WO2000055338A1 - Sesquiterpenoid synthase genes and their use for influencing bitterness and resistance in plants - Google Patents

Abstract

This invention relates to the use of sesquiterpenoid synthase genes, particularly genes encoding germacrene A synthase, to modulate (i.e. repress, induce or increase) the expression or activity of sesquiterpenoid synthases in plants, so as to directly or indirectly influence taste, the production of sesquiterpene lactones, and/or resistance against insects, nematodes, micro-organisms and vertebrate herbivores in the plant.

Description

Title of the invention

Sesquiterpenoid synthase genes and their use for influencing bitterness and resistance in plants

Field of the invention

This invention relates to the use of sesquiterpenoid synthase genes, particularly genes encoding germacrene A synthase, to modulate (i.e. repress, induce or increase) the expression or activity of sesquiterpenoid synthases in plants, so as to influence sesquiterpenoid production of these plants. More particularly, the invention is directed to the inhibition of sesquiterpenoid synthase expression, reducing the production of sesquiterpene lactones in the plant. Particularly, in crops where these sesquiterpene lactones are associated with a bitter taste, such as chicory (Cichorium intybus L.), the invention can be used to obtain plants or plant parts that are less bitter. More particularly, this is achieved by reducing gene expression of germacrene A synthase by anti-sensing or co-suppression. Other aspects of this invention relate to the use of sesquiterpenoid synthase genes, more particularly genes encoding germacrene A synthase, to obtain increased resistance against insects, nematodes or micro-organisms in plants, to obtain increased formation of sesquiterpene lactones with attractive, e.g. medicinal, properties, and to obtain increased formation of germacrene A derived flavor and fragrance compounds or phytoalexins. This invention also relates to plant cells and plants transformed with one or more transgenes, which results in the modulation of activity of a sesquiterpenoid synthase therein.

All documents cited are incorporated herein by reference. Background of the Invention

The sprouts of chicory (Cichorium intybus ), known as the Belgian endive, are characterized by their slightly bitter taste, which is a limiting factor to its commercial value as food crop. The taproots of chicory, which are even more bitter, were used in former days as a coffee substitute. Because of their bitterness these roots are not very well suited for use as cattle feed and are mainly regarded as a waste product of chicory cultivation. Chicory roots of specific varieties have been demonstrated to be an interesting source for inulin and/or high-fructose syrup for which special extraction procedures have been developed (Perschak and Wolfslehner, Zuckerind. 115(6):466-470, 1990); nevertheless, production of fructose from chicory roots requires the removal of the bitter taste in the course of the extraction procedure.

The bitter constituents of chicory and other vegetables have been associated with sesquiterpene lactones, more particularly the guianolides lactucin, 8- deoxyiactucin and lactupicrin (van Beek et al. J. Agric. Food Chem. 38: 1035- 1038, 1990; Price et al. J. Sci. Food Agric. 53: 185-192, 1990). Other sesquiterpene lactones identified in chicory are eudesmanolides, and germacranolides (Seto et al., Chem. Pharm. Bull. 36:2423-2429,1988). The sesquiterpenoids belong to a very large family of plant products, the terpenoids, which have been associated with a variety of biological functions mainly related to plant-plant, plant-insect and plant-pathogen interactions. The production of terpenoids is based on a common biosynthetic pathway after which specific enzymes or synthases lead to the individual terpenoid structures.

The initial step of this pathway involves the fusion of three molecules of acetyl CoA to produce the C6 compound 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA). HMG-CoA is reduced to mevalonate by HMG-reductase, and mevalonate is in turn phosphorylated by two kinases, mevalonate- and phosphomevalonate kinase, to form 5-pyrophosphomevalonate. Pyrophosphomevalonate decarboxylase then converts the latter into isopentenyl pyrophosphate (IPP), which represents the first "active" isoprene unit or building block. Alternatively, IPP can be produced via the newly discovered mevalonate-independent deoxyxylulose pathway (Rohmer, In Comp. Nat. Prod. Chem. Vol. 2, ed. by D. Cane, Pergamon, 1999). After isomerization of IPP to dimethylallyl pyrophosphate (DMAPP), prenyl pyrophosphate co-substrates are added to this basic unit to form longer chains. Two diphosphorylated building blocks generate geranyl diphosphate (GDP), a linear C10 intermediate, that can be converted into linear or cyclic products representing the monoterpenes. Addition of a third unit of IPP generates farnesyl diphosphate (FDP) from which the sesquiterpenoids are derived. The addition of one more IPP unit generates geranylgeranyl diphosphate (GGDP), the precursor for diterpenes, carotenoids, etc. The conversion of GDP, FDP and GGDP into terpenoid products is realized by monoterpene, sesquiterpene and diterpene synthases respectively, which give rise to stable end products or substrates for other enzymes catalyzing secondary transformations. It is assumed that the sesquiterpene lactones originate from a germacrane precursor that is formed from FDP by a germacrane synthase. The germacrane precursor is further cyclized to either a guiane skeleton (of the guianolides) or a eudesmane skeleton (of the eudesmanolides). This germacrane precursor has recently been identified as (+)-germacrene A (De Kraker et al Plant Physiol. 117: 1381-1392, 1998).

Other vegetables, such as lettuce (Lactuca salva and L. sativa), radicchio (Cichorium intybus), endive (Cichorium endivia), and artichoke (Cynara scolymus) have also been demonstrated to contain sesquiterpene lactones as bitter constituents (Price et al., 1990, above; Herrmann K., Z. Lebensm. Unters. Forsch. 167:262-273, 1967).

Examples of sesquiterpenoids associated with bitter taste are cnicin (from Cnicus benedictus), absinth (from the wormwood, Artemisia absintha ), alantolactone and isoalantolactone (from Inula helenium roots) and helenalin (from sneezeweed, Helenium autumnale) (Fischer N., Methods in Plant Biochemistry 7:187-211 , 1991).

Several sesquiterpenoids have been described to have an anti-feedant activity on herbivorous insects and vertebrate herbivores. Examples of these are tenulin (from Helenium amarum; Arnason et al., Journal of Natural products, 50(4): 690-695, 1987) helenalin (from sneezeweed, Helenium autumnale), parthenin (from Parthenium histerophorus) (Pieman A. and Pieman J., Biochemical systematics and Ecology, 12(1): 89-93, 1984) and linifolin A (Nawrot et al., Prace Naukowe/OR, 24: 27, 1982). Many sesquiterpene lactones have been shown to possess pharmacological [parthenolide from feverfew (Tanacetum parthenium) has an anti-migraine effect (Hewlett et al., Journal of the Chemical Society Perkin Transactions 1, 16: 1979-1986, 1996)], as well as anti-fungal, anti-bacterial, anti-protozoan, schistomicidal and moiluscidal activities (Pieman, Biochemical Systematics and Ecology 14(3): 255-281 , 1978). (-)-Germacrene A has been identified as the alarm pheromone in aphids (Bowers et al., Science 196:680-681 , 1976). Also, germacrene A has been postulated to be an intermediate in the formation of the important flavor compound nootkatone (Croteau and Karp, In Perfumes: art, science and technology, ed. by P.M. Muller and D. Lamparsky, Elsevier Science Publishers LTD, England, 1991), as well as an (enzyme-bound) intermediate in the biosynthesis of phytoalexins such as aristolochene, 5-epi-aristolochene, capsidiol, debneyol, and vetispiradiene (Back and Chappell, J. Biol. Chem. 270(13): 7375-7381 , 1995; Whitehead et al., Phytochemistry 28(3): 775-779, 1989).

The biological structure and known functions of a large number of sesquiterpenoid lactones as well as the different methods by which they can be isolated is described in the review by Fischer (Methods in Plant Biochemistry 7:187-21 1 , 1991 ) .

McGarvey and Croteau (The Plant Cell 7:1015-1026, 1995) give an overview of the biosynthetic pathways of terpenoids and their regulation. Chappel (Annu. Rev. Plant Physiol. Plant Mol. Biol., 46:521-47, 1995) reviews the biochemistry and molecular biology of the isoprenoid biosynthetic pathway in plants. Molecular comparison of a monoterpene, a sesquiterpene and a diterpene synthase demonstrates a strong similarity in gene- organization and in amino acid sequence within domains.

A number of genes involved in sesquiterpenoid biosynthesis have been isolated, of which some examples are given:

Two independent cDNA clones encoding 5-epi-aristolochene synthase (EAS) from tobacco have been isolated and characterized by Facchini and Chappell (Proc Natl Acad. Sci. USA, 89:11088-11092, 1992). The cDNA encoding farnesyl diphosphate synthase was cloned and analyzed for Arabidopsis thaliana by Delourme et al. (Plant Molec. Biol., 26:1867-1873, 1994) and for Artemisia annua by Matsushita et al. (Gene, 172:207-209, 1996). Back and Chappell described the cloning and bacterial expression of vetispiradiene synthase found in Hyoscyamus muticus (1995, above). Molecular comparison of this sequence with that of tobacco EAS displayed identical intron-exon organization of the gene and strong sequence similarities, which is suggested to be reflective of the conservation of several partial reactions common to both enzymes (Back and Chapell, Proc. Natl. Acad. Sci. USA, 93:6841 -6845, 1996).

WO 9715584 describes the use of S-linalool synthase, an acyclic monoterpene synthase, in the genetic engineering of scent production.

The use of the limonene (monoterpene) cyclase in the control of corn rootworm, by inserting a nucleotide sequence coding for limonene cyclase into the plants is described in WO 9637102.

The inactivation of endogenous genes using either sense or anti-sense transgene constructs, has been demonstrated to be successful (Mol, J.N.M. et al., In Homologous recombination and gene silencing in plants, ed. by J. Paszkowski, Kluwer Academic Publishers, the Netherlands, 1994; Hamilton, A.J. et al., Current Topics in Microbiology and Immunology 197, 77-89, 1995; Bourque J., Plant Science, 105:125-149, 1995; Cannon M. et al., Plant Molecular Biology 15:39-47, 1990; Smith C.J.S. et al., Molecular and General Genetics, 224:477-481 , 1990). Also the inactivation of two non-homologous endogenous genes using a single sense gene construct has been reported (Seymour et al., Plant Molecular Biology 23:1 -9, 1993). The inactivation of an endogenous gene using constructs encoding ribozymes targeting endogenous genes is described by Haselhoff and Gerlach (Nature 334:585- 591 , 1988) and in WO 89/05852.

Alternative methods have been described for decreasing endogenous gene expression. For instance, direct modulation of the endogenous gene using the chimeric RNA-DNA oligonucleotide technology. The method is based on the construction of a chimeric RNA-DNA oligonucleotide in duplex conformation with double hairpin caps on the ends, of which the sequence is designed so as to align with the sequence wherein a mutation is targeted and so as to contain the desired nucleotide change and subsequent introduction of the chimeric oligonucleotide in the cell. A detailed description of this method and its efficiency for bringing mutations into endogenous genes is described by Cole-Strauss et al. (Science, 273:1386-1389, 1996) and in patent n° US patent number 5,565,350.

Suppression of endogenous gene activity can also be achieved by introducing transgenes encoding inhibitors of the enzymatic gene product. Modulation of physiological functions using recombinant immunoglobulins is reviewed by Conrad and Fiedler (Plant Mol. Biol. 38:101-109, 1998).

The aim of the present invention is to provide a polynucleic acid sequence encoding a sesquiterpenoid synthase, more particularly a germacrene A synthase.

Another aim of the present invention is to provide a process for producing a plant with modified sesquiterpenoid synthase activity.

Another aim of the present invention is to provide a process for producing a plant or plant parts with an increased content of germacrene A or sesquiterpene lactone metabolites thereof.

Another aim of the present invention is to provide a process for producing a plant or plant parts with reduced bitterness.

Another aim of the present invention is to provide a recombinant polynucleic acid encoding germacrene A synthase. Another aim of the present invention is to provide a plant cell or plant, which is transformed with a recombinant polynucleic acid encoding a molecule having the biological activity of a germacrene A synthase.

Any other method for suppressing, decreasing or inducing endogenous gene expression known to the skilled man is also comprised within the content of this application. Summary of the invention

The present invention relates to an isolated polynucleic acid encoding a protein or polypeptide having the biological activity of a germacrene A synthase. The invention further relates to an isolated DNA sequence encoding a protein or polypeptide with germacrene A synthase activity, having at least 70%, preferably at least 75% or 80%, more preferably at least 85% or 90%, most preferably at least 95%, especially preferably 100% sequence similarity with part or all of the amino acid sequence of SEQ ID NO 7 and/or SEQ ID NO 8, most preferably with the region of AA 271 to 455 of SEQ ID NO 7 or the region of AA 293 to 477 of SEQ ID NO 8. The invention further relates to an isolated polynucleic acid encoding a protein or polypeptide with germacrene A synthase activity, whereby the DNA sequence has at least 70%, preferably at least 75% or 80%, more preferably at least 85% or 90%, most preferably at least 95%, especially preferably 100% sequence similarity with all or part of the DNA sequence of SEQ ID NO 3 or SEQ ID NO 4.

The term "polynucleic acid" refers to DNA or RNA, or amplified versions thereof, or the complement thereof.

The invention further relates to a polynucleic acid encoding a protein or polypeptide having the biological activity of a germacrene A synthase comprising (a) a sequence represented in SEQ ID NO 3 or 4, or,

(b) a sequence hybridizing with a sequence as defined in (a) or,

(c) a sequence which is redundant as a result of the degeneracy of the genetic code to a sequence under (a) or (b), or

(d) a complement of any of the sequences under (a), (b) or (c). The term "hybridizing" refers to hybridization conditions as described in Sambrook (Molecular cloning, a laboratory manual, Cold Spring Harbor Press, 1989, page 7.52), preferably specific or stringent hybridization conditions are used.

The invention further relates to a method of producing germacrene A or sesquiterpene lactones, which method comprises expressing a polynucleic acid having at least 70%, preferably at least 75% or 80%, more preferably at least 85% or 90%, most preferably at least 95% similarity with, especially 100% sequence similarity to the nucleotide sequence of SEQ ID NO 3 and/or SEQ ID NO 4, encoding a polypeptide having the biological activity of a germacrene A synthase, in a suitable host cell, in the presence of famesyl diphosphate, and, optionally, isolating the germacrene A or sesquiterpene lactones thus formed.

The invention further pertains to a recombinant polynucleic acid comprising one or more DNA sequences having at least 70% or 75%, preferably at least

80% or 85%, more preferably at least 90%, most preferably at least 95%, especially preferably 100% sequence similarity to the nucleotide sequence of

SEQ ID NO 3 or SEQ ID NO 4, or the complementary strand thereof, under the control of a plant expressible promoter. Furthermore, the invention pertains to a recombinant polynucleic acid, which is a sesquiterpenoid modulating gene (SMG), comprising one or more polynucleic acid sequences, each under control of a plant-expressible promoter, such as, but not limited to those sequences described above or parts thereof, which when expressed in a cell of a plant either induce, increase or decrease the activity of a sesquiterpenoid synthase, such as germacrene A synthase, in that cell.

The present invention also relates to probes and primers derived from the new germacrene A synthase genes that are useful for instance for the isolation of additional germacrene A synthase genes having sequences which differ from SEQ ID NO 1 to 4 by techniques known in the art, such as PCR cloning.

The term "probe" according to the present invention refers to a single- stranded oligonucleotide which is designed to specifically hybridize to any of the germacrene A synthase polynucleic acids of the invention.

The term "primer" refers to a single stranded oligonucleotide sequence capable of acting as a point of initiation for synthesis of a primer extension product which is complementary to the germacrane synthase A gene nucleic acid strand to be copied. Preferably the primer is about 5-50 nucleotides long. The term "target region" of a probe or a primer according to the present invention is a sequence within the germacrene A synthase polynucleic acid(s) to which the probe or the primer is completely complementary or partially complementary (i.e. with some degree of mismatch). It is to be understood that the complement of said target sequence is also a suitable target sequence in some cases. "Specific hybridization" of a probe to a target region of the germacrene A synthase polynucleic acid(s) means that the probe forms a duplex with part of this region or with the entire region under the experimental conditions used, and that under those conditions this probe does substantially not form a duplex with other regions of the polynucleic acids present in the sample to be analysed.

"Specific hybridization" of a primer to a target region of the germacrene A synthase polynucleic acid(s) means that, during the amplification step, said primer forms a duplex with part of this region or with the entire region under the experimental conditions used, and that under those conditions the primer does not form a duplex with other regions of the polynucleic acids present in the sample to be analysed. It is to be understood that "duplex" as used hereby, means a duplex that will lead to specific amplification. Preferably, the probes of the invention are about 5 to 50 nucleotides long, more preferably from about 10 to 25 nucleotides. Particularly preferred lengths of probes include 10, 11 , 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 , 22, 23, 24 or 25 nucleotides. The nucleotides as used in the present invention may be ribonucleotides, deoxyribonucleotides and modified nucleotides such as inosine or nucleotides containing modified groups which do not essentially alter their hybridization characteristics. Probe and primer sequences are represented throughout the specification as single stranded DNA oligonucleotides from the 5' to the 3' end. It is obvious to the man skilled in the art that any of the below-specified probes can be used as such, or in their complementary form, or in their RNA form (wherein T is replaced by U). For designing probes with desired characteristics, the following useful guidelines known to the person skilled in the art can be applied. The extent and specificity of hybridization reactions such as those described herein are affected by a number of factors, such as degree of complementarity, stability of the probe:target nucleic acid and hybridization conditions including ionic strength, incubation temperature and presence of chemical reagents. Manipulation of one or more of those factors will determine the exact sensitivity and specificity of a particular probe. The importance and effect of various assay conditions are well known to the person skilled in the art. Standard hybridization and wash conditions are disclosed in the Examples section. Other conditions are for instance 3X SSC (Sodium Saline Citrate), 20% deionized FA (Formamide) at 50°C. Other solutions (SSPE (Sodium saline phosphate EDTA), TMAC (Tetramethyl ammonium Chloride), etc.) and temperatures can also be used provided that the specificity and sensitivity of the probes is maintained. When needed, slight modifications of the probes in length or in sequence have to be carried out to maintain the specificity and sensitivity required under the given circumstances.

The invention further encompasses transgenic plants, plant organs, plant tissues or cells, obtained by introducing into their genome a recombinant polynucleic acid comprising one or more DNA sequences having at least 70% or 75%, preferably at least 80% or 85%, more preferably at least 90%, most preferably at least 95%, especially preferably 100% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or the complementary strand thereof, each under the control of a plant expressible promoter.

Furthermore, the invention pertains to a recombinant polynucleic acid, which is a sesquiterpenoid modulating gene (SMG), comprising one or more polynucleic acid sequences, each under control of a plant-expressible promoter, such as, but not limited to those sequences described above or parts thereof, which when expressed in a cell of a plant either induce, increase or decrease the activity of a sesquiterpenoid synthase, such as germacrene A synthase in that cell.

The invention further encompasses transgenic plants, plant organs, plant tissues or cells, obtained by introducing into their genome a recombinant polynucleic acid comprising one or more DNA sequences having at least 70% or 75%, preferably at least 80% or 85%, more preferably at least 90%, most preferably at least 95%, especially preferably 100% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or the complementary strand thereof, each under control of a plant expressible- promoter. The invention further encompasses transgenic plants, plant organs, plant tissues or cells, having modified sesquiterpenoid synthase activity, due to the presence in their genome of one or more transgenes which, when expressed inhibit the activity of a sesquiterpenoid synthase, such as a germacrene A synthase, or another enzyme involved in the biosynthesis of sesquiterpenoids in plants. For instance, such enzymes can be enzymes involved further down in the biosynthesis pathway of the sesquiterpene lactone biosynthesis, such as those responsible for the hydroxylation of germacrene A, the formation of the lactone ring and biosynthesis of costunolide (Fransen et al., 1999, Poster abstracts of the '99 BIOTRANS meeting, 26/9-1/10, Taormina, Sicily, Italy, p. 76; De Kraker et al., 2000, Poster presentation at the 10th Symposium ALW discussion group on Secondary Metabolism in Plant and Plant Cell, Feb. 11 , Amsterdam, The Netherlands)

The invention further encompasses transgenic plants, plant organs, plant tissues or cells, having modified taste or pathogen resistance due to the presence in their genome of one or more transgenes which, when expressed inhibit the activity of a sesquiterpenoid synthase, such as a germacrene A synthase, or other enzymes involved in the biosynthesis of sesquiterpenoid lactones from germacrene A.

The invention further encompasses transgenic plants, plant organs, plant tissues or cells, having modified taste or pathogen resistance due to the presence in their genome of one or more transgenes which, when expressed induce or increase the activity of a sesquiterpenoid synthase, such as a germacrene A synthase, or other enzymes involved in the biosynthesis of sesquiterpenoid lactones from germacrene A.

The invention further encompasses transgenic plants, plant organs, plant tissues or cells, having modified sesquiterpene lactone production due to the presence in their genome of one or more transgenes which, when expressed induce or increase the activity of a sesquiterpenoid synthase, such as a germacrene A synthase, or other enzymes involved in the biosynthesis of sesquiterpenoid lactones from germacrene A. The invention further encompasses a process for modifying taste and/or resistance in a plant, plant organ, tissue or cell comprising introducing one or more recombinant polynucleic acids which induce, increase, decrease or inhibit the expression or activity of a sesquiterpenoid synthase, such as germacrene A synthase, or other enzymes involved in the biosynthesis of sesquiterpenoid lactones from germacrene A.

More particularly, the invention relates to a process for decreasing the bitter taste in a plant, plant organ, tissue or cell, comprising introducing into plant cells or tissues on or more recombinant polynucleic acids comprising a polynucleic acid sequence having at least 70% or 75%, preferably at least 80% or 85%, more preferably at least 90%, most preferably at least 95%, especially preferably 100% similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4 or parts thereof, or the complementary strand thereof, under the control of a plant-expressible promoter, regenerating the transformed plant cells or tissues into plants and obtaining the plants, plant organs, tissues or cells having decreased bitter taste.

Brief description of the drawings

The following detailed description, given by way of example, but not intended to limit the invention to specific embodiments described, may be understood in conjunction with the accompanying figures, incorporated herein by reference, in which:

Figure 1. Enzyme activity of 0.5 ml_ fractions eluting from a Mono-Q anion exchange column (FPLC).

Figure 2. Radio-GLC traces showing radio-labeled products of enzyme assays on A, fraction 20 (elution volume 10 mL) and B, fraction 26 (elution volume 13 mL) of the Mono-Q eluent shown in Fig. 1. The major peak in both traces represents germacrene A, the minor peaks are rearrangement products of germacrene A. Figure 3. Radio-GLC analysis of radiolabeled products formed from [³H]- farnesyl diphosphate in assays with protein extracts from transformed E. coli BL 21 (DE3) cells (Stratagene). A, FID signal showing an unlabelled authentic standard of germacrene A. B, C, radio-traces showing enzymatic products of protein extracts from BL 21 (DE3) cells transformed with A, the short cDNA and B, the long cDNA. 1, selina-4, 11-diene 2,3, α- and β- selinene 4, germacrene A. Long and short cDNA refer to the genes encoding the iso-enzymes of germacrene A synthase, of which the cDNA sequences are provided herein.

Figure 4. GC-MS analysis on an HP5-MS column of products formed from farnesyl diphosphate in assays with protein extracts from transformed E. coli BL 21 (DE3) cells (Stratagene). A, chromatogram of the negative control (vector without insert); B, chromatograms of B, the short cDNA; C chromatogram of C, the long cDNA; D, an authentic standard of germacrene A. 1, selina-4, 11 -diene 2, β-selinene 3, -selinene 4, germacrene A. "Long" and "short" cDNA refer to the genes encoding the iso-enzymes of germacrene A synthase, of which the cDNA sequences are provided herein.

Figure 5. Mass spectra of main product peaks 4 from chromatograms in Figure 4; A: the "short" cDNA; B: the "long" cDNA; C: authentic standard of germacrene A.

Figure 6. GC-MS analysis on an enantioselective column (Selected Ion Monitoring-mode) of products formed from farnesyl diphosphate in assays with protein extracts from transformed E. coli BL 21 (DE3) cells (Stratagene) with co-injection of an authentic standard of (+)- and (-)-β-elemene. (A,B) chromatograms of the short cDNA, with A, an injection port temperature of 150°C and B, an injection port temperature of 250°C. C,D, chromatograms of the long cDNA, with C, an injection port temperature of 150°C and D, an injection port temperature of 250°C. 1, (+)-β-elemene; 2, (-)-β-elemene; 3, α- selinene; 4, β-selinene; 5, selina-4, 11 -diene; 6, germacrene A. "Long" and "short" cDNA refer to the genes encoding the iso-enzymes of germacrene A synthase, of which the cDNA sequences are provided herein. Figure 7. (a) Northern blot analysis of the expression of the two germacrene A synthase genes in several tissues of chicory; (b) Quantification of Northern blot analysis of the expression of the two germacrene A synthase genes in several tissues of chicory.

Figure 8. Radio-GC analysis of radiolabeled products of incubations of crude extracts of etiolated seedlings of Cichorium intybus (A), inuline chicory (B), Lactuca sativa (C), radicchio (Chioggia type) (D), radicchio (Treviso type) (E), and endive (F) and Lactuca sativa (C) with 3H-labeled farnesyl diphosphate as substrate. Peaks: 1 , germacrene A; 2, α/β-selinene; 3, farnesol.

Figure 9. GC-MS spectrum of A, the major sesquiterpene product of an incubation of a crude extract of etiolated seedlings of Lactuca sativa with farnesyl diphosphate, and B, of an authentic standard of germacrene A.

Figure 10. (a). GC-MS analysis of the products of an enzyme assay using 50 μM FPP as substrate. A, standard of germacrene A; B, control sample (tobacco transformed with GUS gene); C, D, trangenic tobacco expressing the long germacrene A synthase gene. Injected with an injection port temperature of 150°C (C) or 250°C (D). 1 , β-elemene, 2, germacrene A. (b) Sesquiterpene synthase activity of tobacco in vitro regenerants. Wt, wildtype, non-transformed, tobacco plantlets (also regenerated in vitro). 121 -17, 8 and 16, transgenic plants containing the GUS gene. E, (putative) transgenic tobacco plants containing the long germacrene A synthase gene, (c) Sesquiterpene synthase activity of tomato Micro-Tom regenerants. C1 , C2: transgenic control plants containing a GUS construct. Numbers 2-14: (putative) transgenic tomato plants containing the long germacrene A synthase gene.

Figure 1 1. Constructs for use in the production of transgenic plants with decreased germacrene A synthase activity. A= gene 1 , B=gene 2 (or fragments thereof), A5'= 5'end of gene 1 , B5' = 5' end of gene 2, Prom = promoter, T = terminator. Gene 1 and gene 2 refer to the cDNAs encoding the isoenzymes of germacrene A synthase, of which the sequences are provided herein (or fragments thereof) The arrows in the boxes represent the sense and anti-sense orientation of the DNA sequence. The 5' ends comprise several hundred basepairs including part of the UTR. The promoter is preferably an enhanced 35S promoter, the terminator a nos terminator.

Figure 12. Sesquiterpene synthase activity of chicory in in vitro regenerants. C, transgenic plants containing the GUS gene. A, D and E, plants harboring constructs containing the germacrene A synthase gene(s); A, construct 1 ; D, construct 4 (Figure 1 1 ). E, sense construct of the long germacrene A synthase (Example 7);

Figure 13. Sequence alignment of the two cDNAs (A = "short", SEQ ID NO 3; B = "long", SEQ ID NO 4) encoding germacrene A synthase isolated from chicory. Sequence alignment was done with the ClustalW program.

Figure 14. Sequence alignment of the deduced amino-acid sequences (A= "short", SEQ ID NO 7; B = "long", SEQ ID NO 8) of two iso-enzymes of germacrene A synthase in chicory. Sequence alignment was done with the ClustalW program.

Description of the invention

The term "gene" as used herein refers to any DNA sequence comprising several operably linked DNA fragments such as a promoter and a 5' untranslated region (the 5'UTR), which together form the promoter region, a coding region (which may or may not code for a protein), and an untranslated 3' region (3'UTR) comprising a polyadenylation site. Typically in plant cells, the 5'UTR, the coding region and the 3'UTR (together referred to as the transcribed DNA region) are transcribed into an RNA which, in the case of a protein encoding gene, is translated into the protein. A gene may include additional DNA fragments such as, for example, introns. As used herein, a genetic locus is the position of a given gene in the genome of a plant. The term "polynucleic acid" refers to DNA or RNA, or amplified versions thereof, or the complement thereof. The term "chimeric" when referring to a gene or DNA sequence is used to refer to the fact that the gene or DNA sequence comprises at least two functionally relevant DNA fragments (such as promoter, 5'UTR, coding region, 3'UTR, intron) that are not naturally associated with each other and originate, for example, from different sources. "Foreign" referring to a gene or a DNA sequence with respect to a plant species is used to indicate that the gene or DNA sequence is not naturally found in that plant species. An endogenous plant gene is a gene that is naturally found in the concerned plant species.

As used herein the term "transgene" refers to a recombinant DNA or polynucleic acid molecule that is introduced into the genome of a plant. The term "recombinant DNA or polynucleic acid molecule" is used to exemplify and thus can include an isolated nucleic acid molecule which can be DNA and which can be obtained through recombinant or other procedures. This recombinant DNA molecule usually comprises at least one copy of at least one "gene of interest" (e.g. a recombinant DNA) which is capable of conferring one or more specific characteristics to the transformed plant. A "transgenic plant" refers to a plant comprising a transgene in the genome of all of its cells.

Expression of the transgene is used to indicate that the gene(s) of interest comprised in the transgene is expressed so as to confer on the plant one or more phenotypic traits (e.g. induced, increased or decreased sesquiterpenoid level) that were intended to be conferred by the introduction of the recombinant DNA molecule - the transforming DNA - used during transformation.

The term "sequence identity" with respect to a nucleotide sequence or an amino acid sequence, refers to the number of positions with identical nucleotides divided by the number of nucleotides in the shorter of the two sequences wherein alignment of the two sequences can be determined in accordance with the Wilbur and Lipmann algorithm (Wilbur and Lipmann,

PNAS USA, 80:726, 1983) using a window size of 20 nucleotides, a word length of 4 nucleotides, and a gap penalty of 4, and computer-assisted analysis and interpretation of the sequence data can be conveniently performed using programs of the intelligeneticsTM Suite (Intelligenetics Inc.

CA). Sequences which are essentially identical have a sequence identity of at least about 70% or 75%, advantageously at least about 80%, such as at least about 85%, preferably at least about 90%, especially about 95%, such as at least 97%, and especially about 100%. It is clear that when RNA sequences are said to be essentially identical or identical, or have a degree of sequence identity with DNA sequences, thymidine (T) in the DNA sequence is considered to be equal to uracil (U) in the RNA sequence. Additionally or alternatively, the term "sequence similarity" with respect to a nucleotide or amino acid sequence is intended to indicate a quantitative measure of similarity between two sequences. Sequence similarity as used herein can be measured using the alignment algorithm of the ClustalW program (Thompson et al., Nucleic Acids Research 22(22): 4673-7680, 1994). Sequences which are essentially similar have a sequence similarity of at least about 70%, advantageously at least about 75% or 80%, such as at least about 85%, preferably at least about 90%, especially about 95%, such as at least 97%, and especially about 100%.

More particularly, the sesquiterpenoid modulating genes as used herein will comprise a DNA sequence which is essentially similar, or, preferentially, essentially identical or identical to one or both of the nucleotide sequences or encodes an amino acid sequence which is essentially similar, or preferentially, essentially identical to one or both of the amino acid sequences corresponding to germacrene A synthase disclosed herein, more specifically in the nucleotide sequence encoding, or the amino-acid sequence corresponding to the "active domain" of the enzyme. The active domain of sesquiterpenoid synthases, such as germacrene A synthase, was determined by Back and Chappell (1996, above) to stretch from about 40 amino acids before to about 140 amino acids behind the conserved DDXXD region.

Reduced or decreased bitterness as used herein refers to a decrease in bitter constituents, i.e., molecules that confer a bitter taste. In the context of the present invention, bitter constituents are sesquiterpenoid molecules that confer a bitter taste on plants, e.g., sesquiterpenoid lactones. These can be determined qualitatively and quantitatively using HPLC (Price et al., 1990, above; Van Beek et al., 1990, above). Alternatively, the activity of enzymes catalyzing the formation of intermediates in the synthesis of the bitter constituents can be used as a measure for bitterness, such as the activity of germacrene A synthase, which catalyses the production of germacrene A, an intermediate in the production of sesquiterpenoid lactones. An "increase" or "decrease" of bitterness or bitter constituents in a transgenic plant or plant part, as described herein, is determined relative to a non-transgenic plant or plant part.

Resistance as referred to herein relates to a decreased infection state of a plant by certain insects, nematodes, microorganisms or decreased feeding of vertebrate herbivores. In the context of the present invention, resistance will primarily be the result of an increased deterrence to certain organisms, but can also be the result of an increased toxicity of the plant or plant parts to certain organisms, or the increased attraction to predators of the infecting organism. Alternatively, resistance of a plant or plant part can be measured by the presence therein of sesquiterpenoid molecules with deterring activity. An "increase" in resistance of a transgenic plant or plant part, as described herein, is determined relative to the resistance of a comparable non- transgenic plant or plant part.

As used herein, "modulation of sesquiterpenoids" refers to the influencing of the level of one or more sesquiterpenoids in a plant, and can thus refer either to an induction, increase or decrease of production of sesquiterpenoids in the plant. This modulation is preferably achieved, according to the invention, by influencing the level and/or activity of one or more sesquiterpenoid synthases in a plant. Sesquiterpenoid synthases are enzymes that are involved in the biosynthesis of sesquiterpenoids. A "germacrene A synthase" as used herein refers to an enzyme capable of producing germacrene A, preferably as a stable compound which is released from the enzyme without further processing by that enzyme.

The genes which according to this invention, can be used to modulate the level and/or activity of sesquiterpenoid synthases in plants will generally be referred to as "sesquiterpenoid modulating genes" ("SMGs"). These are foreign or endogenous genes comprising one or more DNAs encoding sesquiterpenoid synthases or transgenes derived from genes encoding sesquiterpenoid synthases, more particularly genes encoding germacrene A synthase, or other enzymes involved in the biosynthesis of sesquiterpenoids in plants. More particularly, the DNAs encoding germacrene A synthase, isolated in the context of the present invention are referred to as the "long" and "short" DNAs herein. Modulation of sesquiterpenoid synthase activity is obtained, according to one embodiment of the invention, by influencing endogenous gene expression in the plant. This is preferably achieved by introducing into the genome of the plant, one or more transgenes which interact with the expression of endogenous genes, by anti-sense RNA, co- suppression or ribozyme suppression. Alternatively, introduction of one or more DNA sequences encoding a sesquiterpenoid synthase into the plant genome, in a suitable conformation for gene expression (e.g. under control of a plant-expressible promoter), will result in increased or induced expression of the sesquiterpenoid synthase(s) in the plant, and, in the presence of an adequate substrate, in an increase of the corresponding sesquiterpenoid.

Induced, increased or reduced expression of a sesquiterpenoid synthase gene in a transgenic plant or plant cell as compared to a non-transgenic plant or plant cell can be measured by measuring mRNA levels, or where appropriate, the level or activity of the sesquiterpenoid synthase (e.g. ELISA, activity of the enzyme as indicated by the level of sesquiterpenoid or metabolites thereof (such as sesquiterpenoid lactones) formed. Endogenous sesquiterpenoid synthase expression refers to the expression of a protein with sesquiterpenoid synthase activity which is naturally found in the concerned plant, plant part or plant cell.

The biological activity of a sesquiterpenoid synthase can be measured directly in vitro by incubation of a purified or non-purified sample with the substrate of the sesquiterpenoid synthase, preferably labeled, after which the catalytic activity of the sesquiterpenoid synthase can be measured. For example, germacrene A synthase activity in a sample can be measured by incubating a sample allegedly containing the enzyme with (radiolabeled) farnesyl diphosphate as substrate, after which production of germacrene A can be measured by radio-GC analysis or GC-MS analysis (for example as described in the examples herein).

As used herein, the term a "plant-expressible promoter" refers to a promoter that is capable of driving transcription in a plant cell. This includes any promoter of plant origin, including the natural promoter of the transcribed DNA sequence, but also any promoter of non-plant origin which is capable of directing transcription in a plant cell, i.e. certain promoters of viral or bacterial origin such as the Cauliflower Mosaic Virus 35S (CaMV35S) or the T-DNA gene promoters. The term "plant-expressible promoter" includes, but is not restricted to, constitutive, inducible, and tissue-specific promoters.

The present invention is based on the observation that the bitter taste of certain vegetables, for example chicory, is related to the synthesis of sesquiterpene lactones, for example guianolides. As decreasing the bitterness would increase the market value of some of these vegetables, the biosynthesis of the sesquiterpene lactones in chicory was investigated. It was found that germacrene A is the product of a germacrene A synthase from which it is released without being further converted into other sesquiterpenoids by this enzyme. Other enzymes further modify the germacrene A skeleton to produce the variety of sesquiterpene lactones present in chicory. Germacrene A synthase was partially purified and the corresponding genes were isolated. The present invention is further based on the observation that certain sesquiterpene lactones play a role in the resistance of plants against several organisms. Based on these observations the concept was developed that the genes encoding sesquiterpenoid synthases could be used to influence both flavor and resistance in plants.

As the isolated genes encoding monoterpene-, sesquiterpene- and diterpene cyclases display a strong similarity in gene-organization and in amino acid sequence within domains, it is expected that modulation of gene expression, e.g., by anti-sensing or co-suppression, may influence the expression of different genes displaying such similar structure. It should be understood that such similarities can and should be taken into account when designing the transgenes used in the present invention.

In one embodiment of the invention, the production of the bitter constituents in plants is reduced or suppressed, by modulating the level and/or activity of sesquiterpenoid synthase(s) in the plant involved in the production of guianolides and other sesquiterpenoids associated with the bitter taste in vegetables. More particularly, modulation is achieved by suppressing endogenous germacrene A synthase levels by anti-sense RNA, co- suppression or other methods of gene suppression. In different vegetables, such as chicory, endives, radicchio, lettuce and artichoke, sesquiterpenoid lactones have been shown to be important bitter constituents. The isolation from chicory of the sesquiterpenoid synthase involved in the biosynthesis of these bitter constituents as well as the genes encoding this enzyme is described herein (example 1 to 5).

According to one aspect of the invention, a decrease in activity of a sesquiterpenoid synthase in a plant or parts of a plant is obtained by introducing into the cells of the plant one or more transgenes which are sesquiterpenoid modulating genes (SMGs), capable of influencing the level of one or more endogenous sesquiterpenoid synthase(s) in the plant. The sesquiterpenoid modulating genes of the present invention comprise a transcribed DNA sequence under the control of, and fused at its 5' end to, the plant-expressible promoter, whereby the resulting RNA, protein or polypeptide, when expressed in cells of the plant, significantly disturb or reduce the level and/or the activity of the endogenous sesquiterpenoid synthase(s). Alternatively, the stable integration of the transgene(s) into the cell in itself results in a decreased expression of the endogenous sesquiterpenoid synthase gene(s).

Thus, in one embodiment of the invention, the sesquiterpenoid modulating gene (SMG) comprises a DNA which encodes an anti-sense RNA which is complimentary to at least part of the sense mRNA of a sesquiterpenoid synthase gene that is naturally transcribed in the cells. More particularly, the SMG comprises a DNA encoding an anti-sense RNA which is the complement of the sense RNA of a germacrene A synthase gene from chicory, most particularly the complement of SEQ ID NO 3 or 4 or a part thereof. Alternatively, the SMG comprises a DNA encoding an anti-sense RNA which has at least 70% or 75%, preferably at least 80% or 85%, particularly at least 90%, more particularly 95%, especially has 100% sequence similarity to the complement of the sense RNA of the sequence of SEQ ID NO 3 or SEQ ID NO 4, or a part thereof. The anti-sense RNA may be complementary to any part of the sense mRNA (corresponding to part or all of an intron, exon, leader sequence etc., coding or non-coding region). Preferably, the anti-sense RNA is complementary to the sense RNA sequence encoding the active domain of the enzyme. More particularly, the anti-sense RNA comprises a sequence of at least 20 nucleotides, preferably 100 nucleotides complementary to the sense RNA encoded by nucleotide 845 to 1390 of SEQ ID NO 3 or to the sense RNA encoded by nucleotide 906 to 1460 of SEQ ID NO 4. Preferably, the SMG does not encode a functional protein, more particularly it does not encode a protein. Suppression of germacrene A synthase activity may be obtained using one or more SMGs, which can comprise a DNA sequence which encodes an anti- sense RNA which is identical or similar to the complement of the sequence of SEQ ID NO 3 or part thereof, or a DNA sequence which encodes an anti- sense RNA which is identical or similar to the complement of the sequence of SEQ ID NO 4 or part thereof. Alternatively, an SMG may be used which encodes an anti-sense RNA which is at least 60%, preferably at least 65%, most preferably at least 70% similar to the complement of a sequence between nucleotide 845 and nucleotide 1390 of SEQ ID NO 3 and of a sequence between nucleotide 906 and nucleotide 1460 of SEQ ID NO 4.

In another embodiment of the invention, the transcribed DNA sequence of the SMG comprises a DNA that is strongly homologous or similar to an endogenous sesquiterpenoid synthase sequence, so that introduction of the SMG into the genome of the plant causes the endogenous sesquiterpenoid synthase gene to be suppressed (co-suppression). Suppression of expression of the endogenous gene is achieved by introduction of a SMG comprising a strong plant-expressible promoter operably linked to a DNA so that the resulting transcribed RNA is a sense RNA comprising a nucleotide sequence which has at least 75%, preferably at least 80%, particularly at least 85%, more particularly at least 90%, especially at least 95% similarity with, more especially has 100% sequence similarity to the coding or transcribed DNA sequence (sense) of the endogenous sesquiterpenoid synthase gene of which the expression is to be suppressed. Particularly, The SMG comprises a DNA that displays a sequence similarity with the transcribed DNA region of a germacrene A synthase gene or a part thereof. More particularly, it comprises a DNA with a sequence similarity to the transcribed DNA region of SEQ ID NO 3 or SEQ ID NO 4. Particularly, the transcribed region of the SMG does not code for a protein. Preferably, the transcribed DNA region of the SMG does not code for a functional protein. Suppression of germacrene A synthase activity may be obtained using one or more SMGs, which can comprise one or more DNA sequences which is identical or essentially similar the sequence of SEQ ID NO 3 or part thereof, or identical or essentially similar to the sequence of SEQ ID NO 4 or part thereof. Alternatively, an SMG may be used which has at least 70% or 75%, preferably at least 80%, most preferably at least 90%, especially at least 95% similarity with, more especially has 100% sequence similarity to a sequence between nucleotide 845 and nucleotide 1390 of SEQ ID NO 3 and to a sequence between nucleotide 906 and nucleotide 1460 of SEQ ID NO 4. Recently, Waterhouse et al. (PNAS, 95(23): 13959-64, 1998) have described methods and means to make gene silencing in plants more efficient and predictable, by simultaneous expression of both sense and anti-sense constructs in cells of one plant. The sense and anti-sense nucleic acids may be in the same transcriptional unit, so that a single RNA transcript that has self-complementarity is generated upon transcription. In an analogous way, Hamilton et al. (The Plant Journal 15(6): 737-746, 1998) describe improved silencing e.g. of tomato ACC-oxidase gene expression using a sense RNA containing two additional upstream inverted copies of its 5' untranslated region.

WO 98/53083 describes constructs and methods for enhancing the inhibition of a target gene within an organism, involving the insertion into the gene silencing vector of an inverted repeat of all or part of a polynucleotide region within the vector.

In a further embodiment of the invention, an SMG comprises a DNA, which encodes a specific RNA enzyme or ribozyme, capable of highly specific cleavage of an endogenous sesquiterpenoid synthase gene of a plant. Particularly, the ribozyme encoded by the DNA is targeted against a gene encoding germacrene A synthase, most particularly against the mRNA sequence corresponding to the cDNA of SEQ ID NO 3 and/or SEQ ID NO 4.

It is understood that alternative methods can be developed for decreasing the sesquiterpenoid synthase activity in plants or plant parts in order to reduce bitterness, for instance inhibition the activity of the enzyme itself. Thus, the present invention also relates to sesquiterpenoid modulating genes encoding a protein or polypeptide capable of inhibiting the activity of a sesquiterpenoid synthase, more particularly, capable of inhibiting germacrene A synthase activity. Such an SMG can encode, for instance, an antibody or a fragment of an antibody directed against a germacrene A synthase. More particularly, the antibody fragment will be directed against an epitope of the protein made up of the sequence of SEQ ID NO 7 and/or SEQ ID NO 8,

According to another aspect of the invention, sesquiterpenoid modulating genes (SMG), are used to increase or induce expression of sesquiterpenoid synthase in a plant, so as to increase the level of sesquiterpenoids conferring resistance to the plant or increase the level of sesquiterpenoids that are interesting for other reasons, for example flavor and fragrance compounds derived from germacrene A or sesquiterpene lactones with pharmacological activity. This is achieved by introducing into the genome of a plant one or more SMGs comprising a DNA encoding a protein with sesquiterpenoid synthase activity, under the control of a plant-expressible promoter. More specifically, the SMG comprises a DNA encoding protein with germacrene A synthase activity. For instance, the SMG can comprise a sequence encoding a protein which has at least 70% or 75%, preferably at least 80% or 85%, most preferably 90%, especially at least 95% similarity with, more especially has 100% sequence similarity to SEQ ID NO 7 and/or SEQ ID NO 8, or a part thereof, encoding a functional part of a germacrene A synthase. Plants particularly suited for this embodiment of the invention are plants already producing sesquiterpene lactones such as for example many of the members of the Asteracea, such as species from the genera Cichorium, Lactuca, and Helenium (in case upregulation of sesquiterpene lactone formation is required), or plants already producing sesquiterpenes such as for example the genera Carum, Capsicum, Chamomilla, Cichorium, Citrus, Daucus, Gossypium, Juniperus, Lactuca, Tanacetum, Lycopersicon, Nicotiana, Pogostemon, Vetiveria (in case the production of germacrene A or other terpenoids derived thereof such as nootkatone is desired). If a high production is required, or when a shortage in FDP, the enzyme's substrate, is anticipated, a recombinant DNA encoding a protein or polypeptide with germacrene A synthase activity may be combined with a DNA encoding FDP or a protein with FDP synthase activity.

According to the invention, sesquiterpenoid synthase expression and/or activity in a plant or in plant parts is modulated by introducing one or more sesquiterpenoid modulating genes (SMGs) into the genome of the plant. The

SMG(s) comprise(s) a coding region placed under the control of, and fused at its 5' end to, a plant-expressible promoter. This promoter can be the natural promoter of an endogenous sesquiterpenoid synthase gene, more particularly the promoter of an endogenous germacrene A synthase gene, most particularly the promoter of a gene corresponding to the cDNA of SEQ ID NO 3 or SEQ ID NO 4.

Alternatively, the SMG is placed under control of a constitutive promoter, directing expression in essentially all cells of the plant. More specifically, the constitutive promoter can be, but is not restricted to, one of the following: a 35S promoter (Odell et al., Nature 313:482-493, 1985), a 35S'3 promoter (Hull and Howell, Virology 86:482-493, 1987), the promoter of the nopaline synthase gene ("PNOS") of the Ti-plasmid (Herrera -Estrella, Nature 303:209-213, 1983) or the promoter of the octopine synthase gene ("POCS", De Greve et al., J. Mol. Appl. Genet. 1(6): 499-511 , 1982). It is clear that other constitutive promoters can be used to obtain similar effects. For specific embodiments of this invention, the use of inducible promoters can provide certain advantages. In one embodiment of the invention, modulation of sesquiterpenoid synthase activity is used to increase pest resistance and can be required only upon infection by pests. It has been observed that infestation of peppers by the spider mite induces germacrene A production, possibly as part of a defense mechanism which leads to production of signal molecules which attract spider mite predators (personal communication). Transformation of such a plant with a sesquiterpenoid synthase gene under control of a promoter which initiates gene transcription upon infection of the plant by the spider mite will increase the production of these signal molecules, improving the natural defence mechanism.

In another embodiment of the invention, modulation of sesquiterpenoid synthase activity is required at least in, but possibly only in certain parts of the plant, making it possible to limit modulation to a certain period of culture or developmental stage of the plant. More particularly, it may be desired to decrease the sesquiterpenoid synthase(s) in the plant specifically in those parts of the plant destined for consumption or processing. More specifically, in a preferred embodiment of the invention the bitterness of chicory is decreased, at least in the shoots (eaten as vegetables) and/or roots (used as a source for sugars and/or feed for cattle). The shoots and roots of chicory are grown under dark conditions. Thus, in one aspect of the invention, the sesquiterpenoid modulating gene(s), is (are) placed under the control of a promoter which directs expression in the cells of the plant under specific dark conditions.

Alternatively, for other bitter tasting plants of which the leaves are used as food crop, such as, but not limited to, the lettuce (Lactuca sativa), light- inducible promoters can be used. Examples of inducible promoters are the dark regulated PRB-1b protein promoter described by Sessa et al. (Plant Mol. Biol., 28(3): 537-547, 1995) and the dark and light regulated chlorophyll A/B binding protein promoters, described by Cashmore (Proc. Natl. Acad. Sci. 81 :2960-2964, 1984) and by Simpson, et al. (EMBO J. 4:2723-2729, 1985) and in US patent n° 5,656,496.

Similarly, an inducible increase in sesquiterpenoid production can be of interest to protect plants from insects, fungi, nematodes or vertebrate herbivores by placing the SMG(s) under the control of an insect- fungus-, nematode-, or wounding-inducible promoter.

For specific embodiments of this invention, the use of tissue-specific promoters can provide certain advantages. More particularly, reduction of bitterness in plants will mainly be of value for parts of the plants destined for consumption or processing. Thus, in specific embodiments of the invention, the SMG(s) is (are) placed under the control of a promoter directing expression in specific plant tissues, such as roots or leaves. For instance, in chicory, reduction of the activity of sesquiterpenoid synthase, more particularly germacrene A synthase, is directed at the shoots (eaten as vegetables) and/or the roots (used as a source for sugars).

Similarly, in plants where certain parts of the plants are particularly susceptible to the damage of insects, microorganisms, nematodes or vertebrate herbivores, tissue-specific increase in sesquiterpenoid production can be of interest. For instance, to protect plants from infection by aphids, an increase in sesquiterpenoid synthase production is directed to the phloem or the chlorophyll-producing plant parts. More particularly, the SMG(s) is (are) placed under the control of a phloem-specific promoter (such as the rolC promoter of Agrobacterium) or the promoter of the gene encoding the small subunit of Rubisco. Alternatively, to protect plants from infection by root pathogens, for example fungi or nematodes, the increase in sesquiterpenoid synthase production is directed to the roots. More particularly, the SMG(s) is(are) placed under the control of a root-specific promoter (such as described by Keller et al., Genes Devel. 3: 1639-1646, 1989).

The sesquiterpenoid modulating gene(s) may include further regulatory or other sequences from other plant or bacterial genes, such as leader sequences (e.g. the cab22 leader from Petunia), 3'transcription termination and polyadenylation signals (e.g. from the octopine synthase gene or the nopaline synthase gene), plant translation initiation consensus sequences, introns etc, which is or are operably linked to the SMG.

The recombinant DNA comprising one or more SMGs may be accompanied by a chimeric marker gene. The chimeric marker gene can comprise a marker DNA that is operably linked at its 5' end to a plant-expressible promoter, preferably a constitutive promoter, such as the CaMV 35S promoter, or a light inducible promoter such as the promoter of the gene encoding the small subunit of Rubisco; and operably linked at its 3' end to suitable plant transcription 3' end formation and polyadenylation signals. It is expected that the choice of the marker DNA is not critical, and any suitable marker DNA can be used. For example, a marker DNA can encode a protein that provides a distinguishable color to the transformed plant cell, such as the A1 gene (Meyer et al., Nature 330: 677, 1987), can provide herbicide resistance to the transformed plant cell, such as the bar gene, encoding resistance to phosphinothricin (EP 0,242,246), or can provide antibiotic resistance to the transformed cells, such as the aac(β') gene, encoding resistance to gentamycin (WO94/01560).

The cell of a plant is preferably transformed in accordance with this invention, using a vector that is a disarmed Ti-plasmid containing the transgene and carried by Agrobacterium. This transformation can be carried out using the procedures described, for example, in European patent publications 0,116,718 and 0,270,822. Protocols describing Agrobactehum-med ated transformation of lettuce, chicory and tobacco are described in Michelmore, R. et al. (Plant Cell Reports 6, 439-442, 1987), Hohn and Ohlrogge, (Plant Physiology 97, 460-462, 1991) and Frulleux et al. (Plant Cell, Tissue and Organ Culture 50, 107-112, 1997). Preferred Ti-plasmid vectors contain the transgene sequence between the border sequences, or at least located to the left of the right border sequence, of the T-DNA of the Ti-plasmid. Where advantageous, plants are preferably transformed with auxotrophic Agrobacterium strains as described in European Patent Application 9711465.3). Of course other methods can be used to transform the plant cell, such as direct gene transfer (as described, for example in EP 0,223,247), pollen-mediated transformation (as described, for example in EP 0,270,356, WO85/01856), in vitro protoplast transformation (as described for example in US patent 4,684,611 ), plant RNA virus-mediated transformation (as described, for example in European patent publication 0,067,553 and US patent 4,407,956) and liposome mediated transformation (as described, for example, in US patent 4,536,475).

Although it is clear that the invention can be applied essentially to all plant species and varieties, the invention will be especially suited for those plants for which a decrease in bitter constituents or an increased resistance would result in an enhanced commercial value. The obtained transformed plants can be used in a conventional breeding scheme to produce more transformed plants with the same characteristic or to introduce the modified sesquiterpenoid synthase activity characteristic of the invention in other varieties of the same or related plant species. Seeds obtained from the transformed plants contain the transgene of the invention as a stable genomic insert.

The following Examples describe the isolation of a novel sesquiterpenoid synthase gene, the germacrene A synthase gene from Cichorium intybus and the use of this sequence or parts thereof in the manipulation of germacrene A synthase activity in plants. Unless stated otherwise in the Examples, all recombinant DNA techniques are carried out according to standard protocols as described in Sambrook et al. (1989) Molecular Cloning: A Laboratory Manual, Second Edition, Cold Spring Harbor Laboratory Press, NY and in volumes 1 and 2 of Ausubel et al. (1994) Current Protocols in Molecular

Biology, Current Protocols, USA. Standard materials and methods for plant molecular work are described in Plant Molecular Biology Labfax (1993) by

R.D.D. Croy, jointly published by BIOS Scientific Publications Ltd. (UK) and Blackwell Scientific Publications, UK. Throughout the Description and Examples reference is made to the following sequences:

SEQ ID NO PCR fragment 1 (short) SEQ ID NO PCR fragment 2 (long) SEQ ID NO cDNA 1 encoding C. intybus germacrene A synthase (short) SEQ ID NO cDNA 2 encoding C. intybus germacrene A synthase (long) SEQ ID NO amino acid sequence encoded by PCR fragment of SEQ ID

N0 1 SEQ ID NO 6: amino acid sequence encoded by PCR fragment of SEQ ID

NO 2

SEQ ID NO 7 amino acid sequence encoded by cDNA of SEQ ID NO 3 SEQ ID NO 8 amino acid sequence encoded by cDNA of SEQ ID NO 4 SEQ ID NO 9 primer SEQ ID NO 10 primer SEQ ID NO 1 1 primer SEQ ID NO 12 primer SEQ ID NO 13 primer SEQ ID NO 14 primer

Example 1 : Partial purification from chicory of two proteins catalyzing the formation of germacrene A from FDP

Chicory chicons were cut into small pieces, frozen in liquid nitrogen and ground to a fine powder using a cooled mortar and pestle. One gram of this powder was homogenized in 10 mL buffer containing 25 mM Mopso (pH 7.0), 20% (v/v) glycerol, 25 mM sodium ascorbate, 25 mM NaHS0₃, 10 mM MgCI₂ and 5 mM DTT (buffer A), slurried with 0.5 g polyvinylpolypyrrolidone (PVPP) and a spatula tip of purified sea sand. To the homogenate 0.5 grams of polystyrene resin (Amberlite XAD-4, Serva) were added and the slurry was stirred carefully for 10 min and then filtered through cheesecloth. The filtrate was centrifuged at 20,000g for 20 min (pellet discarded), and then at 100,000g for 90 min. The 100,000g supernatant was loaded on a 10 x 2.5 cm column of Q-sepharose (Pharmacia Biotech) previously equilibrated with buffer containing 15 mM Mopso (pH 7.0), 10% (v/v) glycerol, 10 mM MgCI₂ and 2 mM DTT (buffer B). The column was washed with the equilibration buffer and eluted with a 0-2.0 M KCI gradient. For determination of enzyme activities, 20 μL of the 2.0-ml fractions were diluted 5-fold in an Eppendorf tube with buffer B and 20 μM [³H]FDP was added. The reaction mixture was overlaid with 1 mL of hexane to trap volatile products and the contents mixed. After incubation for 30 min at 30°C, the vials were mixed, and centrifuged to separate phases. A portion of the hexane phase (750 μL) was transferred to a new Eppendorf tube containing 40 mg of silica gel, and, after mixing and centrifugation, 500 μL of the hexane layer was removed for liquid scintillation counting in 4.5 ml of Ultima Gold cocktail (Packard). The combined active fractions were desalted to buffer B, and 1.0 mL of this enzyme preparation was applied to a Mono-Q FPLC column (HR5/5, Pharmacia Biotech), previously equilibrated with buffer B containing 0.1% Tween-20. The column was eluted with a gradient of 0-600 mM KCI in the same buffer. The activity, which eluted as one peak from the Q-sepharose column, was now separated into two activity peaks (activity assessed as described above) (Fig. 1). For determination of product identity, 0.5 mL of the two most active fractions were diluted 2-fold with buffer B and 20 μM [³H]- FDP were added. After the addition of a 1-mL redistilled pentane overlay, the tubes were carefully mixed and incubated for 1 h at 30°C. Following the assay, the tubes were mixed, the organic layer was removed and passed over a short column of aluminum oxide overlaid with anhydrous MgS0 . The assay was extracted with another 1 mL of diethyl ether, which was also passed over the aluminum oxide column, and the column washed with 1.5 mL of diethyl ether. Before radio-GLC-analysis the extract was carefully concentrated under a stream of N₂. Radio-GLC was performed on a Carlo-Erba 4160 Series gas chromatograph equipped with a RAGA-90 radioactivity detector (Raytest, Straubenhardt, Germany). Sample components eluting from the column were quantitatively reduced before radioactivity measurement by passage through a conversion reactor filled with platinum chips at 800°C. Samples of 1 μL were injected in the cold on-column mode. The column was a fused silica capillary (30 m x 0.32 mm i.d.) coated with a film of 0.25 μm of polyethylene glycol (EconoCap EC-WAX, Alltech Associates) and operated with a He-flow of 1.2 mL min^"1. The oven temperature was programmed to 70°C for 5 min, followed by a ramp of 5° min^"1 to 210°C and a final time of 5 min. About 20% of the column effluent was split with an adjustable splitter to an FID (temperature 270°C). The remainder was directed to the conversion reactor and radio detector. H₂ was added prior to the reactor at 3 mL min^"1, and CH₄ as a quench gas prior to the radioactivity detector (5 mL counting tube) to give a total flow of 36 mL min^"1. Both fractions showed exactly the same radiolabeled products, with the major peak belonging to germacrene A (Fig. 2), proving that chicory contains two distinct proteins both catalyzing the formation of germacrene A from FDP. The minor peaks preceding the germacrene A peak, belong to rearrangement products of germacrene A, viz, α/β-selinene, and selina-4,11 - diene (De Kraker et al., 1998, above).

Example 2: Isolation of the genes encoding germacrene A synthase a) Isolation of mRNA. Total RNA was isolated from chicory chicons using the purescript RNA isolation kit (Biozym). DNase I (Deoxyribonuclease I, RNase free) was used to remove DNA from the RNA isolate. The DNase I was removed with a phenol/chloroform extraction after which the RNA was precipitated (ethanol precipitation with NaAc). Poly(A) + RNA was extracted from 20 μg of total RNA using 2 μg poly-d(T)25V oligonucleotides coupled to 1 mg paramagnetic beads (Dynal A.S.). The poly(A) + RNA was resuspended in 20 μ I H₂0.

b) cDNA synthesis. The reverse transcription reaction was carried out in a 50 μl reaction containing 10 μl poly (A) + mixture, 0.3 μg oligo (dT)₂₅V, 1 mM each dATP, dTTP, dCTP and dGTP, 50 mM Tris-HCI pH=8.3, 80 mM KCI, 10 mM MgCI2 and catalyzed with 12 U AMV reverse transcriptase (Pharmacia). After an incubation for 2h at 42°C the reaction was stopped and the cDNA purified with the Wizard PCR Preps DNA purification system (Promega). The cDNA was resuspended in 50 μl H₂0.

c) PCR-based probe generation. Based on comparison of sequences of terpenoid synthases, two degenerated primers were designed for two conserved regions (Yuba et al., Archives of Biochemistry and Biophysics, 332: 280-287,1996).

sense primer (primer A): 5'-TTY CAR GAY GAR AAY GGI AAR TTY AAR GA-3' (SEQ ID NO 9) wherein and R=G/A

anti-sense primer (primer B): 5'-CC RTA IGC RTC RAA IGT RTC RTC -3' (SEQ ID NO 10) wherein Y=C/T and R=G/A

PCR was performed in a total volume of 50 μl containing 0.5 μM of each of the two primers, 0.2 mM dNTP, 1 U Super Taq polymerase / 1x PCR buffer (HT Biotechnology LTD, Cambridge, England) and 10 μl cDNA. The reaction mixture was incubated in a thermocycler (Robocycler, Stratagene) with 1 min denaturation at 94°C, 1.5 min annealing at 42°C and 1 min elongation at 72°C during 40 cycles. Agarose gel electrophoresis revealed a single specific PCR product of approximately 550 bp. The PCR product was purified using the Wizard PCR Preps DNA purification system (Promega) and subcloned using the pGEMT system. E. coli JM101 was transformed with this construct. 12 individual transformants were sequenced which resulted in two different sequences (SEQ ID NO 1 and SEQ ID NO 2, the deduced amino acid sequences (primers included) are shown in SEQ ID NO 5 and 6, respectively).

d) cDNA library construction and screening.

A cDNA library was constructed using the UniZap XR custom cDNA library service (Stratagene). For library screening 200 ng of both PCR amplified probes were gel-purified, randomly labeled with [α-³²p]dCTP, according to manufacturer's recommendation (Ready-To-Go DNA labeling beads (-dCTP), Pharmacia) and used to screen replica filters of 10⁴ plaques of the cDNA library plated on E. coli XL1-Blue MRF' (Stratagene). The plaque lifting and hybridization were carried out according to standard protocols. Positive clones were isolated using a second and third round of hybridization. In vivo excision of the pBluescript phagemid from the Uni-Zap vector was performed according to manufacturer's instructions (Stratagene). Two groups of positive clones were obtained which could be distinguished using restriction enzymes and specific PCR primers. The cDNA sequences of two representatives of the two groups are shown in SEQ ID NO 3 and 4. These were named the "short" and "long" germacrene A synthase cDNAs (also referred to as gene 1 and gene 2 or A and B). The deduced amino acid sequences are shown in SEQ ID NOs 7 and 8, respectively. Nucleotide and amino acid sequence alignments are shown in Figures 13 and 14 respectively.

Example 3: Expression of the isolated genes in E. coli For functional expression, the cDNA clones were subcloned in frame into the expression vector pET 11 d (Stratagene). To introduce suitable restriction sites for subcloning, gene A was amplified by PCR using the following sense and anti-sense primers:

sense primer:

5'-CAA TCC GAA CCA TGG CTC TCG TT-3' (SEQ ID NO 11) (introducing an Λ/col site at the start codon ATG)

anti-sense primer:

5'- CAC CAA ATG GAT CCA AAT TCG C-3' (SEQ ID NO 12) (introducing a BamH\ site behind the stop codon TGA).

Gene B was amplified by PCR using the following sense and anti-sense primers:

sense primer:

5'-CCT TCA AGC CAT GGC AGC AGT TG-3' (SEQ ID NO 13)

(introducing an Λ/col site at the start codon ATG)

anti-sense primer: 5'-TTG TAA TAG GAT CCA CTA TAG G-3' (SEQ ID NO 14)

(introducing a BamH\ site behind the stop codon TGA)

The PCR reaction was performed under standard conditions. After digestion with BamH and Λ/col, the PCR product and the expression vector pET 11d were gel purified and iigated.

The two constructs and pET 11 d without an insert (as negative control) were transformed to E. coli BL 21 (DE3) (Stratagene), and grown overnight on LB agar plates supplemented with ampicillin at 37°C. Cultures of 50 ml LB medium supplemented with ampicillin (100 μg/ml) and 0.25 mM isopropyl-1 - thio-β-D-galactopyranoside (IPTG) were occulated with these over night cultures to A₆oo = 0.5 and grown for 3 h at 27°C. The cells were harvested by centrifugation during 8 minutes at 2000 g and resuspended in 1.2 ml buffer B containing 1 mM sodium ascorbate (buffer C). The resuspended cells were sonicated on ice during 4 min (5 sec on, 30 sec off), centrifuged for 5 minutes at 4°C (14.000 rpm) and the supernatant used for assays.

Example 4: Verification of product identity of cDNAs expressed in E. coli For determination of product identity, 20 μM [³H]-FDP was added to 0.5 mL of the enzyme preparations diluted 1 :1 with buffer C containing 0.1 % tween- 20. After the addition of a 1 -mL redistilled pentane overlay, the tubes were carefully mixed and incubated for 1 h at 30°C. Following the assay, the tubes were mixed, the organic layer was removed and passed over a short column of aluminum oxide overlaid with anhydrous MgS0 . The assay was re- extracted with 1 mL of pentane:diethyl ether (80:20), which was also passed over the aluminum oxide column, and the column washed with 1.5 mL of pentane:diethyl ether (80:20). The extract was analyzed using radio-GLC as described above (Example 1 ) and using GC-MS as described below. Radio- GLC analysis showed that both cDNAs formed functionally active proteins catalyzing the formation of three or more radiolabeled sesquiterpenes from [³H]-FDP (Fig. 3). The negative control (vector without insert) produced no radioactivity. The samples were also analyzed by GC-MS using a HP 5890 series II gas chromatograph equipped with an HP-INNOWax column (30 m x 0.25 mm i.d., 0.25 μm df) and HP 5972A Mass Selective Detector (Hewlett- Packard). The oven was programmed at an initial temperature of 70°C for 1 min, with a ramp of 5°C min^" to 210°C and final time of 5 min. The injection port (splitless mode), interface and MS source temperatures were 150, 290 and 180°C, respectively, and the He inlet pressure was controlled by electronic pressure control to achieve a constant column flow of 1.0 mlJmin. lonization potential was set at 70 eV, and scanning was performed from 30- 250 amu. The negative control produced no sesquiterpenes (Fig 4(a)), whereas in assays with the expression products of both the short (Fig. 4(b)) and the long cDNA (Fig. 4(c)) four different sesquiterpenes could be detected: selina-4, 11 -diene (1), β-selinene (2), α-selinene (3), and germacrene A (4) as major product. The identity of the latter was confirmed by analysis of an authentic standard of germacrene A (courtesy of Dr W.A. Kόnig) (Fig. 4(d)), and comparison of the mass spectra with the authentic standard (Fig. 5). The other three products 1,2,3 are rearrangement products of germacrene A, i.e. they are not produced enzymatically (Teisseire, P.J., Chemistry of fragrant substances, VCH Publishers Inc., USA, 1994; De Kraker, J-W. et al., Plant Physiology 117: 1381 -1392, 1998).

The chirality of the germacrene A produced by the two genes was assessed by GC-MS using the fact that the high-temperature-induced Cope- rearrangement of germacrene A to β-elemene occurs with retention of stereochemical configuration at C7 (De Kraker et al, 1998, above). GC-MS analysis was carried out essentially as described above, but the GC was equipped with a 25 m (0.25 mm i.d.) heptakis (6-0-TBDMS-2,3-di-0-methyl)- β-cyclodextrin (50% in 0V17) column that is able to separate the enantiomers of β-elemene (Kόnig et al., J. High Resolut. Chromatogr. 17: 315-320, 1994). The oven temperature was programmed to 45°C for 4 min followed by a ramp of 2°C min^"1 to 170°C, and spectra were recorded in scan or Selected Ion Monitoring mode (m/z 121 , 147 and 189). The injection port temperature was either 150°C (no Cope-rearrangement of germacrene A) or 250°C (Cope-rearrangement of germacrene A to β-elemene). A standard of (+)- and (-)-β-elemene was co-injected with the germacrene A produced by the two clones. Figs 6A and C show the chromatograms of the short and the long clone, respectively, with co-injection of (+)- and (-)-β-elemene at an injection port temperature of 150°C. Germacrene A (6) is by far the major product, with small amounts of the proton-induced rearrangement products α-selinene (3), β-selinene (4) and selina-4, 1 1-diene (5). The two enantiomers of β-elemene are separated: (+)-β-elemene (1) and (-)-β-elemene (2). When the injection port temperature is increased only the (-)-enantiomer of β- elemene is formed from the germacrene A of both clones. This was demonstrated using scan measurements also without co-injection with the β- elemene standard (data not shown). Upon co-injection with the (+)- and (-)-β- elemene standard and using a high injection port temperature, (only) the (-)- β-elemene peak areas increase for both clones (Figs 6B,D). This proves that the germacrene A produced by both clones is exclusively rearranged to (-)-β- elemene, implying that both clones produce exclusively (+)-germacrene A (De Kraker et al, 1998, above). Thus it was concluded that the two sequences encode iso-enzymes of germacrene A synthase (also referred to as "long" and "short" or A and B).

Example 5: Expression pattern of the two genes in chicory

The expression pattern of the two germacrene A synthase genes was investigated in Chicory by Northern blot analysis. RNA from different tissues was isolated using the Wizard system (SV Total RNA Isolation System, Promega) according to the procedure recommended by the manufacturer. Of each sample 2 μg of total RNA, treated with DMSO glyoxal, was separated on a 1 % gel and blotted onto Hybond-N+ nylon membrane using 7.5 mM NaOH as described by Sambrook et al (Molecular cloning, second edition, 1989, 7.40-7.50). To fix the RNA, the membrane was exposed to Ultraviolet light (254 nm). Prehybridization and hybridization itself were carried out according to the procedures recommended by the manufacturer (Amersham) in a solution containing 5 x SSPE, 5 x Denhardt's solution, 0.5 % SDS and 0.1 mg/ml herring sperm DNA. Subsequently, the blots were washed at 65°C with 0.1 x SSPE and 0.1 % SDS and exposed to a Fuji Photo Film. The pattern on the film was analyzed using the BAS 2000 Image Plate Scanner. The probe used in the hybridization step was generated using the Ready to go system according to the procedure recommended by the manufacturer (Pharmacia). As templates for the probes (gel-) purified PCR fragments of the genes to be analyzed were used.

There were marked differences in the expression of the two genes in the different tissues tested (Figure 7(a), (b)). The short gene was expressed particularly in the root tissues (about equally in the outer and core tissue) and in the seedlings, but hardly in the chicon and the green leaves. The long gene was expressed strongest in the root outer tissue, and much less in the root inner tissue. It was expressed at a simmilar level in chicon tissue and seedlings and much lower in green leaves. These results suggest that in order to reduce bitterness in the chicon tissue of Chicory inhibition of the long gene could be sufficient.

Example 6: Germacrene A synthase activity in other plants

In addition to chicory, several other crops belonging to the Compositae have been shown to contain bitter sesquiterpene lactones (Price et al., 1990, above). It was therefor investigated whether germacrene A synthase activity could be detected in other lettuce, endive and chicory varieties containing these lactones. Etiolated seedlings of seven different varieties were grown for a period of 8 days at 20°C in darkness after which an enzyme extract was made of the seedlings. These extracts were incubated with radiolabeled farnesyl diphosphate, the ubiquitous precursor of sesquiterpenes. Radio-GC analysis was performed on these samples.

All seven samples displayed germacrene A synthase activity (peak 1 , Figure 8). The identity of peak 1 was confirmed using GC-MS, of which one example is shown in Figure 9. The fronting of peak 1 and 2 represents selina-4,11 - diene and α- and β-selinene, acid-induced rearrangement products of germacrene A (De Kraker et al., 1998, above) Peak 3 represents famesol, produced from FDP by non-specific phosphohydrolase activity. These results strongly suggest that also in other lettuce, endive and chicory varieties, sesquiterpene lactone biosynthesis proceeds via the central intermediate germacrene A.

Example 7: Transformation of tobacco and tomato with the germacrene A synthase gene(s) to obtain (increased) germacrene A or sesguiterpene lactone formation To induce or upregulate the production of sesquiterpene lactones or the production of germacrene A in transgenic plants, plants were transformed using plasmids comprising a sesquiterpenoid synthase modulating gene comprising a sequence encoding protein or polypeptide having germacrene A synthase activity, placed under the control of a suitable plant-expressible promoter, such as a constitutive promoter. Tobacco transformation. For the transformation of Nicotiana tabacum (Petit Havana SR1 ) leaf disks were immersed in an antibiotic-free suspension of the A. tumefaciens strain LBA4404 transformed with pBI.E(LB medium, OD600 = 0.5). The pBI.E construct is a derivative of pBI121 in which the gus gene was replaced by the long germacrene A gene. The infected leaf disks were incubated on co-cultivation medium (MS, 20 g/l sucrose, 1 mg/l NAA, 0.2 mg/l BAP, 6 g/l agar pH 5.8) for 3 days at 25°C under continuous dimmed light.To select and regenerate transformed tissue the leafdisks were transferred several times to selection medium (MS, 20 g/l sucrose, 1 mg/l zeatin, 0.1 mg/l NAA, 150 mg/l cefotaxine, 150 mg/l vancomycin, 100 mg/l kanamycin, 6 g/l agar, pH 5.8) at intervals of 7-14 days and incubated at 25°C under continuous dimmed light. The regenerated shoots were maintained on MS media supplemented with 20 g/l sucrose and 100 mg/l kanamycin.

Transgenic plants were screened for the activity of the introduced gene by examining sesquiterpene synthase activity in enzyme extracts. Hereto, 100 mg of tissue, ground in liq N2, was extracted in a 2-ml Eppendorf vial, using a plastic probe to further homogenize the tissue, in 1.0 ml of extraction buffer containing containing 50 mM Mopso (pH 6.8), 20% (v/v) glycerol, 50 mM sodium ascorbate, 50 mM NaHS03, 1 % PVP-40, 10 mM MgCI2 and 5 mM DTT. After extraction, the samples were centrifuged for 20 min at 20,000g. at 4 °C 10 μL of the supernatant were diluted 10 fold with assay buffer containing 15 mM Mopso (pH 7.0), 10% (v/v) glycerol, 10 mM MgCI2, 1 mM sodium ascorbate, 2 mM DTT and 6 mM sodium orthovanadate (an inhibitor of phosphohydrolase activity). After addition of 15 μM 3H-FPP (at 65 Ci mol- 1), the reaction mixture was overlaid with 1 mL of hexane to trap volatile products and the contents carefully mixed. After incubation for 30 min at 30°C, the vials were vigorously mixed, and centrifuged (2 min 15.000g 4°C) to separate phases. A 750-μL portion of the hexane phase was transferred to a second Eppendorf vial containing approx. 20 mg silica to bind sesquiterpene alcohols produced by any remaining phosphohydrolase activity, vigorously mixed and centrifuged. (10 min 15.000g 4°C) 500 μL of hexane were removed from these vials for liquid scintillation counting in 4.0 ml of Ultima Gold cocktail (Packard). All assays were performed in duplicate.

The wildtype and GUS-construct controls all exhibited a similar sesquiterpene synthase activity (Figure 10 (b)), which is due to the presence of endogenous tobacco sesquiterpene synthases, such as for example the tobacco epi-aristolochene synthase (Facchini and Chappell, 1992). The transformants E24.4, 26, 12.2, 24.3, 26.2 and 25.3 exhibited a significantly higher sesquiterpene synthase activity when compared with the 6 controls showing that transformation with the germacrene A synthase resulted in increased sesquiterpene synthase activity (Figure 10 (c)). Subsequently, the sesquiterpene synthase activity of a number of transformants was assessed on a larger scale. Hereto, 500 mg of ground tissue was homogenized in 4 ml of the extraction buffer described above, and centrifuged for 20 min at 20,000g. The supernatant was desalted to the assay buffer described above. After addition of 50 μM unlabelled FPP to 1 ml of this desalted extract, the reaction mixture was overlaid with 1 ml of redistilled pentane and incubated for 60 min at 30°C. The assays were worked up, and analyzed using GC-MS as described under Example 6. GC-MS analysis showed the presence of several sesquiterpenes in both control and putative transgenic plants. However, transgenic regenerant E12.2 showed a large peak, which was not present in the control samples, with the mass spectrum and retention time of the authentic germacrene A standard (Figure 10(a)). The fact that high injection port temperature causes this peak to shift to a lower retention time (of β -elemene) confirms that indeed the germacrene A synthase gene was functionally expressed in tobacco.

Tomato transformation. A tobacco (Nicotiana bentiana) cell suspension culture (TCSC) in a liquid NIBE medium (4.4g/l MS salts with B5 vitamins, 3% sucrose, 0.2mg/l BAP, 0.2mg/l 2,4-D NAA, pH 5.8) was set up and used for feederlayers. The cultures were grown for at least 2 weeks on a shaker at 25°C. A feederlayer consists of 2 ML of a tobacco cell suspension culture incubated on NIBE plates (NIBE medium, 0.8% purified agar (Oxoid), pH 6.0). The feederlayer was set to grow overnight, covered with 4 folds of filter paper, in a culture room (25°C) under low light conditions. The agrobacterium strain harbouring the germacrene A construct were streaked out on LB/RIF/KAN plates (10g/l Bacto tryptone, 5g/l Bacto yeast extract, 10g/l NaCI, 15g/l Bacto agar, pH 7.0, 100mg/l riframycin, 50mg/l kanamycin.

The plates were set to grow for three days at 28°C under dark conditions. A single colony was inoculated in YEP-selection medium (1 Og/I yeast extract, 10g/l pepton, 5g/l NaCI, pH 7.0, 0.1 M glucose, 50mg/l kanamycin, 50mg/l riframycin, 100μM acetosyringone) and set to shake overnight at 28°C.The selection culture was spin down (2500 rpm 15 minutes) and re-suspended in MS20 (4.4g/l MS salts including vitamins, 2% sucrose, pH 5.8). This Agrobacterium suspension, with an OD600 of 0.2, was used to immerse the explants. The tomato cultivar 'Micro-Tom' (Lycopersicon flavour) was used (Scott and Harbaugh, 1989). The plants were grown from seeds provided by a seed company (Beekenkamp seed, Holland). Micro-Tom seeds were first sterilised. A rinse in 70% ethanol followed by a two hour bleaching in 1.5% HCI04. After bleaching, the seeds were quickly rinsed in water twice and then washed in water for ten and sixty minutes. After sterilisation, seeds were sowed in pots, containing 80ml vermiculite and 70ml of germination medium containing 4.4g/l MS salts with vitamins and 0.5% sucrose (pH 5.8). After 7 days of growth in a culture room (25°C), covered with 2 folds of filter paper, the cotyledons were cut under water near the petiole and the tip with a rolling action of the scalpel, to minimize damage. The explants were placed on their backs on filter paper on feederlayers to incubate overnight in the culture room (25°C), covered with 4 folds of filter paper, under low light conditions. After incubation, the explants were immersed in the 42

The down-regulation of genes in plants is achieved in different ways, e.g. through sense and anti-sense inactivation. In order to inhibit the activity of endogenous germacrene A synthases to obtain plant species with decreased production of germacrene A or products derived thereof, for example sesquiterpene lactones, plant species such as chicory and lettuce (and other sesquiterpene lactone producing species) are transformed by the techniques described above using plasmids containing genes coding for the germacrene A synthase(s) in either sense (to obtain co-suppression) or anti-sense orientation.

In order to test the impact of both genes on the production of sesquiterpenoids and the bitter taste of Chicory plants, constructs were made to inhibit either one or both germacrene A synthase genes together. Based on the expression pattern of the genes (Example 5) it was expected that for reduction of bitterness in the chicon, inhibition of the long gene alone could be sufficient.

The coding regions of the two genes encoding isoenzymes of germacrene A synthase of the present invention have a sequence similarity of 67%. Within the region encoding what is believed to be the "active domain" of the enzyme (stretching from about 40 amino acids before to about 140 amino acids behind the conserved DDXXD sequence) the sequence similarity between the two genes is 82.4%. Therefore, constructs are developed which comprise more than one DNA sequence whereby one DNA sequence comprises a DNA encoding an RNA with a sequence similarity to all or part of the sequence of SEQ ID NO 3, or the complementary strand thereof and the other encodes an RNA sequence with a sequence similarity to all or part of the sequence of SEQ ID NO 4, or the complementary strand thereof. The nucleic acid molecule used preferably comprises two sequences whereby the first sequence is identical to the complement of the second sequence, possibly separated by a spacer sequence, so as to form inverted repeats. The DNA sequences are placed under the control of adequate promoters, such as the 35S promoter, and terminator sequences and are introduced into chicory by Agrobacterium mediated transformation.

Examples of the DNA sequences comprise: 41

Agrobacterium suspension for 20 minutes. After immersion, the explants were placed back on feederlayers for co-cultivation, following a rinse in a solution containing 400mg/l carbenicillin and 100mg/l tricarcillin. The explants were placed in callus inducing medium (4.4g/l MS salts with Nitsch vitamins, 3% sucrose, 0.8% purified agar (Oxoid), pH 6.0, 2mg/l zeatin, 400mg/l carbenicillin, 100mg/l tricarcillin, 100mg/l kanamycin). The plates were covered with 2 folds of filter paper and set to grow in a culture room (25°C) under low light conditions for 3 weeks. Formed callus was transferred to shoot inducing medium (as callus inducing medium, but with 1mg/l zeatin, 200mg/l carbenicillin, 50mg/l tricarcillin).

These plates were set to grow under the same conditions as the callus- inducing plates. Shoots formed were transferred to rooting medium in pots (4.4g/l MS salts with Nitsch vitamins, 3% sucrose, 0.5% agargel (Sigma), pH 6.0, 0.25mg/l IBA, 50mg/l kanamycin, 400mg/l carbenicillin. The growing conditions remained the same. Fully-grown plants were subsequently transferred to the greenhouse.

Sesquiterpene synthase activity was tested as described above for tobacco, but with 10 μM 3H-FPP as substrate. A number of transformants were found to have significantly higher (up to 4 to 5-fold) sesquiterpene synthase activity, as a result of the transformation with the germacrene A synthase construct (Figure 11 (c)).

The transgenic tobacco and tomato plants are then tested for their resistance against insects and micro-organisms. This is done by infesting control and transgenic plants with set numbers of pests and evaluating infestation of the plants after periods of 1 , 2, 5, 7 and 14 days.

Example 8: Transformation of chicory with the germacrene A synthase gene(s) to obtain reduced bitterness

Based on the results described above, the sequences encoding germacrene A synthase are used to make transgenic plants showing reduced germacrene A synthase activity. 42

The down-regulation of genes in plants is achieved in different ways, e.g. through sense and anti-sense inactivation. In order to inhibit the activity of endogenous germacrene A synthases to obtain plant species with decreased production of germacrene A or products derived thereof, for example sesquiterpene lactones, plant species such as chicory and lettuce (and other sesquiterpene lactone producing species) are transformed by the techniques described above using plasmids containing genes coding for the germacrene A synthase(s) in either sense (to obtain co-suppression) or anti-sense orientation.

In order to test the impact of both genes on the production of sesquiterpenoids and the bitter taste of Chicory plants, constructs were made to inhibit either one or both germacrene A synthase genes together. Based on the expression pattern of the genes (Example 5) it was expected that for reduction of bitterness in the chicon, inhibition of the long gene alone could be sufficient.

The coding regions of the two genes encoding isoenzymes of germacrene A synthase of the present invention have a sequence similarity of 67%. Within the region encoding what is believed to be the "active domain" of the enzyme (stretching from about 40 amino acids before to about 140 amino acids behind the conserved DDXXD sequence) the sequence similarity between the two genes is 82.4%. Therefore, constructs are developed which comprise more than one DNA sequence whereby one DNA sequence comprises a DNA encoding an RNA with a sequence similarity to all or part of the sequence of SEQ ID NO 3, or the complementary strand thereof and the other encodes an RNA sequence with a sequence similarity to all or part of the sequence of SEQ ID NO 4, or the complementary strand thereof. The nucleic acid molecule used preferably comprises two sequences whereby the first sequence is identical to the complement of the second sequence, possibly separated by a spacer sequence, so as to form inverted repeats. The DNA sequences are placed under the control of adequate promoters, such as the 35S promoter, and terminator sequences and are introduced into chicory by Agrobacterium mediated transformation.

Examples of the DNA sequences comprise: 43

- the DNA of SEQ ID NO 3 and 4 (or parts thereof), behind a suitable promoter and upstream of a suitable terminator

- the DNA of SEQ ID NO 3 and 4 (or parts thereof), each behind a suitable promoter and upstream of a suitable terminator - the DNA of SEQ ID NO 3 and 4 (or parts thereof), without a promoter

- two copies of SEQ ID NO 3 and 4 (or parts thereof) behind a promoter and upstream of a terminator

- a fragment of one of the two DNA's of SEQ ID NO 3 or SEQ ID NO 4 (or parts thereof) exhibiting a sequence similarity of preferably >80% to the other DNA of SEQ ID NO 3 or 4, behind a promoter and upstream of a terminator

- both DNA's of SEQ ID NO 3 and SEQ ID NO 4 (or parts thereof) and an additional upstream inverted copy of the 5' end (with or without the untranslated region) of one or of both, each behind a suitable promoter (or together behind one suitable promoter, such as a 35S promoter) and upstream of a suitable terminator (Hamilton et al., 1998, above; Waterhouse et al., 1998, above). Examples of such panhandle constructs are illustrated in Figure 11 (A, B, C).

- the cDNAs of SEQ ID NO 3 and SEQ ID NO 4, or a fragment thereof, displaying at least 70% homology to each other, whereby one is place in sense and one in anti-sense orientation, placed between a suitable promoter and terminator (Figure 1 1 (D)). The activity of the promoter, and hence the effectiveness of the co- suppression may be increased by including suitable enhancer elements behind the promoter, upstream of the coding sequence(s).

Chicory transformation: seeds were sterilized in a 2% sodiumhypochlorite solution during 20 minutes. After three rinses, the seeds were sown on MS20 in containers and grown at 27°C in light. Between 4 and 8 weeks after sowing the leaf-explants can be cut for transformation purposes. These explants (4x6mm) of which all sides are cut are ented with the backside onto the medium and pre-cultured for one day in MSN20 (Murashige & Skoog salts, Nitsch & Nitsch (1965) vitamins, 2.0 mg/l Glycine, 20 g/l sucrose, 8g/l agar, pH 5,8) medium containing 1 mg/ml BA + 0.2 mg/ml NAA. The pre-cultured 44

leaf pieces were infected by submersing them for 20 minutes in a diluted bacterial suspension (OD 0.01 and 0.1). After removal of excess suspension the pieces were replaced on the pre-culture trays. After two days of co- cultivation, the leaf pieces were rinsed in MS20 medium for 30 minutes. They were then incubated on MSN20 containing 1 mg/ml BA and 0.1 mG/l NAA and 100 mg/l kanamycin (with 200 mg/l carbenicillin and 200 mg/l Claforan) at 27° in light. Selection for PPT was done on MSN medium containing 1 mg/ml BA and 0.1 mg/l NAA and 2x10^"5M DL-PPT (200 mg/l Carbenecillin and 200 mg/l Claforan). The leaf pieces were transferred to fresh selection medium every 14 days. About 5 weeks after cutting of the explants the selection medium was changed to MS 20 containing 0.1-1 mg/l BA and 100 mg/l kanamycin (200 mg/l Carbenecillin and 200 mg/l Claforan).

Chicory was transformed with constructs 1 and 4 (Figure 11), as well as the sense construct harboring the long DNA that was also used to transform tobacco and tomato (Example 7). After regeneration, leaf samples of 2-4 cm large regenerants were tested for germacrene A synthase activity as described in Example 7. For all three constructs there were a number of individuals with significantly reduced germacrene A synthase activity (and thus reduced amounts of bitter sesquiterpene lactones (Figure 12).

Claims

Claims

1. An isolated polynucleic acid comprising a nucleotide sequence encoding a protein or polypeptide having the biological activity of a germacrene A synthase.

2. The isolated polynucleic acid of claim 1 , wherein said nucleotide sequence encodes a protein or polypeptide with an amino acid sequence having at least 70% sequence similarity to the sequence of SEQ ID NO 7 or SEQ ID NO 8.

3. The isolated polynucleic acid of claim 2, wherein said nucleotide sequence encodes a protein or polypeptide with an amino acid sequence having at least 70% sequence similarity with the sequence of SEQ ID NO 7, between amino acid 271 and amino acid 455, or with the sequence of SEQ ID NO 8, between amino acid 291 and 477.

4. The isolated polynucleic acid of claim 1 , wherein said nucleotide sequence encodes the amino acid sequenc of SEQ ID NO 7.

5. The isolated polynucleic acid of claim 1 , wherein said nucleotide sequence encodes the amino acid sequence of SEQ ID NO 8.

6. The isolated polynucleic acid of claim 1 , wherein said nucleotide sequence has at least 70% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or the complement thereof.

7. The isolated polynucleic acid of claim 1 , wherein said nucleotide sequence has at least 95% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or the complement thereof.

8. The isolated polynucleic acid of claim 7, wherein said nucleotide sequence is the nucleotide sequence of SEQ ID NO 3, or the complement thereof.

9. The isolated polynucleic acid of claim 7, wherein said nucleotide sequence is the nucleotide sequence of SEQ ID NO 4, or the complement thereof.

10. A process for producing a plant with modified sesquiterpenoid synthase activity, said process comprising introducing into the genome of a plant cell a recombinant DNA which when expressed in a plant cell modifies the expression of a sesquiterpenoid synthase encoded by a polynucleic acid of any of claims 1 to 9 in said cell.

11. A process for producing a plant with reduced bitterness in some or all of its plant parts, said process comprising reducing the expression of an endogenous sesquiterpenoid synthase gene in said plant.

12. The process of claim 11 , comprising

(a) introducing into the genome of a plant cell one or more recombinant DNAs, said recombinant DNAs comprising: a DNA encoding an RNA, protein or polypeptide, which when expressed in said plant cell inhibits or reduces the expression of an endogenous sesquiterpenoid synthase in said cell, and a plant-expressible promoter, whereby said DNA is in the same transcriptional unit and under the control of said plant-expressible promoter; and

(b) regenerating said plant from said plant cell or tissue

13. The process of claim 12, wherein said sesquiterpenoid synthase is a germacrene A synthase.

14. The process of claim 13, wherein said DNA encodes a sense or anti-sense

RNA capable of inhibiting or reducing the expression of said endogenous germacrene A synthase.

15. The process of claim 14, wherein said DNA comprises a sequence having at least 70% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or the complementary strand thereof.

16. A process for producing a plant with increased pest resistance, said process comprising increasing or inducing the expression of a protein of polypeptide having germacrene A synthase in said plant or having the activity of an enzyme involved in the production of sesquiterpenoid lactones from germacrene A.

17. The process of claim 16, comprising

(a) introducing into the genome of a plant cell or tissue a recombinant DNA comprising:

- a DNA encoding a protein or polypeptide having germacrene A synthase activity, and

- a plant-expressible promoter; said DNA being in the same transcriptional unit and under the control of said plant-expressible promoter; and

(b) regenerating said plant from said plant cell or tissue

18. The process of claim 17, wherein said DNA encodes a protein or polypeptide having at least 70% sequence similarity to the amino acid sequence of SEQ ID NO 7 or with the sequence of SEQ ID NO 8.

19. The process of claim 17, wherein said DNA comprises a sequence having at least 70% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4.

20. The process of claim 17, wherein said DNA comprises the sequence of SEQ ID NO 3 or SEQ ID NO 4.

21. A recombinant polynucleic acid comprising

(a) a DNA encoding an RNA or protein, which when expressed in a cell of a plant either induces, increases or decreases the expression of germacrene A synthase in said cell, and

(b) a plant-expressible promoter; wherein said DNA is in the same transcriptional unit and under the control of said plant expressible promoter.

22. The recombinant polynucleic acid of claim 21 , wherein said DNA encodes an antisense RNA, a ribozyme or a sense RNA, which when expressed in a cell of a plant decreases the expression of an endogenous germacrene A synthase in said cell.

23. The recombinant polynucleic acid of claim 21 , wherein said DNA has at least

70% sequence similarity to the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or the complementary strand thereof.

24. The recombinant polynucleic acid of claim 23, wherein said polynucleic acid comprises the nucleotide sequence of SEQ ID NO 3 or SEQ ID NO 4, or part thereof.

25. The recombinant polynucleic acid of claim 21 , wherein said DNA comprises

- a first nucleotide sequence having at least 70% sequence similarity to the complementary sequence of SEQ ID NO 3 or SEQ ID NO 4, or part thereof, and

- a second nucleotide sequence having at least 70% sequence similarity to the sequence of SEQ ID NO 3 or SEQ ID NO 4 , or part thereof, and optionally, - a spacer sequence between said first and said second sequence.

26. The recombinant polynucleic acid of claim 25, wherein said first nucleotide sequence is complementary to part of said second sequence.

27. The recombinant polynucleic acid of claim 21 , wherein said DNA comprises

- a first nucleotide sequence having at least 70% sequence similarity to the sequence of SEQ ID NO 3 or SEQ ID NO 4, or part thereof, and

- a second nucleotide sequence having at least 70% sequence similarity to the sequence of SEQ ID NO 3 or SEQ ID NO 4, or part thereof.

28. The recombinant polynucleic acid of claim 21 , wherein said DNA encodes a protein or polypeptide with germacrene A synthase activity.

29. The recombinant polynucleic acid of claim 28, wherein said DAN encodes a protein or polypeptide having at least 70% sequence similarity to the sequence of SEQ ID NO 7 or SEQ ID NO 8.

30. The recombinant polynucleic acid of any one of claims 21 to 29, wherein said plant-expressible promoter is the promoter of an endogenous germacrene A synthase gene.

31. The recombinant polynucleic acid of any one of claims 21 to 29, wherein said plant-expressible promoter is a constitutive promoter.

32. The recombinant polynucleic acid of any one of claims 21 to 29, wherein said plant-expressible promoter is an inducible or a tissue-specific promoter.

33. A cell of a plant, transformed with the recombinant polynucleic acid of any one of claims 21 to 32.

34. A plant consisting essentially of the plant cells of claim 33.

35. The plant of claim 34, which is selected from the group of the genera Carum, Chichorium, Daucus, Juniperus, Chamomilla, Lactuca, Pogstemon, and Vetivera.

36. The seed of a plant of claim 35, comprising said recombinant DNA.

37. A probe which is part of a polynucleic acid sequence according to any of claims 1-9 and which hybridizes specifically with said polynucleic acid or the completement thereof.

38. A primer derived from a polynucleic acid sequence according to any of claims 1-9 and which specifically amplifies with said polynucleic acid or the completement thereof.

39. A process for producing a plant with reduced bitterness in some or all of its plant parts, said process comprising reducing the production of germacrene A opr a sesquiterpenoid lactone derived from germacrene A in said plant.