Identyfikatory
Warianty tytułu
The use of amino acid fertilizers in agriculture
Języki publikacji
Abstrakty
Nawozy aminokwasowe (AAF) zawierające hydrolizaty białkowe i/lub aminokwasy są znanymi biostymulatorami roślin. W pracy opisano funkcje wybranych aminokwasów w roślinach oraz omówiono wpływ AAF na wzrost i jakość plonu roślin uprawnych. Omówiono również zastosowanie nawozów aminokwasowych w łagodzeniu skutków abiotycznego i biotycznego stresu roślin.
Amino acid fertilizers (AAF) containing protein hydrolysates and/or amino acids are known as plant biostimulants. This paper describes the functions of selected amino acids in plants and discusses the influence of AAF on the growth and quality of crop plants. The use of amino acid fertilizers in alleviating the effects of abiotic and biotic stress of plants was also discussed.
Czasopismo
Rocznik
Tom
Strony
144--157
Opis fizyczny
Bibliogr. 64 poz., tab.
Twórcy
autor
- Sieć Badawcza Łukasiewicz – Instytut Przemysłu Skórzanego
autor
- Sieć Badawcza Łukasiewicz – Instytut Przemysłu Skórzanego
Bibliografia
- [1] Piwowar A.: Zarys problematyki nawożenia w zrównoważonym rozwoju rolnictwa w Polsce, Ekonomia i Środowisko 1, 2013, str. 143-155.
- [2] Katyal J. C., Datta S. P.: Role of micronutrients in ensuring optimum use of macronutrients, IFA International Symposium on Micronutrients, New Delhi, India 2004, str. 12.
- [3] Spiak Z.: Jak należy nawozić mikroelementami – warunki stosowania i doboru mikroelementów, Wieś Jutra 11, 2001, str. 15-17.
- [4] Podleśna A.: Źródła składników pokarmowych dla roślin we współczesnym rolnictwie, Wieś Jutra 7, 2006, str. 6-8.
- [5] Antonkiewicz J., Łabętowicz J.: Innowacje chemiczne w odżywianiu roślin od starożytnej Grecji i Rzymu po czasy najnowsze. Praca przeglądowa, Agronomy Science 72, 2017, str. 1-18.
- [6] Ditta A., Arshad M., Ibrahim M.: Nanoparticles in sustainable agricultural crop production: applications and perspectives, Nanotechnology and Plant Sciences, 2015, str. 55-75.
- [7] Calvo P., Nelson L., Kloepper J. W.: Agricultural uses of plant biostimulants, Plant Soil 383, 2014, str. 3-41.
- [8] McMurry J.: Chemia organiczna, Wydawnictwo Naukowe PWN, Warszawa 2007.
- [9] Grishin D. V., Zhdanov D. D., Pokrovskaya M. V., Sokolov N. N.: D-aminoacids in nature, Agriculture and Biomedicine 13 (1), 2019, str. 11-22.
- [10] Colla G., Rouphael Y., Canaguier R., Svecova E., Cardarelli, M.: Biostimulant action of a plant-derived protein hydrolysate produced through enzymatic hydrolysis, Frontiers in Plant Science 5, 2014, str. 448.
- [11] Ertani A., Cavani L., Pizzeghello D., Brandellero E., Altissimo A., Ciavatta C., Nardi S.: Biostimulant activities of two protein hydrolysates on the growth and nitrogen metabolism in maize seedlings, Journal of Plant Nutrition and Soil Science 172, 2009, str. 237-244.
- [12] Ławińska K., Lasoń-Rydel M., Gendaszewska D., Grzesiak E., Sieczyńska K., Gaidau C., Epure D. G., Obraniak A.: Coating of seeds with collagen hydrolysates from leather waste, Fibres and Textiles in Eastern Europe 136, 2019, str. 59-64.
- [13] Cavani L., Halle A. T., Richard C., Ciavatta C.: Photosensitizing properties of protein hydrolysate-based fertilizers, Journal of Agricultural and Food Chemistry 54, 2006, str. 9160-9167.
- [14] Colla G., Nardi S., Cardarelli M., Ertani A., Lucini L., Canaguier R., Rouphael Y.: Protein hydrolysates as biostimulants in horticulture, Scienta Horticulturae 96, 2015, str. 28-38.
- [15] Colla G., Hoagland L., Ruzzi M., Cardarelli M., Bonini P., Canaguier R., Rouphael Y.: Biostimulant action of protein hydrolysates: unraveling their effects on plant physiology and microbiome, Frontiers in Plant Science 8, 2017, str. 2202.
- [16] Jie M., Raza W., Xu Y. C., Shen Q. R.: Preparation and optimization of amino acid chelated micronutrient fertilizer by hydrolyzation of chicken waste feathers and the effects on growth of rice, Journal of Plant Nutrition and Soil Science 31, 2008, str. 571-582.
- [17] Zhang F., Meng X., Feng C., Ran W., Yu G., Zhang Y., Shen Q.: Hydrolytic amino acids employed as a novel organic nitrogen source for the preparation of PGPF-containing bio-organic fertilizer for plant growth promotion and characterization of substance transformation during BOF production, PLOS One 11, 2016.
- [18] Csapó J., Kiss-Csapó Zs., Albert Cs., Lóki K.: Hydrolysis of proteins performed at higher temperature and for short times with reduced racemization, in order to determine the enantiomers of D- and L- amino acids; Analytica Chimica Acta 1, 2008, str. 31-48.
- [19] Bhaskar N., Benila T., Radha C., Lalitha R. G.: Optimization of enzymatic hydrolysis of visceral waste proteins of Catla (Catla catla) for preparing protein hydrolysate using a commercial protease, Bioresource Technology 99, 2008, str. 335-343.
- [20] Friedman M.: Chemistry, nutrition, and microbiology of D-aminoacids, Journal of Agricultural and Food Chemistry, 47, 1999, 3457-3479.
- [21] Brückner H., Westhauser T.: Chromatographic determination of L- and D-amino acids in plants, Amino Acids 24, 2003, str. 43-55.
- [22] Rai V. K.: Role of amino acids in plant responses to stress, Biologia Plantarum 45, 2002, str. 471-478.
- [23] Popko M., Michalak I., Wilk R., Gramza M., Chojnacka K., Górecki H.: Effect of the new plant growth biostimulants based on amino acids on yield and grain quality of winter wheat, Molecules 23, 2018, str. 470.
- [24] Shukla R., Sharma Y. K., Shukla A. K.: Molecular mechanism of nutrient uptake in plants, International Journal of Current Research and Academic Review 2, 2014, str. 142-154.
- [25] Davies D. D.: Physiological aspects of protein turn-over, Encyclopedia of Plant Physiology 45, 1982, str. 481-487.
- [26] Radkowski A., Radkowska I., Godyń D.: Effects of fertilization with an amino acid preparation on the dry matter yield and chemical composition of meadow plants, Journal of Elementology 23, 2018, str. 947-958.
- [27] Kowalczyk K., Zielony T.: Effect of Aminoplant and Asahi on yield and quality of lettuce grown on rockwool [w:] Biostimulators in modern agriculture. General aspects. H. Gawrońska (red.), Wieś Jutra, Warszawa 2008.
- [28] Ali Q., Athar H., Haider M. Shahid S., Aslam N., Shehzad F., Naseem J., Ashraf R., Ali A., Hussain S.: Role of amino acids in improving abiotic stress tolerance to plants [w:] Plant Tolerance to Environmental Stress, CRC Press, Boca Raton 2019, str. 175-204.
- [29] Meijer A. J.: Amino acids as regulators and components of nonproteinogenic pathways, The Journal of Nutrition 39, 2003, str. 2057-2062.
- [30] Khan Sh., Yu H., Li Q., Gao Y., Sallam B. N., Wang H., Liu P., Jiang W.: Exogenous application of amino acids improves the growth and yield of lettuce by enhancing photosynthetic assimilation and nutrient availability, Agronomy 9, 2019, str. 266.
- [31] Tegeder M., Rentsch D.: Uptake and partitioning of amino acids and peptides, Molecular Plant 3, 2010, str. 997– 1011.
- [32] Mohamed A. M.: Effect of some bio-chemical fertilization regimes on yield of maize – master thesis, 2006, Zagazig University, str. 70-177.
- [33] Azimi M. S., Daneshian J., Sayfzadeh S., Zare, S.: Evaluation of amino acid and salicylic acid application on yield and growth of wheat under water deficit, International Journal of Agronomy and Crop Science 5, 2013, str. 816-819.
- [34] Baqir H. A., Zeboon N. H., Al-behadili A. A. J.: The role and importance of amino acids within plants: a review, Plant Archives 19, 2019, str. 1402-1410.
- [35] Souri M. K.: Aminochelate fertilizers: the new approach to the old problem; a review, Open Agriculture 1, 2016, str. 118–123.
- [36] Levitt J.: Response of plant to environmental stress Volume 1: chilling, freezing and high temperature stress, Academic Press, California 1980.
- [37] Zeier J.: New insights into the regulation of plant immunity by amino acid metabolic pathways, Plant Cell and Environment 36, 2013, str. 2085-2103.
- [38] Mattioli R., Biancucci M., El Shall A., Mosca L., Costantino P., Funck D., Trovato M.: Proline synthesis in developing microspores is required for pollen development and fertility, BMC Plant Biology 18, 2018, str. 356.
- [39] Hayat S., Hayat Q., Alyemeni M. N., Wani A. S., Pichtel J., Ahmad A.: Role of proline under changing environments: a review, Plant Signaling and Behavior 7, 2012, str. 1456-1466.
- [40] Zhao Y.: Auxin Biosynthesis, Arabidopsis Book 2014.
- [41] Drobek M., Frąc M., Cybulska J.: Plant biostimulants: importance of the quality and yield of horticultural crops and the improvement of plant tolerance to abiotic stress– a review, Agronomy 9, 2019, str. 335.
- [42] Van Oosten M. J., Pepe O., De Pascale S., Silletti S., Maggio A.:. The role of biostimulants and bioeffectors as alleviators of abiotic stress in crop plants, Chemical and Biological Technologies in Agriculture 4, 2017, str. 1-12.
- [43] Näsholm T., Kielland K., Ganeteg U.: Uptake of organic nitrogen by plants, New Phytologist 182, 2009, str. 31-48.
- [44] Amirkhani M., Netravali A. N., Huang W.: Investigation of soy protein–based biostimulant seed coating for broccoli seedling and plant growth enhancement, Hortscience 51, 2016, str. 1121–1126.
- [45] Wilson H. T., Xu K., Taylor A. G.: Transcriptome analysis of gelatin seed treatment as a biostimulant of cucumber plant growth, The Scientific World Journal 2015, 2015, str. 1-14.
- [45] Koukounararas A., Tsouvaltzis P., Siomos A. S.: Effect of root and foliar application of amino acids on the growth and yield of greenhouse tomato in different fertilization levels, Journal of Food, Agriculture and Environment 11, 2013, str. 644-648.
- [47] Parrado J., BautistaJ., RomeroE. J., Garcia-Martinez A. M., Friaza V., Tejada M.: Production of a carob enzymatic extract: potential use as a biofertilizer, Bioresource Technology 99, 2008, str. 2312-2318.
- [48] Morales-Pajan J. P., Stall, W.: Passion fruit (Passiflora edulis) trans plant production and affected by selected biostimulants, Proceedings of the Florida State Horticultural Society 117, 2004, str. 224-227.
- [49] Gurav R. G., Jadhav, J. P.: A novel source of biofertilizer from feather biomass for banana cultivation, Environmental Science and Pollution Research 20, 2013, str. 4532-4539.
- [50] Parrado J., Escudero-Gilete M. L., Friaza V., Garcia-Martinez A., González- Miret M. L., Bautista J. D., Heredia F. J.: Enzymatic vegetable extract with bioactive components: influence of fertilizer on the colour and anthocyanins of red grapes, Journal of the Science of Food and Agriculture 87, 2007, str. 2310-2318.
- [51] Tejada M., Benitez C., Gomez I., Parrado J.: Use of biostimulants on soil restoration: effects on soil biochemical properties and microbial community, Applied Soil Ecology 49, 2011, str. 11-17.
- [52] Erdal S., Aydın M., Genisel M., Taspinar M. S., Dumlupinar R., Kaya O., Gorcek Z.: Effects of salicylic acid on wheat salt sensitivity, African Journal of Biotechnology 30, 2011, str. 5713-5718.
- [53] Sadak M. S. H., Abdelhamid M. T., Schmidhalter U.: Effect of foliar application of aminoacids on plant yield and some physiological parameters in bean plants irrigated with seawater, Acta Biologica Colombiana 20, 2015, str. 141-152.
- [54] Ertani A., Schiavon M., Muscolo A., Nardi S.: Alfalfa plant-derived biostimulant stimulate short-term growth of salt stressed Zea mays L. Plants, Plant Soils 364, 2012, str. 145-58.
- [55] Lucini L., Rouphael Y., Cardarelli M., Canguier R., Kumar P., Colla, G.: The effect of a plant-derived biostimulant on metabolic profiling and crop performance of lettuce grown under saline conditions, Scientia Horticulturae 182, 2015, str. 124-133.
- [56] Cuin T. A., Shabala S.: Amino acids regulate salinity-induced potassium efflux in barley root epidermis, Planta 225, 2007, str. 753-61.
- [57] Hammad S. A. R., Ali O. A. M.: Physiological and biochemical studies on drought tolerance of wheat plants by application of amino acids and yeast extract, Annals of Agricultural Sciences 59, 2014, str. 133-145.
- [58] Pooryousef M., Alizadeh K.: Effect of foliar application of free amino acids on alfalfa performance under rainfed conditions, Research on Crops 15, 2014, str. 254-258.
- [59] Botta A.: Enhancing plant tolerance to temperature stress with amino acids: an approach to their mode of action, Acta Horticulturae 1009, 2013, str. 29-35.
- [60] Kauffman G. L., Kneival D. P., Watschke T. L.: Effects of biostimulant on the heat tolerance associated with photosynthetic capacity, membrane thermostability and polphenol production of perennial ryegrass, Crop Science 47, 2007, str. 261-267.
- [61] Parađiković N., Vinković T., Vinković Vrček I., Žuntar I., Bojić M., Medić-Šarić M.: Effect of natural biostimulants on yield and nutritional quality: an example of sweet yellow pepper (Capsicum annuum L.) plants, Journal of the Science of Food and Agriculturae 91, 2011, str. 2146-2152.
- [62] Wojdyła A. T., Sobolewski J.: Możliwość wykorzystania środków zawierających aminokwasy w ochronie fasoli przed zgnilizną twardzikową, Zeszyty Naukowe Instytutu Ogrodnictwa 24, 2016, str. 131-140.
- [63] Wojdyła A.T.: 2017. Możliwość wykorzystania środków zawierających aminokwasy w ochronie róż przed Podosphaera pannosa oraz ich wpływ na rozwój roślin, Progress in Plant Protection 57, 2017, str. 82-87.
- [64] Wojtyła A. T.: Możliwość wykorzystania środków zawierających aminokwasy w ochronie bratka ogrodowego (Viola wittrockiana) przed Colletotrichum violae tricoloris oraz ich wpływ na wzrost roślin, Progress in Plant Protection 58, 2018, str. 107-114.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Praca została wykonana w ramach subwencji pt.: „Wpływ zastosowania biostymulatora na plonowanie kukurydzy zwyczajnej (Zea mays L.)”, Ł–IPS (PS/LD20/229.05/30).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-1605234f-147a-447e-8aac-fd104a0468e6