BR112020002437B1 - USE OF AT LEAST ONE NONIONIC SURFACTANT DERIVED FROM POLYOLS AND ONE STEROL TO COMBAT ABIOTICAL STRESS - Google Patents

Abstract

Use of at least one nonionic surfactant derived from polyols and a sterol to promote plant growth and plant resistance to abiotic stress and to stimulate a plant's defense systems against abiotic stress.

Description

[001] In the course of their evolution, plants have developed protective mechanical barriers (cuticle, pectocellulosic wall), particularly against pests.

[002] These barriers give them a constitutive resistance, especially against pathogens. When these mechanical barriers are breached, plants develop active defense mechanisms such as systemic acquired resistance (SAR). SAR is certainly less intense or active than the application of a phytosanitary product, but it is sustainable: the plant is prepared for a new attack by a pathogen or other aggressor and will be able to respond more quickly.

[003] In other words, plants have intrinsic means of defending themselves.

[004] Reinforcing its own defenses in response to a biotic stress instead of directly combating the threat with a phytosanitary product is a scientifically and agronomically interesting solution. It is verified that defensive means are stimulants of natural plant defenses (SDN), which are also called elicitators.

[005] Within the meaning of the invention, "biotic stress" refers to stress originating from living organisms such as pathogenic microorganisms, for example fungi, bacteria, viruses, but also nematodes, insects, mites, herbivores or parasitic plants.

[006] Within the meaning of the invention, "elicitor" refers to a substance that is recognized by plants and activates a signaling cascade that leads the plant to mobilize its means of defense. An elicitor is a substance capable, under certain conditions, of stimulating natural defense mechanisms. These natural defenses are directed against biothreats (diseases, pests).

[007] It is also known how to produce plants more resistant to abiotic stress using a biostimulant.

[008] Within the meaning of the invention, "abiotic stress" refers to stress resulting from non-living organisms such as water stress, salt stress, flood stress ("flooding"), wind ("acama"), thermal stress (cold, frost, thermal shock), ultraviolet stress (solar radiation), stress related to nutrient deficiencies, injury stress, oxidative stress, osmotic stress and chemical stress.

[009] In the context of the present invention, the term biostimulant or plant biostimulant is defined by the study undertaken by the Center for Studies and Strategic Perspective of the French Ministry of Agriculture, Agro-Food and Forestry (MAAF, Center for Studies and Strategic Foresight of the French Ministry of Agriculture, Agri-Food and Forestry) and funded by MAAF under Program 215 (Contract No. SSP-2013-094, Final Report - December 2014), entitled “Produits de stimulation en agriculture visant à améliorer les fonctionnalités biologiques des sols et des plants - Étude des connaissances disponibles et recommandations stratégiques”.

[0010] A biostimulant is: “a material that contains (a) substance(s) and/or micro-organism(s) whose function, when applied to plants or the rhizosphere, is to stimulate natural processes to improve/favor nutrient uptake , nutrient efficiency, tolerance to abiotic stress, and crop quality, regardless of the nutrient content of the biostimulant”. (EBIC, 2014).

[0011] Examples of correctly used biostimulants are microorganisms, plant extracts or synthetic chemical compounds. However, the effectiveness of these biostimulants is not ideal.

[0012] At the same time, contemporary agriculture has a growing need to protect its crops and harvests if it wants to maintain its high yields and already low margins on certain productions.

[0013] The poor public image of pesticides (as evidenced by the campaign conducted by the French Union of Plant Protection Industries - UIPP) raises problems. In addition, the effectiveness of phytosanitary products tends to decrease. In fact, as with antibiotics used in human medicine, resistance makes them less effective or even ineffective. For all these reasons, it is necessary to limit its use as much as possible by optimizing its effects.

[0014] The first problem that this invention proposes to solve, is therefore to develop compositions that contribute to the biostimulation of plants through certain effects.

[0015] As a result, the aim is to develop alternative compositions that are able to promote plant resistance to abiotic stress more effectively than prior art compounds.

[0016] In other words, the aim is to stimulate certain natural processes to improve/favor nutrient uptake, nutrient efficiency, abiotic stress tolerance, and crop quality with, in the case of particular nutrients, as a direct effect or indirect, plant growth and thus yield improvement.

[0017] A second problem that the invention proposes to solve is the development of compositions that are able to stimulate certain natural mechanisms to improve tolerance to biotic stresses.

[0018] A third problem that the invention proposes to solve is the development of compositions that make it possible to limit the amount of phytosanitary products applied while maintaining the same effect as standard doses. In other words, the third objective is to develop a composition that can be used as a supplement to particular phytosanitary compositions.

[0019] This invention answers all these technical problems. More specifically, the Applicant found that these objectives were achieved by combining a non-ionic surfactant derived from polyols and a sterol, hereinafter referred to as “the composition or compositions of the invention”.

[0020] As a first effect contributing to biostimulation, the composition of the invention is used to promote the elongation of the main roots and the multiplication and elongation of the secondary roots, that is, the growth of the main and secondary roots.

[0021] As a second effect contributing to biostimulation, the composition of the invention is used to promote flowering.

[0022] As a third effect contributing to biostimulation, the composition of the invention is used to promote plant resistance against abiotic stress.

[0023] As a product that improves resistance to abiotic stress, the composition is used in particular to limit the loss of stomatal water, ie to enable the plant to better withstand water stress.

[0024] As a natural defense mechanism against a biotic stress, the composition of the invention has a particular effect on the activation of the acquired systemic resistance system.

[0025] In some cases, and according to the invention, the composition acts not only to stimulate natural defense mechanisms against biotic stresses, but also to promote resistance to abiotic stress.

[0026] The fact that the composition of the invention is not a product with a specific activity makes it possible to consider a broad spectrum of use in a large number of crops, which can save smaller crops for which the number of plant protection products available is almost nil.

[0027] Furthermore, the Applicant noted that the composition of the invention made it possible to improve the distribution of liquids on the sheet, in particular of an aqueous solution. This phenomenon will result from the reduction of the surface tension of the sheet in contact with the composition of the invention. As a result, by improving the distribution of a solution containing a product that is active in contact with the plant, the amount of product needed for an equivalent effect is reduced.

[0028] This is therefore of particular interest with respect to plant protection products.

[0029] As a result, and according to a further aspect, the invention also relates to the use of the composition as a supplement to a solution containing an active product for the plant.

[0030] As an active product, in particular nutrients, one or more fertilizers, one or more growth regulators and/or with a biocontrol product can be considered. Biocontrol products are intended to prevent the action of organisms harmful to plants and are selected in particular from fungicides, fungistats, bactericides, bacteriostats, insecticides, acaricides, parasiticides, nematicides, taupicides or repellents for birds or game animals, one or more substances intended to destroy or retard the growth of undesirable plants, chosen in particular from herbicides and anti-dicots

[0031] The composition of the invention thus constitutes an economy for the farmer that reduces the number of applications (passages in the field).

[0032] Used indirectly, the product does not cause resistance.

[0033] In addition, optional alternating use, but above all in combination with “classic” plant protection products (biocontrol products) not only makes it possible, as already mentioned, to limit the amount of product to be applied, but also prevent or delay the development of resistance to these products and increase their durability.

[0034] When the composition of the invention is used in association with a product that is active in contact with the plant as described above, it is used simultaneously or sequentially.

[0035] This type of synergy corresponds in all aspects to society's demands for phytosanitary products: - respect for the environment; - absence of risks for humans; - low doses; - wide spectrum of use; - multiple cultures; - no induced resistance; - helps in delaying the development of resistance to plant protection products; decrease in inputs into the crop; - improvement of environmental conditions; - economic interest; - regulatory interest.

[0036] The composition according to the invention can be applied after emergence or before emergence, on the seed, the seedling (juvenile stage before flowering), the plant during flowering (before, during or after pollination), the plant after fertilization, the plant during fruiting, the fruit, the flowers, the leaves, the stems, roots or in the soil, before or after sowing.

[0037] The composition can in practice be applied by spraying, watering, adding to hydroponic growing medium, seed dipping and/or seed coating.

[0038] It is possible to treat plants grown in the field or plants grown in greenhouses or plants grown above ground.

[0039] According to this invention, the plant is selected from the group comprising dicotyledons and monocotyledons, advantageously from the group comprising cereals, plants with roots and tubers, sugar plants, legumes, nut plants, oil or oil plants, vegetables, fruit trees , aromatic plants and spices, plants for growing flowers, or plants for industrial cultivation intended for the production of a raw material for processing.

[0040] According to another feature of the invention, the non-ionic surfactant derived from polyols is selected from the group comprising esters of sugars and fatty acids, alkyl mono- and alkyl polyglycosides, esters of alkyl mono- and alkyl polyglycosides and fatty acids, and N- alkyl glucamides.

[0041] Advantageously, the non-ionic surfactant derived from polyols is selected from the group comprising sucrose esters, sorbitan esters and glucose esters.

[0042] According to a particular embodiment, the nonionic surfactant derived from polyols is ethoxylated or non-ethoxylated.

[0043] Advantageously, the nonionic surfactant derived from polyols is sucrose stearate.

[0044] According to another feature of this invention, the sterol is selected from cholesterol, plant sterols such as campesterol, beta-sitosterol, stigmasterol, brassicasterol, campestanol, sitostanol, animal sterols such as lanosterol or sterols from yeast or mushrooms such as ergosterol.

[0045] Advantageously, the sterol is beta-sitosterol.

[0046] According to a particular embodiment, the nonionic surfactant derived from polyols and the sterol are in solution, advantageously in the form of an aqueous solution, comprising 0.01% to 80%, preferably 0.05% to 30%, even more preferably 0.75% to 3% by weight of the nonionic surfactant solution derived from polyols and sterol.

[0047] Advantageously, the use according to the invention is at least one nonionic surfactant derived from polyols is sucrose stearate and the sterol corresponding to beta-sitosterol.

[0048] According to another aspect, this invention relates to a composition comprising sucrose stearate and beta-sitosterol.

[0049] Advantageously, beta-sitosterol is between 1 and 99% by weight of the composition and sucrose stearate is between 99 and 1% by weight of the composition, preferably beta-sitosterol is between 40 and 1% and sucrose stearate is between 60 and 99% by weight of the composition.

[0050] The embodiments of the invention and the advantages derived therefrom are best shown by the following indicative and non-limiting examples of implementation, supported by the attached Figures.

[0051] Figure 1 shows the comparison of the size of parsley plants after watering with water or after watering with a solution comprising the combination of sucrose stearate and beta-sitosterol according to this invention.

[0052] Figure 2 shows the quantification of salicylic acid in parsley plants 2, 4 or 8 hours after watering with water or a solution comprising the combination of sucrose stearate and beta-sitosterol according to this invention.

[0053] Figure 3 shows the measurement of taproot length of Arabidopsis thaliana plants grown in the absence of sucrose stearate and beta-sitosterol (0%) or in the presence of 10-5% or 10-3% of sucrose stearate and beta-sitosterol in solution.

[0054] Figure 4 shows the evaluation of the secondary root system of Arabidopsis thaliana plants grown in the absence of sucrose stearate and beta-sitosterol (0%) or in the presence of 10-5% or 10-3% of sucrose stearate and beta-sitosterol in solution.

[0055] Figure 5 shows the flowering time for Arabidopsis thaliana plants treated with solutions comprising 1, 3 and 10% of the mixture of sucrose stearate and beta-sitosterol or a control solution (water; H2O) sprayed once ( 1%, 3%, and 10%) or twice at two-day intervals (1% 2X, 3% 2X, and 10% 2X).

[0056] Figure 6 shows the evolution of stomatal water loss as a function of time of Arabidopsis thaliana plants treated with water or a solution comprising the mixture of sucrose stearate and beta-sitosterol according to this invention. Example 1: Preparation of combinations of a non-ionic surfactant and a sterol according to this invention and evaluation of their effect on parsley (Petroselinum crispum) resistance to abiotic stress.

[0057] Different combinations of this invention with a plant sterol are prepared from sucrose stearate and beta-sitosterol.

[0058] The combinations are prepared by dry mixing sucrose stearate and beta-sitosterol, in proportions ranging from 0 to 100% by weight with respect to the total weight of the mixture, for each of these ingredients, as shown in the following Table 1 .

[0059] The effectiveness of each combination on plant tolerance to abiotic stress is analyzed.

[0060] Potted parsley plants are grown in a climatic chamber under the following conditions: 23°C and a photoperiod of 16 h/8 h. Before treatment, all the leaves of the parsley plants are cut off. The treatment of parsley plants consists of watering the pots every three days with: - 40 ml of water (Control lot) - 40 ml of a solution composed of a sample according to Table 1 (97% water + 3% sample)

[0061] Abundant watering is intended to mimic a “flood” type stress.

[0062] Each batch consists of four vases.

[0063] After 18 days, the plants are observed and pictures are taken.

[0064] All samples except that of beta-sitosterol alone (sample A) show a positive effect on plant stress tolerance.

[0065] Optimum effectiveness, that is, a better resistance to abiotic stress (“flooding”) is obtained with

[0066] The results show that sample S produces the optimal effect of plant resistance to abiotic stress (sample S composed of 80% sucrose stearate and 20% beta-sitosterol).

[0067] An uplifting habit was observed in the treated plants, whereas the control plants had a decaying habit. Also, the leaves of treated plants are darker in color.

[0068] The results are shown in Figure 1.

[0069] The application of this invention by irrigation allows a better tolerance to stress by "flooding". Example 2: Evaluation of the effect of a non-anionic surfactant and a sterol according to this invention on the synthesis of parsley salicylic acid.

[0070] Salicylic acid is a phenolic compound that is involved in the development of both local and systemic resistance (SAR) in plants.

[0071] Potted parsley plants are grown under the conditions according to example 1.

[0072] The solutions are applied by watering the base of the plant (40 ml) and spraying on the leaves. The tested solutions are: - control lot: water; - treated batch A: solution comprising 97% water and 3% sample A, i.e. 0% sucrose stearate and 100% beta-sitosterol; - treated batch B: solution comprising 97% water and 3% sample Y, 100% sucrose stearate and 0% beta-sitosterol; - treated batch C: solution comprising 97% water and 3% sample S, ie 80% sucrose stearate and 20% beta-sitosterol.

[0073] Each batch consists of four vases.

[0074] The plants harvested after the application of the treatment were frozen and crushed with liquid nitrogen in order to carry out a quantitative analysis of the salicylic acid content of the plants.

[0075] The results are shown in Figure 2.

[0076] Unexpectedly, it was observed that the combination of sucrose stearate and beta-sitosterol (sample S) induced a greater stimulation of salicylic acid synthesis than the sum of the effects of each individual compound (sample A: beta-sitosterol + sample Y: sucrose stearate), in response to biotic stress.

[0077] These results therefore demonstrate a synergy of action of these two molecules. Example 3: Evaluation of the effect of a non-anionic surfactant and a sterol according to this invention on Arabidopsis thaliana root growth.

[0078] Arabidopsis thaliana plants are cultivated on agar medium in a climatic chamber under the following conditions: 23°C and a photoperiod of 16 h day/8 h night.

[0079] An agar medium is used as a control.

[0080] Agar media containing 10-5% and 10-3% mixture of sucrose stearate and beta-sitosterol according to sample S are used to evaluate the effect of this invention on the development of the root system.

[0081] The length of the main root and secondary roots is measured between the 2nd and the 21st day after germination.

[0082] The amount of secondary roots is assessed visually.

[0083] The results are shown in Figures 3 and 4.

[0084] Figure 3 shows that the taproot of plants grown in the presence of 10-5% and 10-3% of the mixture according to this invention is longer than for plants grown on control agar medium.

[0085] Figure 4 shows that plants grown on agar media comprising 10-5% and 10-3% of the mixture according to this invention have more secondary roots which are also longer.

[0086] It follows from this demonstration that the mixture of sucrose stearate and beta-sitosterol allows growth of the primary and secondary root system. As a result, the plant is better anchored in the soil and nutrient penetration into the plant is more efficient due to a more developed secondary root system. Example 4: Evaluation of the effect of a non-anionic surfactant and a sterol according to this invention on the flowering time of Arabidopsis thaliana

[0087] Potted plants of Arabidopsis thaliana are grown under the conditions of Example 1.

[0088] Solutions comprising 1, 3 and 10% of the mixture of sucrose stearate and beta-sitosterol according to sample S or a control solution (water; H2O) are sprayed once (1%, 3% and 10% ) or twice at two-day intervals (1% 2X, 3% 2X, and 10% 2X), on 3-week-old plants.

[0089] The number of flowering plants per modality was measured as a function of time.

[0090] The results are shown in Figure 5.

[0091] The results show that the solution containing 10% of the mixture according to this invention and sprayed once, as well as the solution comprising 1% of the mixture is sprayed twice, have the same effectiveness as water on the flowering of the plants.

[0092] On the other hand, a single spraying on the plants of the solutions comprising 1% or 5% of the mixture increases the number of flowering plants compared to the control.

[0093] As a result, the mixture of sucrose stearate and betasitosterol according to this invention accelerates flowering of Arabidopsis thaliana. Example 5: Evaluation of the effect of a non-anionic surfactant and a sterol according to this invention on the stomatal water loss of Arabidopsis thaliana.

[0094] Potted plants of Arabidopsis thaliana are grown under the conditions of Example 1.

[0095] The 4-week-old plants are treated with a foliar spray, 4 hours before the measurements are taken, with water (Control) or a solution comprising 3/% of the mixture of sucrose stearate and beta-sitosterol according to S sample.

[0096] The amount of water lost through the stomata over time is measured after the rosette has been released from the total water mass at=0, according to the following formula:

[0097] The results are shown in Figure 6.

[0098] The data show that the spray application of sucrose stearate and beta-sitosterol according to this invention makes it possible to reduce the loss of water through the stomata of the plant in an effective and sustainable way over time. Example 7: Evaluation of the wetting effect of a non-anionic surfactant and a sterol according to this invention on Arabidopsis thaliana.

[0099] Potted plants of Arabidopsis thaliana are grown under the conditions of Example 1.

[00100] The leaves of Arabidopsis thaliana are treated with a foliar spray, water (Control) or a solution comprising 3% of the mixture of sucrose stearate and beta-sitosterol according to the sample S.

[00101] The number of droplets present on the surface of the plant leaf is quantified.

[00102] The results show a decrease in the number of droplets on the Arabidopsis thaliana leaf after applying the mixture according to this invention. In other words, the composition of the invention reduces the surface tension of the sprayed solution on the leaves and thus allows a better distribution of the droplets and a better adhesion of the solution on the leaf.

[00103] Furthermore, the results show that there is no accumulation of the solution comprising the mixture of sucrose stearate and beta-sitosterol according to this invention in the veins and axillary buds of the plant.

[00104] As a result, the mixture of sucrose stearate and betasitosterol according to this invention makes it possible in particular to treat grasses known to be poorly wettable.

[00105] Another interest is the use of this mixture as a supplement to products that have a contact action.

[00106] Furthermore, the use of the mixture according to this invention makes it possible to increase the coverage of the plant and use less product per hectare.

Claims (12)

1. Use of at least one non-ionic surfactant derived from polyols selected from the group comprising esters of fatty acid sugars, alkylmonoglycosides, esters of alkylmonoglycosides and alkylpolyglycosides of fatty acids and N-alkyl glucamides and a sterol, characterized in that be to combat abiotic stress. 2. Use according to claim 1, characterized in that the abiotic stress is the loss of stomatal water. 3. Use according to claim 1 or 2, characterized in that it is after emergence or before emergence, on the seed, the seedling (juvenile stage before flowering), the plant during flowering (before, during or after pollination), the plant after fertilization, the plant during fruiting, the fruit, flowers, leaves, stems, roots or in the soil, before or after sowing. 4. Use according to any one of claims 1 to 3, characterized in that the plant is selected from the group comprising dicotyledons and monocotyledons, advantageously from the group comprising cereals, plants with roots and tubers, saccharides, legumes, nut plants, oil or oil plants, vegetables, fruit trees, aromatic plants and spices, plants for growing flowers, or plants for industrial cultivation intended for the production of a raw material for processing. 5. Use according to any one of claims 1 to 4, characterized in that the nonionic surfactant derived from polyols is selected from the group comprising sucrose esters, sorbitan esters and glucose esters. 6. Use according to any one of claims 1 to 5, characterized in that the nonionic surfactant derived from polyols is ethoxylated or non-ethoxylated. 7. Use according to any one of claims 1 to 6, characterized in that the nonionic surfactant derived from polyols is sucrose stearate. 8. Use according to any one of claims 1 to 7, characterized in that the sterol is selected from cholesterol, plant sterols such as campesterol, beta-sitosterol, stigmasterol, brassicasterol, campestanol, sitostanol, animal sterols such as lanosterol or yeast or mushroom sterols such as ergosterol. 9. Use according to any one of claims 1 to 8, characterized in that the sterol is beta-sitosterol. 10. Use according to any one of claims 1 to 9, characterized in that the nonionic surfactant derived from polyols and the sterol is advantageously in the form of an aqueous solution, comprising 0.01% to 80%, preferably 0. 05% to 30%, even more preferably 0.75% to 3% by weight of nonionic surfactant derived from polyols and sterol. 11. Use according to any one of claims 1 to 10, characterized in that at least one non-ionic surfactant derived from polyols is sucrose stearate and the sterol is beta-sitosterol. 12. Use according to any one of claims 1 to 11, characterized in that the non-ionic surfactant derived from polyols and the sterol are applied to the plant by spraying, watering the plant, adding to a hydroponic culture medium, immersing the seed and/or seed coat.