CH670655A5 - - Google Patents

Description

DESCRIPTION

The present invention relates to a method for producing genetically transformed plant objects, which is used for the production of new types (forms) of plants, including agricultural plants, which are characterized by certain properties, such as specific resistance to herbicides, specific resistance to pathogenic viruses and microorganisms, the changed amino acid composition, the increase in the useful biomass, an increased resistance to adverse environmental factors and the like.

Various methods are known which make it possible to transform protoplasts of higher plants with subsequent production therefrom by selecting cell lines and plants with new inheritable properties. For example, a method is known which consists in adding Nicotiana tabacum DNA to the suspension of the protoplasts, the mixture obtained subsequently being influenced by physical and chemical factors, which leads to the penetration of DNA into protoplasts (Potiykus J., Shillito RD, Saul MW, Paszkowski J. Direct Gene Transfer. State of the Art and Future Potential. Plant Mol. Biol. Reporter, v. 3, No. 3, 1985, p. 117-128).

A method is also known in which genetic material is added to protoplasts Nicotiana tabacum, which is enclosed in lipid vesicles (liposomes) in the presence of an agglutinator, which leads to the confluence of protoplasts and liposomes with penetration of the genetic material into the protoplast (Nagata T. Liposomes as a Carrier of Ti-plasmid into Protoplasts. In: Molecular Genetics of the Bacteria-Plant Interaction. Ed. Pühler, Springer-Verlag, Berlin ea 1983, 268-273).

The methods mentioned are characterized by their limited application possibilities, because they can be used for a limited number of plant species, and only for the plants and cell cultures for which the methods for producing and cultivating the protoplast with subsequent regeneration of plants develop therefrom -celt. In addition, the methods mentioned are characterized by a low transformation effectiveness (at most one percent) and a significant consumption of transforming factor.

A method for producing the genetically transformed plant objects is known, in which proto-plastics from Nicotiana tabacum are used as the recipient. The plasmids pCGN 561 are introduced into protoplasts by microinjection (Crossway A. et al., Integration of foreign DNA following microinjection of tabacco mesophyll protoplasts. Mol. Gen.

Genet., 1986, v. 202, p. 179-185).

Neither cell lines nor plants with new heritable properties were obtained in the mentioned method, nor was the expression of the introduced genetic material shown. The method mentioned can only be used for protoplasts, was only implemented on a laboratory scale and cannot be used in practice.

The invention has for its object to develop a method by expanding the circle of object recipients and transforming factors, which makes it possible to increase the transformation effectiveness, reduce the consumption of the transforming factor and to increase the number of plant species, the genetic manipulations can be exposed to higher plants.

The object was achieved in that, in the method according to the invention for producing genetically transformed plant objects, by introducing the transforming factor into the recipient and subsequently selecting cell lines and plants with new heritable properties from them, according to the invention, a DNA molecule or an autonomously transforming factor Replicating cell organelles and the protoplast, the single cell or a cell in the cell assembly can be used as the object receiver, the transformation factor being introduced into the object receiver by microinjection. The microinjections can be carried out by any suitable method. It is expedient to carry out the microinjections under the influence of the pressure or the electric field.

The method according to the invention allows the transformation effectiveness to be increased to 40%, which exceeds the transformation effectiveness of known methods by 10 to 20 times, the consumption of the transforming factor being significantly lower.

The method according to the invention allows the protoplast as well as the single cell and a cell in the cell cluster or in the plant to be used as the object receiver, and both the DNA molecules and the autonomously replicating cell organelles as the transforming factor. This allows to expand the number of plant species that are fed into genetic manipulations, including agriculturally important crops, for example grass crops.

The method according to the invention is carried out as follows.

The protoplast, the single cell or a cell in the cell cluster or in the plant (micro callus, embiyogenic callus,

Embiyoid), which are used as object receivers, are accommodated in the corresponding nutrient solution in a micro-chamber, which has been mounted on the microscope slide, and fixed with the aid of a device for suctioning or by pouring agar or mechanically. The glass needle filled with the transforming factor (plasmids, cosmids, chloroplast) in the appropriate medium is inserted into the object receiver with the aid of a micromanipulator under visual control through the microscope. Microinjection is carried out under the influence of pneumatic or hydraulic pressure or under the influence of the electric field. The volume of the solution to be introduced is dosed from 1 to 10 pl (picoliter). All of the work is done under sterile conditions. The injected object receivers are transferred to the selective nutrient medium. The selection of the selective nutrient medium is determined by the transforming factor. The selection of the transformant and the enrichment of its biomass is carried out on multiple passes through the object receiver on selective media. Plants are regenerated from the transformed cell lines and cell cultures on the selective media. The transformation effectiveness is at most 40%. The indexing and expression of the imported genetic material becomes after

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known biochemical methods confirmed.

In order to better understand the present invention, the following examples are given for realizing the method according to the invention.

example 1

A microneedle with a tip diameter of about 1 .mu.m is inserted into the protoplast isolated from the Nicotiana debneyi callus, and 1 to 2 μl (picoliter) of buffer solution (10 mmol of Iis, pH 7.2) are pressed using the hydraulic system. 1 mmol sodium ethylenediaminetetraacetate, 5 mmol KCl), which contains the plasmids pSV2 Neo in an amount of approximately 100 copies per 1 picoliter buffer. During the microinjection and until the first cell divisions, the protoplast is in the Caboche nutrient medium with the addition of 0.1% by weight agarose. The microcolonies formed from the injected protoplasts are transferred to the Gamborg nutrient medium with the addition of 60 mg / dm3 antibiotic kanamycin sulfate. From 53 injected protoplasts, 8 cell lines were obtained which are capable of growing on a medium containing up to 120 mg / dm3 antibiotic. The transformation effectiveness is 15%. From three stable lines, plants capable of growth and consolidation on the medium with kanamycin were regenerated on the Gamborg nutrient medium without the addition of phytohormones.

Example 2

The procedure is carried out similarly to Example 1. The individual cells of Nicotiana tabacum are used as object recipients and the plasmids pLGV23 Neo as the transforming factor. The microinjection is carried out with the help of the pneumatic system. From 20 injected cells, 3 cell lines were selected according to the selection method which are capable of growing on the Gamborg nutrient medium containing 120 mg / dm3 antibiotic kanamycin sulfate.

Example 3

The procedure is carried out similarly to Example 1. The cells in the microcallus (from 8 to 30 cells) Lycopersicon esculentum in the Sachin nutrient medium with the addition of 0.3% by weight of agarose are used as object recipients. The plasmid pGV0319 is used as a transforming factor. According to the properties coded with the plasmid, the selection of the transformants is carried out on the Sachin nutrient medium which does not contain any hormones. When the plasmids were introduced into 95 cells, 19 cell lines were selected according to the selection method which are capable of growing on a hormone-free medium. The transformation effectiveness is 19%.

Example 4

5 The procedure is carried out similarly to Example 1. The individual cells of Nicotiana tabacum are used as object recipients and the cosmid pGA 471 as the transforming factor. The injection is effected under the influence of the electric field strength of 5 to 10 V with a few pulses of 0.5 duration at a current value of up to 0.1 jiA realized. From 23 cells transformed in this way, 6 cell lines were obtained which are capable of growing on the nutrient medium containing 120 mg / dm3 kanamycin sulfate. The transformation effectiveness is about 25%. Plants were regenerated from 2 cell lines, which are capable of growth and solidification on the medium with kanamycin.

Example 5

The procedure is carried out similarly to Example 4. The cells of the embiyogenic callus from the Triticum aestivum wheat of the Mironovskaya rannyaya variety are used as the object recipient, which are mechanically fixed. Eight calluses are used and from 20 to 100 cells are injected into each. The calluses are passed through on the culture medium of Murashige-Skoog with 2 mg / dm2 2,4-dichlorophenoxyacetic acid with the addition of 60 mg / dm3 kanamycin sulfate. Eight cell lines were obtained which are capable of growing on the culture medium with kanamycin sulfate.

Example 6

The procedure is carried out similarly to Example 1. Individual white cells of the Nicotiana tabacum plastom-mutant of the IP line and as the autonomously replicating organelles chloroplasts, which were isolated from the leaves of Nicotiana tabacum of the SR2 line, were used as the object recipient. most encoded antibiotic streptomycin is labeled. The chloroplast suspension in the nutrient medium from Jensen and Basshem is used to fill a micropipette with a tip diameter of up to 8 µm and to press 5 to 10 chloroplasts into the cell. The injected cells after the first tick marks are transferred to the Gamborg culture medium, which contains 1 mg / dm3 streptomycin sulfate. From 16 cells injected in this way, 3 cell lines were selected, which are characterized by the green color and the ability to grow on a nutrient medium with 1 mg / dm3 antibiotic.

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Claims (3)

670 655 PATENT CLAIMS 1. A process for the production of genetically transformed plant objects by introducing a transforming factor into the object receiver and then selecting the cell lines and plants with new heritable properties, characterized in that a DNA molecule or an autonomously replicating cell organelle and as a transforming factor Object recipient, a protoplast, a single cell or a cell in the cell cluster can be used, the introduction of the transforming factor into the object recipient being carried out by microinjection. 2. The method according to claim 1, characterized in that the microinjection is carried out under the action of pressure or an electric field. 3. Use of the plant objects obtained by the process according to claim 1 for the production of plants by regeneration on selective media.