RU2158496C2 - Method of obtaining f1 hybrid seeds - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves selecting plants with long-pistillate flowers of plant group with heteromorphic self-sterility; isolating selected plants; effectuating artificial pollination or natural hybridization for initiating predetermined hybridization to obtain line composed of plants with long-pistillate flowers; effectuating artificial or natural hybridization of specimens of obtained line under condition of isolating this line from other lines; promoting seed germination for obtaining of parental seed line composed of plants with long-pistillate flowers; planting seeds of parental line (line A) composed of plants with long-pistillate flowers; planting seeds of other line (line B) in the vicinity of line A, with plants of line B being composed of plants with short-pistillate flowers or of plants with both short-pistillate and long-pistillate flowers; collecting seeds of line A pollinated with line B pollen. Method allows large quantities of F1 hybrid seeds to be produced by hybridization of A and B lines. EFFECT: simplified method and provision for commercial production of F1 hybrid seeds. 3 cl, 4 tbl, 3 ex

Description

The invention relates to a method for producing seeds F _{i of a} hybrid of plants exhibiting heteromorphic self-sterility.

State of the art
By self-sterility is understood a phenomenon in which there is no natural cross-pollination of two plants with normal male and female organs. Heteromorphic self-sterility refers to the phenomenon when there are no seeds during cross-pollination of the same type of flowers having long pistils and short stamens or short pistils and long stamens. In fact, plants with long-flowered flowers are homozygous with a recessive gene "s", and plants with short-flowered flowers are heterozygous with a recessive gene "s" and a dominant gene "S". Typically, the ratio of plants with long-tailed flowers and short-tailed flowers ss and sS is maintained at 1: 1. But if the process of crossing is carried out in a group consisting only of plants with long-pistil flowers, then the next and subsequent generations will consist entirely of plants with long-pistil flowers.

When the crossing process is carried out between two different self-pollinating lines (or forcedly pollinated), hybrid seeds are possible. The resulting hybrid seeds can be further used to produce hybrid plants called F _i hybrids. It is known that for cross-pollinated crops such as wheat and some vegetables were withdrawn several elite varieties F ₁ hybrids.

Over time, the F ₁ hybrid crop has been proven effective. In particular, it turned out to be most useful for obtaining elite varieties of cross-pollinated plants such as wheat and rape. Therefore, there is a need to create practically useful methods for producing seeds of the F ₁ hybrid.

 For this, the line with cytoplasmic male sterility was most often used. However, it is difficult to find a cytoplasm that provides male sterility in many plant species.

To solve the problem, a method was proposed for producing F ₁ hybrid seeds using incompatibility (see, for example, D.N.Duvik, Influence of morphology and sterility on the selection methodology: in collection Plant breeding. Edited by K. J. Frey: ed. University of Iowa (USA), 1964, pp. 85-137). The specified method was tested in the process of growing plants, in particular, when obtaining improved varieties of certain varieties of vegetables belonging to the species Brassica, such as cabbage, exhibiting homomorphic self-incompatibility (self-sterility).

On the other hand, it seems possible to use the method of obtaining F ₁ hybrid seeds for plants that exhibit heteromorphic self-sterility. However, at present, there is no method that really would allow to obtain a large number of F ₁ hybrid seeds for industrial purposes. That is why there is still no industrial way to obtain a line consisting only of plants with long-pedigree flowers or plants with short-pedigree flowers.

Research in the field of pollination technique indicates the possibility of producing hybrid seeds experimentally, in which pollination of long-pistil flowers is done manually, but this technique is not applicable to obtain a line consisting only of plants with long-pistil flowers, which can be used for industrial seed production. Currently, as practically useful, the method of obtaining F ₁ hybrid seeds at the experimental level is implemented by manual pollination. Plants with long-pistil or short-pedicle flowers are selected from the group on the same line, and then pollinated by pollen from other lines using pollinators.

However, these methods are expensive, since they are very laborious for the production of a large number of F ₁ hybrid seeds, which excludes their use for industrial purposes.

SUMMARY OF THE INVENTION
The objective of the present invention is to provide an effective method for producing F ₁ hybrid seeds of plants with heteromorphic self-sterility and thus solve the above-mentioned problems characteristic of these areas.

The problem is solved in a method for producing F ₁ hybrid seeds of plants with heteromorphic self-sterility, comprising the following stages:
- selection of plants with long-pistil flowers from a group of plants with heteromorphic self-sterility;
- isolation of selected plants;
- the implementation of artificial pollination or natural hybridization to initiate a predetermined hybridization, providing a line consisting only of plants with long-pistil flowers:
- the implementation, by artificial or natural means, of further hybridization of individuals of the obtained line in conditions of isolation of this line from other lines;
- stimulation of seed growth to obtain a seed parent line, consisting only of plants with long-pedicled flowers;
- planting seeds of the parental line (line A), consisting only of plants with long-pistil flowers;
- planting close to line A of another line (line B) consisting only of plants with short-pedicled flowers or plants of both species - both with short-pedigree and long-pedicled flowers;
- collecting seeds of line A pollinated by pollen of line B, and thus producing F ₁ hybrid seeds by hybridizing lines A and B.

 The resulting plants exhibiting heteromorphic self-sterility include several varieties of buckwheat, such as Kitavasesoba, Kityayuka, Botansoba, Shinanonatsusoba, Shatilovskaya 5, Ballad, Sumchanka.

 The above objectives and features of the present invention will be better understood from the following description with reference to tables.

 Implemented methods in accordance with the present invention can be described in detail as follows.

Initially, plants with long-pistil flowers are selected from the group of plants exhibiting heteromorphic self-sterility and create isolated conditions for them. Next, artificial pollination or natural hybridization is carried out to initiate a given hybridization, providing a line consisting only of plants with long-pistil flowers. Then, in conditions of isolation of the obtained line from other lines, the subsequent hybridization is carried out artificially or naturally, and by germinating the seeds, a parent line is obtained consisting only of plants with long-pistil flowers. Further, in accordance with the present invention, seeds of the parent line (line A) are planted. Then, another line (line B) is planted near line A, consisting of plants with short pedicel flowers or plants with both short pedicel and long pedicel flowers. Finally, seeds of line A pollinated by pollen of line B are harvested, thereby producing F ₁ hybrid seeds by hybridization of lines A and B.

 The invention is disclosed in the following experiments.

 First, plants with short-pedigree flowers were removed from the Kitavasesoba plant group, and plants with long-pedicled flowers were left. Further, these plants were covered with an insulator and thus they were completely isolated from the environment. After this, several pollinators (insects) were placed in an insulator. Thus, the desired hybridization was achieved, and the seeds obtained amounted to 1/4 of the amount obtained under normal growing conditions. Next, the resulting seeds were collected and sown. It was found that the next generation of plants had long-flowered flowers. Further, the obtained plants were planted under natural conditions separately from other buckwheat lines, and it was further established that a predetermined hybridization takes place, and the obtained seeds are seeds of the parent line of plants that have only long-pistil flowers.

 From the experiment described above, it is clear that in this way it is possible to grow a line consisting of plants with only long-pistil flowers in an amount that satisfies industrial purposes.

 After conducting several similar experiments on six types of buckwheat grown both locally and abroad, it was established that seeds can be obtained by hybridization of plants with only long-pistil flowers, producing parental lines of plants with only long-pistil flowers.

Further, a group of representatives of Kitavasesoba, consisting only of plants with long-pistil flowers, was planted at different distances from the group of Kitavasesoba plants with long-pistil and short-pedigree flowers. It was found that the rate of seed formation decreases with increasing distance between these groups. Namely, the farther the distance, the lower the rate of seed formation. Seeds were obtained on all experimental plants. When we conducted the same study of the next generation, we found that the ratio of plants with long-pedigree flowers and plants with short-pedigree flowers is 1: 1. From this it is clear that pollination with a short-pistil flower is possible and that almost all groups of plants with only long-pistil flowers can be pollinated with pollen from plants with short-pedicled flowers. The foregoing indicates that the present invention allows, by growing near a line having only long-pistil flowers (line A), another line having only short-pistil flowers (line B), to obtain a large amount of F ₁ hybrid seeds on an industrial scale.

 Three experiments, a detailed description of which are presented below, were carried out on flowering plants.

Plant: Buckwheat (Fagopyrum esculentum Moench)
Varieties: Kitavasesoba, Kitayuka, Botansoba, Shinanonatsusoba, Shatilovskaya 5, Ballad, Sumanka.

Pollinator: stinging fly
Experiment N 1
Twenty plants with long-pistil Kitavasesoba flowers (buckwheat cultivar) immediately after flowering were covered with a plant insulator so that insects could not get there. Then the blossoming flowers were opened and 100 stinging flies were introduced into the plant isolator. After 90 days, the ripened seeds were collected, the number of brushes and the number of seeds were counted. The collected seeds were then sown in a greenhouse or field and their flowers were studied. At the same time, natural crosses were carried out in vivo. Then, after full ripening, 20 plants were randomly selected, the number of brushes and the number of seeds were calculated.

 Results.

 In this experiment, seeds were obtained by initiating crossbreeding in a group of buckwheat individuals consisting only of plants with long-pistil flowers, as shown in Table. 1. It was found that although the number of seeds obtained in this experiment varies significantly from one individual to another, seeds are obtained from almost all buckwheat individuals. In addition, it was found that after sowing these seeds in a greenhouse and on a field that was significantly removed from other buckwheat fields, the desired seeds were obtained by crossing buckwheat individuals with only long-pistil flowers (all the plants studied were plants with long-pistil flowers), as this is shown in table. 2. As follows from the table. 2, when plants obtained from the isolator were cultivated under natural conditions, it was found that the desired seeds are obtained. In accordance with the table. 2, although the number of seeds produced for each brush was only 0.5 of the corresponding value obtained under conditions when plants with long-pistil flowers and plants with short-pedigree flowers were cultivated in a mixed way, we can assume that a sufficient increase in seeds and a sufficient development of the line were obtained. Thus, it can be argued that a practically useful method has been developed for the production and development of a line consisting only of plants with long-pistil flowers.

 The desired seeds obtained in this experiment were intended to be used as seeds of the parental line, consisting only of plants with long-pistil flowers.

Experiment N 2
Using the same method as in experiment 1, the crossing process was carried out in each of six groups consisting of six varieties of buckwheat (Kitayuk, Botansoba, Shinanonatsusoba, Shatilovskaya 5, Ballad, Sumchanka) in six isolators. These six varieties of buckwheat were those that are grown locally and abroad, and consisted only of plants with long-pistil flowers. After their full maturation, 20 individuals were randomly selected in each group, the number of brushes and the number of seeds were calculated.

 Results.

 As in experiment No. 1, although the number of seeds obtained in this experiment varied from one individual to another, all plants of these six varieties were all able to produce seeds with such a cross that is shown in Table. 3. As can be understood from the table. 3, it is possible to obtain plant lines consisting only of plants with long-pistil flowers, regardless of genotype.

Experiment N 3
A group of Kitavasesoba plant individuals, consisting only of plants with long-pistil flowers, was planted in various places at distances of 0-12 m from the pollen source of the usual Kitavasesoba variety, containing plants with both long-pistil flowers and short-pedicled flowers. Next, another buckwheat variety (Hokai N 3) was planted between the above plants. Then the crossing process was carried out in vivo. After ripening, 20 plant individuals were randomly selected, the number of brushes and the number of seeds were counted. Then 100 seeds were randomly selected from these seeds, they were sown and cultivated, after which their morphology was examined.

 Results.

 It is well known that hybrid seeds cannot be obtained by crossing Kitavasesoba and Hokai N 3 plants, since the former are diploid and the latter tetraploid. Therefore, the seeds of the studied plants were obtained either by pollination with pollen from a pollen source of the usual Kitavasesoba or by crossing among plants with only long-pistil flowers inside the same experimental site. As shown in Table 4, the more the experimental site is removed from the pollen source, the more difficult pollination is (from the pollen source). As a result, the greater distance between the site and the pollen source is expressed in the lesser efficiency of seed formation on the site.

 In addition, it was found that next-generation plants grown from the aforementioned seeds obtained at the aforementioned sites include plants with long-pistil flowers and plants with short-pedigree flowers in a 1: 1 ratio. This means that almost all the seeds obtained in this experiment at the above sites were pollinated with pollen from plants with short-pedigree flowers.

As can be understood from this experiment, if a group consists only of plants with long-pedicled flowers and if it is possible for a group of plants to be pollinated by short-pedicled flowers, pollen pollination of plants with short-pedicled flowers will be more likely than pollen pollination of plants with long-pedicled flowers. That is, if in the vicinity of line A, consisting of plants with long-pedicled flowers, line B is planted containing plants with short-pedicled flowers, almost all plants of line A (or 100% of plants of line A) will be pollinated by pollen of line B. Thus, they will be obtained with high efficiency seeds of F ₁ hybrid.

As follows from the foregoing, the claimed method provides the production of seeds of F ₁ hybrid on an industrial scale, which will improve new plant varieties adapted for reproduction with high productivity and having uniform quality.

 Despite the fact that the description provides only the preferred implementation of the proposed method, it is clear that it reveals the essence of the invention and that various changes and modifications of the method are possible without changing its essence set forth in the claims.

Claims (3)

1. The method of obtaining F ₁ hybrid seeds of plants with heteromorphic self-sterility, comprising the following stages: selection of plants with long-pied flowers from the group of plants with heteromorphic self-sterility; isolation of selected plants; the implementation of artificial pollination or natural hybridization to initiate a predetermined hybridization, providing a line consisting only of plants with long-pistil flowers; the implementation by artificial or natural means of subsequent hybridization of individuals of the obtained line in conditions of isolation of this line from other lines; stimulation of seed growth to obtain the seed parent line, consisting only of plants with long-pedigree flowers; planting seeds of the parent line (line A), consisting only of plants with long-pedicled flowers; planting near the line A of another line (line B) consisting only of plants with short-pedicled flowers or of plants of both species - both with short-pedicled and long-pedicled flowers; collecting seeds of line A pollinated by pollen of line B, and thereby producing F ₁ hybrid seeds by hybridizing lines A and B.  2. The method according to claim 1, characterized in that buckwheat varieties are used as plants exhibiting heteromorphic self-sterility.  3. The method according to claim 2, characterized in that the following varieties of buckwheat are used: Kitavasesoba, Kitayuk, Botansoba, Shinanonatsusoba, Shatilovskaya 5, Ballad, Sumanka.

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