Nitric Oxide as an Attenuator of Copper Toxicity in the concentration of Nutrients in maize Seedlings

Autores

  • Ana Ecidia de Araújo Brito Federal Rural University of the Amazon
  • Priscilla Andrade Silva Federal Rural University of the Amazon
  • Job Teixeira Oliveira UFV - DS https://orcid.org/0000-0001-9046-0382
  • Cassiano Garcia Roque Federal University of Mato Grosso do Sul https://orcid.org/0000-0001-6872-0424
  • Tulio Russino Castro Federal University of Mato Grosso do Sul https://orcid.org/0000-0002-1533-8587
  • Cândido Ferreira de Oliveira Neto Federal Rural University of the Amazon

DOI:

https://doi.org/10.13083/reveng.v32i1.16812

Palavras-chave:

Bioaccumulation, Heavy metal, adubação com micronutrientes, Zea mays L.

Resumo

The maize crop is highlighted in the worldwide and Brazilian agribusiness, presenting itself as a raw material for both human and animal nutrition. Nitric oxide (NO) stands out as a signalling molecule playing a crucial role in plant responses to abiotic stresses as caused by heavy metals. Therefore, the objective of this work was to evaluate the effect of nitric oxide on the levels of macro and micronutrients, such as cationic magnesium, calcium, iron, copper, zinc and manganese. The copper bioaccumulation and translocation factor, in the initial growth of maize seedlings were subjected to copper toxicity. The seeds were soaked for 48 hours in Germitest paper using a solution containing sodium nitroprusside Na2[Fe(CN)5NO]2H2O as a donor of nitric oxide, sodium ferrocyanide Na4Fe (CN)6 as compensator and deionized water (control). The experiment was carried out in a 4 x 3 completely randomized factorial design with 12 treatments and 8 repetitions, totaling 96 trays containing 25 seeds per repetition. The results showed that the doses of nitric oxide were not sufficient to attenuate the copper toxicity, highlighting the metal accumulation in the roots. The doses of sodium nitroprusside and sodium ferrocyanide provided toxicity, changing the mineral balance in the mobilization of macro and cationic micronutrients and their translocation to the aerial part of K9606VIP3 maize seedlings in the initial growth.

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Referências

AMEH, C.M.S.; & SAYES, C.M. The potential exposure and hazards of copper nanoparticles: a review. Environmental Toxicology and Pharmacology; v. 71; p. 103 - 220. 2019.

ASATI, A.; PICHHODE, M.; & NIKHIL, K. Effect of Heavy Metals on Plants: An Overview. International Journal of Innovation Management; v. 3; p. 56 – 66. 2016. ISSN 2319 – 4847

BÜCKER-NETO, L.; PAIVA, A.L.S.; MACHADO, R.D.; RAFAEL, A.R.A.; & MARGIS-PINHEIRO, M. Interactions between plant hormones and heavy metals responses. Genetics and Molecular Biology; v. 40; n. 1; p. 373 – 386. 2017.

BUET, A.; MORICONI, J.I.; SANTA-MARÍA, G.E.; & SIMONTACCHI, M. An exogenous source of nitric oxide modulates zinc nutritional status in wheat plants. Plant Physiology and Biochemistry; v. 83; p. 337 – 345. 2014.

CHANDRA, R.; & KUMAR, V. Phytoextraction of heavy metals by potential native plants and their microscopic observation of root growing on stabilised distillery sludge as a prospective tool for in situ phytoremediation of industrial waste. Environmental Science and Pollution Research. v. 24; p. 2605 – 2619. 2017.

Conab - Companhia Nacional de Abastecimento. Acompanhamento da Safra Brasileira de Grãos, Brasília, DF, v. 11, safra 2023/24, n. 8 oitavo levantamento, 140 p. maio 2024. https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos

DE MARCO, R.; SILVA, R.F.; SCHEID, D.L.; ROS, C.O.; & SILVA, V.R. Organics Amendment and Eucalyptus grandis for Phytostabilization on Soil Contaminated with Copper. Floresta e Ambiente; v. 24; p. 1 - 9. 2017.

DEL RIO, L.A. ROS & RNS in plant physiology: an overview. Journal of Experimental Botany; v. 66; n.10; p. 2827 - 2837. 2015. h

FENG, R.; LIAO, G.; GUO, J.; WANG, R.; XU, Y.; DING, Y.; MO, L.; FAN, Z.; & LI, N. Responses of root growth and antioxidative systems of paddy rice exposed to antimony and selenium. Envionmental and Experimental Botany; v. 122; p. 29 - 38. 2016.

FERNÁNDEZ, O.E.; BACCHETTAB, G.; LALLENAC, A.M.; NAVARROD, F.B.; ORTIZA, I.; & JIMÉNEZE, M.N. Use of BCR sequential extraction procedures for soils and plant metal transfer predictions in contaminated mine tailings in Sardinia. Journal of Geochemical Exploration; v. 172; p. 133 – 141. 2017.

FERREIRA, D.F. SISVAR: A computer analysis system to fixed effects split plot type designs: Sisvar. Brazilian Journal of Biometrics; v. 37; n. 4; 529-535. 2019. D

FRITSCHE NETO, R.; & BORÉM, A. Phenomics How Next-Generation Phenotyping is Revolutionizing Plant Breeding. Switzerland: Springer Press. 142 p. 2015. ISBN 978-3- 319-13677-6

GATTI, V. C. M.; BARATA, H. S.; SILVA, V. F. A., CUNHA, F. F., DE OLIVEIRA, R. A., DE OLIVEIRA, J. T., & SILVA, P. A. (2023). Influence of calcium on the development of corn plants grown in hydroponics. AgriEngineering, v. 5; n.1, p. 623-630. h

GOHARI, G.Z.; ALAVI, E.; ESFANDIARI, S.; PANAHIRAD, S.; HAJIHOSEINLOU, S. & FOTOPOULOS; V. Interaction between hydrogen peroxide and sodium nitroprusside following chemical priming of Ocimum basilicum L. against salt stress. Physiologia Plantarum; v. 168; p. 361 - 373. 2020.

HASANUZZAMAN, M.H.; OKU, K.; NAHAR, M.H.M.B.; BHUYAN, J.; AL, M.; & BALUSKA, M.F. Nitric oxide-induced salt stress tolerance in plants: ROS metabolism; signaling; and molecular interactions. Plant Biotechnoogy; v. 12; p. 77 - 92. 2018. h

IWAI, T.; TAKAHASHI, M.; ODA, K.; TERADA, Y.; & YOSHIDA, K.T. Dynamic changes in the distribution of minerals in relation to phytic acid accumulation during rice seed development. Plant Physiology; v. 160; p. 2007 - 2014. 2012.

KOTAPATI, K.V.; PALAKA, B.K.; & AMPASALA, D.R. Alleviation of nickel toxicity in finger millet Eleusine coracana L. germinating seedlings by exogenous application of salicylic acid and nitric oxide. The Crop Journal; v. 5; n. 3; p. 240 - 250. 2017.

KUMAR, A.; CHANDERMAN, A.; MAKOLOMAKWA, M.; PERUMAL, K.; & SINGH, S. Microbial production of phytases for combating environmental phosphate pollution and other diverse applications. Critical Reviews in Environmental Science and Technology; v. 46; p. 556 - 591. 2016.

LIU, M.; ZHANG, H.; FANG, X.; ZHANG, Y.; & JIN, C. Auxin acts downstream of ethylene and nitric oxide to regulate magnesium deficiency-induced root hair development in Arabidopsis thaliana. Plant & Cell Physiology; v. 59; p. 1452 – 1465. 2018.

LOPES, M.J.S.; DIAS FILHO, M.B.; CASTRO, T.H.R.; & SILVA, G.B. Light and plant growth promoting rhizobacteria effects on Brachiaria brizantha growth and phenotypic plasticity to shade. Grass and Forage Science; v. 73; n.2; p. 493499. 2018.

MACHADO, L. C.; PAIVA, R. C.; SOUSA, J. D. C. M. D.; COSTA, T. C.; MARTINS, J. T. D. S.; NASCIMENTO, V. R. D.; OLIVEIRA, C. F. D. Path analysis of the influence of cadmium on mahogany. Ciência Florestal, v. 34; n.1; e73800.

MARQUES, D.M.; SILVA, A.B.; MANTOVANI, J.R.; PEREIRA, D.S.; & SOUZA, T.C. Growth and physiological responses of tree species Hymenaea courbaril L.; Peltophorum dubium Spreng. Taub. and Myroxylon peruiferum L. F. exposed to different copper concentrations in the soil. Revista Árvore; v. 42; n. 2; p. 62 - 67. 2018.

MIKULA, K.; IZYDORCZYK, G.; SKRZYPCZAK, D.; MIRONIUK, M.; MOUSTAKAS, K.; WITEK-KROWIAK, A.; & CHOJNACKA, K. Controlled release micronutrient fertilizers for precision agriculture: a review. Science of The Total Environment; Amsterdam; v. 712; p. 136 - 365. 2020.

MIYAZAWA, M.; PAVAN, M.A.; MURAOKA, T.; CARMO, C.A.F.S.; & MELO, W.J. Chemical analysis of plant tissue. In: SILVA; F. C. ed. Manual analysis of soil; plant and fertilizer analyzes. 2.ed. Brasília: Embrapa technological information; Cap.1; p. 191 - 233. 2009. ISBN 978-85-7383-430-7

NAKAGAWA, J. Vigor tests based on seedling evaluation. In: KRZYZANOWSKI; F.C.; VIEIRA; R.D.; & FRANÇA-NETO; J.B. ed. Seed vigor: concepts and tests; Londrina: Abrates; p. 2:1 - 2:21. 1999. ISBN 978-65-992000-0-7

NAZIR, F.; HUSSAIN, A.; & FARIDUDDIN, Q. Hydrogen peroxide modulate photosynthesis and antioxidant systems in tomato Solanum lycopersicum L. plants under copper stress. Chemosphere; v. 230; p. 544 - 558. 2019.

NOGUEIRA, G. A. D. S.; BRITO, A. E. D. A.; RESENDE, V. N.; ALBUQUERQUE, G. D. P.; AMARANTES, C. B. D.; OLIVEIRA, J. T. D.; OLIVEIRA NETO, C. F. D. Nitrogen and carbon metabolism evaluation in paricá plants subjected to different cadmium concentrations. Biosci. j., p.1-10. 2022.

REHMAN, M.; LIU, L.; WANG, Q.; SALEEM, M.H.; BASHIR, S.; ULLAH, S.; & PENG, D. Copper environmental toxicology; recent advances; and future outlook: a review. Environmental Science and Pollution Research International; v. 26; p. 18003 - 18016. 2019.

WANG, W.H.; LUO, X.G.; LIU, L.; ZHANG, Y.; & ZHAO, H.Z. Ramie Boehmeria nivea uranium bioconcentration and tolerance attributes. Journal of Environmental Radioactivity; v. 184-185; p. 152 - 157. 2018.

XU, Q.; & ZHANG, M. Source identification and exchangeability of heavy metals accumulated in vegetable soils in the coastal plain of eastern Zhejiang province; China; Ecotoxicology and Environmental Safety; v 142; p. 410 - 416. 2017.

ZANCHETA, A.C.F.; ABREU, C.A.; ZAMBROSI, F.C.B.; ERISMANN, N.M.; & LAGÔA, A.M.A. Copper phytoextraction by different plant species grown in nutrient solution. Bragantia; v. 70; n. 4; p. 737 - 744. 2011.

ZHANG, D.; LIU, X.; MA, J.; YANG, H.; & ZHANG, W.; LI, C. Genotypic differences and glutathione metabolism response in wheat exposed to coppe. Environmental and Experimental Botany; v. 157; p. 250 - 259. 2019.

ZHU, C.Q.; ZHANG, J.H.; & ZHU, L.F. NH4 + facilitates the reuse of iron in the cell walls of rice Oryza sativa roots in conditions of iron deficiency. Environmental and Experimental Botany; v. 151; p. 21 – 31. 2018.

ZHU, X.F.; ZHU, C.Q.; WANG, C.; DONG, X.Y.; & SHEN, R.F. Nitric oxide acts upstream of ethylene in cell wall phosphorus reutilization in phosphorus-deficient rice. Journal of Experimental Botany; v. 68; n. 3; p. 753 – 760. 2017.

ZVOBGO, G.; LWALABA, J.L.W.; SEHAR, S.; MAPODZEKE, J.M.; SHAMSI, I.H.; & ZHANG, G. The Tolerance Index and Translocation Factor were Used to Identify the Barley Genotypes with High Arsenic Stress Tolerance. Communications in Soil Science and Plant Analysis; v. 49; p. 50 – 62. 2018.

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Publicado

2024-07-11

Como Citar

Brito, A. E. de A., Silva, P. A., Oliveira, J. T., Roque, C. G., Castro, T. R., & Oliveira Neto, C. F. de. (2024). Nitric Oxide as an Attenuator of Copper Toxicity in the concentration of Nutrients in maize Seedlings. Revista Engenharia Na Agricultura - REVENG, 32(Contínua), 16–26. https://doi.org/10.13083/reveng.v32i1.16812

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