A functional map of the nopaline synthase promoter

Evaluation of potential impacts on biodiversity of the salt-tolerant transgenic Eucalyptus camaldulensis harboring an RNA chaperonic RNA-Binding-Protein gene derived from common ice plant

We recently reported that a genetic transformation of the RNA-Binding-Protein (McRBP), an RNA chaperone gene derived from common ice plant (Mesembryanthemum crystallinum), alleviated injury and loss of biomass production by salt stress in Eucalyptus camaldulensis in a semi-confined screen house trial. In this study, we assessed the potential environmental impact of the transgenic Eucalyptus in a manner complying with Japanese biosafety regulatory framework required for getting permission for experimental confined field trials. Two kinds of bioassays for the effects of allelopathic activity on the growth of other plants, i.e., the sandwich assay and the succeeding crop assay, were performed for three transgenic lines and three non-transgenic lines. No significant differences were observed between transgenic and non-transgenic plants. No significant difference in the numbers of cultivable microorganisms analyzed by the spread plate method were observed among the six transgenic and non-transgenic lines. These results suggested that there is no significant difference in the potential impact on biodiversity between the transgenic McRBP-E. camaldulensis lines and their non-transgenic comparators.

Safety Assessment of Genetically Modified Feed: Is There Any Difference From Food?

Food security is one of major concerns for the growing global population. Modern agricultural biotechnologies, such as genetic modification, are a possible solution through enabling an increase of production, more efficient use of natural resources, and reduced environmental impacts. However, new crop varieties with altered genetic materials may be subjected to safety assessments to fulfil the regulatory requirements, prior to marketing. The aim of the assessment is to evaluate the impact of products from the new crop variety on human, animal, and the environmental health. Although, many studies on the risk assessment of genetically modified (GM) food have been published, little consideration to GM feedstuff has been given, despite that between 70 to 90% of all GM crops and their biomass are used as animal feed. In addition, in some GM plants such as forages that are only used for animal feeds, the assessment of the genetic modification may be of relevance only to livestock feeding. In this article, the regulatory framework of GM crops intended for animal feed is reviewed using the available information on GM food as the baseline. Although, the majority of techniques used for the safety assessment of GM food can be used in GM feed, many plant parts used for livestock feeding are inedible to humans. Therefore, the concentration of novel proteins in different plant tissues and level of exposure to GM feedstuff in the diet of target animals should be considered. A further development of specific methodologies for the assessment of GM crops intended for animal consumption is required, in order to provide a more accurate and standardized assessment to the GM feed safety.

Engineering synthetic regulatory circuits in plants

Plant synthetic biology is a rapidly emerging field that aims to engineer genetic circuits to function in plants with the same reliability and precision as electronic circuits. These circuits can be used to program predictable plant behavior, producing novel traits to improve crop plant productivity, enable biosensors, and serve as platforms to synthesize chemicals and complex biomolecules. Herein we introduce the importance of developing orthogonal plant parts and the need for quantitative part characterization for mathematical modeling of complex circuits. In particular, transfer functions are important when designing electronic-like genetic controls such as toggle switches, positive/negative feedback loops, and Boolean logic gates. We then discuss potential constraints and challenges in synthetic regulatory circuit design and integration when using plants. Finally, we highlight current and potential plant synthetic regulatory circuit applications.

Quantitative characterization of genetic parts and circuits for plant synthetic biology

Plant synthetic biology promises immense technological benefits, including the potential development of a sustainable bio-based economy through the predictive design of synthetic gene circuits. Such circuits are built from quantitatively characterized genetic parts; however, this characterization is a significant obstacle in work with plants because of the time required for stable transformation. We describe a method for rapid quantitative characterization of genetic plant parts using transient expression in protoplasts and dual luciferase outputs. We observed experimental variability in transient-expression assays and developed a mathematical model to describe, as well as statistical normalization methods to account for, this variability, which allowed us to extract quantitative parameters. We characterized >120 synthetic parts in Arabidopsis and validated our method by comparing transient expression with expression in stably transformed plants. We also tested >100 synthetic parts in sorghum (Sorghum bicolor) protoplasts, and the results showed that our method works in diverse plant groups. Our approach enables the construction of tunable gene circuits in complex eukaryotic organisms.

Evolution of CONSTANS Regulation and Function after Gene Duplication Produced a Photoperiodic Flowering Switch in the Brassicaceae

Environmental control of flowering allows plant reproduction to occur under optimal conditions and facilitates adaptation to different locations. At high latitude, flowering of many plants is controlled by seasonal changes in day length. The photoperiodic flowering pathway confers this response in the Brassicaceae, which colonized temperate latitudes after divergence from the Cleomaceae, their subtropical sister family. The CONSTANS (CO) transcription factor of Arabidopsis thaliana, a member of the Brassicaceae, is central to the photoperiodic flowering response and shows characteristic patterns of transcription required for day-length sensing. CO is believed to be widely conserved among flowering plants; however, we show that it arose after gene duplication at the root of the Brassicaceae followed by divergence of transcriptional regulation and protein function. CO has two close homologs, CONSTANS-LIKE1 (COL1) and COL2, which are related to CO by tandem duplication and whole-genome duplication, respectively. The single CO homolog present in the Cleomaceae shows transcriptional and functional features similar to those of COL1 and COL2, suggesting that these were ancestral. We detect cis-regulatory and codon changes characteristic of CO and use transgenic assays to demonstrate their significance in the day-length-dependent activation of the CO target gene FLOWERING LOCUS T. Thus, the function of CO as a potent photoperiodic flowering switch evolved in the Brassicaceae after gene duplication. The origin of CO may have contributed to the range expansion of the Brassicaceae and suggests that in other families CO genes involved in photoperiodic flowering arose by convergent evolution.

An intergenic region shared by At4g35985 and At4g35987 in Arabidopsis thaliana is a tissue specific and stress inducible bidirectional promoter analyzed in transgenic arabidopsis and tobacco plants

On chromosome 4 in the Arabidopsis genome, two neighboring genes (calmodulin methyl transferase At4g35987 and senescence associated gene At4g35985) are located in a head-to-head divergent orientation sharing a putative bidirectional promoter. This 1258 bp intergenic region contains a number of environmental stress responsive and tissue specific cis-regulatory elements. Transcript analysis of At4g35985 and At4g35987 genes by quantitative real time PCR showed tissue specific and stress inducible expression profiles. We tested the bidirectional promoter-function of the intergenic region shared by the divergent genes At4g35985 and At4g35987 using two reporter genes (GFP and GUS) in both orientations in transient tobacco protoplast and Agro-infiltration assays, as well as in stably transformed transgenic Arabidopsis and tobacco plants. In transient assays with GFP and GUS reporter genes the At4g35985 promoter (P85) showed stronger expression (about 3.5 fold) compared to the At4g35987 promoter (P87). The tissue specific as well as stress responsive functional nature of the bidirectional promoter was evaluated in independent transgenic Arabidopsis and tobacco lines. Expression of P85 activity was detected in the midrib of leaves, leaf trichomes, apical meristemic regions, throughout the root, lateral roots and flowers. The expression of P87 was observed in leaf-tip, hydathodes, apical meristem, root tips, emerging lateral root tips, root stele region and in floral tissues. The bidirectional promoter in both orientations shows differential up-regulation (2.5 to 3 fold) under salt stress. Use of such regulatory elements of bidirectional promoters showing spatial and stress inducible promoter-functions in heterologous system might be an important tool for plant biotechnology and gene stacking applications.

Recombinant protein production in plants: challenges and solutions

In a recent presentation at the 2010 International Association for Plant Biotechnology meeting, Dr. Richard Flavell (Ceres, Malibu, CA, USA) motivated the plant community to act quickly and with purpose to move a multitude of traits into crop plants to improve their productivity. Current progress toward understanding of plants is too slow and will not achieve our communal goal of doubling agricultural productivity by 2050. Major breakthroughs are necessary! Thus, high-throughput methods that couple gene identification and phenotype observations are required to put potential products into the hands of plant breeders to make varieties with good agronomic characteristics that will be approved by the regulatory agencies. These first improved crops must be on the market in the next 10 years, according to Flavell, in order to begin to meet our doubled productivity goals in 30 years. Because it takes approximately 10 years to produce a characterized variety from an identified gene and move it through product development and regulatory approval, we must begin now. Presumably, by employing the techniques in the following -chapters, we can do that.

Agrobacterium rhizogenes-mediated transformation of Prunus as an alternative for gene functional analysis in hairy-roots and composite plants

Resistant rootstocks offer an alternative to pesticides for the control of soil pests. In Prunus spp., resistance loci to root-knot nematodes (RKN) have been mapped and a transformation method is needed to validate candidate genes. Our efforts have focused on the generation of transformed hairy-roots and composite plants appropriate for nematode infection assays. An efficient and reliable method using the A4R strain of Agrobacterium rhizogenes for the transformation of Prunus roots with an Egfp reporter gene is given. The rooting efficiency, depending on the genotypes, was maximal for the interspecific hybrid 253 (Myrobalan plum × almond-peach), susceptible to RKN, that was retained for subsequent studies. From the agro-inoculated cuttings, 72% produced roots, mainly at the basal section of the stem. Transformed roots were screened by microscope detection of Egfp fluorescence and molecular analyses of the integration of the transgene. The absence of residual agrobacteria in the plants was checked by the non-amplification of the chromosomal gene chvH. Egfp was expressed visually in 76% of the rooted plants. Isolated hairy roots in Petri dishes and composite plants (transformed roots and non-transformed aerial part) in soil containers were inoculated with the RKN Meloidogyne incognita. In both cases, root transformation did not affect the ability of the nematodes to develop in the root tissues. Our results showed that isolated hairy-roots can be used to validate candidate genes and the conditions in which composite plants offer a complementary system for studying the function of root genes in physiological conditions of whole plants are discussed.

Approaches for gene targeting and targeted gene expression in plants

Transgenic science and technology are fundamental to state-of-the-art plant molecular genetics and crop improvement. The new generation of technology endeavors to introduce genes 'stably' into 'site-specific' locations and in 'single copy' without the integration of extraneous vector 'backbone' sequences or selectable markers and with a 'predictable and consistent' expression. Several similar strategies and technologies, which can push the development of 'smart' genetically modified plants with desirable attributes, as well as enhance their consumer acceptability, are discussed in this review.

Gene transfer in cereals

Until recently, gene transfer in plants was achieved only by sexual hybridization. Now, in addition, plant genetic manipulation, with the use of both recombinant DNA and protoplast fusion technology, is being applied to an increasing range of plants. The soil bacterium Agrobacterium tumefaciens, with its associated plasmid, is used as a vector for introducing DNA into the genomes of dicotyledonous plants, but it has not proved suitable for cereals. Instead, the direct uptake of plasmid DNA into cereal protoplasts is being used for the transformation of cells in rice, wheat, and maize. Transformation efficiencies, in some cases, are becoming comparable to those obtained in dicotyledons with Agrobacterium. In rice it is now possible to regenerate efficiently whole plants from protoplasts, and this capability may soon be extended to the other cereals. By means of direct interaction of cereal protoplasts with plasmids, coupled with improved procedures for the regeneration of plants from their protoplasts, gene transfer in the cereals is becoming established at the frontiers of recombinant DNA technology.

Identification of an essential upstream element in the nopaline synthase promoter by stable and transient assays

We studied the fine structure of the nopaline synthase (nos) promoter, which is active constitutively in a wide range of plant tissues, by both transient and stable transformation expression analyses. 3' and 5' deletion fragments were linked to form a set of internal deletion and duplication mutants that scanned the nos promoter. These mutated promoters were linked to the gene for the marker chloramphenicol acetyltransferase (CATase) as a means to readily assay promoter strength. The stable transformation analysis revealed the functional importance of an extended CCAAT box region (-97 to -63). Deletion of an upstream region (-112 to -101) containing an octameric repeated element resulted in a reduction in promoter strength by a factor of 30. A further deletion (-119 to -101) disrupted a potential Z-DNA-forming element as well, totally eliminating promoter function. Thus, a 19-base deletion across a repeated octamer and a potential Z-DNA-forming element identifies an essential upstream activator in the nos promoter. Duplication of the upstream element tripled promoter activity. Electroporation-mediated transient analysis was unable to distinguish downstream promoter elements. However, the upstream element behaved similarly in both assays in that deletion of the entire upstream element resulted in no promoter activity and that duplication of the element significantly enhanced the promoter strength.

Cytokinin gene fused with a strong promoter enhances shoot organogenesis and zeatin levels in transformed plant cells

The isopentenyltransferase (ipt) gene associated with cytokinin biosynthesis in plants was cloned from a tumor-inducing plasmid carried by Agrobacterium tumefaciens and placed under the control of promoters of differing activities, the cauliflower mosaic virus 35S promoter and the nopaline synthase promoter. These promoter-gene constructs were introduced into wounded Nicotiana stems, leaf pieces, and cucumber seedlings by A. tumefaciens infection. Shoots were observed in the infection site on all responding genotypes of Nicotiana plants infected with the 35S promoter construct (35S-ipt), whereas only 41% responded similarly to infection with the unmodified gene. Furthermore, shoots were observed 19 days after infection with the 35S-ipt gene but not until 28 to 45 days with the unaltered ipt gene. Shoots were more numerous (>40) on galls incited by 35S-ipt and were up to 6 times taller than shoots induced by the native gene. On Cucumis (cucumber), shoots were observed only on galls incited by the 35S-ipt construct. These galls were on the average 7.5 times larger than those incited by the nopaline synthase promoter construct (NOS-ipt) or the unmodified ipt gene. Zeatin and zeatinriboside concentrations averaged 23 times greater in the 35S-ipt transformed shoots than in ones transformed with the native ipt gene. These results suggest that a more active promoter on the ipt gene can enhance or change the morphogenic potential of transformed plant cells by increasing their endogenous cytokinin levels.

Production of heterologous proteins in plants: strategies for optimal expression

Plants are a promising expression system for the production of heterologous proteins, especially therapeutic proteins. Currently the majority of therapeutic proteins are produced in mammalian cell lines or bacteria. In a few cases insects, yeast and fungi have been developed for production of human proteins. However, these expression systems have limitations in terms of suitability, cost, scalability, purification and post-translational modifications. Therefore, alternative expression systems are being developed in transgenic animals and transgenic plants. Transgenic plants could provide an attractive alternative in terms of low production cost and lower capital investment in infrastructure, and with appropriate post-translational modifications. The potential of plants as an expression host has not been capitalized, primarily due to lower level of expression of transgenes in plants. The present review will evaluate the rate limiting steps of plant expression systems and suggest strategies to optimize protein expression at each of the steps: gene integration, transcription, translation and protein accumulation.

Intronic regulatory elements determine the divergent expression patterns of AGAMOUS-LIKE6 subfamily members in Arabidopsis

The screening of enhancer detector lines in Arabidopsis thaliana has identified genes that are specifically expressed in the sporophytic tissue of the ovule. One such gene is the MADS-domain transcription factor AGAMOUS-LIKE6 (AGL6), which is expressed asymmetrically in the endothelial layer of the ovule, adjacent to the developing haploid female gametophyte. Transcription of AGL6 is regulated at multiple stages of development by enhancer and silencer elements located in both the upstream regulatory region and the large first intron. These include a bipartite enhancer, which requires elements in both the upstream regulatory region and the first intron, active in the endothelium. Transcription of the AGL13 locus, which encodes the other member of the AGL6 subfamily in Arabidopsis, is also regulated by elements located in the upstream regulatory region and in the first intron. There is, however, no overlapping expression of AGL6 and AGL13 except in the chalaza of the developing ovule, as was shown using a dual gene reporter system. Phylogenetic shadowing of the first intron of AGL6 and AGL13 homologs from other Brassicaceae identified four regions of conservation that probably contain the binding sites of transcriptional regulators, three of which are conserved outside Brassicaceae. Further phylogenetic analysis using the protein-encoding domains of AGL6 and AGL13 revealed that the MADS DNA-binding domain shows considerable divergence. Together, these results suggest that AGL6 and AGL13 show signs of subfunctionalization, with divergent expression patterns, regulatory sequences and possibly functions.

The intergenic region of Arabidopsis thaliana cab1 and cab2 divergent genes functions as a bidirectional promoter

Genetic engineering plays a unique role in fundamental plant biology studies and in improving crop traits. These efforts often necessitate introduction and expression of multiple genes using promoters from a very limited repertoire. Current common practice of expressing multiple genes is the repeated use of the same or similar promoters. This practice causes more frequent transgene silencing due to a high degree of sequence homology and a greater chance of rearrangement among repeatedly used promoter sequences. Therefore, availability and use of natural bidirectional promoters to minimize gene silencing and achieve desirable expression pattern of transgenes is a critical issue in the field of plant genetic engineering. Here we describe the use of a single natural bidirectional promoter to drive the expression of two reporter genes in onion epidermal cells and in transgenic tobacco plants. We show that (1) the promoter drives the simultaneous expression of GUS and GFP reporter genes after transient expression and stable transformation, (2) the transcription is equally strong in both directions, (3) immediate upstream regions in each direction control transcription independently from each other, and (4) the reporter genes are expressed in leaves and stems but not in roots, as expected from the fact that the endogenous promoter controls the expression of two photosynthetic genes in Arabidopsis. Hence, use of bidirectional promoters in heterologous background provides a means to express multiple genes in transgenic plants and aids genetic engineering-based crop improvement.

Approaches to achieve high-level heterologous protein production in plants

Plants offer an alternative to microbial fermentation and animal cell cultures for the production of recombinant proteins. For protein pharmaceuticals, plant systems are inherently safer than native and even recombinant animal sources. In addition, post-translational modifications, such as glycosylation, which cannot be achieved with bacterial fermentation, can be accomplished using plants. The main advantage foreseen for plant systems is reduced production costs. Plants should have a particular advantage for proteins produced in bulk, such as industrial enzymes, for which product pricing is low. In addition, edible plant tissues are well suited to the expression of vaccine antigens and pharmaceuticals for oral delivery. Three approaches have been followed to express recombinant proteins in plants: expression from the plant nuclear genome; expression from the plastid genome; and expression from plant tissues carrying recombinant plant viral sequences. The most important factor in moving plant-produced heterologous proteins from developmental research to commercial products is to ensure competitive production costs, and the best way to achieve this is to boost expression. Thus, considerable research effort has been made to increase the amount of recombinant protein produced in plants. This research includes molecular technologies to increase replication, to boost transcription, to direct transcription in tissues suited for protein accumulation, to stabilize transcripts, to optimize translation, to target proteins to subcellular locations optimal for their accumulation, and to engineer proteins to stabilize them. Other methods include plant breeding to increase transgene copy number and to utilize germplasm suited to protein accumulation. Large-scale commercialization of plant-produced recombinant proteins will require a combination of these technologies.

Consistent transcriptional silencing of 35S-driven transgenes in gentian

In this study, no transgenic gentian (Gentiana triflora x Gentiana scabra) plants produced via Agrobacterium-mediated transformation exhibited transgene (GtMADS, gentian-derived MADS-box genes or sGFP, green fluorescent protein) expression in their leaf tissues, despite the use of constitutive Cauliflower mosaic virus (CaMV) 35S promoter. Strikingly, no expression of the selectable marker gene (bar) used for bialaphos selection was observed. To investigate the possible cause of this drastic transgene silencing, methylation-specific sequences were analysed by bisulfite genomic sequencing using tobacco transformants as a control. Highly methylated cytosine residues of CpG and CpWpG (W contains A or T) sites were distinctively detected in the promoter and 5' coding regions of the transgenes 35S-bar and 35S-GtMADS in all gentian lines analysed. These lines also exhibited various degrees of cytosine methylation in asymmetrical sequences. The methylation frequencies in the other transgene, nopaline synthase (NOS) promoter-driven nptII, and the endogenous GtMADS gene coding region, were much lower and were variable compared with those in the 35S promoter regions. Transgene methylation was observed in the bialaphos-selected transgenic calluses expressing the transgenes, and methylation sequences were distributed preferentially around the as-1 element in the 35S promoter. Calluses derived from leaf tissues of silenced transgenic gentian also exhibited transgene suppression, but expression was recovered by treatment with the methylation inhibitor 5-aza-2'-deoxycytidine (aza-dC). These results indicated that cytosine methylation occurs exclusively in the 35S promoter regions of the expressed transgenes during selection of gentian transformants, causing transcriptional gene silencing.

Regeneration and Agrobacterium-mediated transformation of hop (Humulus lupulus L.)

An efficient procedure for direct organogenesis and regeneration of hop (Humulus lupulus L.) was established. For the first time Agrobacterium-mediated genetic transformation of hop (cv. "Tettnanger") was achieved. Shoot internodes from in vitro cultures were identified as the most suitable type of explant for regeneration. Using this type of explant, a shoot-inducing medium was developed that supported direct organogenesis of approximately 50% of the explants. Plantlets were successfully rooted and transferred to the greenhouse. Overall, in less than 6 months hop cultures propagated in vitro were regenerated to plants in the greenhouse. Agrobacterium-mediated genetic transformation was performed with the reporter gene GUS (beta-glucuronidase). The presence and function of transgenes in plants growing in the greenhouse was verified by PCR (polymerase chain reaction) and enzyme assay for GUS activity, respectively. We have obtained 21 transgenic plants from 1,440 explants initially transformed, yielding an overall transformation efficiency of 1.5%.

A novel, two-component system for cell lethality and its use in engineering nuclear male-sterility in plants

Ablation of cells by the controlled expression of a lethal gene can be used to engineer plant traits such as male sterility and disease resistance. However, it may not be possible to achieve sufficient specificity of expression to prevent secondary effects in non-targeted tissues. In this paper we demonstrate that the extracellular ribonuclease, barnase, can be engineered into two complementary fragments, allowing overlapping promoter specificity to be used to enhance targeting specificity. Using a transient system, we first show that barnase can be split into two inactive peptide fragments, that when co-expressed can complement each other to reconstitute barnase activity. When a luciferase reporter gene was introduced into plant cells along with genes encoding both partial barnase peptides, a substantial reduction in luciferase activity was seen. Cytotoxicity of the reconstituted barnase was demonstrated by crossing together parents constitutively expressing each of the barnase fragments, then assaying their progeny for the presence of both partial barnase genes. None of over 300 tomato seeds planted resulted in a viable progeny that inherited both transgenes. When expression of the partial barnase genes was instead targeted to the tapetum, male sterility resulted. All 13 tomato progeny that inherited both transgenes were male sterile, whereas the three progeny inheriting only the N-terminal barnase gene were male fertile. Finally, we describe how male sterility generated by this type of two-component system can be used in hybrid seed production.

Plant-specific promoter sequences carry elements that are recognised by the eubacterial transcription machinery

During evolution the promoter elements from prokaryotes and eukaryotes have developed differently with regard to their sequence and structure, implying that in general a transfer of eukaryotic promoter sequences into prokaryotes will not cause an efficient gene expression. However, there have been reports on the functionality of the 35S promoter from cauliflower mosaic virus (CaMV) in bacteria. We therefore decided to experimentally investigate the capability of plant promoter sequences to direct gene expression in various bacteria. Accordingly, we tested ten different plant-specific promoters from Solanum tuberosum, Nicotiana tabacum, CaMV, Agrobacterium tumefaciens, and A. rhizogenes for their ability to initiate transcription in five different eubacterial species (Escherichia coli, Yersinia enterocolitica, A. tumefaciens, Pseudomonas putida, and Acinetobacter sp. BD413). To monitor the strength of the plant-specific promoters in bacteria we created fusions between these promoters and the coding region of the luciferase genes from Vibrio harveyi and measured the luminescence in the bacteria. Heterologous gene expression was observed in 50% of the combinations analysed. We then mapped the transcription start site caused by one of the plant-specific promoters, the ST-LS1 promoter from S. tuberosum, in these bacterial species. The location of the mapped transcription start site indicated that the sequences of the plant promoter themselves were recognised by the bacterial transcription apparatus. The recognition of plant-specific promoter sequences by the bacterial RNA polymerase was further confirmed by site-directed mutagenesis of the ST-LS1 promoter and the analysis of the effects of the mutations on the strength of gene expression in E. coli. Using these mutants in our reporter assays we could localise the sequences of the ST-LS1 promoter serving as -10 region in E. coli. The results of our study show that promoter sequences are much less specific than is generally assumed. This is of great importance for our knowledge about the evolution of gene expression systems and for the construction of optimised expression vectors.

Localization of a phytochrome-responsive element within the upstream region of pea rbcS-3A

The pea rbcS-3A promoter with a 5' deletion to -166 (-166 rbcS-3A) contains two GT-1-binding sites. Mutational analyses demonstrated that a decrease in affinity for GT-1 correlates with reduced promoter activity. Transcription of -166 rbcS-3A in transgenic etiolated seedlings is induced by red light and suppressed by far-red light, indicating that it contains a phytochrome-responsive element.

Localization of a phytochrome-responsive element within the upstream region of pea rbcS-3A

The pea rbcS-3A promoter with a 5' deletion to -166 (-166 rbcS-3A) contains two GT-1-binding sites. Mutational analyses demonstrated that a decrease in affinity for GT-1 correlates with reduced promoter activity. Transcription of -166 rbcS-3A in transgenic etiolated seedlings is induced by red light and suppressed by far-red light, indicating that it contains a phytochrome-responsive element.

Spacing between GT-1 binding sites within a light-responsive element is critical for transcriptional activity

Dissection of the light-responsive element (LRE) located between -166 and -50 of rbcS-3A from pea has revealed critical spacing requirements between the two GT-1 binding sites for light-responsive transcription. An increase in spacing between the two sites by as little as 2 bp reduces dramatically the rbcS-3A transcript levels in vivo. Mutation of the 10 bp between the binding sites leads to slightly lower transcript levels, as do deletions of either 3 bp or 8 bp. Deletions of 5 bp or 7 bp from between the GT-1 binding sites do not affect rbcS-3A transcript levels; however, a deletion of 10 bp virtually abolishes the activity of this element. These spacing changes within the light-responsive element similarly affect transcription of a divergently oriented and truncated nopaline synthase promoter. Most spacing changes between the two GT-1 binding sites, however, do not impair the binding of GT-1 to this element in vitro. Together with previous observations, these results suggest that the nuclear factor GT-1 may interact with the binding sites in either a productive or nonproductive manner and that GT-1 binding is necessary but not sufficient for light-responsive transcription. We also discuss our results in relation to the observed spacing of similar sequence elements present within other light-responsive promoters.

Ti plasmid-specified chemotaxis of Agrobacterium tumefaciens C58C1 toward vir-inducing phenolic compounds and soluble factors from monocotyledonous and dicotyledonous plants

Twelve phenolic compounds with related structures were analyzed for their ability to act as chemoattractants for Agrobacterium tumefaciens C58C1 and as inducers of the Ti plasmid virulence operons. The results divided the phenolic compounds into three groups: compounds that act as strong vir inducers and are chemoattractants for A. tumefaciens C58C1 harboring the nopaline Ti plasmid pDUB1003 delta 31, but not the isogenic cured strain; compounds that are at best weak vir inducers and are weak chemoattractants for Ti plasmid-harboring and cured A. tumefaciens C58C1; and compounds that are vir noninducers and are also nonattractants. A strong correlation between vir-inducing ability and Ti plasmid requirement for chemotaxis is thus established. In addition, chemical structure rules for vir induction and chemotaxis are outlined. Positive chemotaxis toward root and shoot homogenates from monocotyledonous and dicotyledonous plants was observed. At low extract concentrations, chemotaxis was enhanced by the presence of Ti plasmid. The chemoattractants do not derive from intact cell walls. Lack of attraction is not responsible for the apparent block to monocot transformation by A. tumefaciens.

virA and virG are the Ti-plasmid functions required for chemotaxis of Agrobacterium tumefaciens towards acetosyringone

Octopine and nopaline Ti-plasmids confer upon Agrobacterium tumefaciens C58C1 the ability to respond chemotactically to the vir-inducing phenolic wound exudate, acetosyringone. A. tumefaciens C58C1 containing Ti-plasmids with Tn5 insertions in virB, C, D or E exhibited marked chemotaxis towards acetosyringone. However, Ti-plasmids with mutations in virA or virG were unable to confer the responsive phenotype. Of the cosmid clones pVK219 (virAB) pVK221 (virBGC) pVK225 (virGCDE) and pVK257 (virABGC) mobilized to cured A. tumefaciens C58C1, only pVK257 bestowed acetosyringone chemotaxis. virA and virG are thus required for chemotaxis of A. tumefaciens towards acetosyringone. This suggests a multifunctional role for virA and virG: at low concentrations of acetosyringone they mediate chemotaxis and at higher concentrations they effect vir-induction.

Primary structure of a C-hordein gene from barley

The nucleotide sequence of a 2065 base pair HindIII fragment, containing a gene (lambda hor1-14) belonging to the Hor1 locus in barley, has been determined. The fragment consists of 1044 bp of coding region interrupted by an amber codon at base 481, a 5' non-coding region of 428 bp and a 3' non-coding region with 593 bp. The deduced amino acid sequence of the mature protein (327 amino acids) is characterized by an octapeptide motif PQQPFPQQ which is repeated throughout the peptide chain between a unique 12 amino acid long NH2-terminal and an equally unique 10 amino acid long COOH-terminal end. The proline + glutamine content is 62% and the next three most abundant amino acids are leucine (9%), phenylalanine (8%) and isoleucine (3%). In the 5' non-coding region there is a TATA box at -98 bp from the start methionine. The 3' non-coding region has a polyadenylation signal 76 bp downstream from the TAA stop codon. The deduced amino acid sequences of the NH2- and COOH-terminals of lambda hor1-14 are very similar but not identical to those known from the Edman degradation and carboxypeptidase Y analysis of C-hordein polypeptides. The 3' coding and non-coding region of lambda hor1-14 is closely similar but different in detail to the known C-hordein cDNA clones. One polyadenylation signal is found in lambda hor1-14 whereas two are present in each of the three known C-hordein cDNAs. These differences and the amber codon interrupting the open reading frame indicate that this gene is silent.

Factors affecting the level of kanamycin resistance in transformed sunflower cells

A 230 base pair DNA segment containing the sequences 5' to the 700 to 750 nucleotide (nt) transcript 7' (ORF 3; RF Barker, KB Idler, DV Thompson, JD Kemp 1983 Plant Mol Biol 2: 335-350) of the octopine tumor inducing plasmid pTiA6 has been isolated. This region has (a) 180 base pairs of DNA upstream of the TATA box, (b) the start of RNA synthesis, and (c) the entire 5' untranslated region of the gene. We have fused this presumed promoter fragment to the neomycin phosphotransferase II (NPTII) gene from Tn5 in a plant expression cassette. After recombination into a tumor inducing plasmid delivery plasmid, this cassette confers selectable kanamycin resistance to transformed sunflower cells. Removal of the out-of-frame ATG in the 5' leader sequence of the NPTII gene by two different modifications increased both the levels of NPTII enzyme activity and the ID(50) for kanamycin in the tumor cells. The promoter region of the transcript 7 gene gives levels of kanamycin resistance equivalent to the nopaline synthase promoter and octopine synthase promoter when used in the same constructions and assayed in the same tissues.

Deletion analysis of the mannopine synthase gene promoter in sunflower crown gall tumors and Agrobacterium tumefaciens

We have used deletion mutagenesis to analyze a TR-DNA promoter from the octopine-type Ti plasmid pTiB6806. The promoter for the gene encoding mannopine synthase (mas) was cloned upstream of the bacterial kanamycin-resistance gene neomycin phosphotransferase II (NPT II). Bal31 deletion mutagenesis was used to generate deletion derivatives of the mas/NPTII gene beginning 1353 bp upstream of the initiation of transcription and extending to 120 bp downstream from the mRNA start site. Deletions that left intact 318 bp upstream of transcription initiation had no detectable effect on the ability of tumors harboring the deletion to synthesize correctly initiated mRNA or to grow on the kanamycin analogue G418. Deletion to-138 destroyed the ability of sunflower crown gall tumors to grow on G418 although low levels of the mas/NPTII transcript were detected in one tumor line. Deletions that left only 57 bp upstream of transcription initiation allowed neither growth on G418 nor detectable mas/NPTII synthesis, even though the CCAAT and TATAA homologies were intact. The mas promoter is functional in Agrobacterium tumefaciens and we present data concerning the effects of the Bal31 deletions on the growth of A. tumefaciens on kanamycin.

Functional domains of a T-DNA promoter active in crown gall tumors

Promoter domains required for transcriptional expression of the 780 gene of T-right (pTi15955) were identified by deletion mutagenesis. Accurate quantitation of transcriptional activity of a series of 5' and internal deletion mutants was achieved by using a double gene vector containing a reference 780 gene as an internal standard. Results of the 5' deletions delineated an activator element located between -440 and -229 base pairs (bp) from the start of transcription. Removal of this region resulted in a 100-fold decrease in promoter activity. Two relatively small internal deletion/substitution mutations at positions -74 to -76 and -98 to -112 reduced promoter activity to 38 and 42%, respectively. In most cases large-scale internal deletions (38 to 151 bp) occurring in various locations from positions -12 to -348 bp caused a significant loss in major promoter activity. However, three internal deletions starting at position -37 and extending upstream as far as -153 bp either had little effect on transcriptional activity or resulted in increased activity. Removal of the TATA motif drastically reduced promoter activity to less than 0.1% of the wild type. A minor start of transcription was detected 60 bases upstream from the major transcriptional start site. This minor promoter shares the same activator element as the major promoter for full activity. Deletion and insertion mutations downstream of the minor promoter TATA demonstrated the role of the TATA box in positioning the start of transcription.

Functional domains of a T-DNA promoter active in crown gall tumors

Promoter domains required for transcriptional expression of the 780 gene of T-right (pTi15955) were identified by deletion mutagenesis. Accurate quantitation of transcriptional activity of a series of 5' and internal deletion mutants was achieved by using a double gene vector containing a reference 780 gene as an internal standard. Results of the 5' deletions delineated an activator element located between -440 and -229 base pairs (bp) from the start of transcription. Removal of this region resulted in a 100-fold decrease in promoter activity. Two relatively small internal deletion/substitution mutations at positions -74 to -76 and -98 to -112 reduced promoter activity to 38 and 42%, respectively. In most cases large-scale internal deletions (38 to 151 bp) occurring in various locations from positions -12 to -348 bp caused a significant loss in major promoter activity. However, three internal deletions starting at position -37 and extending upstream as far as -153 bp either had little effect on transcriptional activity or resulted in increased activity. Removal of the TATA motif drastically reduced promoter activity to less than 0.1% of the wild type. A minor start of transcription was detected 60 bases upstream from the major transcriptional start site. This minor promoter shares the same activator element as the major promoter for full activity. Deletion and insertion mutations downstream of the minor promoter TATA demonstrated the role of the TATA box in positioning the start of transcription.

Expression of Agrobacterium tumefaciens T-DNA gene 7 in Xenopus laevis oocytes

The expression of Agrobacterium tumefaciens T-DNA gene 7 was investigated in Xenopus laevis oocytes. Cloned DNA injected into oocytes consisted of T-DNA sequences derived from octopine type Ti plasmid B6-806 and T-DNA attached to plant DNA sequences at the left junction in crown gall tumors. Transcription initiation sites observed in oocytes were similar to those for transcript 7 in crown gall tumors. Quantitative differences in transcription occurred depending on the flanking sequences of the injected clones indicating that sequences upstream of the TATA box of T-DNA gene 7 affect the quantitative expression of this gene in Xenopus oocytes.

A disarmed binary vector from Agrobacterium tumefaciens functions in Agrobacterium rhizogenes : Frequent co-transformation of two distinct T-DNAs

Binary Ti plasmid vector systems consist of two plasmids in Agrobacterium, where one plasmid contains the DNA that can be transferred to plant cells and the other contains the virulence (vir) genes which are necessary for the DNA transfer but are not themselves stably transferred. We have constructed two nononcogenic vectors (pARC4 and pARC8) based on the binary Ti plasmid system of Agrobacterium tumefaciens for plant transformation. Each vector contains the left and right termini sequences from pTiT37. These sequences, which determine the extent of DNA transferred to plant cells, flank unique restriction enzyme sites and a marker gene that functions in the plant (nopaline synthase in pARC4 or neomycin phosphotransferase in pARC8). After construction in vitro, the vectors can be conjugatively transferred from E. coli to any of several Agrobacterium strains containing vir genes. Using A. rhizogenes strain A4 containing the resident Ri plasmid plus a vector with the nopaline synthase marker, we found that up to 50% of the hairy roots resulting from the infection of alfalfa or tomato synthesized nopaline. Thus, vector DNA encoding an unselected marker was frequently co-transferred with Ri plasmid DNA to an alfalfa or a tomato cell. In contrast, the frequency of co-transfer to soybean cells was difficult to estimate because we encountered a high background of non-transformed roots using this species. Up to five copies of the vector DNA between the termini sequences were faithfully transferred and maintained in most cases suggesting that the termini sequences and the vir genes from the Ri and Ti plasmids are functionally equivalent.

Functional analysis of regulatory elements in a plant embryo-specific gene

Previously we demonstrated the expression of a plant embryo-specific gene encoding the alpha' subunit of beta-conglycinin, a seed storage protein of soybean (Glycine max), in transgenic petunia plants. To examine the regulatory elements that control the expression of this embryo-specific gene (Gmg17.1), a series of deletion mutants was made that contain the alpha'-subunit gene flanked in the 5' direction from +14 nucleotides to -8.5 kilobases (kb) relative to the site of transcription initiation. Each of these deletion mutants was introduced into the genome of petunia cells with the help of Ti-plasmid-derived vectors. Petunia plants were regenerated from transformed cells and expression of the introduced soybean gene was examined. When the alpha'-subunit gene was flanked by 159 nucleotides upstream (Gmg17.1 delta-159), the gene was expressed at a low level in immature embryos. When the gene was flanked by 257 nucleotides upstream of the site of transcription initiation (Gmg17.1 delta-257), a high level of expression was obtained. An additional 8 kb of DNA sequence (which includes the sequence GTGGATAG at -560, which is identical to the core enhancer sequence of simian virus 40 and some animal genes) did not significantly increase the level of expression. The increase in expression level between the delta-159 and delta-257 mutants was at least 20-fold. Analysis of the nucleotides between delta-159 and delta-257 reveals four repeats of a 6-base-pair (G + C)-rich sequence (see formula in text). The deletion Gmg17.1 delta-159 contains a single AACCCA sequence. We suggest that the (G + C)-rich repeats play a critical role in determining the level of expression of the transgenic plants.

Light regulation of a SSRubisco-nos chimaeric gene: photoregulatory control sequences from a C3 plant function in cells of a CAM plant

A SSRubisco-nos chimaeric gene has been constructed, in an oncogenic Ti-plasmid vector. A 900bp soybean SSRubisco upstream fragment, carrying CAAT and TATA boxes and transcription initiation point, was fused to the nos coding region, the fusion site being within the 5'-untranslated region. When this chimaeric construct was transferred to Kalanchoe cells, nos expression was shown to be light-regulated. Thus DNA sequences responsible for light-dark control of gene expression are wholly or partly contained within the 900bp soybean SSRubisco upstream region. Moreover, this is the first demonstration that photoregulatory elements in a gene derived from a C3 plant, function in cells of a plant exhibiting the CAM trait.

Transformed cell clones as a tool to study T-DNA integration mediated by Agrobacterium tumefaciens

A large number of tobacco SR1 cell clones transformed by the wild-type Agrobacterium C58 have been analysed for the presence of screenable markers such as tumour morphology, opine synthesis and hormone dependence. Distinct phenotypic classes were observed depending upon whether the cell clones were isolated from primary tumours or were obtained via cocultivation of protoplasts. These classes of tobacco SR1-C58 transformants appear to arise from errors in the Ti plasmid (T-DNA) transfer and integration mechanism itself rather than from subsequent T-DNA rearrangements, since 900 subclones, obtained by recloning a wild-type SR1-C58-transformed cell clone, yielded no variation in the phenotypes. A detailed genomic T-DNA analysis showed the presence of characteristic, abnormally short T-DNAs in the teratoma-forming, Acs- class and also in the Nos- class. The abnormal right border in two Nos- clones ends close to a sequence that resembles the normal T-DNA terminus and lies adjacent to the nos promoter, suggesting that this sequence could have functioned as a recognition site directing these particular T-DNA transfers. On the basis of the phenotypic and genomic blotting data it is clear that the short T-DNAs are characteristic of the cocultivation method. Other phenomena causing phenotypic variation, such as the loss of the T-DNA, and the gradual repression of T-DNA gene expression by methylation, are the main causes of aberrations in primary tumours. Moreover, the physical data suggest that early in the transformation cycle of Agrobacterium a replication step of a preselected T-DNA occurs before integration into the plant genome.

Light regulation of plant gene expression by an upstream enhancer-like element

Light regulates many varied physiological and developmental phenomena during plant growth and differentiation, including the formation of a photosynthetically competent chloroplast from a proplastid. The expression of ribulose 1,5-bisphosphate carboxylase small subunit (rbcS) genes is regulated by light in a development- and tissue-specific manner2,3. In some plant species, phytochrome has been demonstrated to mediate this response, and photoregulation of rbcS expression occurs at least in part at the level of transcription. We have shown previously that a 5'-noncoding fragment (4-973 base pairs (bp) upstream of the messenger RNA cap site) of the pea rbcS ss3.6 gene contains all of the nucleotide sequence information necessary to direct the photoregulated expression of a bacterial chloramphenicol acetyltransferase (cat) gene in tobacco. Consistent with these findings, Morelli et al.11 have shown by deletion analysis of a second rbcS gene promoter, that the sequences required for photoregulated expression of rbcS E9 reside within the 5'-noncoding region. They identified an upstream region of approximately 700 bp needed for maximum transcription but not light-dark regulation, and a region from -35 to -2 bp which included the TATA box and contained the necessary information for light responsiveness. We now demonstrate that regulatory sequences 5' distal to the rbcS ss3.6 TATA box and transcriptional start site not only contain the information necessary for maximum expression, but also confer photoregulation. These upstream regulatory sequences function independently of orientation when fused to their homologous promoter or a heterologous promoter.

Nucleotide sequence of a B1 hordein gene and the identification of possible upstream regulatory elements in endosperm storage protein genes from barley, wheat and maize

The B-hordeins are the major group of prolamin storage proteins in barley (Hordeum vulgare L.) and they are encoded by a small multigene family that is expressed specifically in the developing endosperm. We report the complete nucleotide sequence of a clone of one B-hordein gene (pBHR184). The cloned gene contains no introns and belongs to the B1 sub-family of B-hordein genes. Comparison of the 5'-flanking sequences of pBHR184 with those of related S-rich prolamin genes from wheat shows that several short sequences within 600 bp upstream of the translation initiation codon are strongly conserved. A sequence that is conserved at around -300 bp in the S-rich prolamins is also conserved at similar locations in genes encoding the two major classes of maize prolamin (the Z19 and Z21 zeins) and appears to be unique to prolamin genes. We discuss the possible role of this '-300 element' in the control of gene expression in the developing cereal endosperm.

The 5'-flanking regions of three pea legumin genes: comparison of the DNA sequences

Approximately 1200 nucleotides of sequence data from the promoter and 5'-flanking regions of each of three pea (Pisum sativum L.) legumin genes (legA, legB and legC) are presented. The promoter regions of all three genes were found to be identical including the "TATA box", and "CAAT box', and sequences showing homology to the SV40 enhancers. The legA sequence begins to diverge from the others about 300bp from the start codon, whereas the other two genes remain identical for another 550bp. The regions of partial homology exhibit deletions or insertions and some short, comparatively well conserved sequences. The significance of these features is discussed in terms of evolutionary mechanisms and their possible functional roles. The legC gene contains a region that may potentially form either of two mutually exclusive stem-loop structures, one of which has a stem 42bp long, which suggests that it could be fairly stable. We suggest that a mechanism of switching between such alternative structures may play some role in gene control or may represent the insertion of a transposable element.

Sequence of a pseudogene in the legumin gene family of pea (Pisum sativum L.)

A second legumin gene, denoted psi Leg D, has been located on the pea genomic clone lambda Leg 1, approx. 1.3 Kbases 3' of Leg A, in the same orientation. The complete sequence of psi Leg D shows that it is a pseudogene, having two stop codons near the 5' end of its predicted coding sequence, as well as deletions and frame shift errors when compared to Leg A. No transcripts from this gene could be detected in developing pea seeds. Leg A and psi Leg D are homologous over their coding sequences, and partially homologous in the intron sequences and the immediate 5' flanking sequences. Other flanking sequences of the two genes show no significant homology, apart from the presence of polyadenylation signals 3' to both coding sequences. The introns in the two genes occur in corresponding positions in the sequences, but a deletion in psi Leg D affects the 3' boundary of IVS-2. Hybridisation of psi Leg D to pea genomic DNA suggests that it does not represent a hitherto undetected sub-family of legumin genes.