WO1999054480A1 - Transgenic plants presenting a modified inulin producing profile - Google Patents
Transgenic plants presenting a modified inulin producing profile Download PDFInfo
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- WO1999054480A1 WO1999054480A1 PCT/EP1999/002538 EP9902538W WO9954480A1 WO 1999054480 A1 WO1999054480 A1 WO 1999054480A1 EP 9902538 W EP9902538 W EP 9902538W WO 9954480 A1 WO9954480 A1 WO 9954480A1
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- sst
- enzyme encoding
- fft
- inulin
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- 0 CCC(CCN)=***1[C@](C)(*)C1 Chemical compound CCC(CCN)=***1[C@](C)(*)C1 0.000 description 1
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12N—MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
- C12N9/00—Enzymes; Proenzymes; Compositions thereof; Processes for preparing, activating, inhibiting, separating or purifying enzymes
- C12N9/10—Transferases (2.)
- C12N9/1048—Glycosyltransferases (2.4)
- C12N9/1051—Hexosyltransferases (2.4.1)
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12N—MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
- C12N15/79—Vectors or expression systems specially adapted for eukaryotic hosts
- C12N15/82—Vectors or expression systems specially adapted for eukaryotic hosts for plant cells, e.g. plant artificial chromosomes (PACs)
- C12N15/8241—Phenotypically and genetically modified plants via recombinant DNA technology
- C12N15/8242—Phenotypically and genetically modified plants via recombinant DNA technology with non-agronomic quality (output) traits, e.g. for industrial processing; Value added, non-agronomic traits
- C12N15/8243—Phenotypically and genetically modified plants via recombinant DNA technology with non-agronomic quality (output) traits, e.g. for industrial processing; Value added, non-agronomic traits involving biosynthetic or metabolic pathways, i.e. metabolic engineering, e.g. nicotine, caffeine
- C12N15/8245—Phenotypically and genetically modified plants via recombinant DNA technology with non-agronomic quality (output) traits, e.g. for industrial processing; Value added, non-agronomic traits involving biosynthetic or metabolic pathways, i.e. metabolic engineering, e.g. nicotine, caffeine involving modified carbohydrate or sugar alcohol metabolism, e.g. starch biosynthesis
- C12N15/8246—Non-starch polysaccharides, e.g. cellulose, fructans, levans
Definitions
- the present invention relates to transgenic plants presenting a modified inulin producing profile, to a method for producing said plants, to a method for modifying and controlling the inulin producing profile of plants and to a method for producing inulin from said transgenic plants. Furthermore, the present invention relates to novel 1-SST and 1-FFT enzyme encoding DNA sequences, to novel recombinant DNA constructs and recombinant genes derived thereof, to novel combinations of expressible 1-SST and 1-FFT enzyme encoding genes, as well as to novel polypeptides or fragments thereof presenting 1-SST and /or 1-FFT activity, and to antibodies capable of binding to them.
- Inulin is a fructan type carbohydrate polymer which occurs as a polydisperse composition in many plants and can also be produced by certain bacteria and fungi.
- Inulin from plant origin consists of a polydisperse composition of mainly linear chains composed of fructose units, mostly terminating in one glucose unit, which are linked to each other through ⁇ (2-l) fructosyl-fructose linkages.
- Inulin can be generally represented, depending from the terminal carbohydrate unit, by the formulae GF n and F m , wherein G and F respectively represent a glucose unit and a fructose unit, n is an integer representing the number of fructose units linked to the terminal glucose unit, and m is an integer representing the number of fructose units linked to each other in the polyfructose chain.
- the number of saccharide units (fructose and glucose units) in one molecule i.e. the values n+1 and m in the above formulae, are commonly referred to as the degree of polymerisation, represented by DP.
- the parameter (number) average degree of polymerisation, represented by ( DP) is used, which is the value DPn calculated, after complete hydrolysis and considering that in native inulins the F m fraction is negligible, as follows:
- % refers to weight per cent (wt%).
- G glucose
- F fructose
- GF saccharose
- the average degree of polymerisation is thus the ( DPn) of inulin, herein interchangeably referred to in short as ⁇ DP) inulin or ⁇ DP) (De Leenheer, 1996) .
- the polysaccharide chains of native inulin from plant origin generally have a degree of polymerisation (DP) ranging from 3 to about 100, whereas the ( DP) of the native inulin largely depends from the plant source, the growth phase of the plant, the harvesting time and the storage conditions.
- the ( DP) of isolated inulin largely depends on the ( DP) of the native inulin and on the process conditions used for the extraction, purification and isolation of the inulin from the plant or plant parts.
- native inulin or crude inulin is meant herein inulin that has been extracted from plants or parts of plants, without applying any process to increase or decrease the ( DP), while taking precautions to inhibit the plant's own hydrolase activity and to avoid hydrolysis.
- the ( DP) of native inulin thus essentially corresponds to the ⁇ DP) of the inulin as present in the plant or plant parts.
- the isolated inulin obtained from plants or plant parts through conventional manufacturing techniques, commonly including extraction, purification and isolation, without any process to modify the ⁇ DP) of the native inulin is termed herein, interchangeably, standard ( DP) grade inulin or standard grade inulin.
- standard ( DP) grade inulin or standard grade inulin is usually about 1 to 1.5 lower than the ( DP) of the native inulin.
- Inulin molecules with a DP ⁇ 10 are commonly termed oligofructose, inulo-oligosaccharides or fructo-oligosaccharides (in short FOS). Both, inulin chains with a DP ⁇ 10 and inulin chains with a DP > 10, are embraced herein by the term inulin .
- inulin profile is meant the relative composition of the polydisperse inulin as formed by the individual components including glucose, fructose, sucrose and individual inulin chains, including the distribution pattern of the polyfructose (inulin) chains.
- Linear inulin is common in a specific plant family, the Asteraceae, including the plant species Jerusalem artichoke ⁇ Helianthus tuberosus) and chicory ⁇ Cichorium intybus). Inulin is commonly stored in tap roots (chicory) or in tubers (Jerusalem artichoke) and acts as a storage reserve for regrowth of the sprout after the winter period. 3
- inulin typically sources for the production of inulin at industrial scale are roots of chicory and, on a much smaller scale, tubers of Jerusalem artichoke, in which inulin can be present in concentrations of about 14 % to 18 % by weight on fresh weight. Inulin can be readily extracted from these plant parts, purified and optionally fractionated in order to remove impurities, monosaccharides, disaccharides and undesired oligosaccharides, as for example described in PCT patent application WO 96/01849.
- sucrose sucrose 1-fructosyltransf erase
- fructan fructan 1-fructosyltransf erase
- 1-FFT short 1-FFT enzyme
- GFF trisaccharide kestose
- the 1-SST enzyme cannot catalyse reaction (1).
- the 1-SST enzyme next to reaction (1), can catalyse reactions of type (2) yielding inulin molecules with a low DP (catalysis by known 1-SST enzymes being able to yield inulin molecules with a DP up to about 5). 4
- both the 1-SST and the 1-FFT enzymes are contributing to inulin synthesis and the profile of native inulin is determined, inter alia, by sucrose supply, expression of the 1-SST enzyme encoding genes and 1-FFT enzyme encoding genes and the kinetic properties and relative activity of the 1-SST and 1-FFT enzymes which may be controlled by the relative expression of the 1-SST and the 1-FFT enzyme encoding genes.
- Inulin is an edible, water soluble polydisperse polysaccharide composition which is used in the manufacture of many food and feed products, drinks and non-food products.
- inulin can be used, inter alia, as a bulking agent as well as a total or partial substitute for sugar and /or fat.
- inulin can be added to food, feed and drinks to enrich them with soluble fibres having prebiotic properties.
- inulin can also be used as a component of prophylactic and therapeutic compositions.
- inulin with a ( DP) of about 10 and more is commonly used at industrial scale as starting material for the manufacture of oligofructose and of fructose, which both are increasingly used in industry as sweeteners, particularly in drinks and fruit compositions.
- inulin with a different profile.
- the inulin molecules should have a low DP, preferably about 3 to 8, whereas for use as fat replacer inulin should preferably have a ⁇ DP) higher than 15.
- inulin may have to be derivatised, for example to obtain carboxymethylated inulin which can be used as sequestering agent for divalent cations.
- Inulin suitable as starting material in derivatisation reactions should preferably have a ( DP) of at least 20, whereas its level of low molecular weight sugars should be very low.
- Standard grade inulin from chicory or Jerusalem artichoke has a too low ( DP) and a too high level of low molecular weight sugars, which makes derivatisation of said inulins difficult.
- inulin which is low in mono- and disaccharides and has a high average degree of polymerisation, preferably a ( DP) of at least 20
- various techniques have already been disclosed, for example, a method of manufacture involving a directed crystallisation starting from native or standard grade chicory inulin as described in PCT patent application WO 96/01849.
- Inulin with such a profile is also very suitable as ingredient in various food, feed, drinks and non-food applications, and as starting material for the manufacture of hydrolysates and derivatives of inulin.
- oligofructose usually standard grade chicory inulin or preferably chicory inulin with a higher ( DP) , e.g. a ⁇ DP) of at least 20, is 5 subjected to partial, enzymatic hydrolysis, whereas to prepare fructose, typically in the form of a fructose syrup, said inulins are subjected to complete enzymatic or acidic hydrolysis, as for example described in patent applications PCT/BE97/00087 and EP 97870111.8
- every treatment of native inulin or standard grade inulin to reduce the content of low molecular weight sugars, to increase the ( DP) of the inulin, to modify the inulin profile, particularly to modify the distribution pattern of the inulin chains of the source inulin, or to transform inulin into oligofructose requires one or more additional processing steps, such as, for example, size fractioning or hydrolysis. These additional process steps inevitably result in technical and economical disadvantages.
- the terms genetically modified, transformed and transgenic are used interchangeably;
- the terms 1-SST or 1-SST enzyme and 1-FFT or 1-FFT enzyme refer to the respective enzymes, whereas the terms sstl03 or sstl03 sequence and fftlll or fftll 1 sequence indicate an example of a 1-SST, respectively 1-FFT encoding DNA sequence, and the terms sstl03 gene and fftlll gene indicate an example of a 1-SST, respectively a 1-FFT enzyme encoding gene.
- PCT patent application WO 96/01904 claims a method for producing fructo-oligosaccharides from a transgenic plant containing a gene construct comprising a fructosyl transferase encoding/* 1 / gene from Streptococcus mutans _ a fructosyl transferase encoding Sac B gene from Bacillus subtilus or a mutated version of said genes.
- the invention aims particularly low molecular fructo-oligo-saccharides having a DP 3 to 4.
- the patent application WO 96/01904 describes the isolation of an SST enzyme from onion and shows the activity of the purified enzyme in vitro by incubation with sucrose with the formation of 1-kestose only. Neither the DNA sequence coding for this SST enzyme nor the amino acid sequence of the purified SST enzyme were disclosed.
- the patent application also discloses the sequences of two other fructosyl-transferases and the use of the 6-sft gene isolated from barley, where it is involved in the biosynthesis of non-inulin type branched fructans, in an heterologous screening leading to the isolation of the cDNA sequences of two virtually identical genes from the flowers of onion, respectively pAC22 and pAC92, which have been tested separately in 6 protoplasts of tobacco.
- a 6-G-FFT enzyme can not use saccharose as donor of a fructosyl residue (as a 1-SST enzyme does) but needs kestose as a fructosyl unit donor, and (ii) the 6-G-FFT enzyme catalyses the synthesis of neokestose (FGF) constituting the starting moiety for the building up of a fructan of the inulin neoseries class, whereas the 1-SST enzyme catalyses the synthesis of kestose (GFF) constituting the starting moiety for the building up of a fructan of the inulin class.
- FGF neokestose
- GFF kestose
- a 6-G-FFT enzyme can catalyse only the production of polysaccharide chains with a low DP, i. e. a DP ⁇ about 10
- a 1-FFT enzyme can catalyse the synthesis of polysaccharide chains with a higher DP, i.e. a DP up to about 70 and even up to about 100.
- Vijn et al., 1997 disclosed that introduction of the onion 6-G-FFT enzyme encoding sequence in chicory resulted in a transgenic plant which made linear inulins (i.e. genuine chicory inulin) and in addition fructans 7 of the inulin neoseries.
- the native 1-SST enzyme encoding sequences together with the native 1-FFT enzyme encoding sequences of the chicory ensured via the corresponding enzymes the synthesis of the native inulin molecules, whereas the native 1-SST enzyme encoding sequences together with the onion 6-G-FFT enzyme encoding sequence lead via the corresponding enzymes to the synthesis of inulin neoseries of low molecular weight.
- PCT patent application WO 96/21023 discloses a 1-SST encoding DNA sequence and a 1-FFT encoding DNA sequence both from J. artichoke, designated sstl03 (or pSST103 when referring to the original clone being the sstl03 inserted in the pBluescript SK vector) and fftl 11 (or pFFTlll when referring to the original clone being the fftlll inserted in the pBluescript SK vector), respectively, the construction of recombinant genes comprising said 1-SST enzyme or 1-FFT enzyme encoding sequence, and the transformation of plants (petunia and potato plants) by insertion of said sstl03 gene or fftlll gene in the plant genome.
- inulin As a result thereof industry is continuously confronted with problems regarding the supply of inulin, particularly the supply of inulin compositions with desirable inulin 8 profiles of highly linear polysaccharide chains.
- Said inulin compositions should preferably be readily and directly producible at industrial scale from plant sources at economically interesting costs.
- Preferably said production should be possible by conventional manufacturing processes and without additional process steps to modify the inulin profile of the native inulin, since each additional process step would inevitably increase the manufacturing costs and reduce the overall yield of suitable inulin.
- the object of the present invention is, inter alia, to provide a method by which said and other problems can be solved, as well as to provide means for use in said method. Description of the invention.
- sstl03 a 1-SST encoding DNA sequence, termed sstl03 , from the genome of J. artichoke is disclosed which codes for a 1-SST that catalyses in a plant the conversion of sucrose into kestose, thus enabling the plant to synthesise kestose (GFF), the smallest inulin molecule, from sucrose.
- GFF synthesise kestose
- the inventors have now discovered the existence of a further 1-SST encoding DNA sequence in the genome of J. artichoke which apparently is part of a sleeping gene of said genome.
- the sequence has been identified in the form of its cDNA by DNA sequencing and this cDNA sequence, termed a33 , is given in SEQ ID NO: 1 and is shown in Fig 1 as A33.
- Fig. 1 also the corresponding amino acid sequence is indicated, given in SEQ ID NO: 2 .
- c86b This cDNA sequence termed c86b , is given in SEQ ID NO: 3 and is shown in Fig 2 A as C86B, together with the corresponding amino acid sequence, given in SEQ ID NO: 4.
- the a33 cDNA sequence can be expressed in a host organism, particularly a plant or a plant part, to produce active 1-SST, when it is inserted in reading frame in a proper DNA construct in the genome of the organism.
- Said construct typically comprises the a33 cDNA sequence operably linked in the normal orientation to a promoter sequence and to a terminator sequence which are active in said host organism.
- the construct is preferably further comprising an operably linked DNA sequence encoding a targeting signal or a transit peptide which ensures targeting of the a33 encoded 1-SST enzyme to a specific subcellular compartment.
- the constructs, thus constituting a 1-SST enzyme encoding 9 recombinant gene can be introduced into the genome of the host organism by conventional techniques.
- said a33 cDNA sequence codes for an 1-SST enzyme which catalyses not only the transformation of sucrose to kestose and to lower oligofructoses (DP ⁇ about 5), as do the known 1-SST enzyme encoding DNA sequences such as e.g. sst!03 from J. artichoke , but encodes an 1-SST enzyme which is also able to catalyse the synthesis of higher fructo-oligosaccharides (DP up to about 10) in a plant.
- the a33 cDNA thus encodes in fact a 1-SST enzyme which has an activity which extends beyond the one of the known 1-SST enzymes, e.g. the 1-SST enzyme encoded by the sstl03 cDNA, and has also an activity which is with respect to the building up of inulin chains functionally comparable to an aspect of a 1-FFT enzyme.
- the c86b cDNA sequence can be expressed in a host organism, particularly a plant or a plant part, to produce active 1-FFT, when it is inserted in reading frame in a proper DNA construct in the genome of the host organism.
- Said construct typically comprises the c86b cDNA sequence operably linked in the normal orientation to a promoter sequence and to a terminator sequence which are active in said host organism.
- the construct is preferably further comprising an operably linked DNA sequence encoding a targeting signal or a transit peptide which ensures targeting of the c86b encoded 1-FFT enzyme to a specific subcellular compartment.
- the constructs, thus constituting a 1-FFT enzyme encoding recombinant gene (in short herein l-bblc86b gene), can be introduced into the genome of the host organism by conventional techniques.
- Expression of said recombinant gene in a host plant results in the production of 1-FFT, which catalyses, as mentioned above, the stepwise synthesis of inulin by transformation of an oligofructose chain or inulin chain into an inulin molecule with a higher DP.
- a host organism in particular a plant, can be transformed to comprise in its genome a combination of one or more expressible 1-SST enzyme encoding genes and one or more expressible 1-FFT enzyme encoding genes, wherein either the 1-SST enzyme encoding genes or the 1-FFT enzyme encoding genes or both comprise one or more recombinant genes containing one or more 1-SST enzyme encoding DNA sequences, respectively one or more 1-FFT enzyme encoding DNA sequences, of plant origin, resulting in a transgenic organism, particularly a transgenic plant, with a modified inulin producing profile.
- the inventors have found that the inulin producing profile of a plant and the profile of the inulin produced by a plant can be modified and even controlled, i.e. modified to yield a desired inulin profile, by producing a transgenic plant which comprises in its genome a combination of one or more expressible 1-SST enzyme encoding genes and one or more expressible 1-FFT enzyme encoding genes which code for 1-SST and 1-FFT enzymes with different kinetic properties.
- Either the 1-SST enzyme encoding genes or the 1-FFT enzyme encoding genes or both comprise one or more recombinant genes containing one or more 1-SST enzyme encoding DNA sequences, respectively one or more 1-FFT enzyme encoding DNA sequences, from plant sources, the latter 1-SST encoding sequences and 1-FFT encoding sequences being from the same or from different plant sources.
- the invention relates to a method for producing a transgenic plant by transforming a host plant to comprise in its genome a combination of one or more expressible 1-SST enzyme encoding genes and one or more expressible 1-FFTenzyme encoding genes, wherein either the 1-SST enzyme encoding genes or the 1-FFT enzyme encoding genes or both comprise one or more expressible recombinant genes containing one or more expressible 1-SST enzyme encoding DNA sequences, respectively one or more expressible 1-FFT enzyme encoding DNA sequences which are of plant origin, comprising transforming a host plant by inserting one or more of said 1- SST enzyme encoding genes and /or one or more of said 1-FFT enzyme encoding genes into the genome of the host plant, yielding a transgenic plant with a modified inulin producing profile.
- said 1-SST encoding DNA sequence(s) and said 1-FFT encoding DNA sequence(s) of said recombinant genes are not restricted to the sequences as obtained from the plant sources, but also include expressible homologous sequences thereof with a degree of homology of at least 70 %, preferably at least 75%, more preferably at least 80% , even more preferably at least 85%, and most preferably at least 90% , respectively, irrespective whether or not the homologous sequences are derived from plant sources or are obtained by mutagenesis of DNA sequences from plant sources or from micro-organisms.
- inulin is meant herein fructans of the inulin class, i.e. molecules of the general formulae GF n and F m , as defined above, exclusive of fructans of the inulin neoseries class corresponding to the general formula 11
- modified inulin producing profile is meant the production of inulin by a transgenic plant which is quantitatively and /or qualitatively different from the production of inulin by the non-transformed host plant.
- modified inulin profile is meant an inulin profile which is qualitatively different from the one of the inulin produced by the host plant, i.e. an inulin composition wherein the ratio of monosaccharides, disaccharides, oligo- saccharides and /or the distribution pattern of the chain length of the individual inulin molecules, i.e. the DP and the ⁇ DP), are different from the ones of the inulin composition produced by the non-transformed host plant.
- the term modified inulin producing profile is embracing herein a modified inulin producing profile, a controlled inulin producing profile as well as a modified inulin profile and a controlled inulin profile.
- the non-transformed host plant suitable for the invention can be an inulin producing plant containing in its genome one or more 1-SST encoding genes and 1-FFT encoding genes or only 1-SST encoding genes, or a non-inulin producing plant. If in the genome of the host plant a 1-FFT encoding gene and /or a 1-SST encoding gene is present, when producing the desired transgenic plant according to the present invention said gene or genes can be maintained or their expression can be totally or partially suppressed by known techniques. For example the expression of said genes can be suppressed through anti-sense expression or co-suppression strategies.
- the said 1-SST enzyme encoding genes can consist of a native gene or a mixture of different native genes, of a mixture of native and recombinant genes, or of one or more different recombinant genes.
- said combination of 1-SST encoding gene(s) and 1-FFT encoding gene(s) comprises known 1-SST encoding gene(s), respectively known 1-FFT encoding gene(s), these known genes may be the ones which are present in the genome of the non-transformed host plant. If said combination comprises recombinant genes, their 1-SST enzyme encoding sequence, respectively the 1-FFT enzyme encoding sequence, can be a known one or a novel one, from a plant source, or a homologous sequence 12 thereof, as defined above, which encodes a 1-SST enzyme, respectively a 1-FFT enzyme.
- both the 1-SST enzyme encoding genes and the 1-FFT enzyme encoding genes comprise a recombinant gene
- the 1-SST enzyme encoding sequence(s) and the 1-FFT enzyme encoding sequence(s) of said recombinant genes can be from the same or from different plant species.
- the 1-SST encoding sequences may be identical or not, may be present in one or in different genes, and these 1-SST encoding genes, respectively 1-FFT encoding genes, may be present on one or on different chromosomes.
- the recombinant 1-SST encoding gene comprises said a33 cDNA sequence or an expressible homologous sequence thereof as defined above.
- the recombinant 1-FFT encoding gene comprises said c86b cDNA sequence or an expressible homologous sequence thereof as defined above.
- the recombinant 1-SST encoding gene comprises said a33 cDNA sequence or said homologous sequence and the 1-
- FFT encoding gene comprises said c86b cDNA sequence or said homologous sequence.
- Said homologous sequences are at least 70 % identical to said a.33 cDNA, respectively to said c86b cDNA, irrespective of whether or not the homologous sequences are derived from an other plant species or are obtained by mutagenesis of fructosyltransferase-encoding sequences from plant sources or from micro-organisms.
- the degree of homology is at least 75%, more preferably at least 80% , and even more preferably at least 85%. Most preferably the degree of homology is at least 90%.
- the transgenic plant has been produced by inserting into the genome of a host plant a combination of one or more genes with a known 1-FFT enzyme encoding DNA sequence and one or more genes with the 1-SST enzyme encoding a33 cDNA sequence or said respective homologous sequences thereof which encode a 1-FFT enzyme, respectively, a 1-SST enzyme.
- the transgenic plant has been produced by inserting into the genome of a host plant a combination of one or more genes with a known 1-SST encoding DNA sequence and one or more genes with the 1-FFT enzyme encoding c86b cDNA, 13 or said respective homologous sequences thereof.
- the transgenic plant has been produced by inserting into the genome of a host plant a combination of one or more genes with the 1-SST enzyme encoding a33 cDNA sequence or a said homologous sequence thereof and one or more genes with the 1-FFT enzyme encoding c86b cDNA or a said homologous sequence thereof.
- the host plant is a non-inulin producing plant.
- Typical combinations of 1-SST encoding genes and 1-FFT encoding genes according to the invention comprise respectively a 1-SST enzyme encoding sequence or a said homologous sequence thereof and a 1-FFT enzyme encoding sequence or a said homologous sequence thereof selected from plant species of the Asteraceae family, with the 1-SST encoding sequence and the 1-FFT encoding sequence being selected from the same or from different plant species.
- 1-SST encoding genes and 1-FFT encoding genes comprise respectively a 1-SST enzyme encoding sequence or a said homologous sequence thereof and a 1-FFT enzyme encoding sequence or a said homologous sequence thereof selected from plant species from the same or different plant families of the group consisting of the Asteraceae (Compositae) and Campanulaceae, comprising plant species such as, for example, Echinops, species, Helianthus tuberosus, Cichorium intybus, Dahlia species, Cynara species, Viguiera species, such as e.g.Viguiera discolor, Viguiera deltoida, Viguiera annua, Viguiera lanata, Viguiera multiflora, Veronia herbacea, Scorzonera hispanica, Tragopogon porriflorus, Taraxacum, species, Arctium lappa, Campanula rapuncolo ⁇ des and Bellis perennis.
- Asteraceae Com
- suitable DNA sequences include, for example, the 1-SST encoding sequences sstl03 (J. artichoke), a33 (J. artichoke), c33 (chicory), Genbank accession No U81520 (chicory), Genbank accession No Y09662 ⁇ Cynara scolymus), and the 1-FFT encoding sequences c86b (chicory) and fftlll (J. artichoke).
- the 1-SST encoding sequences sstl03 J. artichoke
- a33 J. artichoke
- c33 chicory
- Genbank accession No U81520 chicory
- Genbank accession No Y09662 ⁇ Cynara scolymus Genbank accession No Y09662 ⁇ Cynara scolymus
- 1-FFT encoding sequences c86b (chicory) and fftlll J. artichoke
- a transgenic plant in combination with the selection of a proper ratio between the expression of the 1-SST encoding and 1-FFT encoding genes and the selection of a suitable host plant, a transgenic plant can be produced according to the invention with a desired modified inulin producing profile.
- the selection of proper combinations of said parameters by routine experiments makes it possible to produce inulin with an almost tailored profile and to modify in a desired manner the inulin producing profile of a given host plant.
- the genome of the transgenic plant comprises a combination of said expressible 1-SST encoding genes and said expressible 1-FFT encoding genes which induces the synthesis of native inulin with a degree of polymerisation which is higher, respectively lower, than the one of the native inulin produced, if any, by the non-transformed host plant.
- a method for producing a transgenic plant by transforming a host plant to comprise in its genome a combination of one or more expressible 1-SST encoding genes, originating from the host plant or from a different plant source and one or more l-SST ⁇ 33 genes. If the host plant contains a native 1-SST encoding gene and a native 1-FFT encoding gene in its genome, the expression of the native 1-FFT encoding gene or of both the native 1-SST encoding gene and the native 1-FFT encoding gene can optionally be suppressed by known techniques, for example through anti-sense expression.
- a transgenic plant is produced by inserting into the genome of a host plant which does not contain a 1-SST encoding gene nor a 1-FFT encoding gene, one or more 1-SST a33 genes or genes which contain a cDNA sequence which is an homologous sequence thereof, as defined above, which encodes an a33 1-SST enzyme.
- This particular embodiment of the present invention has become possible as a result of the fact that the 1-SST a33 gene codes for an enzyme which presents an activity of a 1- SST enzyme, i.e.
- the transgenic plant can be 15 produced by inserting into the genome of the host plant by conventional techniques one or more expressible 1-SST «33 genes or expressible homologues thereof, or one or more of said expressible 1-SST encoding genes from plant sources or said homologues thereof and /or one or more of said expressible 1-FFT encoding genes from plant sources or said expressible homologues thereof, resulting in a transgenic plant which comprises in its genome one or more l-SST ⁇ 33 enzyme encoding genes or combination of said 1-SST encoding genes and said 1-FFT encoding genes as defined herein above.
- a cell of a host plant is transformed to comprise in its genome a said combination of 1-SST encoding genes and 1-FFT encoding genes as defined above, by inserting by conventional techniques one or more of said genes into the genome of the cell, followed by regenerating a transgenic plant from said transformed cell. If the host plant is transformed with both said 1-SST encoding genes and said 1-FFT encoding genes, the genes can be inserted into the host genome simultaneously or in subsequent steps.
- said method comprises the following subsequent steps which can be carried out by conventional techniques: i) the preparation of a recombinant gene construct comprising one or more 1-SST enzyme encoding DNA sequences, respectively 1-FFT enzyme encoding DNA sequences as defined above, operably linked to a promoter sequence active in said host plant and a terminator sequence active in said host plant, ii) introduction of the recombinant gene construct obtained in step i) into the genome of a cell of the host plant, and iii) regeneration of the transformed plant cell obtained in step ii) to the corresponding transgenic plant. More specifically the method of the invention comprises preferably the following subsequent steps: a) the construction of a recombinant gene, i.e. a recombinant DNA construct, comprising essentially the following sequences:
- a promoter which ensures the formation of a functional RNA or a functional protein in the intended target plant, target organs, tissues or cells thereof,
- a DNA sequence encoding a targeting signal or a transit peptide which ensures targeting of the 1-SST enzyme, respectively the 1- FFT enzyme to a specific subcellular compartment b) the introduction of the recombinant gene obtained in a) into the genome of the host plant yielding genetically modified material, typically a cell, comprising said combination of 1-SST enzyme and 1- FFT enzyme encoding sequences, and regeneration of the genetically transformed material in the corresponding transformed host plant.
- one or more copies of the 1-SST and 1-FFT enzyme encoding DNA sequences are preferably linked to one or more regulatory sequences which are operational in the host plant ensuring proper expression of said DNA sequence at a sufficiently high expression level in the host plant, in the different plant organs, tissues or cells.
- Regulatory sequences are, for example, a promoter, a termination signal and a transcription or translational enhancer.
- a promoter can, for example, be the 35S promoter of the cauliflower mosaic virus (CaMV) or an organ-specific promoter like the tuber-specific potato proteinase inhibitor II promoter, or any other inducible or tissue-specific promoter.
- a highly preferred promoter is a promoter which is active in organs and cell types which normally accumulate sucrose (the primary substrate for inulin synthesis).
- the production of inulin is particularly advantageous in the vacuole which can accumulate very high concentrations of sucrose (e.g. up to about 500 mol m " 3 ).
- the DNA sequence encoding 1-SST or 1-FFT enzyme is preferably linked to a sequence encoding a transit peptide which directs the mature 1-SST or 1-FFT enzyme protein to a subcellular compartment containing sucrose, such as for example said vacuole.
- the host plant is a non-inulin producing plant; in another preferred embodiment, the host plant is an inulin producing plant.
- Typical host plants for use in the method according to the invention are plants which can easily be grown, which are rather resistant to attack by injurious organisms such as insects and fungi, which give a high yield of plant material per hectare and which can be easily harvested and processed.
- said plants should after transformation be able to produce large amounts of inulin, give a high content of produced inulin based on fresh plant material 17 and preferably be able to deposit said inulin in a concentrated manner in parts of the plant, preferably in tap roots or tubers, which can be easily harvested, stored and processed.
- typical host plants for use in the method of the invention are non- inulin producing plants which are quite sensitive to abiotic stresses such as, for example, drought, cold, and other ones. Transformation of said host plants according to the present invention resulting in a transgenic plant which is producing inulin, even in a quite low level, may significantly increase the resistance of the plant against said abiotic stresses, particularly against drought and/or cold.
- Typical host plants suitable for use in the method according to the invention include corn, wheat, rice, barley, sorghum, millets, sunflower, cassava, canola, soybean, oil palm, groundnut, cotton, sugar cane, chicory, bean, pea, cawpea, banana, tomato, beet, sugar beet, Jerusalem artichoke, tobacco, potato, sweet potato, coffee, cocoa and tea.
- the present invention provides a method for modifying the inulin producing profile of a plant and for controlling the profile of the inulin produced by a plant, which comprises genetically transforming a plant by inserting into its genome one or more expressible l-SST ⁇ 33 genes or expressible homologues thereof, or one or more expressible 1-SST encoding genes, and/or one or more expressible 1-FFT encoding genes, as defined above, yielding a transgenic plant comprising in its genome a combination of said 1- SST encoding genes and said 1-FFT encoding genes, as defined herein above, which plant, when cultured under conventional conditions, shows a modified inulin producing profile.
- the present invention relates to a method for producing inulin from plant material, particularly inulin with a modified profile, by conventional techniques, wherein the source plant material for the method is material, typically tap roots or tubers, from a transgenic plant which comprises in its genome one or more expressible
- transgenic plant is obtainable by a method of the present invention as described herein before.
- the production of inulin from plant parts is well known in the art and commonly comprises (i) an isolation step, wherein the crude, native inulin is isolated from the plant material (typically involving extraction of shredded plant parts e.g.
- a 18 purification step typically comprising a depuration treatment (involving liming and carbonatation or another flocculation technique and filtration) followed by a refining treatment (involving treatment over ion-exchangers, treatment with active carbon and filtration) and optionally a concentration of the purified inulin solution, and (iii) an isolation step wherein the inulin is isolated in particulate form from the purified inulin solution obtained in (ii), for example by spray-drying or by directed crystallisation, filtration and drying.
- a depuration treatment involving liming and carbonatation or another flocculation technique and filtration
- a refining treatment involving treatment over ion-exchangers, treatment with active carbon and filtration
- an isolation step wherein the inulin is isolated in particulate form from the purified inulin solution obtained in (ii), for example by spray-drying or by directed crystallisation, filtration and drying.
- the invention further embraces the novel DNA sequences a.33 cDNA and c86b cDNA , and homologous sequences thereof, as defined above, encoding respectively 1-SST enzyme and 1-FFT enzyme, as well as novel recombinant
- novel recombinant genes and vectors comprising one or more of said novel cDNA sequences.
- Said novel cDNA sequences are suitable intermediates for the construction of said novel recombinant DNA constructs and recombinant genes, which are on their turn, suitable intermediates and tools for the production of transgenic plants presenting a modified inulin producing profile according to the present invention.
- the invention furthermore embraces a novel combination of one or more expressible 1-SST encoding genes and one or more expressible 1-FFT encoding genes, wherein either the 1-SST encoding genes or the 1-FFT encoding genes or both comprise one or more recombinant genes of which one or more of the
- 1-SST enzyme encoding DNA sequences and one or more of the 1-FFT enzyme encoding DNA sequences are of plant origin or homologues thereof, as defined above.
- Said novel combination of genes constitutes a suitable intermediate and tool for the production of transgenic plants according to the present invention.
- the invention also embraces a transgenic plant, producible by a method according to the present invention, the genome of which comprises a combination of one or more expressible 1-SST encoding genes and one or more expressible 1-FFT encoding genes, as defined above.
- the present invention also includes cells, plant tissue, plant parts, roots and shoots of transgenic plants according to the invention as well as seeds thereof, which comprise in their genome a combination of one or more expressible 1-SST encoding genes and one or more expressible 1-FFT encoding genes, as defined above.
- the present invention also includes novel inulin compositions, i.e. inulin having a novel inulin profile, obtainable by a method according to the present invention, and the use thereof in the manufacture of food, feed, drinks, and non-food compositions, of derivatives of inulin , and of partial and complete hydrolysates of inulin . 19
- the present invention relates to a purified and isolated polypeptide having an amino acid sequence as shown in SEQ ID NO:2, respectively in SEQ ID NO: 4, and to purified and isolated respective homologues thereof having at least 70% homology, preferably at least 75%, more preferably at least 80% , even more preferably at least 85%, and most preferably at least 90% homology, as well as to a fragment of said polypeptides, which polypeptides, said homologues thereof and said fragments thereof have 1-SST, respectively 1-FFT, activity.
- Said polypeptides, homologues and fragments can be obtained according to conventional techniques. For example the polypeptides of SEQ ID NO: 2 and of
- SEQ ID NO: 4 can be obtained from chicory roots through a purification procedure based on ammonium sulphate precipitation, followed by lectin affinity chromatography, anion- and cation exchange chromatography.
- the present invention relates to antibodies capable of specifically binding one or more polypeptides and/or homologues and /or fragments thereof as defined above.
- Fig. 1 shows the nucleotide sequence (SEQ ID NO: 1) (A33) and deduced amino acid sequence (SEQ ID NO: 2) of the isolated a.33 cDNA .
- Fig. 2A shows the nucleotide sequence (SEQ ID No. 3) (C86B) and deduced amino acid sequence (SEQ ID No. 4) of the isolated c86b cDNA.
- Fig. 2B shows the nucleotide sequence (SEQ ID No. 5) (C33) and deduced amino acid sequence (SEQ ID No. 6) of the isolated c33 cDNA.
- Fig. 3 depicts a Southern blot analysis of Helianthus tuberosus genomic DNA probed with an a33 PCR fragment. H. tuberosus DNA was digested with EcoRI, £coR5, Xbal, AflHI, Oral, Ndel, Hindi and, Xhol. Plasmid pA33 (the a33 cDNA in the pBluescript vector) was used as a positive control, potato DNA digested with EcoRI was used as negative control.
- Fig. 4 depicts a Northern blot analysis of RNA isolated from various tissues from Helianthus tuberosus. : RNA was isolated from dormant tubers (lane 1), sprouting tubers ( lane 2), stolons (lane 3), tubers with a 2-5 mm diameter (lane 4), tubers with a 2-2.5 cm diameter (lane 5), tubers with a 5-7 cm diameter (lane 6), leaves (lane 7), stems (lane 8), fibrous roots (lane 9), receptacle (lane 10) and flower (lane 11). RNA was probed with an sstl03 (Fig. 4A), fftlll (Fig. 4B) or a33 PCR fragment (Fig. 4C). 20
- Fig. 5 presents the chimeric gene construct pA33.236 consisting of the enhanced CaMV35S promoter (Penh35S) with a ALMV translational enhancer (amv) , the coding sequence of a33 (a33) and the nos- termination signal (Tnos).
- Plant no 27B, 50, 83, 93 and 23 represent individual potato plants harbouring the pA33.236 construct.
- Control is a control plant harbouring the AGL0 construct. Form each plant (control plant as well as transgenic plants) two tubers were analysed (lanes 1 and 2) and one leaf (lane 3).
- Fig. 7 shows HPAEC separations of carbohydrates extracted from leaves of control potato transformed with AGL0 lacking the binary vector (A), from leaves of transgenic potato harbouring the pA33.236 construct (B) and a standard inulin extracted from chicory tap roots (C),
- Fig. 8 represents the chimeric gene construct pUCPA33.342 consisting of the coding sequence of a33 (a33) under control of the enhanced CaMV35S promoter (Penh35S) and the nos -termination signal
- Fig. 9 represents the chimeric gene construct pUCPCA342.25 harbouring the coding sequences of a33 (a33) and c86b (c86b), each under control of the enhanced CaMV35S promoter (Penh35S) and the nos terminator (Tnos) v the ALMV translational enhancer (amv), and the herbicide resistance gene (pat) under control of the promoter (P35S) and terminator sequences (T35S) of the CaMV35S gene.
- Fig. 9 represents the chimeric gene construct pUCPCA342.25 harbouring the coding sequences of a33 (a33) and c86b (c86b), each under control of the enhanced CaMV35S promoter (Penh35S) and the nos terminator (Tnos) v the ALMV translational enhancer (amv), and the herbicide resistance gene (pat) under control of the promoter (P35S) and terminator sequences (T35S) of the CaMV35S gene.
- 10 represents the chimeric gene construct pUCPSF344.18 harbouring the coding sequences of fftlll (1-fft) and sstl03 (1-sst), each under control of the enhanced CaMV35S promoter (Penh35S) and the nos - termination signal (Tnos), the ALMV translational enhancer (amv), and the herbicide resistance gene (pat) under control of the promoter (P35S) and terminator sequences (T35S) of the CaMV35S gene.
- Penh35S enhanced CaMV35S promoter
- Tnos nos - termination signal
- amv ALMV translational enhancer
- pat herbicide resistance gene
- Fig. 11 represents the chimeric gene construct pUCPSC344.14 harbouring the coding sequences of c86b (c86b) and sstl03 (1-sst), each under control of the enhanced CaMV35S promoter (Penh35S) and the nos - 21 termination signal (Tnos), the ALMV translational enhancer (amv), and the herbicide resistance gene (pat) under control of the promoter (P35S) and terminator sequences (T35S) of the CaMV35S gene.
- Fig. 11 represents the chimeric gene construct pUCPSC344.14 harbouring the coding sequences of c86b (c86b) and sstl03 (1-sst), each under control of the enhanced CaMV35S promoter (Penh35S) and the nos - 21 termination signal (Tnos), the ALMV translational enhancer (amv), and the herbicide resistance gene (pat) under control of the promoter (P35S) and terminator sequences (T35S) of the
- FIG. 12 represents the chimeric gene construct pUCPAF21.17 harbouring the coding sequences of a33 (a33) and fftlll (1-fft), each under control of the enhanced CaMV35S promoter (Penh35S) and the nos -termination signal (Tnos), the ALMV translational enhancer (amv), and the herbicide resistance gene (pat) under control of the promoter (P35S) and terminator sequences (T35S) of the CaMV35S gene.
- Fig. 14 shows HPAEC separations of carbohydrates extracted from tap root of transgenic sugar beet line 7PSF22 expressing the sstl03 and fftlll genes.
- Fig. 15 shows HPAEC separations of carbohydrates extracted from tap root of chicory.
- Fig. 16 shows HPAEC separations of carbohydrates extracted from tap root of transgenic sugar beet line 9PSC2 expressing the sstl03 and c86b genes.
- Fig. 17 shows HPAEC separations of carbohydrates extracted from tap root of transgenic sugar beet line 8PAF5 expressing the a33 and fftlll genes.
- Fig. 18 shows HPAEC separations of carbohydrates extracted from tap root of transgenic sugar beet line 8PAF1 expressing the ⁇ 33 and fftlll genes.
- the invention provides novel plant sources of inulin thus helping to solve the problem of sufficiency of inulin supply.
- Said plant sources may comprise known inulin producing plants which as a result of a genetically modification according to the invention produce more inulin and /or inulin of a preferred modified profile entailing improved functional properties, as well as non-inulin producing plants which have been transformed to produce inulin, particularly inulin having a desired profile.
- the method according to 22 the present invention enables to obtain directly, i.e. without any additional process steps such as e.g. size fractioning or partial hydrolysis, inulin with a certain desirable inulin profile, such as inulin essentially composed of inulin chains with a DP ⁇ 10. This obviously has considerable advantages with respect to manufacturing and manufacturing costs.
- the invention provides the possibility of producing many transgenic plant species and variants thereof within the scope of the present invention, resulting from the flexibility of the method of the present invention for producing a transgenic plant with a modified inulin producing profile.
- the possibility to produce many different transgenic plants starting from different host plant species and by using various different combinations of the 1-SST and/or 1-FFT enzyme encoding sequences according to the invention, i.e. including different 1-SST, respectively 1-FFT enzyme encoding DNA sequences originating from various different plant species or homologous sequences thereof, as defined above, and different ratio's of said 1-SST, respectively 1-FFT enzyme encoding DNA sequences, enables to produce various inulin compositions with a different, desired profile.
- Said desired inulin profile is often translated in improved functional properties of the inulin and commonly in improved physico-chemical and /or or anoleptic properties of end products containing said inulin, and of hydrolysates and of derivatives of said inulin.
- the invention enables furthermore to produce transgenic plant species like for example cultural crops and ornamental plants with an increased resistance against abiotic stresses like e.g. drought and /or cold, which also results in economically important advantages.
- polypeptides, homologues and fragments thereof, as defined above may be used to catalyse specific in vitro chemical reactions, such as, for example, the use of polypeptide of SEQ ID NO: 2 in the synthesis of 1-kestose from sucrose by a fructosyl transfer reaction; the use of polypeptide of SEQ ID NO:4 in the synthesis of fructo-oligosaccharides or inulin by a fructosyl transfer reaction from fructo-oligosaccharides; and the use of a combination of the polypeptides of SEQ ID NO:2 and SEQ ID NO:4, or respective homologues or fragments thereof as defined above, for the synthesis of fructo-oligosaccharides and inulin from one or more carbohydrates selected from the group consisting of sucrose, 1-kestose and oligofructoses.
- DNA and RNA isolation, subcloning, restriction analysis and sequencing were performed using standard methods described in molecular biology manuals (e.g. Sambrook et al. 1989; Ausubel et al. 1994).
- DNA and protein alignments were performed using the DNA analysis software Genworks 2.5.1. (Intelligenetics, Inc., CA). This program uses a progressive alignment method, building the alignment in approximate phylogenetic order using an algorithm similar to FASTA. Protein alignments use a PAM-250 scoring matrix. Construction and screening of a cDNA library from H. tuberosus
- a 840 bp DNA fragment was synthesised by PCR using primers 5'-TACGCTGTCAACTCGTCGG-3' and 5'-TTGAATAGAACATCGGGCTCTAGCG-3' and plasmid pSST103 ⁇ sstl 03 cDNA in pBluescript phagemid, Van der Meer et al. 1998) as a template.
- a 860 bp DNA fragment was obtained by PCR using primers 5'- GTTCAACGCTGCTTGATCCACC-3' and 5'-ACCACGGTCCTTCCAAACGG-3' and plasmid pFFTlll (fftlll cDNA in pBluescript phagemid Van de Meer et al., 1998) as a template.
- the two PCR fragments were radiolabelled by the RadPrime DNA labelling system (Life Technologies). Hybridisation was at 50°C in 500 mM NaP-buffer, pH 7.2, 7% SDS, 1% BSA, 1 mM EDTA. Filters were washed to a final stringency of 2xSSC, 0.1% SDS at 50°C. (2 x 30 min) and finally exposed to X-omat AR (Kodak). Positive plaques were purified in 3-4 rounds of plaque hybridisation. The pBluescript phagemids were excised from the Uni-ZAP vector using the Exassist/Solr system (Stratagene). The inserts were analysed by restriction enzyme analysis and sequencing.
- Hybridisation and washing of Hybond-N + membranes were performed under low stringency conditions (hybridisation at 50°C, final wash step with 2xSSC, 0.1% SDS, 50°C). Positive plaques were purified in 3-4 rounds of plaque hybridisation.
- the lambda TriplEx clones were converted into pTriplEx clones using the cre-recombinase mediated site-specific recombination at the loxP sites flanking the embedded pTriplEx (Clontech). The pTriplEx clones were analysed by restriction enzyme analysis and DNA sequencing.
- PCR was performed in 50 ⁇ l PCR buffer (Life Technologies), containing 100 pmol plasmid as a template, and 100 pmol of gene specific primers (specific for sstl03, fftlll, a33, c33, or c86b, depending on the experiment). Amplification involved 30 cycles of denaturing (0.5 min, 92°C), annealing (1 min, 55°C) and amplification (1 min, 72°C). The resulting fragments were checked by DNA sequencing and restriction digestion to confirm the identity. Transformation of potato Transformation of potato was performed according to Visser (1991), with the following modifications.
- the plasmid ON A- Agrobacterium mixture was incubated on ice, for 30 min, then frozen in liquid nitrogen and thawed in a water bath at 37°C for 5 min. After addition of 1 ml YEP medium, the bacteria were incubated at 28°C for 2 hours with gentle shaking. Cells were pelleted and resuspended in 100 ⁇ l YEP-medium. Finally, transformed bacteria were selected on YEP-agar plates containing 25 mg/1 kanamycin. The presence of pA33.236 was tested by restriction enzyme analysis.
- A. tumefaciens cells, transformed with pA33.236 were grown at 30°C in 5 ml LB medium, containing 50 ⁇ g/ml kanamycin and 100 ⁇ g/ml rifampicin. After 48 h of growth, the cells were washed twice in 5 ml 2 mM MgS ⁇ 4 , then suspended in 5 ml MS medium. Stem internodes were incubated in 20 ml of a diluted (lOOx in MS) A. tumefaciens suspension, and gently shaken for 30 min. After incubation, the stem internodes were blotted dry on filter paper and placed on 25 top of PCM-agar plates (48 h at 21°C).
- Hybridisation was at 65°C in 500 mM NaP-buffer, pH 7.2, 7% SDS, 1% BSA, 1 mM EDTA. Filters were washed to a final stringency of 0.1 x SSC, 0.1% SDS at 65°C (2 x 15 min) and finally exposed to X-omat AR (Kodak).
- Transgenic sugar beets ⁇ Beta vulgaris were generated by a stomatal guard cell based transformation system (Hall et. al. 1996).
- Guard cell protoplasts were obtained from shoot cultures of the diploid breeding line Bv-NF (Hall et. al. 1996).
- One million guard cell protoplasts were transformed with 50 ⁇ g of the plasmid in the presence of PEG. Regeneration and selection of transformants was as described (Hall et. al. 1996). Plants were grown in a greenhouse at 18/15°C (day/night) under a 16 h photoperiod. Two months old leaves were cut to prevent spread with powdery mildew. DNA and RNA analysis of transgenic plants
- Leaf and root tissues were ground in liquid nitrogen to a fine powder. Five hundred mg of the powdered tissue were extracted in 1 ml 50 mM BisTris pH
- the inulin composition of transgenic plants beet was measured by TLC (Thin Layer Chromatography) and HPAEC (High Performance Anion Exchange Chromatography). Two to five months after transfer of the plants to the greenhouse, fresh plant material (500 mg) was collected and cut into 2 mm thick slices with a sterile razor blade. A 20 mM phosphate buffer, pH 7.0, of 100°C was added to the slices to a final volume of 3 ml, and kept at 85°C for 30 min, with occasional vortexing. The extract was centrifuged at 14000 rpm and the supernatant collected.
- TLC analysis was performed on silica gel G (Schleicher and Schuell Nederland BV, The Netherlands) developed two times in a mixture of l-butanol:2-propanol:water 3:12:4. Carbohydrates were stained with a fructose-specific urea phosphoric spray (Wise et al., 1955).
- the extracts were deionized with a mixture of equal amounts of Q- sepharose and S-sepharose Fast How (Pharmacia, Upssala, Sweden), which were pre-equilibrated in 20 mM phosphate buffer, pH 7.0.
- the ion exchanger was added to 50% of the total extract volume, mixed for 5 min at 600 rpm, then centrifuged at 14000 rpm for 2 min. The supernatant was analysed by High Pressure Anion Exchange Chromatography /Pulsed Amperometric Detection (HPAEC-PAD, Dionex, The Netherlands) equipped with 250 x 4 mm CarboPac 27
- PA1 anion exchange column and a 25 x 3 mm CarboPac PA guard column PA1 anion exchange column and a 25 x 3 mm CarboPac PA guard column.
- Inulins were separated with a 80 min linear gradient of 0 to 0.4 mol m NaAc in 0.1 mol m 3 NaOH at a flow rate of 1 ml min 1 , or over 85 minutes with an aqueous gradient (A: NaOH 0.1 mol m "3 ; B: (0.1 mol m “3 NaOH + 0.4 mol m “3 NaAc); C: NaOH 1 mol m "3 ) as follows: min 0-5: A:B 96:4; min 5-15 linear gradient A:B from 96:4 to 60:40; min 15-35: linear gradient A:B from 60:40 to
- Sequence ID. No. 1 The DNA sequence of a.33 (Sequence ID. No. 1) and the corresponding amino acid sequence (Sequence ID. No. 2) is presented in Fig. 1. Sequence ID. No. 1, designated a33 has an open reading frame of 1845 base pairs and encodes a protein of 615 amino acid residues
- sequence ID. No. 2 On DNA level, a33 shows a 70% identity with the 1-SST encoding sstl03 cDNA sequence from H. tuberosus and 54% identity with the 1- FFT encoding fftlll cDNA sequence from H. tuberosus. At the amino acid level, 28 33 shows a 75% similarity with sstl03 fromH. tuberosus and a 58% similarity with fftlll from H. tuberosus.
- Example 2 Isolation of a new cDNA from the cDNA library of Cichorium intybus homologous to sstl 03 and fftlll horn Helianthus tuberosus
- a Lambda TriplEx cDNA library constructed from mRNA isolated from the tap roots of C. intybus, was screened with a mixture of a 840 bp sstl03 and a 860 bp fftlll fragment (see example 1). The primary screening of about 60.000 cDNA clones yielded about 700 positive clones, of which 96 clones were picked.
- Sequence ID. No. 3 designated c86b, has an open reading frame of 1851 base pairs and encodes a protein of 617 amino acid residues (Sequence ID. No. 4). On DNA level, c86b shows a 61% identity with sstl03 from H. tuberosus and 77% identity with fftlll from H. tuberosus. At the amino acid level, c86b shows a 53% similarity with sstl03 from H. tuberosus and a 78% similarity with fftlll from H. tuberosus . The DNA sequence of another clone, designated c33 (Sequence ID. No. 5) and the corresponding amino acid sequence (Sequence ID. No.
- Sequence ID. No. 5 designated c33, has an open reading frame of 1920 base pairs and encodes a protein of 640 amino acid residues (Sequence ID. No. 6). On DNA level, c33 shows a 97% identity with
- a.33 is not expressed to a measurable level in any of the tested tissues (Fig. 4 C).
- 100.000 plaques of the cDNA library of Jerusalem artichoke tubers were blotted onto Hybond filters, hybridised to either an a33, sstl03 or fftlll probe at 65°C, then washed at high stringency (65°C, O.lxSSC, 0.1% SDS).
- Expression levels of a33, sstl03 or fftlll in tubers were 0.001, 1 and 0.2%, respectively. If a33 encodes a functional fructosyltransferase protein, it does not effectively contribute to inulin synthesis in tubers of Jerusalem arti-choke. From a functional point of view, a33 can be considered as a silent gene.
- pFFT405 From the plasmid pFFT405 (see further, for a complete description), which contains the enhanced Cauliflower Mosaic Virus 35S promoter ⁇ enh35S), Alfalfa Mosaic Virus RNA4 leader sequence ⁇ mv), cDN A fftlll from Jerusalem Artichoke and the nos terminator sequence ⁇ Tnos), the complete fftlll sequence was replaced by the ⁇ .33 PCR fragment.
- the eH/z35S- ⁇ rau- ⁇ 33-Ttt ⁇ s-fragment was cut from pA33.102 with Sfld and Sail, and ligated into the plant transformation vector pBLNPLUS (Van Engelen et al., 1995) digested with Sad/ Sail, which resulted in pA33.236 (Fig. 5).
- pFFT 405 was obtained by cloning the Penh35S-amv-fftlll-Tnos-fragment cut 30 from pFFT209 (Van der Meer et al, 1998), with EcoRI (partial digest) and H dIII into pBluescript SK+ (Stratagene, USA) cut with EcoRI/H dffl.
- Example 5 Analysis of transgenic plants expressing the a33 gene
- transgenic potato plants were generated harbouring the pA33.236 construct.
- Ten potato plants were transformed with the Agrobacterium strain AGLO lacking a binary vector. These plants were used as a control.
- Southern blot analysis of genomic DNA isolated from 22 transformed plants showed that 17 plants has integrated into their genome less than 3 copies of the introduced chimeric gene (data not shown).
- Plant numbers 23, 27B, 74, 84 and 93 had integrated one copy.
- Northern analysis showed that a33 was highly expressed in plants numbers 27B, 74 and 93, and less, but still clearly expressed in plant numbers 23 and 84.
- the carbohydrate composition of the a33 harbouring plants was analysed by two essentially different techniques: thin layer chromatography (TLC) and high pressure anion exchange chromatography (HPAEC).
- TLC thin layer chromatography
- HPAEC high pressure anion exchange chromatography
- a33 encodes a fructosyltransferase enzyme, able to synthesise inulins up tot a DP of at least 11. Since the a.33 encodes an enzyme that can catalyse all steps required for inulin synthesis, including reaction (1), the conversion of sucrose into GFF, the a33 encoded enzyme (A33) belongs to the group of SST encoding genes. Example 6.
- Plasmid pUCM2 is derived from the cloning vector pUCAP (Van Engelen et al. 1995). 31
- plasmid pUCM2 To construct plasmid pUCM2 the multiple-cloning-site of plasmid pUCAP was modified by the insertion of two adapters. First, adapter 5'-TCGACCATATCGATGCATG-375'-CATCGCTATTGG-3', containing the restriction sites Sall/Clal/SphI, was cloned in the pUCAP plasmid digested with Sall/Sphl. This resulted in plasmid pUCMl. Next, adapter 5'-TCGACCATATCGATGCATG-375'-CATCGCTATTGG-3', containing the restriction sites Sall/Clal/SphI, was cloned in the pUCAP plasmid digested with Sall/Sphl. This resulted in plasmid pUCMl. Next, adapter 5'-TCGACCATATCGATGCATG-375'-CATCGCTATTGG-3', containing
- Example 7 Construction of a chimeric a33-c86b gene for transformation into sugar beet
- the Notl/Ascl fragment of pUCA33.1, containing the full length A33-cDNA ⁇ a33) was ligated into pUCPC86B.342 cut with Notl/Ascl, yielding pUCPCA342.25. (Fig. 9).
- pUCPCA342.25 was used to transform guard cell protoplasts of sugar beet.
- Example 8 Construction of a chimeric sstl03-fftlll gene for transformation into sugar beet
- the pat gene encoding phosphinotricin acetyl transferase (AgrEvo, Berlin, Germany), which confers bialaphos resistance, was cut from pIGPD7 (Hall et al., 1996) with EcoRI and ligated into pUCM3, digested with EcoRI, which yielded pUCPAT34.
- plasmid pUCM3 was digested with Pacl/Ascl and the whole multiple-cloning-site was replaced by adapter 5'- TAAGGGGTACCACCATCGATACCGAATTCTACATGCATGCATGGAGATC TCCCAAGCTTCTAAGATGCGGCCGCTAAACATGG-375'- CGCGCCATGTTTAGCGGCCGCATCTTAGAAGCTTGGGAGATCTCCATGC ATGCATGTAGAATTCGGTATCGATGGTGGTACCCCTTAAT-3'
- the complete chimerical 22 gene ⁇ Penh35S-amv-fftlll-Tnos) cut from pFFT405 with Noil and Clal was ligated into pUCM2, cut with Notl/Clal, resulting in pUCFT21.
- the complete chimeric sstl03 gene was cut from pUCST21 with Pad and Clal and introduced into pUCPAT34, digested with Pad/ Clal, yielding pUCPS34.4.
- the complete chimeric fft 111 gene was cut from pUCFT21 with
- pUCPSF 344.18 was used to transform guard cell protoplasts of sugar beet.
- PCR fragment (1895 bp) was cloned into pCR-Script Amp SK(+) (Stratagene, USA) yielding p86BpCRscp.
- pFFT405 which contains the enhanced Cauliflower Mosaic Virus 35S promoter ⁇ Penh35S), Alfalfa Mosaic Virus RNA4 leader sequence ⁇ amv) , fftlll cDNA clone from Jerusalem Artichoke and the nos terminator sequence ⁇ Tnos
- the completej ⁇ i ⁇ ll sequence was replaced by the c86B PCR fragment.
- the Notl/Ascl fragment of pUC86B2 was cloned into the pUCPS344 digested with Notl/Ascl, resulting in pUCPSC344.25 (Fig. 11).
- pUCPSC344.25 was used to transform guard cell protoplasts of sugar beet.
- Bialophos-resistent calli were obtained after bialophos selection. Regeneration and selection of transformants was as described (Hall et al. 1996). Transgenic sugar beets were analyzed by Northern analysis (Fig. 13): as the sstl03 probe a
- DNA fragment was used which was prepared by PCR using primers 5'-TTGAATAGAACATCGGGCTCTAGCG-3' and
- Line 7PSF22 expressed both the sstl03 and the fftlll gene (Fig. 13, lane 1). This line was further analyzed by HPAEC.
- the inulin profile can be described as a mixture of inulin molecules up to a DP of 9 (Fig. 14).
- the inulin profile of sugar beet line 7PSF22 is essentially different from the inulin profile of transgenic sugar beet lines comprising only the sst!03 gene (Sever ⁇ er et al. 1998).
- the sugar beet comprising only the sst!03 gene accumulates inulins up to a DP of 5 (GF 2 , GF 3 and GF 4 ; Sevenier et al. 1998).
- the inulin profile of line 7PSF22 is also different from the standard grade inulin from chicory ( Fig 15), which comprises of a mixture of inulins up to a DP of about 55.
- the plasmid prepared according to the description in example 9, was used to transform stomatal guard cell protoplasts of sugar beet. Bialophos-resistent calli were obtained after bialophos selection. Regeneration and selection of transformants was as described (Hall et al. 1996).
- Transgenic sugar beets were analysed by Northern analysis (Fig. 13): as a c86b probe a DNA fragment was used, which was prepared by PCR using primers 5'-GTGACCTTGAGGATGCATCC-3'and 5'-TCGGTTGCACCCGCGCTCG-3' and plasmid pUC86B2 (example 9) as a template.
- Line 9PSC2 expressing both the sst!03 and the c86b gene (Fig 13, lane 2), was selected for further analysis by HPAEC.
- the inulin profile of sugar beet line 9PSC2 can be described as a polydisperse mixture of inulin molecules with a DP ranging from 3 to 15 (Fig. 16).
- the inulin profile of sugar beet line 9PSC2 is essentially different from transgenic sugar beet lines comprising only the sst!03 gene (Sevenier et al. 1998), but also from line 7PSF22 comprising a combination of sst!03 an ⁇ fftll, which accumulate inulin molecules up to a DP of 9 (Fig 14). 34
- the inulin profile of line 9PSC2 is also different from the standard grade inulin from chicory ( Fig. 15), which comprises of inulins up to a DP of about 55.
- Lines 8PAF1 and 8PAF5 which were expressing both the a33 and the fftlll gene (Fig. 13, lanes 3 and 4, respectively), were analysed by HPAEC.
- Sugar beet line 8PAF5 accumulates inuline molecules ranging from DP 3-22 (Fig. 17).
- Sugar beet line 8PAF1 accumulates a mixture of inulin molecules with a DP ranging from 3 to 26 (Fig. 18).
- line 8PAF1 In contrast to lines 7PSF22 (example 11), 9PSC2 (example 12) and 8PAF5 (example 13), in which GF 2 is invariably the most abundant inulin molecule, in line 8PAF1, the concentrations of GF 2 , GF 3 , GF 4 and GF 5 are in the same range, being 2.5. 2.5. 2.4 and 2.2% of total dry matter, respectively. Surprisingly, line 8PAF1 also accumulates significant amounts of F 2 , F 3 , F 4 , F 5 F 6 , F 7 , F 8 and F 9 , being 0.4, 0.4, 0.5, 0.4, 0.4, 0.3, 0.2, 0.1% of total dry weight, respectively (CGC- analysis results).
- the inulin profiles of sugar beet lines 8PAF1 and 8PAF5 are essentially different from from sugar line 7PSF22 comprising a combination of sstl03 and fftll, which accumulate inuline molecules up to a DP of only 9.
- the inulin profile of lines 8PAF1 and 8PAF5 are also different from the standard grade inulin from chicory (Fig. 15), which comprises of inulins up to a DP of about 55. 35
- pBLNPLUS an improved plant transformation vector based on pBIN19. Transgenic Research 4, 288-290. - Van der Meer IM, Koops AJ, Hakkert JC and Van Tunen AJ (1998). Cloning of Fructan Biosynthesis genes of Jerusalem Artichoke. Plant Journal 1998.
- Fructan of the inuline Neoseries is synthesized in transgenic chicory plants ⁇ Cichorium intybus L.) harbouring onion ⁇ Allium cepa L.) fructan:fructan 6G-fructosyltransf erase. Plant J. 11, 387-398.
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Priority Applications (5)
Application Number | Priority Date | Filing Date | Title |
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US09/673,492 US6664444B1 (en) | 1998-04-17 | 1999-04-15 | Transgenic plants presenting a modified inulin producing profile |
NZ507607A NZ507607A (en) | 1998-04-17 | 1999-04-15 | Method of producing a transgenic plant by transforming witha 1-SST enzyme (sucrose:surcose 1-fructosyltransferase) and/or a 1-FFT enzyme (fructan:fructan 1-fructosyltransferase) |
AU36065/99A AU3606599A (en) | 1998-04-17 | 1999-04-15 | Transgenic plants presenting a modified inulin producing profile |
EP99917984A EP1084254A1 (en) | 1998-04-17 | 1999-04-15 | Transgenic plants presenting a modified inulin producing profile |
AU2003246315A AU2003246315B2 (en) | 1998-04-17 | 2003-09-15 | Transgenic plants presenting a modified inulin producing profile |
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EP98870084.5 | 1998-04-17 | ||
EP98870084A EP0952222A1 (en) | 1998-04-17 | 1998-04-17 | Transgenic plants presenting a modified inulin producing profile |
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PCT/EP1999/002538 WO1999054480A1 (en) | 1998-04-17 | 1999-04-15 | Transgenic plants presenting a modified inulin producing profile |
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US (1) | US6664444B1 (en) |
EP (2) | EP0952222A1 (en) |
AU (1) | AU3606599A (en) |
NZ (1) | NZ507607A (en) |
WO (1) | WO1999054480A1 (en) |
ZA (1) | ZA200005516B (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2003000854A2 (en) * | 2001-06-25 | 2003-01-03 | Ses Europe N.V./S.A. | Double fructan beets |
US7253335B2 (en) * | 2000-10-30 | 2007-08-07 | E. I. Du Pont De Nemours And Company | Fructan biosynthetic enzymes |
WO2021122982A1 (en) * | 2019-12-19 | 2021-06-24 | Keygene N.V. | Germacrene a synthase mutants |
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US20040073975A1 (en) * | 2002-08-21 | 2004-04-15 | Stoop Johan M. | Product of novel fructose polymers in embryos of transgenic plants |
AU2003902253A0 (en) * | 2003-05-12 | 2003-05-29 | The University Of Queensland | Method for increasing product yield |
AR052059A1 (en) * | 2004-12-21 | 2007-02-28 | Bayer Cropscience Gmbh | CANE SUGAR PLANTS WITH INCREASED CONTENT OF STORAGE CARBOHYDRATES |
JP4714894B2 (en) * | 2005-06-22 | 2011-06-29 | 独立行政法人農業・食品産業技術総合研究機構 | Cold-tolerant plant and its development method |
US20090297671A1 (en) * | 2008-06-02 | 2009-12-03 | Frito-Lay North America, Inc. | Infusion Method for Vacuum Fried Fruit Leveraging |
WO2009152285A1 (en) | 2008-06-11 | 2009-12-17 | Syngenta Participations Ag | Compositions and methods for producing fermentable carbohydrates in plants |
CA2653883C (en) * | 2008-07-17 | 2022-04-05 | Colin Leslie Dow Jenkins | High fructan cereal plants |
MX2011002786A (en) | 2008-09-15 | 2011-09-21 | Agriculture Victoria Serv Pty | Modification of fructan biosynthesis, increasing plant biomass, and enhancing productivity of biochemical pathways in a plant. |
AU2015264827B2 (en) * | 2008-09-15 | 2017-12-07 | Agriculture Victoria Services Pty Ltd | Modification of fructan biosynthesis, increasing plant biomass, and enhancing productivity of biochemical pathways in a plant (2) |
CN110066348A (en) * | 2018-01-23 | 2019-07-30 | 天津科技大学 | A method of it extracts, purification witloof oligosaccharide |
CN110250005B (en) * | 2019-07-22 | 2023-04-07 | 中国热带农业科学院热带作物品种资源研究所 | Cultivation method of new cymbidium goeringii variety |
US20220372501A1 (en) * | 2019-09-24 | 2022-11-24 | Ginkgo Bioworks, Inc. | Production of oligosaccharides |
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WO1996021023A1 (en) * | 1995-01-06 | 1996-07-11 | Centrum Voor Plantenveredelings- En Reproduktieonderzoek (Cpro - Dlo) | Dna sequences encoding carbohydrate polymer synthesizing enzymes and method for producing transgenic plants |
WO1997029133A1 (en) * | 1996-02-09 | 1997-08-14 | Coöperatie Cosun U.A. | Modified inulin |
WO1997042331A1 (en) * | 1996-05-03 | 1997-11-13 | Südzucker Aktiengesellschaft | Process for producing transgenic inulin-generating plants |
WO1998039460A1 (en) * | 1997-03-04 | 1998-09-11 | MAX-PLANCK-Gesellschaft zur Förderung der Wissenschaften e.V. | Nucleic acid molecules from artichoke ($i(cynara scolymus)) encoding enzymes having fructosyl polymerase activity |
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SI0769026T1 (en) | 1994-07-07 | 2000-02-29 | Tiense Suikerraffinaderij N.V. (Raffinerie Tirlemontoise S.A.) | Fractionated polydisperse compositions |
NL1000064C1 (en) | 1994-07-08 | 1996-01-08 | Stichting Scheikundig Onderzoe | Production of oligosaccharides in transgenic plants. |
BE1010449A3 (en) | 1996-08-01 | 1998-08-04 | Raffinerie Tirlemontoise Sa | PROCESS FOR PREPARING A COMPOSITION SACCHARIDES POLYDIPERSEE, COMPOSITION polydispersed saccharide, PRODUCTS, PHARMACEUTICAL AND / OR COSMETIC COMPOSITION COMPRISING polydisperse. |
BE1010450A3 (en) | 1996-08-01 | 1998-08-04 | Tiense Suikerraffinaderij Nv | PROCESS FOR MAKING A HIGH FRUCTOSE SYRUP fructose. |
DE19749122A1 (en) | 1997-11-06 | 1999-06-10 | Max Planck Gesellschaft | Enzymes encoding nucleic acid molecules that have fructosyl transferase activity |
US6365800B1 (en) * | 1998-03-12 | 2002-04-02 | E. I. Du Pont Nemours & Company | Transgenic crops accumulating fructose polymers and methods for their production |
-
1998
- 1998-04-17 EP EP98870084A patent/EP0952222A1/en not_active Withdrawn
-
1999
- 1999-04-15 WO PCT/EP1999/002538 patent/WO1999054480A1/en active Application Filing
- 1999-04-15 NZ NZ507607A patent/NZ507607A/en unknown
- 1999-04-15 AU AU36065/99A patent/AU3606599A/en not_active Abandoned
- 1999-04-15 US US09/673,492 patent/US6664444B1/en not_active Expired - Fee Related
- 1999-04-15 EP EP99917984A patent/EP1084254A1/en not_active Withdrawn
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WO1996021023A1 (en) * | 1995-01-06 | 1996-07-11 | Centrum Voor Plantenveredelings- En Reproduktieonderzoek (Cpro - Dlo) | Dna sequences encoding carbohydrate polymer synthesizing enzymes and method for producing transgenic plants |
WO1997029133A1 (en) * | 1996-02-09 | 1997-08-14 | Coöperatie Cosun U.A. | Modified inulin |
WO1997042331A1 (en) * | 1996-05-03 | 1997-11-13 | Südzucker Aktiengesellschaft | Process for producing transgenic inulin-generating plants |
WO1998039460A1 (en) * | 1997-03-04 | 1998-09-11 | MAX-PLANCK-Gesellschaft zur Förderung der Wissenschaften e.V. | Nucleic acid molecules from artichoke ($i(cynara scolymus)) encoding enzymes having fructosyl polymerase activity |
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Cited By (5)
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US7253335B2 (en) * | 2000-10-30 | 2007-08-07 | E. I. Du Pont De Nemours And Company | Fructan biosynthetic enzymes |
WO2003000854A2 (en) * | 2001-06-25 | 2003-01-03 | Ses Europe N.V./S.A. | Double fructan beets |
WO2003000854A3 (en) * | 2001-06-25 | 2004-03-04 | Ses Europe Nv Sa | Double fructan beets |
US7608754B2 (en) | 2001-06-25 | 2009-10-27 | Ses Europe N.V./S.A. | Double fructan beets |
WO2021122982A1 (en) * | 2019-12-19 | 2021-06-24 | Keygene N.V. | Germacrene a synthase mutants |
Also Published As
Publication number | Publication date |
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NZ507607A (en) | 2003-06-30 |
US6664444B1 (en) | 2003-12-16 |
EP1084254A1 (en) | 2001-03-21 |
AU3606599A (en) | 1999-11-08 |
ZA200005516B (en) | 2001-10-30 |
EP0952222A1 (en) | 1999-10-27 |
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