Hydrogen sulfide, potassium phosphite and zinc sulfate as alleviators of drought stress in sunflower plants

Almeida, Gabriel Martins; Silva, Adinan Alves da; Batista, Priscila Ferreira; Moura, Luciana Minervina de Freitas; Vital, Roberto Gomes; Costa, Alan Carlos

doi:10.1590/1413-7054202044006320

ABSTRACT

Drought is the most harmful environmental factor crop productivity. Some chemicals are used in agriculture to mitigate the damage from this stress on plants. Therefore, we examined whether the spraying of zinc sulfate (ZS), potassium phosphite (KPhi) and the hydrogen sulfide (H₂S) donor sodium hydrosulfide (NaHS) would mitigate the deleterious effects of water deficit on sunflower plants by analyzing physiological and biometric characteristics. The experiment was carried out in a greenhouse using a randomized block design with five replications. The treatments were arranged in a 4 x 2 factorial scheme: [Factor A (Alleviators)] - spraying of KPhi (0.5 L ha^-1), ZS (3.2 kg ha^-1), NaHS (1.2 g ha^-1), and water; [Factor B (substrate humidity, SH)] - 100% (well irrigated) and 30% (water deficit, WD) of field capacity. Under WD conditions, alleviators led to the maintenance of higher values of water potential (Ψ_W), a lower content of leaf malonaldehyde (MDA), and increased activity of the antioxidant enzyme peroxidase (POX), except for ZS. However, leaf osmotic potential, proline concentration, variables related to gas exchange and chlorophyll a fluorescence, and biometric characteristics differed only according to the SH factor. The results of Ψ_W and MDA for sunflower plants under WD are indicative of the mitigating capacity of ZS, KPhi, and H₂S. Thus, the spraying of these compounds on sunflower plants mitigates the effects of WD, acting specifically in physiological processes related to antioxidant responses and in the maintenance of water in leaf tissues.

Index terms:
Photosynthesis; water deficit; malonaldehyde; leaf water potential; mitigating substance

RESUMO

A seca é o fator ambiental que mais prejudica a produtividade das culturas. Alguns produtos químicos têm sido utilizados na agricultura para mitigar os danos causados por esse estresse nas plantas. Portanto, examinamos se a pulverização dos compostos sulfato de zinco (ZS), fosfito de potássio (FP) e doador de sulfeto de hidrogênio (H₂S) - hidrossulfeto de sódio (NaHS) - mitigam os efeitos deletérios do déficit hídrico em plantas de girassol, analisando características fisiológicas e biométricas. O experimento foi conduzido em casa de vegetação sob delineamento de blocos ao acaso com cinco repetições. Os tratamentos foram arranjados em esquema fatorial 4 x 2: [Fator A (aliviadores)] - pulverização de FP (0.5 L ha^-1), ZS (3.2 kg ha^-1), NaHS (1.2 g ha^-1), e água; [Fator B (umidade do substrato, US)] - 100% (bem irrigado) e 30% (déficit hídrico, DH) da capacidade de campo. Nas condições de DH, os aliviadores levaram à manutenção de maiores valores de potencial hídrico (Ψ_W), menor teor de malonaldeído foliar (MDA) e aumento da atividade da enzima antioxidante peroxidase (POX), exceto para ZS. Entretanto, o potencial osmótico foliar, a concentração de prolina, as variáveis relacionadas às trocas gasosas, fluorescência da clorofila a e as características biométricas diferiram apenas em função do fator US. Os resultados de Ψ_W e MDA em plantas de girassol sob DH são indicativos da capacidade mitigadora do ZS, FP e H₂S. Assim, a pulverização desses compostos em plantas de girassol mitiga os efeitos do DH, atuando especificamente em processos fisiológicos relacionados a respostas antioxidantes e na manutenção de água nos tecidos foliares.

Termos para indexação:
Fotossíntese; déficit hídrico; malonaldeido; potencial hídrico foliar; substância mitigador

INTRODUCTION

The sunflower (Helianthus annuus L.) has great importance in the world economy as one of the most cultivated oilseed crops (Castro; Leite, 2018CASTRO, C.; LEITE, R. D. C. Main aspects of sunflower production in Brazil Cesar. Oilseeds & Fats Crops and Lipids, 25(1):1-11, 2018.). Sunflower seeds contain 38% to 50% oil, which is widely used in human food and the production of biodiesel (Miladinović et al., 2019MILADINOVIĆ, D. et al. Sunflower and climate change: Possibilities of adaptation through breeding and genomic selection. In: CHITTARANJAN, K. Genomic Designing of Climate-Smart Oilseed Crops. Springer International Publishing, p. 173-238, 2019.). The average productivity of sunflower crops in the worldwide was 1803.9 kg/ha in 2019 (FAO, 2019FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS - FAO. FAOSTAT, Production Quantity: Sunflower. 2019. Available in: <Available in: http://www.fao.org/faostat/en/#data/QC >. Access in: March, 20, 2019.
http://www.fao.org/faostat/en/#data/QC... ). Many environmental factors contributed to the non-achievement of greater productivity in the sunflower harvest in Brazil, which highlights the increase in the frequency of drought seasons (Soares et al., 2019SOARES, M. M. et al. Effects of Competition and water deficiency on sunflower and weed growth. Revista Caatinga, 32(2):318-328, 2019.). Large economic losses were reported for Brazilian agribusiness, primarily due to periods of severe drought in the field (Ribeiro et al., 2018RIBEIRO, I. O. et al. Biomass burning and carbon monoxide patterns in Brazil during the extreme drought years of 2005, 2010, and 2015. Environmental Pollution, 243:1008-1014, 2018.). Increases in these abiotic stress events are among the consequences of anthropogenic global warming (Mora et al., 2017MORA, C. et al. Global risk of deadly heat. Nature Climate Change, 7(7):501-506, 2017.; Dai; Zhao; Chen, 2018DAI, A.; ZHAO, T.; CHEN, J. Climate change and drought: A precipitation and evaporation perspective. Current Climate Change Reports, 4(3):301-312, 2018.), which threatened agricultural productivity worldwide.

Plants exposed to water deficit show changes in several physiological and biochemical processes, such as chlorophyll degradation (Zhou et al., 2014ZHOU, L. et al. Exogenous abscisic acid significantly affects proteome in tea plant (Camellia sinensis) exposed to drought stress. Horticulture Research, 1:1-9, 2014.), cell osmotic adjustment (Batista et al., 2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.), reduction in stomatal opening and carbon dioxide (CO₂) assimilation (Tariq et al., 2018TARIQ, A. et al. Phosphorous fertilization alleviates drought effects on Alnus cremastogyne by regulating its antioxidant and osmotic potential. Scientific Reports, 8(1):1-11, 2018.). The increase in the formation of reactive oxygen species (ROS) in plants exposed to water deficit is also noteworthy (Batista et al., 2018BATISTA, P. F. et al. Nitric oxide mitigates the effect of water deficit in Crambe abyssinica. Plant Physiology and Biochemistry, 129:310-322, 2018. ). ROS promote membrane lipid peroxidation and the oxidation of macromolecules, such as nucleic acids and proteins (Rivas et al., 2017RIVAS, R. et al. Photosynthetic limitation and mechanisms of photoprotection under drought and recovery of Calotropis procera, an evergreen C3 from arid regions. Plant Physiology and Biochemistry, 118:589-599, 2017.; Tariq et al., 2018TARIQ, A. et al. Phosphorous fertilization alleviates drought effects on Alnus cremastogyne by regulating its antioxidant and osmotic potential. Scientific Reports, 8(1):1-11, 2018.). Under oxidative stress, higher concentrations of malonaldehyde (MDA) are an indicative of cellular damage, and increases in the activity of antioxidant enzymes act in the plant defense against the stress (Li et al., 2017LI, J. et al. Influence of drought stress on photosynthetic characteristics and protective enzymes of potato at seedling stage. Journal of the Saudi Society of Agricultural Sciences , 16(1):82-88, 2017.).

Finding methods to minimize the negative effects of water restriction is essential for maintaining crop productivity. An alternative technique to mitigate the damage of abiotic stresses in plants is the application of different classes of chemical compounds using, via leaf spraying (Dinis et al., 2016DINIS, L. T. et al. Kaolin-based, foliar reflective film protects photosystem II structure and function in grapevine leaves exposed to heat and high solar radiation. Photosynthetica , 54(1):47-55, 2016.; Van Oosten et al., 2017VAN OOSTEN, M. J. et al. The role of biostimulants and bioeffectors as alleviators of abiotic stress in crop plants. Chemical and Biological Technologies in Agriculture, 4(5):1-12, 2017.; Kahlaoui et al., 2018KAHLAOUI, B. et al. Physiological and biochemical responses to the exogenous application of proline of tomato plants irrigated with saline water. Journal of the Saudi Society of Agricultural Sciences, 17(1):17-23, 2018.; Sabir; Sari, 2019SABIR, A.; SARI, G. Zinc pulverization alleviates the adverse effect of water deficit on plant growth, yield and nutrient acquisition in grapevines (Vitis vinifera L.). Scientia Horticulturae , 244:61-67, 2019.). Among the numerous alleviators researched, zinc sulfate (ZS) potassium phosphite (KPhi), and hydrogen sulfide (H₂S) mitigated stress due to water deficit via maximizing the physiological processes involved in maintaining turgor and increasing antioxidant metabolism (Batista et al., 2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.).

The ZS application increases enzyme antioxidant defenses and prevents oxidative stress in plants (Ma et al., 2017MA, D. et al. Physiological responses and yield of wheat plants in zinc-mediated alleviation of drought stress. Frontiers in Plant Science, 8:1-12, 2017.). ZS also contributes to higher levels of total chlorophyll, abscisic acid and proline, and well as improves the efficiency of stomatal control (Monjezi; Vazin; Hassanzadehdelouei, 2013MONJEZI, F.; VAZIN, F.; HASSANZADEHDELOUEI, M. Effects of iron and zinc spray on yield and yield components of wheat (Triticum Aestivum L.) in drought stress. Cercetari Agronomice in Moldova, 46(1):23-32, 2013.; Zafar et al., 2014ZAFAR, S. et al. Effect of zinc and sulfur foliar applications on physiological characteristics of sunflower (Helianthus annuus L.) under water deficit stress. International Journal of Biosciences, 5(12):87-96, 2014.). Potassium phosphite (KPhi) was initially proposed as a protective fungicide, but studies described its potential as a plant biostimulant, and it induced tolerance to abiotic stresses (Gómez-Merino; Trejo-Téllez, 2015GÓMEZ-MERINO, F. C.; TREJO-TÉLLEZ, L. I. Biostimulant activity of phosphite in horticulture. Scientia Horticulturae, 196:82-90, 2015.). This effect was verified via the stimulation of antioxidant enzymes, such as superoxide dismutase (SOD), ascorbate peroxidase (APX) and guaiacol peroxidase (POX) (Oyarburo et al., 2015OYARBURO, N. S. et al. Potassium phosphite increases tolerance to UV-B in potato. Plant Physiology and Biochemistry , 88:1-8, 2015.; Machinandiarena et al., 2018MACHINANDIARENA, M. F. et al. The reinforcement of potato cell wall as part of the phosphite-induced tolerance to UV-B radiation. Biologia Plantarum, 62(2):388-394, 2018.).

In addition to foliar fertilizers, cell signaling molecules show several improving effects on plant metabolism, such as the performance of hydrogen sulfide (H₂S) in inducing antioxidant defenses and, improving the photosynthetic capacity and stomatal control of plants in water deficit conditions (García-Mata; Lamattina, 2010GARCÍA-MATA, C.; LAMATTINA, L. Hydrogen sulphide, a novel gasotransmitter involved in guard cell signalling. New Phytologist, 188(4):977-984, 2010.; Corpas, 2019CORPAS, F. J. Hydrogen sulfide: A new warrior against abiotic stress. Trends in Plant Science, 24(11):983-988, 2019.). Therefore, the application of the H₂S donor NaHS (sodium hydrosulfide) promoted increases in the relative water content and antioxidant defenses in soybean under drought (Batista et al., 2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.). Smaller amounts of ROS and MDA were also verified (Zhang et al., 2010ZHANG, H. et al. Hydrogen sulfide protects soybean seedlings against drought-induced oxidative stress. Acta Physiologiae Plantarum, 32(5):849-857, 2010.). These studies support NaHS as a potential reliever of abiotic stresses in cultivated plants (Singh; Tripathi; Fotopoulos, 2020SINGH, V. P.; TRIPATHI, D. K.; FOTOPOULOS, V. Hydrogen sulfide and nitric oxide signal integration and plant development under stressed/non-stressed conditions. Physiologia Plantarum , 168(2):239-240, 2020.).

The present study tested the hypothesis that ZS, KPhi and H₂S would improve the tolerance of sunflower to water deficit. This study is the first report on the application of these three compounds to sunflower plants under water deficit conditions. Thus, the objective was to verify whether the foliar spraying of ZS, KPhi and NaHS alleviated the deleterious effects of water deficit on sunflowers and, provided better water and osmotic adjustment, protection against cellular damage, maintenance of CO₂ assimilation and plant growth.

MATERIAL AND METHODS

Plant material and experimental conditions

The experiment was performed in a pad-cooled greenhouse where the air temperature was programmed not to exceed 27 ºC. The greenhouse is located at the Instituto Federal Goiano - Campus Rio Verde, Goiás, Brazil. The sunflower hybrid used in this study was the Sany 66 (Atlântica Sementes^®), with a cycle of approximately 110 days. Sunflower plants were grown in plastic pots containing 5 dm^-3 of substrate (Bioplant^®), one plant per pot. Each pot was fertilized with 4.6 g of the formulated fertilizer 10-10-10 (NPK) and 0.32 g of the formulated FTE BR12 (S = 3.2%; B = 1.8%; Cu = 0.18%; Mn = 2.0%; Mo = 0.1%; Zn = 9.0%).

Experimental design

The experimental design was arranged in randomized blocks, with five (5) replicates. It consisted of a 4 x 2 factorial design: [Factor A (alleviators and water)] 1) spraying of 0.5 L ha^-1 potassium phosphite (KPhi), 2) 3.2 kg ha^-1 zinc sulfate (ZS), 3) 1.2 g ha^-1 sodium hydrosulfide (NaHS), and 4) water (without product, WP) and [Factor B (Substrate humidity, SH)] 1) 100% well-watered control (WW), and 2) 30% (water deficit, WD) of field capacity (FC).

Imposition of treatments and analysis

Thirty-eight days after sowing and at the R1 stage, sunflower plants were sprayed one day before the imposition of the water regimes using a sprayer pressurized by CO₂, four-tip bar type XR11002-VP, with a double fan and a spray volume equivalent to 200 L ha^-1 via pressure regulation of 2 bar. The meteorological data at the time of application were 24.8 °C temperature and 88.3% relative humidity, as measured using a Kestrel 4000 weather meter (Kestrel Instruments, Nielsen-Kellerman Company). For the imposition of water treatments, the FC of the cultivation substrate was determined using a gravimetric method (Costa et al., 2015COSTA, A. C. et al. The effect of irradiance and water restriction on photosynthesis in young jatobá-do-cerrado (Hymenaea stigonocarpa) plants. Photosynthetica, 53(1):118-127, 2015.). To control substrate moisture during the stress period, each pot was weighed twice daily (11 am and 5 pm), and the water lost through evapotranspiration was replaced, to maintain the plants as well-watered (WW) or under water deficit (WD) using 100 and 30% of FC, respectively. Ten days after the imposition of treatments (DAIT), analyses of water relations, gas exchanges, chlorophyll a fluorescence, concentration of chloroplast pigments, content of proline and malonaldehyde, antioxidant enzyme activity and biometric measurements were performed.

Water relations

Predawn leaf water potential (Ψ_W) was measured using a Scholander pressure chamber (model 3005-1412, Soilmoisture Equipment Corp.), between 04:00 and 06:00 in the morning. For the evaluation of leaf osmotic potential (Ѱ_S), the cellular exudate was extracted from the leaves and 10 µL analyzed using a vapor pressure osmometer (model 5600, VAPRO, Wescor, Logan, Utah, USA) (Pask et al., 2012PASK, A. J. D. et al. Physiological breeding II: A field guide to wheat phenotyping. Cimmyt, 2012. 134p.). Osmotic potential values were obtained using the Van’t Hoff’s equation: Ψ_S = − R×T×Cs, where R is the universal gas constant (0.08205 l atm mol^-1 K^-1), T is the temperature (T °K = T °C + 273), and Cs the solute concentration (M), usually expressed in atmospheres and converted to MPa (0.987 ≈1 atm = 0.1 MPa).

Gas exchange

Gas exchanges of the plants were measured using a portable infrared gas analyzer with coupled modulated fluorometer (IRGA, model LI6800xt, Li-Cor, Nebraska, United States), on the latest fully expanded plant leaf. Net photosynthetic rate [A, µmol (CO₂) m^-2s^-1], transpiration rate [E, mmol (H₂O) m^-2s^-1], stomatal conductance [g _s, mol (H₂O) m^-2s^-1], and the ratio between internal and external CO₂ concentration (C _i/C _a) were measured under photosynthetically active radiation (PAR) of 1500 µmol m^-2s^-1 and a block temperature of 25 °C. The instant water use efficiency was obtained by the formula EUA = [A/E, µmol (CO₂) mmol (H₂O)^-1 m^-2s^-1].

Chlorophyll a fluorescence

The fluorescence variables of chlorophyll a were recorded on the same leaf of photosynthesis using a portable modulated fluorometer coupled to the IRGA (LI6800xt, Li-Cor, Nebraska, United States). The evaluations were performed in the dark-adapted leaves, so that the reaction centers were fully open (primary oxidized receptors) with minimal heat loss. Leaves were initially dark-adapted to estimate the initial fluorescence (F₀), maximum fluorescence (Fm) and potential quantum yield of photosystem II (PSII) F _V/F _M = [(F₀ − Fm)/Fm] (Genty; Briantais; Baker, 1989GENTY, B.; BRIANTAIS, J. M.; BAKER, N. R. The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. Biochimica et Biophysica Acta - General Subjects, 990(1):87-92, 1989.). The slow phase variables were obtained after the application of an actinic illumination, followed by a pulse of saturated actinic light for the determination of steady-state fluorescence (F) and maximum fluorescence in a sample adapted to light (Fm’), respectively, allowing to calculate the effective quantum yield of photochemical energy conversion in PSII (Φ_II) = (Fm’ − F)/Fm′]. The Φ_II was also used to estimate the apparent electron transport rate, ETR = Φ_II. PAR×Aleaf ×0.5 (Bilger; Schreiber; Bock, 1995BILGER, W.; SCHREIBER, U.; BOCK, M. Determination of the quantum efficiency of photosystem II and of non-photochemical quenching of chlorophyll fluorescence in the field. Oecologia, 102(4):425-432, 1995.), where PAR is the photon flow (μmol m^-2 s^-1) on the leaves, A_leaf is the amount corresponding to the fraction of incident light that is absorbed by the leaves and 0.5 is the excitation energy fraction directed to the PSII (Laisk; Loreto, 1996LAISK, A.; LORETO, F. Determining photosynthetic parameters from leaf CO2 exchange and chlorophyll fluorescence1: Ribulose-1,5-bisphosphate carboxylase/oxygenase specificity factor, dark respiration in the light, excitation distribution between photosystems, alternative electron transport rate, and mesophyll diffusion resistance. Plant Physiology , 110(3):903-912, 1996.). The non-photochemical quenching coefficient (NPQ) was calculated as NPQ = (Fm − Fm’)/Fm’; and the relative energy excess at the PSII level as (EXC = (F _V/F _M) - (Fq’/ Fm’)/(F _V/F _M) (Bilger; Schreiber; Bock, 1995BILGER, W.; SCHREIBER, U.; BOCK, M. Determination of the quantum efficiency of photosystem II and of non-photochemical quenching of chlorophyll fluorescence in the field. Oecologia, 102(4):425-432, 1995.).

Pigment concentration

Pigment concentration was determined by extraction with dimethylsulfoxide (DMSO) saturated with calcium carbonate (CaCO₃) according to Castro et al. (2019CASTRO, J. N. et al. Physiological tolerance to drought under high temperature in soybean cultivars. Australian Journal of Crop Science, 13(6):976-987, 2019.). Three leaf discs (0.6 cm²) were incubated in 5 mL of DMSO solution, and the pigments were extracted for 24 h in a water bath set to 65 ºC. The spectrophotometric readings were later obtained at 480.0, 649.1, and 665.1 nm using a UV-VIS spectrophotometer (model Evolution 60S, Thermo Fisher Scientific Inc.). The chlorophyll a (Chla = 12.19A ₆₆₅ - 3.45A ₆₄₉), and chlorophyll b (Chlb = 21.99A ₆₄₉ - 5.32A ₆₆₅) and total carotenoids (Carot = (1000A ₄₈₀ - 2.14C_a - 70.16C_b)/220) concentrations were calculated according to Wellburn (1994WELLBURN, R. W. The spectral determination of chlorophylls a and b, as well as total carotenoids, using various solvents with spectrophotometers of different resolution. Journal of Plant Physiology , 144(3):307-313, 1994.) and expressed in micrograms per leaf area.

Determination of proline content

For free proline measurement, 200 mg of fresh leaf material was homogenized in 4 mL of 80% ethanol according Bates, Waldren and Teare (1973BATES, L. S.; WALDREN, R. P.; TEARE, I. D. Rapid determination of free proline for water-stress studies. Plant and Soil, 39(1):205-207, 1973.), with some modifications. After centrifugation (6300 g, 10 min), an aliquot of 250 μl of filtrate extract was mixed with 2 mL acid ninhydrin (1.25 g ninhydrin, 30 mL glacial acetic acid, 20 mL 6 M orthophosphoric acid in 200 mL), 2 mL of glacial acetic acid and 2.65 mL of water. The samples were incubated at 90 °C in a water bath for 35 min and, after this period, placed on ice to stop the reaction. We added 4 mL of toluene to the solution, followed by stirring for complete separation of the chromophore-containing toluene to be analysed. The absorbance of the supernatant was measured at 515 nm in a UV-VIS spectrophotometer (model Evolution 60S, Thermo Fisher Scientific Inc.). The proline concentration was calculated by comparison with a proline standard curve (0 to 100 μg mL^-1) and was expressed as μmol g FM^-1.

Determination of malondialdehyde (MDA)

The content of MDA was evaluated to determine the lipid peroxidation using the method proposed by Heath and Packer (1968HEATH, R. L.; PACKER, L. Photoperoxidation in isolated chloroplasts. I. Kinetics and stoichiometry of fatty acid peroxidation. Archives of Biochemistry and Biophysics, 125(1):189-198, 1968.). Leaf samples (0.160 g) were homogenized in 2 mL 0.1% (w/v) trichloroacetic acid (TCA), and the homogenate was centrifuged at 12 000 g for 15 min at 4 °C. The supernatant (500 μL) was mixed with 2 mL of TBA reagent (0.5% [w/v] of TBA in 20% TCA). The reaction mixture was heated at 90 °C for 20 min in a water bath and then quickly cooled in an ice bath and centrifuged at 3000 g for 4 min. The absorbance of the colored supernatant was monitored at 440, 532 and 600 nm using a UV-VIS spectrophotometer (Evolution 60S, Thermo Fisher Scientific, Madison, EUA). The concentration of MDA was calculated using the molar extinction coefficient of 155 mM^-1 cm^-1 according to the following equation: MDA (nmol mL^-1) = [(A532-A600)/155000] 10⁶. The concentration of MDA in leaves was expressed nmol TBA-MDA g^-1 FW (Heath; Packer, 1968HEATH, R. L.; PACKER, L. Photoperoxidation in isolated chloroplasts. I. Kinetics and stoichiometry of fatty acid peroxidation. Archives of Biochemistry and Biophysics, 125(1):189-198, 1968.).

Determination of peroxidase activity

Peroxidase (POX, EC 1.11.1.7) activity was determined by addition of the crude enzyme extract to a reaction mixture containing 25 mM potassium phosphate buffer (pH 6.8), 20 mM pyrogallol and 20 mM hydrogen peroxide (Kar; Mishra, 1976KAR, M.; MISHRA, D. Catalase, peroxidase, and polyphenoloxidase activities during rice leaf senescence. Plant Physiology , 57(2):315-319, 1976.). The reaction was measured at 420 nm in a UV-VIS spectrophotometer for 1 min at 25 °C. An extinction coefficient of 2.47 mM^-1 cm^-1 (Chance; Maehley, 1955CHANCE, B.; MAEHLEY, A. C. Assay of catalases and peroxidases. Methods in Enzymology, 2:764-775, 1955.) was used to calculate POX activity and was expressed as µmol min^-1 mg^-1 of protein. Protein concentration was determined according to Bradford (1976BRADFORD, M. M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, 72(1-2):248-254, 1976.).

Biometry

The plants were measured to determine the biometric variables: plant height (H, cm), number of leaves, number of nodes, and stem diameter (mm). Leaves and stem were separated into paper bags and oven dried at 65 °C for 72h to obtain leaf dry matter (g) and stem dry matter (g).

Statistical analysis

The data were evaluated for homogeneity and normality of errors (Bartlet and Shapiro-Wilk test) and, when significant, Box-Cox transformation was used (Box; Cox, 1964BOX, G. E.; COX, D. R. An analysis of transformations. Journal of the Royal Statistical Society: Series B Statistical Methodological, 26(2):211-243, 1964.). After meeting the prerequisites, analysis of variance was performed to examine the effects of the isolated factors and their interaction (F test, α <0.05). When there was a difference between treatments, multiple comparisons of means were used (Tukey’s test, α <0.05). The analyses were performed using Software ActionStat Pro^® (ActionStat v. 3.3.2). Graphs were generated using SigmaPlot^® software (Systat Software v.10.0).

RESULTS AND DISCUSSION

The leaf water potential (Ψ_W) of sunflower plants differed separately due to the alleviating and substrate humidity (SH) factors (Figure 1a-b ). Therefore, Ψ_W was higher in plants sprayed with potassium phosphite (KPhi), zinc sulfate (ZS) and the hydrogen sulfide donor (H₂S) NaHS in both field capacities (FC) (Figure 1a). H₂S showed results similar to plants without product (WP) application, which showed lower values of Ψ_W (Figure 1a). The higher values of Ψ_W of sunflower plants were observed due to the spraying of the H₂S donor, and primarily KPhi and ZS, which indicate a higher water content in the leaf tissues of the plants (Figure 1a-b). Batista et al. (2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.), observed similar results in soybean plants under stress during 8 days of treatments, in which the application of these same alleviators promoted the maintenance of relative water content of plants under water deficit (WD) equal to well-watered (WW) plants. Although the Ψ_W was higher in the water deficit (WD) condition after spraying NaHS, KPhi, and ZS, the values were not statistically equal to those of the well-watered (WW) plants in the present study of sunflower plants (Figure 1b). There was also a mitigating effect regardless of substrate moisture level (Figure 1a).

Figure 1:
Water potential [Ψ_W, (a and b)], osmotic potential [Ψ_S, (c)] and proline concentration [Pro, (d)] of sunflower plants after 10 days of substrate humidity (SH) conditions of 100% (well-watered, WW) and 30% (water deficit, WD) of the field capacity (FC) combined with the spraying of the alleviators: potassium phosphite (KPhi), zinc sulfate (ZS), hydrogen sulfide (HS) donor NaHS, and without product (WP). Means followed by different capital letters between Alleviators (n = 10) or SH (n = 20) differ significantly from each other (Tukey’s test α <0.01). Vertical bars indicate means ± SE.

The proline (Pro) leaf concentration was higher in the WD condition and differed only as a function of FC (Figure 1d). The general strategy of plants for maintaining water in WD conditions is an osmotic adjustment, due to the accumulation of osmolytes (Chaumont; Tyerman, 2014CHAUMONT, F.; TYERMAN, S. D. Aquaporins: Highly regulated channels controlling plant water relations. Plant Physiology, 164(4):1600-1618, 2014.; Nawaz et al., 2016NAWAZ, M. et al. Proteomic analysis of soybean root including hypocotyl during recovery from drought stress. Article in Journal of proteomics, 144:39-50, 2016.; Silva et al., 2019SILVA, D. C. et al. Silicon foliar application attenuates the effects of water suppression on cowpea cultivars. Ciência e Agrotecnologia, 43:e023019, 2019.). However, there was no differential osmotic adjustment due to the spraying of KPhi, NaHS, and ZS in the present study, which was observed in the results of osmotic potential (Ψ_S) (Figure 1c), with only an effect of the imposed water regimes. The Pro accumulation is one of the strategies used in collaboration with the osmo-protection, and it act as an antioxidant (Azmat; Moin, 2019AZMAT, R.; MOIN, S. The remediation of drought stress under VAM inoculation through proline chemical transformation action. Journal of Photochemistry and Photobiology B: Biology, 193:155-161, 2019. ). Unlike wheat and soybean plants under WD conditions, which showed an increase in Pro due to treatment with ZS (Ma et al., 2017MA, D. et al. Physiological responses and yield of wheat plants in zinc-mediated alleviation of drought stress. Frontiers in Plant Science, 8:1-12, 2017.; Batista et al., 2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.), KPhi and H₂S (Batista et al., 2020).

The gas exchange parameters of sunflower plants differed only as a function of FC (Figure 2), and the photosynthetic rate (A), stomatal conductance (g _s), transpiration rate (E), ratio between internal and external CO₂ (C _i/C _a) and carboxylation efficiency (A/C _i) were lower in the WD condition (Figure 2a-d e Figure 2f). However, the water use efficiency (WUE) was higher in the WD condition (Figure 2e). The lowest A was primarily due to the restriction of stomatal opening, which was observed in soybean and Jatropha curcas plants under WD conditions (Silva et al., 2015SILVA, E. N. et al. Photoprotective function of energy dissipation by thermal processes and photorespiratory mechanisms in Jatropha curcas plants during different intensities of drought and after recovery. Environmental and Experimental Botany, 110:36-45, 2015.; Castro et al., 2019CASTRO, J. N. et al. Physiological tolerance to drought under high temperature in soybean cultivars. Australian Journal of Crop Science, 13(6):976-987, 2019.). There was likely no damage to the biochemical stage of photosynthesis. One indication of damage to the Calvin-Benson cycle is the accumulation of CO₂ in the substomatal chamber (Silva et al., 2015SILVA, E. N. et al. Photoprotective function of energy dissipation by thermal processes and photorespiratory mechanisms in Jatropha curcas plants during different intensities of drought and after recovery. Environmental and Experimental Botany, 110:36-45, 2015.; Rivas et al., 2017RIVAS, R. et al. Photosynthetic limitation and mechanisms of photoprotection under drought and recovery of Calotropis procera, an evergreen C3 from arid regions. Plant Physiology and Biochemistry, 118:589-599, 2017.), which cannot be verified in the ratio between the internal and external concentration of CO₂ (C _i/C _a) (Figure 2d). Despite the C _i/C _a ratio being 3.2% lower in the WD condition in the present study, a greater difference was expected compared to the WW condition. This result is due to the limitation of g _s affecting A and E more intensely than C _i/C _a (Figure 2a-d), which corroborates the lower A/C _i observed in sunflowers (Figure 2f), which was unlike cocoa plants under WD conditions (Zanetti et al., 2016ZANETTI, L. V. et al. Leaf application of silicon in young cacao plants subjected to water deficit. Pesquisa Agropecuária Brasileira, 51(3):215-223, 2016.). Notably, the values of A in WD conditions suggest that the imposed stress was not severe. These values were close to the values found by Vital et al. (2017VITAL, R. G. Physiological changes and in the carbohydrate content of sunflower plants submitted to sub-doses of glyphosate and trinexapac-ethyl. Bragantia, 76(1):33-44, 2017.) in sunflower plants, but in the control treatment.

Figure 2:
Photosynthetic rate [A, (a)], stomatal conductance [g _s , (b)], transpiration rate [E, (c)], relationship between internal and external CO₂ concentration [C _i /C _a , (d)], water use efficiency [WUE, (e)] and carboxylation efficiency of Rubisco [A/C _i, (f)] of sunflower plants after 10 days in substrate humidity (SH) conditions of 100% (well-watered, WW) and 30% (water deficit, WD) of the field capacity (FC) combined with the spraying of the alleviators: potassium phosphite (KPhi), zinc sulfate (ZS), hydrogen sulfide (HS) donor NaHS, and without product (WP). Means followed by different capital letters between SH (n = 20) differ significantly from each other using the Tukey’s test (α <0.05 and α <0.01). Vertical bars indicate means ± SE.

The regulation of stomatal opening is a strategy to prevent plant dehydration via the loss of water in the atmosphere (Henry et al., 2019HENRY, C. et al. A stomatal safety-efficiency trade-off constrains responses to leaf dehydration. Nature Communications, 10(1):1-9, 2019.). There was a lower E of sunflower plants due to the limitation of g _s as a function of WD. Therefore, the objective of the entire strategy of stomatal regulation under WD conditions is to increase the WUE (Buezo et al., 2019BUEZO, J. et al. Drought tolerance response of high-yielding soybean varieties to mild drought: Physiological and photochemical adjustments. Physiologia Plantarum , 166(1):88-104, 2019.). Furthermore, this increase in WUE, as expected, was verified in the sunflower plants in the present study (Figure 2e).

The potential quantum yield of photosystem II (PSII) (F _V/F _M) did not differ between treatments (Figure 3a). However, the effective quantum yield of PSII (Φ_II) and the electron transport rate (ETR) differed as a function of FC and were lower in the WD condition (Figure 3b e d ). The nonphotochemical dissipation (NPQ), the excess energy relative to the PSII (EXC) and the ETR/A ratio were higher in the WD condition (Figure 3c e 3e-f). Therefore, the effects of WD on photosynthesis also occurred via a decrease in the efficiency of the photochemical step, which was observed in the effective quantum yield of the PSII (Φ_II) and the electron transport rate (ETR) (Figure 3b and 3d). The ETR/A ratio was also indicative of the lower photosynthetic efficiency in the WD condition (Figure 3f) because sunflower plants demanded more electrons for each CO₂ molecule assimilated. This effect was also seen in plants of Calotropis procera under the same stress condition (Rivas et al., 2017RIVAS, R. et al. Photosynthetic limitation and mechanisms of photoprotection under drought and recovery of Calotropis procera, an evergreen C3 from arid regions. Plant Physiology and Biochemistry, 118:589-599, 2017.). Therefore, the ETR/A results corroborate the A/C _i, parameter, indicate a disturbance in the assimilation of CO₂ that was not only due to the stomatic restriction. Notably, KPhi, H₂S, and ZS were reported to alleviate the harmful effects of stress on photosynthetic machinery (Oyarburo et al., 2015OYARBURO, N. S. et al. Potassium phosphite increases tolerance to UV-B in potato. Plant Physiology and Biochemistry , 88:1-8, 2015.; Ma et al., 2017MA, D. et al. Physiological responses and yield of wheat plants in zinc-mediated alleviation of drought stress. Frontiers in Plant Science, 8:1-12, 2017.), and act as inducers of the antioxidant defense system (Machinandiarena et al., 2018MACHINANDIARENA, M. F. et al. The reinforcement of potato cell wall as part of the phosphite-induced tolerance to UV-B radiation. Biologia Plantarum, 62(2):388-394, 2018.; Corpas, 2019CORPAS, F. J. Hydrogen sulfide: A new warrior against abiotic stress. Trends in Plant Science, 24(11):983-988, 2019.), but no stress-alleviating effects of these substances were observed in the photosynthetic process of sunflower plants.

Figure 3:
Potential quantum yield [F _V /F _M , (a)] and effective [Φ_II, (b)] of the PSII, nonphotochemical dissipation [NPQ, (c)], electron transport rate [ETR, (d)], excess energy related to PSII [EXC, (e)], and the ratio ETR/A (f) of sunflower plants after 10 days under substrate humidity (SH) conditions of 100% (well-watered, WW) and 30% (water deficit, WD) of the field capacity (FC) combined with the spraying of alleviators: potassium phosphite (KPhi), zinc sulfate (ZS), hydrogen sulfide (HS) donor NaHS, and without product (WP). Means followed by different capital letters between SH (n = 20) differed significantly from each other using the Tukey’s test (α <0.05). Vertical bars indicate means ± SE.

The increase in energy dissipation in NPQ is a strategy of tolerance to WD (Figure 3c). This response occurs due to the increased performance of the xanthophyll cycle, which is a strategy to prevent damage to the photosynthetic apparatus due to the excess of light energy (EXC) (Rivas et al., 2017RIVAS, R. et al. Photosynthetic limitation and mechanisms of photoprotection under drought and recovery of Calotropis procera, an evergreen C3 from arid regions. Plant Physiology and Biochemistry, 118:589-599, 2017.; Głowacka et al., 2018GŁOWACKA, K. et al. Photosystem II Subunit S overexpression increases the efficiency of water use in a field-grown crop. Nature Communications, 9(1):1-9, 2018.). The regeneration of ADP and NADP⁺ for the photochemical step is impaired with the lowest of the Calvin-Benson cycle, which generate a negative regulation of photosynthesis (Silva et al., 2015SILVA, E. N. et al. Photoprotective function of energy dissipation by thermal processes and photorespiratory mechanisms in Jatropha curcas plants during different intensities of drought and after recovery. Environmental and Experimental Botany, 110:36-45, 2015.). Sunflower plant strategies were effective during WD stress to avoid the occurrence of photoinhibition. This success was verified in the stability of the F _V/F _M ratio (Figure 3a) because the reduction of this variable is indicative of photoinhibition (Maxwell; Johnson, 2000MAXWELL, K.; JOHNSON, G. N. Chlorophyll fluorescence: A practical guide. Journal of Experimental Botany, 51(345):659-668, 2000.), which was not observed in this study.

Among the chloroplast pigments, there was no difference between treatments for the content of chlorophyll a (Chl a) and carotenoids (Carot) (Table 1). The chlorophyll b (Chl b) content differed for factor FC, with lower values observed for plants under WD (Table 1). Corroborating with the F _V/F _M results, there was no degradation of Chl a content, which are part of the reaction center of the photosystems. However, WD reduced the content of Chl b (Table 1), which plays an important role in the light harvesting complex (LHC) of photosystems (Nagao et al., 2020NAGAO, R. et al. Structural basis for assembly and function of a diatom photosystem I-light-harvesting supercomplex. Nature Communications, 11(1):1-12 2020.). This strategy decrease light absorption to avoiding photooxidative damage during stress conditions (Buezo et al., 2019BUEZO, J. et al. Drought tolerance response of high-yielding soybean varieties to mild drought: Physiological and photochemical adjustments. Physiologia Plantarum , 166(1):88-104, 2019.).

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Table 1:
Chlorophyll a (Chl a), chlorophyll b (Chl b) and carotenoids (Carot) content of sunflower plants after 10 days in substrate humidity (SH) conditions of 100% (well-watered, WW) and 30% (water deficit, WD) of the field capacity (FC) combined with the spraying of alleviators: potassium phosphite (KPhi), zinc sulfate (ZS), hydrogen sulfide (HS) donor NaHS, and without product (WP).

There was an interaction between the Alleviating x SH factors for the content of malondialdehyde (MDA) (Figure 4a) and activity of peroxidase (POX) (Figure 4b). The water deficit did not increase the MDA values in response to the application of the compounds, only without product. When compared between the substrate humidity per product, no difference was observed, except in plants sprayed with only water. The lower accumulation of MDA in sunflower plants due to the spraying of NaHS, KPhi, and ZS suppots the potential role of these substances in mitigating the oxidative stress caused by WD (Figure 4a), which was observed in soybean plants in development stage V4 and R1 (Batista et al., 2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.). The content of MDA was statistically equivalent between the plants under WD and WW with the application of NaHS, KPhi, and ZS. This result indicates an important role of these substances in the antioxidant metabolism of sunflower plants because plants that received only water spray in the WD condition accumulated 46% more MDA than the WW condition. The MDA content observed in this work under optimal conditions (WW condition with spraying only water) was compatible with that observed by Vital et al. (2017VITAL, R. G. Physiological changes and in the carbohydrate content of sunflower plants submitted to sub-doses of glyphosate and trinexapac-ethyl. Bragantia, 76(1):33-44, 2017.), also under control conditions, which indicates that the plants in the WP treatment were under oxidative stress in the WD condition.

Figure 4:
Malonaldehyde content [MDA, (a)] and peroxidase activity [POX, (b)] of sunflower plants after 10 days in substrate humidity (SH) conditions of 100% (well-watered, WW) and 30% (water deficit, WD) of the field capacity (FC) combined with the spraying of alleviators: potassium phosphite (KPhi), zinc sulfate (ZS), hydrogen sulfide (HS) donor NaHS, and without product (WP). Means followed by different capital letters between SH and lower letters between Alleviators differed significantly from each other using Tukey’s test (α <0.01). Vertical bars indicate means ± SE.

POX activity was higher in plants under water deficit than in well-watered plants in the absence of alleviators and after the spraying of KPhi and NaHS. Plants treated with ZS did not differ between water availability conditions, which indicates that other antioxidant enzymes may have acted because the MDA content did not increase in the WD condition. One possible enzyme with increased activity is superoxide dismutase, which use zinc as a metal cofactor (Marreiro et al., 2017MARREIRO, D. N. et al. Zinc andoxidative stress: Current mechanisms. Antioxidants, 6(2):24-32, 2017.; Batista et al., 2020BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.). The spraying of KPhi induced less POX activity in well-watered plants than WP and ZS. Under water deficit, greater POX activities occurred in the WP and NaHS treatments. The induction in POX activity may have contributed to plant protection against damage to cell membranes (Figure 4b). The role of H₂S in increasing the antioxidant metabolism of plants under WD conditions was reported (Corpas, 2019CORPAS, F. J. Hydrogen sulfide: A new warrior against abiotic stress. Trends in Plant Science, 24(11):983-988, 2019.). This increase was observed in wheat and soybean plants, in which the application of NaHS promoted a reduction in the content of MDA and H₂O₂ due to the increased activity of antioxidant enzymes, including peroxidase (Ma et al., 2016MA, D. et al. Alleviation of drought stress by hydrogen sulfide is partially related to the abscisic acid signaling pathway in wheat. PLoS ONE, 11(9):1-16, 2016.; Zhang et al., 2010ZHANG, H. et al. Hydrogen sulfide protects soybean seedlings against drought-induced oxidative stress. Acta Physiologiae Plantarum, 32(5):849-857, 2010.). The application of NaHS increased the biosynthesis of abscisic acid and promoted stomatal closure in wheat plants (Ma et al., 2016MA, D. et al. Alleviation of drought stress by hydrogen sulfide is partially related to the abscisic acid signaling pathway in wheat. PLoS ONE, 11(9):1-16, 2016.). KPhi also acted in the potentiation of the sunflower antioxidant system in the WD condition via increasing POX activity, which corroborates observations in potato plants (Oyarburo et al., 2015OYARBURO, N. S. et al. Potassium phosphite increases tolerance to UV-B in potato. Plant Physiology and Biochemistry , 88:1-8, 2015.; Machinandiarena et al., 2018MACHINANDIARENA, M. F. et al. The reinforcement of potato cell wall as part of the phosphite-induced tolerance to UV-B radiation. Biologia Plantarum, 62(2):388-394, 2018.).

WD stress decreased the growth of sunflower plants based on the reduction in biometric characteristics at the end of the stress period (Figure 5). Among the biometric variables, plant height, stem diameter, leaf dry matter, and stem dry matter differed as a function of FC, with lower values detected in the WD condition (Figure 5c-f). However, the number of leaves and the nodes of sunflower plants did not differ as function of the treatments (Figure 5a-b). There was no alleviation of the WD condition in reducing the biometric characteristics of plants with the spraying of NaHS, KPhi, and ZS. The decrease in growth primarily occurred due to the restriction of CO₂ assimilation and reduction in the accumulation of biomass, which was reported in other plants with high oil production potential (Moura et al., 2018MOURA, L. M. F. Drought tolerance in potential oilseed plants for biofuel production. Australian Journal of Crop Science , 12(2):289-298, 2018.).

Figure 5:
Number of leaves (a), number of nodes (b), plant height (c), stem diameter (d), leaf dry matter [LDM, (e)] and stem dry matter [SDM, (f)] of sunflower plants after 10 days in substrate humidity (SH) conditions of 100% (well-watered, WW) and 30% (water deficit, WD) of the field capacity (FC) combined with the spraying of alleviators: potassium phosphite (KPhi), zinc sulfate (ZS), hydrogen sulfide (HS) donor NaHS, and without product (WP). Means followed by different capital letters between SH (n = 20) differed significantly from each other using Tukey’s test (α < 0.01). Vertical bars indicate means ± SE.

CONCLUSIONS

The spraying of potassium phosphite, zinc sulfate, and the hydrogen sulfide donor sodium hydrosulfide on sunflower plants mitigated the effects of drought stress by acting specifically in physiological processes related to antioxidant responses and the maintenance of water in leaf tissues. However, there was no alleviation of water deficit for photosynthetic processes. These results indicate the potential of these substances to mitigate water deficit in sunflower crop and the importance of carrying out field experiments.

ACKNOWLEDGMENTS

The authors are grateful to the CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico, Brazil), CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, Brazil), FAPEG (Fundação de Amparo à Pesquisa do Estado de Goiás), Instituto Federal Goiano - Campus Rio Verde and the PPGCA (Programa de Pós-Graduação em Ciências Agrárias - Agronomia).

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Publication Dates

Publication in this collection
28 Aug 2020
Date of issue
2020

History

Received
18 Mar 2020
Accepted
17 July 2020

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

[1] AZMAT, R.; MOIN, S. The remediation of drought stress under VAM inoculation through proline chemical transformation action. Journal of Photochemistry and Photobiology B: Biology, 193:155-161, 2019.

[2] BATES, L. S.; WALDREN, R. P.; TEARE, I. D. Rapid determination of free proline for water-stress studies. Plant and Soil, 39(1):205-207, 1973.

[3] BATISTA, P. F. et al. Biochemical and physiological impacts of zinc sulphate, potassium phosphite and hydrogen sulphide in mitigating stress conditions in soybean. Physiologia Plantarum, 168(2):456-472, 2020.

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	Chl a	Chl b	Carot
	[µg cm^-2 FW]
	WW - 100% of FC
WP	38.66 ± 2.77	14.47 ± 0.32	7.57 ± 0.52
KPhi	38.75 ± 1.68	14.85 ± 1.54	7.42 ± 0.34
ZS	40.42 ± 2.43	15.20 ± 0.90	7.92 ± 0.31
HS	45.07 ± 2.26	15.92 ± 1.21	8.79 ± 0.52
Mean	40.73 ± 1.22	15.11 ± 0.52A	7.93 ± 0.23
	WD - 30% of FC
WP	40.04 ± 1.82	14.06 ± 0.48	7.59 ± 0.47
KPhi	42.33 ± 2.03	14.90 ± 1.13	8.08 ± 0.36
ZS	36.88 ± 4.18	13.42 ± 0.92	7.58 ± 0.81
HS	40.54 ± 2.64	13.75 ± 0.58	7.87 ± 0.46
Mean	39.95 ± 1.37	14.03 ± 0.40B	7.78 ± 0.26
C.V. (%)	13.38	9.59	13.78
Alleviators	N.S.	N.S.	N.S.
SH	N.S.	*	N.S.
Alleviators x SH	N.S.	N.S.	N.S.

Brasil