EP1576164A2 - Method for producing transgenic plants having an elevated vitamin e content by modifying the serine-acetyltransferase content - Google Patents

Abstract

The invention relates to a method for producing transgenic plants and/or plant cells having an elevated vitamin E content, said transgenic plants and/or plant cells having a serine-acetyltransferase (SAT) content and/or activity which is modified in relation to the wild type, and/or a modified thiol compound content. The invention also relates to the use of nucleic acids coding for a SAT, for producing transgenic plants or plant cells having an elevated vitamin E content. The invention further relates to a method for producing vitamin E by cultivating transgenic plants or plant cells having a modified SAT content in relation to the wild type.

Description

 Process for the production of transgenic plants with increased vitamin E content by changing the serine acetyltransferase content

The present invention relates to a process for the production of transgenic plants and / or plant cells with an increased vitamin E content, the transgenic plants or plant cells having a serine acetyltransferase (SAT) content and / or activity that is different from that of the wild type and / or have an altered content of thiol compounds. The present invention also relates to the use of nucleic acids which code for a SAT for the production of transgenic plants or plant cells with an increased vitamin E content. The present invention also relates to a process for the production of vitamin E by culturing transgenic plants or plant cells which have a content of SAT which is different from that of the wild type.

Vitamin E usually refers to the eight naturally occurring compounds with vitamin E activity, which are derivatives of 6-chromanol (UUmann's Encyclopedia of Industrial Chemistry, Vol. A 27 (1996), VCH Verlagsgesellschaft, Chapter 4 ., 478-488, vitamin E). The group of tocopherols (1) has a saturated side chain, the group of tocotrienols (2) has an unsaturated side chain:

α-tocopherol: R ¹ = R ² = R ³ = CH ₃ ß-tocopherol: R ¹ = R ³ = CH ₃ , R ² = H γ-tocopherol: R ¹ = H, R ² = R ³ = CH ₃ δ -Tocopherol: R ¹ = R ² = H, R ³ = CH ₃

α -Tocotrienol: R l ¹ _ = _D R2 _ = R- _D 3 ^J _ =, CH ₃ p -Tocotrienol: R ¹ = R ³ = CH ₃ , R ² = H γ -Tocotrienol: R ¹ = H, R ² = R ³ = CH _{3 δ-} tocotrienol: R 1 ¹ _ = R = H, R ^J = CH ₃

In the present invention, vitamin E means all of the above-mentioned tocopherols and tocotrienols with vitamin E activity.

These compounds with vitamin E activity are important natural fat-soluble antioxidants. A lack of vitamin E leads to pathophysiological situations in humans and animals. Vitamin E compounds therefore have a high economic value as additives in the food and feed sector, in pharmaceutical formulations and in cosmetic applications.

Of the compounds mentioned with vitamin E activity, the .alpha.-tocopherol is biologically most important. The tocopherols and tocotrienols are found in many vegetable oils; the seed oils of soy, wheat, corn, rice, cotton, rapeseed, alfalfa and nuts are particularly rich in tocopherols and tocotrienols. Also fruits and vegetables, such as raspberries, beans, peas, fennel, peppers etc. contain the above-mentioned vitamin E compounds. As far as known, tocopherols and tocotrienols are synthesized exclusively in plants or photosynthetically active organisms. Some of the most important synthetic routes of tocopherols and tocotrienols are shown in Figures la and lb.

Due to their redox potential, tocopherols help to prevent the oxidation of unsaturated fatty acids by atmospheric oxygen; α-tocopherol is the most important fat-soluble antioxidant in humans. It is believed that tocopherols act as antioxidants to stabilize biological membranes by protecting unsaturated fatty acids

Membranes the membrane fluidity is maintained. According to recent findings, the formation of arteriosclerosis can also be counteracted by the regular intake of relatively high doses of tocopherol. Further beneficial properties of tocopherols have been described as delaying late-stage diabetes-related damage, reducing the risk of cataract formation, reducing oxidative stress in smokers, anticarcinogenic effects, and protective effects against skin damage such as erythema and aging. Tocopherol compounds such as tocopherol acetate and succinate are the usual forms of application for the use of vitamin E in blood circulation and lipid-lowering agents and veterinary as a feed additive.

Because of their antioxidant properties, the tocopherols and tocotrienols are not only used in terms of food technology, but also in paints based on natural oils, in deodorants and other cosmetics such as sunscreens, skin care products, lipsticks etc.

Economic processes for the production of vitamin E compounds or of food and feed with an increased vitamin E content are therefore of great importance. Biotechnological processes or through are particularly advantageous Genetic change optimized vitamin E-producing organisms such as transgenic plants and plant cells.

In the production of transgenic plants or plant cells with an increased vitamin E content, enzymes are usually used in the prior art which are involved in the biosynthesis of tocopherols and tocotrienols in higher plants (see also Figures la and lb).

In higher plants, tyrosine is formed from chorismate, prephenate and arogenate. The aromatic amino acid tyrosine is converted into hydroxyphenyl pyruvate by the enzyme tyrosine aminotransferase, which is converted into homogentisic acid by dioxygenation.

The homogentisic acid is then bound to phytyl pyrophosphate (PPP) or geranylgeranyl pyrophosphate to form the precursors of α-tocopherol and α-tocotrienol, the 2-methyl-6-phytylhydroquinol or the 2-methyl-6-geranylgeranylhydroquinol. By methylation steps with S-adenosyl methionine as the methyl group donor, first 2,3-dimethyl-6-phytylquinol is formed, then by cyclization γ-tocopherol and by repeated methylation of α-tocopherol.

Attempts are known to increase the metabolite flow in transgenic organisms by overexpressing individual biosynthetic genes in order to increase the tocopherol or tocotrienol content.

WO 97/27285 describes a modification of the tocopherol content by increased expression or by down-regulation of the enzyme p-hydroxyphenylpyruvate dioxygenase (HPPD). WO 99/04622 and DellaPenna et al, (1998) Science 282, 2098-2100 describe gene sequences coding for a γ-tocopherol methyltransferase from Synechocystis PCC6803 and Arabidopsis thaliana and their incorporation into transgenic plants which have a modified vitamin E content.

WO 99/23231 shows that the expression of a geranylgeranyl reductase in transgenic plants results in an increased tocopherol biosynthesis.

WO 00/08169 describes gene sequences encoding an l-deoxy-D-xylose-5-phosphate synthase and a geranyl-geranyl-pyrophosphate oxidoreductase and their incorporation into transgenic plants which have a modified vitamin E content.

WO 00/68393 and WO 00/63391 describe gene sequences encoding a phytyl / prenyl transferase and their incorporation into transgenic plants which have a modified vitamin E content.

WO 00/61771 postulates that the combination of a gene from the sterol metabolism in combination with a gene from the tocopherol metabolism can lead to an increase in the tocopherol content in transgenic plants.

Although all of these methods provide genetically modified organisms, in particular plants which generally have a modified vitamin E content, they have the disadvantage that the level of vitamin E in the genetically modified organisms known in the prior art is not yet is satisfactory.

There is therefore still a great need for transgenic plants or plant cells with significantly increased vitamin E contents, which can be used to obtain the vitamin E compounds. The invention is therefore based on the object of providing a method which enables the production of transgenic plants or plant cells with an increased vitamin E content.

These and other objects of the invention as they appear from the description are solved by the subject matter of the independent claim.

Preferred embodiments of the invention are defined by the dependent subclaims.

It has now surprisingly been found that the change in the content and / or the activity of SAT in transgenic plants or plant cells enables an increase in the content of vitamin E compounds such as the tocopherols and tocotrienols mentioned. This was particularly surprising because it has previously been assumed that enzymes with SAT activity only function in biosynthetic pathways for the production of sulfur-containing compounds such as cysteine, methionine and e.g. Have glutathione.

Serine acetyltransferase (SAT, EC2.3.1.30) is involved in the two-step process by which cysteine biosynthesis is accomplished in vivo in microorganisms and plants.

SAT ensures the formation of the activated thioester O-acetylserine (OAS) from serine and acetyl-coenzymeA. Free sulfide is introduced into O-acetylserine to obtain cysteine and acetate by enzymatic catalysis by O-acetylserine (thiol) lyase. The reaction catalyzed by SAT represents the rate-limiting step, the activity of this enzyme being found exclusively in conjunction with O-acetylserine (thiol) lyase (OAS-TL) in the so-called cysteine synthase complex. OAS-TL depends on the activity SAT-free homodimers are present in large excess (Kredich et al., (1969) J. Biol. Chem., 244, 2428-2439; Saito (2000) Curr. Opin. Biol. 3, 188-195).

Microbial, vegetable and animal SATs can be divided into different groups according to their allosteric controllability. A number of SATs are inhibited by the end product of the biosynthetic pathway they catalyze, cysteine. Such SATs are commonly referred to as feedback-regulated SATs (Wirtz et al., (2002), Amino acids, in press; Hell et al., (2002) Amino Acids 22, 245-257; Noji et al, (1998) J Biol. Chem. 273, 32739-45; Inoue et al., (1999) Eur. J. Biochem. 266, 220-27; Saito (2000) Curr. Op. Plant Biol. 3, 188-95).

The prototypes for feedback-regulated SATs are the microbial SATs CysE from E. coli (Accession Code E12533; Denk and Bock (1987) J. Gen. Microbiol. 133, 515-25) and S. typhimurium (Accession Code A00198; Kredich and Tomkins (1966) J. Biol. Chem. 241, 4955-65), and the vegetable SATs SAT-c from A. thaliana (Accession Code U30298; Noji et al., Vide supra), SAT2 from Citrullus vulgaris (Accession Code D49535 ; Saito et al, (1995) J. Biol. Chem. 270, 16321-26) and SAT56 from Spinacia oleracea (Accession Code D88529; Noji et al., (2001) Plant Cell Physiol. 42, 627-34).

There is also a group of SATs that can be inhibited to a much lesser extent by cysteine or not at all by cysteine. These SATs are also called feedback-independent SATs. Typical representatives of such feedback-independent SATs are so far only known from plants. These include e.g. Arabidopsis thaliana SAT A (EMBL Accession code X82888;

Bogdanova and Hell (1995) Plant Physiol. 109, 1498; Wirtz et al, 2002, vide supra), SAT 4 from Nicotiana tabacum (Accession Code AJ414052; Wirtz et al, 2002, vide supra) and ASAT5 from Allium tuberosum (Urano et al., (2000) Gene 257, 269-277) , Because of their role in the biosynthetic pathway for cysteine, the use of SAT-coding nucleic acid sequences for the production of transgenic plants or plant cells has only been discussed in connection with processes for the production of transgenic organisms with increased cysteine or glutathione contents (Wirtz et al, vide supra ). No functional connection between SAT and biosynthetic pathways leading to the production of vitamin E compounds such as tocopherols and tocotrienols is known from the prior art.

It has now surprisingly been found in the context of the present invention that the change in the content or the activity of functional or non-functional SATs in plants can be used to produce transgenic plants or plant cells which have increased vitamin E contents , The change in the content and / or the activity of SATs in transgenic plants or plant cells can be e.g. can be attributed to plant cells or plants due to the transmission and overexpression of nucleic acids which code for functional or non-functional SATs. The change in the content and / or the activity of SAT in transgenic plants or plant cells with increased vitamin E content can also be due to the up or down regulation of the activity and / or the amount of endogenous SATs synthesized.

In the context of the present invention, it has now additionally been found that the change in the content of thiol compounds can be used to produce transgenic plants or plant cells which have increased vitamin E contents. The change in the content of thiol compounds can be attributed, for example, to the change in the content and / or the activity of SATs in transgenic plants or plant cells and thus, for example, to the transmission and overexpression of nucleic acids which are necessary for functional or non-functional SATs code, can be reached on plant cells or plants. The change in the content of thiol compounds can also affect the Changes in the content and / or the activity of other enzymes involved in the metabolic pathways of thiol compounds can be attributed to plant and thus, for example, by the transfer and overexpression of nucleic acids which code for such enzymes or homologs, mutants or fragments thereof. cells or plants can be reached.

The present invention therefore relates to a process for the production of transgenic plants or plant cells with an increased vitamin E content and a changed content and / or activity of SAT compared to the wild type.

The invention also relates to a method for producing transgenic plants or plant cells with an increased vitamin E content, in which the expression of SAT by transferring nucleic acid sequences which code for functional or nonfunctional SATs or functional equivalents thereof to plants or Plant cells is effected.

The present invention further relates to processes for the production of transgenic plants or plant cells with an increased vitamin E content, in which the activity or amount of endogenous SAT is up or down regulated.

Another object of the invention is a method for producing transgenic plants or plant cells with an increased vitamin E content, in which antibodies which are specific for SATs and which possibly inhibit their function are expressed in the cell.

The invention further relates to processes for the production of transgenic plants or plant cells with an increased vitamin E content, in which the post-translational modification status of overexpressed or endogenous functional and / or non-functional SATs is changed. The present invention also relates to processes for the production of transgenic plants or plant cells with an increased vitamin E content, in which the expression of some of the endogenous SAT genes by processes such as, for example, antisense processes, post-transcriptional gene silencing (PTGS ), virus-induced gene silencing (VIGS), RNA interference (RNAi) or homologous recombination was silenced.

The invention also relates to transgenic plants or plant cells with an increased vitamin E content, which have a content and / or activity of SAT which is different compared to the wild type.

The present invention also relates to a process for the production of transgenic plants or plant cells with an increased vitamin E content, the plants having a modified content of thiol compounds compared to the wild type.

The present invention also relates to transgenic plants or plant cells which have been produced by one of the processes according to the invention and which have increased vitamin E contents compared to the wild type.

Another object of the present invention is the use of nucleic acids, which code for functional or non-functional SATs from different organisms, for the production of transgenic plants or plant cells with an increased vitamin E content.

According to the invention, serine acetyltransferase activity means the enzyme activity of a serine acetyltransferase. A serine acetyl transferase is understood to be a protein which has the enzymatic activity of linking serine and acetyl coenzyme A to the activated thioester O-acetylserine (OAS).

Accordingly, serine acetyltransferase activity is understood to mean the amount of serine converted or amount of O-acetylserine formed in a certain time by the protein serine acetyltransferase.

If the SAT activity is different from that of the wild type, a different amount of serine is converted or a different amount of O-acetylserine is formed by the protein SAT compared to the wild type in a certain time.

If the SAT activity is higher than that of the wild type, the amount of serine converted or the amount of O-acetylserine formed is increased in a certain time by the protein SAT compared to the wild type.

If the SAT activity is lower than that of the wild type, the amount of serine converted or the amount of O-acetylserine formed is reduced by the protein SAT in a certain time compared to the wild type.

If the content of SAT is different from that of the wild type, a different amount of the protein SAT is thus produced in the plant or plant cell compared to the wild type.

If the content of SAT is higher than that of the wild type, more SAT is produced in a plant or plant cell compared to the wild type.

Accordingly, if the content of SAT in the plant or plant cell is lower than that of the wild type, less SAT is produced in comparison to the wild type. If the content of thiol compounds is different from that of the wild type, a different amount of the thiol compounds is thus produced in the plant or plant cell compared to the wild type. The same applies to increased or decreased thiol contents.

The increase in the content and / or the activity of SAT in a transgenic plant cell or plant brought about by a method according to the invention is preferably at least 5%, preferably at least 20%, likewise preferably at least 50%, particularly preferably at least 100%), likewise particularly preferably at least the factor 5, particularly preferably at least the factor 10, likewise particularly preferably at least the factor 50, more preferably at least the factor 100 and most preferably at least the factor 1000.

The reduction in the content and / or the activity of SAT in a transgenic plant cell or plant brought about by a method according to the invention is preferably at least 5%, preferably at least 10%, particularly preferably at least 20%, likewise particularly preferably at least 40%, also particularly particularly preferably at least 60%, particularly preferably at least 80%, also particularly preferably at least 90% and most preferably at least 98%).

According to the invention, a wild type is understood to mean the corresponding non-genetically modified starting organism.

If the term “SAT” is used in the context of the present invention, this means both feedback-regulated and feedback-independent SATs. In the context of the present invention, the term SAT includes functional and non-functional SATs. Functional SATs fall under the definition as given above for a SAT.

When functionally equivalent parts of SATs are referred to in the context of the invention, this means fragments of the nucleic acid sequences of complete SATs, the expression of which still leads to proteins with the enzymatic activity of a SAT. These protein fragments also fall under the term “functionally equivalent parts of SATs”.

According to the invention, non-functional SATs have the same nucleic acid or amino acid sequences as functional SATs or functional equivalent parts thereof, but have point mutations, insertions or deletions of nucleotides or amino acids at some points which have the effect that the nonfunctional SATs do not or are only able to acetylate to a very limited extent to form O-acetylserine. Non-functional SATs also include those SATs that carry point mutations, insertions or deletions at the nucleic acid or amino acid sequence level and are not or are nevertheless able to interact with physiological binding partners of the SAT. Such physiological binding partners include e.g. the O-acetylserine (thiol) lyase.

According to the invention, the term “non-functional SAT” does not include those proteins which have no essential sequence homology at the amino acid or nucleic acid level to functional SATs. Proteins which are not able to transfer acetyl groups to serine and which have no essential sequence homology with SATs are therefore by definition not meant by the term “non-functional SATs” according to the invention. Non-functional SATs are also referred to as inactivated or inactive SATs in the context of the invention.

Thus, non-functional SATs according to the invention which carry the point mutations, insertions and / or deletions mentioned above are characterized by a essential sequence homology to the known functional SATs according to the invention or their functionally equivalent parts.

According to the invention, essential sequence homology is generally understood to mean that the nucleic acid or amino acid sequence of a DNA molecule or a protein is at least 40%, preferably at least 50%, more preferably at least 60%, likewise preferably at least 70%, particularly preferably is at least 90%, particularly preferably at least 95% and most preferably at least 98% identical to the nucleic acid or amino acid sequences of a known functional SAT or their functionally equivalent parts.

Identity between two proteins is understood to mean the identity of the amino acids over the respective total protein length, in particular the identity which is determined by comparison with the aid of the laser gene software from DNA Star, Inc., Madison,

Wisconsin (USA) using the CLUSTAL method (Higgins et al, (1989), Comput. Appl. Biosci., 5 (2), 151).

Homologies can also be determined using the laser gene software from DNA Star, Inc., Madison, Wisconsin (USA) using the CLUSTAL method (Higgins et al, (1989), Comput. Appl. Biosci., 5 (2), 151) can be calculated.

Nucleic acid or amino acid sequences of feedback-regulated or feedback-independent functional SATs are known to the person skilled in the art. You can e.g. from the well-known databases such as the nucleotide sequence database Genbank or the protein sequence database of the NCBI. In addition, there are numerous examples of the SATs mentioned in the literature (see above).

The nucleic acid sequences for feedback-regulated functional SATs from A. thaliana (SAT-c; U30298; Noji et al., (1998) vide supra), from Citrullus vulgaris (SAT2; Accession Code D49535; Saito et al., (1995) J. Biol. Chem. 270, 16321-26) and from Spinacia oleracea (SAT56; D88529 ; Noji et al., (2001) Plant Cell Physiol. 42, 627-34) and from microorganisms such as S. typhimurium (CysE; Accession Code A00198; Kredich and Tomkins (1966) J. Biol. Chem. 241, 4955-65 ).

The nucleic acid sequences for feedback-independent functional SATs from plants, microorganisms, fungi and animals are also particularly preferred for the methods according to the invention. The cDNA sequences of the Nicotiana tabacum SAT genes 1, 4 and 7 (EMBO accession numbers AJ414051, AJ414052 and AJ414053) and the Arabidopsis thaliana SAT genes SAT 52, SAT 5 and SAT A (EMBL Accession Codes U30298, Z34888 and X82888).

Further preferred nuclear acid sequences for the mentioned SATs include the A. thaliana genes SAT-p (Accession Code L42212; Noji et al, (1998) vide supra) and SAT-m (identical to SAT A; Accession code X82888; Noji et al, ( 1998) vide supra; Bogdanova and Hell (1995) Plant Physiol, 109, 1498; Wirtz et al, (2002) vide supra).

SATs with sequences which are essentially homologous to the sequences of the above-mentioned accession numbers are also the subject of preferred embodiments of the invention.

Nucleic acids encoding proteins containing the amino acid sequence GKXXGDRHPKIGD (X stands for any amino acid; Wirtz et al, (2001) Eur. J. Biochem. 268, 686-93) or one of these sequences are particularly preferably used for the method according to the invention sequence derived by substitution, insertion or deletion of amino acids, which has an identity of at least 30%>, preferably of at least 50%), preferably of at least 70% o, more preferably at least 90%), most preferably at least 95%) at the amino acid level with the sequence with the accession code X82888 (Bogdanova et al., (1995) FEBS L. 358, 43-47; Bogdanova and Hell (1995) Plant Physiol. 109, 1498; Wirtz et al., 2002, vide supra) and which have the enzymatic property of a SAT.

Non-functional feedback-regulated or non-functional feedback-independent SATs according to the invention can be identified in a simple manner by the person skilled in the art. A number of techniques are available to the person skilled in the art with which it is possible to insert mutations, insertions or deletions into the nucleic acid sequences which code for functional SATs (Sambrook (2001), Molecular Cloning: A Laboratory Manual, 3rd Edition, Cold Spring Harbor Laboratory Press). After introduction of the point mutation, insertion and / or deletion, which are also generally referred to as a mutation, the person skilled in the art can determine whether the mutagenized SATs still have enzyme activity by appropriate enzyme activity tests, as shown in the examples or known from the prior art feature. Non-functional SATs have a reduced activity compared to the non-mutagenized SAT. According to the invention, a non-functional SAT has from 1 to 90%, preferably from 1 to 70%, particularly preferably from 1 to 50%, likewise particularly preferably from 1 to 30%, particularly preferably from 1 to 15% and most preferably over 1 to 10%> of the activity of the corresponding functional SAT with wild-type sequence.

Non-functional SATs that are no longer (or nevertheless) able to bind to physiological binding partners of the SAT, e.g. The person skilled in the art can also identify OAS-TL in routine experiments using appropriate in vitro binding tests.

Preferred non-functional SATs for the methods according to the invention are nucleic acid sequences which are used for a non-functional SAT with reduced encoded enzyme activity, the SAT at least one amino acid exchange within the amino acid motif preserved in SAT enzymes

GKXiÄGDRHPKIGD

features. The amino acid X is generally any amino acid; Xi is preferably Q or A; amino acid X is preferably C or S. Amino acids are abbreviated in the one-letter code. The N- or C-terminal amino acids located next to this motif are also highly conserved in SATs. The core motif within the amino acid sequence motif mentioned is DRH. An amino acid exchange within this core motif is particularly preferred.

In a particularly preferred embodiment, the mutation which leads to the enzymatic inactivation of the SAT is an amino acid exchange of the amino acid histidine within the motif mentioned. An exchange of histidine to alanine is particularly preferred.

In the description, the term “point mutation” is to be understood as the replacement of an amino acid or a nucleotide by another amino acid or another nucleotide. With regard to amino acids, so-called conservative exchanges are preferably carried out, in which the replaced amino acid has similar physico-chemical properties to the original amino acid, for example an exchange of glutamate by aspartate or valine by isoleucine. Deletion is the replacement of an amino acid or nucleotide with a direct link. Insertions are insertions of amino acids or nucleotides into the polypeptide chain or into the nucleic acid molecule, a direct bond being formally replaced by one or more amino acids or nucleotides. In the attached Figure 2 different SAT amino acid sequences are shown in comparison. SAT1 stands for Arabidopsis thaliana SAT isoform A (SAT-1, database axcession no. U 22964), SAT5 stands for Arabidopsis thaliana SAT isoform B (SAT-5, database axcession no. Z 34888), SAT52 stands for the Arabidopsis thaliana SAT isoform C (SAT-52, database axcession no. U 30298), CysE stands for the SAT enzyme from S. typhimurium (CysE, database accession no. A 00198); TDT stands for tetrahydrodipicolinate-N-succinyl transferase from E. coli (TDT; database accession no. P 56220); LpxA stands for UDP-N-acetylglucosamine acyltransferase from E. coli (LpxA; database accession no. P 10440). Further sequence information can be found in Murillo et al., (1995) Cell. Mol. Biol. Res. 41, 425-433; Howarth et al., (1997) Biochim. Biophys. Acta 1350, 123-127; Saito et al., (1995) J. Biol. Chem. 270, 16321-16326, Genbank Accession no. D 88530 (K. Saito). The enclosed alignment shows the position of the motif suitable for the inactivation of the SAT enzyme. Accordingly, the position of the conserved amino acid motif in further, the

State of the art to determine SAT enzymes. For example, the core motif D R H is in the Arabidopsis thaliana SAT isoform A at amino acid 307-309, whereby the numbering always refers to the first methionine of the longest open reading frame. The position of the motif in the other SAT isoforms can easily be found in the amino acid alignment shown in Fig. 2.

In addition to the above-mentioned SAT genes, the person skilled in the art has at his disposal further SAT sequences described in the prior art and available in the gene databases, which are suitable for implementing the invention. In addition, the person skilled in the art is easily able to isolate further SAT gene sequences from any organism using routine methods such as PCR or screening of libraries with suitable SAT gene probes. A large number of DNA sequences which code for functional as well as for non-functional, feedback-regulated or feedback-independent SATs from different organisms have already been given above. The person skilled in the art knows how to isolate corresponding corresponding DNA sequences from other organisms. Typically, the person skilled in the art will first attempt to identify corresponding homologous sequences by comparing homology in the established databases such as the Genebank database at the NCBI. Such databases can be found on the NCBI homepage at the NIH at http://www.ncbi.nlm.nih.gov.

DNA sequences with high homology, i.e. a high similarity or identity are bona fide candidates for DNA sequences which correspond to the DNA sequences according to the invention, i.e. Correspond to SATs. These gene sequences can be determined by standard methods, e.g. PCR and hybridization are isolated, and their function can be determined by appropriate enzyme activity tests and other experiments by the person skilled in the art. Homology comparisons with DNA sequences can also be used according to the invention to design PCR primers by first identifying the regions which are most conserved between the DNA sequences of different organisms. Such PCR primers can then be used to isolate in a first step DNA fragments which are components of DNA sequences which are homologous to the DNA sequences of the invention.

There are a number of search engines that can be used for such homology comparisons or searches. These search engines include e.g. the CLUSTAL program group of the BLAST program, which is made available by the NCBI.

In addition, a number of experimental methods are known to the person skilled in the art with which DNA sequences are isolated from a wide variety of organisms can be homologous to the SATs according to the invention. This includes, for example, the preparation and screening of cDNA libraries with appropriately degenerate probes (see also Sambrook et al., Vide supra).

The present invention also relates to a process for the production of transgenic plants or plant cells with an increased vitamin E content, the plants having a modified content of thiol compounds compared to the wild type. In a preferred embodiment of the invention, these trapped plants show increased levels of thiol compounds compared to the wild type. The increase in thiol compounds can be at least a factor of 2, preferably at least a factor of 5, particularly preferably at least a factor of 10, particularly preferably at least a factor of 20 and most preferably at least a factor of 100. The increase in the vitamin E content usually corresponds to the values mentioned below.

According to the invention, thiol compounds are understood to mean compounds with thiol groups that occur naturally in plants. In particular, the thiol compounds include glutathione, S-adenosylmethionine, methionine and cysteine.

According to the invention, transgenic plants with an altered content of thiol compounds, e.g. by changing the content and / or activity of SAT, as discussed in detail below. However, such transgenic plants can also be produced by changing the content and / or the activity of other enzymes which are involved in the production of thiol compounds.

The SAT activity and the SAT content can be increased in various ways, for example by switching off inhibitory regulatory mechanisms at the level of transcription, translation and protein or by Increasing the gene expression of a nucleic acid coding for a SAT compared to the wild type, for example by inducing the SAT gene or by introducing nucleic acids coding for a SAT.

In a preferred embodiment, the SAT activity or the SAT content is increased compared to the wild type by increasing the gene expression of a nucleic acid encoding a SAT. In a further preferred embodiment, the gene expression of a nucleic acid encoding a SAT is increased by introducing nucleic acids encoding a SAT into the organism, preferably into a plant.

In principle, any SAT gene from a wide variety of organisms, ie any nucleic acid encoding a SAT, can be used for this purpose. In the case of genomic SAT nucleic acid sequences from eukaryotic sources which contain introns, in the event that the host organism is unable or unable to splice the corresponding SATs, nucleic acid sequences which have already been processed, such as the corresponding cDNAs, are preferred use. All of the nucleic acids mentioned in the description can e.g. be an RNA, DNA or cDNA sequence.

In a preferred method according to the invention for the production of transgenic plants or plant cells with an increased vitamin E content, a nucleic acid sequence which codes for one of the functional or non-functional, feedback-regulated or feedback-independent SATs defined above is generated transfer a plant or plant cell. This transmission leads to an increase in the expression of the functional or non-functional SAT and accordingly to an increase in the vitamin E content in the transgenic plants or plant cells. According to the invention, such a method typically comprises the following steps:

a) Production of a vector comprising the following nucleic acid sequences, preferably DNA sequences, in 5'-3 'orientation:

a promoter sequence which is functional in plants is operatively linked to it, a DNA sequence which codes for a SAT or functionally equivalent parts thereof - a termination sequence which is functional in plants

b) transfer of the vector from step a) to a plant cell and possibly integration into the plant genome.

Such a method can be used to increase the expression of DNA sequences which code for functional or non-functional, feedback-regulated or feedback-independent SATs or their functionally equivalent parts, and thus the vitamin E content in plants or Plant cells also increase. The use of such vectors which comprise regulatory sequences, such as promoters and termination sequences, is known to the person skilled in the art. In addition, the person skilled in the art knows how a vector from step a) can be transferred to plant cells and which features a vector must have in order to be integrated into the plant genome.

By overexpressing active SAT, the total activity of SAT in leaves of transgenic tobacco can be increased by a factor of 100 (Wirtz et al. (2002) vide supra). The measurable total SAT activity does not increase accordingly after overexpression of non-functional SAT, but the amount of non-functional SAT does. Nevertheless, the rate of formation of O-acetylserine and cysteine must have increased in these transgenic lines, since the levels of these Connections increase sharply (WO 02/060939). Without wishing to be bound by a scientific hypothesis, it is assumed that this increase is very likely to be achieved by compensating the unaffected cell compartments, which have their own cysteine synthesis enzymes, in order to reduce the deregulation caused by the inactivated SAT in plastids or to balance the cytosol (WO 02/060939). At the same time, a significant increase in the vitamin E content is achieved in the plants.

In general, the method described can also increase the vitamin E content by at least 20%, preferably by at least 50%, also preferably by at least 75%, particularly preferably by at least 100%, particularly preferably by at least a factor of 5 particularly preferably by at least a factor of 10 and most preferably by at least a factor of 100 compared to the wild type.

If the SAT content in transgenic plants or plant cells is increased by transferring a nucleic acid that is suitable for a SAT from another organism, e.g. E. coli encoded, then it is advisable to use the nucleic acid sequence e.g. to convert the amino acid sequence encoded from E. coli into a nucleic acid sequence by back-translating the polypeptide sequence according to the genetic code, which comprises above all those codons which are used more frequently owing to the organism-specific codon usage. The codon usage can easily be determined on the basis of computer evaluations of other known genes of the organisms in question.

Increasing the gene expression or the activity of a nucleic acid encoding a SAT also means, according to the invention, the manipulation of the expression of the organism-specific, in particular plant-specific, endogenous SATs. This can be achieved, for example, by changing the promoter DNA sequence for genes coding for SAT. Such a change that changed, preferably increased expression rate of at least one endogenous SAT gene can result from the deletion or insertion of DNA sequences.

A change in the promoter sequence of endogenous SAT genes generally leads to a change in the expressed amount of the SAT gene and thus also to a change in the SAT activity detectable in the cell or in the plants.

Furthermore, an altered or increased expression of at least one endogenous SAT gene can be achieved in that a regulator protein which does not occur in the non-transformed organism interacts with the promoter of these genes. Such a regulator can represent a chimeric protein which consists of a DNA binding domain and a transcription activator domain, as described for example in WO 96/06166.

Another way to increase the activity and content of endogenous SATs is to include transcription factors involved in the transcription of the endogenous SAT genes, e.g. upregulate by overexpression. The measures for overexpression of transcription factors are known to the person skilled in the art and are likewise disclosed for SATs in the context of the present invention.

In addition, a change in the activity of endogenous SATs can be achieved by targeted mutagenesis of the endogenous gene copies.

A change in the endogenous SATs can also be achieved by influencing the post-translational modifications of SATs. This can be done, for example, by regulating the activity of enzymes such as kinases or phosphatases, which are involved in the post-translational modification of SATs, by appropriate measures such as overexpression or "gene silencing". The expression of endogenous SATs can also be regulated via the expression of aptamers which specifically bind to the promoter sequences of SAT. Depending on whether the aptamers bind to stimulating or repressing promoter regions, the amount and in this case the activity on endogenous SAT is increased or decreased.

Aptamers can also be designed to specifically bind to the SAT proteins and e.g. Binding to the catalytic center of the SATs reduce the activity of the SATs. The expression of aptamers is usually carried out by vector-based overexpression and is well known to the person skilled in the art, as is the design and selection of aptamers (Famulok et al., (1999) Curr Top Microbiol Immunol., 243, 123-36).

In addition, the amount and activity of endogenous SATs can be reduced by various experimental measures which are well known to the person skilled in the art. These measures are usually summarized under the term "gene silencing". For example, by transmitting a vector mentioned above, which has a DNA sequence coding for SAT coding or parts thereof in antisense orientation, the expression of an endogenous SAT gene can be silenced. This is due to the fact that the transcription of such a vector in the cell leads to an RNA which can hybridize with the mRNA transcribed by the endogenous SAT gene and thus prevents its translation.

In principle, the antisense strategy can be coupled with a ribozyme process. Ribozymes are catalytically active RNA sequences which, coupled to the antisense sequences, cleave the target sequences catalytically (Tanner et al., (1999) FEMS Microbiol Rev. 23 (3), 257-75). This can increase the efficiency of an antisense strategy. Other methods for reducing SAT expression, particularly in plants as organisms, include overexpression of homologous SAT nucleic acid sequences (Jorgensen et al, (1996) Plant Mol. Biol. 31 (5), 957-973) or induction of the specific one, which leads to cosuppression Plant RNA degradation using a viral expression system (Amplikon) (Angell et al, (1999) Plant J. 20 (3), 357-362). These methods are also known as "post-transcriptional gene silencing" (PTGS).

Other methods are the introduction of nonsense mutations into the endogenous gene by introducing RNA / DNA oligonucleotides into the plant (Zhu et al, (2000) Nat. Biotechnol 18 (5), 555-558) or the generation of knockout Mutants with the help of e.g. T-DNA mutagenesis (Koncz et al, (1992) Plant Mol Biol. 20 (5) 963-976) or homologous recombination (Hohn et al, (1999) Proc. Natl. Acad. Sci. USA. 96, 8321- 8,323th).

Furthermore, gene repression (but also gene overexpression) is also possible with specific DNA-binding factors e.g. Factors of the type of zinc finger transcription factors possible. In addition, factors can be introduced into a cell that inhibit the target protein itself. The protein binding factors can e.g. Be aptamers (Famulok et al, (1999) Curr Top Microbiol Immunol 243, 123-36).

SAT-specific antibodies can be considered as further protein-binding factors, the expression of which in plants causes a reduction in the content and / or activity of SAT. The production of monoclonal, polyclonal or recombinant SAT-specific antibodies follows standard protocols (Guide to Protein Purification, Meth. Enzymol 182, pp. 663-679 (1990), MP Deutscher, ed.). The expression of antibodies is also known from the literature (Fiedler et al, (1997) Immunotechnology 3, 205-216; Maynard and Georgiou (2000) Annu. Rev. Biomed. Eng. 2, 339-76). Other techniques that can be used to suppress, minimize or prevent the expression of endogenous SAT genes include VIGS, RNAi or "gene knockouts", for example by homologous recombination. The corresponding methods are known to the person skilled in the art or can be easily researched in the literature. Another common method for "gene silencing" is co-suppression (see, for example, Waterhouse et al, (2001), Nature 411, 834-842; Tuschl (2002), Nat. Biotechnol 20, 446-448 and other publications therein Edition, Paddison et al, (2002), Genes Dev. 16, in press, Brummelkamp et al, (2002), Science 296, 550-553).

The techniques mentioned are well known to those skilled in the art. He also knows which sizes are used for e.g. The antisense method or the RNAi method must have the nucleic acid constructs used, and the complementarity, homology or identity of the respective nucleic acid sequences.

The terms complementarity, homology and identity are known to the person skilled in the art.

In the context of this invention, sequence homology or homology is generally understood to mean that the nucleic acid or amino acid sequence of a DNA molecule or a protein is at least 40%, preferably at least 50%, more preferably at least 60%, likewise preferably at least 70%>, particularly preferably at least 90%, particularly preferably at least 95%) and most preferably at least 98% are identical to the nucleic acid or amino acid sequences of a known DNA or RNA molecule or protein. The degree of homology or identity relates to the entire length of the coding sequence. The term complementarity describes the ability of a nucleic acid molecule to hybridize with another nucleic acid molecule due to hydrogen bonds between complementary bases. The person skilled in the art knows that two nucleic acid molecules do not have to have 100 percent complementarity in order to be able to hybridize with one another. One is preferred

Nucleic acid sequence which is to hybridize with another nucleic acid sequence, at least 40% of this, at least 50%>, at least 60%, preferably at least 70%), particularly preferably at least 80%>, likewise particularly preferably at least 90% , particularly preferably at least 95%> and most preferably at least 98 or 100% »complementary.

Nucleic acid molecules are identical if they have the same nucleotides in the same 5'-3 'order.

Hybridization of an antisense sequence with an endogenous mRNA sequence typically takes place in vivo under cellular conditions or in vitro. According to the invention, hybridization is carried out in vivo or in vitro under conditions which are stringent enough to ensure a specific hybridization.

Stringent in vitro hybridization conditions are known to the person skilled in the art and can be found in the literature (see, for example, Sambrook et al, vide supra). The term "specific hybridization" refers to the fact that a molecule preferentially binds to a particular nucleic acid sequence under stringent conditions if this nucleic acid sequence is part of a complex mixture of e.g. Is DNA or RNA molecules.

The term "stringent conditions" thus refers to conditions under which a nucleic acid sequence binds preferentially to a target sequence, but does not bind or at least significantly reduces it to other sequences. Stringent conditions depend on the circumstances. Longer sequences hybridize specifically at higher temperatures. In general, stringent conditions are chosen so that the hybridization temperature is approximately 5 ° C below the melting point (Tm) for the specific sequence at a defined ionic strength and a defined pH. Tm is the temperature (at a defined pH value, a defined ionic strength and a defined nucleic acid concentration) at which 50% of the molecules which are complementary to a target sequence hybridize with this target sequence. Typically, stringent conditions include salt concentrations between 0.01 and 1.0 M sodium ions (or other salt) and a pH between 7.0 and 8.3. The temperature is at least 30 ° C for short molecules (for example, those that contain between 10 to 50 nucleotides). In addition, stringent conditions can include the addition of destabilizing agents such as formamide. Typical hybridization and wash buffers have the following composition.

prehybridization solution:

0.5% SDS 5x SSC

50 mM NaPO ₄ , pH 6.8 0.1% Na pyrophosphate 5x Denhardt's reagent 100 μg / ml salmon sperm

Hybridization solution: prehybridization solution lxlO ⁶ cpm / ml probe (5-10 min 95 ° C)

20x SSC: 3 M NaCl

0.3 M sodium citrate ad pH 7 with HCl

50x Denhardt's reagent: 5 g Ficoll

5 g polyvinylpyrrolidone 5 g Bovine Serum Albumine ad 500 ml A. dest.

A typical procedure for hybridization is as follows:

Optional: wash blot in lx SSC / 0.1% SDS at 65 ° C for 30 min

Prehybridization: at least 2 h at 50-55 ° C

Hybridization: over Nac] tιt at 55-60 ° C.

Wash: 05 min 2x SSC / 0.1% SDS hybridization temp

30 min 2x SSC / 0.1% SDS hybridization temp

30 min lx SSC / 0.1% SDS hybridization temp

45 min 0.2x SSC / 0.1% SDS 65 ° C

5 min 0.1x SSC room temperature

The terms “sense” and “antisense” and “antisense orientation” are known to the person skilled in the art. The person skilled in the art also knows how long nucleic acid molecules that are to be used for antisense methods have to be and what homology or complementarity they have to have with regard to their target sequences.

Accordingly, the person skilled in the art also knows how long nucleic acid molecules which are used for other “gene silencing” processes must be. For example The person skilled in the art knows that in an RNAi method nucleic acid molecules have to be introduced into the cell, which are either double-stranded RNA, one strand of which is homologous or identical to an endogenous RNA sequence, or DNA molecules , the transcription of which results in corresponding double-stranded RNA molecules in the cell, the RNA-interference-inducing double-stranded RNA molecules usually comprising 20-25 nucleotides (see also Tuschl et al, vide supra). A detailed description of this method is also disclosed in WO 99/32619.

A combined application of the methods described above is also conceivable.

Another object of the invention is a method for increasing the vitamin E content in transgenic plants, in which, in addition to the change in the content and / or the activity of SAT, such enzymes, the increased formation of homogenate or phytyl pyrophosphate, a reduced degradation of Homogenizat or phytyl pyrophosphate or an increased implementation within the last steps of tocopherol biosynthesis cause (eg tocopherol methyl transferase, tocopherol cyclase, γ-tocopherol methyl transferase), are changed in terms of their content or their activity in the transgenic plants.

Examples of such enzymes can be found in WO 02/072848, which is expressly introduced here as a disclosure.

Since these enzymes are enzymes that are involved in the regulation of

Vitamin E synthesis involved in vivo, the upregulation of the content or the activity of the aforementioned enzymes in connection with the change in the content and / or the activity of SATs brings further advantages in the production of plants with an increased vitamin E content. The up or down regulation of Activity or the content of the enzymes mentioned can take place by one and / or a combination of the aforementioned methods.

If, according to the invention, DNA sequences are used which are operatively linked in 5'-3 'orientation to a promoter which is active in plants, vectors can generally be constructed which, after transfer to plant cells, overexpress the coding sequence enable in transgenic plants or plant cells or effect the suppression of endogenous nucleic acid sequences.

Vectors which can be used according to the invention for overexpression and for repression of DNA sequences which code for the various SATs or functionally equivalent parts thereof can comprise regulatory sequences in addition to the nucleic acid sequences to be transmitted. Which specific regulatory elements or sequences are contained in these vectors depends on the purpose of the application. Vectors which can be used to overexpress coding sequences in plants are known to the person skilled in the art. Methods for transferring the sequences and for producing transgenic plants or plant cells with an increased or reduced expression of proteins are also known to the person skilled in the art.

Typically, the regulatory elements contained in vectors ensure transcription and, if desired, translation of the nucleic acid sequence that is transferred to the plants.

These nucleic acid constructs, in which the coding nucleic acid sequences are operatively linked to one or more regulatory signals which ensure transcription and translation in organisms, in particular in plants, are called vectors or expression cassettes. Accordingly, the invention further relates to nucleic acid constructs, in particular nucleic acid constructs functioning as an expression cassette, containing a nucleic acid encoding a SAT or functionally equivalent parts thereof, which is functionally linked to one or more regulation signals which ensure transcription and translation in organisms, in particular in plants.

The regulation signals preferably contain one or more promoters which ensure transcription and translation in organisms, in particular in plants.

The expression cassettes contain regulatory signals, that is to say regulatory nucleic acid sequences which control the expression of the coding sequence in the host cell.

According to a preferred embodiment, an expression cassette comprises upstream, i.e. at the 5 'end of the coding sequence, a promoter and downstream, i.e. at the 3 'end, a polyadenylation signal and optionally further regulatory elements which are operatively linked to the intervening coding sequence for at least one of the genes described above.

An operative link is understood to mean the sequential arrangement of promoter, coding sequence, terminator and possibly further regulatory elements in such a way that each of the regulatory elements can fulfill its function in the expression of the coding sequence as intended.

In a preferred embodiment, the nucleic acid constructs and expression cassettes according to the invention additionally contain a nucleic acid which codes for a peptide which regulates the location of the expressed SAT in the cell. Such nucleic acids preferably encode plastidic transit peptides that encode the Ensure localization in plastids, particularly preferably in chloroplasts, or for signal peptides which cause localization in the cytoplasm, mitochondria or in the endoplasmic reticulum.

The preferred nucleic acid constructs,

Expression cassettes and vectors for plants and methods for producing transgenic plants, and the transgenic plants themselves are described.

The sequences preferred but not limited to the operative linkage are targeting sequences to ensure the subcellular

Localization in the apoplast, in the vacuole, in plastids, in the mitochondrion, in the endoplasmic reticulum (ER), in the cell nucleus, in oil cells or other compartments and translation enhancers such as the 5 'guide sequence from the tobacco mosaic virus (Gallie et al, ( 1987) Nucl Acids Res. 15, 8693 -8711).

In principle, any promoter which can control the expression of foreign genes in plants is suitable as promoters of the expression cassette. In particular, a plant promoter or a plant virus-derived promoter is preferably used. The CaMV 35S promoter from the cauliflower mosaic virus (Franck et al. (1980) Cell 21, 285-294) is particularly preferred. As is known, this promoter contains different recognition sequences for transcriptional effectors, which in their entirety lead to permanent and constitutive expression of the introduced gene (Benfey et al, (1989) EMBO J. 8 2195-2202). Another possible promoter is the nitrilase promoter.

The expression cassette can also contain a chemically inducible promoter, by means of which the expression of the target gene in the plant can be controlled at a specific point in time. Such promoters such as the PRP1 promoter (Ward et al, (1993) Plant. Mol Biol 22, 361-366), a promoter induced by salicylic acid (WO 95/19443), one which can be induced by benzenesulfonamide (EP 388 186), one that can be induced by tetracycline (Gatz et al, (1992) Plant J. 2, 397-404), one that can be induced by abscisic acid (EP 335 528) or one that can be induced by ethanol or cyclohexanone (WO 93/21334 ) Promoter can be used.

Furthermore, promoters are particularly preferred which ensure expression in tissues or parts of plants in which, for example, the biosynthesis of vitamin E or its precursors takes place. Promoters that ensure leaf-specific expression should be mentioned in particular. The promoter of the cytosolic FBPase from potato or the ST-LSI promoter from potato (Stockhaus et al, (1989) EMBO J. 8 2445-245) should be mentioned.

With the help of a seed-specific promoter, a foreign protein could be stably expressed up to a proportion of 0.67% of the total soluble seed protein in the seeds of transgenic tobacco plants (Fiedler et al, (1995) Bio / Technology 10 1090-1094). Expression of the SATs in the seeds of plants using seed-specific promoters such as e.g. the Phaseolin (US 5504200), the USP (Baumlein et al, (1991) Mol Gen. Genet. 225 (3), 459-467), the LEB4, the Vicilin and the Legumin B4 promoter.

The biosynthesis site of vitamin E in plants is, inter alia, the leaf tissue, so that leaf-specific expression of the nucleic acids according to the invention encoding a SAT is useful. However, this is not restrictive, since the expression can also be tissue-specific in all other parts of the plant - especially in fatty seeds.

A further preferred embodiment therefore relates to a seed-specific expression of the nucleic acids described above. In addition, constitutive expression of the SAT is advantageous. On the other hand, inducible expression may also appear desirable.

The effectiveness of the expression of the transgenically expressed SAT can be determined, for example, in vitro by sprout meristem propagation. In addition, a change in the type and level of expression of the SAT and its effect on the vitamin E biosynthesis performance on test plants can be tested in greenhouse experiments.

The promoter can be native or homologous as well as foreign or heterologous to the host plant. The expression cassette preferably contains the promoter, a coding nucleic acid sequence and possibly a region for homologous or heterologous the transcriptional termination in the 5 '-3' transcription direction. Different termination areas are interchangeable.

Preferred polyadenylation signals are plant polyadenylation signals, preferably those which essentially correspond to T-DNA polyadenylation signals from Agrobacterium tumefaciens, in particular gene 3 of T-DNA (octopine synthase) of the Ti plasmid pTiACH5 (Gielen et al, (1984) EMBO J. 3, 835 ff.) Or functional equivalents thereof.

An expression cassette is preferably produced by fusing a suitable promoter with a nucleic acid described above, such as a sequence coding for SAT and preferably a target nucleic acid inserted between promoter and nucleic acid sequence, which codes, for example, for a chloroplast-specific transit peptide, and a polyadenylation signal, according to common recombination and cloning techniques, such as those found in Sambrook et al, (vide supra) and in TJ Silhavy, ML Berman and LW Enquist, Experiments with Gene Fusions, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY (1984) and Ausubel et al, Current Protocols in Molecular Biology, Greene Publishing Assoc. and Wiley-Interscience (1987).

Particularly preferred are inserted target nucleic acids which ensure targeting in the plastids.

Expression cassettes can also be used, the nucleic acid sequence of which codes for a fusion protein, part of the fusion protein being a transit peptide which controls the translocation of the polypeptide. Preferred transit peptides are preferred for the chloroplasts, which are cleaved enzymatically from the target protein part after translocation of the target protein into the chloroplasts.

Sequences which code for a fusion protein with a cytoplasmic peptide are likewise preferably contained in expression cassettes. The localization in the cytoplasm can possibly can also be ensured by omitting the sequence for the plastid transit peptide.

Particularly preferred is the transit peptide derived from the Nicotiana tabacum transketolase plastid or another transit peptide (e.g. the Rubisco small subunit transit peptide (rbcs) or the ferredoxin NADP oxidoreductase as well as the isopentenyl pyrophosphate isomerase-2) or its functional equivalent.

The nucleic acids according to the invention can be produced synthetically or obtained naturally or contain a mixture of synthetic and natural nucleic acid constituents, and can consist of different heterologous gene segments from different organisms.

As described above, preference is given to synthetic nucleotide sequences with codons which are preferred by plants. These preferred by plants Codons can be determined from codons with the highest protein frequency, which are expressed in most interesting plant species.

When preparing an expression cassette, various DNA fragments can be manipulated in order to obtain a nucleotide sequence which expediently reads in the correct direction and which is equipped with a correct reading frame. To connect the DNA fragments to one another, adapters or linkers can be attached to the fragments.

The promoter and terminator regions can expediently be in

Direction of transcription are provided with a linker or polylinker which contains one or more restriction sites for the insertion of this sequence. As a rule, the linker has 1 to 10, usually 1 to 8, preferably 2 to 6, restriction sites. In general, the linker has a size of less than 100 bp, often less than 60 bp, but at least 5 bp within the regulatory ranges.

Manipulations which provide suitable restriction sites or which remove superfluous DNA or restriction sites can also be used. Where insertions, deletions or substitutions such as Transitions and transversions can be used in vztro mutagenesis, "primerrepair", restriction or ligation.

With suitable manipulations, e.g. Restriction, "chewing-back" or filling of overhangs for "bluntends", complementary ends of the fragments can be made available for the ligation.

The invention thus relates to vectors containing the nucleic acids, nucleic acid constructs or expression cassettes described above. The transfer of foreign genes into the genome of an organism, especially a plant, is called transformation.

For this purpose, methods known per se for transforming and regenerating plants from plant tissues or plant cells for transient or stable transformation can be used, in particular in plants.

Suitable methods for the transformation of plants are the protoplast transformation by polyethylene glycol-induced DNA uptake, the biolistic method with the gene gun - the so-called particle bombardment method, the electroporation, the incubation of dry embryos in DNA-containing solution, the microinjection and the Agrobacterium mediated gene transfer. The methods mentioned are described, for example, in B. Jenes et al, (1993) Techniques for Gene Transfer, in: Transgenic Plants, Vol. 1, Engineering and Utilization, published by S.D. Kung and R. Wu, Academic Press, 128-143 and in Potrykus et al, (1991) Annu. Rev. Plant Physiol Plant Molec. Biol. 42, 205-225).

When injecting and electroporation of DNA into plant cells, there are no special requirements per se for the plasmids used. The same applies to direct gene transfer. Simple plasmids such as pUC derivatives can be used. Typically, vectors can be used which have sequences necessary for propagation and selection in E. coli. This also includes vectors from the pBR322, M13mp series and pACYC184. However, if whole plants are to be regenerated from such transformed cells, the presence of a selectable marker gene is necessary. The usual selection markers are known to the person skilled in the art and it is no problem for him to select a suitable marker. Common marker markers are those that give the transformed plant cells resistance to a biocide or an antibiotic such as kanamycin, G418, bleomycin, hygromycin, methotrexate, Mediate glyphosate, streptomycin, sulfonyl urea, gentamycin or phosphinotricin and the like.

Depending on the method of introducing desired genes into the plant cell, additional DNA sequences may be required. If, for example, the Ti or Ri plasmid is used for the transformation of the plant cell, at least the right boundary, but often the right and left boundary of the T-DNA contained in the Ti and Ri plasmid, must be connected as a flank region to the genes to be introduced ,

If agrobacteria are used for the transformations, the DNA to be introduced must be cloned into special plasmids, either in an intermediate or in a binary vector. The intermediate vectors can be integrated into the Ti or Ri plasmid of the agrobacteria by means of sequences which are homologous to sequences in the T-DNA by homologous recombination. This also contains the vir region necessary for the transfer of the T-DNA. Intermediate vectors cannot replicate in agrobacteria. Using a helper plasmid, the intermediate vector can be transferred to Agrobacterium tumefaciens (conjugation).

Binary vectors can replicate in both E. coli and agrobacteria. They contain a selection marker gene and a linker or poly linker, which are framed by the right and left T-DNA border region. They can be transformed directly into the agrobacteria (Holsters et al, (1978) Molecular and General Genetics 163, 181-187). The agrobacterium serving as the host cell should contain a plasmid carrying a vir region. The vir region is necessary for the transfer of the T-DNA into the plant cell. T-DNA may also be present. The agrobacterium transformed in this way is used to transform plant cells. The use of T-DNA for the transformation of plant cells has been intensively investigated and has been sufficiently described in EP 120 515.

For the transfer of the DNA into the plant cell, plant explants can expediently be cultivated with Agrobacterium tumefaciens or Agrobacterium rhizogenes. The transformation of plants by agrobacteria is known, among other things, from F.F. White, Vectors for Gene Transfer in Higher Plants; in Transgenic Plants, Vol. 1, Engineering and Utilization, edited by S.D. Kung and R. Wu, Academic Press, 1993, pp. 15-38.

Whole plants can then be regenerated from the infected plant material (for example leaf pieces, stem segments, roots, but also protoplasts or suspension-cultivated plant cells) in a suitable medium, which can contain antibiotics or biocides for the selection of transformed cells. The plants are regenerated using conventional regeneration methods using known nutrient media. The plants or plant cells obtained in this way can then be examined for the presence of the introduced DNA. '

Using the recombination and clomerization techniques cited above, the expression cassettes can also be cloned into suitable vectors that allow their proliferation, for example in E. coli. Suitable cloning vectors include pBR332, pUC series, M13mp series and pACYC184. Binary vectors which can replicate both in E. coli and in agrobacteria are particularly suitable.

For example, the plant expression cassette can be installed in a derivative of the transformation vector pSUN2 with a vicilin promoter (WO 02/00900). While the transformation of dicotyledonous plants or their cells via Ti plasmid vector systems with the help of Agrobacterium tumefaciens is well established, recent work indicates that monocotyledonous plants or their cells are also very accessible to transformation by means of vectors based on Agrobacteria (see Chan et al., (1993) Plant Mol. Biol. 22, 491-506, among others).

Alternative systems for the transformation of monocotyledonous plants or their cells are transformation using the biolistic approach (Wan et al, (1994) Plant Physiol. 104, 37-48; Vasil et al, (1993) Bio / Technology 11, 1553-1558 ; Ritala et al, (1994) Plant Mol. Biol. 24, 317-325; Spencer et al, (1990) Theor. Appl. Genet. 79, 625-631), the protoplast transformation, the electroporation of partially permeabilized cells and the introduction of DNA using glass fibers (see L. Willmitzer (1993) Transgenic Plants in: Biotechnology, A Multi-Volume Comprehensive Treatise (editor: HJ. Rehm et al, Volume 2, 627-659, VCH Weinheim, Germany).

The transformed cells grow within the plant in the usual way (see also McCormick et al, (1986) Plant Cell Reports 5, 81-84). The resulting plants can be grown normally and crossed with plants that have the same transformed genetic makeup or other genetic makeup. The resulting hybrid individuals have the corresponding phenotypic properties.

Two or more generations should be attracted to ensure that the phenotypic trait is stably maintained and inherited. Seeds should also be harvested to ensure that the appropriate phenotype or other characteristics have been preserved.

It is also possible to determine transgenic lines which are homozygous for the new nucleic acid molecules and their phenotypic behavior by customary methods examined for an increased vitamin E content and compared with that of hemizygotic lines.

Of course, plant cells which contain the nucleic acid molecules according to the invention can also be further cultivated as plant cells (including protoplasts, calli, suspension cultures and the like).

In addition to the plants, the expression cassette can also be used to transform bacteria, in particular cyanobacteria, mosses, yeasts, filamentous fungi and algae.

The invention therefore also relates to the use of the nucleic acids and the nucleic acid constructs described above, in particular the expression cassettes for the production of genetically modified organisms, in particular for the production of genetically modified plants or for the transformation of plant cells, tissues or parts of plants.

These transgenic plants preferably have an increased vitamin E content compared to the wild type.

The invention therefore also relates to the use of SATs or the nucleic acid constructs according to the invention for increasing the content of vitamin E in organisms which, as a wild type, are able to produce vitamin E.

Plants with a high vitamin E content are known to increase

Have resistance to abiotic stress. Abiotic stress means, for example, cold, frost, dryness, heat and salt. The invention therefore further relates to the use of the nucleic acids according to the invention for the production of transgenic plants which are more resistant to abiotic stress than the wild type.

The proteins and nucleic acids described above can be used for the production of fine chemicals in transgenic organisms, preferably for the production of vitamin E in transgenic plants.

The aim of the use is preferably to increase the content of vitamin E in the plant or parts of plants.

Depending on the choice of the promoter, the expression can take place specifically in the leaves, in the seeds, petals or other parts of the plant.

Accordingly, the invention further relates to a method for producing genetically modified organisms by introducing a nucleic acid described above or a nucleic acid construct described above or a combination of nucleic acid constructs described above into the genome of the starting organism.

The invention further relates to the genetically modified organisms themselves described above.

As mentioned above, the genetically modified organisms, in particular plants, have an increased vitamin E content.

In a preferred embodiment, as mentioned above, photosynthetically active organisms such as cyanobacteria are used to produce organisms with a higher vitamin E content than the wild type. Mosses, algae or plants, particularly preferably plants, are used as starting organisms.

In principle, the plants used for the method according to the invention can be any plant. It is preferably a monocot or dicot crop, food or feed plant. Examples of monocotyledonous plants are plants belonging to the genera Avena (oat), Triticum (wheat), Seeale (rye), Hordeum (barley), Oryza (rice), Panicum, Pennisetum, Setaria, sorghum (millet), Zea (corn ) and the like.

Dicotyledonous crops include cotton, legumes such as legumes and in particular alfalfa, soybean, rapeseed, tomato, sugar beet, potatoes, ornamental plants and trees. Other useful plants can include fruit (in particular apples, pears, cherries, grapes, citrus, pineapples and bananas), oil palms, tea, cocoa and coffee bushes, tobacco, sisal and, in the case of medicinal plants, rauwolfia and digitalis. The cereals wheat, rye, oats, barley, rice, corn and millet, sugar beet, rapeseed, soybeans, tomato, potatoes and tobacco are particularly preferred. Further useful plants can be found in US Pat. No. 6,137,030.

Preferred plants are tagetes, sunflower, arabidopsis, tobacco, red pepper, soy, tomato, eggplant, bell pepper, carrot, carrot, potato, corn, salads and cabbages, cereals, alfalfa, oats, barley, rye, wheat, triticale, millet, Rice, alfalfa, flax, cotton, hemp, Brassicacaeen such as rape or canola, sugar beet, sugar cane, nut and wine species or woody plants such as aspen or yew.

Arabidopsis thaliana, Tagetes ereeta, Brassica napus, Nicotiana tabacum, sunflower, canola, potato or soy are particularly preferred. Such transgenic plants, their food, and their plant cells, tissue or parts are a further subject of the present invention.

The invention thus also relates to crop products and nutritional material of transgenic plants which have been produced by a process according to the invention and have an increased vitamin E content. The harvested products and the propagation material are in particular fruits, seeds, flowers, tubers, rhizomes, seedlings, cuttings, etc. Parts of these plants, such as plant cells, protoplasts and calli, can also be involved.

The genetically modified organisms, in particular plants, can be used to produce vitamin E as described above.

Genetically modified plants according to the invention with increased vitamin E content that can be consumed by humans and animals can also be used, for example, directly or after processing known per se as food or feed or as feed and food supplement.

The genetically modified plants according to the invention can also be used for the production of extracts containing vitamin E.

Increasing the content of vitamin E in the context of the present invention preferably means the artificially acquired ability of an increased biosynthetic capacity of these compounds in the plant compared to the non-genetically modified plant, preferably for the duration of at least one plant generation.

An increased vitamin E content is generally understood to mean an increased total tocopherol content. Taking an increased vitamin E content but also understood in particular a changed content of the 8 compounds with tocopherol activity described above.

The vitamin E content is determined by methods customary in the prior art. These are disclosed in particular in detail in WO 02/072848, the content of which is expressly stated here as a disclosure for methods of detecting the vitamin E content in plants.

The vitamin E content can e.g. in leaves and seeds of plants transgenic for SATs. In particular, dry seeds or frozen leaf material are used.

The leaf material of the plants is frozen in liquid nitrogen immediately after sampling. The subsequent digestion of the cells (leaves or seeds) is carried out by means of a stirring apparatus by incubation three times in an Eppendorf shaker at 30 ° C., 1000 rpm (revolutions per minute) in 100%> methanol for 15 minutes, the supernatants obtained in each case being combined. Further incubation and extraction steps usually do not result in any further release of tocopherols or tocotrienols.

In order to avoid oxidation, the extracts obtained are analyzed immediately after extraction using an HPLC system (Waters Allience 2690). Tocopherols and tocotrienols are separated on a conventional “reverse phase” column (ProntoSil 200-3-C30 ™, from Bischoff) with a mobile phase of 100% methanol and identified using standards (from Merck). The serves as the detection system Fluorescence of the substances (excitation 295 nm, emission 320 nm), which can be detected using a Jasco FP 920 fluorescence detector. The present invention is illustrated in the following examples, which serve only to illustrate the invention and are in no way to be understood as a limitation.

Examples

General cloning procedures:

Cloning methods, e.g. Restriction cleavage, DNA isolation, agarose, gel electrophoresis, purification of DNA fragments, transfer of nucleic acids to nitrocellulose and nylon membranes, linking of DNA fragments, transformation of E. co / z cells, cultivation of bacteria, sequence analysis of recombinant DNA were carried out according to Sambrook et al, vide supra. The transformation of Agrobacterium tumefaciens was carried out according to the method of Höfgen et al, ((1988) Nucl. Acids Res. 16, 9877). The agrobacteria were grown in YEB medium (Vervliet et al, (1975) J. Gen. Virol 26, 33).

Bacterial strains and plasmids

E. coli (XL 1 Blue) bacteria were obtained from Stratagene, La Jolla, USA. The agrobacterial strain used for plant transformation (GV3101; Bade und Damm in Gene Transfer to Plants; Protrykus, I. and Spangenberg, G., eds., Springer Lab Manual, Springer Verlag, 1995, 30 - 38) was transformed with the vector pSUN2. The vector pSUN2 was used for cloning. Production of transgenic oilseed rape plants (Brassica napus)

Transgenic oilseed rape plants were produced according to a standard protocol (Bade und Damm in Gene Transfer to Plants; Protrykus, I. and Spangenberg, G., eds., Springer Lab Manual, Springer Verlag, 1995, 30-38). The cited reference also discloses the composition of the media and buffers used.

The seeds of Brassica napus var. Westar were surface sterilized with 70% ethanol (v / v), washed in water at 55 ° C for 10 min and in a 1% hypochlorite solution (25%) (v / v) Teepol, 0.1% (v / v) Tween20) incubated for 20 min. Thereafter, each seed was washed six times with sterile water for 20 minutes. The seeds were dried on filter paper for three days. 10 to 15 seeds were then germinated in a glass jar containing 15 ml of germination medium. The roots and apices were removed from various seedlings (approx. 10 cm in size) and the remaining stems (hypocotyls) were cut into pieces of approx. 6 mm in length. The approximately 600 explants obtained in this way were washed in 50 ml "BasaP" medium for 30 min and then transferred to a 300 ml container. After the addition of 100 ml callus induction medium, the cultures were incubated with shaking at 100 rpm (revolutions per minute) for 24 h.

For transformation, an overnight culture of Agrobacterium tumefaciens in "Luria BrotiY" medium to which kanamycin (20 mg / l) was added was grown at 29 ° C. and 2 ml of this culture in 50 ml antibiotic-free "Luria Broth" medium Incubated at 29 ° C. for 4 hours until an OD ₆ oo of 0.4 to 0.5 was reached. The culture was then centrifuged at 2000 rpm for 25 min and the cell pellet was resuspended in 25 ml "basal" medium. The concentration of the bacteria in the solution was adjusted to an OD ₆ oo of 0.3 by appropriate addition of medium. The callus induction medium was removed from the oilseed rape explants using sterile pipettes and 50 ml of the bacterial suspension was added to the explants. The reaction mixture was then mixed gently and incubated for 20 min. The bacterial suspension was then removed and the oilseed rape explants were then washed with 50 ml of the callus induction medium for 1 min. 100 ml of the callus induction medium were then added. The co-cultivation was carried out with shaking at 100 rpm for 24 h and stopped by removing the callus induction medium. The explants were then washed twice with 25 ml of washing medium for 1 min and twice with 100 ml of washing medium for 60 min with shaking at 100 rpm. The washing medium was then transferred with the explants into 15 cm petri dishes and the medium was removed using sterile pipettes.

For regeneration, 20 to 30 explants were transferred to 90 mm petri dishes containing 25 ml "shoot induction" medium with kanamycin. The petri dishes were sealed with two layers of Leukopor® and subjected to a photocycle of 16 h light and 16 h dark at 25 ° C and 2000 lux. After 12 days, the developing calli were transferred to fresh petri dishes, which also contained "shoot induction" medium. All further steps for the regeneration of complete plants were carried out as indicated in the above-mentioned reference (Bade und Damm, vide supra).

Production of an enzymatically inactive serine acetyltransferase (SAT) that is still able to interact with OAS-TL.

The SAT-A from Arabidopsis thaliana described in the prior art with regard to its amino acid sequence and the underlying DNA sequence (EMBL Accession code X82888; Bogdanova and Hell (1995) Plant Physiol 109, 1498; Wirtz et al, 2002, vide supra) was inactivated by directed mutagenesis of the amino acid histidine 309 to alanine (the numbering refers to the first methionine of the open reading frame). The directed mutagenesis of the associated cDNA in the plasmid pBlueScript (Stratagene) was carried out by base pair exchange using a commercially available method from Promega (Heidelberg, Germany).

The site-directed mutagenesis of the SAT-A cDNA was carried out with pBS / ΔSATl-6 (Bogdanova et al, (1995) FEBS Lett. 358, 43-47). The Promega GeneEditor in vitro Site Directed Mutagenesis System used achieved an average of 80% positive clones. The point mutations were verified by DNA sequencing and the resulting amino acid changes were numbered in relation to the start codon of the longest possible open reading frame of a mitochondrial SAT-A cDNA (cDNA SAT-1 (Roberts et al. (1996) Plant Mol. Biol 30, 1041 -1049)).

The inactivation of the SAT mutant by the amino acid exchange in position 309 (histidine - alanine) was demonstrated by the lack of heterologous complementation of a SAT-free E. co b 'mutant and by enzyme determination in vitro (maximum 1%> residual activity). The ability to interact with O-acetylserine (thiol) lyase (OAL-TL) was demonstrated by heterologous expression in the yeast "two-hybrid" system and coexpression in E. coli with subsequent biochemical purification.

The inactivation of the E. coli cysE gene to generate a SAT-free E. coli mutant was carried out according to the method described by Hamilton et al. described method carried out (Hamilton et al. (1989) J. Bacteriol. 171, 4617-4622). This should provide a bacterial strain that is more stable in terms of its SAT deficiency than that currently available in the prior art. For this purpose, the wild-type c sE gene was cloned by means of PCR and obtained by inserting a gentamycin resistance cassette into a Clal restriction site at position 522 on the start codon of the cysE gene, inactivated. After cloning this cassette into the plasmid pMAK705, which carries a temperature-sensitive origin of replication, the inactivated cysE gene was integrated into the genome of E. coli C600 via homologous recombination to give the strain MW1 (tbr, leu, thi, lac , λ-P \ + F ', cysE, Gm ^r ). Complementation tests using the E. co / f strains EC1801 (E. coli Genetics Stock Center, Yale University, New Haven, CT, USA) or MW1 were carried out on M9 minimal medium agar plates with or without cysteine with the addition of induction agents and selective antibiotics carried out.

The constructs for the expression of Arabidopsis thaliana mitochondrial SAT-A included pBS / ΔSATl-6 (X82888; Bogdanova et al, (1985) vide supra), pET / ΔSATl-6 and mutated forms of SAT-A. In order to obtain the latter plasmid, the coding region of the SAT-A was amplified by PCR from base pair 28-939 without a mitochondrial transit peptide using specific primers, flanked by EcoRI and Xhol cleavage sites. This fragment was cloned into the plasmid pCAP (Röche, Mannheim, Germany), the sequence was verified by sequencing both strands and inserted into the corresponding cleavage sites of pET29a (Novagen, Madison, USA), which resulted in a fusion protein with the 35 amino acids of the S- Day at its N-terminus for affinity purification on S-agarose resulted. Mitochondrial OAS-TL from A. thaliana was similarly obtained by cloning a PCR product that contained the mature protein without the mitochondrial transit peptide from base pair 172-1162 (AJ271727 (Hesse et al, (1999) Amino Acids 16, 113-131) in the NcoI-BamHI cleavage sites of pET3d, which gave pET / OAS-C.

The expression, cultivation and affinity purification of SAT and OAS-TL using the S-tag system (Novagen) were carried out essentially as described by Droux et al. (1998, Eur. J. Biochem. 255,235-245) with the following modifications. After the last washing step, the S-tag was not Removed lytic cleavage on the affinity column as this treatment resulted in fractions with labile SAT activity. Instead, SAT was eluted with 3 M MgCl ₂ , which was then removed by gel filtration on PDIO columns (Amersham, Freiburg, Germany). In vitro interaction of SAT and OAS-TL on the column was determined according to a standard washing and elution protocol with or without 1 mM OAS (O-acetylserine) as described by Droux et al, (1998, vide supra).

The determination of the protein concentration and the separation of proteins were carried out according to standard protocols (e.g. Sambrook et al, vide supra).

The SAT enzyme activity with and without OAS-TL was determined in a standard assay based on the method of Kredich and Becker (1971, In Methods in Enzymology (Tabor and Tabor, eds), pages 459-469, Academic Press, New York , USA). Crude or purified recombinant SAT protein was incubated in a volume of 250 μl (50 mM Tris / HCl, pH 7.5, 0.2 mM acetyl-CoA, 2 mM Dithiothreitol, 5 mM serine) at 25 ° C. and A ₂ 3 ₂ was recorded for up to 3 minutes.

OAS-TL activity was examined under saturated conditions as previously described (Nakamura et al, (1987) Plant Cell Physiol. 28, 885-891). Kinetic analysis was performed with the SigmaPlot software, which allowed hyperbolic adjustments based on the Michaelis-Menten equation: v = V _max x ([S] / (K _m + [S]).

For the interaction analyzes using the yeast "two-hybrid" system, the transformation of the yeast strains HF7c and PCY2, the selection on minimal medium and β-galactosidase assays were carried out as already described (Bogdanova and Hell (1997) Plant J. 11, 251 -262). PCR with specific primer pairs, flanked by Sall or Spel interfaces, was used for all constructs in order to convert the coding regions into the corresponding restriction To insert interfaces of pPC86 (GAL4 activation domain) and pPC97 (GAL4 DNA binding domain) (Chevray and Nathans (1992) Proc. Natl. Acad. Sci. USA 89, 5789-5793). EST 181H17T7 (GenBank Accession Number AJ2711727) was used as a template to generate OAS-TL C without a mitochondrial transit peptide from base pair 172-1162. In contrast to the fill length construct previously used (Bogdanova et al, (1997) vide supra), the pPC vectors with mitochondrial SAT-A without a mitochondrial transit peptide were constructed by amplifying base pairs 28-939 (X82888 (Bogdanova et al, ( 1995) vide supra).

Expression of active SAT-A and non-functional S AT-A mutant (H309A) in plants

The cDNAs of the active SAT-A (SAT) and the inactivated mutant SAT-A H309A (SATH309A) were cloned into a binary transformation vector (pSUN2, WO 02/00900). SAT and SATH309A were amplified in the same way by PCR and fused to the reading frame of the rbcs transit peptide. Both SATs were localized in the cytosol with pSUN2, leaving out the section for the import peptide. Either the nitrilase promoter for constitutive expression or the vicilin promoter for seed-specific expression were used as promoters.

The cloning was carried out in the given Xhol or Smal restriction sites of the vector pSUN2 mentioned.

The cDNA of the active SAT and the SAT mutant SATH309A were each amplified by standard PCR with the oligonucleotide primers SAT269 and SAT270, which had 5 ′ additional Xhol and EcoRI restriction sites. After digestion with EcoRI, the SAT fragments were ligated with the also fused with EcoRI digested transit peptide rbcs. The transit peptide was also amplified by standard PCR using the oligonucleotide primers Tra201 and Tra202, which had 5 'additional EcoRI and Smal restriction sites. The fused fragments were then ligated into the Xhol and Smal restriction sites of the vector.

Example of standard PCR: reaction volume 50 μl with 20 pmol of each primer, 1-10 ng plasmid, buffer from the manufacturer, 1 U Taq polymerase (Promega). Sequence: 5 minutes at 94 ° C, then 30 cycles of 30 seconds at 94 ° C, 60 seconds at 55 ° C, 30 seconds at 72 °, followed by 10 minutes at 72 ° C.

Tra201: 5'-CTC GAG AAT GGC TTC CTC AAT G-3 'Tra202: 5'-GAA TTC CCA CAC CTG CAT GCA TTG TAG TC-3' SAT269: 5'-GAA TTC CAT GAA CTA CTT CCG TTA TC-3 'SAT270: 5'-CCC GGG TCA AAT TAC ATA ATC CGA C-3'

Extraction and activity determination of the SATs from transgenic oilseed rape plants

The SATs were extracted from the transgenic plant material and their activity was determined. For this, the protocol of Nakamura et al, ((1987) Plant Cell Physiol, 28, 885-891) was used. The leaves (nitrilase promoter) or the seeds (vicilin promoter) of three independent transgenic lines were examined in each case. It was shown that transgenic plants that express the SATH309A have an unchanged SAT activity compared to non-transgenic plants, while transgenic plants that overexpress the active SAT have a significantly increased total S AT activity. Determination of the vitamin E content of the transgenic plants

The extraction of vitamin E and its detection was carried out as described above. Frozen leaf material (nitrilase promoter) or dry seeds (vicilin promoter) were used for the analysis. The leaf material of the plants was correspondingly deep-frozen in liquid nitrogen immediately after the sampling. The subsequent digestion of the cells (leaves or seeds) was carried out by means of a stirring apparatus by incubating three times in an Eppendorf shaker at 30 ° C., 1000 rpm (revolutions per minute) in 100% methanol for 15 minutes, the supernatants obtained in each case being combined. More incubation and

Extraction steps generally showed no further release of tocopherols or tocotrienols.

In order to avoid oxidation, the extracts obtained were analyzed immediately after extraction using an HPLC system (Waters Allience 2690).

Tocopherols and tocotrienols were separated on a conventional “reverse phase” column (ProntoSil 200-3-C30 ™, from Bischoff) with a mobile phase of 100% methanol and identified using standards (from Merck). The used as the detection system Fluorescence of the substances (excitation 295 nm, emission 320 nm), which was detected using a Jasco FP 920 fluorescence detector.

In transgenic plant material with active SAT or inactive SATH304A, regardless of whether constitutive or seed-specific expression was carried out, an increase in the vitamin E content compared to the wild type was found.

The results described above clearly showed that the Arabidopsis thaliana SAT mutant with an amino acid exchange in position 309 no longer has any enzymatic SAT activity, but nevertheless for complex formation, i.e. for action with OAS-TL. The expression of this mutant, like the expression of an active SAT, led to a surprising increase in the content of vitamin E.

pictures

Figure 1 shows typical vitamin E biosynthetic pathways.

Figure 2 shows an amino acid alignment of various sermacetyl transferases.

Figure 3 shows a vector map of pSUN2 with the rbcs-SATH309A construct.

Claims

Patent claims

1. Process for the production of transgenic plants and / or

Plant cells with increased vitamin E content, characterized in that the content and / or the activity of serine acetyl transferase (SAT) in the plants is changed compared to the wild type.

2. The method according to claim 1, characterized in that the SAT content is increased by transferring a nucleic acid which codes for a SAT or a functionally equivalent part thereof to the plant or plant cell.

3. The method according to claim 1 or 2, characterized in that it is a feedback-regulated and / or feedback-independent SAT.

4. The method according to any one of claims 1 to 3, characterized in that it is a SAT from microorganisms, preferably from E. coli, Corynebacterium glutamicum, from fungi, preferably from Saccharomyces cerevisiae, Schizosaccharomyces pombe, Asper gillus nidulans, Neurospora crassa, or from plants, preferably from Arabidopsis thaliana, Nicotiana tabacum, Allium tuberosum, Brassica oleracea or hybrids such as Glycine max, Zea mays, Triticum aestivum.

5. The method according to claim 4, characterized in that it is the SATs with the Genbank Accession Numbers (in brackets: gene annotations of the Arabidopsis genome sequencing) L422l2 (Atlg55920), AF112303 (At2gl7640), X82888 (At3gl3110), U30298 (At5g56760), At4g35640, AJ414051, AJ414052, AJ414053 or are SATs with sequences which are essentially homologous to the sequences of the accession numbers mentioned.

6. The method according to any one of claims 1 to 5, characterized in that it is non-functional SATs that have point mutation (s), deletions and / or insertions.

7. The method according to claim 6, characterized in that it is a non-functional SAT that has point mutations, deletions and / or insertions that bind to physiological binding partners, preferably to acetyl-coenzyme A and / or OAS-TL prevent.

8. The method according to claim 6, characterized in that it is a non-functional SAT, which is enzymatically inactive due to a mutation within the amino acid sequence motif G K X X G D R H P K I G D (X stands for any amino acid).

9. The method according to claim 8, characterized in that the mutation relates to the core motif D R H.

10. The method according to claim 8 or 9, characterized in that the mutation affects the histidine within the motif.

11. The method according to any one of claims 1 to 10, comprising the following steps: a) production of a vector comprising the following nucleic acid sequences in 5'-3 'orientation: - a promoter sequence functional in plants

- operatively linked to a DNA sequence that codes for a SAT or functionally equivalent parts thereof

- A termination sequence functional in plants b) transfer of the vector from step a) to a plant cell and optionally integration into the plant genome.

12. The method according to claim 11, characterized in that the vector additionally has nucleic acid sequences which bring about a compartment-specific expression of the SAT in the transgenic plant and / or plant cell, preferably in mitochondria, plastids, chloroplasts and / or in the cytosol.

13. The method according to claim 1, characterized in that the content and / or the activity of the endogenous SATs is changed compared to the wild type.

14. The method according to claim 13, characterized in that the content and / or the activity of the endogenous SATs is increased by influencing the transcription and / or translation.

15. The method according to claim 13, characterized in that the content and / or the activity of the endogenous SATs is increased by regulating the post-translational modifications.

16. The method according to claim 13, characterized in that the content and / or the activity of the endogenous SATs is lowered by gene silencing.

17. The method according to claim 16, characterized in that the gene silencing by an antisense method, by PTGS, by VIGS, by RNAi or by homologous recombination.

18. The method according to claim 1, characterized in that the activity of the SAT is reduced by expression of antibodies which are specific for SAT, in the plant cell.

19. The method according to any one of claims 1 to 18, characterized in that the organism is harvested after culturing and vitamin E is then isolated from the organism.

20. Process for the production of transgenic plants and / or plant cells with an increased vitamin E content, characterized in that the content of thiol compounds in the plants is changed compared to the wild type.

21. The method according to claim 20, characterized in that the content of glutathione, S-adenosylmethionine, methionine and cysteine in the plants is changed compared to the wild type.

22. The method according to claim 20 or 21, characterized in that the method is carried out according to one of claims 1 to 19.

23. Use of nucleic acid sequences which code for SAT or functionally equivalent parts thereof for the production of transgenic plants and / or plant cells with an increased content of vitamin E.

24. Use of nucleic acid sequences according to claim 23, characterized in that the nucleic acids code for a functional or non-functional, feedback-regulated or feedback-independent SAT or functionally equivalent parts thereof.

25. Use of a nucleic acid sequence according to one of the claims

23 or 24 in one of the methods according to claims 1 to 19.

26. Transgenic plant and / or plant cell with an increased vitamin E content, characterized in that it is obtainable by a process according to one of claims 1 to 22.

27. Transgenic plant and / or plant cell according to claim 26, characterized in that it is a monocot or dicot plant.

28. Transgenic plant and / or plant cell according to claim 27, characterized in that the plant is cotton, legumes, soybeans, rapeseed, tomato, sugar beet, potatoes, tobacco, sisal and cereals, preferably wheat, rye, oats, Barley, rice, corn and millet.