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dc.creatorFreitas, Douglas Siqueira-
dc.creatorRodak, Bruna Wurr-
dc.creatorCarneiro, Marco Aurélio Carbone-
dc.creatorGuilherme, Luiz Roberto Guimarães-
dc.date.accessioned2020-05-12T11:37:01Z-
dc.date.available2020-05-12T11:37:01Z-
dc.date.issued2019-
dc.identifier.citationFREITAS, D. S. et al. How does Ni fertilization affect a responsive soybean genotype? A dose study. Plant Soil, [S.I.], v. 441, p. 567-586, 2019.pt_BR
dc.identifier.urihttps://link.springer.com/article/10.1007/s11104-019-04146-2pt_BR
dc.identifier.urihttp://repositorio.ufla.br/jspui/handle/1/40807-
dc.description.abstractBackground and aims: Nickel affects a wide range of physiological processes in plants, which may result in higher growth and yield. Recent studies demonstrate that soybean genotypes show positive, but differential, responsiveness to Ni-fertilization. Thus, this study investigated the impact of supplying this micronutrient to a soybean genotype previously known to be responsive to Ni-fertilization, with the aim of identifying a suitable range of Ni for the adequate development of this crop plant. Methods: We tested, under greenhouse conditions, the effect of applying six Ni doses (0.00, 0.25, 0.50, 1.00, 3.00, and 9.00 mg kg−1) via soil to a commonly-grown soybean genotype. Soybean plants were evaluated for nutrition, physiology, growth, N-urea metabolism, and efficiency of the N2 fixation process. Results: Nickel supply positively affected the physiology and growth of the genotype, indicating a deficiency of this micronutrient. Ni-application also led to an increased N metabolism; in particular, nodules had a higher nitrogenase activity associated with greater Ni-concentrations in areas of highest metabolic activity. By exploiting the data acquired in a growth response curve (grain yield x Ni concentration), the greatest beneficial effects were observed following an application of 3.35 mg of Ni kg−1. A supply of more than 4.25 mg of Ni kg−1 was toxic to the plants. Conclusions: Ni-fertilization improved the N-mineral and N-biological assimilation pathways of soybean, optimizing the overall development of the plants. Through this study, we defined a reliable and adequate Ni-range for both plants and soil, which can be used as a basis for agricultural practice. Moreover, supplying plants with Ni at the recommended doses was revealed to be safe for in natura human consumption of soybean grains; however, more studies are required to establish the appropriate safety limit standards for soybean-based food products.pt_BR
dc.languageenpt_BR
dc.publisherSpringer Naturept_BR
dc.rightsrestrictAccesspt_BR
dc.sourcePlant Soilpt_BR
dc.subjectGlycine maxpt_BR
dc.subjectUrease activitypt_BR
dc.subjectN2-fixationpt_BR
dc.subjectNickel deficiencypt_BR
dc.subjectNickel toxicitypt_BR
dc.subjectNodulationpt_BR
dc.subjectSoja - Adubos e fertilizantespt_BR
dc.subjectFertilização nitrogenadapt_BR
dc.subjectUreasept_BR
dc.subjectNitrogênio - Fixaçãopt_BR
dc.subjectDeficiência de níquelpt_BR
dc.subjectNíquel - Toxicidadept_BR
dc.subjectNodulaçãopt_BR
dc.titleHow does Ni fertilization affect a responsive soybean genotype? A dose studypt_BR
dc.typeArtigopt_BR
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