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    • 专利摘要:
    This invention relates to the use of a composition in low doses containing single L-amino acids, including their precursors and still biologically active metabolites, for influencing the life processes of crops, such as, for example, their growth, the total amount of single L-amino acids when applying the composition is at least o.5 g / hectare and at most 250 g / hectare, and wherein the L-amino acids are selected from the group of glutamine, asparagine, aspartic acid, histidine, lysine and combinations thereof with each other and / or with arginine and / or with glutamic acid.
    公开号:BE1019681A5
    申请号:E2011/0566
    申请日:2011-09-23
    公开日:2012-09-04
    发明作者:Koen Quaghebeur
    申请人:Globachem;
    IPC主号:
    专利说明:

    Use of single amino acids in low concentrations to influence the life processes of crops.
    This invention relates to the use in small amounts and dosages of certain single L-amino acids for influencing the life processes of crops.
    Amino acids are the building blocks of proteins, and therefore occur in large quantities in nature. Very often they are also added to formulations and compositions to stimulate the growth and production of vegetable crops. For example, they are included in formulations containing fertilizers, plant food, but also in pesticide compositions. In these compositions, the amino acids may be present in their singular form, in the form of proteins, or as polypeptides in protein hydrolysates.
    Amino acids are added to plants for various reasons. In combination with fertilizers, they are said to improve their uptake, and mixtures of different amino acids and / or polypeptides are often added as a nitrogen (N) source for the crops. After all, all amino acids contain at least one N atom. Amino acids are therefore usually given to plants as food. In this context, amino acids are generally applied to the crops in relatively large quantities.
    In US 2008/0194407, highly nitrogen-containing chelates of metals with amino acids or other nitrogen-containing substances are used as leaf nutrients for plants. The metal dosage used is considerable, so that the amino acid residues are also used in high doses.
    In EP1241149 a method is described for making a fertilizer for plants via hydrolysis of proteins. More specifically, animal proteins from slaughterhouse waste are used. By making use of protease enzymes, these proteins are broken down, and thus a mixture is obtained that can be used as a fertilizer for plants. This mixture will have an arbitrary composition of different kinds of single amino acids, di, tri and polypeptides, all of which can function as plant nutrients.
    An exact composition of such protein hydrolysates is of course very difficult to determine. It can be said that these mixtures contain a very large number of types of amino acids in the bound and unbound state, and this in very high concentrations. According to EP
    1 - c 1241149, the concentration of L-amino acids is an important characteristic for use as fertilizer or fertilizer, because they are useful building blocks for the synthesis of enzymes and proteins. Such mixtures may exhibit a good effect in increasing crop yield, although this effect is only due to the nourishing function of the amino acids and polypeptides in question, e.g. as a nitrogen source, or their function as a raw material. These good results are by no means the result of an action as an active substance, for example because it would influence the metabolism of the plant or perform a function as a plant growth regulator, etc.
    EP926113 further describes a biostimulant consisting of a combination of nitrogen, potassium and phosphorus sources and plant growth regulators that further contains amino acids. This biostimulant increases the efficiency of traditional fertilization.
    US 2004/0209777 A1 describes the use of a composition containing proline for increasing the quality of fruit and berries by improving the flower bone formation and increasing the sugar content.
    Also Caronia, A et al, in International Society for Horticultural Science, in Influence of L-proline on Citrus sinensis fruit quality, describes the use of proline in repeated treatments to improve the stress resistance and nitrogen absorption of the orange trees, and of the organoleptic characteristics of the oranges.
    Kim, Y.H. et al, in “Abscisic acid and proline improve desiccation tolérance and increase fatty acid content or celery somatic embryos”, Plant Cell, Tissue and Organ Culture (1991), describes the use of abscisic acid with proline, and this to germinate in vitro of plant embryos.
    Rahagopal, V, in “Effect of abscisic acid with glutamate on the production of prûline in barley leaves”, Plat Biochemical Journal (1981), also describes the use of abscisic acid and / or glutamate in in vitro tests to increase the content of proline .
    DE 2217896 describes the use of the sulfur-containing amino acid methionine as a plant growth regulator.
    RU 2337544 describes the use of glycine in a field where sugar beets are sown, to activate the defense mechanisms of the plants, to promote synthesis, to increase yield and sugar content, and to increase disease resistance.
    DD 248 499 A1 describes the use of N-ethyl glycine for the stimulation of the yield of tomato plants.
    EP1124419 describes a composition containing glutamic acid, always in combination with glycolic acid, applied in a carrier medium wherein this carrier medium is a pesticide, fungicide or calcium nitrate. This mixture would increase the productivity of plants. With regard to the concentration of the glutamic acid and the glycolic acid, a very wide range is stated, ranging from 0.5 ppm to 2500 ppm. At 500 ppm of glutamic acid only a small effect was obtained, and the combination with glycolic acid is set as a requirement to obtain a good effect.
    Wang L. et al. In "Promotion of L-glutamic acid on anthocyanin accumulation or Fuji apples", Guoshu Guaïei Zazhishe (2006) describes the use of glutamic acid in a relatively high dose as a precursor for 5-aminolevulinic acid, and this necessarily more than 5 weeks before picking to increase the coloring of Fuji apples.
    In GB 955685 amino acids are used to increase the stimulatory effect of the plant hormone 2,4-dichlorophenoxy acetic acid on the enzyme activity, and thereby to achieve better growth. In addition, glutamic acid is always used together with methionine. The added amino acids are attributed an enzymatic effect.
    JP 2001199812 proposes the use of glutamic acid or a salt thereof in a composition with uracil and proline to accelerate flower induction and to achieve growth stimulation. In the example, not glutamic acid but glycine is used.
    CN 101352165 describes the use of a composition that contains abscisic acid, glutamic acid and phenyl alanine in addition to sugars and phosphate fertilizer in particular, to improve the coloring of pears with a high dose.
    WO 00/25582 describes the use of a composition of (poly) glycolic acid and glutamic acid to increase the yield of plants. A test with only glutamic acid did not result in any notable improvement over the coke test.
    WO 2005/102047 describes the use of the magnesium salt of dihydrojasmonic acid to increase tolerance to abiotic stress conditions, such as high temperatures and low humidity. L-arginine was sometimes added to the compositions.
    However, none of these preceding publications describes the use of very low doses of L-amino acids to influence the life processes of plants. All previous publications describe either the use of amino acids, polypeptides, etc. as fertilizer or as a source of nitrogen, where the amino acids are applied in very large quantities to the plants or in the soil, or the amino acids are described in combination with other active substances or pesticides. .
    SUMMARY OF THE INVENTION
    The object of this invention is therefore to provide a composition for influencing the life processes of crops and thereby involving the lowest possible risk to humans and nature.
    Do this! is achieved by the use of a composition containing single L-amino acids to influence the life processes of crops, the total amount of single L-amino acids when applying the composition to the crops being at least 0.5 g / hectare and at most 250 g / hectare, and wherein the L-amino acids are selected from the group of glutamine, asparagine, histidine, and combinations thereof with each other and / or with arginine and / or with glutamic acid and / or with aspartic acid and / or with lysine .
    Surprisingly, the inventor has now established that these very low doses of these selected single L-amino acids can nevertheless exert a very strong influence on the life processes of the treated crops. These low doses of 0.5 g / hectare to a maximum of 250 g / hectare influence the life processes of the crops, and usually in such a way that the yield of the crops is greatly increased. The coloring can also be stimulated, the ripening influenced, and / or the quality of the fruits and / or seeds of agricultural and horticultural crops can be stimulated or improved. Moreover, the effects that the L-amino acids have on the plants is so strong that they cannot be explained by the N-content of the amino acids. The L-amino acids in the composition according to the present invention thus do not act as a source of N or as a significant nutrient for the treated crops. For example, treatment with 250 g / ha of glutamine corresponds to a supply of only around 47.9 grams of nitrogen per hectare. This is negligibly small compared to the normal foliar fertilization that is usually administered, and for which the nitrogen administrations are at least 500 grams per ha, or compared to soil fertilizers where they are usually much higher, in the range of 30 to 200 kilograms of nitrogen per hectare. It is thus clear that the chosen L-amino acids exert a regulating and stimulating function on the metabolism of the plants if they are applied at these low doses. The selected L-amino acids thus act as active substance in the composition according to the present invention.
    DETAILED DESCRIPTION OF THE INVENTION
    Certain precursors and still biologically active metabolites of single L-amino acids can produce similar effects in the metabolism of the plant, even if they are applied at these low doses. The selected single L-amino acids per se can thus possibly be replaced or supplemented with this. Those skilled in the art will be able to determine which precursors and / or still biologically active metabolites of these single L-amino acids can be used. However, it is preferred to use the chosen single L-amino acids themselves, and not the still biologically active metabolites or their precursors.
    Hereby, the still biologically active metabolites are defined as these metabolites of the selected single L-amino acids which increase or decrease the total content of these amino acids by at least 20%, preferably at least 25%, and more preferably at least 30%. decrease.
    It is very surprising that the effects can already be achieved without the addition of substances known as plant hormone, i.e. with the chosen L-amino acids per se.
    The increased crop yield is influenced by two different factors. Namely, the inventor has established that by applying the selected single L-amino acids to the crops, fruit set is very strongly influenced, so that more fruits are present on the crops. On the other hand, the inventor has determined that the fruits themselves also become relatively larger after application of the composition according to the present invention. When applied to fruit trees, for example, more fruit will be present on the trees, which moreover will often be at least as large as those of fruit trees on which a comparative control composition without active substance has been applied, or in many cases even larger. In the case of a very large increase in the number of fruits, on the contrary, the size of it may lose some, but no more than what can be explained by the higher number of fruits. The total fruit yield is in any case increased by the treatment according to the invention. In cereals, for example, the grains in the ears will occur in a considerably higher number or become considerably larger by applying the composition according to the present invention, and the number of ears per unit area will also increase.
    Moreover, the inventor has surprisingly determined that this yield-increasing effect applies to both monocotyle and dicotyle crops. Consequently, the yield of just about all economically important agricultural crops can be improved with this invention, which is an important advantage.
    In addition to the increased yield of the crops, the present invention further offers the advantage that the quality of the crops is also greatly increased. Thus it appears that the treated crops have a higher sugar and a higher protein content. It also appears that the composition at the low doses of L-amino acids may also have an influence on the color and / or the ripening of the yield. With fruit it appears that the color of the fruit can also be more intense after application of the composition according to the present invention. These additional effects can be influenced by secondary factors such as the time of application, the nature of the crop, and the like.
    Without wishing to limit itself to this theory, the inventor believes that the chosen single L-amino acids that only have a function as nutrient in large quantities can have an influence on the synthesis or action of certain endogenous plant growth regulators when applied in very low quantities. , similar to a hormonal influence, and through which the life processes of one and / or multi-year mono- or dicotyle plants are influenced and these externally observable effects or phenomena are effected.
    Furthermore, it is very important that the total amount of chosen L-amino acids remains within the above range. A composition in which one specific single amino acid is at a dosage of between 0.5 and 250 g per hectare when applying the composition, but furthermore there are others of the selected single L-amino acids present such that the total dose of selected single L- amino acids far exceeds 250 g per hectare, may therefore not have the intended effect. The action of the chosen L-amino acids as active substance can therefore disappear in such a case. If a growth-stimulating effect is nevertheless achieved in this case, this will mainly be due to the function of the amino acids as an N source and / or as a plant food.
    Preferably, the total amount of selected single L-amino acids when applying the composition is at least 1 g / hectare and at most 50 g / hectare.
    In this low dosage range, the best results are usually obtained, and the growth of the crops is optimally regulated in many cases. More specifically, the growth of the fruits and seeds is strongly stimulated, and the yield of the crops is very high.
    As already described above, the present invention relates to the use of a composition of the selected single L-amino acids primarily for influencing the growth of crops. The influencing of crops can vary depending on the dosage used of the selected single L-amino acids that is applied to the crops, and different forms of influencing are possible.
    Thus, this invention relates more specifically to the use of the above-mentioned composition for inhibiting the vegetative growth of crops, wherein the total amount of selected single L-amino acids when applying the composition is at least 1 g / hectare and maximum 30 g / hectare.
    If the selected L-amino acids are applied to the crops in such an amount, a clear growth-inhibiting effect is observed. This growth-inhibiting effect only relates to the vegetative growth of the plants, being the growth of the shoot. This is usually the growth of the green part of the plants, and is not to be confused with the growth of the fruits or seeds, also known as generative growth, which is by no means inhibited.
    Thus, in these dosages, the composition of the present invention can also be used as a growth inhibitor. This may, for example, entail the additional advantage that the crops need to be pruned less quickly, will be less likely to loot, etc ... The reduced leaf growth, fruits and seeds will also provide improved access to sunlight and aeration, which will improve the quality. and the yield can also benefit. For example, fruits that receive an increased dose of sunlight due to the reduced leaf growth will show a more intense color and their protein and sugar content will also be increased.
    It should further be noted that if the vegetative growth is slowed down, i.e. the longitudinal growth of the plant and essentially the growth of the green parts of the plant, then the generative growth of the plant, being growth of the fruits and from the seeds, is strongly encouraged. This can be explained by the fact that the balance within the plant is likely to shift from vegetative to generative growth. More energy and nutrients are therefore sent to the reproductive organs of the plant, as a result of which more and / or larger fruits and seeds will be formed. Thus, as stated above, the growth inhibitory effect obtained does not in any way relate to the growth of the fruits and seeds, and the increased yield and fruit set discussed above still occurs at these very low dosages.
    Preferably, the composition according to the invention, in case it is used to inhibit the vegetative growth of crops as described above, is applied to the crops at least 2 times, preferably with an interval of at least 1 day or 2 days and at most 6 weeks, more preferably at least 3 or 4 days and at most 5 weeks, still preferably at least 5 or 6 days and at most 4 weeks, and even more preferably an interval of at least 1 week and up to 3 weeks. The aforementioned intervals are very suitable for arable crops, and can shorten up to a maximum of 2 weeks. With trees, and certainly with fruit trees, the interval can usually be a little longer, preferably from 1 to 3 weeks, between the two treatments.
    The inventor has determined that if the composition is applied at least twice at this interval, a very good inhibition of vegetative growth is obtained. The composition is preferably applied twice. Optionally, the composition can also be applied more than 2 times, preferably always using the above-mentioned interval.
    Of course, the invention is not limited by this and it is not excluded that a good influence is also obtained for different selected single L-amino acids if the composition is applied only once.
    Furthermore, the invention also relates to the use of the composition described above for stimulating the growth of agricultural and horticultural crops, wherein the total amount of selected single L-amino acids when applying the composition is at least 30 g / hectare and maximum 100 g / hectare.
    In this context, growth refers to both vegetative and generative growth. In this dosage range, which is slightly higher than the aforementioned range for inhibiting vegetative growth, the inventor has determined that the full growth of the crops is stimulated. The plants will therefore have a generally improved growth. The yield of the crops and the fruit set will still be improved, but we have found that the shoot and the green part of the plant also show improved growth.
    The skilled person will be able to determine for himself in what amount or dosage the treatment is optimal for a specific crop. If the person skilled in the art intends only to improve the yield of a crop, and if it is thereby advantageous to limit vegetative growth, he better applies the chosen single L-amino acids in the above-mentioned total quantities of 1 to 30 g / hectare . However, if a generally improved growth is envisaged for certain crops, where it is also desirable to stimulate the growth of the shoot and the green plant part, quantities of 30 to 100 g / hectare are preferably used.
    If the composition is used to stimulate the general growth of crops as described above, the composition is preferably applied once to the crops.
    A single treatment results in good stimulation of both vegetative and generative growth.
    A single treatment with the selected single L-amino acids is generally sufficient to stimulate growth and is therefore preferred, although this is not a strict condition. It is possible that the general growth can also be stimulated by applying the composition several times. The person skilled in the art is able, depending on the L-amino acid used, the crops, and the intended purpose, etc., to determine whether the composition must be applied one or more times.
    The selected L-amino acids are selected from the group of L-amino acids containing an N atom in the R group, the acid forms of L-amino acids containing an N atom in the R group and combinations thereof. Herein, the R group is understood to be a side group that occurs in many cases on the usual hydrocarbon compound between the amino group (H 2 N-) at one end and the acid group (-COOH) at the other end of the amino acid.
    All of these preferred amino acids thus have an N atom in their R group (or side chain of the amino acid) except for the amino acids that have an acid form as an R group of an R group containing an N atom, for example glutamic acid and aspartic acid.
    Preferably, the composition contains substantially no multiple peptides. We found that multiple peptides do not initially exhibit the same growth-regulating effects as the chosen single L-amino acids, even in small doses. The incorporation of multiple peptides such as polypeptides or oligopeptides thus apparently offers little or no drive value to the composition. It is, however, possible that the incorporation of multiple peptides has a negative impact on the action of other active substances present. It is also difficult to check whether there are no single amino acids with the multiple peptides, or that later on possibly single amino acids can be split off, so that the total dose of selected single amino acids can nevertheless increase unintentionally. This makes it more difficult to guarantee a specific dosage at the chosen single L-amino acids, as a result of which the action of the composition according to the present invention can no longer be regulated and guaranteed as easily and accurately. For these reasons, the composition preferably contains substantially no multiple peptides.
    When treating with a single amino acid, it was sometimes noted that the strength of the response to a particular amino acid could show a bimodal pattern depending on the dosage level. However, the location of the peaks of the pattern, ie at which concentrations the strongest effects could be recorded, and the location of the trough between the two peaks, ie the range in which the response was again somewhat less, appear to depend on the choice of the amino acid and of the life process that one wishes to influence. For example, treatment with histidine showed a higher response in a range of 0.5-5 g / ha as well as in a range of 15-250 g / ha, compared to the response in the intermediate range of 5-15 g / ha.
    In a preferred embodiment of the present invention, the composition further comprises S-abscisic acid or one of its salts.
    S-abscisic acid is a plant hormone that occurs naturally in plants. S-abscisic acid suppresses the action of other growth-stimulating plant hormones and is generally known as a natural growth inhibitor. Together with the growth-promoting plant hormones such as auxins, gibberellins and cytokinins, abscisic acid regulates aging processes, leaf fall, and has a growth-inhibiting effect on vegetative growth. As already mentioned above, this is the growth of the shoot of the plant, so the growth in the longitudinal direction and usually the growth of the green plant part. The action of S-abscisic acid thus has some similarities with the action described above of the chosen single L-amino acids in very low doses. Generative growth, i.e. the growth of fruits and seeds, will also be stimulated with a reduction in vegetative growth due to a shift in equilibrium in the plant. S-abscisic acid can therefore also have a yield-increasing effect on crops thanks to its growth-inhibiting effect. More specifically, the size of the fruits and seeds will be increased, and the fruit set of crops will also be promoted.
    The inventor has now surprisingly determined that S-abscisic acid exhibits a synergistic effect in combination with the low dosage of the chosen single amino acids. This effect surpasses the result that could be expected by the combination of the effects induced by the same dosages of the selected single amino acids and S-abscisic acid, if applied separately.
    The composition according to the invention preferably also contains a growth-regulating substance A selected from the group of gibberellin synthesis Inhibitors, precursors for plant hormones, or combinations thereof.
    The inventor has determined that a further synergistic effect can take place between these growth-regulating substances A and the above-described effect of increase in yield caused by the S-abscisic acid. Thus, if in addition to the S-abscisic acid also one of these growth-regulating substances A is added to the composition with the chosen single L-amino acids, an even more increased yield of the crops will be obtained.
    Preferably, the growth regulator is a gibberellin synthesis inhibitor selected from the group of trinexapac-ethyl, paclobutrazol, uniconazole-P, chloromequat-CI, mepiquat-CI, 2-isopropyl-4-dimethylamino-5-methylphenyi-1-piperidinecarboxylate methyl chloride (also known as "AMO-1618"), etcyclacis, ancymidol, flurprimidol, prohexadione-Ca, daminozide, 16,17-dihydorgas, chlorpropham and combinations of two or more of these. More preferably, trinexapac-ethyl is used.
    These growth-regulating substances A all have a strong inhibitory effect on the gibberellin synthesis, and a strong synergistic effect with the effect of abscisic acid and / or the chosen single L-amino acids, whereby the yield of agricultural crops i.
    can be increased considerably.
    In a further preferred embodiment of this invention, the growth-regulating substance A is a precursor for a plant hormone selected from ethephon, 1-aminocyclopropane-1-carboxylic acid (ACC) and combinations thereof.
    Ethefon and ACC are both precursors for the plant hormone ethylene. Precursors for ethylene in combination with abscisic acid and / or the selected single L-amino acids show a surprising synergistic effect that greatly benefits the yield of the crops. Of course, other precursors for ethylene can also be used in the present invention.
    However, the present invention is by no means limited to this. Any other precursor for a plant hormone or inhibitor for the synthesis of gibberellins that is considered suitable by those skilled in the art can also be used.
    In a further preferred embodiment, the composition according to the invention further comprises a pesticide selected from the group of herbicides, insecticides, fungicides, bactericides, nematicides, algicides, molluscicides, rodenticides, virucides, substances that induce resistance in plants, biological control agents such as viruses, bacteria , nematodes, fungi and other microorganisms, repellents for birds and animals, plant growth regulators, or a combination of two or more of them.
    If a composition according to the present invention also contains pesticides, this composition will, in addition to a yield-increasing effect, also have a function as a pesticide. Different types of pests such as insects, bacterial germs and the like can adversely affect the yield of crops and may even lead to the dying off of the crops. If the composition according to the present invention only brings about a yield-increasing effect in the plants, there is therefore still the possibility that this effect would be canceled out as a result of such pests. It may therefore be useful to add pesticides to the composition. The composition will thereby combine a growth-regulating effect with an effect of pest control. Because the active substances that produce these two different effects are present in one and the same composition, only one composition will therefore have to be applied to the crops. This means a considerable time and therefore money saving for the farmer in question. It should be noted here that reduced vegetative growth in itself entails the risk of infection by pests and diseases. In certain cases, this effect can already be achieved at least in part by the use according to the present invention.
    In a specific preferred embodiment of the present invention, the pesticide is a fungicide selected from the group of triazoles, and combinations thereof.
    The inventor has surprisingly found that fungicides selected from the group of the triazoles can, in addition to an antifungal effect, also enhance the growth-affecting action of the selected single L-amino acids. The addition of such fungicides from the group of triazoles thus offers two important additional advantages.
    These triazoles are preferably selected from the group of epoxiconazole, triadimenole, propiconazole, metconazole, cyproconazole, tebuconazole, flusilazole, diphenoconazole, penconazole, paclobutrazole, prothioconazole, and combinations of two or more of these. The triazoles are preferably selected according to the crop to be treated. For example, epixiconazole, propiconazole, tebuconazole are more suitable for cereals, metconazole, tebuconazole for rapeseed, for example, and diphenoconazole is more suitable for fruit growing.
    However, the composition according to the present invention is by no means limited to this and all other triazoles which are considered suitable by those skilled in the art can also be used.
    In an embodiment of the invention, the composition contains one or more active substances that increase the plant's own defense mechanism. In addition to their basic resistance, plants also have the ability to increase their resistance to specific infections in response to induction by outside microorganisms. A distinction is made between systemically acquired resistance (Systemic Acquired Resistance or SAR) and systemically induced resistance (Induced Systemic Resistance or ISR). With SAR the inducing microorganism is pathogenic or pathogenic, with ISR this is not the case. Preference is given to adding substances which promote these mechanisms, such as jasmic acid, ethyl jasmonate or another ethylene precursor that influence the ISR reaction, or salicylic acid and / or chitosan, or another substance that influences the SAR mechanism. The inventors have determined that these active substances can also have a growth-inhibiting effect.
    In further embodiments of the invention, the composition further contains one or more surfactants.
    Preferably, the surfactants are selected from the group of calcium alkyl sulfonates, ethoxylated castor oil, ethoxylated alcohols, glycols or polyols, polyoxyethylated alkyl phenols, polyoxyethylated fatty alcohols and / or fatty acid amines, fatty acid, alcohol, polyglycol ether sulfates, alkyl sulfonates or alkylarylates and dispersants, ethoxylated sorbitan esters and Siloxanes, or a mixture of two or more of them.
    Surfactants are substances that can lower the surface tension of an aqueous mixture. In compositions to be applied to plants, they can perform various functions. They can thus increase the solubility of the active substances in the usually water-based mixture. Furthermore, they will often fulfill a role as a follower. Because it reduces the surface tension of the mixture, hydrophobic surfaces can be moistened more quickly. The addition of a bleed can thus lead to a better distribution of, for example, the spray liquid, and to a better wetting of the sprayed crops.
    Furthermore, surfactants can act as adjuvants. Hereby they increase the absorption of the active substance by the plant. The functions of the surfactants described above ensure that less active substance must be dosed without this affecting the action of the active substance. On the one hand, this provides an economic advantage and also ensures that the impact on the environment is reduced.
    Furthermore, the composition may contain one or more UV-filtering substances.
    If sunlight falls on the composition, this could entail premature inactivation of the active substances. To prevent this, one or more UV-filtering substances are preferably added as a precaution. Various suitable UV filters are known to those skilled in the art.
    In a further embodiment, the composition further comprises an anti-foaming agent.
    Preferably, the anti-foaming agent is selected from the group of silica, polydialkylsiloxanes, fluoroalkyl phosphine acids or salts thereof, or a mixture of two or more of them.
    In a further embodiment, the composition further comprises a fertilizer.
    The composition according to the present invention will influence the life processes of the crops, whereby the yield is increased. If a fertilizer is also present in the composition, it is ensured that the plants have sufficient nutrients to enable this growth, so that the yield can be increased even further.
    Preferably, the composition is applied in a formulation selected from the group of powders, water-soluble powders, water-dispersible powders, granules, suspension concentrates, emulsifiable concentrates, concentrated emulsions, suspension emulsions, coated granules, microcapsules, tablets, water-soluble concentrates or combinations of two or several of these.
    The composition is preferably diluted with water.
    A composition that can be diluted with water can be sold commercially in a concentrated form with a small volume. This form can then be dissolved or mixed with water to a larger volume that can eventually be applied to the plants. An aqueous dilution can be applied to the plants very easily, and also guarantees an even distribution of the active substances on the crops, which also guarantees a constant concentration and an evenly distributed dosage of the active substances during application. The latter constitutes an important advantage within the context of the present invention, since the activity of the active substances is concentration and / or dose dependent.
    Preferably, the composition is applied to the crops by spraying or spraying.
    By spraying or spraying, a uniform and even distribution of the composition on the crops can be achieved.
    Preferably, the crops are selected from the group of one-year and multi-year mono- or dicotyle crops.
    The composition according to the present invention can be used both on crops that are monocotyl and on dicotyle crops, and shows a good effect on both groups of plants.
    The crops are preferably selected from fruit trees, cereals, rapeseed, beets, potatoes, and any combinations thereof.
    These agricultural crops exhibit a greatly increased yield after application of the composition according to the present invention.
    Furthermore, this invention relates to a use as described above wherein influencing the life processes of crops is selected from increasing the yield of crops, increasing the fruit set of crops or the number of fruits or seeds, increasing the fruit - or grain size of crops, the fruit size or diameter of fruits or seeds, improving the color or coloring of the fruits, influencing the ripening of crops, increasing the protein or protein content of fruits or seeds, increasing of the total yield, increasing the yield of a first harvest, increasing the yield of colored fruit at a first harvest, shortening the extension of shoots, and combinations thereof.
    The effect of coloring can thereby depend on the amino acid used and the time of application. With vegetative growth inhibition, the lower doses up to 30 g / ha are more likely to indirectly improve the coloring. For later applications, such as just before picking, where growth inhibition is no longer achieved or envisaged, it may be that the best dose will be higher, again somewhat, depending on the amino acid. A distinction must also be made between ripening and coloring. This consideration mainly applies to coloring. Other preferred doses may apply for ripening depending on the crop, time and amino acid.
    The selected single L-amino acids initiate a physiological reaction in the plants that has an external influence, mainly on plant growth. In the description above, this reaction was described very generally as influencing the life processes, for example, the growth of crops. It has already been said that this influencing entails, among other things, an increased yield of the crops, an increased fruit set, an improved color of the fruits, etc. All of the phenomena listed above are also associated with the physiological response of the plants to the low doses of the selected L-amino acids. The invention therefore relates to all uses or methods intended to induce one of these phenomena in plants through the use of low doses to the selected L-amino acids.
    In the above description of the invention, the amounts of the substances to be administered are stated in g / hectare. This indicates the amount by which the substances are applied to the crops. The substances are preferably applied in an aqueous solution, with, for example, for easy conversion, approximately 1000 liters of this solution being applied to a 1-hectare plot. This means, for example, that a composition in which the chosen L-amino acids are applied in an amount of 50 g per hectare is in an aqueous solution at a concentration of 50 ppm. In practice, a different amount of water per hectare can be used, and the conversion to the desired concentration must be adjusted accordingly. For example, with a use of only 200 liters per hectare, which also means approximately 200 kg of water, a treatment intended for 50 g per hectare will have to handle a concentration of 50 g per 200 kg or approximately 250 ppm weight.
    The invention is now further illustrated with reference to the following examples.
    Example 1: Improvement of apple coloring.
    This experiment was performed on mature apple trees of the Jonagold variety (mutant King). The spraying was carried out with a back sprayer at 300 liters of water / ha. The spray liquid used contained 300 ppm wt of glutamine in the first test and 150 ppm of glutamine in the second test with the spread treatment. The spraying fluid also contained surfactants and a UV filter.
    Improving the coloration at Jonagold is a very important advantage for the grower. Only well-colored fruits achieve a good price. In addition, it is also important to harvest these colored fruits as early as possible because then the fruit quality (hardness, shelf life, storage options) is much better. The more fruits you can harvest in the first harvest, the better. Moreover, if more fruits can be harvested in the first harvest, the remaining, not yet colored, fruits will be easier to color and therefore of a better quality.
    Finally, being able to harvest the fruit earlier will also have an important positive influence on the flowerbed quality of the following year. Fruits that have to linger for a long time generally reduce the production of the following year considerably.
    The apples from the trees in the test field were harvested in 3 times. Glutamine was used as an active substance, in the first test 2 weeks before the probable first picking date, and in the second test first 2 weeks and then another 1 week before the probable picking date. The dosages used are shown below. During the harvest, the total yield, the kilos of colored fruit that could be harvested in the first harvest, and the average fruit weight on the total harvest (in grams per apple fruit) were determined. The results are shown in Table 1, and are compared to a control without treatment.
    Table 1
    The total harvest was hardly affected, if at all, by the treatments. This application of the invention is directed to staining, not to fruit set, which is no longer influenced by the late time of treatment. More importantly, the treatments led to an increase in the useful yield at the first harvest, which is the most valuable part of the total harvest. The single treatment achieved an effect that was still relatively modest, but the effect with the spread treatment was more pronounced. An increase of 5% or 1 kg is interesting, but could be partly explained by the slightly lower yield, because with fewer fruits on the same plant the fruits color more easily. However, the effect of the double treatment cannot be explained by the slightly lower yield or by natural variation. A difference of 3 kg or 10% makes an important difference for fruit growers. As a result, it has more quality fruit that it can keep for longer. This will also result in a better coloring of the 2nd and 3rd picking, and in a better flower quality the following year.
    Example 2: Improvement of apple coloring
    In an experiment similar to that in Example 1 on Jonagold, glutamine was used twice, the first time 14 days for the picking and then a few days for the picking. The dose of treatment this time was 2 times 15 g / ha (each time with a concentration of 50 ppm weight in a spraying of 300 liters of water per ha each). The% first pluck was determined and is shown in Table 2, compared to a control test without treatment.
    Table 2
    Just as in Example 1, double treatment of glutamine gives an increase in first harvest of around 10% in absolute percent and with respect to the weight of the total harvest. Jonagold easily achieves a yield of 60 tons / ha. An increase of approximately 10% in the percentage of the first harvest therefore means an increase of at least 6 tonnes / ha of the part of the harvest with the highest quality and which offers the highest value to the grower.
    Example 3: Increase of both the yield and the coloring of apple.
    This experiment was performed on mature apple trees of the Jonagold variety, mutated Jonagored. In contrast to the two previous tests, the emphasis here is mainly on increasing the yield. To achieve this, the treatments must start much earlier in the season. The dose here is lower than in the two previous applications because the purpose here is fruit set and growth inhibition, instead of coloring. One could suffice with two treatments at the start of the growing season, but multiple applications spread over the entire growing season gives a more certain result. The applications were started in this test around the end of flowering and were repeated every 7 to 14 days, depending on the weather conditions. 7 times were treated in total, more precisely on 24 April, 7 May, 14 May, 20 May, 9 June, 16 June and on 24 June. The spraying was done with a back fogger.
    Glutamine, each at a concentration of 50 ppm by weight in 300 liters of water / ha, and thus a dosage of 15 g / ha, was used separately as well as in combination with S-abscisic acid (ABA). ' In the combination test, ABA was administered at the first 2 sprayings of the season, and each time at a concentration of 3.3 ppm in the 300 I water / ha spray liquid, corresponding to a dose of 1.0 g / ha of ABA. At the end of the season, the extension of the shoots was measured and the number of fruits per tree determined. Immediately after the end of the spraying, on 25 June, the average fruit diameter was also determined. The results are shown in Table 3.
    Table 3
    This experiment clearly shows that glutamine increases the fruit setting, which can be seen in the number of fruits per tree, and that this effect is even stronger in combination with ABA. The fruit size itself is apparently not affected at all by this. The shoot length is noticeable with glutamine alone, but is strongly inhibited in the combination.
    Glutamine alone gives an increase of 14 fruits per tree in this test. The plant density of a standard tree beard is around 1714 trees / ha. This means, at 5 apples per kilo, that this yields an additional yield of almost 5000 kg / ha, which is considerable. The combination of both products gives an even higher higher yield of more than 9900 kg / ha, or more than double the treatment with only glutamine. The advantage of the growth inhibition is not only for the fruit grower to get a higher yield more easily, but it also means a labor saving during the winter pruning and a lighter tree, which is positive for a better coloring of the fruit and for avoiding diseases.
    This test shows that glutamine at various doses can have a beneficial growth-inhibiting effect. when it is applied repeatedly to low dose.
    Example 4: Improvement of apple coloring
    In this experiment, glutamine was applied to a Jonagored parcel 4 days prior to picking, at a concentration of 8.3 ppm in 300 l / ha, which corresponds to a dose of 2.5 g / ha of glutamine. In table 4 below the% 1st pluck is shown.
    Table 4
    A treatment a few days before the picking at a very low dose clearly also increases the percentage of first picking in this test.
    Example 5: Growth inhibition with wheat
    This experiment was performed in four repetitions on wheat seedlings. Six seedlings per seed were sown in a pot and followed up. When the seedlings were approximately 15 cm high, they were treated once with the following treatments and after 10 days the growth increase was measured. The dose is given in g / ha with the conversion from the concentration being made at a use of 300 l / ha. The results are shown in Table 5.
    Table 5
    From this test it can be deduced that histidine in a very low amount has a growth-inhibiting effect on wheat. This effect is apparently also somewhat dose dependent. In further experiments with histidine only, it was noted that the strength of the effect shows a bimodal pattern as a function of the dosage, in that the response at approximately 10 g / ha was less than that in the tests with the lower (2 g) / ha) and the higher (100 g / ha) doses included in the table. This finding could be confirmed when these tests were repeated, so that apparently it is not an artifact.
    The combination of histidine with trinexapac-ethyl shows a synergistic effect.
    Example 6: Growth inhibition in barley
    This experiment was performed in four repetitions on barley seedlings. Six seedlings per seed were sown in a pot and followed up. When the seedlings were approximately 15 cm high, they were treated once with the following treatments and after 8 days the growth increase was measured. The dose is given in g / ha with the conversion from the concentration being made at a use of 300 l / ha. The results are shown in Table 6.
    Table 6
    This test also clearly shows the enhancing effect of a very low dose of glutamine on the growth inhibition of tebuconazole.
    Now that the invention has been fully described above, it will be understood by those skilled in the art that the invention can be implemented within a wide range of parameters within what is described in the following claims, without therefore departing from the spirit and scope of the invention. . It will be understood by those skilled in the art that the invention in general, as defined in the claims, also encompasses other embodiments which are not specifically shown in this document.
    权利要求:
    Claims (27)
    [1]
    Use of a composition containing single L-amino acids for influencing the life processes of crops, wherein the total amount of single L-amino acids when applying the composition to the crops is at least 0.5 g / hectare and at most 250 g / hectare, and wherein the single L-amino acids are selected from the group of glutamine, asparagine, histidine, and combinations thereof with each other and / or with arginine and / or with glutamic acid and / or with aspartic acid and / or with lysine.
    [2]
    Use according to claim 1, wherein influencing the life processes of crops is selected from increasing the yield of crops, increasing the fruit set of crops or the number of fruits or seeds, increasing the fruit or grain size of crops , the fruit size or diameter of fruits or seeds, improving the color or coloring of the fruits, influencing the ripening of crops, increasing the protein or protein content of fruits or seeds, increasing the total yield, increasing the yield of a first harvest, increasing the yield of colored fruit at a first harvest, shortening the extension of shoots, and combinations of these!
    [3]
    Use according to claim 1 or 2, wherein the total amount of the selected single L-amino acids when applying the composition is at least 1 g / hectare and at most 50 g / hectare.
    [4]
    Use according to any one of the preceding claims for inhibiting the vegetative growth of crops, wherein the total amount of the chosen single L-amino acids when applying the composition is at least 1 g / hectare and at most 30 g / hectare.
    [5]
    Use according to claim 4 for slowing down the growth of crops wherein the composition is applied at least 2 times per crop, preferably with an interval of at least 1 day and at most 6 weeks, more preferably an interval of at least 1 week and at most 3 weeks.
    [6]
    Use according to any of claims 1 to 2 for stimulating the growth of agricultural and horticultural crops, wherein the total amount of the selected single L-amino acids when applying the composition is at least 30 g / hectare and at most 100 g / hectare.
    [7]
    Use according to claim 6 for stimulating the growth of crops, wherein the composition is applied once to the crops.
    [8]
    Use according to any one of the preceding claims, wherein the composition contains substantially no multiple peptides.
    [9]
    Use according to any one of the preceding claims, wherein the composition further contains S-abscisic acid or one of its salts.
    [10]
    Use according to any one of the preceding claims, wherein the composition further comprises a growth-regulating substance selected from the group of gibberellin synthesis Inhibitors, precursors for plant hormones, or combinations thereof
    [11]
    The use according to claim 10, wherein the growth regulator is a gibberellin synthesis inhibitor selected from the group of trinexapac-ethyl, paclobutrazol, uniconazole-P, chloromequat-CI, mepiquat-CI, 2-isopropyl-4-dimethylamino-5- methylphenyl-1-piperidine-carboxylate methyl chloride (also known as "AMO-1618"), etcyclacis, ancymidol, flurprimidol, prohexadione-Ca, daminozide, 16,17-dihydorgas, chlorprofam and combinations of two or more of these.
    [12]
    The use of claim 10 wherein the growth regulator is a plant hormone precursor selected from ethephon, 1-aminocyclopropane-1-carboxylic acid (ACC) and combinations thereof.
    [13]
    Use according to any one of the preceding claims, wherein the composition further comprises a pesticide selected from the group of herbicides, insecticides, fungicides, bactericides, nematicides, algicides, molluscicides, rodenticides, virucides, substances that induce resistance in plants, biological control agents such as viruses, bacteria, nematodes, fungi and other microorganisms, repellents for birds and animals, plant growth regulators, or a combination of two or more of these.
    [14]
    The use of claim 13 wherein the pesticide is a fungicide selected from the group of the triazoles, and combinations thereof.
    [15]
    The use of claim 14 wherein the pesticide is a fungicide selected from the group of epoxiconazole, triadimenole, propiconazole, metconazole, cyproconazole, tebuconazole, flusilazole, diphenoconazole, penconazole, epoxiconazole, paclobutrazole, prothioconazole, and combinations of two or more of these.
    [16]
    Use according to any one of the preceding claims, wherein the composition further comprises one or more active substances that increase the plant's own defense mechanism, preferably jasmine acid, ethyl jasmonate or salicylic acid.
    [17]
    The use according to any one of the preceding claims, wherein the composition further comprises one or more surfactants.
    [18]
    The use according to claim 19 wherein the surfactant is selected from the group of calcium alkyl sulfonates, ethoxylated castor oil, ethoxylated alcohols or glycols or polyols, polyoxyethylated alkyl phenols, polyoxyethylated fatty acid alcohols and fatty acid amines, fatty acid, alcohol, polyglycol ether sulfates, or alkyl sulfates alkylaryl sulfonates and dispersants, ethoxylated sorbitan esters and siloxanes, or a mixture of two or more of them.
    [19]
    Use according to any one of the preceding claims, wherein the composition further contains one or more UV filtering substances.
    [20]
    Use according to any one of the preceding claims, wherein the composition further comprises an anti-foaming agent.
    [21]
    The use of claim 20, wherein the anti-foaming agent is selected from the group of silica, polydialkylsiloxanes, fluoroalkylphosphine acids or salts thereof, or a mixture of two or more of them.
    [22]
    The use according to any one of the preceding claims, wherein the composition further comprises a fertilizer.
    [23]
    Use according to any one of the preceding claims, wherein the composition is applied in a formulation selected from the group of powders, water-soluble powders, water-dispersible powders, granulates, etc. suspension concentrates, emulsifiable concentrates, concentrated emulsions, suspension emulsions, coated granules, microcapsules, tablets, water-soluble concentrates or combinations of two or more of them.
    [24]
    Use according to any one of the preceding claims wherein the composition is diluted with water.
    [25]
    Use according to any one of the preceding claims, wherein the composition is applied to the crops by spraying or spraying.
    [26]
    The use according to any one of the preceding claims wherein the crops are selected from the group of one or multi-year mono- or dicotyle crops.
    [27]
    The use of claim 26 wherein the crops are selected from fruit trees, cereals, rapeseed, beets, potatoes, and any combinations thereof.
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    同族专利:
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    EP2618664B1|2014-07-30|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    BE201000569|2010-09-23|
    BE201000569|2010-09-23|
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