DD242425A5 - Process for the transformation of hereditary genetic material - Google Patents

Abstract

The invention relates to a method for the transformation of hereditary genetic material. The aim of the invention is to provide an improved method by which a direct transfer of new genetic information into a plant material without the use of biological vectors is possible to produce plants with new and / or improved properties. According to the invention, foreign genes are directly transferred into plant genomes in such a way that a gene is under the control of expression signals effective in plants, and it is transferred by contact with protoplasts without the aid of natural plant-infectious systems directly into plant cells, from which subsequently genetically modified plants can be obtained ,

Description

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Field of application of the invention

The present invention relates to a novel process for the transformation of hereditary genetic material and the vegetable products obtainable by this process.

Characteristic of the known technical solutions

With the rapid growth of the world's population and the associated higher food and commodity needs, increasing the yield of crops and increasing the production of herbal ingredients, particularly food and nutritional progress, is one of the most urgent tasks of biological research. Essential aspects include, for example: increasing the resistance of crops to unfavorable soil conditions or climatic conditions, to diseases and pests, increased resistance to pesticides such as insecticides, herbicides, fungicides and bactericides, and a favorable change in nutrient content or content Crop yield of plants. Such desirable effects could generally be brought about by induction or increased formation of protective agents, valuable proteins or toxins. A corresponding influence on plant genetic material can be done, for example, by specifically introducing a particular foreign gene into plant cells, without making use of conventional breeding measures.

The transfer of new DNA sequences into plant cells using genetically engineered plant bacteria are known from the literature by some publications, such as Nature, Vol. 303, 209-213 (1983); Nature, Vol. 304, 184-187 (1983); Scientific American 248 (6), 50-59 (1983); EMBO Journal 2 (6), 987-995 (1983); Science 222, 476-A82 (1983); Science 223,247-248 (1984); or proc. Natl. Acad. Be. USA 80,4803-4807 (1983). The natural plant-sensitizing properties of these bacteria were exploited to inject new genetic material into plant cells. For this purpose, Agrobacterium tumefaciens as such or its Ti plasmid have hitherto preferably been used, as well as cauliflower mosaic virus.

Object of the invention

The object of the invention is to provide an improved process for the transformation of hereditary genetic material, with which by the introduction of new genetic information into plant material plants with new and / or improved properties can be produced.

Explanation of the essence of the invention

The invention has for its object to enable the use of new technologies, the direct transfer of a gene without the use of biological vectors.

According to the present invention, a novel process for the transformation of hereditary genetic material is proposed, which comprises transferring a gene directly into plant cells without the aid of natural plant-infectious systems.

In the previously known methods, pathogens are used as vectors. Since the method according to the invention is carried out without pathogens, the restrictions which are given by the host specificity of the pathogens are therefore also eliminated. The development of the plants on which the novel method of transformation is carried out, is not affected by this.

In addition to the method according to the invention for the transformation of hereditary genetic material, the invention also relates to the products obtainable by this process, in particular protoplasts and plant material derived therefrom, such as cells and tissues, in particular complete plants which have been regenerated from the protoplasts and their genetically identical progeny ,

In the context of the present invention, the following definitions apply:

Gene: Structural gene with accompanying expression signals. Structural gene: Protein-encoding DNA sequence. Expression signals: promoter signal and termination signal. Plant-active expression signal Expression signal that functions in plants

Promoter signal: the transcription initiating signal

Termination signal: the transcription-terminating signal

Enhancer signal: the transcriptional enhancement signal

Replication signal: signal enabling DNA replication

Integration signal: DNA sequence, which promotes the integration of the gene into the genomic DNA

Hybrid gene: from heterologous DNA sequences, d. H. DNA sequences of different origin constructed gene,

which may be both natural and synthetic DNA sequences

Carrier DNA: the gene flanking neutral, d. H. DNA sequence not involved in the function of the gene

Isolated gene: DNA sequence separated from the original DNA which encodes a single protein

NPT-II gene: neomycin S'-phosphotransferase gene, type II of transposon Tn 5 (Rothstein, S.J. and W. S. Reznikoff,

Cell 23, 1991-199 [1981]) Genomic DNA: DNA of the plant genome (total or part thereof)

The method according to the invention is a vector-free transformation. In this vector-free transformation, the foreign gene to be introduced is under the control of plant-active expression signals. Preferably, the vector-free transformation of plant genes is carried out by introducing an introduced foreign gene and acting as a recipient plant protoplasts (receptor protoplasts) together in a suitable solution and leaves it until the uptake of the gene in the protoplasts.

As plant protoplasts, preferably those of a single plant species or of a subordinate systematic unit are used in each case.

The foreign gene and the protoplasts are expediently left in the solution for a period of a few seconds to a few hours, preferably 10 to 60 minutes, in particular 30 minutes.

The inventive method is widely applicable. Thus, it is possible to use any structural genes of plant origin, such as, for example, the zein gene (Wienand, U., et al., Mol. Gen. Genet. 182, 440-444 [1981]), of animal origin, such as, for example, the TPA gene (tissue-type plasminogen activator gene; Pennica, D., et al., Nature 301, 214-221, [1983]), of microbial origin, such as the NPT-II gene, or of synthetic origin, such as the insulin gene (Stepien, P , et al., Gene 24, 289-297 [1983]), into the genetic material of plants, provided that the structural genes are flanked by expression signals effecting plant expression, wherein the expression signals are more plant, animal, microbial or synthetic Origin can be.

The transferred genes, consisting of structural genes and flanking expression signals, can be both naturally occurring genes and hybrid genes. In the method according to the invention, preference is given to using those genes whose expression signals are of animal or, in particular, of plant or synthetic origin. Examples of such genes are:

a) complete genes from plants, consisting of the structural gene with its natural expression signals;

b) fully synthetic genes, consisting of a structural gene of synthetic origin, flanked by expression signals of synthetic origin;

c) structural genes of plant origin, flanked by plant-active expression signals, wherein structures and expression signals originate from different plant species;

d) structural genes of plant origin, flanked by expression signals of synthetic origin;

e) structural genes of animal, microbial or synthetic origin, flanked by expression signals of plant origin; or

f) structural genes of animal or microbial origin, flanked by expression signals of synthetic origin.

Very particular preference is given to structural genes of bacterial origin, flanked by expression signals of plant origin, in particular those originating from plant viruses. As in the application of the present invention particularly suitable expression signals, the expression signals of the gene Vl Cauliflower mosaic virus have been found.

The hybrid genes are prepared by microbiological methods known per se, whereby the reading frame of the coding for the proteins to be produced by the plant cell is retained. Such methods are known and are described, for example, in the following publications: "Molecular Cloning", Maniatis, T., Fritsch, EF and J. Sambrook, Cold Spring Harbor Laboratory, 1982, and "Recombinant DNA Techniques", Rodriguez, RL and RC Tait , Addison-Wesley Publishing Comp., London, Amsterdam, Don Mills. Ontario, Sydney, Tokyo, 1983.

For the integration of the foreign gene into the genomic DNA of the plant cell, it is advantageous if the gene, consisting of structural genes and plant-active expression signals, is flanked by neutral DNA sequences (carrier DNA). The carrier DNA may consist of two linear DNA strands, so that the construction to be introduced into the plant cell is a linear DNA molecule. However, the DNA sequence produced for gene transfer can also have an annular structure (plasmid structure). Such plasmids consist of a DNA strand into which the foreign gene is integrated with the expression signals. The carrier DNA may be of synthetic origin or obtained by treatment with suitable restriction enzymes from naturally occurring DNA sequences. For example, naturally occurring plasmids which have been opened with a selective restriction enzyme are suitable as the carrier DNA.

An example of such a plasmid is the freely available plasmid PUC8 (described in Messing, J. and J. Vieira, Gene 19, 269-276, 1982). Furthermore, fragments of naturally occurring plasmids can also be used as carrier DNA. For example, the deletion mutant can be used as the carrier DNA for gene VI of Cauliflower Mosaic Virus.

The likelihood of genetic transformation of a plant cell can be increased by several factors.

Thus, as one knows from experiments with yeast, the number of successful, stable gene transformations increases

1) with increasing number of copies of new genes per cell,

2) when combining a replication signal with the new gene, as well

3) when combining an integration signal with the new gene.

Thus, the method according to the invention is to be used particularly advantageously when the transferred gene is combined with an effective in plant cells replication or an effective in plant cells integration signal or with both signals.

The expression of a gene in a plant cell is dependent on the transcription frequency of the gene in a messenger RNA sequence. It is therefore also advantageous if the new gene is combined with an enhancer signal enhancing this transcription. In particular, those methods are to be emphasized in which a gene is transferred, which is combined with pfienzenzellen effective replication, integration and enhancer signals.

Furthermore, it is of great procedural advantage if the transferred gene has a selective marker function, i.e., that the transformed plant cells can be separated from the non-transformed plant cells by a targeted selection. Such a marker function allows a rational operation in that only those plant cells must be regenerated by conventional microbiological measures to KaIIi or complete plants in whose genome a gene reaching for expression is present, which allows marker-specific selection measures.

While protoplasts, cell culture cells, cells in plant tissues, pollen, pollen tubes, oocytes, embryo sacs or zygotes and embryos at different developmental stages are to be mentioned as plant cells which are to be considered as starting materials for a transformation, protoplasts are without further possibilities because of the direct application possibility Pretreatment preferred.

The recovery of plant-derived, isolated protoplasts, cells or tissue can be carried out by methods known per se or analogously thereto.

Isolated plant protoplasts, which are also useful as starting material for isolated cells and tissues, can be obtained from any part of the plant, such as leaves, seedlings, stems, flowers, roots or pollen. Preferably, leaf protoplasts are used. The isolated protoplasts can also be obtained from cell cultures. Methods for the isolation of protoplasts can be found, for example, in Gamborg, O.L. and Wetter, L.R., Plant Tissue Culture Methods, 1975, 11-21.

The transfer of the new genes into the plant cells takes place directly without the use of a natural plant-infectious system, such as a plant bacterium, a plant virus or transmission by insects or phytopathogenic fungi. For this purpose, the plant cells to be transformed are treated directly with the gene to be transferred by introducing the foreign gene and plant protoplasts into a suitable solution and leaving it therein for a period sufficient for the uptake of the foreign gene into the protoplasts. By combining this with techniques used in microbiological gene transfer research, such as poly-L-ornithine or poly-L-lysine treatment, liposome fusion, DNA-protein complexation, charge change to the protoplast membrane, fusion with microwave protoplasts or calcium phosphate coprecipitation, and in particular polyethylene glycol treatment, heat shock method and electroporation and combination of these last three measures with each other, the transformation frequency can be increased. , As solutions in which the foreign gene and the recipient protoplasts are introduced, preferably osmotically stabilized culture media, as used for protoplast cultures into consideration.

There are already numerous culture media available that differ in individual media components or groups of such components. However, all media are based on the following principle: they contain a group of inorganic ions in the concentration range of about 10 mg / l to several hundred mg / l (so-called macroelements such as nitrate, phosphate, sulfate, potassium, magnesium, iron), a another group of inorganic ions in amounts of at most a few mg / l (the so-called microelements such as cobalt, zinc, copper, manganese), furthermore a number of vitamins (for example inositol, folic acid, thiamine), an energy and carbon source such as sucrose or glucose , and growth regulators in the form of natural or synthetic phytohormones from the classes of auxins and cytokinins in the concentration range of 0.01 to 10 mg / l. The culture media are also osmotically stabilized by addition of sugar alcohols (for example mannitol) or sugars (for example glucose) or salt ions (for example CaCl ₂ ) and are adjusted to a pH of 5.6 to 6.5.

A more detailed description of common culture media can be found, for example, in Koblitz, H., Methodological aspects of cell and tissue breeding in Gramineae, with special reference to cereals, cultivated plant XXII, 1974, 93-157. As a technique for gene transformation especially the "polyethylene glycol treatment" is suitable, in the context of the present invention, the term "polyethylene glycol" is not only for the substance polyethylene glycol itself, but as a generic term for all substances that also modify the protoplast membrane and as they are for example on the Area of cell fusion is used to understand. The term thus also includes, for example, other long-chain, polyhydric alcohols, such as polypropylene glycol (425 to 4000g / Moi), polyvinyl alcohol or polyhydric alcohols whose hydroxy groups are partially or completely etherified, and plant-compatible, common in the agricultural field detergents, as for example in the following publications to be discribed:

"McDeckcheon's Detergents and Emulsifiers Annual" MC Publishing Corp., Ridgewood New Jersy, 1981; Stäche, H., "Tensid-Taschenbuch", Carl Hanser Verlag, Munich / Vienna, 1981

If polyethylene glycol itself is used (as in Examples 1 to 3, 5 and 7), preference is given to using those having a molecular weight between 1000 and 10000 g / mol, in particular between 3000 and 8000 g / mol.

Of the aforementioned agents, the substance polyethylene glycol itself is preferred.

With the aforementioned measures can already be a considerable and reproducible transformation frequency of 10 ~ ⁶ achieve, but which can be significantly improved by appropriate measures, as explained in more detail below.

In the case of the polyethylene glycol treatment, it is possible to proceed, for example, by initially introducing a suspension of the protoplasts into a culture medium and then adding the gene, which is usually used as a plasmid, in a mixture of polyethylene glycol and culture medium, or advantageously prothoplasts and gene (plasmid) Submitting culture medium and then added only polyethylene glycol.

In the context of the method according to the invention, the electroporation and the heat shock treatment have also proved to be particularly advantageous measures.

In electroporation (Neumann, E. et al., The EMBO Journal 7, 841-845 [1982]) protoplasts are suspended in an osmoticum, for example a mannitol / magnesium solution, and the protoplast suspension is introduced into the electroporator chamber located between two electrodes. The protoplasts are now exposed to an electrical pulse of high voltage and short duration by discharging a capacitor through the suspension liquid. This causes a polarization of the protoplast membrane and the opening of pores in the membrane.

In the heat treatment, protoplasts are suspended in an osmoticum, such as a mannitol / calcium chloride solution, and heated in small containers, such as centrifuge tubes, conveniently in a water bath. The duration of the heating depends on the selected temperature. In general, the values in the range of 40 ⁰ C for one hour and 80 ° C for one second are. Optimal results are provided by a temperature of 45 ° C over a period of 5 minutes. Subsequently, the suspension is cooled to room temperature or lower.

It has also been shown that the transformation frequency can be increased by inactivating the extracellular nucleases. Such inactivation can be achieved by the use of plant-acceptable divalent cations, such as magnesium or calcium, and preferably also by carrying out the transformation at high pH, with a pH of 9 to 10.5 being considered as the optimum range.

Surprisingly, the targeted use of these various measures results in a tremendous increase in the frequency of transformations, as has long been the goal in the field of genetic engineering.

The lower the transformation frequency in a gene transformation, the more difficult and expensive it is to find the few cell clones resulting from the transformed cells among the enormous number of untransformed clones, and the application of conventional screening methods is almost or completely impossible with low transformation frequencies unless it is a gene with selective marker function (eg resistance to a specific substance).

Low transformation frequency thus requires enormous effort in genes without marker function.

When transformed with genes without marker function is standard screening methods for selectioning transformed cell clones can only be meaningful and successful use if the transformation frequency in the range of percentages (about 10 ~ ^2). As will be shown below, the desired transformation frequency can now be achieved with the method according to the invention. Surprisingly, the targeted use of various measures in the context of the method according to the invention results in a tremendous increase in the transformation frequency achieved up to 1 to 2%.

The combination of foreign gene and recipient protoplasts before the other measures such as polyethylene glycol treatment, electroporation and heat shock treatment, causes an improvement in the transformation frequency by about a power of ten compared to a procedure in a different order.

By electroporation, an improvement of the transformation frequency by 5 to 10 times and by heat shock treatment by 10 times or more can be achieved.

A combination of two or three of the techniques has proved advantageous: polyethylene glycol treatment, heat shock treatment and electroporation, with particularly good results being obtained when these techniques are applied only after the introduction of foreign genes and protoplasts into a solution. Preference is given to the use of the heat shock treatment before the polyethylene glycol treatment and optionally subsequent electroporation. In general, the additional use of electroporation brings a further increase in the frequency of transformation, but in some cases the results achieved by heat shock and polyethylene glycol treatment are not significantly improved by additional electroporation.

As well as the techniques with each other, the use of plant-compatible divalent cations and / or the implementation of the transformation at a pH of 9 to 10.5 can be combined both with individual techniques and with combinations of techniques, in particular with polyethylene glycol treatment, heat shock treatment and electroporation. Due to the numerous possible variations, the method according to the invention can be distinguished from the respective conditions

to adjust.

The combination of heat shock treatment, polyethylene glycol treatment and, if appropriate, electroporation following the already brought together foreign gene and recipient protoplasts now leads to a transformation frequency of 10 ~ ² to 10 ~ ³ .

Thus, with the method according to the invention, a high transformation frequency can be achieved, without the use of biological vectors for the transformation, such as Cauliflower Mosaic Virus or Agrobacterium.

An advantageous method consists, for example, in that protoplasts are converted into a mannitol solution and the resulting protoplast suspension is mixed with the aqueous gene solution. Subsequently, the protoplasts are incubated in this mixture for 5 minutes to 45 ⁰ C and then cooled to 0 ° C within 10 seconds. Subsequently, polyethylene glycol (MW 3000 to 8000) is added until a concentration of 1 to 25%, preferably of about 8%, is reached.

After thorough mixing, the treatment is carried out in the electroporator. Subsequently, the protoplast suspension is diluted with culture medium and the protoplasts are cultured.

The inventive method is suitable for the transformation of all plants, in particular those of the systematic groups Angiospermae and Gymnospermae.

Among the gymnospermae the plants of the class Coniferae are of special interest.

Among the angiosperms are in addition to the deciduous trees and shrubs of particular interest plants of the families Solanaceae, Cruciferae, Compositae, Liliaceae, Vitaceae, Chenopodiaceae, Rutaceae, Bromeliaceae, Rubiaceae, Theaceae, Musaceae or Gramineae and the order Leguminosae and especially the family Papilionaceae. Preference is given to representatives of the families Solanaceae, Cruciferae and Gramineae.

Particularly noteworthy are plants of the genus Nicotiana, Petunia, Hyoscyamus, Brassica and Lolium, such as Nicotiana tabacum, Nicotiana plumbagenifolia, Pectunia hybrida, Hyoscyamus muticus, Brassica napus, Brassica rapa and Lolium multiflorum.

The crops having large crops such as corn, rice, wheat, barley, rye, oats or millet are primarily an object of efforts in the field of plant cell transformation.

All plants which can be produced by regeneration from protoplasts can also be transformed using the method according to the invention. Representatives of the family Gramineae (grasses), which also includes cereals, could not be genetically manipulated so far. It has now been demonstrated that with the above-described

Method of direct gene transformation Gramine cells, including grain cells, can be genetically transformed. In the same way is a transformation of the crops of the genera Solanum, Nicotiana, Brassica, Beta, Pisum, Phaseolus, Glycine, Helianthus, Allium, wheat, barley, oats, Setaria, rapeseed, rice, Cydonia, Pyrus, Malus, Rubus, Fragaria, Prunus, Arachis, Seeale, Panicum, Saccharum, Coffea, Camillia, Musa, Pineapple, Vitis or Citrus are possible and desirable, although the total yields and cultivated areas are lower worldwide.

The detection of transformed genes can be carried out in a manner known per se, for example by cross-linking analyzes and molecular-biological investigations, which include, in particular, the Southern blot analysis and enzyme activity assays The Southern blof analysis can be carried out, for example, as follows: The DNA taken from the transformed cells or protoplasts is subjected to electrophoresis in 1% agarose gel after treatment with restriction enzymes, transferred to a nitrocellulose membrane (Southern, EM, J. Mol. Biol. 98, 503-517 [1975]) and incubated with the DNA subjected to nick translation (Rigby, WJ, Dieckmann, M., Rhodes, C. and P.Berg, J. Mol. Biol. 113, 237-251, [1977]) (DNA-specific activity of 5 x 10 ⁸ to 10 x 10 ⁸ cpm / jug) The filters are washed three times for one hour each with an aqueous solution of 0.03 M sodium citrate and 0.3 M sodium chloride at 65 ° C. The hybridized DNA wi Rd made visible by blackening of an X-ray film for 24 to 48 hours. An assay for enzyme activity can be described more fully in the assay for aminoglycoside phosphotransferase (enzyme for kanamycin-specific phosphorylation), for example as follows: Callus or leaf pieces (100 to 200 mg) are homogenized in 20 μl of extraction buffer in an Eppendorf centrifuge tube. The buffer is a modification of the procedure described by Herrera-Estrella, L, DeBlock, M., Messens, E., Hemalsteens, J.-P., Van Montagu, M. and J. Schell, EMBO J. 2,987-995 (1983). Buffer in which albumin was omitted from bovine blood and added to 0.1 M sucrose. The extracts are centrifuged for 5 minutes at 12000g and the supernatant phase is added with bromophenol blue to a final concentration of 0.004%. By electrophoresis in a 10% non-denaturing polyacrylamide gel, the proteins are separated from 35μ, Ι of the supernatant phase. The gel is overlaid with a kanamycin and Y- ³² P-labeled ATP-containing agarose gel, incubated, and the phosphorylated reaction products are transferred to Whatman p81 phosphocellulose paper. The paper is washed six times with 9O ⁰ C deionized water and then autoradiographed.

embodiment

The following examples serve to illustrate the present invention without, however, limiting it. They describe the construction of a hybrid gene and its incorporation into carrier DNA sequences of cyclic character, the transfer of this hybrid gene into plant cells, the selection of the transformed plant cells and the regeneration of complete plants from the transformed Pf lanfenzellen and their crossing genetic and molecular biological analysis.

In the examples, the process according to the invention is illustrated as follows:

1) by transformation of tobacco plants by transfer of the NPT-II gene, in such a way that provides the NPT-II gene with promoter and termination signals of the CaMV gene Vl, this incorporates into the pUC8 plasmid and the obtained chimeric Plamid transfers to isolated tobacco protoplast by polyethylene glycol treatment,

2) by transformation of plants of the genus Brassica by transfer of the NPT-II gene, in such a way that provides the NPT-II gene with promoter and termination signals of the CaMV gene Vl, this construction instead of the CaMC gene Vl incorporated into the CaMV genome and transfers the resulting plasmid by polyethylene glycol treatment in isolated Brassicaprotoplasten, and

3) by transformation of plants of the genus Lolium by transfer of the NPT-II gene, in such a way that provides the NPT-II gene with promoter and termination signals of the CaMV gene Vl, this incorporates into the pUC8 plasmid and transfers the resulting chimeric plasmid to isolated lolium protoplasts by treatment with polyethylene glycol.

Furthermore, the advantageous effect on the transformation by heat shock treatment and electroporation and the combined method of heat shock treatment, polyethylene glycol treatment and electroporation after the assembly of protoplasts and NPT-II gene is exemplified by examples.

Example 1: Transformation of cells of Nicotiana tabacum c. v. Petit Havana SRI by transfer of the NPT-II gene a) Construction of the plasmid pABDI

The freely accessible plasmids pkm21 and pkm244 are cut (Beck, E., et al., Gene 19, 323-336 [1982]) with the restriction endonuclease PstI. The fragments of the plasmids used for recombination are purified by electrophoresis in 0.8% agarose gel. The plasmid pkm21244 obtained from the junction of fragments contains a combination of the 5 'and 3' BaI 31 deletions of the NPT-II gene, as described by Beck et al in Gene 19, 323-336 (1982). To link the promoter signal of cauliflower mosaic virus with the HindIII fragment of plasmid pkm21244, the coupling plasmid pJPAX is constructed. The coupling plasmid pJPAX is obtained from the plasmids pUC8 and pUC9 (Messing, J and J. Vieira, Gene 19, 266-276 [1982]). Ten base pairs from the coupling sequence of plasmid pUC9 are cleaved at the HindIII and SalI positions and then filled with the adhesive ends with the polymerase I Klenow fragment (Jacobsen, H., et al., Eur. J. Biochem 45, 623, [1974]) and ligating the polynucleotide chain to restore the HindIII position. A synthetic coupling member of 8 base pairs (Xhol) is inserted at the Smal position of this separated coupling sequence. Recombination of the appropriate Xor1 and HindIII fragments of the plasmid pUC8 and the modified plasmid pUC9 yields the plasmid pJPAX with a partially asymmetric coupling sequence with the consecutive restriction sites: EcoRI, SMaI, BamHI, Sail, PstI, HindIII, BamHI; Xhol and EcoRI. The connection of the 5 'expression signal of the cauliflower mosaic virus gene Vl and the HindIII fragment of the NTP-II gene is inserted in the plasmid pJPAX by inserting the promoter region of the cauliflower mosaic virus gene Vl between the PstI and causes the HindIII position. The resulting plasmid is the only one

Cut Hind position and the Hind fragment of the plasmid pkm 21244 is incorporated into this interface in both orientation directions to obtain the plasmids pJPAX Cakm ⁺ and pJPAK CakrrT. To create an EcoRV sequence near the 3 'termination signal of the NPT-II hybrid gene, a BamHI fragment of the plasmid pJPAX Cakm ^{+ is} transfected into the BamHI position of plasmid pBR 327 (Soberon, X. et al., Gene 9, 287-305 (1980)). The plasmid pBR 327Cakm is obtained. The EcoRV fragment of plasmid pBR 327Cakm containing the new DNA construction is used to replace the EcoRV region of the cauliflower mosaic virus gene Vl, which is cloned at the Sall position in plasmid pUC8, thereby placing the protein-coding DNA sequence of the NPT-II gene under the control of the 5 'and 3' expression signals of the cauliflower mosaic gene Vl. The plasmids thus prepared are designated pABDI and pABDII (see FIG.

b) Transformation of protoplasts of Nicotiana tabacum c. V. Peti Havana SRI by transfer of the NPT-II gene as part of the plasmid pABDI by PEG treatment.

In 1 ml of K ₃ medium [see Z. Pflanzenphysiologie 78, 453-455 (1976); Mutation Research 81 (1981) 165-175] containing 0.1 mg / l of 2,4-dichlorophenoxyacetic acid, 1.0 mg / l of 1-naphthylacetic acid and 0.2 mg / l of 6-benzylaminopurine are in a population density of 2 x 10 ⁶ per ml of tobacco protoplasts previously obtained from an enzyme suspension by flotation to 0.6 molar sucrose at pH 5.8 and subsequent sedimentation (100 g for 5 minutes) in 0.17 molar calcium chloride at pH 5.8. To this suspension successively 0.5 ml of 40% polyethylene glycol MG 6000 (PEG) in modified (after autoclaving again adjusted to pH 5.8) F-medium (Nature 296,72-74 (1982)) and 65μΙ of an aqueous Solution containing 15 / xg of the plasmid pABDI and 50 / * g calf thymus DNA added. This mixture is incubated with occasional panning for 30 minutes at 26 ° C and then gradually diluted with F-medium. The protoplasts are separated by centrifugation (5 minutes at 100 g) and resuspended in 30 ml of fresh K ₃ medium. Further incubation takes place in 10 ml portions in Petri dishes of 10 cm diameter at 24 ° C and darkness, the population density being 6.3 x 10 ⁴ protoplasts per ml. After 3 days, the culture medium is diluted per dish with 0.3 volume of fresh K ₃ medium and incubated for a further 4 days at 24 ^C C and 3000 lux of artificial illumination. After a total of 7 days, the clones developed from the protoplasts are embedded in 1% agarose solidified, 50 mg / l kanamycin containing nutrient medium and by the "bead-type" culture method [Plant Cell Reports, 2,244-247 (1983)] at 24 ° C cultivated under darkness.The nutrient medium is replaced every 5 days by fresh, similar nutrient solution.

c) regeneration of kanamycin-resistant tobacco plants

After 3 to 4 weeks of continued culture in kanamycin-containing nutrient medium, the resistant cells of 2 to 3 mm in diameter are grown on agar-solidified LS culture medium [Physiol. Plant 18, 1-127 (1965)] containing 0.05 mg / l 2,4-dichlorophenoxyacetic acid, 2 mg / l 1-naphthylacetic acid, 0.1 mg / l 6-benzylaminopurine, 0.1 mg / l kinetin and 75 mg / l Kanamycin, transplanted. Shoot induction on LS medium containing 150 mg / l kanamycin and 0.2 mg / l 6-benzylaminopurine followed by rooting on T-medium [Science 163, 85-87 (1969)] contains Petit Havana Kanamycin-resistant Nicotiana tabacum plants SRI.

d) Detection of the NPT-II gene in the plant heritage

0.5 g of callus of the transformed cell cultures or leaf tissue of regenerated plants therefrom at 0 ⁰ C dissolved in 15% sucrose solution containing 50 mmol / l ethylenediamine -Ν, Ν, Ν ', Ν'-tetraacetic acid, EDTA), 0.25 mol / 1 sodium chloride and 50 mmol / l aa.a-tris-fhydroxymethyl-methylamine hydrochloride (TRIS-HCl) at pH 8.0. By centrifuging the homogenate for 5 minutes at 1000g, the nuclei are roughly separated. The cell nuclei are resuspended in 15% sucrose solution containing 50 mMol / L EDTA and 50 mMol / l TRIS-HCl at pH 8.0, sodium dodecyl sulfate added to a final concentration of 0.2%, and 70 ° C for 10 minutes C heated. After cooling to 20-25 ^c C, the mixture of potassium acetate is added to a concentration of 0.5 mol / l. This mixture is incubated for 1 hour at ⁰ ° C. The precipitated precipitate is centrifuged by centrifugation (15 minutes at 4 ⁰ C in a microfuge). The DNA is precipitated from the supernatant by adding 2.5 times the volume of ethanol at 20-25 ° C. The separated DNA is dissolved in this solution of 10 mM of TRIS-HCl containing 10 / ng / ml ribonuclease A, incubated for 10 minutes at 37 ° C, added with proteinase K to a concentration of 250 .mu.g / ml and for an additional hour incubated at 37 ⁰ C. Proteinase K is removed by phenol and chloroform / isoamyl alcohol extractions. From the aqueous phase, the DNA is precipitated by adding 0.6 volumes of 0.6 molar isopropanolic sodium acetate solution and dissolved in 50 μ \ a solution containing 10 mmol / 1 TRIS-HCl and 5 mmol / l EDTA, at pH 7.5 , The preparation yields DNA sequences predominantly containing more than 50,000 base pairs. Restriction of this DNA with EcoRV endonuclease, hybridization of the fragments with radiolabelled HindIII fragments of the NPT-II gene and comparison with the plasmid PABDI shows in a Southern blof analysis the presence of the NPT-II gene in the nuclear DNA of the transformed Nicotiana tabacum cells.

e) Evidence of the transmission of the transformed gene to the sexual progeny and its inheritance as a normal pet gene

Extensive genetic cross-linking analyzes and in-depth molecular biology studies (eg, "Southern blot" analysis of plant genome DNA; investigation of enzyme activity of aminoglycoside phosphotransferase, ie, the enzyme for kanamycin-specific phosphorylation) with the genetically modified plants (first generation and progeny) have the following Results provided:

1. The bacterial gene is stably incorporated into the plant genome;

2. It is usually transferred unchanged and regularly to cross-breeding offspring;

3. Its inheritance corresponds to that of a natural, simple, dominant plant gene;

4. Molecular analysis by DNA hybridization and enzyme assay confirms the results of genetic cross-analysis;

5. The genetically modified plants have retained their normal, natural phenotype during treatment; So no undesirable changes have been detected.

These results show that with the method according to the invention of direct gene transfer into protoplasts the best way for the targeted genetic modification of plant material has been found. The genetic change is stable and undesirable changes in the genotype of the plants do not occur. Corresponding results are obtained by carrying out the transformation described in the previous example also with Nicotiana plumbagenifolia, Petunia hybrida, Hyoscyamus muticus and Brassica napus.

Example 2: Transformation of cells of Brassica rapa c. v. Just Right by transmitting the NPT-II gene

a) Construction of the plasmid pCAMV 6 km

The plasmid pBR 327CAkm ⁺ described in example 1 a) is cut with restriction endonuclease EcoRV and the EcoRV restriction fragment with the kanamycin resistance gene (NPT-II) against the EcoRI fragment of the plasmid containing the gene VI of cauliflower mosaic virus pCa20-Bal 1 replaced. This gives the plasmid pCaMV 6 km (Figure 2). The plasmid Ca20-Bal 1 is a chimeric CaMV plasmid derived from the natural deletion mutant CM4-184. In this plasmid, with the exception of the first five codons and the translational stop signal TGA, the entire region II is missing. An Xho I coupling fragment was inserted immediately before the stop codon in the region II.

b) Transformation of protoplasts of Brassica rapa c. v. Just Right by transferring the NPT-II gene as part of the plasmid pCaMV 6 km by PEG treatment

Brassica rapa protoplasts are washed with an appropriate osmoticum and at a population density of 5 x 10 ⁶ per ml in a culture medium prepared according to Protoplasts 83, Poster Proceedings Experientia Supplementum, Birkhäuser Verlag, Basel, Vol. 45 (1983), 44-45 suspended. 40% polyethyleneglycol MG 6000 (PEG) dissolved in modified F medium (pH 5.8) (compare Example 1b) are mixed with the protoplast suspension to a final concentration of 13% PEG. To this mixture is added immediately a solution of 10% Endonuclease Sail-digested plasmid pCaMV 6km and 50 / xg calf thymus DNA in 60μ water. With occasional panning, the mixture is incubated for 30 minutes at 20-25 ⁰ C. Then 2 ml of modified F-medium (total 6 ml) and 2 ml of 2 ml of culture medium (4 ml in total) are added three times at intervals of 5 minutes each time. The resulting protoplast suspension is transferred into petri dishes of 10 cm diameter and made up to a total volume of 20 ml with further culture medium. These protoplasts suspensions are incubated at 26 ° C for 45 minutes in the dark. The protoplasts are separated by sedimentation for 5 minutes at 100 g, taken up in an initially liquid, then gelling agarose gel culture medium and cultured according to the "bead type" culture technique [Plant Cell Reports 2,244-247 (1983)] After 4 days At the stage of development of the first cell division, kanamycin is added to the cultures at a concentration of 50 mg / L. The liquid culture medium surrounding the agarose segments is replaced by fresh, kanamycin-containing nutrient solution every 4 days, and the kanamycin-resistant clones are isolated after 4 weeks are reproduced by weekly feeding with kanamycin-containing broth (50 mg / l).

c) detection of the NPT-II gene in the plant heritage

Isolation of the nuclear DNA and its restriction and hybridization of the DNA fragments can analogously to Example 1 d) the presence of the NPT-II gene in the nucleus of the transformed Bassica rapa cells are detected.

Example 3: Tranformation of Graminee Protoplasts of the Species Lolium multiflorum

Protoplasts of Lolium multiflorum (Italian Raygrass) are taken up in a concentration of 2 x 10 ⁶ per ml in 1 ml of 0.4 molar mannitol, pH 5.8. 0.5 ml of 40% polyethylene glycol MG 6000 (PEG) in modified (pH 5.8) F medium (Nature 296, 72-74 (1982), and 65 μl of an aqueous solution containing 15% are successively added to this suspension This mixture is incubated with occasional panning for 30 minutes at 26 ° C and then gradually diluted with F-medium, as described in Nature 296 (1982) 72-74.The protoplasts are purified by centrifugation (5 minutes at 100 g) and taken up in 4 ml CC culture medium [Protrykus, Harms, Callus formation cell culture protoplasts of corn ([Zea mays L.], Theor. Appl. Genet., 54, 209-214 [1979]), and incubated in darkness at 24 ° C. After 14 days, the growing cell cultures are transferred to the same culture medium but with the antibiotic G-418 G-418 is toxic to Lolium cells at a concentration of 25 mg / liter and allows only the further development of cells, which have taken up the bacterial gene for kanamycin resistance. G-418 is a kanamycin analog having significantly better potency in gramineous cells than kanamycin itself. Resistant cell colonies are transferred to agar medium (same medium as above, 25 ml / l G-418, without osmoticum) and after reaching a size of several grams fresh weight per cell colony, for the presence of the bacterial gene and for biological activity of the gene. The former is accomplished by hybridizing a radiolabeled DNA sample of the gene with DNA isolated from the cell culture; the latter is done by detecting the enzyme activity by phosphorylation of kanamycin with radioactive ATP. Both molecular detection methods provided clear evidence for the genetic transformation of the cell colonies that had been selected on G-418. The experiments represent the first evidence of the genetic transformation of Gramineae protoplasts, and prove, moreover, that with the described method grass protoplasts can in principle be genetically manipulated. Thus, the possibility of genetic manipulation of cultivated grasses, such. B. of cereals opened.

Example 4: Transformation of cell culture cells of Nicotiana tabacum by transfer of the NPT-II gene using electroporation

Of 50 ml of a log-phase suspension culture of the nitrate reductase-deficient variant of Nicotiana tabacum, cell strain nia-115 (Muller, AJ and R. Grrafe, Mol. Gen. Genet., 161, 67-76 (1978)), the protoplasts are passed through Sedimentation prepared in 20 ml enzyme solution [2% Cellulase Onozuka R-10.1% Mazerozym R-10 and 0.5% Driselase (Chemische Fabrik Schweizerhalle, Basel) in washing solution (0.3M mannitol, 0.04M calcium chloride and 0.5 % 2- (N-morpholino) -ethane-sulfonic acid); with KOH adjusted to pH 5.6] and incubated for three hours on a rotary shaker at 24 ^C. The protoplasts are then filtered through a sieve of 100 / mesh, retaining the undigested tissue remnants, added with an equal volume of 0.6 M sucrose, and centrifuged at 100 g for 10 minutes. The surface-floating protoplasts are collected and washed three times by sedimentation in the wash solution. The transformation is carried out using electroporation. The chamber of the "Porator" dialogue is sterilized by washing with 70% ethanol and then washing with 100% ethanol and exposed to a sterile stream of air from a laminar airflow blower for drying. The protoplasts are suspended in a concentration of 1 × 10 ⁶ / ml in 0.4M mannitol solution, adjusted with magnesium chloride to a resistance of 1.4 kOhm and treated with pABDI-DNA in a concentration of 10 / u, g / ml. Portions of 0.38 ml each of this protoplast suspension are exposed 3 times at intervals of 10 seconds each to a pulse of 1000 volts or a pulse of 2,000 volts. The protoplasts are then in a concentration of 1 χ 10 ⁵ / ml in 3 ml of AA-CH medium (AA medium according to Glimelius, K. et al ..

Physiol. Plant. 44,273-277 (1978), modified by increasing the inositol content to 100 mg / l and the sucrose content to 34 g / l and addition of 0.05 ml / l 2- (3-methyl-2-butenyl) adenine) cultured by containing 0.6% agarose in the solid state. After one week, the agarose layer containing the protoplasts is transferred to 30 ml of liquid AA-CH medium containing 50 mg / l kanamycin. After three weeks, in which weekly half of the liquid medium is replaced by fresh medium of the same composition, the transformed cell colonies can be perceived optically. These cell colonies are cultured further and examined 4 weeks after transfer to the kanamycin-containing medium on AA medium (Glimelius, K. et al., Physiol. Plant 44, 273-277 (1978), 0.8% agar). containing 50 mg / l kanamycin. The confirmation of the successful transformation is made by DNA hybridization and testing of the enzyme activity of aminoglycoside phosphotransferase. Analogous experiments with protoplasts of Brassica rapa and Lolium multiflorum also lead to successful transformation.

Example 5: Transformation of cells of Nicotiana tabacum by transfer of the NPT-II gene using electroporation

The preparation of the electroporator chamber is carried out as described in Example 4 and that of the protoplasts as described in Example 1.

For transformation, Nicotiana tabacum protoplasts are concentrated at 1.6 × 10 ⁶ / ml in mannitol solution (0.4 M, buffered with 0.5% by weight / volume 2- (N-morpholino) -ethanesulfonic acid pH 5.6). The resistance of the protoplast suspension is measured in the porer chamber (0.38 ml) and adjusted to 1 to 1.2 kΩ with magnesium chloride solution (0.3 M). Portions of 0.5 ml each are placed in closable plastic tubes (5 ml volume) and then 40 μl per tube, Ι of water containing 8 μl of pABDI (linearized with SmaI) and 20 / K) of calf thymus DNA, and then 0.25 ml of polyethylene glycol solution (24 wt% / vol in 0.4M mannitol). 9 minutes after DNA addition, 0.38 ml portions are added to the pulse chamber, and 10 minutes after DNA addition, the protoplasmic suspension contained in the chamber is exposed to 3 pulses (1000-2000 volts) at 10 second intervals. The so treated portions are placed in Petri dishes (diameter 6cm) and kept at 20 ° C for 10 minutes. To each petri dish is then added 3 ml of K ₃ medium containing 0.7% by weight / volume Sea Plaque agarose and the contents of the dish are well mixed. After solidification of the contents, the cultures are kept at 24 ° C for one day in the dark, then in the light for 6 days. Subsequently, the protoplast-containing agarose is cut into quarters and introduced into liquid medium. The protoplasts are then cultured by the bead-type culture method, and in callus tissues obtained by selection of the transformed material by kanamycin and in plants regenerated therefrom, the NPT-II enzyme (aminoglycoside phosphotransferase) as a product of the NPT-II enzyme is cultivated. With electroporation, an increase of the transformation frequency by 5 to 10 times is achieved compared to the corresponding method without electroporation Analogous experiments with Brassica rapa cv Just Right and Lolium multiflorum also increase the transformation frequency in the same order of magnitude.

Example 6: Transformation of cells of Nicotiana tabacum by transfer of the NPT-II gene using heat shock treatment

Protoplasts from leaves or cell cultures of Nicotiana tabacum are isolated as described in Examples 1 and 4 and transferred to an osmotic medium as described in the preceding examples. The protoplast suspension is kept for 5 minutes at a temperature of 45 ° C, cooled within 10 seconds with ice and then treated with the plasmid pABDI as described in Examples 1 and 4. Transformation frequency is increased by a factor of 10 or greater by heat shock treatment versus transformation without this procedure.

Analogous experiments with the protoplasts and plasmids described in Examples 2 and 3 also show an increase in the transformation frequency in the same order of magnitude.

Example 7: Transformation of various plant cells by transfer of the NPT-II gene combining protoplasts and gene as a first measure and subsequent combined treatment

Protoplasts of plants: Nicotiana tabacum c. v. Petit Havana SRI (A), Brassica rapa c. v. Just Right (B) and Lolium multiflorum (C)

are isolated and transferred into osmotic medium as described in Example 5. The protoplast suspension of A) and C) are mixed with the plasmid pABDI (Example 1 a), that of B) with the plasmid pCaMV 6km (Example 2a), as described in Examples 1 to 3, but without simultaneous treatment with polyethylene glycol. Subsequently, the protoplast suspensions are subjected to a heat shock treatment according to Example 6, then to a polyethylene glycol treatment as described in Examples 1 to 3, and then to electroporation according to Example 5. The transformation frequency in this procedure is in the range of 10 ~ ³ to 10 ~ ² , and depending on conditions, 1 to 2% can be achieved. (Transformation frequency in Examples 1 to 3 at about 10 ~ ^5). Results in the range of 10 ^-3 to 10 ^-2 also be achieved if the following measures of the heat shock treatment, polyethylene glycol treatment, electroporation, and are used in a different order for the matching of protoplasts and plasmids.

Claims (23)

Invention claim: 1. A method for the transformation of hereditary genetic material, characterized in that a gene which is under control of plant-active expression signals, without the aid of natural plant-infectious systems directly into plant cells, by introducing a foreign gene to be introduced and acting as a recipient, plant protoplasts together in a suitable solution and remains therein until the uptake of the gene into the protoplasts. 2. The method according to item 1, characterized in that an osmotically stabilized protoplast culture medium is used as the solution. 3. The method according to item 1, characterized in that leaving foreign gene and protoplasts over a period of a few seconds to a few hours in the solution. 4. The method according to item 1, characterized in that one uses a gene whose structural part is of plant, animal, microbial, viral or synthetic origin and whose expression signals are of plant origin. 5. The method according to item!, Characterized in that the gene transfer by means of one of the known per se, selected from the series: polyethylene glycol treatment, poly-L-ornithine or poly-L-lysine treatment, liposome fusion, electroporation, co-incubation of gene and plant cell, DNA-protein complexation, charge change on the protoplast membrane, fusion with microbial protoplasts, calcium phosphate coprecipitation or heat shock treatment. 6. The method according to item!, Characterized in that the gene transfer by means of one of the known per se, selected from the series: Polyethylene glycol treatment, poly-L-ornithine. or poly-L-lysine treatment, liposome fusion, electroporation, co-incubation of gene and plant cell, DNA protein complexation, charge change on the protoplast membrane, fusion with microbial protoplasts or calcium phosphate co-precipitation. 7. The method according to item 6, characterized in that the gene transfer is carried out by means of polyethylene glycol treatment. 8. The method according to item 5, characterized in that the gene transfer is carried out by means of heat shock treatment. 9. The method according to item 6, characterized in that the gene transfer is carried out by means of electroporation. 10. The method according to item 5, characterized in that the gene transfer by means of a combination of two or three • the techniques of polyethylene glycol treatment, heat shock treatment and electroporation is performed. 11. The method according to item 10, characterized in that the gene transfer by means of a combination of two or three of the techniques polyethylene glycol treatment, heat shock treatment and electroporation, which only after the introduction of foreign gene and protoplasts in a solution used, is performed. 12. The method according to item 11, characterized in that the gene transfer by introducing foreign gene and protoplasts into a solution, followed by heat shock treatment and subsequent polyethylene glycol treatment is performed. 13. The method according to item 11, characterized in that the gene transfer by introducing foreign gene and protoplasts into a solution, subsequent heat shock treatment, subsequent polyethylene glycol treatment and final electroporation is performed. 14. The method according to item 1, characterized in that the gene transfer in the presence of plant-compatible, divalent cation is performed. 15. The method according to item 14, characterized in that the cations are mangnesium or calcium cations. 16. The method according to item 1, characterized in that the gene transfer is carried out at a pH of 9 to 10.5. 17. The method according to item 1, characterized in that they are protoplasts of plants of the families Solanaceae, Cruciferae, Compositae, Liliaceae, Vitaceae, Chenopodiaceae, Rutaceae, Bromeliaceae, Rubiaceae, Theaceae, Musaceae or Gramineae or order Leguminosae. 18. The method according to item 17, characterized in that they are protoplasts of the families Solanaceae, Cruciferae and Gramineae. Method according to item 1, characterized in that it is used for the transformation of plants regenerable from protoplasts. 20. Method according to item 1 for transformation of plants of the group Nicotiana tabacum, Nicotiana plumagenifolia, Petunia hybrida, Hyoscyamus muticus and Brassica napus by transfer of the IMPT-II gene, characterized in that the NPT-II gene with promoter and termination signals of the CaMV gene Vl incorporates this into the PCU8 plasmid and transfers the obtained chimeric plasmid by polyethylene glycol treatment in isolated protoplasts of plants of the aforementioned group. 21. The method according to item 20 for the transformation of tobacco plants by transfer of the NPT-II gene, characterized in that one provides the NPT-II gene with promoter and termination signals of the CAMV gene Vl, this incorporates into the PUC8 plasmid and transfers the resulting chimeric plasmid to isolated tobacco protoplasts by polyethylene glycol treatment. 22. Method according to item 1, for the transformation of plants of the genus Brassica by transfer of the NPT-II gene, characterized in that one provides the NPT-II gene with promoter and termination signals of the CaMV gene Vl, this construction instead of the CAMV gene Vl incorporated into the CaMV genome and transfers the resulting chimeric plasmid by polyethylene glycol treatment in isolated Brassicaprotoplasten. 23. Method according to item 1 for the transformation of plants of the genus Lolium by transfer of the NPT-II gene, characterized in that one provides the NPT-II gene with promoter and termination signals of the CaMV gene Vl, this in the PuC8- Plasmid incorporates and transfers the resulting chimeric plasmid by polyethylene glycol treatment in isolated Loliumprotoplasten.