 promoter, is supplied in trans. The truncated version has ATG₁₀ at codon 103 in frame with ORF_a and is preceded by 7 out-of-frame ATGs. The assay is quick and well suited for detection of excision frequencies above the value obtained with the wild-type Ac. The presence of empty donor sites following excision can be demonstrated by PCR amplification and direct sequencing of the appropriate DNA fragment.     

Dissection of a pollen-specific promoter from maize by transient transformation assays

We have previously reported the isolation and characterization of a gene (Zm 13) from Zea mays which shows a pollen-specific pattern of expression. Stably transformed tobacco plants containing a reporter gene linked to portions of the Zm 13 5 flanking region show correct temporal and spatial expression of the gene. Here we present a more detailed analysis of the 5 regions responsible for expression in pollen by utilizing a transient expression system. Constructs containing the -glucuronidase (GUS) gene under the control of various sized fragments of the Zm13 5 flanking region were introduced into Tradescantia and Zea mays pollen via high-velocity microprojectile bombardment, and monitored both visually and with a fluorescence assay. The results suggest that sequences necessary for expression in pollen are present in a region from –100 to –54, while other sequences which amplify that expression reside between –260 and –100. The replacement of the normal terminator with a portion of the Zm13 3 region containing the putative polyadenylation signal and site also increased GUS expression. While the –260 to –100 region contains sequences similar to other protein-binding domains reported for plants, the –100 to –54 region appears to contain no significant homology to other known promoter fragments which direct pollen-specific expression. The microprojectile bombardment of Tradescantia pollen appears to be a good test system for assaying maize and possibly other monocot promoter constructs for pollen expression.     

Isolation of the promoter of a root cap expressed pectinmethylesterase gene from Pisum sativum L. (rcpme1) and its use in the study of gene activity

A genomic clone of a pea pectinmethylesterase encoding gene, rcpme1, was isolated; the promoter region was found to include regions of homology to phenylalanine ammonia lyase (PAL) and nodulin gene promoters. Agrobacterium rhizogenes mediated hairy roots were used for rcpme1 expression and functional analysis in pea. Patterns of rcpme1 expression in cultured hairy roots, measured using uidA encoding -glucuronidase (GUS) as a reporter gene, were distinct from patterns which occur in normal pea roots. No reporter gene expression occurred in transgenic Arabidopsis thaliana, whose roots do not produce border cells. Border cell number from transgenic hairy roots expressing rcpme1 anti-sense mRNA under the control of its 2.75 kb 5 flanking sequence was reduced by > 50%. Nodulation genes of Rhizobium leguminosarum were used as a marker to document that roots with reduced production of border cells and other root cap exudates have a corresponding reduction in levels of biologically active signal molecules. Direct measurements were used to confirm that most of the exudate harvested from young, unwounded roots of normal pea plants is derived from the root tip region where rcpme1 is expressed. The potential application of the rcpme1 gene as a molecular marker for root exudate production is discussed.     

The Promoter of a Metallothionein-Like Gene from the Tropical Tree Casuarina Glauca is Active in Both Annual Dicotyledonous and Monocotyledonous Plants

A chimeric gene consisting of the -glucuronidase (gusA) reporter gene under the control of the metallothionein-like promoter cgMT1 from the tropical tree Casuarina glauca was introduced into Nicotiana tabacum via Agrobacterium tumefaciens and into Oryza sativa by particle bombardment. The strongest histochemical staining for GUS activity was observed in the root system of the transgenic plants, and especially in lateral roots. In contrast, a relatively low level of reporter gene expression was seen in the aerial tissues and GUS staining was located mainly in the plant vascular system. The average ratio of GUS activity between root and leaf was found to be 13:1 in tobacco and 1.5:1 in rice. The pattern of cgMT1 promoter activity in floral organs was found to be different in tobacco and rice. High levels of gusA gene expression were detected in the ovules, pollen grains and tapetum, whereas in rice PcgMT1 directs expression to the vascular system of the floral organs. These results suggest that PcgMT1 is potentially useful in molecular breeding to express genes of interest whose products are preferentially needed in roots.     

Far upstream activating promoter regions are responsible for expression of the BnC1 cruciferin gene from Brassica napus

Summary Cruciferin is the major seed storage protein in Brassica napus. As much as 1.9 kbp of the BnC1 cruciferin gene promoter have been sequenced and analyzed. Promoter fragments with 5 deletions from –2500 to –v202 were fused with the ß-glucuronidase reporter gene and used for Nicotiana tabacum transformation. ß-glucuronidase could be specifically expressed in transgenic tobacco seeds under the control of the BnC1 promoter and regulatory elements were found to be dispersed over 1903 bp. An almost 5-fold increase in ß-glucuronidase expression was obtained when the promoter length was increased from –379 to –498, and another 10-fold increase was observed when sequences between –1266 and –1903 were added. Histochemical analysis shows that the region between –844 and –1266 directs the expression of the chimeric gene specifically to the root apical meristem.Abbreviations GUS ß-glucuronidase - MU 4-methyl umbelliferone - MUG 4-methyl-umbelliferyl-ß-D-glucuronide - X-gluc 5-bromo-4-chloro-3-indolyl-ß-D-glucuronide     

Different promoter regions control level and tissue specificity of expression of Agrobacterium rhizogenes rolB gene in plants

Expression of the rolB gene of A. rhizogenes T-DNA triggers root differentiation in transformed plant cells. In order to study the regulation of this morphogenetic gene, the GUS reporter gene was placed under the control of several deleted fragments of the rolB 5 non-coding region: carrot disc transformations and the analysis of transgenic tobacco plants containing these constructions identified the presence of distinct regulatory domains in the rolB promoter. Two regions (located from positions –623 to –471 and from –471 to –341, from the translation start codon) control the level but not the tissue specificity of rolB expression: progressive deletions of the rolB promoter starting from position –1185 to –341, although at different levels, maintained the same pattern of GUS expression — maximal in root meristems and less pronounced in the vascular tissue of aerial organs. Further deletion of 35 bp, from –341 to –306, drastically affected tissue specificity: GUS activity was still clearly detectable in the vascular tissue of the aerial organs while expression in the root meristem was totally suppressed. Analysis of transgenic embryos and seedlings confirmed that distinct promoter domains are responsible for meristematic (root) and differentiated (vascular) expression of rolB. Finally, we present data concerning the effects of plant hormones on the expression of rolB-GUS constructions.     

Promoter analysis of the auxin-regulated tobacco glutathione S-transferase genes Nt103-1 and Nt103-35

We have analysed the promoter regions of two closely related auxin-regulated glutathione S-transferase genes. All active deletion constructs tested showed expression of the reporter gene -glucuronidase (gusA) in root tips of young seedlings and newly developing lateral roots. Auxin treatment greatly enhanced the level of expression. The Nt103-1 promoter region –370/–276 was found to be necessary, at least as a quantitative element to confer auxin-responsiveness to a reporter gene, and sequences responsible for the auxin-responsiveness must be located downstream of –370. The region –651/–370 contains sequence information necessary for uninduced expression. The Nt103-35 promoter manifested its auxin-responsiveness within the –504/–310 region. Electrophoretic mobility shift analysis, using nuclear extracts from tobacco leaves and suspension cells, identified a factor binding to a sequence (ap103, TGAGTCT) at position –560 of the Nt103-1 promoter, which shows homology to the mammalian AP-1 site. A second factor was found to bind a sequence (as103, ATAGCTAAGTGCTTACG) with homology to the CaMV 35S promoter as-1 element. The as103 element is present in both promoters and positioned around –360, so within the region determined to be indispensable for the response to auxin. A third factor was found binding to the –276/–190 region of both promoters. Combined, these data point to the relevance of a 90 bp region for auxin-induced activity of both tobacco genes. The ASF-1 like factor binding to the as103 element within this region might be involved in mediating the auxin response.     

Expression of the rice Osgrp1 promoter-Gus reporter gene is specifically associated with cell elongation/expansion and differentiation

To study the expression and regulation of a rice glycine-rich cell wall protein gene, Osgrpl, transgenic rice plants were regenerated that contain the Osgrpl promoter or its 5 deletions fused with the bacterial -glucuronidase (GUS) reporter gene. We report here a detailed histochemical analysis of the Osgrpl-Gus expression patterns in transgenic rice plants. In roots of transgenic rice plants, GUS expression was specifically located in cell elongation and differentiation regions, and no GUS expression was detectable in the apical meristem and the mature region. In shoots, GUS activity was expressed only in young leaves or in the growing basal parts of developing leaves, and little GUS activity was expressed in mature leaves or mature parts of developing leaves. In shoot apices, GUS activity was detected only in those leaf cells which were starting to expand and differentiate, and GUS expression was not detected in the apical meristem and the young meristematic leaf primordia. GUS activity was highly expressed in the young stem tissue, particularly in the developing vascular bundles and epidermis. Thus, the expression of the Osgrpl gene is closely associated with cell elongation/expansion during the post-mitotic cell differentiation process. The Osgrpl-Gus gene was also expressed in response to wounding and down-regulated by water-stress conditions in the elongation region of roots. Promoter deletion analysis indicates that both positive and negative mechanisms are involved in regulating the specific expression patterns. We propose a simple model for the developmental regulation of the Osgrpl gene expression.     

Spatial and temporal patterns of GUS expression directed by 5′ regions of the Arabidopsis thaliana farnesyl diphosphate synthase genes FPS1 and FPS2

Farnesyl diphosphate synthase (FPS), the enzyme that catalyses the synthesis of farnesyl diphosphate (FPP) from isopentenyl diphosphate (IPP) and dimethylallyl diphosphate (DMAPP), is considered a regulatory enzyme of plant isoprenoid biosynthesis. The promoter regions of the FPS1 and FPS2 genes controlling the expression of isoforms FPS1S and FPS2, respectively, were fused to the -glucuronidase (GUS) reporter gene and introduced into Arabidopsis thaliana plants. The FPS1S:GUS gene is widely expressed in all plant tissues throughout development, thus supporting a role for FPS1S in the synthesis of isoprenoids serving basic plant cell functions. In contrast, the FPS2:GUS gene shows a pattern of expression restricted to specific organs at particular stages of development. The highest levels of GUS activity are detected in flowers, especially in pollen grains, from the early stages of flower development. After pollination, much lower levels of GUS activity are detected in the rest of floral organs, with the exception of the ovary valves, which remain unstained throughout flower development. GUS activity is also detected in developing and mature seeds. In roots, GUS expression is primarily detected at sites of lateral root initiation and in junctions between primary and secondary roots. No GUS activity is detected in root apical meristems. GUS expression is also observed in junctions between primary and secondary stems. Overall, the pattern of expression of FPS2:GUS suggests a role for FPS2 in the synthesis of particular isoprenoids with specialized functions. Functional FPS2 gene promoter deletion analysis in transfected protoplasts and transgenic A. thaliana plants indicate that all the cis-acting elements required to establish the full pattern of expression of the FPS2 gene are contained in a short region extending from positions –111 to +65. The potential regulatory role of specific sequences within this region is discussed.     

Footprinting of the spinach nitrite reductase gene promoter reveals the preservation of nitrate regulatory elements between fungi and higher plants

Nitrite reductase (NiR) is the second enzyme in the nitrate assimilatory pathway reducing nitrite to ammonium. The expression of the NiR gene is induced upon the addition of nitrate. In an earlier study, a 130 bp upstream region of the spinach NiR gene promoter, located between –330 to –200, was shown to be necessary for nitrate induction of -glucuronidase (GUS) expression in tissue-specific manner in transgenic tobacco plant [28]. To further delineate the cis-acting elements involved in nitrate regulation of NiR gene expression, transgenic tobacco plants were generated with 5 deletions in the–330 to –200 region of the spinach NiR gene promoter fused to the GUS gene. Plants with the NiR promoter deleted to –230 showed a considerable increase in GUS activity in the presence of nitrate, indicating that the 30 bp region between –230 to –200 is crucial for nitrate-regulated expression of NiR. In vivo DMS footprinting of the –300 to –130 region of the NiR promoter in leaf tissues from two independent transgenic lines revealed several nitrate-inducible footprints. Footprinting within the –230 to –181 region revealed factor binding to two adjacent GATA elements separated by 24 bp. This arrangement of GATA elements is analogous to cis-regulatory sequences found in the promoters of nitrate-inducible genes of Neurospora crassa, regulated by the NIT2 Zn-finger protein. The –240 to –110 fragment of the NiR promoter, which contains two NIT2 consensus core elements, bound in vitro to a fusion protein comprising the zinc finger domain of the N. crassa NIT2 protein. The data presented here show that nitrate-inducible expression of the NiR gene is mediated by nitrate-specific binding of trans-acting factors to sequences preserved between fungi and higher plants.     

Transgenic white clover. Studies with the auxin-responsive promoter,GH3, in root gravitropism and lateral root development

We report an improved method for white clover (Trifolium repens) transformation usingAgrobacterium tumefaciens. High efficiencies of transgenic plant production were achieved using cotyledons of imbibed mature seed. Transgenic plants were recovered routinely from over 50% of treated cotyledons. Thebar gene and phosphinothricin selection was shown to be a more effective selection system thannptII (kanamycin selection) oraadA (spectinomycin selection). White clover was transformed with the soybean auxin responsive promoter, GH3, fused to the GUS gene (-glucuronidase) to study the involvement of auxin in root development. Analysis of 12 independent transgenic plants showed that the location and pattern of GUS expression was consistent but the levels of expression varied. The level of GH3:GUS expression in untreated plants was enhanced specifically by auxin-treatment but the pattern of expression was not altered. Expression of the GH3:GUS fusion was not enhanced by other phytohormones. A consistent GUS expression pattern was evident in untreated plants presumably in response to endogenous auxin or to differences in auxin sensitivity in various clover tissues. In untreated plants, the pattern of GH3:GUS expression was consistent with physiological responses which are regarded as being auxin-mediated. For the first time it is shown that localised spots of GH3:GUS activity occurred in root cortical tissue opposite the sites where lateral roots subsequently were initiated. Newly formed lateral roots grew towards and through these islands of GH3:GUS expression, implying the importance of auxin in controlling lateral root development. Similarly, it is demonstrated for the first time that gravistimulated roots developed a rapid (within 1 h) induction of GH3:GUS activity in tissues on the non-elongating side of the responding root and this induction occurred concurrently with root curvature. These transgenic plants could be useful tools in determining the physiological and biochemical changes that occur during auxin-mediated responses.     

A novel oxidative stress-inducible peroxidase promoter from sweetpotato: molecular cloning and characterization in transgenic tobacco plants and cultured cells

A strong oxidative stress-inducible peroxidase (POD) promoter was cloned from sweetpotato (Ipomoea batatas) and characterized in transgenic tobacco plants and cultured cells in terms of environmental stress. A POD genomic clone (referred to as SWPA2) consisted of 1824 bp of sequence upstream of the translation start site, two introns (743 bp and 97 bp), and a 1073 bp coding region. SWPA2 had previously been found to encode an anionic POD which was highly expressed in response to oxidative stress. The SWPA2 promoter contained several cis-element sequences implicated in oxidative stress such as GCN-4, AP-1, HSTF, SP-1 reported in animal cells and a plant specific G-box. Employing a transient expression assay in tobacco protoplasts, with five different 5-deletion mutants of the SWPA2 promoter fused to the -glucuronidase (GUS) reporter gene, the 1314 bp mutant deletion mutant showed about 30 times higher GUS expression than the CaMV 35S promoter. The expression of GUS activity in transgenic tobacco plants under the control of the –1314 SWPA2 promoter was strongly induced in response to environmental stresses including hydrogen peroxide, wounding and UV treatment. Furthermore, GUS activity in suspension cultures of transgenic cells derived from transgenic tobacco leaves containing the –1314 bp SWPA2 promoter-GUS fusion was strongly expressed after 15 days of subculture compared to other deletion mutants. We anticipate that the –1314 bp SWPA2 promoter will be biotechnologically useful for the development of transgenic plants with enhanced tolerance to environmental stress and particularly transgenic cell lines engineered to produce key pharmaceutical proteins.     

Tissue-specific regulation of BiP genes: a cis-acting regulatory domain is required for BiP promoter activity in plant meristems

The binding protein BiP is an endoplasmic reticulum (ER)-resident member of the HSP70 stress-related protein family, which is essential for the constitutive function of the ER. In addition to responding to a variety of environmental stimuli, plant BiP exhibits a tissue-specific regulation. We have isolated two soybean BiP genomic clones, designated gsBiP6 and gsBiP9, and different extensions of their 5 flanking sequences were fused to -glucuronidase (GUS) reporter gene and introduced into Nicotiana tabacum by Agrobacterium tumefaciens-mediated transformation. Transgenic plants displayed prominent GUS activity in the vascular bundles of roots and shoots as well as in regions of intense cell division, such as procambial region and apical meristems. Promoter deletion analyses identified two cis-regulatory functional domains that are important for the spatially-regulated activation of BiP expression under normal plant development. While an AT-rich enhancer-like sequence, designated cis-acting regulatory domain 1, CRD1 (–358 to –211, on gsBiP6), activated expression of the BiP minimal promoter in all organs analyzed, BiP promoter activity in meristematic tissues and phloem cells required the presence of a second activating domain, CRD2 (–211 to –80). Apparently, the CRD2 sequence also harbors negative cis-acting elements, because removal of this region caused activation of gsBiP6 promoter in parenchymatic xylem rays. These results suggest that the tissue-specific control of BiP gene expression requires a complex integration of multiple cis-acting regulatory elements on the promoter.