Okra cultivation under irrigation with saline water and foliar application of hydrogen peroxide

Roque, Iara Almeida; Soares, Lauriane Almeida dos Anjos; Lima, Geovani Soares de; Lopes, Iracy Amélia Pereira; Silva, Luderlândio de Andrade; Dantas, Maíla Vieira; Torres, Rafaela Aparecida Frazão; Lima, Vera Lúcia Antunes de

doi:10.4136/ambi-agua.2980

Abstract

Foliar application of hydrogen peroxide can induce plant defense mechanisms against salt stress, favoring plant acclimation in regions with qualitative and quantitative scarcity of water resources, such as the Brazilian semi-arid region. From this perspective, this study aimed to evaluate the effects of foliar hydrogen peroxide application on chlorophyll a fluorescence, growth, and production of okra under irrigation with saline water. The experiment was conducted under field conditions in Pombal, PB, using a randomized block design with a 5 × 3 factorial arrangement corresponding to five electrical conductivity levels of water - ECw (0.3, 1.3, 2.3, 3.3, and 4.3 dS m^-1) and three hydrogen peroxide concentrations - H₂O₂ (0, 25, and 50 μM), with five replications. Irrigation water salinity levels up to 2.2 dS m^-1 increase the maximum fluorescence of okra plants 75 days after transplanting. Foliar application of 50 µM hydrogen peroxide proved to be beneficial for plant height, stem diameter, stem dry matter, root dry matter, and total dry matter of okra when plants were grown in low-salinity water. The hydrogen peroxide concentrations of 25 and 50 µM increased the number of leaves. However, these concentrations reduced the average weight of the okra dry fruits. Foliar application with 50 µM hydrogen peroxide had a significant effect on the dry leaf phytomass of the okra cv. Clemson American 80 regardless of the electrical conductivity of irrigation water. Foliar hydrogen peroxide application at concentrations up to 50 µM intensifies the deleterious effects of salt stress on the total weight of dried okra fruits.

Keywords:
Abelmoschus esculentus L.; acclimation; salt stress

Resumo

A aplicação foliar de peróxido de hidrogênio pode induzir mecanismos de defesa das plantas contra o estresse salino, favorecendo a aclimatação das plantas em regiões com escassez qualitativa e quantitativa de recursos hídricos, como o semiárido brasileiro. Nessa perspectiva, este estudo teve como objetivo avaliar os efeitos da aplicação foliar de peróxido de hidrogênio na fluorescência da clorofila a, no crescimento e na produção de quiabo sob irrigação com água salina. O experimento foi conduzido em condições de campo em Pombal, PB, utilizando delineamento em blocos casualizados com arranjo fatorial 5 × 3 correspondendo a cinco níveis de condutividade elétrica da água - CEa (0,3, 1,3, 2,3, 3,3 e 4,3 dS m-1) e três concentrações de peróxido de hidrogênio - H2O2 (0, 25 e 50 μM), com cinco repetições. Níveis de salinidade da água de irrigação de até 2,2 dS m-1 aumentam a fluorescência máxima das plantas de quiabo 75 dias após o transplantio. A aplicação foliar de 50 µM de peróxido de hidrogênio provou ser benéfica para a altura da planta, diâmetro do caule, matéria seca do caule, matéria seca da raiz e matéria seca total do quiabo quando as plantas foram cultivadas em água com baixa salinidade. As concentrações de peróxido de hidrogênio de 25 e 50 µM aumentaram o número de folhas. Porém, essas concentrações reduziram o peso médio dos frutos secos de quiabo. A aplicação foliar com 50 µM de peróxido de hidrogênio teve efeito significativo na fitomassa seca foliar do quiabeiro cv. Clemson American 80 independentemente da condutividade elétrica da água de irrigação. A aplicação foliar de peróxido de hidrogênio em concentrações de até 50 µM intensifica os efeitos deletérios do estresse salino sobre o peso total dos frutos secos de quiabo.

Palavras-chave:
Abelmoschus esculentus L; aclimatação; estresse salino

1. INTRODUCTION

Okra (Abelmoschus esculentus (L.) Moench) is a crop of great socio economic importance for northeastern Brazil, being found in virtually all tropical and subtropical areas and standing out for its early vegetative cycle, high yield, low production costs, and high food and nutritional value. It is a vegetable source of fiber, vitamin A, C, B6, calcium, iron, magnesium, phosphorus, sodium and potassium (Couto and Coqueiro, 2020COUTO, L. A.; COQUEIRO, J. S. Desenvolvimento de farinha de quiabo orgânico. Profiscientia, v. 14, n. 1, p. 194-208, 2020.; Soares et al., 2020SOARES, L. A. dos A.; SILVA, R. G. da; LIMA, G, S. de; SALES, G. N. B.; COSTA, F. B. da.; NETA, A. M. de S. S. et al. Preservation by lactic fermentation and physicochemical characterization of okra produced under water salinity and potassium fertilization. Semina: Ciências Agrárias, v. 41, n. 6, p. 2495-2508, 2020. https://doi.org/10.5433/1679-0359.2020v41n6p2495
https://doi.org/10.5433/1679-0359.2020v4... )

Although okra plants are adapted to different soil conditions of the semi-arid region of Brazil (Modesto et al., 2019MODESTO, F. J. N.; SANTOS, M. A. C. dos; SOARES, T. M.; SANTOS, E. P. M. dos. Crescimento, produção e consumo hídrico do quiabeiro submetido à salinidade em condições hidropônicas. Irriga, v. 24, n. 1, p. 86-97, 2019. https://doi.org/10.15809/irriga.2019v24n1p86-97
https://doi.org/10.15809/irriga.2019v24n... ; Lima et al., 2020LIMA, G. S. de; SOUZA, C. M. A. de; NOBRE, R. G. ; SOARES, L. A. dos A.; GHEYI, H. R.; CAVALCANTE, L. F. et al. Gas exchanges, growth and production of okra cultivated with saline water and silicon fertilization. Semina: Ciências Agrárias, v. 41, p. 1937-1950, 2020. https://doi.org/10.5433/1679-0359.2020v41n5Supl1p1937
https://doi.org/10.5433/1679-0359.2020v4... ), this crop faces production limitations due to the qualitative and quantitative scarcity of water resources (Goes et al., 2020GOES, G. F.; GUILHERME, J. M. da S.; SALES, J. R. da S.; SOUSA, G. G. de. Ambiência agrícola e estresse salino em mudas de quiabo. Revista Brasileira de Agricultura Irrigada, v. 13, n. 5, p. 3646-3655, 2020. https://doi.org/10.7127/rbai.v13n5001125
https://doi.org/10.7127/rbai.v13n5001125... ) as a result of long drought periods and high evapotranspiration rates (Lopes et al., 2020LOPES, J. R. A.; BEZERRA, J. M.; ALMEIDA, N. M. D. P.; GONÇALVES, G. L.; MENDONÇA, S. dos. S. C. Águas subterrâneas como alternativa de subsistência em uma comunidade rural no semiárido brasileiro. Águas Subterrâneas, v. 34, n. 2, p. 1-6, 2020. https://doi.org/10.14295/ras.v34i2.29889
https://doi.org/10.14295/ras.v34i2.29889... ).

Most vegetables are glycophytic, showing changes in the photosynthetic process and allocation of photoassimilates due to osmotic and ionic effects, with impacts on plant growth and production (Oliveira et al., 2017OLIVEIRA, W. J. de; SOUZA, E. R. de; CUNHA, J. C.; SILVA, E. F. de F.; VELOSO, V. de L. Leaf gas exchange in cowpea and CO2 efflux in soil irrigated with saline water. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 21, n. 1, p. 32-37, 2017. https://doi.org/10.1590/1807-1929/agriambi.v21n1p32-37
https://doi.org/10.1590/1807-1929/agriam... ; Alvarenga et al., 2019ALVARENGA, C. F de S.; SILVA, E. M. da; NOBRE, R. G.; GHEYI, H. R.; LIMA, G. S. de.; SILVA, L. de A. Morfofisiologia de aceroleira irrigada com águas salinas sob combinações de doses de nitrogênio e potássio. Revista de Ciências Agrárias, v. 42, n. 1, p. 191-200, 2019. https://doi.org/10.19084/RCA18215
https://doi.org/10.19084/RCA18215... ). Okra plants, in turn, have a threshold salinity of 1.3 dS m^-1 in the saturation extract (Campos, 2013CAMPOS, M. S. Balanço de água e sais no solo cultivado com quiabeiro irrigado sob diferentes lâminas de água salobra. 2013. 74f. Dissertação (Mestrado em Irrigação e Drenagem) - Universidade Federal Rural do Semiárido, Mossoró, 2013. ; Gheyi et al., 2016GHEYI, H. R.; DIAS, N. da S.; LACERDA, C. F. de; GOMES FILHO, E. Manejo da salinidade na agricultura: Estudos básicos e aplicados. 2. ed. Fortaleza: INCTSal, 2016. 504 p.), but can be cultivated under higher salinity levels as long as in association with substances that mitigate the deleterious effects of salt stress in plants (Zafar et al., 2021ZAFAR, S.; HASNAIN, Z.; ASLAM, N.; MUMTAZ, S.; JAAFAR, H. Z.; WAHAB, P. E. M. et al. Impact of Zn nanoparticles synthesized via green and chemical approach on okra (Abelmoschus esculentus L.) growth under salt stress. Sustainability, v. 13, n. 7, p. 1-2, 2021. https://doi.org/10.3390/su13073694
https://doi.org/10.3390/su13073694... ; Mendonça et al., 2022aMENDONÇA, A. J. T.; SILVA, A. A. R. da.; LIMA, G. S. de.; SOARES, L. A. dos. A.; OLIVEIRA, V. K. N.; GHEYI, H. R. et al. Salicylic acid modulates okra tolerance to salt stress in hydroponic system. Agriculture, v. 12, n. 10, p. 1-24, 2022a. https://doi.org/10.3390/agriculture12101687
https://doi.org/10.3390/agriculture12101... ; Silva et al., 2023SILVA, A. A. R. da.; SOUSA, P. F. do N.; LIMA, G. S. de.; SOARES, L. A. dos. A.; GHEYI, H. R.; SILVA, L. de A. et al. Salicylic Acid Modulates Okra Tolerance to Salt Stress in Hydroponic System. Arid Land Research and Management, v. 37, n. 4, p.1-17, 2023. https://doi.org/10.1080/15324982.2023.2188314
https://doi.org/10.1080/15324982.2023.21... ). Although there are several strategies in the literature that aim to mitigate the effects of saline stress on okra plants, the intensity of the deleterious effects on the plants depends on the culture, cultivar, development phase, irrigation and fertilization management and climatic conditions (Pinheiro et al., 2022PINHEIRO, F. W. A.; LIMA, G. S. de; GHEYI, H. R.; SOARES, L. A. dos A.; OLIVEIRA, S. G. de; SILVA, F. A. da. Gas exchange and yellow passion fruit production under irrigation strategies using brackish water and potassium. Revista Ciência Agronômica, v. 53, n.1, e20217816, 2022. https://doi.org/10.5935/1806-6690.20220009
https://doi.org/10.5935/1806-6690.202200... ; Mendonça et al., 2022aMENDONÇA, A. J. T.; SILVA, A. A. R. da.; LIMA, G. S. de.; SOARES, L. A. dos. A.; OLIVEIRA, V. K. N.; GHEYI, H. R. et al. Salicylic acid modulates okra tolerance to salt stress in hydroponic system. Agriculture, v. 12, n. 10, p. 1-24, 2022a. https://doi.org/10.3390/agriculture12101687
https://doi.org/10.3390/agriculture12101... )

In this scenario, it is essential to develop strategies that mitigate the effects of salt stress in plants. The available alternatives include foliar application of hydrogen peroxide (H₂O₂) (Veloso et al., 2023VELOSO, L. L. dos S. A.; AZEVEDO, C. A. V. de; NOBRE, R. G.; LIMA, G. S. de; SILVA, I. J. da; LACERDA, C. N. de. Hydrogen peroxide in the acclimation of colored - fiber cotton genotypes to salt stress. Revista Caatinga, v. 36, n. 2, p. 414-423, 2023. https://doi.org/10.1590/1983-21252023v36n218rc
https://doi.org/10.1590/1983-21252023v36... ), which can act as a signaling molecule in plants under biotic and abiotic stresses and induce defense mechanisms before exposure to stress (Mendonça et al., 2022bMENDONÇA, A. J. T.; LIMA, G. S. de. ; SOARES, L. A. dos. A.; OLIVEIRA, V. K. N.; GHEYI, H. R. ; SILVA, L. de A. et al. Gas exchange, photosynthetic pigments, and growth of hydroponic okra under salt stress and salicylic acid. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 27, n. 9, p. 1-9, 2022b. https://doi.org/10.1590/1807-1929/agriambi.v27n9p673-681
https://doi.org/10.1590/1807-1929/agriam... ).

H₂O₂ can favor the accumulation of proteins and soluble carbohydrates that act as organic solutes and contribute to the osmotic adjustment of plants under salt stress (Ramos et al., 2021RAMOS, J. G.; LIMA, G. S. de; LIMA, V. L. A. de; PAIVA, F. J. da S.; NUNES, K. G.; PEREIRA, M. de O. et al. Foliar application of H2O2 as salt stress attenuator in ‘BRS Rubi do Cerrado’ sour passion fruit. Semina: Ciências Agrárias, v. 42, n. 4, p. 2253-2270, 2021. https://doi.org/10.5433/1679-0359.2021v42n4p2253
https://doi.org/10.5433/1679-0359.2021v4... ; Veloso et al., 2023VELOSO, L. L. dos S. A.; AZEVEDO, C. A. V. de; NOBRE, R. G.; LIMA, G. S. de; SILVA, I. J. da; LACERDA, C. N. de. Hydrogen peroxide in the acclimation of colored - fiber cotton genotypes to salt stress. Revista Caatinga, v. 36, n. 2, p. 414-423, 2023. https://doi.org/10.1590/1983-21252023v36n218rc
https://doi.org/10.1590/1983-21252023v36... ). Furthermore, it can act in cells as a secondary messenger, increasing the flow of Ca²⁺ ions and modifying the pattern of proteins and gene expression (Bienert et al., 2006BIENERT, G. P.; SCHJOERRING, J. K.; JAHN, T. P. Membrane transport of hydrogen peroxide. Biochimica et Biophysica Acta, v. 1758, n. 8, p. 994-1003, 2006. https://doi.org/10.1016/j.bbamem.2006.02.015
https://doi.org/10.1016/j.bbamem.2006.02... ). Research carried out using foliar H₂O₂ application has highlighted beneficial effects in plants under salt stress conditions, as observed in pepper (Aragão et al., 2023ARAGÃO, J.; LIMA, G. S. de; LIMA, V. L. A. de; SILVA, A. A. R. da; SANTOS, L. F. S.; DIAS, M. dos S. et al. Hydrogen peroxide in the mitigation of salt stress in bell pepper. Semina: Ciências Agrárias, v. 44, n. 1, p. 217-236, 2023. https://doi.org/10.5433/1679-0359.2022v44n1p217
https://doi.org/10.5433/1679-0359.2022v4... ), soursop (Silva et al., 2019aSILVA, A. A. R. da.; LIMA, G. S. de.; VELOSO, L. L. de S. A.; AZEVEDO, C. A. V. de; GHEYI, H. R.; FERNANDES, P. D. et al. Hydrogen peroxide on acclimation of soursop seedlings under irrigation water salinity. Semina: Ciências Agrárias, v. 40, n. 4, p. 1441-1454, 2019a. https://doi.org/10.5433/1679-0359.2019v40n4p1441
https://doi.org/10.5433/1679-0359.2019v4... ), sour passion fruit (Silva et al., 2019bSILVA, A. A. R. da; LIMA, G. S. de; AZEVEDO, C. A. V. de; GHEYI, H. R.; SOUZA, L. de P.; VELOSO, L. L. de S. A. Gas exchanges and growth of passion fruit seedlings under salt stress and hydrogen peroxide. Pesquisa Agropecuária Tropical, v. 49, n. 1, p. 1-10, 2019b. https://doi.org/10.1590/1983-40632019v4955671
https://doi.org/10.1590/1983-40632019v49... ), and colored fiber cotton (Veloso et al., 2023VELOSO, L. L. dos S. A.; AZEVEDO, C. A. V. de; NOBRE, R. G.; LIMA, G. S. de; SILVA, I. J. da; LACERDA, C. N. de. Hydrogen peroxide in the acclimation of colored - fiber cotton genotypes to salt stress. Revista Caatinga, v. 36, n. 2, p. 414-423, 2023. https://doi.org/10.1590/1983-21252023v36n218rc
https://doi.org/10.1590/1983-21252023v36... ).

The hypothesis of this study is that the foliar application of hydrogen peroxide in low concentrations works as an abiotic stress signaling molecule, playing an important role in the growth and production of okra plants under saline stress. From this perspective, this study aimed to evaluate the effects of foliar hydrogen peroxide application on chlorophyll a fluorescence, growth, and production of okra under irrigation with saline water.

2. MATERIAL AND METHODS

The experiment was conducted under field conditions from December 2020 to March 2021, at the Agri-food Science and Technology Center - CCTA of the Federal University of Campina Grande - UFCG, Pombal, Paraíba, located at the geographic coordinates 6º46'13” S, 37°48'06” W, and at an elevation of 193 m a.s.l.

A randomized block design with a 5×3 factorial arrangement was adopted, corresponding to five water electrical conductivity levels - ECw (0.3, 1.3, 2.3, 3.3, and 4.3 dS m^-1) and three hydrogen peroxide concentrations - H₂O₂ (0, 25, and 50 μM), with five replications and one plant per plot. The water salinity levels were based on research carried out by Soares et al. (2020)SOARES, L. A. dos A.; SILVA, R. G. da; LIMA, G, S. de; SALES, G. N. B.; COSTA, F. B. da.; NETA, A. M. de S. S. et al. Preservation by lactic fermentation and physicochemical characterization of okra produced under water salinity and potassium fertilization. Semina: Ciências Agrárias, v. 41, n. 6, p. 2495-2508, 2020. https://doi.org/10.5433/1679-0359.2020v41n6p2495
https://doi.org/10.5433/1679-0359.2020v4... . The concentrations of H₂O₂ used in this study were based on previous research carried out with summer squash (Dantas et al., 2021DANTAS, M. V.; LIMA, G. S. de; GHEY, H. R.; PINHEIRO, F. W. A.; SILVA, L. de A.; FERNANDES, P. D. Summer squash morphophysiology under salt stress and exogenous application of H2O2 in hydroponic cultivation. Comunicata Scientiae, v.12, n.1, e.3464, 2021. https://doi.org/10.14295/cs.v12.3464
https://doi.org/10.14295/cs.v12.3464... ).

Sowing was carried out in a 50-mL polyethylene tray using the cultivar Clemson Americano 80, with two seeds per cell in a substrate obtained by mixing soil, sand, and cattle manure in a ratio of 2:1:1 (on a volume basis), respectively. At this stage, the plants were irrigated daily with low-salinity water (0.3 dS m^-1) and subsequently thinned to one plant per cell.

Transplanting was carried out 20 days after sowing (DAS) into 20-mL pots adapted as drainage lysimeters filled with a 0.5-kg-cm layer of gravel over a geotextile fabric covering the bottom of the container to avoid clogging. Soon after, the pots received 22 kg of a Fluvic Neosol with a sandy loam texture. A 15-mm diameter hose was also installed as a drain at the base of each lysimeter, coupled to a plastic container (2 L) to collect the drained water and determine water consumption by the plants. The chemical and physical characteristics of the soil used in the experiment (Table 1) were determined according to Teixeira et al. (2017)TEIXEIRA, P. C.; DONAGEMMA, G. K.; FONTANA, A.; TEIXEIRA, W. G. Manual de métodos de análise de solo. Rio de Janeiro: Embrapa, 2017. 573 p..

Fertilization was carried out according to the recommendation of Novais et al. (1991)NOVAIS, R. F.; NEVES, J. C. L.; BARROS, N. F. Ensaio em ambiente controlado. In: OLIVEIRA, A. J. (ed). Métodos de pesquisa em fertilidade do solo. Brasília - DF: Embrapa-SEA, 1991. p. 189-253. by applying 100 mg N kg^-1, 300 mg P₂O₅ kg^-1, and 150 mg K₂O kg^-1 using urea, monoammonium phosphate, and potassium chloride as the respective sources of nitrogen, phosphorus, and potassium. Fertilization was carried out via topdressing in three applications, starting 10 days after transplanting. Micronutrients were supplied every 15 days, and their application began 20 days after transplanting with the commercial product Micro Rexene® (Mg - 1.2%, B - 0.85%, Zn - 4.2%, Fe - 3.4%, Mn - 3.2%, Cu - 0.5%, and Mo - 0.06%) at the concentration of 0.5 g L^-1.

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Table 1.
Chemical and physical characteristics of the soil used in the experiment before the application of treatments.

The different water electrical conductivity levels (ECw) were prepared by dissolving sodium chloride (NaCl) in local water supply (ECw = 0.3 dS m^-1) while considering the relationship between the ECw and salt concentration (Richards, 1954RICHARDS, L. A. Diagnosis and improvement of saline and alkali soils. Washington: USDA, 1954. 160p. ), according to Equation 1:

C (m m o l_{c} L^{- 1}) = 10 x E C w

(1)

Where:

C = salt concentration to be applied (mmolc L^-1);

ECw = water electrical conductivity (dS m^-1).

At the time of transplanting, the soil moisture content was raised to the level corresponding to the maximum water retention capacity, and irrigation was carried out daily with water of low electrical conductivity (0.3 dS m^-1) until 17 DAT. After this period, irrigation was started daily with different salinity levels. The water depth applied was determined based on drainage lysimetry in order to replace the average daily consumption (Equation 2).

V C = \frac{V A - V D}{1 - L F}

(2)

Where:

VC - volume consumed (L);

VA - water volume applied on the previous day;

VD - drained volume, quantified in the morning of the next day;

LF - leaching fraction estimated at 0.1, every 10 days, in order to minimize salt accumulation in the root zone.

During the experiment, chemical interventions were carried out with preventive applications of commercial pesticides, e.g., insecticides and fungicides, using a manual compression sprayer for phytosanitary control.

The different concentrations of H₂O₂ were prepared from a stock solution of hydrogen peroxide, obtained by diluting H₂O₂ - 30% in deionized water in each application event. Applications were started 72 hours before irrigation with saline water (15 DAT), according to their respective treatments, using a manual sprayer. The product was applied on the abaxial and adaxial sides in order to completely wet the leaves. A cardboard structure was used to avoid drifting onto neighboring plants. During the experiment period, 2 mL of H₂O₂ was applied per plant.

Chlorophyll a fluorescence was measured at 75 DAT, between 7:00 and 10:00 a.m., using leaf tweezers (clips) to determine the initial fluorescence (F₀), maximum fluorescence (Fm), variable fluorescence (Fv) and quantum efficiency of photosystem II (Fv/Fm) after 30 minutes of dark adaptation using a pulse amplitude modulated fluorometer (PAM fluorometer ¬ Model OS5p, Opti Science/Hudson, NY, USA).

Growth was determined at 75 DAT by determining the number of leaves (NL), considering those with a minimum length of 3 cm; plant height (PH) was measured from the base of the plant to the insertion of the apical meristem; stem diameter (SD) was determined at 2 cm from the ground with a digital caliper. Leaf area (LA) was measured by following the methodology of Fideles Filho et al. (2010)FIDELES FILHO, J.; BELTRÃO, N. E. DE M.; PEREIRA, A. S. Desenvolvimento de uma régua para medidas de área foliar do algodoeiro. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 14, n. 7, p. 736-741, 2010. https://doi.org/10.1590/S1415-43662010000700008
https://doi.org/10.1590/S1415-4366201000... , according to Equation 3:

L A = \sum 0.7254 (X)^{2.08922}

(3)

Where:

LA - leaf area per plant (cm²);

X - length of the midrib of the respective leaf (cm).

Fruit harvest began at 59 DAT and continued until 82 DAT by removing fruits that had the typical green color of ripe fruits. The average fruit length (AFL) measured from the base to the apex of the fruit and the average fruit diameter (AFD) were evaluated using a digital caliper. Subsequently, the fruits were dried to constant weight in an air circulation oven at 65ºC, after which they were taken to a precision balance (0.01g), where the average dry fruit weight (ADF, g per plant) and total dry fruit weight (TDF, g per plant) were determined.

At 82 DAT, the plants were collected and separated into different parts (leaves, stems, and roots); subsequently, the parts were packed in paper bags and taken to an air circulation oven at 65ºC until reaching constant weight. After this period, the material was weighed on a semi-analytical balance, obtaining the phytomass of leaves (DPL, g per plant), stem (DPS, g per plant), and roots (DPR, g per plant), the sum of which resulted in the total dry phytomass (TDP, g per plant).

The cumulative water consumption (WC, L per plant) was calculated from the sum of daily water consumption per experimental unit, considering the volume applied and drained during the experiment.

The data obtained were subjected to analysis of variance (F-test) at a probability level of 0.05. In cases of significance, linear and quadratic polynomial regression were performed for the water electrical conductivity levels and H₂O₂ concentrations using the statistical software SISVAR (Ferreira, 2019FERREIRA, D. F. SISVAR: A computer analysis system to fixed effects split plot type designs. Revista Brasileira de Biometria, v. 37, n. 4, p. 529-535, 2019. https://doi.org/10.28951/rbb.v37i4.450
https://doi.org/10.28951/rbb.v37i4.450... ). In cases of significant interaction between factors, response surface graphs were created using the software SigmaPlot Version 12.5.

3. RESULTS AND DISCUSSION

There was a significant effect of water salinity on the maximum (Fm) and variable (Fv) fluorescence of okra plants (Table 2). Hydrogen peroxide concentrations and the interaction between factors (SL × H₂O₂) did not significantly influence the chlorophyll a fluorescence of okra plants at 75 DAT.

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Table 2.
Summary of the analysis of variance for initial fluorescence (F₀), maximum fluorescence (Fm), variable fluorescence (Fv) and quantum efficiency of photosystem II (Fv/Fm) of okra cv. Clemson Americano 80 cultivated with saline water and concentrations of hydrogen peroxide 75 days after transplanting (DAT).

The maximum fluorescence of okra plants (Figure 1A) achieved the maximum estimated value under the ECw of 2.2 dS m^-1 (2052.24), decreasing from this level. The lowest value occurred in plants grown under the ECw of 4.3 dS m^-1 (1997.89). The increase in Fm is related to the reduction of the damage caused by salt stress, increasing the plant's capacity to transfer energy for the formation of NADPH, ATP, and reduce ferredoxin, in addition to favoring the assimilation of CO₂ in the biochemical phase of photosynthesis (Figueiredo et al., 2019FIGUEIREDO, F. R. A.; LOPES, M. D. F. Q.; SILVA, R. T. da; NÓBREGA, J. S.; SILVA, T. I. da; BRUNO, R. D. L. A. Respostas fisiológicas de mulungu submetida a estresse salino e aplicação de ácido salicílico. Irriga, v. 24, n. 3, p. 662-675, 2019. https://doi.org/10.15809/irriga.2019v24n3p662-675
https://doi.org/10.15809/irriga.2019v24n... ).

Figure 1.
Maximum fluorescence - Fm (A) and variable fluorescence - Fv (B) of the okra cv. Clemson Americano 80 as a function of irrigation water salinity - ECw 75 days after transplanting.

The variable fluorescence (Fv) of okra plants also showed a quadratic behavior (Figure 1B), with the maximum estimated value of 1593.68 being achieved at the ECw of 1.9 dS m^-1. On the other hand, the minimum value of 1518.11 was achieved in plants subjected to irrigation with 4.3 dS m^-1 (Figure 1B). Under salt stress conditions, deficiency in the photoreduction of quinone A (QA) and in the flow of electrons between photosystems may occur, probably due to the damage caused to the photosynthetic apparatus as a result of water stress caused by the osmotic effect, with the imbibition forces of plant roots becoming low in relation to the water retention forces in the soil due to excess salts (Cova et al., 2021COVA, A. M. W.; SILVA, P. C. C.; GHEYI, H. R.; AZEVEDO NETO, A. D. de; RIBAS, R. F. Aspectos bioquímicos e fluorescência da clorofila a em plantas de minimelancia hidropônica sob estresse salino. Irriga, v. 26, n. 2, p. 221-239, 2021. https://doi.org/10.15809/irriga.2021v26n2p221-239
https://doi.org/10.15809/irriga.2021v26n... ).

There was a significant effect of the interaction between factors (SL × H₂O₂) on plant height and okra stem diameter at 75 DAT. Water salinity levels significantly influenced all growth variables measured (Table 3). Hydrogen peroxide concentrations had a significant effect only on the number of leaves and leaf area of okra.

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Table 3.
Summary of the analysis of variance for plant height (PH), stem diameter (SD), number of leaves (NL), and leaf area (LA) of the okra cv. Clemson Americano 80 cultivated with saline water and hydrogen peroxide concentrations 75 days after transplanting (DAT).

The plant height (Figure 2A) of okra reached the maximum estimated value under the ECw of 0.3 dS m^-1 (77.92 cm) and foliar application of 50 µM of H₂O₂, being 27.6 cm higher than the lowest value (50.32 cm) obtained under irrigation with 4.3 dS m^-1 and at a concentration of 0 µM of H₂O₂. When the plants received irrigation with 1.8 dS m^-1 and 50 µM of H₂O₂, this decrease was only 13.57 cm in relation to the highest value found. The beneficial effects of hydrogen peroxide may be related to its role as an abiotic stress signal in plants, activating the defense system and favoring adaptation to adverse conditions (Souza et al., 2019SOUZA, L. de P.; NOBRE, R. G.; FATIMA, R. T. de; PIMENTA, T. A.; DINIZ, G. L; BARBOSA, J. L. Morfofisiologia e qualidade de porta-enxerto de cajueiro sob peróxido de hidrogênio e estresse salino. Revista Brasileira de Agricultura Irrigada, v. 13, n. 3, p. 3477-3486, 2019. https://doi.org/10.7127/rbai.v13n301082
https://doi.org/10.7127/rbai.v13n301082... ).

Figure 2.

Plant height (A) and stem diameter (B) of the okra cv. Clemson Americano 80 as a function of the interaction between irrigation water salinity - ECw and hydrogen peroxide concentrations - H₂O₂, 75 days after transplanting.

X and Y - Electrical conductivity of irrigation water - ECw and hydrogen peroxide concentrations - H2O2, respectively; ns, *, **, non-significant and significant at p ≤ 0.05 and 0.01 by the F-test.

Irrigation with 0.3 dS m^-1 and foliar hydrogen peroxide application at a concentration of 50 µM resulted in the highest value (18.91 mm) of stem diameter (SD) in okra plants (Figure 2B). When the plants received irrigation with an ECw of 4.3 dS m^-1 and a concentration of 12.5 µM of H₂O₂, they showed a SD of 15.24 mm, representing a reduction of 19.41% compared to the highest estimated value. The foliar application of hydrogen peroxide at adequate concentrations can favor greater accumulation of proteins and soluble carbohydrates that act in the osmotic adjustment of plants under salt stress, thus allowing greater water and nutrient uptake and, consequently, greater plant growth (Aragão et al., 2023ARAGÃO, J.; LIMA, G. S. de; LIMA, V. L. A. de; SILVA, A. A. R. da; SANTOS, L. F. S.; DIAS, M. dos S. et al. Hydrogen peroxide in the mitigation of salt stress in bell pepper. Semina: Ciências Agrárias, v. 44, n. 1, p. 217-236, 2023. https://doi.org/10.5433/1679-0359.2022v44n1p217
https://doi.org/10.5433/1679-0359.2022v4... ).

The number of leaves (NL) decreased linearly with the increase in the water electrical conductivity levels (Figure 3A), with reductions of 11.82% per unit increase in the ECw. When comparing the NL of plants subjected to an ECw of 4.3 dS m^-1 to those irrigated with the lowest salinity, a reduction of 50.9% was observed. Reductions in the number of leaves in plants subjected to salt stress are considered a protection and/or acclimatization strategy to high salinity, minimizing water losses through transpiration and maintaining a high water potential in the cell (Nascimento et al., 2019NASCIMENTO, E. C. S.; NASCIMENTO, R. do; SILVA, A. A. R. da; BEZERRA, C. V. de C.; BATISTA, M. C.; VELOSO, L. L. de S. A. et al. Growth and photosynthetic pigments of cotton cultivars irrigated with saline water. Agricultural Sciences, v. 10, n. 1, p. 81-91, 2019. https://doi.org/10.4236/as.2019.101007
https://doi.org/10.4236/as.2019.101007... ).

Figure 3.

Number of leaves (A) and leaf area (B) of the okra cv. Clemson Americano 80 as a function of irrigation water salinity- ECw and number of leaves as a function of hydrogen peroxide concentrations - H₂O₂ 75 days after transplanting.

Equal letters indicate that the H₂O₂ means do not differ by the Tukey test at p<0.05. The bars represent the standard error of the mean (n = 5).

The leaf area (LA) of okra plants was also negatively affected by water salinity (Figure 3B), with the maximum estimated value of LA (2738.39 cm²) obtained in plants grown under the ECw of 1.3 dS m^-1, decreasing from this point onwards and reaching the minimum value of 1802.28 cm² under the ECw of 4.3 dS m^-1. The leaf area reduction constitutes one of the initial responses of plants to salt stress and may be related to cellular inhibition and leaf surface expansion (Lima et al., 2017LIMA, G. S. de; SANTOS, J. B. dos; SOARES, L. A. dos A.; GHEYI, H. R.; NOBRE, R. G.; PEREIRA, R. F. Irrigação com águas salinas e aplicação de prolina foliar em cultivo de pimentão 'All Big'. Comunicata Scientiae, v. 7, n. 4, p. 513-522, 2017. https://doi.org/10.14295/CS.v7i4.1671
https://doi.org/10.14295/CS.v7i4.1671... ). Under these conditions, plants delay the emission of leaves (Figure 4A) and deactivate part of their leaf area through leaf abscission, in an attempt to reduce water loss through transpiration (Dias et al., 2017DIAS, A. S.; LIMA, G. S. de; GHEYI, H. R.; SOARES, L. A. dos A.; SOUZA, L. de P.; BEZERRA, I. L. Crescimento do algodoeiro ‘BRS Rubi’ em função da irrigação com águas salinas e adubação nitrogenada. Revista Brasileira de Agricultura Irrigada, v. 11, n. 7, p. 1945-1955, 2017. https://doi.org/10.7127/rbai.v11n700660
https://doi.org/10.7127/rbai.v11n700660... ).

Hydrogen peroxide (H₂O₂) at a concentration of 50 µM (Figure 3C) resulted in a number of leaves (NL) 16.43% higher than plants grown in the absence of H₂O₂ (0 µM). However, when comparing the NL of plants that received foliar application of 25 and 50 µM of H₂O₂, it appears that there was no significant difference between them. The application of H₂O₂ favors the activation of physiological responses that allow the accumulation of proteins, soluble carbohydrates, and NO₃ ^-, inducing cell division and increasing the emission of leaves (Gondim et al., 2011GONDIM, F. A.; GOMES FILHO, E.; MARQUES, E. C.; PRISCO, J. T. Efeitos do H2O2 no crescimento e acúmulo de solutos em plantas de milho sob estresse salino. Revista Ciência Agronômica, v. 42, n. 2, p. 373-38, 2011. https://doi.org/10.1590/S1806-66902011000200016
https://doi.org/10.1590/S1806-6690201100... ).

There was a significant effect of the interaction between salinity levels and hydrogen peroxide (SL × H₂O₂) on the stem (DPS), root (DPR) and total (TPM) dry matter of okra plants (Table 4) 82 days after transplanting. The water salinity levels significantly affected all variables analyzed. The hydrogen peroxide concentrations significantly influenced the DPL, DPR, and TDP of okra plants at 82 DAT.

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Table 4.
Summary of the analysis of variance for dry phytomass of leaves (DPL), stem (DPS), roots (DPR) and total dry phytomass (TDP) of the okra cv. Clemson Americano 80 cultivated with saline water and hydrogen peroxide concentrations 82 days after transplanting (DAT).

The dry phytomass of okra leaves (DPL) was negatively affected by the increase in water electrical conductivity (Figure 4A), with a reduction of 11.98% per unit increase in the ECw. A reduction of 49.72 % (14.27 g per plant) was observed when comparing the DPL of plants subjected to the ECw of 4.3 dS m^-1 to those under the lowest electrical conductivity (0.3 dS m^-1). The reduction in DPL is related to the lower emission of leaves observed in this study under salinity conditions as excess salts reduce the free energy status of water in the root environment and the availability of water and nutrients to plants and compromise meristematic activity and cell elongation, consequently restricting phytomass accumulation in the leaves (Shankar et al., 2016SHANKAR, V.; KUMAR, D.; AGRAWAL, V. Assessment of Antioxidant Enzyme Activity and Mineral Nutrients in Response to NaCl Stress and its Amelioration Through Glutathione in Chickpea. Applied Biochemistry and Biotechnology, v. 178, n. 1, p. 267-284, 2016. https://doi.org/10.1007/s12010-015-1870-1
https://doi.org/10.1007/s12010-015-1870-... ; Silva et al., 2020SILVA, S. S. da; LIMA, G. S. de; LIMA, V. L. A. de; GHEYI, H. R.; SOARES, L. A. dos A.; OLIVEIRA, A. P. M. et al. Production and quality of watermelon fruits under salinity management strategies and nitrogen fertilization. Semina: Ciências Agrárias, v. 41, n. 6, p. 2923-2936, 2020. https://doi.org/10.5433/1679-0359.2020v41n6Supl2p2923
https://doi.org/10.5433/1679-0359.2020v4... ).

When analyzing the effects of Hydrogen peroxide (H₂O₂) concentrations on okra leaf dry matter (DPL) (Figure 4B), it was observed that plants subjected to foliar application of 50 µM of H₂O₂ had an NL 8.51 and 13.28% higher than those under 0 and 25µM of H₂O₂, respectively. These results are related to the effect of the highest H₂O₂ level (50 µM) on leaf emission, indicating the role of hydrogen peroxide in inducing the production of several enzymes, e.g., catalase, superoxide dismutase, glutathione reductase, and peroxidase, which are associated with plant detoxification (Das and Roychoudhury, 2014DAS, K.; ROYCHOUDHURY, A. Reactive oxygen species (ROS) and response of antioxidants as ROS-scavengers during environmental stress in plants. Frontiers in Environmental Science, v. 2, n. 53, p. 1-13, 2014. https://doi.org/10.3389/fenvs.2014.00053
https://doi.org/10.3389/fenvs.2014.00053... ). Pereira et al. (2022)PEREIRA, F. H. F.; SANTOS, G. L. dos.; LACERDA, F. H. de; SOUSA, D. D. A. de; SOUSA, V. F. de O.; FERNANDES, J. E. de M. et al. Use of hydrogen peroxide in acclimatization of melon to salinity of irrigation water. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 27, n. 1, p. 51-56, 2022. https://doi.org/10.1590/1807-1929/agriambi.v27n1p51-56
https://doi.org/10.1590/1807-1929/agriam... evaluated the effects of irrigation with saline water (ECw varying from 0.3 and 5.0 dS m^-1) and four concentrations of H₂O₂ (0, 5, 10, and 15 µmol L^-1) on melon and found that the highest dry phytomass values of the shoot part were 78.62 and 46.34 g per plant under ECw values of 0.3 and 5.0 dS m^-1 and foliar application of 9.11 and 8.35 µmol L^-1 of H₂O₂.

Figure 4.

Dry phytomass of leaves of the okra cv. Clemson Americano 80 as a function of irrigation water salinity - ECw (A) and hydrogen peroxide concentrations - H₂O₂ (B) 82 days after transplanting.

Equal letters indicate that the H₂O₂ means do not differ by the Tukey test at p<0.05. The bars represent the standard error of the mean (n = 5).

Irrigation with low salinity water (ECw of 0.3 dS m^-1) and foliar application of H₂O₂ at a concentration of 50 µM provided greater accumulation of dry phytomass in the stem (DPS) (28.71 g per plant). On the other hand, the water salinity of 4.3 dS m^-1 and the concentration of 18.75 µM of H₂O₂ resulted in a lower DPS (10.54 g per plant), i.e., a reduction of 34.69% compared the plants grown under the ECw of 0.3 dS m^-1 and 50 µM H₂O₂ (Figure 5A). For Bienert et al. (2006)BIENERT, G. P.; SCHJOERRING, J. K.; JAHN, T. P. Membrane transport of hydrogen peroxide. Biochimica et Biophysica Acta, v. 1758, n. 8, p. 994-1003, 2006. https://doi.org/10.1016/j.bbamem.2006.02.015
https://doi.org/10.1016/j.bbamem.2006.02... , hydrogen peroxide can act as a secondary messenger in cells by increasing the flow of Ca²⁺ ions and modifying the pattern of proteins and gene expression. Andrade et al. (2019)ANDRADE, E. M. G.; LIMA, G. S. de; LIMA, V. L. A. de; SILVA, S. S. da; GHEYI, H. R.; SILVA, A. A. R. da. Gas exchanges and growth of passion fruit under saline water irrigation and H2O2 application. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 23, n. 12, p. 945-951, 2019. https://doi.org/10.1590/1807-1929/agriambi.v23n12p945-951.
https://doi.org/10.1590/1807-1929/agriam... evaluated four concentrations of hydrogen peroxide (0, 20, 40, and 60 µM) in sour passion fruit under salt stress and observed beneficial effects with foliar application of 20 µM of H₂O₂.

Figure 5.

Dry phytomass of stem (A), roots (B) and total dry phytomass (C) of the okra cv. Clemson Americano 80 as a function of the interaction between irrigation water salinity - ECw and hydrogen peroxide concentrations - H₂O₂ 82 days after transplanting.

X and Y - Electrical conductivity of irrigation water- ECw and hydrogen peroxide concentrations - H₂O₂, respectively; ^ns, ^*, ^** significant at p ≤ 0.05 and 0.01 by the F-test.

For root dry phytomass (DPR), the maximum estimated value (31.02 g per plant) was obtained in plants grown under the ECw of 0.3 dS m^-1 and foliar application of 50 µM of H₂O₂. On the other hand, the minimum value of 4.49 g per plant was reached in plants grown under the water salinity of 4.3 dS m^-1 and foliar application of 0 µM H₂O₂ (Figure 5B). The restriction in water uptake due to the osmotic effect causes stomatal closure, reducing carbon accumulation in the cell and resulting in less photosynthesis, consequently decreasing phytomass accumulation (Silva et al., 2023SILVA, A. A. R. da.; SOUSA, P. F. do N.; LIMA, G. S. de.; SOARES, L. A. dos. A.; GHEYI, H. R.; SILVA, L. de A. et al. Salicylic Acid Modulates Okra Tolerance to Salt Stress in Hydroponic System. Arid Land Research and Management, v. 37, n. 4, p.1-17, 2023. https://doi.org/10.1080/15324982.2023.2188314
https://doi.org/10.1080/15324982.2023.21... ).

The total dry mass (TDP) of okra plants achieved the maximum value (90.54 g per plant) under irrigation with 0.3 dS m^-1 and foliar application of 50 µM of H₂O₂. The lowest value (30.31 g per plant) was achieved in plants irrigated with water at 4.3 dS m^-1 and hydrogen peroxide at a concentration of 6.25 µM (Figure 5C). The toxicity of specific ions (Na⁺, Cl^-, and B) occurs due to the absorption of saline water by plant roots, causing cell disruption and metabolic changes in plants and reducing growth and phytomass (Ali et al., 2021ALI, M.; NIAZ, Y.; ABBASI, G. H.; AHMAD, S.; MALIK, Z.; KAMRAN, M. et al. Exogenous zinc induced NaCl tolerance in okra (Abelmoschus esculentus) by ameliorating osmotic stress and oxidative metabolism. Communications in Soil Science and Plant Analysis, v. 52, n. 7, 2021. https://doi.org/10.1080/00103624.2020.1869761
https://doi.org/10.1080/00103624.2020.18... ).

There was a significant effect of the interaction between factors (SL × H₂O₂) only for the total dry fruit weight (TDF) (Table 5). The salinity levels significantly influenced water consumption (WC). On the other hand, the hydrogen peroxide concentrations significantly affected the average dry fruit weight (TDF) of okra plants.

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Table 5.
Summary of the analysis of variance for total dry fruit weight (TDF), average dry fruit weight (ADF), water consumption (WC), average fruit diameter (AFD), and average fruit length (AFL) of the okra cv. Clemson Americano 80 cultivated with saline water and hydrogen peroxide concentrations 82 days after transplanting (DAT).

The total weight of the dry fruit (TDF) decreased with increasing salinity levels (Figure 6), with the maximum value (18.39 g per plant) being achieved in plants irrigated with 0.3 dS m^-1 and no H₂O₂ (0 µM). It should be noted that the increase in salinity levels associated with the increase in H₂O₂ concentrations intensified the deleterious effects of salt stress on okra, with irrigation with 4.3 dS m^-1 and a concentration of 50 µM of H₂O₂ resulting in a reduction of 66.82% compared to the plants grown under the ECw of 0.3 dS m^-1. Azeem et al. (2017)AZEEM, A.; WU, Y.; XING, D.; JAVED, Q.; ULLAH, I. Photosynthetic response of two okra cultivars under salt stress and re-watering. Journal of Plant Interactions, v. 12, n. 1, p. 67-77, 2017. https://doi.org/10.1080/17429145.2017.1279356
https://doi.org/10.1080/17429145.2017.12... explain that a reduction in photosynthetic efficiency in okra plants, which are sensitive to the effects of saline stress, decreases fruit growth and biomass production. Similar results were found by Soares et al. (2020)SOARES, L. A. dos A.; SILVA, R. G. da; LIMA, G, S. de; SALES, G. N. B.; COSTA, F. B. da.; NETA, A. M. de S. S. et al. Preservation by lactic fermentation and physicochemical characterization of okra produced under water salinity and potassium fertilization. Semina: Ciências Agrárias, v. 41, n. 6, p. 2495-2508, 2020. https://doi.org/10.5433/1679-0359.2020v41n6p2495
https://doi.org/10.5433/1679-0359.2020v4... in research with okra and irrigation with saline water (ECw ranging from 0.3 to 4.3 dS m^-1), in which they found that higher salinity levels reduce fruit weight, and the highest value of 33 .64 g for average fruit weight was achieved in plants irrigated with an ECw of 2.4 dS m^-1 and under hydroponic conditions (nutrient solution EC levels of 2.1, 3.6, 5.1, and 6.6 dS m⁻¹), Mendonça et al. (2022a)MENDONÇA, A. J. T.; SILVA, A. A. R. da.; LIMA, G. S. de.; SOARES, L. A. dos. A.; OLIVEIRA, V. K. N.; GHEYI, H. R. et al. Salicylic acid modulates okra tolerance to salt stress in hydroponic system. Agriculture, v. 12, n. 10, p. 1-24, 2022a. https://doi.org/10.3390/agriculture12101687
https://doi.org/10.3390/agriculture12101... observed a 3.82% reduction in the average weight of okra fruits per unit increase in the EC of the nutrient solution.

Figure 6.

Total dry fruit weight (TDF) of the okra cv. Clemson Americano 80 as a function of the interaction between salinity levels of irrigation water - ECw and concentrations of hydrogen peroxide - H₂O₂ 82 days after transplanting.

X and Y - Electrical conductivity of irrigation water- ECw and hydrogen peroxide concentrations - H2O2, respectively; ns,*, **, non-significant and significant at p ≤ 0.05 and 0.01 by the F-test.

With regard to the effects of H₂O₂ on the average dry fruit weight (Figure 7A), the foliar application of 25 and 50 µM H₂O₂ reduced this parameter by, respectively, 16.79 and 12.94% in plants that received 0 µM H₂O₂. The average dry fruit weight decreased with the application of H₂O₂, probably because it is a reactive oxygen species (ROS) which, depending on its concentration, can act in the oxidation of the lipid membrane, DNA, and other cell components through toxic free radicals (Barbosa et al., 2014BARBOSA, M. R.; SILVA, M. M. de A.; WILLADINO, L.; ULISSES, C.; CAMARA, T. R. Geração e desintoxicação enzimática de espécies reativas de oxigênio em plantas. Ciência Rural, v. 44, n. 3, p. 453-460, 2014. https://doi.org/10.1590/S0103-84782014000300011
https://doi.org/10.1590/S0103-8478201400... ; Silva et al., 2019cSILVA, A. A. R. da; LIMA, G. S. de; AZEVEDO, C. A. V. de; GHEYI, H. R.; SOUZA, L. de P.; VELOSO, L. L. de S. A. Salt stress and exogenous application of hydrogen peroxide on photosynthetic parameters of soursop. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 23, n. 4, p. 257-263, 2019c. https://doi.org/10.1590/1807-1929/agriambi.v23n4p257-263
https://doi.org/10.1590/1807-1929/agriam... ).

Figure 7.

Average dry fruit weight - ADF of the okra cv. Clemson Americano 80 as a function of hydrogen peroxide concentrations, (A) and water consumption - WC of okra plants as a function of irrigation water salinity - ECw (B) 82 days after transplanting.

Equal letters indicate that the H2O2 means do not differ by the Tukey test at p≤0.05. The bars represent the standard error of the mean (n = 5).

The water consumption of okra (WC) plants decreased quadratically with the increase in the electrical conductivity of irrigation water (Figure 7B). Okra plants irrigated with an ECw of 0.3 dS m^-1 achieved the highest WC (29.71 L per plant), decreasing sharply from this salinity level and reaching the lowest WC under the ECw of 4.3 dS m^-1 (22.24 L per plant). When comparing plants subjected to the ECw of 4.3 dS m^-1 in relation to those grown under 0.3 dS m^-1, there was a reduction in water consumption amounting to 7.46 L per plant. The reduction in water consumption is a reflection of the osmotic effect that reduces water absorption by plants due to high salt concentrations in the soil, making the osmotic potential more negative and leading to greater stomatal resistance and reduced transpiration, thus reducing water uptake by roots (Santos et al., 2022SANTOS, T. B. dos; RIBAS, A. F.; SOUZA, S. G. H. de; BUDZINSKI, I. G. F.; DOMINGUES, D. S. Physiological responses to drought, salinity, and heat stress in plants: a review. Stresses, v. 2, n. 1, p. 113-135, 2022. https://doi.org/10.3390/stresses2010009
https://doi.org/10.3390/stresses2010009... ). Ünlükara et al. (2008)ÜNLÜKARA, A.; SEMIZ, D. G.; YURTSEVEN, E.; KURUNC, A. Growth and evapotranspiration of okra (Abelmoschus esculentus L.) as influenced by salinity of irrigation water. Journal of Irrigation and Drainage Engineering, v. 134, n. 2, p. 160-166, 2008. https://doi.org/10.1061/(ASCE)0733-9437(2008)134:2(160)
https://doi.org/10.1061/(ASCE)0733-9437(... evaluated five salinity levels of irrigation water (1.5, 2.5, 3.5, 5.0, and 7.0 dS m^-1) in okra plants and found a reduction in water consumption of 2.43% per unit increase in the ECw.

4. CONCLUSIONS

Irrigation water salinity levels up to 2.2 dS m^-1 increase the maximum fluorescence of okra plants 75 days after transplanting.

The foliar application of 50 µM hydrogen peroxide proved to be beneficial for plant height, stem diameter, stem dry matter, root dry matter, and total dry matter of okra when plants were grown in low-salinity water.

The hydrogen peroxide concentrations of 25 and 50 µM increased the number of leaves. However, these concentrations reduced the average weight of the okra dry fruits.

The foliar application with 50 µM hydrogen peroxide had a significant effect on the dry leaf phytomass of the okra cv. Clemson American 80 regardless of the electrical conductivity of irrigation water.

Foliar hydrogen peroxide application at concentrations up to 50 µM intensifies the deleterious effects of salt stress on the total weight of dried okra fruits.

5. REFERENCES

ARAGÃO, J.; LIMA, G. S. de; LIMA, V. L. A. de; SILVA, A. A. R. da; SANTOS, L. F. S.; DIAS, M. dos S. et al Hydrogen peroxide in the mitigation of salt stress in bell pepper. Semina: Ciências Agrárias, v. 44, n. 1, p. 217-236, 2023. https://doi.org/10.5433/1679-0359.2022v44n1p217
» https://doi.org/10.5433/1679-0359.2022v44n1p217
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» https://doi.org/10.1080/17429145.2017.1279356
ANDRADE, E. M. G.; LIMA, G. S. de; LIMA, V. L. A. de; SILVA, S. S. da; GHEYI, H. R.; SILVA, A. A. R. da. Gas exchanges and growth of passion fruit under saline water irrigation and H₂O₂ application. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 23, n. 12, p. 945-951, 2019. https://doi.org/10.1590/1807-1929/agriambi.v23n12p945-951
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ALI, M.; NIAZ, Y.; ABBASI, G. H.; AHMAD, S.; MALIK, Z.; KAMRAN, M. et al Exogenous zinc induced NaCl tolerance in okra (Abelmoschus esculentus) by ameliorating osmotic stress and oxidative metabolism. Communications in Soil Science and Plant Analysis, v. 52, n. 7, 2021. https://doi.org/10.1080/00103624.2020.1869761
» https://doi.org/10.1080/00103624.2020.1869761
ALVARENGA, C. F de S.; SILVA, E. M. da; NOBRE, R. G.; GHEYI, H. R.; LIMA, G. S. de.; SILVA, L. de A. Morfofisiologia de aceroleira irrigada com águas salinas sob combinações de doses de nitrogênio e potássio. Revista de Ciências Agrárias, v. 42, n. 1, p. 191-200, 2019. https://doi.org/10.19084/RCA18215
» https://doi.org/10.19084/RCA18215
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Publication Dates

Publication in this collection
12 Aug 2024
Date of issue
2024

History

Received
27 Dec 2023
Accepted
30 Apr 2024

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[2] AZEEM, A.; WU, Y.; XING, D.; JAVED, Q.; ULLAH, I. Photosynthetic response of two okra cultivars under salt stress and re-watering. Journal of Plant Interactions, v. 12, n. 1, p. 67-77, 2017. https://doi.org/10.1080/17429145.2017.1279356
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[4] ALI, M.; NIAZ, Y.; ABBASI, G. H.; AHMAD, S.; MALIK, Z.; KAMRAN, M. et al Exogenous zinc induced NaCl tolerance in okra (Abelmoschus esculentus) by ameliorating osmotic stress and oxidative metabolism. Communications in Soil Science and Plant Analysis, v. 52, n. 7, 2021. https://doi.org/10.1080/00103624.2020.1869761
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[5] ALVARENGA, C. F de S.; SILVA, E. M. da; NOBRE, R. G.; GHEYI, H. R.; LIMA, G. S. de.; SILVA, L. de A. Morfofisiologia de aceroleira irrigada com águas salinas sob combinações de doses de nitrogênio e potássio. Revista de Ciências Agrárias, v. 42, n. 1, p. 191-200, 2019. https://doi.org/10.19084/RCA18215
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[6] BARBOSA, M. R.; SILVA, M. M. de A.; WILLADINO, L.; ULISSES, C.; CAMARA, T. R. Geração e desintoxicação enzimática de espécies reativas de oxigênio em plantas. Ciência Rural, v. 44, n. 3, p. 453-460, 2014. https://doi.org/10.1590/S0103-84782014000300011
» https://doi.org/10.1590/S0103-84782014000300011

[7] BIENERT, G. P.; SCHJOERRING, J. K.; JAHN, T. P. Membrane transport of hydrogen peroxide. Biochimica et Biophysica Acta, v. 1758, n. 8, p. 994-1003, 2006. https://doi.org/10.1016/j.bbamem.2006.02.015
» https://doi.org/10.1016/j.bbamem.2006.02.015

[8] CAMPOS, M. S. Balanço de água e sais no solo cultivado com quiabeiro irrigado sob diferentes lâminas de água salobra. 2013. 74f. Dissertação (Mestrado em Irrigação e Drenagem) - Universidade Federal Rural do Semiárido, Mossoró, 2013.

[9] COVA, A. M. W.; SILVA, P. C. C.; GHEYI, H. R.; AZEVEDO NETO, A. D. de; RIBAS, R. F. Aspectos bioquímicos e fluorescência da clorofila a em plantas de minimelancia hidropônica sob estresse salino. Irriga, v. 26, n. 2, p. 221-239, 2021. https://doi.org/10.15809/irriga.2021v26n2p221-239
» https://doi.org/10.15809/irriga.2021v26n2p221-239

[10] COUTO, L. A.; COQUEIRO, J. S. Desenvolvimento de farinha de quiabo orgânico. Profiscientia, v. 14, n. 1, p. 194-208, 2020.

[11] DANTAS, M. V.; LIMA, G. S. de; GHEY, H. R.; PINHEIRO, F. W. A.; SILVA, L. de A.; FERNANDES, P. D. Summer squash morphophysiology under salt stress and exogenous application of H₂O₂ in hydroponic cultivation. Comunicata Scientiae, v.12, n.1, e.3464, 2021. https://doi.org/10.14295/cs.v12.3464
» https://doi.org/10.14295/cs.v12.3464

[12] DAS, K.; ROYCHOUDHURY, A. Reactive oxygen species (ROS) and response of antioxidants as ROS-scavengers during environmental stress in plants. Frontiers in Environmental Science, v. 2, n. 53, p. 1-13, 2014. https://doi.org/10.3389/fenvs.2014.00053
» https://doi.org/10.3389/fenvs.2014.00053

[13] DIAS, A. S.; LIMA, G. S. de; GHEYI, H. R.; SOARES, L. A. dos A.; SOUZA, L. de P.; BEZERRA, I. L. Crescimento do algodoeiro ‘BRS Rubi’ em função da irrigação com águas salinas e adubação nitrogenada. Revista Brasileira de Agricultura Irrigada, v. 11, n. 7, p. 1945-1955, 2017. https://doi.org/10.7127/rbai.v11n700660
» https://doi.org/10.7127/rbai.v11n700660

[14] FERREIRA, D. F. SISVAR: A computer analysis system to fixed effects split plot type designs. Revista Brasileira de Biometria, v. 37, n. 4, p. 529-535, 2019. https://doi.org/10.28951/rbb.v37i4.450
» https://doi.org/10.28951/rbb.v37i4.450

[15] FIGUEIREDO, F. R. A.; LOPES, M. D. F. Q.; SILVA, R. T. da; NÓBREGA, J. S.; SILVA, T. I. da; BRUNO, R. D. L. A. Respostas fisiológicas de mulungu submetida a estresse salino e aplicação de ácido salicílico. Irriga, v. 24, n. 3, p. 662-675, 2019. https://doi.org/10.15809/irriga.2019v24n3p662-675
» https://doi.org/10.15809/irriga.2019v24n3p662-675

[16] FIDELES FILHO, J.; BELTRÃO, N. E. DE M.; PEREIRA, A. S. Desenvolvimento de uma régua para medidas de área foliar do algodoeiro. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 14, n. 7, p. 736-741, 2010. https://doi.org/10.1590/S1415-43662010000700008
» https://doi.org/10.1590/S1415-43662010000700008

[17] GONDIM, F. A.; GOMES FILHO, E.; MARQUES, E. C.; PRISCO, J. T. Efeitos do H₂O₂ no crescimento e acúmulo de solutos em plantas de milho sob estresse salino. Revista Ciência Agronômica, v. 42, n. 2, p. 373-38, 2011. https://doi.org/10.1590/S1806-66902011000200016
» https://doi.org/10.1590/S1806-66902011000200016

[18] GHEYI, H. R.; DIAS, N. da S.; LACERDA, C. F. de; GOMES FILHO, E. Manejo da salinidade na agricultura: Estudos básicos e aplicados. 2. ed. Fortaleza: INCTSal, 2016. 504 p.

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Chemical characteristics
pH H₂O (1:2.5)	OM g kg^-1	P (mg kg^-1)	K⁺	Na⁺	Ca²⁺	Mg²⁺	Al³⁺	H⁺
			cmol_ckg^-1
5.58	2.93	39.2	0.23	1.64	9.07	2.78	0.0	8.61
Chemical characteristics				Physical characteristics
ECse (dS m^-1)	CEC cmol_ckg^-1	SAR (mmol L^-1)^0.5	PST %	Granulometric fraction (g kg^-1)			Moisture (dag kg^-1)
				Sand	Silt	Clay	33.42 kPa¹	1519.5 kPa²
2.15	22.33	0.67	7.34	572.7	100.7	326.6	25.91	12.96

Sources of variation	GL	Mean squares
Sources of variation	GL	F₀	Fm	Fv	Fv/Fm
Saline levels (SL)	4	326.97^ns	10600.82^*	15755.9^*	0.0001^ns
Linear regression	1	246.40^ns	663.60^ns	17767.04	0.0000^ns
Quadratic regression	1	768.58^ns	32875.02^**	34830.09	0.0000^ns
Hydrogen peroxide (H₂O₂)	2	756.52^ns	214.86^ns	341.45^ns	0.0000^ns
Interaction (SL x H₂O₂)	8	239.48^ns	2738.63^ns	6075.64^ns	0.0000^ns
Blocks	4	117.72^ns	5822.69^ns	12877.7^ns	0.0000^ns
CV (%)		3.71	3.07	4.63	0.93
Mean		442.73	2027.11	1565.63	0.7809

Sources of variation	GL	Mean squares
Sources of variation	GL	PH	SD	NL	LA
Salinity levels (SL)	4	1674.68^**	28.14^**	259.05^**	2296649.65^**
Linear regression	1	6415.74^**	108.22^**	1008.80^**	6681759.64^**
Quadratic regression	1	212.00^**	1.00^ns	2.976^ns	2141843.89^**
Hydrogen peroxide (H₂O₂)	2	12.97^ns	0.47^ns	52.92^**	1368.75^ns
Interaction (SL x H₂O₂)	8	68.50^**	3.54^**	14.00^ns	280458.11^ns
Blocks	4	10.28^ns	0.30^ns	13.58^ns	390656.05^*
CV (%)		5.19	5.71	17.61	15.17
Mean		62.10	16.91	15.96	2426.35

Sources of variation	GL	Mean squares
Sources of variation	GL	DPL	DPS	DPR	TDP
Salinity levels (SL)	4	480.87^**	593.06^**	1163.05^**	6454.04^**
Linear regression	1	1911.16^**	2340.13^**	4608.83^**	25593.68^**
Quadratic regression	1	9.62^ns	30.83^*	22.68^ns	180.05^*
Hydrogen peroxide (H₂O₂)	2	61.38^**	35.26^ns	122.27^**	477.21^**
Interaction (SL x H₂O₂)	8	5.31^ns	26.99^**	103.80^**	236.85^**
Blocks	4	4.40^ns	4.19^ns	13.87^ns	38.05^**
CV (%)		9.36	14.00	15.64	9.77
Mean		21.57	18.71	17.31	57.60

Sources of variation	GL	Mean squares
Sources of variation	GL	TDF	ADF	WC	AFD	AFL
Salinity levels (SL)	4	42299.95^**	0.2076^ns	142.001^**	3.6310^ns	0.789^ns
Linear regression	1	165812.43^**	0.2046^ns	523.089^**	0.7790^ns	1.626^ns
Quadratic regression	1	549.08^**	0.0082^ns	30.121^**	3.5152^ns	0.016^ns
Hydrogen peroxide (H₂O₂)	2	3669.32^**	0.8674^**	0.636^ns	3.4776^ns	1.428^ns
Interaction (SL x H₂O₂)	8	3300.10^**	0.1466^ns	2.555^ns	3.0261^ns	1.024^ns
Blocks	4	842.41^*	0.0836^ns	1.266^ns	6.4506^ns	1.387^ns
CV (%)		10.51	14.84	5.59	9.57	9.41
Mean		140.92	1.90	25.24	21.08	12.34

Brasil

Brasil

Okra cultivation under irrigation with saline water and foliar application of hydrogen peroxide

Cultivo de quiabo sob irrigação com água salina e aplicação foliar de peróxido de hidrogênio

Abstract

Resumo

1. INTRODUCTION

2. MATERIAL AND METHODS

3. RESULTS AND DISCUSSION

4. CONCLUSIONS

5. REFERENCES

Publication Dates

History