KR20150057056A - Composition containing rhizobacterium for rice sheath blight inhibition - Google Patents

Abstract

The present invention of Pseudomonas putida 17S has an effect to inhibit rice sheath blight caused by Rhizoctonia solani pathogen. Therefore, a composition for inhibiting rice sheath blight, which contains Pseudomonas putida 17S, a cultural filtrate thereof, or a mixture of Pseudomonas putida 17S and the cultural filtrate as effective ingredients can be used as a composition for inhibiting rice sheath blight causing the degradation of rice and the decrease in crop yield.

Description

{Composition containing rhizobacterium for rice sheath blight inhibition containing rice microorganism microorganism}

Rhizosphere microorganism Pseudomonas Pew peptidase 17S (Pseudomonas putida 17S) on rice sheath blight.

Rice is the most important food crop in developing countries, and its yield is continuously affected by various pathogens such as blight of blight, blight, sheath blight, and viral disease (Dai LY et al . 2007). Among them, rice sheath blight caused by Rhizoctonia solani is an important problem because it occurs in the rice growing area of the world and causes damage. Sheath blight disease is increasingly affected by increasing the humidity of the plant communities due to the cultivation of the multi - cultivated varieties with many tillage and tillering of machine transplant. Initially the spot is elliptical or ovate, slightly irregular, with circular or dark gray circular or irregular rounded spots, gradually becoming grayish white, marginally brownish, with brown sclerotia. In packaging, the lesions are generally observed near the surface of the water, and if conditions are favorable, they also spread to the upper sheaths or leaves. Damage caused by sheath blight was mainly caused by a decrease in compost deficiency and a decrease in the number of ginseng. In general, 40 ~ 50% of leaf and leaf sheath were affected by nitrogen and 15 ~ 20%

The life history of sheath blight pathogen is comparatively simple and can be wintered in the soil as sclerotia or mycelium. Sclerotia in dry soil can maintain their vitality for 21 months and survive for 130 days in room temperature soil. On the surface of the rice, winter sclerotium is floated on the water by the harrow before the rice planting. After the rice planting, it starts to germinate on the leaf sheath of rice and forms a lesion on the sheath in late June or early July. After the middle of July, sclerotia are formed. These sclerotia are matured and attached to the sheath. When rice abandonment is rusted by agriculture work or wind, they are sent to the bottom of rice field by physical force. There is a close relationship between the density of winter sclerotia and the occurrence of early disease. There are hundreds of thousands of sclerotia in 300 pyeong rice fields. The pathogen is Rizoctonia solani (the full generation is Thanatephorus cucumeris ), but they act in the form of hyphae or sclerotia. Sclerotium begins to form as a firm mass of mycelia, and its size is maximized after 30 hours. Its color is initially white, but it starts to browse later and becomes completely brown after 40 hours. The mature sclerotium does not float even if it falls into water. After 30 hours, contents of outer sclerotial cells of sclerotia begin to disappear. At 15 days, only a few cells in the central part are left, leaving only a cell wall. . However, since there are few resistant cultivars against sheath blight disease to date, it is mainly dependent on the poisoning control and drug control. It is effective in suppressing the early onset by reducing the primary infectious source. In addition, there is a way to avoid excessive overuse of the nitrogen fertilizer and the smell, and when the transplanting period is slowed or the breeding of the middle breed is cultivated, the temperature becomes low in the latter stage of growth and the onset of the disease is stagnated. The control period of the sheath blight disease is characterized by an increase in the incidence of sheath blight disease in the period from late June to early July, and the period when the onset rate is about 20% . It is important to pay attention to the weather and sickness outbreak information of the year and to observe the site well so that the control is completed before going out.

Although most of the developed countries have relied solely on chemical pesticides for the past 50 years, conservation and conservation are now more important than the economic benefits of agricultural products. Trying hard. In the case of foreign countries, actinomycetes were first used in the United States in 1927 for the control of potato scab disease, and they began to be put into practical use in the form of pesticides since 1960. In Japan, in 1962, Trichoderma live- Many products were developed in the United States and most of the commercialized products were developed for the control of dressing diseases that occur during seedling. The most important success products of pesticide for pest control include Galltrol, Dygall, Nogall, and Bakuterozu using Agrobacterium radiator strain 84 and K1026 strain, which are antagonistic microorganisms, to the root gall bladder (Crown gall) There are products. Although the present organic synthetic pesticides are not effective for all bacterial diseases, the microbial pesticides are used as excellent antiseptic agents. In Korea, basic studies have been carried out in the 1980s, when microorganisms themselves or microorganisms produce bioactive substances in Korea, which are 30 to 50 years late compared to foreign countries. There are no products that have been put into practical use due to the non-existent situation. Since 1985, pathologists of national research institutes and universities have been studying for the control of diseases by using microorganisms themselves, including mosaic diseases of tobacco (TMV), bacterial wilt, cucumber wilt (Fusarium wilt) Studies on Phytophthora blight, wilt of strawberry, Rhizoctonia bud rot, damping-off of beet, rice blast, control of sheath blight disease are under way. In recent years, there have been anthrax, spotting, wilt, gray mold, powdery mildew, and blight of rice blast, sheath blight, and eisak blight in the cultivation of plants.

Therefore, in the present invention, Pseudomonas The pre-treatment of putida 17S strain confirmed the control effect of sheath blight in rice. Therefore, it is expected that it will contribute to the stable rice production by solving the problems of quality deterioration and reduction of yield due to increase of incidence of rice sheath blight disease.

It is an object of the present invention to provide a Pseudomonas sp. putida 17S), a cultured filtrate thereof, or a mixture thereof as an active ingredient.

It is another object of the present invention to provide a method for preventing sheath blight.

In order to achieve the above object, the present invention provides a composition for preventing sheath blight of Pseudomonas putida 17S ( Pseudomonas putida 17S), a cultured filtrate thereof or a mixture thereof as an active ingredient.

In addition, the present invention provides a method for preventing sheath blight.

The Pseudomonas sp. & Lt; RTI ID = 0.0 > 17S & putida 17S) was pretreated with Rhizoctonia solani ), the development of rice sheath blight is remarkably reduced, so that it can be usefully used as a composition for preventing rice sheath blight caused by rice quality deterioration and reduction in yield.

1 is a Pseudomonas 17S Pew peptidase (Pseudomonas Putida 17S) This is a chart measuring the length of sheath blight lesion in Dong Jinbin according to pretreatment concentration.
FIG. 2 is a graph showing the activity of Pseudomonas < RTI ID = 0.0 > putida 17S) Pretreatment by Rhizoctonia solani ) strain of the present invention.
Figure 3 is a graph showing the activity of Pseudomonas < RTI ID = 0.0 > putida 17S), the control effect of rice seedlings (rice sheath blight caused by rice sheath blight) was examined.

Hereinafter, the present invention will be described in detail.

The present invention relates to Pseudomonas sp. putida 17S), a cultured filtrate thereof, or a mixture thereof as an active ingredient.

The sheath blight is caused by Rhizoctonia solani ), and it is preferred that the Rhizoctonia solani solani ) are preferably Rs40104, Rs40105 and Rs45811, but are not limited thereto.

The culture filtrate contained the Pseudomonas sp. putida 17S) strain, which can be obtained by centrifugation or filtration.

The composition of the present invention may include surfactants, plant nutrients, preservatives, biological supplements, surfactants, inorganic salts, adjuvants, binders and extenders commonly used in the art. In addition, the composition of the present invention may include materials capable of improving storability, such as peat moss, zeolite, talc and kaolinite, clay, and the like. The composition of the present invention may be formulated into various preparations such as powders, pellets, granules, and solutions.

The compositions of the present invention Pseudomonas Pew peptidase 17S (Pseudomonas putida 17S) strain can be applied to all plants that can be caused or caused by infection with an antagonistic pathogen. The composition of the present invention can be effectively sprayed on various sites such as seeds, stems, and leaves of plants, or can be effectively treated with plant pathogens by treating the soil with plants grown thereon. In addition, the composition of the present invention may be applied not only to cultivated plants but also to plants such as vegetables, fruits, flowers, etc., which are stored and distributed after harvesting, to control pathogens.

In addition, the present invention provides a method for controlling a sheath blight of a sheep blight comprising the step of pre-treating a plant with a composition for controlling sheath blight blight.

The plant is preferably rice, but is not limited thereto.

The present invention can be more specifically understood by the following examples, and the following examples are intended to illustrate the present invention and are not intended to limit the scope of protection of the present invention.

< Example  1> Identification of rhizome sheath blight control of rice microorganism

4 weeks of rice Dongjin in the greenhouse for daylight conditions Yoshida culture conditions _{(NH 4 NO 3, 1.43 mM} ; NaH 2 PO 4 · 2H 2 O 0.37 mM; K 2 SO 4 0.51 mM; CaCl 2 1 mM; MgSO 4 · 7H 2 O 1.6 mM; Iron chelate 0.5 mM ; Micronutrient solution 1ml) was grown in Pseudomonas putida 17S (Pseudomonas putida Strain 17 isolated from replant soil promotes tomato growth and inhibits conidial germination of soilborne plant pathogens plant Pathol.J 21 (3..) : 244-251 (2005) ) at a concentration of 10 ⁸ ml ^-1 , 10 ⁶ ml ^-1 , 10 ⁴ ml ^-1 or 10 ² ml ^-1 , And treated with 10 mM MgCl ₂ as a control. Specifically, Pseudomonas stored in a cryogenic freezer After inoculation the 17S putida in trypic soy agar (TSA, Difco) for 60 hours and cultured in dark conditions at 28 ℃. The cells were harvested by pouring 10 mM MgCl ₂ and titrated with 10 ⁸ ml ^-1 , 10 ⁶ ml ^-1 , 10 ⁴ ml ^-1 and 10 ² ml ^-1 in the nutrient solution. One week after the appropriate bacteria were pretreated, two solid culture media (6 mm in diameter) of Rhizoctonia solani (Rs40104), a sheath-fungus pathogenic bacterium, a friendly relationship to Dongjinbyeong, Lt; / RTI &gt; The disease progression patterns were compared 14 days after the inoculation. More than 10 plants were used in all treatments.

As a result, the amount of rice sheath blight development was inhibited according to the concentration of the rhizosphere inoculation based on the upper limit of development of the disease from the inoculation part, and the control effect was the largest at the concentration of 10 ⁶ ml ^-1 (FIG. 1).

< Example  2> Rice microorganism rice In the case of herbaceous blight-resistant strains  Check control effect

Pseudomonas strains of the herbivorous pathogenic fungus strains other than Rs40104 The control effect of putida 17S was confirmed. Specifically, the results of the above <Example 1> showed that the inoculation concentration of 10 ⁶ ml ^-1, which was the most effective for controlling the Rhizoctonia evaluate the control effect of the solani strain Rs40104, Rs40105 and Rs45811.

As a result, a delayed disease progression was observed with respect to the strains Rs40104, Rs40105 and Rs45811 as compared with the control (Fig. 2).

< Example  3> Rice cultivars treated with rhizosphere microorganisms Sheath blight pathogen  Check control effect

Pseudomonas Putida 17S was pretreated with 10 ⁶ ml ^-1 and then inoculated with 1, 3, 5, 7, or 9 weeks of sheath blight pathogen strain 40104 or distilled water (control group) Respectively.

As a result, Pseudomonas The control effect of putida 17S treatment on the rice sheath blight pathogen persisted for up to 5 weeks after rhizosphere pretreatment, and it was found that the continuous control effect was effective during the entire pre-ripening period (FIG. 3).

Claims (5)

Pseudomonas Pew peptidase 17S (Pseudomonas putida 17S), a cultured filtrate thereof, or a mixture thereof as an active ingredient.
[3] The composition according to claim 1, wherein the sheath blight is caused by Rhizoctonia solani .
3. The method of claim 2, wherein the Rhizoctonia solani ) is a strain of Rs40104, Rs40105 and Rs45811.
A method for preventing sheath blight of a sheep blight comprising the step of pre-treating the plant with a composition for controlling sheath blight blight of claim 1.
The method for controlling sheath blight disease according to claim 4, wherein the plant is rice.

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