RU2729388C1 - Polyfunctional agent for plants - Google Patents

Abstract

FIELD: biotechnology.

SUBSTANCE: invention represents a polyfunctional agent for plants based on bacterial strains containing a filler with a biomass of bacteria in a spore form, potassium and sodium salts of humic acids, additionally contains fulvic acid in amount of 0.2–2.0 %, wherein content of biomass of bacteria is not less than 0.6x10⁷ CFU/ml of living microbial cells, and salts of humic acids are introduced in form of 4–6 % solution. According to the second version, a polyfunctional agent for plants based on bacterial strains, containing a filler with a biomass of bacteria in a spore form, potassium and sodium salts of humic acids, additionally contains fulvic acid in amount of 0.2–2.0 %, wherein content of biomass of bacteria is not less than 0.3x10⁷ CFU/ml of living microbial cells, and salts of humic acids are introduced in form of 4–6 % solution. Biomass of bacteria in spore form, in particular, contains Bacillus subtilis – strain DSM 24613 (VKPM B-10641), Bacillus amyloliquefaciens – strain DSM 24614 (VKPM B-10642), Bacillus amyloliquefaciens – strain DSM 24615 (VKPM B-10643), in equal percentage ratio.

EFFECT: invention stimulates growth of plants, protects them, influences adaptability and preserves stability of their properties.

4 cl, 10 tbl

Description

The claimed invention relates to compositions containing microorganisms, namely bacteria, for use in plant growing, as a growth regulator, biofungicide, fertilizer and ameliorant, in particular, at the early stages of technological cycles of seed treatment and foliar application, during soil reclamation.

From the prior art, solutions are known that are preparations for increasing plant productivity and restoring soil microbiocenosis, which have bactericidal, fungicidal and virucidal activity. In particular, such solutions are disclosed in the Russian patent for the invention RU2482174 «strains of bacteria Bacillus subtilis and Bacillus amyloliquefaciens, provides recovery microbiocenosis Soil and gastrointestinal tract of animals, have a bactericidal, fungicidal and virucidal activity, and preparations from these strains" (IPC C12N 1/20, A01N 63/00, A61K 35/74, C12R 1/125, published on 05/20/2013) and in the RF patent for invention RU2481760 "METHOD FOR GROWING PLANTS" (IPC A01C 1/06, A01N 63/02, C12N 1 / 20, published on May 20, 2013). A known drug based on strains contains a filler or water with a biomass of bacteria in the spore form Bacillus subtilis VKPM B-10641, or Bacillus amyloliquefaciens number VKPM B-10642, or Bacillus amyloliquefaciens VKPM B-10643, or their mixture in a ratio of 1: 1: 1 s the titer of each bacterial strain is not less than 1x10 ⁴ CFU / g or 1x10 ⁴ CFU / ml, and the method of growing plants includes treating plant seeds before sowing and plants during the growing season with a biological product in liquid form, which is a mixture of B. subtilis strains VKPM B -10641, B. amyloliquefaciens VKPM B-10642 and B. amyloliquefaciens VKPM B-10643 with a titer of at least 10 ⁶ CFU / ml in the form of an aqueous suspension. The disadvantage of such solutions is the insufficient stability of the drug during storage, as well as the need to observe storage conditions in compliance with the temperature regime of + 4-6 ⁰ С and low efficiency in the growth-stimulating effect on plants, due to weather conditions, the influence of ultraviolet radiation (direct sunlight), the presence of moisture ...

There are also known solutions in which the biomass of bacteria in spore form is combined with humic acids as a plant growth activator and as a biomass stabilizer.

For example, there is a known "BIOPREPARATION FOR STIMULATING GROWTH AND PROTECTING PLANTS FROM DISEASES, INCREASING YIELD AND SOIL FERTILITY" according to the RF patent for invention RU2478290 (IPC A01N 63/02, A01C 1/06, published C12N 1/7, C12R 1/04 .2013), which contains the biomass of Bacillus amyloliquefaciens VKPM B-11008 and humates at the following ratio of components, in vol.%: Biomass of Bacillus amyloliquefaciens VKPM B-11008 - vegetative cells and spores 1.24 ÷ 1.30 × 10 ¹⁰ CFU / ml culture liquid and spore content of 94% of the total CFU - 99.0, humates - 1.0. The low content of humates does not provide a sufficient growth-stimulating effect of the known preparation.

Known technical solution describing "COMPOSITIONS AND METHODS FOR INCREASING THE STABILITY OF MICROBES" according to the RF patent for invention RU2658994 (IPC A01N 63/00, A01N 25/04, A01N 25/26, A01C 1/06, C05G 3/08, published on 06/26/2018 ). According to the known method, to increase the survival of agriculturally beneficial microorganisms in a seed treatment composition containing one or more antimicrobial compounds, one or more lecithins and / or peptones are added in an amount sufficient to inhibit the antimicrobial activity of one or more antimicrobial compounds. In one embodiment, the one or more beneficial microorganisms include one or more phosphate solubilizing microorganisms selected from the group including, inter alia, Bacillus amyloliquefaciens, Bacillus atrophaeus, Bacillus circulans, Bacillus licheniformis, Bacillus subtilis. In one embodiment, the compositions described herein may further comprise one or more beneficial biostimulants. Biostimulants can improve metabolic or physiological processes such as respiration, photosynthesis, nucleic acid uptake, ion consumption, nutrient delivery, or combinations thereof. Non-limiting examples of biostimulants include seaweed extracts (eg, Ascophyllum nodosum), humic acids (eg, potassium humate), fulvic acids, myo-inositol, glycine, and combinations thereof. The known method is aimed at enhancing the stability of microorganisms in a seed treatment composition. Information about the protective and growth-stimulating effect of this method, due to the addition of biostimulants, is not disclosed in the known document.

Also known are "LIQUID PHYTOSPORIN BIOPREPARATION FOR PROTECTING PLANTS FROM DISEASES", selected as the closest analogue, according to the RF patent for invention RU2129375 (IPC A01N 63/00, C12N 1/20, C12N 1/20, C12R 1/125, published on 27.04. 1999) and "METHOD FOR OBTAINING THE PREPARATION FITOSPORIN" under the RF patent for invention RU2128914 (IPC A01N 63/00, C12N 1/20, C12N 1/20, C12R 1/125, published on 20.04.1999). Biological product Fitosporin liquid is a culture liquid containing 15-25 billion cells / ml of the endophytic bacterium Bacillus subtilis VNIISKhM 128 (26D), to which a stabilizer - gumi is added in a percentage ratio of 0.5 - 2%.

The disadvantage of the known drug Fitosporin is its low compatibility with substances that have an alkaline reaction due to the inhibitory effect of the alkaline medium on the bacterial strain that is part of this drug, which reduces its effectiveness. In contrast to the known preparation, the claimed preparation contains bacterial strains compatible with substances having a neutral or slightly alkaline medium with a pH of 7-10 units, which contributes to the preservation of the titer of bacteria and ensures efficiency when using the preparation.

There is a need to create a drug that provides protective and growth-stimulating functions for healing and controlling plant growth at the early stages of technological cycles, as well as for increasing the adaptive capabilities of plants, with high storage stability. The technical result consists in increasing the growth-stimulating, protective action and adaptive effect of the agent on plants, the safety and stability of properties.

The solution to the problem of the invention and the claimed technical result is achieved by the fact that a multifunctional agent for plants based on bacterial strains containing a filler with bacterial biomass in spore form, potassium and sodium salts of humic acids, additionally contains fulvic acid in an amount of 0.2-2.0% , while the content of the biomass of bacteria is at least 0.6x10 ⁷ CFU / ml of living microbial cells, and the salts of humic acids are introduced in the form of a 4-6% solution. According to the second embodiment, a multifunctional agent for plants based on bacterial strains containing a filler with bacterial biomass in spore form, potassium and sodium salts of humic acids, additionally contains fulvic acid in an amount of 0.2-2.0%, while the content of bacterial biomass is not less than 0.3x10 ⁷ CFU / ml of living microbial cells, and salts of humic acids are introduced in the form of a 4-6% solution. The biomass of bacteria in spore form, in particular, contains Bacillus subtilis - strain DSM 24613 (VKPM B-10641), Bacillus amyloliquefaciens - strain DSM 24614 (VKPM B-10642), Bacillus amyloliquefaciens - strain DSM 24615 (VKPM) equal percentage.

Potassium and sodium salts of natural humic acids contribute to plant nutrition and protection. As an example of a solution of humic acids and fulvic acid in the composition of the claimed polyfunctional agent, for example, the drug Cytohumate, which is produced from ancient leonardite, soft brown coal of the Mesozoic period, can be used. The drug includes: total phosphorus (P) (also includes mobile phosphorus), total nitrogen (N), total potassium (K) (also includes mobile potassium), sulfur (S), boron (B), calcium (Ca) (also includes exchangeable calcium), magnesium (Mg), iron (Fe) (also includes mobile iron), manganese (Mn), zinc (Zn), copper (Cu), cobalt (Co), molybdenum (Mo), chromium (Cr), selenium (Se), squalene (2,6,10,15,19,23-hexamethyltetracose-2,6,10,14,18,22-hexaene), Ω-7 (palmitic [hexadecanoic] acid ethyl ester) , Ω-9 ethyl ester of oleic acid), Ω-9 (ethyl ester of palmitoleic [cis-9-hexadecenoic] acid). The drug has no sensitizing effect. Biodegradable, does not form harmful and bad smelling fumes and hazardous secondary compounds. It is non-toxic, does not contain chlorine, is harmless to humans, animals and birds, does not possess allergenic, anaphylactogenic, teratogenic, embryotoxic, mutagenic and carcinogenic effects. Not susceptible to seeding by pathogenic microflora, souring and fermentation. The stated percentage in the polyfunctional agent of humic acid salts of 4-6% is due to the technology of their production and depends on the specific characteristics of the starting material - brown coal. In the preferred variant of using the agent, humic acids are introduced in the form of a ballastless solution, which makes it possible to increase the quality of application and the effectiveness of the action. The absence of sediment in the composition of the product eliminates clogging of the nozzles of the devices for applying the product and uneven treatment of plants and seeds.

A combination of soprotrophic bacteria, in particular, Bacillus subtilis - strain DSM 24613 (VKPM B-10641), Bacillus amyloliquefaciens - strain DSM 24614 (VKPM B-10642), Bacillus amyloliquefaciens - strain DSM 24615 (VKPM B-10641), especially for plants early stages of technological cycles, reliable protection against diseases by changing the environment due to the antagonistic effect on phytopathogens, stabilizing action on the soil microbial community and improving the indicators of soil suppression. The use of this combination of bacteria allows plants to effectively fight pathogens of plant diseases that cause rot of roots, fruits, tubers, root crops, seedlings, scab of leaves and tubers, spotting and burns of leaves, stems, buds and flowers: Didymella applanata, Botrytis cinerea, Fusarium oxysporum, Fusarium solani, Fusarium graminearum, Fusarium moniliformes, Fusarium sporotrichiella, Alternaria alternata, Rhizoctonia solani, Streptomyces scabies, Phytophthora infestans, Bipolaris sorokiniana, Septoria ribis, mixed infections caused by bacteria of the genera Pseudwinas. As an example of the source of the claimed combination of resistive bacteria, for example, the preparation Fitop can be used. In particular, water can be used as a filler for the biomass of bacteria.

Fulvic acid, which is a part of the claimed multifunctional agent, contains a large amount of natural biochemical substances, super-saturated antioxidants, free radical scavengers, nutrients, enzymes, hormones, amino acids, natural antibiotics, natural antiviruses and natural fungicides. Due to the fact that fulvic acid has a low molecular weight, it is biologically very active and can penetrate into the biota at the intercellular level, which provides an easily accessible form for assimilation and increases the effectiveness of the agent. The declared range of fulvic acid in a polyfunctional agent is due to the provision of an optimal ratio of effectiveness and cost of the agent and is determined empirically. When the content of fulvic acid is less than 0.2%, the increase in the effectiveness of the agent appears insignificantly; with the content of more than 2%, the cost of the agent becomes unreasonably high in comparison with the effect of its use.

A polyfunctional agent according to the first option, characterized by a bacterial biomass content of at least 0.6x10⁷ CFU / ml of living microbial cells, has a more protective, antagonistic, antimicrobial effect, but also a growth-stimulating effect and provides an increase in the adaptive properties of plants, while the content of bacterial biomass is not less than 0.3x10⁷ According to the second variant, CFU / ml of living microbial cells provides growth-stimulating and anti-stress effect on plants. The multifunctional agent according to the first option is used mainly for treating seeds, tubers, bulbs before sowing (planting) and watering the soil. A multifunctional product according to the second option - for processing on the ground part of plants.

A multifunctional tool for each of the implementation options is used, in particular, for:

- processing of seed (planting) material (seeds, tubers, bulbs, etc. before sowing (planting) by soaking in a working solution or spraying until the surface is completely wetted;

- treatment of the root system when transplanting plants to a permanent place of growth by soaking in a working solution;

- processing of vegetative mass of agricultural plants, garden crops and plants of urban landscapes (flowers, shrubs, lawn grass, etc.);

- irrigation of agricultural plants, garden crops and plants of urban landscapes;

- processing of soil and soil of any type in greenhouses, fields, gardens, etc. by spraying.

The effectiveness of the declared multifunctional agent has been confirmed during many years of field tests. The following are several examples of using the claimed multifunctional tool with tables showing the test results.

Example 1

The effectiveness of the claimed multifunctional agent was studied according to the first and second options with a bacterial biomass content of at least 0.6x10 ⁷ CFU / ml and 0.3x10 ⁷ CFU / ml of living microbial cells, respectively, when growing spring wheat on the effect of the agent on the growth, development and yield of wheat when used for pre-sowing seed treatment, on adaptive capabilities (response to herbicide treatment, weather conditions and other stress factors), as well as on seed infection with phytopathogens and the development of root rot.

Place of laying: the left-bank part of the Novosibirsk district of the Novosibirsk region, the experimental field of the agronomic faculty in the educational experimental farm "Praktik" (northern forest-steppe). The soil of the site: leached medium-thick chernozem, medium-humus, medium-loamy with a neutral reaction of the environment. In terms of its quality, the soil of the experimental site belongs to the best soils of the Novosibirsk region.

Agricultural technology: wheat was sown according to the predecessor of the fallow. The wheat planting date is May 24. The zoned wheat variety Novosibirskaya 31 was sown with a sowing rate of 6 million viable grains per hectare and a planting depth of 3-4 cm. The variety forms grain at the level of valuable varieties. The seed was pickled 4 days before sowing. Production experience area - 7.2 hectares.

In the experiment, there are 5 options laid down in a single repetition:

1) Control, without seed treatment;

2) Preparation Fitop 8.67-9 (1.6 ml / t);

3) the declared polyfunctional agent according to the first option with a bacterial biomass content of at least 0.6x10 ⁷ CFU / ml of living microbial cells, hereinafter - the declared agent-I, (0.33 l / t);

4) Preparation Cytohumate (0.33 l / t);

5) Alcazar, KS (1 l / t) - chemical standard.

Phytop 8.67-9 contains spore biomass Bacillus subtilis strain VKPM B-10641, Bac. amyloliquefaciens strain VKPM B-10642 and Bac. amyloliquefaciens strain VKPM B-10643.

Cytohumate is an extract of humic acids.

The active substance of Alcazar, KS is difenoconazole + cyproconazole.

During the tillering phase, changes were made to the experiment scheme: each option was divided across into 2 parts, on one of which the usual system of plant protection with herbicides was applied, on the other part, a multifunctional agent was added to the tank mixture to herbicides as an antistressant according to the second option with the content of bacterial biomass not less than 0.3x10 ⁷ CFU / ml of living microbial cells, then - the declared agent-II (0.33 l / ha).

Field germination (10 and 14 days after sowing, 10-fold replication in the variant), plant biomass (11.07. 5-fold replication), 3 indicators of plant growth (plant height, spike length and straw diameter - in 25 replicates) , grain yield and elements of its structure (number of plants / m2, productive bushiness, number of grains in an ear, weight of 1000 grains).

After harvesting, 3 quality indicators were determined in the grain: raw gluten (GOST 27839-2013), protein and starch content - on a Foss NIR analyzer (Switzerland).

The phytosanitary state of grain after treatment with the preparations was taken into account by the method of mycological analysis (Naumova, 1970), the damage to the root system of plants by root rot was differentiated by organs according to the scale proposed by V.A. Chulkina (1972).

The response of plants to treatment with herbicides was assessed by the change in the specific electrical conductivity (EC) of spring wheat leaf cells 10 days after chemical weeding of sowing.

Table 1 - Seedlings of spring wheat in the experiment with seed treatment, pcs / m2

Option 10 days after sowing (06/03/19) 14 days after sowing
(7.06.19) Control 442.4 ± 5.2 460.8 ± 8.8 Fitop 8.67-9 422.4 ± 17.1 540 ± 19.0 declared remedy-I 554.4 ± 20.3 597.6 ± 3.6 Cytohumate 438.4 ± 40.7 537.2 ± 20.0 Alcazar 441.6 ± 22.3 509.6 ± 13.0

Germination in the variant with the claimed agent-I was 92.4% on the 10th day, 100% on the 14th day. In other variants with biological products, the germination rate was 70-73.6% and 84-90%. In the control, the germination rate reached 76.7% by the second registration period.

Table 2 - The effect of drugs on wheat growth rates

Option Height
plants, cm Ear length,
cm Diameter
straws, mm Herbicide experience Control, no seed treatment 95.5 8.7 2.7 Fitop 8.67-9 104.7 * 9.8 * 2.8 declared remedy-I 106.2 * 9.7 * 3.0 * Cytohumate 110.4 * 10.6 * 3.0 * Alcazar 106.7 * 10.1 * 3.1 * NSR ₀₅ 5.3 0.6 0.3 Experience with herbicides + declared agent - II Control, no seed treatment 97.6 9,7 2.7 Fitop 8.67-9 106.5 * 10.0 3.0 * declared remedy-I 103.9 * 9.8 2.9 * Cytohumate 96.1 9.5 3.0 * Alcazar 101.7 9,7 2.9 * NSR ₀₅ 6.1 0.6 0.2

* differences from control at 5% significance level.

НСР ₀₅ - the smallest significant difference, allowing 5% error in the experiment. Comparison and evaluation of the arithmetic mean differences are made on the basis of the generalized error, which is the same for any pair of compared options. The analysis of variance is based on the decomposition of the total variation of the experimental data into parts and the isolation of the so-called residual variation arising in connection with experimental errors. The most important task of analysis of variance is to determine the random variation. This makes it possible to establish the experimental error (S) and the smallest significant difference (НСР0.5), i.e., the minimum difference between the average yields, which in this experiment is recognized as significant compared to the 5% significance level, when the risk of making a mistake the conclusion is 5% (5 cases out of 100).

In the variants with seed treatment, the plants everywhere became more resistant to lodging, since in the Novosibirskaya 31 variety, the straw diameter increased by 11-14.9%. In general, the treatment of seeds with the claimed agent according to the described scheme promoted an increase in field germination of spring wheat, its biomass, more active growth of the stem, ear and thickening of the straw.

The effect of the preparations and the declared agent on the phytosanitary state of grain and plants was also studied. Analysis of the control grain for infection with root rot pathogens showed the presence of the fungi Bipolaris sorokiniana, Fusarium, and Alternaria in it.

The causative agent of common rot B. sorokiniana was 2.8 times more than the harmfulness threshold (PV = 10-15%), Fusarians - 2.6 times more (PV = 5%) (Table 4).

Table 3 - Infection of spring wheat seeds with pathogens after treatment with drugs,%

Option B. sorokiniana R. Fusarium R. Alternaria Control, no seed treatment 33 13 56 Fitop 8.67-9 15* 0 * 35 declared remedy-I 12* 3 * 50 Cytohumate thirty 0 * 35 Alcazar 15* 0 * 40 NSR ₀₅ eleven 6.6 21 The degree of influence on Snedekor,% 72.0 64.4 44.4

* differences from control at 5% significance level.

Treatment of spring wheat seeds with biological products Fitop 8.67-9 and the declared agent disinfected them at the severity threshold (hereinafter referred to as PW) from B. sorokiniana and completely from Fusarium infection. These funds have shown biological effectiveness at the level of the chemical disinfectant Alcazar, Cytohumate limited the development of fusarians.

As a result of this phytosanitary effect on seeds in variants with biological products, a limitation of root rot was noted (in humid July it was rot of Fusarium-helminthosporium etiology) (Table 4). The census was carried out on 9.07.19, during the earing phase of spring wheat.

Primary roots on biological products were affected by root rot less than the control by 1.6-1.7 times (on Alcazar by 2 times).

Table 4 - Infestation of spring wheat in the experiment with root rot.

Option Disease development index,% Primary roots Secondary roots Border authorities
soil-air Plant average Control, no seed treatment 9.6 14.9 9.2 12.2 Fitop 8.67-9 6.1 * 11.5 6.8 8.1 declared remedy-I 6.2 * 10.5 8.9 8.5 Cytohumate 5.4 * 9.1 * 10.3 8.3 Alcazar - the chemical standard 4.9 * 9.8 * 6.6 7.1 * NSR ₀₅ 3.3 4.6 5.2 4.4 The degree of influence on Snedekor,% 48.8 43.2 36.2

* differences from control at 5% significance level.

Thus, the treatment of seeds with the declared agent in 2019 helped to limit the development of root rot on wheat roots.

When assessing the effect of the agent on the yield of spring wheat, it was found that in the experiment without adding the declared agent according to the second option as an antistressant to herbicides, the yield of spring wheat Novosibirskaya 31 was higher in the option with Fitop 8.67-9 - 41.6 c / ha (Table 5 ). This preparation provided a grain increase of 6.4 c / ha or 18.2%. A smaller, but significant increase was also given by the use of the declared agent according to the first option and Cytohumate - 13.1% and 8%.

Against the background of a mixture of herbicides with the declared agent according to the second option, the wheat yield was higher on the declared agent-I - 19% relative to the control. At Cytohumate, grain productivity increased by 13.7%, at Fitop 8.67-9 - by 11.4%. Treatment of seeds with Alcazar also increased the yield of the crop, but the difference with the control was not significant. In general, the use of the claimed agent according to the second option as an antistressant made it possible to additionally obtain from 3.2 to 7.2 c / ha of spring wheat grain.

Table 5 - Influence of biological products on the yield of spring wheat Novosibirskaya 31

Option Herbicide experience Experience with herbicides + declared agent-II c / ha increase in control,
c / ha c / ha increase in control,
c / ha (%) Control, no seed treatment 35.2 - 39.5 Phytop 41.6 +6.4 (18.2%) 44.0 +4.5 (11.4%) declared remedy-I 39.8 +4.6 (13.1%) 47.0 +7.5 (19%) Cytohumate 38.0 +2.8 (8%) 44.9 +5.4 (13.7) Alcazar 37.3 +2.1 (6%) 40.5 +1.0 (2.5%) NSR ₀₅ 2.5 3.4

Table 6 - Structure of biological yield of spring wheat

Option The number of plants / m ² Productive bushiness The number of grains per ear, pcs. Weight of 1000 grains, g Productivity from 1 m ² , g Herbicide experience Control, no seed treatment 308.2 1.16 28.7 34.2 352.0 Fitop 8.67-9 320.7 1.17 31.9 * 35.0 * 416.4 * declared remedy-I 328.8 1.18 30.0 * 34,7 398.3 * Cytohumate 313.7 1.13 30.1 * 35.7 * 380.0 * Alcazar 300.6 1.16 30.7 * 34.8 372.5 NSR ₀₅ 23.2 0.08 1.3 0.76 25.2 Experience with herbicides + declared agent-II Control, no seed treatment 320.0 1.23 28.8 34.8 395.3 Fitop 8.67-9 340.6 1.14 32.0 * 35.1 440.4 * declared remedy-I 350.2 * 1.18 31.4 * 36.1 * 469.6 * Cytohumate 320.2 1.14 34.4 * 35.9 * 448.8 * Alcazar 315.2 1.15 32.0 * 35.1 405, 0 NSR ₀₅ 24.9 0.10 1.9 0.85 33.6

* differences from control at 5% significance level.

There was also a change in the quality of spring wheat grain against the background of preparations. The quality of wheat grain in the experiment was determined in accordance with GOST 9353-2016 “Wheat. Technical conditions ". Differences in quality indicators for the variants of the experiment are shown in Table 7. It was found that in all variants with seed treatment, grain formed 2 classes with gluten in the range of 30.4-30.8% and protein 17.6-17.9%. The control in the experiment with the absence of treatment with the declared agent as an antistressant to herbicides was distinguished by a reduced protein content (16.2%) and gluten (27.8%), such grain, according to GOST 9353-2016, belongs to the 3rd class. Against the background of the application of the declared agent together with herbicides, the grain in the control was formed of 2 classes.

Table 7 - Grain quality indicators of spring wheat variety Novosibirskaya 31 against the background of preparations

Option Protein,% Starch,% Gluten
raw,% Herbicide experience Control, no seed treatment 16.2 64.1 27.8 Fitop 8.67-9 17.9 63.1 30.8 declared remedy-I 17.6 63.5 30.5 Cytohumate 17.8 63.2 30.4 Alcazar 17.7 63.3 30.7 Experience with herbicides + declared agent - II Control, no seed treatment 17.6 63.1 30.1 Fitop 8.67-9 17.6 63.1 30.2 declared remedy-I 17.5 63.1 30.0 Cytohumate 17.7 63.1 30.5 Alcazar 17.6 63.3 30.1

Due to the effect on germination, growth processes of wheat, improvement of its phytosanitary and physiological state, the claimed agent provided an additional increase in grain relative to control. The use of the claimed agent according to the second option as an antistressant made it possible to additionally obtain in the experiment from 3.2 to 7.2 c / ha of spring wheat grain. In all variants with seed treatment, grain was formed of 2 classes with gluten 30.4-30.8% and protein 17.6-17.9%. The control in the experiment with herbicides without an antistressant had a grain protein content and gluten lower. The seed of this control was formed of 3 classes.

Example 2

The effectiveness of the claimed polyfunctional agent according to the first option with a bacterial biomass content of at least 0.6x10 ⁷ CFU / ml of living microbial cells was studied when growing strawberries of the garden variety Junia Smides in terms of the effect on the growth, development and fungal disease of plantings.

To bookmark the experiment used seedlings grown in the mother farm of the agricultural artel (SHA) "Sady Sibiri". Strawberry planting dates - in the 2nd decade of June. The number of processed plants - 3000 pieces for 1 variant. The area of option 1 is 350 m2. The method of applying bioagents during pre-planting treatment is the soaking of the root system of strawberry seedlings with an exposure of 2 hours in a working liquid containing the declared multifunctional agent according to the first option at a concentration of 0.21%. The flow rate of the working fluid for 1 option is 24 liters. Consumption of a polyfunctional product 50.4 ml for 1 option.

The control group of plants was not subjected to any treatment.

Table 8. Influence of pre-planting treatment of the root system of strawberries on the growth, development and defeat of fungal disease (production experience, Agricultural Academy "Sady Siberia", registration 09/22/2018)

Option Survival,% (accounting August 04) Root length, cm Total biomass, g / plant Number of new leaves, leaves
/plant The length of the aboveground part, cm Number of sockets, sockets
/plant White spot, degree of damage,% General condition, score Control 59.4 22.5 53.4 2,3 20.9 1.4 32.5 4.6 Multifunctional product, 0.21% 75.0 * 24.8 * 83.8 * 3.4 * 23.1 * 2.1 * 14.3 * 4.9 * NSR ₀₅ 11.5 1.8 13.3 0.3 1.6 0.5 2.7 0.3

* - the difference with the control statistically (P <0.05) is reliable

The survival rate of the planted plants was taken into account 1.5 months after planting. In the control group, the survival rate of plants was 59.4%, under the influence of treatment with the claimed agent, the survival rate significantly (P <0.05) increased 1.3 times relative to the control, to a level of 75.0%.

Indicators of growth, development and damage to strawberries by fungal disease were taken into account at the end of the growing season.

The length of the root system under the influence of pre-planting treatment with the claimed agent increased by 10.0% at 22.5 cm in control.

The total biomass of 1 plant under the influence of the claimed agent increased by 56.9%, at 53.4 g / plant in the control variant. This effect was statistically significant (P <0.05) not only exceeded the control level.

The number of new leaves formed after planting plants under the influence of pre-planting treatment with the claimed agent statistically significantly (P <0.05) increased by 47.2%, with 2.3 leaves / plant in control.

The length of the aerial part under the influence of the claimed agent significantly (P <0.05) increased by 10.4%, at 20.9 cm in control plants.

The number of daughter rosettes formed by 1 strawberry plant under the action of the claimed agent significantly (P <0.05) increased by 48.8%, with 1.4 rosettes / plant in control.

When taken into account at the end of the growing season, the degree of damage to plants with white leaf spot (causative agent - Ramularia tulasnei Sacc, Hyphomycetales, Deuteromycota) when treated with the declared agent statistically significantly (P <0.05) decreased 2.3 times, the biological efficiency was 56.3% ...

The general condition of strawberry plants under the influence of treatment with the claimed agent improved to close to excellent (4.9 points), statistically significantly (P <0.05) higher than that of control plants (4.6 points - intermediate between good and excellent condition).

Thus, the high efficiency of the growth-stimulating effect of the claimed agent, used by pre-planting treatment of the root system of strawberry seedlings in comparison with the control group, is shown, according to such characteristics as the total biomass of plants, the number of new leaves, the length of the aerial part, the number of daughter outlets, as well as the high efficiency of the protective action of the claimed agent against fungal disease of strawberry white spot of leaves.

Example 3

The growth-stimulating, protective and antimicrobial effect of the claimed multifunctional agent was studied when growing early-maturing potatoes of the Rosara variety. The laying of field experiments was carried out in the fields of the "Sad Michurintsev" UPH of the Novosibirsk region, in accordance with the methods of field research in vegetable growing. Before planting, potato tubers were soaked in a 1% suspension of the claimed product according to the first option with a bacterial biomass content of at least 0.6x10 ⁷ CFU / ml of live microbial cells for 1 hour, tubers soaked in water served as a control group, and as a reference used the biological preparation Bactofit (Bacillus subtilis) of the Sibbiopharm production association (10 g / 500 ml of water). The treated potato tubers were planted in rows of 20 in replicates (each variant in 3 replicates). The tests were carried out against the background of the natural spread of diseases in the field. The amount of harvest was assessed by the average samples from each variant in each replication.

A month (4 weeks) after planting the potatoes, the claimed agent showed a statistically significant increase only in the number of stems, exceeding this indicator by 1.9 times compared with the control group and 1.3 times compared to the reference option (treatment of tubers with Baktofit) (Table 9).

Table 9. Growth-stimulating effect of the claimed agent on potato plants and a protective effect against rhizoctonia stems.

Experience Option Weeks
accounting Weight of 1 plant, g Stem length, cm Quantity, pcs. Disease prevalence,% Biological efficiency,% stems stolons Control 4 222.4 53.4 3.2 11.0 25.0 - 6 490.6 57.6 3.3 13.8 57.50 - ten 813.7 68.7 5.3 23.3 69.23 - Baktofit 4 275.7 52.7 4.7 24.0 14.29 71.4 6 562.0 63.3 5.7 28.3 15.4 79.61 ten 1203.0 79.0 6.0 32.3 23.1 66.6 declared remedy-I 4 182.0 49.3 6.0 16.7 0 one hundred 6 565.7 60.0 6.0 38.0 5.56 83.4 ten 1097.0 61.7 6,3 40.7 10.5 84.8 NSR ₀₅ 114.2 5.41 0.89 6.1 11.63 11.63

When counting on the 6th and 10th weeks, reliable results were obtained by the number of stems and stolons. According to the last indicator, on the 10th week, the experimental variant (the declared agent) exceeded both the control (1.7 times) and the reference (1.3 times) variant, which made it possible to form the mass of plants at the level of the variant using Baktofit, exceeding 1.4 times the variant without processing tubers (control).

Thus, the claimed agent had a growth-stimulating effect on the growth of stems and stolons, as well as on the number of tubers in one bush.

The bacterial base of the claimed agent showed a high antifungal effect on the causative agent of rhizoctonia. Already a month later, in the variant with the claimed remedy, no manifestations of the disease on the stems were found, while, in the control variant, the prevalence of the disease reached 25.0%. On the 6th week of accounting, this indicator was low (compared to the control, it was lower by 10.3 times, and with the standard - by 2.8 times). On the 10th week - 6.6 times and 2.2 times, respectively. The biological effectiveness of the declared agent was the highest on all counting dates, and on the 10th week it was 84.8%.

The growth-stimulating activity of the claimed agent and the effectiveness in relation to phytopathological control of the causative agent of rhizoctoniasis made it possible to obtain a better and higher yield of potatoes (Table 10). Moreover, an increase in the mass of tubers occurred due to the formation of a larger fraction and a decrease in the average (from 30 to 130 g). In addition, as a result of the application of the claimed product, a healthier food and planting material was obtained: the prevalence of the disease on the tubers of the new harvest decreased 10 times.

Table 10. The effect of the claimed funds on the quality of the potato crop.

Experience Option Fraction mass,% Productivity, t / ha The prevalence of diseases on tubers of a new crop,% Biological efficiency,% shallow average large Control 4.12 74.36 21.52 29.9 12.5 - Baktofit 7.19 47.88 44.93 31.2 4.5 64.0 declared agent-II 4.25 44.71 51.04 36.8 1,2 90.4 NSR ₀₅ 1.04

Thus, under the conditions of the growing season, the claimed agent had a growth-stimulating and protective effect, due to which the productivity of potatoes increased.

The above examples confirm the increase in the growth-stimulating, protective and antimicrobial action and the adaptive effect of the agent on plants, the safety and stability of the properties, while the claimed combination of the components of the agent is new and not obvious to a specialist in this field. A positive effect on the development and growth of plants of individual components of the claimed agent is known, however, the claimed combination with the declared parameters and proportions made it possible to improve the total effect.

Claims (4)

1. Multifunctional plant agent based on bacterial strains, containing a filler with the biomass of bacteria Bacillus subtilis - strain DSM 24613 (VKPM B-10641), Bacillus amyloliquefaciens - strain DSM 24614 (VKPM B-10642), Bacillus amyloliquefaciens strain VKPM 24 B-10643) in spore form, potassium and sodium salts of humic acids, characterized in that it contains fulvic acid in an amount of 0.2-2.0%, while the content of bacterial biomass is not less than 0.6x10 ⁷ CFU / ml of live microbial cells, and salts of humic acids 4-6%. 2. A multifunctional plant agent according to claim 1, characterized in that it contains bacterial biomass in spore form in an equal percentage. 3. A multifunctional agent for plants based on bacterial strains, containing a filler with the biomass of bacteria Bacillus subtilis - strain DSM 24613 (VKPM B-10641), Bacillus amyloliquefaciens - strain DSM 24614 (VKPM B-10642), Bacillus amyloliquefaciens strain VKPM 24 B-10643) in spore form, potassium and sodium salts of humic acids, characterized in that it contains fulvic acid in an amount of 0.2-2.0%, while the content of bacterial biomass is not less than 0.3x10 ⁷ CFU / ml of live microbial cells, and salts of humic acids 4-6%. 4. A multifunctional plant agent according to claim 3, characterized in that it contains bacterial biomass in spore form in an equal percentage.