KR20130096886A - Novel lactococcus lactis subsp. lactis lks49 comprising solubility upon insoluble salts and antifungal activity - Google Patents

Abstract

PURPOSE: Lactococcus lactis subsp. Lactis LKS49 is provided to make insoluble phosphate salts in soil into soluble phosphate ions, soluble magnesium, and calcium ions and to suppress the growth of plant pathogenic fungi. CONSTITUTION: Novel strain Lactococcus lactis subsp. Lactis LKS49 (deposit number KTCT 12087BP) has insoluble salt-solubilizing activity and antifungal activity. A method for promoting the growth of crops and improving soil comprises the step of inoculating the strain into crops or soil and solubilizing the insoluble salts in soil. A method for preparing biocalcium, biophosphate, and biomagnesium comprises the step of inoculating the strains into waste biological resource (oyster shell, bone, sea foods, and fish byproducts). The strain is used for manufacturing nutritional supplements, feed, fertilizer, and cosmetic materials. [Reference numerals] (1) Tribasic magnesium phosphate (Mg_3(PO_4)_2); (2) Oystershell; (3) Tribasic calcium phosphate (Ca_3(PO_4)_2)

Description

Novel Lactococcus lactis subsp. 49 strains having insoluble salt solubilizing activity and antifungal activity. lactis LKS49 comprising solubility upon insoluble salts and antifungal activity.}

The present invention is a novel strain of Lactococcus lactis to solubilize insoluble phosphate (Lactococcus lactis subsp . lactis ) LKS49 and the treatment of the strains on crops and crop cultivated soils to solubilize insoluble phosphates and to inhibit the growth of phytopathogenic fungi.

-Insoluble phosphate solubilizing strain

Phosphorus is a very important essential nutrient for plant growth and development. It is a macronutrient that requires a large supply. For maximum crop yield, the availability of phosphorus available to plants is a very important condition. Plant growing soils contain between 400 and 1200 mg / kg of phosphorus (Rodriguez and Fraga, biotech. Adv. 1999, 17: 319-339).

However, most of the phosphorus in the soil is insoluble, so plants cannot use it. In other words, phosphorus in the soil is present in the form of chemically tightly bound insoluble complexes or organically bound phytates and insoluble phosphates that cannot be used by plants (Paul and Clark, Soil Microbiology and Biochemistry). , Academic Press, San Diego, CA, 1996).

Thus, available phosphorus in natural soils is present in less than the concentration of micronurtients. After all, the concentration of soluble phosphorus is a limiting factor in the promotion of plant growth and development in the soil. Moreover, the supply of inorganic phosphate fertilizers with soluble phosphorus to the soil changes more than 75% of them very quickly to insoluble phosphates, allowing plants to use less than 25% of the soluble phosphorus supplied (Goldstein, Am. J. Altern). Agric. 1986, 1: 51-57).

Therefore, farmers continue to repeat the excessive fertilization of excessive supply of inorganic phosphate fertilizers to the farmland in order to prevent the deterioration of plant growth and development due to the lack of soluble phosphorus. However, most of the soluble phosphorus supplied by this excessive fertilization is changed from farmland to large insoluble phosphate, which accumulates and eventually becomes salty soils in which plant growth and development are not normally performed.

Moreover, these salt barrier soils occur more frequently in facility cultivation producing high value-added crops, which is a great problem for agricultural productivity and agricultural economy.

Fortunately, it is known that there are microorganisms in the soil that convert these insoluble phosphates into solubilized state. These microorganisms that solubilize these insoluble phosphates (PSBs) are a type of symbiosis that allows the plant to absorb and use soil by converting insoluble phosphates in the soil into solubilized phosphorus by releasing organic acids or secreting specific enzymes in the plant's root zone. It is assumed that the relationship is maintained (Goldstein, Am. J. Altern. Agric. 1986, 1: 51-57).

PSB microorganism Pseudomonas (Pseudomonas), Bacillus (Bacillus), rayijo Away (Rhizobium), Burkholderia (Burkholderia), Agrobacterium (Agrobacterium), micro Cocos (Microccocus), Aero bakteo (Aerobacter), Flavobacterium ( Flavobacterium ) and only a few species belonging to Erwinia .

Examination of these insoluble phosphate solubilization spectra showed overall low activity when only soluble to a specific insoluble phosphate or its broad solubility (lllmer and Schinner, Soil Biol. Biochem., 1992, 24: 389-395; Rodriguez et al., Rev. ICIDCA, 1996, 30: 47-54; Arora and Gaur, Indian J. Exp. Biol., 1979, 17: 1258-1261; Halder and Chakrabartty, Folia Microbiol., 1993, 38: 325 -330).

PSB microorganisms are present in the soil but are not always high enough to compete with other microorganisms that form the plant root zone. Thus, the amount of soluble phosphorus produced by PSB microorganisms in the soil by breaking down insoluble phosphates is not high enough to increase plant growth and development. Therefore, artificially inoculating large amounts of PSB microorganisms into the soil has the potential to increase plant growth and development.

This research has been reported to improve the plant growth using insoluble phosphate solubilizing microorganisms (Kloepper et al., ISI Atlas Sci. Anim. Plant Sci., 1988, pp. 60-64; Chabot et. al., Appl. Environ.Microbiol., 1996, 62: 2767-2772).

Efforts to discover new insoluble phosphate solubilizing microorganisms (PSBs) in addition to known insoluble phosphate solubilizing microorganisms have been reported to allow Rahnella aquatilis to solubilize hydroxyapatite ( Kim et al., FEMS Microbiol. Lett., 1997, 153: 273-277), a related gene, pqq, has also been identified (Kim et al., FEMS Microbiol. Lett., 1998, 159: 121-127). .

Kim et al. Also confirmed that Enterobacter agglomerans can also produce soluble phosphorus by decomposing hydroxyapatite. (Kim et., Soil Biol. Biochem., 1998, 30 : 995-1003).

Meanwhile, Korean Laid-Open Patent Publication No. 2002-0017516 (a new microorganism that solubilizes phosphate immobilized on volcanic ash soil) discloses about Bacillus sparycus PBS-13 solubilizing phosphate immobilized on volcanic ash soil. However, there is still a need to develop new strains that solubilize insoluble phosphate in crop cultivated soils.

Antifungal against phytopathogenic fungi

  Microbial pesticide is a product of a microorganism isolated from nature or modified for use, or a compound secreted by a microorganism, in order to control pests, weeds and pathogenic microorganisms of a crop.

  An essential element in the development of microbial pesticides is to select or modify useful microorganisms having excellent antagonism, and to mass produce the selected microorganisms or drugs secreted by the microorganisms and to efficiently deliver them to the crops for use.

Recently, research and development of microbial pesticides using microorganisms has been actively conducted. Korean patent application 1990-0017551 (a new Bacillus subtilis subspecies and the use of the antifungal substance KRF-001 complex produced therefrom), Bacillus subtilis subspecies cryptiensis (producing antifungal oligopeptide-based substances) subtilis subsp . krictiensis ), but the antifungal activity spectrum has a narrow problem.

  In Korean patent application 1993-0022037 (Method for producing microbial insecticide using bioencapsulation), a natural gel matrix rich in water is mixed with water to prepare a protein-rich natural gel matrix, and after autoclaving, Bacillus terringiensis spores are mixed. Thereafter, there is a method of preparing a bioencapsulated microbial insecticide by drying, but has a narrow antifungal activity spectrum and a complicated composition and composition of the biomatrix.

  Korean Patent Application No. 1998-027468 (Improved Coating Pesticide Matrix, Preparation Method and Composition Containing It) relates to a coated pesticide matrix comprising a pesticide, a polymer, a plasticizer, a sun protection agent, an activity enhancer, and a lubricant. It is known, but the antifungal activity spectrum is narrow and the effect is limited.

The recent rapid increase in facility cultivation area has resulted in overaccumulation of salts and nutrients due to the lack of awareness of the farming environment of farmers, resulting in impediment to crop growth, such as imbalance of essential nutrients in soil, water absorption of crops, and salt concentration disturbance. It is emerging as an important problem of facility cultivation. Inorganic salts are an important factor in the growth of crops. The crop absorbs the required amount of salt and does not absorb the rest, so if the microbes do not consume or increase their absorbency, the salt will continue to accumulate and the plant will not survive.

In addition, as the Green Round Convention on Environmental Protection and Ecosystem Conservation becomes the subject of international concern, the abuse of excessive pesticides, etc. becomes a serious problem, and the development of biocide for plant control to replace them It is emerging as a key field of competition. In order to overcome the environmental pollution problem caused by conventional pesticides, it is very urgent to select antagonistic microorganisms that are easy to produce, store and apply and effectively suppress pathogens and to develop biologically active substances. In particular, antifungal active microorganisms and substances are less toxic to mammals than conventional pesticides, no harm to plants, excellent in activity and less residual, and do not affect rotation, and should not contaminate groundwater, soil and river water.

An object of the present invention is a novel Lactococcus lactis (Lactococcus having a function of solubilizing water-insoluble active salt (PS ⁺⁾ and antifungal activity (AF ⁺⁾ lactis subsp . lactis ) LKS49 and its treatment to crop and crop cultivated soil to provide new strains for solubilizing insoluble phosphate in crop cultivated soils and inhibiting growth of phytopathogenic fungi.

Lactococcus Lactococcus Soluble Insoluble Phosphate in Soil by the Present Invention lactis subsp . lactis ) strain LKS49 is provided. This strain is treated on crops and crop cultivated soils to solubilize insoluble phosphates (3-magnesium phosphate, tricalcium phosphate, calcite, hydroxyapatite, phosphate, phytate, etc.), as well as inhibit the growth of phytopathogenic fungi. Promote.

Brief Description of the Drawings Figure 1 is a graphical representation of the Lactococcus lactis lactis subsp . lactis ) Photos showing the insoluble phosphate solubility of LKS49
Solubilization ability to 1: 3 magnesium phosphate (Mg ₃ (PO ₄ ) ₂ ), solubilization ability to 2: 3 calcium phosphate (Ca ₃ (PO ₄ ) ₂ ,
FIG. 2 is a photograph of the Lactococcus lactis of the present invention lactis subsp . lactis ) Antifungal activity of LKS49
Figure 3 is Lactococcus Lactococcus of the present invention lactis subsp . lactis ) Figure showing the phylogenetic root of LKS49
Figure 4 is Lactococcus Lactococcus lactis subsp . lactis ) A graph showing the change in electrical conductivity after inoculating LKS49 in salt-impacted soil
Figure 5 is Lactococcus Lactococcus lactis subsp . lactis ) Graph showing changes in phosphate (Pi) ion concentration after saline challenge of LKS49
Figure 6 Lactococcus Lactococcus when insoluble phosphate feed to the phosphate source lactis subsp . lactis ) Graph showing changes in LKS49 growth curve (●-●) and phosphoric acid concentration (■-■)
Figure 7 Lactococcus Lactococcus lactis subsp . lactis ) Plant growth-promoting effect of LKS49 treated with impaired soil
A: lettuce, B: cabbage, C: pepper 1: control, 2: LKS2 experimental group
FIG. 8 is a growth promoting effect of the solubilized bacteria when mixed treatment (Bisella Kimchi LKS2, Bisella Corriensis LKS42, Lactococcus Lactis LKS49, Bacillus Ariaphatai LKS28)
A: lettuce, B: cabbage, C: pepper, 1: control, 2: mixed treatment (LKS2, LKS42, LKS49, LKS28) experimental group

In order to select a strain having high insoluble phosphate solubilizing ability, the present inventors have used a solid medium containing insoluble phosphates (3-magnesium phosphate, tricalcium phosphate, hydroxyapatite, phosphate or phytate), respectively, from microorganisms isolated from kimchi and soil. Strains with high solubility of insoluble phosphate were selected by analyzing the size of the clear ring of solid medium when inoculated into culture.

The homology of 16S ribosomal DNA obtained from the selected strains was compared and the biological properties were investigated . As a result , a novel strain of Lactococcus lactis subsp.lactis was found, which was then identified as Lactococcus lactis. subsp . lactis ) was named LKS49, and the strain was deposited with KCTC 12087BP on November 23, 2011, at the Korea Institute of Bioscience and Biotechnology, an international microbial deposit institution for patent applications.

Bisella Kimchi LKS2, Bisella Corriensis LKS42, and Bacillus Ariabhatai LKS28, which have been studied and developed by the inventors of the present invention, have similar functions of solubilizing insoluble phosphate in soil, but they are similar to DNA sequencing and phylogenetics. Investigating the recent years revealed that different genus and other species.

And Lactococcus lactis (Lactococcus lactis subsp. Lactis) LKS49 are gram-positive bacterium of the present invention, there is not a spore form, to form a colony of around 1.5mm in size Lactobacillus emal S (MRS) medium.

Lactococcus lactis according to the present invention (Lactococcus lactis subsp. Lactis) LKS49 is due to its high capability of solubilizing a wide range of water-insoluble phosphate can be useful in improving and plant growth promotion of soil salts disturbance.

The present invention is in the Lactococcus lactis (Lactococcus lactis subsp. Lactis) interference with the LKS49 provides a method for enhancing the growth of improvement and plants in the soil and plant pathogenic fungi, because of the anti-fungal activity against phytopathogenic fungi Provide a control method for

The method for improving impaired soil and enhancing plant growth by using the strain of the present invention comprises the first method of culturing Lactococcus lactis subsp.lactis LKS49 in tryptone-east (TYE) liquid medium or MRS medium . was inoculated with a step, (Lactococcus lactis subsp lactis.) the Lactococcus lactis culture LKS49 in saline soil disturbance consists of a second stage to promote the growth of plants.

Incubate for 1 to 2 days at 30 ~ 36 ℃ during the culture of the first step.

Keep washing the (Lactococcus lactis subsp lactis.) The Lactococcus lactis culture LKS49 with distilled water and isotonic solution of NaCl 0.8%.

Lactococcus lactis subsp.lactis ( Lactococcus lactis subsp . Lactis) LKS49 is inoculated twice a week at 1X10 ⁷ CFU / ml in saltwater soils, and then grown by germinating crops from the top soil.

After transplant the crop continues to Lactococcus lactis four weeks of the present invention further in one week intervals (Lactococcus lactis subsp . lactis ) inoculate LKS49.

Lactococcus of the present invention by the above method ( Lactococcus) lactis subsp . lactis ) LKS49 inoculation results in normal crop growth and development even in saline soils.

Lactococcus selected from the present invention ( Lactococcus) lactis subsp . lactis ) LKS49 was inoculated with a fungi-coated PDA (Difco Co.) medium using a paper disc (diameter 6 mm) and inoculated with a cell culture cultured in a nutrient medium and incubated for 2 to 3 days at 30 ° C. for phytopathogenic fungi. Antifungal activity was investigated. Lactococcus lactis subsp . lactis ) In order to investigate the antifungal activity spectrum of LKS49, the antifungal activity spectrum was again analyzed in many of the plant pathogenic fungi.

In the above pathogenic fungi are Mucor spp. Pyricularia oryzae (rice blast), Pythium ultimum (loose disease), Rhizoctonia solani (riceworm), Botryoshaeria dothidea (apple rot), Bipolaris sorokniana (Sesame Seeds ), Botrytis cinerea (ash fungus), Colletotrichum gloeosporioides (pepper anthrax), Pyricularia grisea (rice fever), Mycosphaerella melonis (watermelon vine blight), Phytophthora capsici ( fermenter ), Alternaria solani (tomato round disease), Fusarium Plant pathogenic fungi and Candida , including oxysporum (locopathy, root disease) or Sclerotinia sclerotiorum (mycobacterium disease) animal pathogenic fungi such as albicans (candidiasis) and the like.

Hereinafter, the present invention will be described in detail by way of examples, but the contents of the present invention are not limited thereto.

< Example  1> Selection of Strains

   In order to select strains from the soil, the soil collected in Korea was used as a microbial extraction source by filtering 2mm sieve.

   50 ml of 25% Ringer's solution was added to 5 g of wet soil, shaken for 2 minutes, and stirred for 1 hour.

The stirred soil sample was repeated three times for 5 minutes sonication was removed from the soil particles.

After centrifugation at 1,500 rpm for 10 minutes, the supernatant was used as a screening sample for insoluble phosphate solubilizing microorganisms.

For the selection of strains from Kimchi, the cells were cultured in MRS medium and tryptone yeast (TYE) medium, and then separated and selected.

  Microorganisms isolated from soil and kimchi were inoculated and incubated in solid medium containing insoluble phosphate (3 magnesium phosphate, tricalcium phosphate, calcite) in MOPS medium, which is the minimum medium.

After incubation, the insoluble phosphate solubilizing strain showing a clear ring in a solid medium was pure culture.

Pure cultured strains were inoculated in the above insoluble phosphate solid medium, respectively, to investigate the insoluble phosphate solubilization range of each strain (FIG. 1).

The size of the clear ring was analyzed to isolate strains with high solubility of insoluble phosphate.

In addition, the isolated microorganisms were inoculated with a cell culture medium incubated in a nutrient medium using a paper disk (diameter 6 mm) in a PDA (Difco Co.) medium on which phytopathogenic fungi were smeared and incubated at 30 ° C. for 2-3 days. The antifungal activity against the pathogenic fungi was investigated (FIG. 2).

< Example 2 > Investigation of genetic similarity between nucleotide sequence of isolated strain and existing strain

Genomic DNA of the strain selected in Example 1 was isolated using CTAB solution.

16S ribosomal DNA (rDNA) was amplified using PCR, cloned, and its nucleotide sequence was determined.

The nucleotide sequence of the determined 16S rDNA was compared with the strains registered in the NCBI gene bank to investigate the phylogenetic tree and genetic similarity and the results are shown in FIG. 3.

As shown in Figure 3, the selected strain is Lactococcus Lactococcus lactis subsp . lactis ).

The present inventors have used the selected strain as Lactococcus lactis lactis subsp . lactis ) LKS49 and deposited with the Korea Biotechnology Research Institute's Biological Resource Center on Nov. 23, 2011 (Accession No .: KCTC 12087BP)

< Example  3> Lactococcus Lactis ( Lactococcus lactis subsp . lactis ) LKS49 Utilization of strain

Prepare tryptone-yeast (TYE) liquid medium.

Exemplary Lactococcus lactis obtained in Example 1 (Lactococcus lactis subsp . lactis ) LKS49 was incubated at 36 ° C. for 2 days.

Cultured Lactococcus lactis subsp . lactis ) LKS49 microorganisms were stored by washing with isotonic solution of 0.8% NaCl.

Prepared Lactococcus Lactococcus lactis subsp . lactis ) LKS49 was diluted in distilled water at a concentration of 1 × 10 ⁷ CFU / ml in saline, and inoculated twice a week.

After transplanting the germinated crops from the topsoil, the inoculation was further inoculated once a week for 4 weeks, and the soil was improved by utilizing the microorganism of the present invention in the crops in the salt impaired soil.

< Example  4> Improved salt disorder soil

The Lactococcus lactis of the present invention lactis subsp . lactis ) LKS49 was incubated at 30 ° C. for 2 days, and then Lactococcus lactis subsp . lactis ) LKS49 was diluted in 50 ml of distilled water at a concentration of 1 × 10 ⁷ CFU / ml and inoculated into 150 g of salt-impacted soil, and then the change in electrical conductivity was investigated.

The control was treated only with distilled water.

The soil solution for measuring the electrical conductivity was used after distilled water was added for 2 to 3 hours so that the ratio of soil and water 1: 5, and then filtered and leached.

As a result, the electrical conductivity of the salt disturbed soil before inoculation was 10.2 ds / m, which was lower after inoculation and appeared to 5.0 ds / m after 4 days (see FIG. 4).

From the above results, Lactococcus of the present invention ( Lactococcus) lactis subsp . lactis ) LKS49 strain was found to have an effect of reducing the electrical conductivity of salt disturbed soils.

< Example  5> Solubilization  Investigation of phosphorus content change

In order to investigate the content of water-soluble solubilized phosphorus in salt barrier soil, 50 ml of distilled water was added to 10 g salt barrier soil, shaken for 3 hours, and then used as a soil solution.

The amount of phosphoric acid was measured using molybdenum blue method with ascorbic acid.

In the experimental group, Lactococcus lactis subsp . lactis ) LKS49 was diluted in 50 ml of distilled water at a concentration of 1X10 ⁷ CFU / ml, inoculated into 150 g of saltwater soil, and 10 g of treated soil was taken every 24 hours, and 50 ml of distilled water was added for 3 hours as in the case of the control group. After shaking, the mixture was filtered and used as a soil solution.

The measurement of phosphorus was also measured using molybdenum blue method with ascorbic acid.

As a result, the content of solubilized phosphorus in the salt disturbed soils was 25 µg / g, compared to Lactococcus. lactis subsp . lactis ) LKS49 strain was inoculated more than three times water-soluble solubilized phosphorus than the control after treatment and was lowered to 35 ㎍ / g on the 5th day (Fig. 5).

From the above results, Lactococcus of the present invention ( Lactococcus) lactis subsp . lactis ) LKS49 strain was found to be a biofertilizer (biofertilizer) producing a large amount of water-soluble solubilized phosphorus from salt disturbed soil.

< Example  6> various insoluble phosphate Availability and  Growth rate and Salt removal ability

On the other hand, after depleting phosphoric acid in the MOPS medium, which is the smallest medium, insoluble phosphate tricalciumphosphate and trimagnesiumphosphate were added to the phosphate solubilizing medium at 0.5%, respectively, to prepare the medium, and then inoculated with the strains. 10 ml of each was measured, and the growth rate was measured. After centrifugation of the culture solution, the solubilized Pi in the medium was measured using the supernatant, and the solubilization and degradation of insoluble phosphate were examined.

As a result, the growth rate was slightly different between insoluble phosphate medium, but most of the strains showed maximum growth at 3 days after incubation. In the case of the free Pi content change, the amount of Pi was high in both the three calcium phosphate medium and the three magnesium phosphate medium supplied as the only person, indicating that the solubilization of the tricalcium phosphate and the magnesium phosphate was very vigorous (FIG. 6).

< Example  7> Changes in germination rate of crops

In order to determine the change in germination rate of crops for each strain, incubate in TYE medium for 1 day, wash three times with 0.85% saline solution, suspend in sterile distilled water, and apply two layers of Whatman No 2 filter paper to four petri dishes. After spreading on the bottom, each strain was treated to 1 × 10 ⁷ CFU / ml. After inoculating 5 ml of suspension, 25 seeds of Chinese cabbage were placed on a plate, and the germination rate was examined after 2 and 3 days. Sterile distilled water was used as a control. As a result, there was no significant difference compared to the control group. Rather, when the phosphate solubilized strains detected by the researchers were treated, the germination rate was the same on the 3rd day compared to the control, or the germination rate increased by 2% for LKS42 and LKS49. Could be (see Table 1.). As a result, the insoluble phosphate solubilized strains searched by the researchers did not cause any damage to the seeds.

Changes in Germination Rate of Chinese Cabbage DW LKS2 Suspension LKS42 Suspension LKS49 Suspension LKS28 Suspension 96 96 98 98 96

< Example  8> Pott Experiment

Based on the results of the germination rate in Table 1, each seed (lettuce, cabbage, red pepper) is germinated in the top soil, and when two leaves appear, it is formulated in a pot filled with obstacle soil, and Lactococcus lactis subsp . lactis ) LKS49 was treated to 10 ⁷ CFU / ml before pot experiments were performed. After inoculation, the insoluble phosphate solubilizing strain was inoculated to examine the growth rate at 7 days. As a result, the growth rate was relatively higher when each strain was inoculated into the obstacle soil compared to the obstacle soil (control).

On the other hand, when the inoculated soils were mixed by solubilizing strains applied for simultaneous patent applications, the growth rate was compared, and all of them were superior to the control group.

Claims (4)

New strain with a water-insoluble salt solubilizing activity and antifungal activity of Lactococcus lactis (Lactococcus lactis subsp . lactis ) LKS49 (Accession Number: KTCT 12087BP) Method of inoculating the strain of claim 1 into a crop or crop cultivating soil to solubilize insoluble salts in the soil to promote soil improvement and crop growth. The method of preparing biocalcium, biophosphoric acid, biomagnesium, etc. by inoculating the strain of claim 1 into biological waste resources (fossils, oyster shells, bones, seafood, fish by-products, etc.) and nutritional supplements, feed, fertilizers, cosmetics using the same Material manufacturing technology Technology to use the strain of claim 1 for fermenting spawn of Kimchi and salted fish, manufacture of processed food (juice, jam, etc.), manufacturing of functional foods, immune enhancement

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