Sucrose-regulated expression of a chimeric potato tuber gene in leaves of transgenic tobacco plants

Patatin is a family of lipid acyl hydrolases that accounts for 30 to 40% of the total soluble protein in potato tubers. Class-I patatin genes encode 98 to 99% of the patatin mRNA in tubers, but are not normally expressed in other tissues. They are not totally tuber-specific; however, since they can be induced to express at high levels in other tissues under conditions of sink limitation or in explants cultured on medium containing elevated levels of sucrose. To examine the evolution of the mechanisms that regulate patatin gene expression, we introduced a chimeric patatin--glucuronidase (GUS) gene containing 2.5 kb of 5 flanking sequence from the Class-I potato patatin gene PS20 into tobacco plants. The construct was not expressed at significant levels in leaves of juvenile plants or plantlets cultured in vitro, but was expressed at high levels in explants cultured on medium containing 0.3 to 0.4 M sucrose. While there were differences in the expression of the chimeric gene between transgenic tobacco and potato plants, the pattern of sucrose induction was very similar. These results suggest that the mechanism that controls patatin gene expression in potato tubers evolved from a widely distributed mechanism in which gene expression is regulated by the level of available photosynthate.     

A detailed study of the regulation and evolution of the two classes of patatin genes in Solanum tuberosum L.

The class-specific expression of patatin genes was investigated by analysing four new patatin genes. A class I patatin gene from cv. Berolina as well as a class I and two class II patatin genes from the monohaploid cultivar AM 80/5793 were isolated and partially sequenced. Sequence comparison indicates rearrangements as the major source for the generation of diversity between the different members of the classes. The expression of single genes was studied in potato plants transformed with chimaeric genes where the putative patatin promoters were fused to the GUS reporter gene. A detailed histochemical analysis reveals that both class I genes are expressed as the previously described class I patatin gene B33 from cv. Berolina [1], i.e. in the starch-containing cells of potato tubers and in sucrose-induced leaves. The class II gene pgT12 shows the same pattern as the previously described class II gene pgT2 [2], i.e. expression in root tips and in the vascular tissue of tubers, whereas no activity was detectable for pgT4. Thus the expression pattern of both classes of genes seems to be stable at least within or even between different cultivars.     

Cis regulatory elements directing tuber-specific and sucrose-inducible expression of a chimeric class I patatin promoter/GUS-gene fusion

Summary The 5-upstream region of the class I patatin gene B33 directs strong expression of the -glucuronidase (GUS) reporter gene in potato tubers and in leaves treated with sucrose. Cis-acting elements affecting specificity and level of expression were identified by deletion analysis in transgenic potato plants. A putative tuber-specific element is located downstream from position –195. Nuclear proteins present in leaf and tuber extracts bind specifically to a conserved AT rich motif within this region. A DNA fragment between –183 and –143, including the binding site is, however, not able to enhance the expression of a truncated 35S promoter from cauliflower mosaic virus. Independent positive elements contributing to a 100-fold increase relative to the basic tuber-specific element are located between –228 and –195; –736 and –509, –930 and –736 and –1512 and –951. Sucrose inducibility is controlled by sequences downstream of position –228, indicating that the tuber-specific and sucrose-inducible elements are in close proximity.     

Xylem-specific expression of a GRP1.8 promoter::4CL gene construct in transgenic tobacco

Lignin is a complex aromatic polymer of vascular plants that provides mechanical strength to the stem and protects cellulose fibres from chemical and biological degradation. 4-Coumarate:CoA ligases (EC 6.2.1.12) are key enzymes for the biosynthetic pathway of monolignols which is an important complex aromatic polymer for lignin biosynthesis and tree growth. Recently, 4-coumarate:CoA ligase has been used as exogenous gene in transgenic plants to genetically modify the lignin biosynthesis pathway. Since most lignin is produced in the vascular cells, a tissue-specific-expressed promoter in the vascular cell would be important and useful to change and modify the content of lignin. Here we report the existence of a promoter of GRP1.8 (the glycine-rich protein 1.8) in Sopho japonica L. (GenBank accession number AF250149) and studies on its function in transgenic tobacco. The promoter activity was analyzed in transgenic tobacco plants by histochemical staining of GUS gene expression driven by a 613-bp sjGRP1.8p promoter sequence. In sjGRP1.8p-GUS transgenic plants, intense GUS staining was detected in the xylem of the stem. To further investigate the regulation of the tissue-specific expression of the 4CL1 gene, we analyzed the activity of the 4CL1 gene which is sense orientated with the sjGRP1.8p promoter in transgenic tobacco. The Pto4CL1 gene was expressed in the stem of transgenic tobacco. The activity of the 4CL1 enzyme was increased 1–2-fold in the stem but not increased in the leaves of transgenic tobacco. In comparison with the control plants, the content of lignin was increased 25% in the stem but there was no increase in the leaves of transgenic tobacco.     

Expression of tandem invertase genes associated with sexual and vegetative growth cycles in potato

The organisation of two invertase genes (invGE and invGF) linked in direct tandem repeat within the potato genome is detailed. The genes exhibit a similar intron/exon structure which differs from previously described plant invertase genes; while intron locations are conserved between the genes, minor differences in exon length are seen. Both genes encode enzymes with putative extracellular location. Biochemical analysis of gene expression showed expression in floral tissues for both genes, with expression of the upstream gene (invGE) also detected in leaf tissue. Promoter sequences from both genes have been fused to the -glucuronidase (GUS) reporter gene (uidA) and transformed into potato. One promoter-GUS reporter construct was also transformed into tobacco. Histochemical analysis of transgenic lines defined specific expression from the downstream (invGF) promoter in potato and tobacco pollen, with expression first detected in the late uninucleate stage of tobacco microspore development. The invGE promoter determined expression in pollen and other floral tissues, but also at lateral nodes in stem, root and tuber. An association of invertase expression with generative tissue, both in vegetative and sexual modes of growth, is indicated.     

Genetic and physical mapping of the patatin genes in potato and tomato

Summary Genes for the major storage protein of potato, patatin, have been mapped genetically and physically in both the potato and tomato genomes. In potato, all patatin genes detected by the cDNA clone pGM01 map to a single locus at the end of the long arm of chromosome 8. By means of pulsed field gel electrophoresis (PFGE) it was possible further to delimit this locus, containing 10–15 copies of the gene, to a maximum size of 1.4 million base pairs. Hybridizations with class-specific clones suggest that the locus is at least partially divided into domains containing the two major types of patatin genes, class I and II. In tomato, patatin-homologous sequences were found to reside at the orthologous locus at the end of chromosome 8. The approximately three copies in tomato were localized by PFGE to a single fragment of 300 kilobases. Whereas the class II-specific 5 promoter sequences reside in tomato at the same locus as the coding sequences, the single class I-specific copy of the 5 promoter sequences was localized on chromosome 3 with no coding sequence attached to it. A clone from this chromosome 3 locus of tomato was isolated and by restriction fragment length polymorphism mapping it could be further shown that a similar class I-specific sequence also exists on chromosome 3 of potato. As in tomato, this copy on chromosome 3 is not linked to a coding sequence for patatin. The results are discussed with respect to genome evolution and PFGE analysis of complex gene families.     

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.     

Organ-specificity and inducibility of patatin class I promoter from potato in transgenic arabidopsis plants

Patatin class I promoter (B33 promoter) is a tissue-specific potato (Solanum tuberosum L.) promoter expressing the patatin gene mainly in tubers. However, it can be induced in other organs by sucrose or light. We compared the activity of this promoter fused with the reporter gene during heterological expression in B33::GUS transgenic arabidopsis (Arabidopsis thaliana L.) plants and homological expression of the same DNA construct in potato. Promoter activity was estimated from quantification of β-glucuronidase (GUS) activity. It was shown that, during heterological expression in arabidopsis seedlings, B33 promoter manifested a tissue-specificity and inducibility, although in a different manner than during homological expression in potato. In noninduced arabidopsis seedlings, B33 promoter was most active in the roots, whereas, after induction with sucrose treatment, it became most active in cotyledons. 10 mM sucrose was sufficient for a manifold activation of B33 promoter in intact seedlings. The degree of B33 promoter induction by sucrose in arabidopsis seedlings was strictly organ-specific and increased in the following sequence: root < hypocotyl < cotyledons. 150–200 mM sucrose enhanced B33 promoter activity in cotyledons by 200 to 300 times, i.e., much stronger than in potato organs. Glucose and fructose were less efficient than sucrose. Phytohormones affecting tuber formation in potato (gibberellins, auxins, and cytokinins) did not affect significantly B33 promoter activity in arabidopsis. A lag period of approximately 6 h preceded sucrose-induced B33 promoter activation. This indicates that the patatin promoter is not the primary target for the sucrose signal. The quantitative examination of heterological expression of patatin class I promoter further clarifies its basic functional characteristics and permits a better prognosis of its behavior after transferring into other plant species.     

Expression of a tuber-specific storage protein in transgenic tobacco plants: demonstration of an esterase activity

A chimaeric gene composed of the 5' upstream region of STLS1, a leaf/stem specifically expressed gene from Solanum tuberosum, and the RNA-coding as well as the 3' downstream region of patatin, the major storage protein of potato tubers, has been transferred into tobacco plants using the Agrobacterium system. The introduction of this gene led to a leaf/stem specific expression of a 42-kd large protein which immunocrossreacts with patatin antiserum. Only low amounts of immunoreacting protein of smaller size could be detected in transgenic tobacco leaves indicating that the patatin protein is fairly stable in this heterologous environment. The size of the protein as well as the size of the RNA detected in transgenic tobacco leaves using a patatin-specific probe indicates that the patatin RNA was accurately processed in both leaf and stem tissue of tobacco. The expression of the patatin gene led to the appearance of a new esterase activity in the transformed tobacco which co-migrated with a protein immunoreacting with patatin antiserum. These data therefore demonstrate that patatin in addition to serving as a storage protein displays an enzymatic activity.     

Sequence-specific interactions of wound-inducible nuclear factors with mannopine synthase 2′ promoter wound-responsive elements

A 318 bp mannopine synthase 2 (mas2) promoter element from the T-DNA of Agrobacterium tumefaciens can direct wound-inducible and root-preferential expression of a linked uidA gene in transgenic tobacco plants. Wound inducibility is further enhanced by sucrose in the medium. Promoter deletion analysis indicated that the sucrose enhancement is conferred by a region extending from –318 to –213. DNase I footprinting indicated that an A/T-rich DNA sequence in this region is protected by tobacco nuclear factors. Regions extending from –103 to +66 and from –213 to –138 directed wound-inducibile expression of a linked uidA gene when placed downstream of a CaMV 35S enhancer or upstream of a truncated (–209) CaMV 35S promoter, respectively. DNase I footprinting analyses indicated that proteins from wounded tobacco leaves specifically bound to three contiguous motifs downstream of the mas2 TATA box. In addition to a common retarded band formed by the upstream wound-responsive element complexed with proteins from either wounded or unwounded tobacco leaves, two unique retarded bands were observed when this element was incubated with protein from wounded leaves. Methylation interference analysis additionally identified an unique motif composed of promoter elements and nuclear factors derived specifically from wounded tobacco leaves. We propose a model to describe the involvement of nuclear factors with mas2 promoter elements in wound-inducible gene expression.     

Analysis of regulatory elements involved in stress-induced and organ-specific expression of tobacco acidic and basic β-1,3-glucanase genes

Infection of tobacco by tobacco mosaic virus (TMV) induces coordinate expression of genes encoding acidic and basic -1,3-glucanase isoforms. These genes are differentially expressed in response to other treatments. Salicylate treatment induces acidic glucanase mRNA to a higher level than basic glucanase mRNA. Ethylene treatment and wounding strongly induce the basic glucanase genes but have little effect on genes encoding the acidic isoforms. Furthermore, the basic glucanase genes are constitutively expressed in roots and lower leaves of healthy plants, whereas the acidic glucanase genes are not. In order to investigate how these expression patterns are established, we fused promoter regions of an acidic and a basic glucanase gene to the -glucuronidase (GUS) reporter gene and examined expression of these constructs in transgenic tobacco plants.A fragment of 1750 bp and two 5-truncated fragments of 650 bp and 300 bp of the acidic glucanase promoter were tested for induction of GUS gene expression after salicylate treatment and TMV infection. Upstream sequences of 1750 bp and 650 bp were sufficient for induction of the reporter gene by salicylate treatment and TMV infection, but the activity of the 300 bp fragment was strongly reduced. The results suggest that the 1750 bp upstream sequence of the acidic glucanase gene contains multiple regulatory elements.For the basic glucanase promoter it is shown that 1476 bp of upstream sequences were able to drive expression in response to TMV infection and ethylene treatment, but no response was found to incision wounding. Furthermore, high GUS activity was found in lower leaves and roots of healthy transgenic plants, carrying the 1476 bp basic glucanase promoter/GUS construct. When the promoter was truncated up to position –446 all activity was lost, indicating that the region between –1476 and –446 of the basic glucanase promoter is necessary for organ-specific and developmentally regulated expression as well as for induced expression in response to infection and other stress treatments.     

Expressed resistance to black shank among tobacco callus cultures

Summary Quantitatively inherited resistance to the black shank pathogen (Phytophthora parasitica var. nicotianae) was expressed among callus tissue cultures of tobacco (Nicotiana). Tissue cultures of genotypes known to posses polygenic mechanisms for black shank resistance expressed that resistance in vitro when challenged by the viable pathogen. Callus of a susceptible cultivar was readily parasitized in culture. Furthermore, single gene resistance to the common pathogen race was also shown to operate in vitro. Nongenetic factors examined did not contribute significantly to the observed differences. Disease expression in vitro appeared to be highly correlated with its expression at the whole plant level.Screening for quantitative disease resistance can be complicated at the whole plant level by variable hostpathogen reactions and by significant genotype × environment interactions. Since quantitatively inherited mechanisms of black shank resistance are expressed in tobacco callus cultures, an in vitro host-pathogen system may be useful in screening tobacco lines for black shank resistance.The research reported in this paper (No. 82-3-6) is in connection with a project of the Kentucky Agr. Exp. Stn., and the paper is published with the approval of the director     

Cotton α-Globulin Promoter: Isolation and Functional Characterization in Transgenic Cotton,Arabidopsis, and Tobacco

Globulins are the most abundant seed storage proteins in cotton and, therefore, their regulatory sequences could potentially provide a good source of seed-specific promoters. We isolated the putative promoter region of cotton -globulin B gene by gene walking using the primers designed from a cotton staged embryo cDNA clone. PCR amplified fragment of 1108 bp upstream sequences was fused to gusA gene in the binary vector pBI101.3 to create the test construct. This was used to study the expression pattern of the putative promoter region in transgenic cotton, Arabidopsis, and tobacco. Histochemical GUS analysis revealed that the promoter began to express during the torpedo stage of seed development in tobacco and Arabidopsis, and during cotyledon expansion stage in cotton. The activity quickly increased until embryo maturation in all three species. Fluorometric GUS analysis showed that the promoter expression started at 12 and 15 dpa in tobacco and cotton, respectively, and increased through seed maturation. The strength of the promoter expression, as reflected by average GUS activity in the seeds from primary transgenic plants, was vastly different amongst the three species tested. In Arabidopsis, the activity was 16.7% and in tobacco it was less than 1% of the levels detected in cotton seeds. In germinating seedlings of tobacco and Arabidopsis, GUS activity diminished until it was completely absent 10 days post imbibition. In addition, absence of detectable level of GUS expression in stem, leaf, root, pollen, and floral bud of transgenic cotton confirmed that the promoter is highly seed-specific. Analysis of GUS activity at individual seed level in cotton showed a gene dose effect reflecting their homozygous or hemizygous status. Our results show that this promoter is highly tissue-specific and it can be used to control transgene expression in dicot seeds.     

Expression of de novo high-lysine α-helical coiled-coil proteins may significantly increase the accumulated levels of lysine in mature seeds of transgenic tobacco plants

We have designed protein molecules based on an -helical coiled-coil structure. These proteins can be tailored to complement nutritionally unbalanced seed meals. In particular, these proteins may contain up to 43% mol/mol of the essential amino acid lysine. Genes encoding such proteins were constructed using synthetic oligonucleotides and the protein stability was tested for in vivo by expression in an Escherichia coli model system. A protein containing 31% lysine and 20% methionine (CP 3-5) was expressed in transgenic tobacco seeds utilizing the seed specific bean phaseolin and soybean -conglycinin promoters. Both promoters provided a level of expression in the mature transgenic tobacco seeds which resulted in a significant increase in the total lysine content of the seeds. Several of these transgenic lines were analyzed for three generations to determine the stability of gene expression. Plants transformed with the soybean -conglycinin promoter/CP 3-5 gene consistently expressed the high-lysine phenotype through three generations. However, expression of the high-lysine phenotype in plants transformed with the bean phaseolin/CP 3-5 was variable. This is the first report of a significant increase in seed lysine content due to the seed-specific expression of a de novo protein sequence.