![]() USE OF PROANTHOCYANIDINES TO LIMIT DENITRIFICATION
专利摘要:
The present invention uses at least one proanthocyanidin to limit the denitrification caused by microorganisms, especially present in a medium, by contacting said at least one proanthocyanidin with said microorganisms. 公开号:FR3033790A1 申请号:FR1552258 申请日:2015-03-19 公开日:2016-09-23 发明作者:Franck Poly;Florence Piola;Gilles Comte;Feth El Zahar Haichar;Clement Bardon 申请人:Centre National de la Recherche Scientifique CNRS;Universite Claude Bernard Lyon 1 UCBL; IPC主号:
专利说明:
[0001] It reduces the area of irrigators precisely to reduce denitrification in the environment, in the soil, and more. , u-uern the floors. of culture. Nitrogen is a limiting factor in plant growth (I eBauer 84. Treseder, 2008). Plant depletion therefore depends on the processes of the nitrogen which condition the conversion of nitrogen in all respects the availability of NH4 and NO3, which are the assimilated forms. 3 plants. By denuclearization processes, denitrification, carried out by so-called denitrifluent bacteria, which consists of the reduction of Nu to N20 and N2, is considered as the main biological pathway of nitrogen loss from soils. . In European agrosystems, these losses account for 59% of your system (Oenema et al., 2009). In fact, the gaseous forms 120 and N2, which are denitrified, are made inaccessible to plants, and the nitrogen losses caused by them are liberated in the conventional atmosphere. The loss of yield is offset by the addition of nitrogen fertilizer, however, this input leads to an increase in NO, a greenhouse gas 330 times more potent than CC. .. Some solutions, based on thesis, t (dimethylpyrazol (DMPP), have been proposed for Walter temporarily by inhibiting nitrification, a process upstream of the denial of ammonium transformation ( Nitrate (NO.sub.3) These compounds, activity of bacteria, soil-scouring agents and therefore limiting: formation of ammonia (NH.sub.4) in (NO.sub.3). ome of Fallopia spp., an invasive plant complex, have been described as ru .. the denitrificatior process. : these soils (Eurdon 2014) Bar. t al. 2014, urit identified in this publication,,, c, iartain number of metabolites pu: UuE-ults in tested extract of Fallopia s 3 (+) - ca echin, the (+) - epicateLnifie, 3033790 2 the piceal7rl glucoside, e resve -rolosida,, odine, the physici, resv. t between the concentration of calcium in the extracts and the denitrification. Subsequently, the inventors of this application cir-a,: -) have tested the effect of catechin, as well as Cl b "IJUS the compounds identified in this publication (epicaL - denitrification completely denitrification- A further 71 did not investigate the diagnosis and the inventors found that other molecules still identified, the proanthocyanins, were responsible for the infection. These compounds have little or no effect on the activity of the enzymes of the respiratory system, which is important for the growth of soil organisms. the presence of proanthocyanidin in the presence of a proanthocyanidin, which is caused by the organism, by the action of proanthocyanidin, with said microorganisms. The denitrifying origin, which is reduced in the cradle, of the invention, is present in a medium. The microorganisms will then be present in the medium with the p: oanthocyanidin. In this case, the proanthocyanic mi contact with the medium r thus, with the micro targeting: in some cases, the neose n contact proanthocyandrr, ', Ib utmes will occur following phenorratte I diffusion to thocyanate the medium. The medium (with TP, and proanthoyanidine is called Intact medium called treated medium), can be in medium soil, and soil G, Iture, compost manure, compost, ca station o, euration , sediments, still know a medium Ariodine hfiFints -, and con té, of.-técnine denied the .unee 1X Hirement: = - se.ntes in the extreme, 73it '3033790 Przip' such qL. i .aqucux. of the water and wastewater type, water treatment plant, whether listed as part of the invention. the contacting of proanthocyanidin with the mouse must be carried out completely. Suitable technique, noting, with hydrogen peroxide on said medium or by blending with the time brought into contact with the micropermets. the microorganism effect corresponds to the desired duration of the limitation of denitrification. In the experimental setting, one or more proanilhin, 3-nidine (s) is (are) used (limiting the denitrification by In particular, such microorganisms possess the co.OD10 and nitrite reductase genes, such microorganisms have the ability to reduce the amount of nutrients in the medium treated. -, r't -nplons such as Cylindrocarpon tonkinense, Fusarium oxysporum or LIG.7 bacteria of the genera Pseudonomas, Bacillus, Burkholderia, Achromobacter, Ochrobactrum, Citrobacter, Paracoccus, Micrococcus, such as the species Pseudomonas brassicacearum, Pseudomonas stutzeri, Pseudomonas alkaligenes, Pseudomonas fluorescens, Burkholderia, vietnamiensis, Achromobacter xylosoxidans, Paracoccus denitrificans, Bacillus cereus, known to be denitrifying series. More often present: The contacting of the organisms is carried out so as to obtain a decrease, denitMcation caused by the microorganisms having one or in other words (7. to inhibit at least the elimination of the denitrifying activity of the nits. In the context of the invention, such a limitation, reduction or reduction is to be determined by -. to the emission of Nn N- and / or to: ... L ation 30 (trans mation in N20 which is in contact with the relevant mechanisms with proanthocyanidine.) In order to evaluate the percentage inhibition of Denitrification, de is obtained measurement of - 120 + N2, a presence and, in the absence, of prde .blocyaPci which allows to obtain! 7 a percenence ----- !. inhibition of the denitrification corresponding to (emission Cë N20 presence of proanthocyanidin) N20 + erythrocyte in ehsen.:2 proanthocyanidin) * 100. denitrification by the prcY: n -'-- H the inhil of the maxini level: -_ ,! 100%, and in particular to induce a ldra in the context of the invention a denitrification inhibition%, usually from 20 to 100%, preferably from 10 to 100%. The technique described in Dambreville et al. 2006, and used in the examples, can be used to evaluate the emission of N20 + N2. The contacting conditions and the amount of proanthocyanic acid (s) used will be adjusted by those skilled in the art to achieve the desired effect. Proarthocyanidines, also known as proanthocyanidic tannins, condensed tannins, or proanthocyanin, and flavonoids, and more specifically, polymers of hydroxyflavan-3-ol. The hydroxyflavan-3-ol monomers constituting the proanthocyarcik. have the following structure (I): wherein R1, R2, R3, R4, R5 and e, which are identical or different, are selected from hydrogen, hydroxyl groups, This pattern, therefore, is less or less hydroxylated on the A and B salts, ranging from 0 to 3 hydroxyl moieties. These hydroxides, hydroxyfavan-3, may be esterified by There are 3094,790 gallate and / or glycosylated and / or methylated groups on the rings A, B and C. There are two main types of proanthocyanidins, which can be used together in the context of the invention. these two types being defned by the bonds of being monomeric: proanthocyanidinas d. type A proanthocyanidins type B. Proanthocyanidins B, pref. In the context of the invention, there are polyhydroxyl polymers of which two monomers are connected by a single covalent between two carbons, at the 4-6 or 4-8 positions (pc7i-ions resp. two mu, - - - -, -, res), as illustrated in Formula (II) corresponds to a dimer comprising a 4-8 bond, followed by a 4-6: 2 'R link 4 -> 6 bond 2 "OH (II) with R 1, R 2, R 3, .-. 41 K R 5 and R 6, R 2 ', R 4', -5 'K and R 6', R 1, R 2 -, R 3 -, R 4 -, - 5 "K and R6", which can be the same groups or different groups representing the hydroxyl group hydrogen, a group-aate, a methyl group still an osidic group .The proantn..Dcyanidines typ, 7., A hydroxyflavan polymers 3-01 whose monomers are connected by two bonds cr-9Ientes eie thes conbones, A) position 2-7 and 4-8 (respective positions -s two monorr,), illustrated in the case of a dimer with the following formula (III) with R1, R2, R3, R4, R5 and R6, Rr, R2 ', R4', R5 'and R6', may be the same or different groups, representing hydrogen, a hydroxyl group, a gallate compound, a methyl group or a saccharide group. The proanthocyanidins which can be used in the context of the invention are composed of 2 to n monomers (hr-1yf1avan-3-O, 15 by covalent bonds previously described, in all possible combinations. one or more proanthocyanidins selected from dimers, toers and tetramers The most well known proanthocyanidins are polymers of (- +) - catechin, (- / +) - epicatec (- / +) - gallocatechin and +) - HO R6 O Liaison 4 -> 8 and 2 -> 7 2 3033790 7 allocin1 bine, D7TIS the group) roanthocyark: n1e7 ...; are found SC -aroui; For example, the prodelphinidines (prociE, procyapidines, procyanidol), and (1, r), 7 polymers of (- / +) - catechin and / or epicatellin are useful. The polymers of (- / +) echin and (- / +) - e-allocatechin by (-) - (-) - (-) or (r) of these isomers. The proanthocyanidins produced naturally can be obtained from extracts of Fallopia spp., And 10 parts from allopia can be added, identified by the inventors, or from grape pips, Pteridiurr Vivicium pp Schinopsis spp., Vicia spp., spp., Quercus spn .. No commercial proanthocyanidins, especially at L (Bordeaux, France), Organic He --b ,, ilangsha Nanjing Zelang Medical Technology Co., Ltd. (Jiangsu, Che.) In the context of the invention, preferably proanthocyanidins type B will be used in an even more preferred manner. of type B, in particular in the form of tr .. According to embodiments less proanthocyanidin used does not extract from Fallopia spp. Tale ff4 of Fallopia x bohemica, and / or in the absentee, catechin and / or en articuliers of the invention did not present under the name: Anthocyanidines, and in p -., Ucuik. ., proanthocyanidin is used, ie, reinvent, a or proanthocyanidin 1PP. ', on the rneH ,,, 1 ,,,: enclosing the microorganisms whose efl.i -, iterant is to be limited, or mixed with the latter, in the form of an aqueous solution or in the form of a powder or graft. [0002] The embodiments in which microorg T'Isras are present: 7, C "Kit now to be described in more detail. In the invention, at least one proanthocyanidin may, in particular, be used to promote plant growth on the soil of Egypt, by reducing clenitrifica caused by microorganisms having an activity r, -tkr.7,, liér. caused by the destructive effects, present in the kyanide of natural products, their use in the total environment. Urdu can be grown in organic farming. In the invention according to the invention on a sol, an isocyanidine is applied to a soil, and in particular a sc CUbi 10 for example by deposition or spraying the earth. In particular, said at least one proanthocyanidin is for denitrification caused by bact of. that Pseudomonas brassicacearum and / or Bac /// us cereus. In the case of a solution of proanthocyanidin (s), it may be ligated by spraying or any other appropriate means. The soils that can be treated in the context of the invention are, in particular, soils for rte, gardening, cereal growing, viticulture generally, soils (various plants of agronomic interest, including plants or flowers various, are grown. [0003] The effect of the proanthocyanidin (s) used on the dolphin will be obtained over a wide range of temperatures, noting the soil temperature of 0 to 50 ° C and with optimum effect a higher moisture content. capacity in the field. The amount of proanthocyanidin (s) required to obtain the desired denitrificab will be applied to the soil, the amount of which will be adapted to those skilled in the art, in particular, depending on the formulation and the rate. In particular, from 0.01 to 10 mg / g of dry soil, and preferably from 0.05 to 5 mg / g of proanthocyanidin (s), are applied. 30 solid media, other than the soil mentioned, in microorganisms may be present. [0004] The results presented in the context of the invention imply that proanthocyanidins, and in particular procyanidins, are preferred. type B, allow the process of bacterial fertilization of soils. The Res have eluted on bacteria in culture, but equaled in each case by one of the riverside and flax, with a mixture of bacteria. The use of this invention, therefore, leads to losses in the form of litter and, therefore, to the effect of the invention. It is important to reduce the need for nitrogen fertilizers in the soil. Nevertheless, proanthocyanidin (E) may have been associated, in the case of cairns, with an azo or phosphate, for example. In the context of invertebrates, it may be applied to a culture soil, in order to promote the growth of the crop by combating denitrification caused by microorganisms. in particular Bacteria present in 1E - .plication may be made without the joint application of a nitrogen fertilizer. Regarding now, the embodiments in which the microorganisms are present in a medium Iq.On 7.7.13 solid solid Hquide will be integrated in said medium. An o-n-thocyanidine (s) for imitation of the present invention will be incorporated into said incorporated amount and will be adapted by those skilled in the art. As 0.01 to 2 ,. Lie medium liquid, and preferably from 0.01 to 1 mg / L millet proanthocyanidin (s) will be incorporated. Ex- rrees, in retrial to the annexed figures, to illustrate the inventory of Tais do not have an imitative. 1: for the inhibition of the control (control-releasable) on the Pseudomonas brassicacearum of a mixture of the compounds: Fallopia x bohemica and extract of Fallopia x bohemica. The bars', /, F2r1:, correspond to the variations obtained on the diff: 3. The stars are significant from Tukey; Figure 2: Chrorr PI-Dgram 280 min of the extract Fallopia x bohemica nr,: sensing the prc.plthocyanic _s and their mco detected and their UV spectrum. proanthocyanidins FIGS. 3A to 3C: Spectr. ESI mass of Tne rneed in Fallopla x bohemica (Dimers (Figure 3A), T jure 3B), Tetramers (Figure 3C) Figure 4: Percentage of leni: ffication and respiration 10 of a) Pseudomonas arm.dt .ddi-Liaî and b) 6. cereus in function 13 concentration in purified proanthocyankints. The stars showed significant differences in averages with the control of proanthocyanidins (T ey test: <0.05). Fiaure 5: Percentage of denitrification of 15% (Ain11) and meadow soil on the basis of commercial carbon concentration. The stars indicate significant mean values, control (Tukey test). Figure 6: Percentage of InNi, r, H, FH, Soil Fccation of the Soil Ami s 7 days of incubation: 3 cape :: a ',; field) in the presence of 20 different amounts of commercially available proanidines. Etc. indicate significant differences in mean: 5 a ', • 7.2c he control (Tukey test, a <0.05). I. MI: RIELS AND [- ', IL :: .. HODES 25 A): 7 7E 3101.:1K7iIC OF PROANTI-1,3CYANIDP, TES - FRUARATION OF FALLOPIA EXTRACTS Compounds were extracted from roots and rhizomes of the genotype F x bohemica (Chrtek and Chrtkov). Field-collected zomes were planted in pots in compost v: lasmann TS3 / sand, 80/20). The rhizomes were cultured for six months in a greenhouse, under artificial light at 21 ° C. The rhizomes and roots produced were harvested, washed with water and lyophilized. Seventy-five grams of rhizomes 3033790 11 and lyophilized roots of a 7-7: JeLyser II beagle Venlo, Netherlands was suspended: 750 ml. melarua water: 'T.hanol v / v) and placed in u for 30 min. After fetlat: H. :::., N using a DC pump. and another extrudate was performed on the EVEC sample 2 x mL of pure diol. All the eluates were then mixed and dried. Then, these dry extracts were resuspended in a medium: methanol (50/50, v / v) at the concentration of 10 mg mL-1. IDENTIFICATION OF PROANTHOCYANIDINES CONTAINED IN THE EXTRACT OF F. X. BOHEMICA: The extract was analyzed using a UHPLC 12 "series ae (Agilent Technologies, Santa Clara, USA). a diode array diodes G4212'ei, r.) AD (AelleFiii: Technologies, Santa C the JF 65- 1 nt Technol es, Santa -aticli compounds was carried out on a PC PT column) Sh Eq`iy pm , 3.0 x 100 mm, Agilent Technologies, Santa ClarE at a temperature of 60 ° C. The mobile phase was a gaseous solution of 0.4% ac acid in water (solvent A) and acetonitrile. (Solvent B) The mobile phase was running at a flow rate of m / min The grainin was 0 to 2% solvaiyii B, 1.5 to min at 17% SO 2, 22 to 41 Min 17 ° / o to 100% Solvent B 41 to 41.5 ml -1.00 ° / 0 Solvent 25 B. System was previously equilibrated before each ECU The injection volume was 1 μl. have been recorded between 190 e! 7 rm and the answer to 280 nrr used for inte ESI source reports were opted for in the same way if, for example, positive mode, scan of 30 m / z spectra from 80 to 2000., 73 pillary 3.0 kV, fragmented 70 V, collision I dissebation. 1-induced dissociation; CD) 3033790 12 set at 20 eV. Nitrogen was born. Gas with a flow rate of 12 l / min and a temperature. Microcyanidines were obtained in the extract by analysis of the UV spectra, MS and MS / MS, using the MassHunter Qualitative software, A.rlysis (Agitate Techno. : es, Santa Clara, USA), the spectra obtained presented da ',', B). - PURIFICA.TJON OF PROANTHOCYA: S. DE F. x BOHEMICA ', Juanthocyanidines contained in the extract of F x bohemica were purified using a column of LH20 - phadex. Sephadex LH 20 was previously equilibrated three times and lumidifying 25 g of Sephadex LH 20 with 100 ml of 80% ethanol and then the supernatant. The F. x bohemica extract (100 ml) concentrated to 10 mg ml-1 was then added to the balanced Sephadex LH 20 and stirred for 3 min. The Sephadex loaded with extract was loaded into a Buch n glass of Sephadex LH. Was washed with 95% ethanol until the absorbance of the eluate at 280 nm was close to zero. Sephadex LH 20 was then washed with 50% acetone until Sephadex was completely washed. The 50% acetal eluate recovered was evaporated using a rotary evaporator. The dried, purified proanthocyanidines were subsequently dissolved in 10 mg.m -1 -1 in this solution being subsequently named proanthocyanidins pure Ls. This solution includes the dimeric and tetrameric FIGS. 3A and 3B, but not the catechin B monomers. COMMERCIAL SOURCE OF PROANTFIOCYANIDINES Proanthocyanidins purified from iotan seeds, Lafforh: nordeaux, France). Analysis by UHPLC made it possible for these proenzies to be unmixed with catechin or with epicatechin. [0005] 3033790 13 II. EFFECT OF PROANTHOCYANIDINES ON DENITRIFICATION: A) - THE 11TAIRES CONTENTS .. .. EXTRACTS OF FX BOK The effect of the catechin, 'épicaté (pikeid, resveratrol, emodine and physcion, identified par, ion et al (2014) as the majority compounds of the extracts of Fallopia x bohemica, were tested in a mixture on the denitrification activity of Pseudomonas brassicacearum, as described in the following paragraph. Sigma-Aldrich, Saint Louis, USA), all of these compounds were prepared in a mixture in an inethanol water solution (v / v, 50/50) at the concentration found in the extracts of Fallopia x bohemica. Bacteria in the medium are 0.0037 mg m1-1 catechin, 0.0057 mg m14 epicatecV 0.022 mg ml piclein, 0.0007 mg m1-1 resveratrol, 0.0015 mg m and 0.0047 mg m1-1 physcion ). 13) - BACTERIAL STRAINS NOW The effect of proanthocyanidines rifled from the ends. F. x 20 bohemica was tested at concentrations of 0.1; 0.07; 0.01 CU on the denitrification and the respration of Pseudomonas brassoo NFM421 and Bacillus cereus A19, two denitrifying species found in soils, for which growth medium with 23 mM K, NO3, The various proanthocyanidins, determined at an optical density of (D0.) = denitrification measurements were carried out in plasma flasks by a rubber stopper, by the determination of N 2 accumulation. replacing the air in the flasks with a mixture of he and acetylene (He / C2H 2, 90/10), each of the treatments being carried out in four replicates, the purpose of the acetylene being to block the transformation of N20 in N2, the measurement of the emmi N20 being then recognized as representative of the emission of N20 ambreville et al. [0006] Respiratory measurements were performed in sealed plasma flasks by assaying the CO2 accumulation without replacing the atmosphere of the 77 L3 N20 and the emitted CO2 were measured every two hours for 48 h and 1-5 minutes. using a microcathower (pGC-R3000, SRA instruments, Marc) Ile, France). c; COMPLEX FUELS IN SUI To test the effect of proanthocyanidins on denitrification complex communities present in the soil, commercial proanthocyanidins purified from grape seeds were used (Laffort, Bordeaux, France). Soils were harvested at Ain 11 sites (45 ° 57'53 "N, 5 ° 15'25" E) and Ain H .'-, 48'15 "N; 5 ° 10'29 "E), then sieved to 2 mm The denitrification rate was measured by emission c NO every two hours for 30 hours in anaerobiosis with a katharometer (pGC-R3000, SRA instruments, Marcy l ' Star, Franci gram of dry equivalent soil was placed in a plasma bottle sealed by a rubber stopper.The atmosphere of the vial replaced p ... H mixture He / C2I-12 mixture (90/10 v The sols were suspended in 10 ml of 0.1M phosphate buffer (NaH 2 PO 4 and NaHPO 4, pH = 7.5) supplemented with glucose of C-glucose (1-1), glutamic acid ( 0.5mg of C-glutamic acid.m1-1) and this KNO3 (20mM) The effect of proanthocyanidines on denitrification was measured for concentrations of 2.5; 1; 0.5; 0.1; 0.05, 0.01 and 0 mg by the addition of water or proanthocyanidins: 7, dyes of soil suspensions were stirred at 28 ° C all the way through 7-ice All the treatments were done in four replicates. EFFECTS OF PROANTHOCYANIDINES ON A COMPLEXITY OF SOIL COMPLEXES REPORTED IN MASS OF PROANTHOCYANIDINES IN RELATION TO A MASS OF DRY SOIL A range of active proanthocyanidin concentrations on denitrification of the soil reported in g of dry soil was carried out. The soil for this experiment is Soil Ain 11. Ten grams of dry sol were incubated in a plasma flask in the open air for 7-28 ° C at the field capacity. 1; 0.5; 0.1; 0.05; 0.01; and dry sol of commercial proanthocyanidins were added to the soil-field capacity for each trichome, 'R t4 In seven replicates, after 7 treated sols was carried out every 30 min for 6 R3000, SRA instruments, Marcy LEf was denatured, "LIU mission of N20 in anaerobi microcatharometer (pGCL plasma flasks were sealed by a rubber stopper, the atronosphere of the flasks was replaced by helium using an inerting bed The floors were supplemented with a 50 ml solution containing the equivalent of 50 pgN-KNO3 dry soil, 0.5 mg of Ca, lutamic.g-1 of dry soil and 0.5 mg of C-glucose.g-1 of dry soil 15 suL1A) -u.-S MAJORITY POSITIONS ON THE DENI PSEUDOMONASBR TRIFICATION The denitrification of Pseudomonas brassicacearum is not inhibited by the melare of the compounds ma. res (catechin, epicatechin, picteide, resveratrim emodin and physicin) in the extracts of Fallopia x bohemica, whereas a marked inheumatic effect is obtained with the extract Fallopia x bohemica for the same concentration of compounds. Thus, it appears that the inhibitory activity obtained does not imply such compounds.) The yanidines detected in IIHPLC in the extract of F. x 30 bohemica are of typE-type dimer-catechin dimer and epi: echin with maximum absorbance at 278 nrr L molecular weights. of 579,15, 867,21 and 1155,27 g mol-1 3033790 16 the ires 2 e- Dectre 3A cc I to dm Figure tétramel e). the spectrum of C) - effect of proa .... _ ... nidines FLHHLL ON DENITRIFIL ..: DENITRIFIANT BILIES It appears that - roantL, -, - yanidines purified ir significantly the denitriiiLouun of Pseudomonas brassicacearum LJ cereus, as shown by the results shown in Figure 4. For both bacterial strains, denitrification is affected up to 800%. The response to inhibition is dose-dependent between 0.01 and 2.5 mg.m1-1. EFFECT OF COMMERCIAL COMMERCIAL PR.OANTHOCY 77.2. SOIL CONDITIONS IN SUSP.E.1,; ...: 15 It has been observed that both manthocyanidines and those tested have significantly denitrification of both in suspension (Figure 5). Inhibition is dose-dependent with a maximum inhibition of as low as 0.5 mg, for AinII sol and 1 mg. m1-1 for Ain6 soil. The maximum inhibition is 85% for Ain11 and 80% for Ain6. The lowest significant effect measured was at a concentration of 0.01 mg.m1-1. E) - EFFECTS OF PROANTHOCYAN'7 '3 £ 1.JTE SOIL COMPLEX REPORTED IN MASS OF PROAFEHC REPORT TO A MASS OF DRY SOIL Commercial proanthocyanidins significantly inhibit the denitrification of soil Ainll after 7 days of contact with said proanthocyanidins (Figure 6). The inhibition is dose-dependent with a maximum of 100% inhibition achieved at 5 mg.g-1 of dry soil. The smallest significant effect was a concentration of 0.1 mg.G. F, Ilvert FZ, Count G, Me, "L71 G, Apple T, Fulialdi S, msafack N, iy F. 2014. Evid .: E .: for denitrificatio by plant secondan ,,,, .-, - abolites. Phytologist: 3trom 3K, Mattl '.) 7'4 2008. HPLC determin cf extractab [ .. ccJ unextractab, e, in plart,! - naterials. Journal of Fclod Cherl5try 56 (17): 7617-732, - Lacombe S, Sun X11, Wu VCcL 013. The effect of 10 Americdri macrocarpor.) Gold LLients, growth inhibition, membrane integrity, and injury of Escherichia coli 0157: H7 and Listeria monocytogenes in comparison to rhamnosus. Food Microbiology 34 (2) : 777-759, Lacombe A, Wu VCH, White J, Tadepalli S, Andre EE., 2012. The antimicrobial 15 .s of the lowbush blueberry (Vaccinium an (ju fractional components against foodborne pathog.,.: Conservation of probiotic Lactobacillus rhamnosus Ncrobioc 30 (1): 12, L-131, LeBauer DS 'Tr.seder KK, 2008. Nitroger ictation of net primary pr ,,, Globally distributed terrestrh osystems ecology 89 (2). ): 371-379 Oenema 0, Witzke HP, Kl imont Z, JP Lesschen, Velthof GL. .2009. 27. Agriculture Ecosystems & Envirolment 133 (3-4): 25-280-288. Christophe Dambrevil '-' ', phanie Hallet, Christoph yrcTc rv an, Jean-Claude Gclindn, Lau, IP, -oliwot 2006. Sth: -1 and aCCiViii -Df the common denitrifying,, 3ize-croppec I fertilized with composted pig rr , c. arnrviniurn nitrate, MICROBIOLOGY ECOLOGY, Volume: 56; 1: 119-131
权利要求:
Claims (3) [0001] REVENDICATIONS1. Use less proanthocyanidin ,. for denit: ica4ion caused by microorganisms, r n- Ise in contact e said. to the mons proanthocyanidin with said microorgaMitio. [0002] According to claim 1, said at least one proanthocyanidinidine is a type B oanthocyanidin. [0003] 3 - Use according to claim 1 or 2 characterized in that ricins proanthocyaniciineesi> LIU --xclusiver nun monorneres rmi catechin epicatechin. Use according to one of niiPiconoue claims 1 to 3 ctérisée in that said a n roanthocyanii is LH era, era or tetramer. 5 - Use according to any one of claims 1 to 4 characterized in that the organisms are present in a year wherein said at least priithocyanidin is present. Use according to Claim 5, characterized in that at least one proanthocyanidin is applied to said substrate, for example no deposit or spraying, the composition being in the range of from 0.01 to 20%. dry soil, and 0.5 to 5 mg / i dry solids, of proanthocyanidin (s) is applied to said soil.A use according to any one of claims 1 to 7, characterized in that said ietniii, proanthocyanidin is used to limit the denitrification of denitrifying bacteria, particularly selected from Pseudomonas brassicacearum, Pseudomonas stutzerl, Pseudomonas alcallgenes, Pseudomonas fiuorescens, Burkholderia vietnamiensis Achromobacter xylosoxidans, Paracoccus denitrificans, Bacillus cereus, 9-Utilistc any of revendiutic: 1 to 8, characterized in that 7) said (iii) is not present in the form of an extract of Fallopia spp. The use according to any one of claims 1 to 9, characterized in that said at least one proanthocyanate is used, in the absence of catechin and / or o-hysteres.
类似技术:
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同族专利:
公开号 | 公开日 FR3033790B1|2018-05-04| WO2016146955A1|2016-09-22| EP3271312A1|2018-01-24|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题 JP2000159669A|1998-11-26|2000-06-13|Mikoo:Kk|Urease inhibitor, medicine and food composition containing the inhibitor and measurement of urease activity| US20140190225A1|2004-10-04|2014-07-10|Agresearch Limited|Altering animal waste composition| EP2653038A1|2012-04-16|2013-10-23|OK Biotech ApS|Plant residues from Sapotaceae trees and uses thereof| CN108602729A|2015-07-13|2018-09-28|皮沃特生物公司|Improve the method and composition of plant trait| CN107858311B|2017-12-07|2020-11-24|江西省农业科学院畜牧兽医研究所|Achromobacter xylosoxidans X10 and application thereof| CN110257291B|2019-06-25|2021-07-23|北京大学|Achromobacter capable of tolerating nickel ion toxicity and application thereof|
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2015-12-24| PLFP| Fee payment|Year of fee payment: 2 | 2016-09-23| PLSC| Publication of the preliminary search report|Effective date: 20160923 | 2017-02-21| PLFP| Fee payment|Year of fee payment: 3 | 2018-03-06| PLFP| Fee payment|Year of fee payment: 4 | 2020-03-19| PLFP| Fee payment|Year of fee payment: 6 | 2021-03-23| PLFP| Fee payment|Year of fee payment: 7 | 2022-01-21| PLFP| Fee payment|Year of fee payment: 8 |
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申请号 | 申请日 | 专利标题 FR1552258|2015-03-19| FR1552258A|FR3033790B1|2015-03-19|2015-03-19|USE OF PROANTHOCYANIDINES TO LIMIT DENITRIFICATION|FR1552258A| FR3033790B1|2015-03-19|2015-03-19|USE OF PROANTHOCYANIDINES TO LIMIT DENITRIFICATION| PCT/FR2016/050600| WO2016146955A1|2015-03-19|2016-03-17|Use of proanthocyanidins for limiting denitrification| EP16715023.4A| EP3271312A1|2015-03-19|2016-03-17|Use of proanthocyanidins for limiting denitrification| 相关专利
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