KR20230067206A - Plant fertilization promoter that promote pollination of self-incompatibility fruit - Google Patents

Abstract

The present invention relates to a fertilization promotor for promoting fertilization of self-incompatible fruit trees. More specifically, by mixing zinc gluconate, vitamin B1, vitamin B6, and boric acid with water by wet dispersion, the present invention contains zinc gluconate, which is effective in inhibiting the activity of S-RNase, a pistil-specific gene, avoiding the self-incompatibility of self-incompatible fruit trees, thereby promoting natural fertilization by inducing self-fertilization. The present invention has the advantage of producing high-quality fruits such as regular fruits and large fruits by increasing the number of seeds during fertilization while minimizing the help of insect vectors, and due to the zinc gluconate, vitamin B1, vitamin B6, and boric acid components contained in the fertilization promotor, fertilization of fruit trees are promoted and the growth of the plant can be benefitted. As a result, high-quality fruit can be obtained.

Description

Fertilization promoter for promoting fertilization of self-incompatible fruit trees

The present invention relates to a fertilization promoter for promoting fertilization of self-incompatible fruit trees, and more specifically, by mixing zinc gluconate, vitamin B1, vitamin B6 and boric acid with water in a wet dispersion method, Since zinc gluconate, which is effective in inhibiting the activity of S-RNase, a gene, can break the self-incompatibility of self-incompatible fruit trees, it has the advantage of promoting natural fertilization by inducing self-fertilization. It has the advantage of producing high-quality fruits such as orthopedic fruits and large fruits by increasing the number of seeds during fertilization while minimizing the help of insects. It relates to a fertilization promoter for promoting the fertilization of self-incompatible fruit trees, which not only has the effect of promoting fertilization of fruit trees but also helps the growth of the plant itself, and consequently has the advantage that fruits of excellent quality can be set.

Most of the fruit trees cultivated in Korea go through the process of flowering and fertilization from mid-March to early April along with the development from flower buds to flower buds.

However, there is a problem that fertilization does not work well due to the abnormal climate and the continued decrease in fertilization vectors, or even if fertilized, the number of seeds is insufficient to form atypical fruits or premature fruit drop.

In order to prevent such damage, at least one selected from hormones such as β-indoleacetic acid and chlorophenoxyacetic acid, purines obtained by decomposition of nucleic acids, pyrimidines, nucleosides (such as inosine), and nucleotide groups, etc. There is a method using a flowering promoter of plants containing as an active ingredient. For example, Korean Patent Publication No. 10-2001-0051263 discloses a plant flowering promoter containing inosine as an active ingredient.

In addition, as disclosed in Korean Patent Registration No. 10-1810356 and Korean Patent Registration No. 10-2095345, methods for accelerating the flowering period of plants using protein variants are also being developed and disclosed.

However, the method of promoting flowering and flowering time of plants as described above has a problem in that it is difficult to apply to various plants. There is also a problem that a similar effect can be expressed when used in combination with a substance, and there is a disadvantage that it is not easy to spread the product due to the high price of the raw material itself. In particular, the flowering promoter and the method for accelerating flowering time as described above have a disadvantage in that they have little or no effect on the flowers of self-incompatible fruit trees.

Self-incompatibility refers to a phenomenon that increases genetic diversity by recognizing and disassembling pollen of a genetically identical plant in the pistil to prevent self-fertilization and induce cross-fertilization. Angiosperms form progeny seeds through double fertilization. In the case of self-incompatible plants, in the early stage of double fertilization, cells located on the stigma recognize pollen that has the same genotype as their own, resulting in pollen tube growth. It stops self fertilization by stopping or degrading nucleic acids in pollen.

More than half of the flowering plants on this planet have the property of being self-incompatible. The nature of self-incompatibility is largely classified into gametophytic self-incompatibility and sporophyte self-incompatibility based on the ability of the shipper to discriminate the genotype of self-pollen and the ability of pollen tissue to inhibit maturation or growth of self-pollen.

Among them, plants belonging to the gametophyte include flowers of the family Solanaceae, Rosaceae, Papaveraceae, and Liliaceae, fruit trees such as apples and pears, and plants of the Cruciferae family such as radishes and Chinese cabbages, and Asteraceae plants belong to the sporophyte.

In the case of gametophytic self-incompatibility, when the genotypes of a diploid pistil and a haploid pollen are the same, pollination takes place but the pollen tube stops elongation in the upper layer of the embryo's metastatic tissue, so fertilization cannot occur in the ruckus. Ultimately, seeds do not form. Combining the knowledge of genetics, biochemistry, cell biology and molecular biology to date, gametophytic self-incompatibility is that S-RNase, one of the locus products of self-incompatibility that has RNase activity in the shipper tissue, is specific to the time and site in the shipper tissue. It is known that when pollen with the same genotype exists as an enemy and grows in the host tissue, it attacks them and makes them self-incompatible.

Accordingly, in the present invention, in order to solve the problem of poor fertilization of fruit trees due to the abnormal climate and the continued decrease in fertilization vectors, a fertilization promoter is developed to promote fertilization of fruit trees, especially suitable for self-incompatible fruit trees. An attempt was made to develop fertility accelerators.

Republic of Korea Patent Publication No. 10-2001-0051263 (2001.06.25. Publication) Republic of Korea Patent Registration No. 10-1810356 (registered on December 12, 2017) Republic of Korea Patent Registration No. 10-2095345 (registered on March 25, 2020)

The present invention has been made to solve the problems described above and provide necessary technology,

The present invention is prepared by mixing zinc gluconate, vitamin B1, vitamin B6, and boric acid with water in a wet dispersion method, and contains zinc gluconate, which is effective in inhibiting the activity of S-RNase, a pistil-specific gene. Since it can break the self-incompatibility of synthetic fruit trees, it has the advantage of promoting natural fertilization by inducing self-fertilization, and increasing the number of seeds during fertilization while minimizing the help of insects, It is an object of the present invention to provide a fertilization promoter for promoting fertilization of self-incompatible fruit trees having the advantage of producing high-quality fruits.

In addition, according to the present invention, zinc gluconate, vitamin B1, vitamin B6, and boric acid contained in the fertilization accelerator not only promote the fertilization of fruit trees but also help the growth of the plant itself, resulting in fruit of excellent quality. Another object is to provide a fertilization promoter for promoting the fertilization of self-incompatible fruit trees with excellent potential.

As one embodiment of the present invention for achieving the above object,

One embodiment of the present invention provides a fertilization promoter for promoting fertilization of self-incompatible fruit trees, characterized in that it is composed of zinc gluconate, vitamin B1, vitamin B6, boric acid and water.

In the present invention, the fertilization accelerator is 0.05 to 10% by weight of zinc gluconate, 0.01 to 2% by weight of vitamin B1, 0.01 to 2% by weight of vitamin B6, 0.01 to 1% by weight of boric acid, and 85 to 99% by weight of water. It is characterized in that the composition is mixed.

In the present invention, the fertilization promoter is characterized in that it is used by diluting with water at a ratio of 900 to 1100 times when spraying on the flower surface of fruit trees.

The fertility promoter according to an embodiment of the present invention is prepared by mixing zinc gluconate, vitamin B1, vitamin B6, and boric acid with water in a wet dispersion method, which is effective in inhibiting the activity of S-RNase, a pistil-specific gene. Since it contains zinc gluconate, it can overcome the self-incompatibility of self-incompatible fruit trees, so it has the advantage of promoting natural fertilization by inducing self-fertilization. It has the advantage of being able to produce high-quality fruits such as regular fruits and large fruits by increasing the number of fruits.

In addition, the fertilization promoter according to one embodiment of the present invention contains zinc gluconate, vitamin B1, vitamin B6, and boric acid components, thereby promoting fertilization of fruit trees as well as helping the growth of the plant itself, resulting in There is an advantage that fruits of excellent quality can be set.

In addition, the fertilization promoter according to one embodiment of the present invention provides a undiluted fertilization promoter in a stabilized liquid state, but is used in a manner that is sprayed on the flower surface of fruit trees during flowering, making it easy to store the fertilization promoter in farms , The stability of the fertilization accelerator can be maintained uniformly to prevent quality deterioration, and since it can be diluted and used immediately when necessary, it has the advantage of being easy to purchase, store, and use at farms.

1 is a photograph showing experimental results of observing fertilization results of apples using a fertilization accelerator according to an embodiment of the present invention.
Figure 2 is a photograph showing the experimental results of observing the number of seeds in the apple non-waiting form and genus using a fertilization promoter according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice the present invention. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the embodiments of the present invention can be modified in many different forms, and the scope of the present invention is not limited to the embodiments described below.

Throughout the specification of the present invention, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

The terms "about," "substantially," and the like used throughout the specification of the present invention are used at or close to that value when manufacturing and material tolerances inherent in the stated meaning are given, and the present invention Accurate or absolute figures are used to prevent unfair use by unscrupulous infringers of the disclosed disclosures mentioned for the sake of understanding.

A fertilization promoter for promoting fertilization of a self-incompatible fruit tree according to an embodiment of the present invention will be described in detail. A fertilization promoter (hereinafter, also referred to as a 'fertilization promoter') for promoting fertilization of self-incompatible fruit trees according to an embodiment of the present invention can be more clearly understood by the description and examples to be described later.

The present invention relates to a fertilization promoter for promoting fertilization of self-incompatible fruit trees, characterized in that it is composed of zinc gluconate, vitamin B1, vitamin B6, boric acid and water.

That is, the fertilization promoter of the present invention is a mixture of zinc gluconate, a component that helps induce self fertilization by inhibiting the activity of S-RNase, and vitamins B1, vitamin B6, and boric acid, which are components that help promote the growth of plant cells. It is characterized by being formed.

In particular, gluconate acid of zinc gluconate exhibits a functional chelating effect and has an advantage of easy absorption due to a wider pH range than general EDTA raw materials, and has an advantage of good absorption even when using various waters. In addition, gluconic acid is a naturally occurring substance such as fruit and honey, and is environmentally friendly to plants, and helps to increase the effect by increasing the absorption rate of other components. In addition, zinc gluconate at a specific concentration is effective in inhibiting the activity of S-RNase, a pistil-specific gene, and plays a pivotal role in breaking (stopping) self-incompatibility.

According to one embodiment of the present invention, the fertility enhancer includes 0.05 to 10% by weight of zinc gluconate, 0.01 to 2% by weight of vitamin B1, 0.01 to 2% by weight of vitamin B6, 0.01 to 1% by weight of boric acid, and 85 to 99% by weight of water. It is characterized in that the composition is mixed in a ratio of %.

The fertilization promoter of the present invention is characterized in that it contains a zinc gluconate component, which inhibits the activity of S-RNase, a pistil-specific gene, to overcome the self-incompatibility of self-incompatible fruit trees. This is because it can induce spontaneous fertilization by inducing fertilization. Zinc gluconate is preferably mixed in an amount of 0.05 to 10% by weight based on the total weight of the fertilization accelerator. This is because there is a concern that the fertilization promoting effect of fruit trees may be insufficient because the absorption rate of other components is not inhibited and the absorption rate of other components is not increased. This is because the content of zinc gluconate is too excessive when considering the weight of the components of the composition, so the effect of promoting fertilization of fruit trees is excellent, but the growth efficiency of plants may be reduced.

The fertilization promoter of the present invention is characterized in that it contains vitamin B1, which is helpful in promoting shoot formation when vitamin B1, which is a vitamin synthesized in plant leaves, is added in a low dose, and is effective in enhancing disease resistance of plants. because there is It is preferable to mix vitamin B1 in an amount of 0.01 to 2% by weight based on the total weight of the fertilization promoter. This is because resistance may not be improved, and if vitamin B1 is composed at a ratio exceeding 2% by weight, a high amount of vitamin B1 is added, causing problems in the growth efficiency of plants or other substances included in fertilization promoters. This is because it may affect the content of the component, which may cause a problem that the fertilization of self-incompatible fruit trees is not effectively promoted.

The fertilization promoter of the present invention is characterized in that it contains a vitamin B6 component, because vitamin B6 helps to promote the growth and increase the germination rate of plant cells and plays an important role in amino acid metabolism. It is preferable that vitamin B6 is mixed in an amount of 0.01 to 2% by weight based on the total weight of the fertilization promoter. When the amount of vitamin B6 is less than 0.01% by weight, the growth of plant cells is relatively not promoted. This is because the growth efficiency of plants may be reduced because the germination rate is not increased, and the content of other ingredients included in the fertilization promoter may be affected when vitamin B6 is composed in a ratio exceeding 2% by weight. This is because there may be a problem in that fertilization of self-incompatible fruit trees is not effectively promoted.

The fertilization promoter of the present invention is characterized in that a boric acid component is included, which is because when fertilizing boric acid in a certain ratio to plants in early spring, not only the fertilization ability of flowers is improved, but also helps to suppress deformities and development. It is preferable that boric acid is mixed in an amount of 0.01 to 1% by weight based on the total weight of the fertility accelerator, which means that when boric acid is composed in an amount of less than 0.01% by weight, the fertility of flowers is relatively lowered, and deformities and incidence rates are reduced. This is because the problem of deteriorating the quality of fruit may occur due to the increase in boric acid, and when boric acid is composed at a ratio exceeding 1% by weight, it may affect the content of other components included in the fertilization promoter, resulting in self-incompatible fruit trees. This is because a problem in which fertilization is not effectively promoted may occur.

Therefore, the fertilization accelerator of the present invention has the advantage of not only promoting fertilization of self-incompatible fruit trees through a complex action of zinc gluconate, vitamin B1, vitamin B6, and boric acid components, but also helping plants themselves grow.

The fertilization accelerator of the present invention provides a stock solution fertilization accelerator in the form of a stabilized liquid, but is characterized in that it is used after diluting with water when spraying on the plant surface. This is to facilitate the storage of the fertilization promoter in the farmhouse, to maintain the stability of the fertilization promoter uniformly to prevent quality deterioration, and to dilute and use immediately when necessary.

That is, the fertility enhancer of the present invention is provided in the form of a stabilized liquid formulation in which zinc gluconate, vitamin B1, vitamin B6, boric acid and water are mixed in an appropriate ratio, but when used, the fertility enhancer is diluted with water so that it can be used immediately, There is an advantage of easy storage of the fertilization promoter, and an advantage of preventing quality degradation by storing the fertilization promoter in a stabilized liquid form.

According to one embodiment of the present invention, the fertilization promoter is characterized in that it is used by diluting with water at a ratio of 900 to 1100 times when spraying on the flower surface of fruit trees. This is because when the fertilization promoter is diluted with water at a ratio of less than 900 times, the fertilization rate of self-incompatible fruit trees is no longer improved, whereas a relatively large amount of the fertilization promoter is used, resulting in improved productivity and economy. This is because the problem of reduction may occur, and when diluted at a rate exceeding 1100 times, the amount of fertilization accelerator is significantly reduced, resulting in a problem that cannot effectively promote fertilization of self-incompatible fruit trees. Because.

Hereinafter, fertilization promoters for promoting fertilization of self-incompatible fruit trees of the present invention will be described in detail with examples so that those skilled in the art can easily practice them. A fertilization promoter for promoting fertilization of a self-incompatible fruit tree according to an embodiment of the present invention can be more clearly understood by referring to the following examples. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Manufacture of Fertility Accelerator

A fertility accelerator was prepared by dispersing a mixture of zinc gluconate, vitamin B1, vitamin B6, boric acid and water, and the mixed composition ratio of each component is as shown in Table 1 below.

fertility enhancer (unit: % by weight) zinc gluconate Zinc gluconate 2 vitamin B1 Thiamine HCl 0.2 vitamin B6 Pyridoxine 0.2 boric acid boric acid 0.09 water - 97.51 Sum 100

Observation experiment on fertilization promoting effect of apple using fertility accelerator

An experiment is conducted to observe the effect of accelerating fertilization of apples using the fertility enhancer according to an embodiment of the present invention.

The fertilization promoter is prepared by setting the mixed composition ratio of zinc gluconate in various ways, and then A treatment, B treatment, C treatment, D treatment, E treatment, and non-treatment are set according to the type of fertilization promoter, Observe the fertilization-accelerating effect of fruit trees. That is, the fertilization promoting effect of fruit trees according to the mixed composition ratio of zinc gluconate mixed in the fertilization accelerator was observed.

[Preparation of fertilization promoter for each treatment group]

Fertilization promoters used in A treatment, B treatment, C treatment, D treatment, and E treatment were prepared in the same manner as the fertilization promoter of Example 1, but the mixed composition ratio of zinc gluconate was changed to the conditions of Table 2 below. did

(unit: % by weight) zinc gluconate Treatment A 13 B treatment area 10 C treatment area 2 D treatment area 0.05 E treatment area 0.025 untreated X

In treatment group A, the fertilization accelerator prepared after setting conditions so that the mixed composition ratio of zinc gluconate mixed in the fertilization accelerator is higher than the mixed composition ratio defined in the present invention is used. That is, the fertilization accelerator used in treatment A is mixed so that zinc gluconate is higher than the mixed composition ratio defined in the present invention during manufacture, but vitamin B1, vitamin B6, boric acid and water are values suitable for the mixed composition ratio defined in the present invention It is formed by mixing so that it becomes.

A fertilization accelerator prepared according to an embodiment of the present invention is used in B treatment, C treatment, and D treatment, and the mixed composition ratio of zinc gluconate mixed in the fertilization promoter is adjusted to the mixed composition ratio defined in the present invention. After setting, the prepared fertilization promoter is used. That is, the fertilization accelerator used in the B treatment, C treatment, and D treatment is mixed with all ingredients (vitamin B1, vitamin B6, and boric acid) including zinc gluconate and water to a value suitable for the mixing composition ratio limited in the present invention. is formed

In the E treatment group, the fertilization accelerator prepared after setting conditions so that the mixed composition ratio of zinc gluconate mixed in the fertilization accelerator is lower than the mixed composition ratio defined in the present invention is used. That is, the fertilization accelerator used in the E treatment group is mixed so that zinc gluconate is lower than the mixed composition ratio defined in the present invention during manufacture, but vitamin B1, vitamin B6, boric acid and water are values suitable for the mixed composition ratio defined in the present invention It is formed by mixing so that it becomes.

Fertilization promoters are not separately used in the untreated area.

[Methods and results of observation of fertility promoting effects for each treatment group]

In order to observe the effect of promoting fertilization of apples grown in Gajo-myeon, Geochang-gun, Gyeongsangnam-do, an experiment was conducted with 4 apple trees with uniform tree shapes. The fertilization promoter was sprayed first when flowering was 80%, and sprayed secondly at full bloom, a total of two times. When the fertilization promoter was sprayed on the surface of apple flowers, it was diluted with water at a rate of 1000 times, and the fertilization promoter was sprayed on the apple flowers to the extent that the fertilization promoter did not flow.

The fertility promotion effect of apples using the fertility enhancer was observed by randomly collecting 15 side fruits per tree and checking the inside after cutting them.

The results of an experiment to observe the fertilization promoting effect of apples according to the mixed composition ratio of zinc gluconate mixed in the fertility accelerator are shown in Table 3 below, and the fertilization results of apples are shown in the photograph of FIG. The number of seeds in the genus is shown in the photograph of FIG. 2 below.

Seed number (average value) Correction and Number (Fault) regular penalty rate Treatment A 8.7 120/150 80.0% B treatment area 8.8 121/150 80.7% C treatment area 9.4 127/150 84.7% D treatment area 8.5 115/150 76.7% E treatment area 7.2 98/150 65.3% untreated 6.5 83/150 55.3%

As a result of using the fertilization promoter for apples, which are self-incompatible varieties, it was confirmed that a large number of flowers increased in the number of seeds after fertilization when the fertilization promoter of the present invention was treated compared to the untreated control. In addition, it was confirmed that the production rate of atypical fruit occurred more in the non-treated group compared to the treated group at the time of entering the non-atmospheric stage, and the related effect of the regular fruit rate was higher in the treated group.

It was observed that the number of seeds and the number of shaped fruits were relatively very small compared to the treated group in the non-treated group in which the fertilization promoter of the present invention was not used, and the shaped fruit rate was only about 55%. In addition, even in the E treatment zone using the fertilization promoter prepared after setting the conditions so that the mixed composition ratio of zinc gluconate mixed in the fertilization promoter is lower than the mixed composition ratio limited in the present invention, the form yield is only about 65% confirmed to be

On the other hand, in the B treatment, C treatment, and D treatment using the fertilization promoter prepared after setting the conditions so that the mixed composition ratio of zinc gluconate mixed in the fertilization promoter is suitable for the mixed composition ratio defined in the present invention, the number of seeds and The number of standard fruits was high, and the rate of standard fruits was over 76%, confirming that fertilization of fruit trees was effectively promoted.

In addition, the number of seeds and the number of shaped fruits are also high in A treatment group using the fertilization promoter prepared after setting conditions so that the mixed composition ratio of zinc gluconate mixed in the fertilization promoter is higher than the mixed composition ratio limited in the present invention, It was also confirmed that fertilization of fruit trees was effectively promoted with a normal fruit rate of about 80% or more. It was confirmed that the fertilization promotion effect of fruit trees was much better than that of the B treatment, C treatment, and D treatment, rather than showing similar results. That is, the higher the content of zinc gluconate contained in the fertilization promoter, the more fertilization of fruit trees is promoted and the number of seeds does not increase further.

Therefore, when the fertilization promoter prepared after setting the conditions so that the mixed composition ratio of zinc gluconate mixed in the fertilization promoter is suitable for the mixed composition ratio defined in the present invention, the number of apple seeds, the number of shaped fruits, and the shaped fruit rate It was confirmed that fertilization of self-incompatible fruit trees was effectively promoted.

In conclusion, through experiments observing the fertility promoting effect of fruit trees (apples) using the preparation of the fertilization promoter of Example 1 and the fertility promoter of Example 2, the fertilization promoter according to one embodiment of the present invention contains zinc gluconate, vitamins It is prepared by mixing B1, vitamin B6, and boric acid with water in a wet dispersion method, and contains zinc gluconate, which is effective in inhibiting the activity of S-RNase, a pistil-specific gene, to break the self-incompatibility of self-incompatible fruit trees. Since it can induce self fertilization, it has the advantage of promoting natural fertilization, and it has the advantage of producing high-quality fruits such as regular fruits and large fruits by increasing the number of seeds during fertilization while minimizing the help of insect vectors. Zinc gluconate, vitamin B1, vitamin B6, and boric acid contained in the fertilization accelerator not only promote fertilization of fruit trees but also help the growth of the plant itself, resulting in fruit of excellent quality. It was confirmed that there are advantages.

Above, the present invention has been described in detail with examples, but the present invention is not limited to the above embodiments, and can be modified in various forms, and conventional knowledge in the art within the technical spirit of the present invention It is clear that many variations are possible by those who have it. In addition, various forms of substitution, modification and change will be possible by those skilled in the art within the scope of the technical spirit of the present invention described in the claims, which also falls within the scope of the present invention. something to do.

Claims (3)

A fertilization promoter for promoting fertilization of self-incompatible fruit trees, characterized in that it is composed of zinc gluconate, vitamin B1, vitamin B6, boric acid and water. The method of claim 1,
The fertilization accelerator,
0.05 to 10% by weight of zinc gluconate, 0.01 to 2% by weight of vitamin B1, 0.01 to 2% by weight of vitamin B6, 0.01 to 1% by weight of boric acid, and 85 to 99% by weight of water A fertilization promoter for promoting fertilization of incompatible fruit trees. According to any one of claims 1 or 2,
The fertilization accelerator,
A fertilization promoter for promoting fertilization of self-incompatible fruit trees, characterized in that it is used by diluting with water at a rate of 900 to 1100 times when spraying on the flower surface of fruit trees.

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