Proline and sodium nitroprusside increase the tolerance of <i>Physalis peruviana</i> L. plants to water deficit through chemical priming

Leite, Romeu da Silva; Navarro, Salvador Hernandéz; Nascimento, Marilza Neves do; Potosme, Norlan Miguel Ruiz; Silva, Alismário Leite da; Santos, Robson de Jesus

doi:10.1590/1413-7054202246004622

ABSTRACT

Water deficit is the main cause of abiotic stress to which plants are susceptible, whether cultivated or those that are underexploited, such as Physalis peruviana L. Searching for tools that contribute to the management of water deficit in plants is fundamental for the maintenance of agriculture, especially in arid and semi-arid areas around the world. Thus, the objective of this study was to evaluate the effect of chemical priming with proline and sodium nitroprusside as promoters of increased tolerance to water deficit in P. peruviana plants. Plants grown under well hydrated conditions (FC of 70±5%) were sprayed with proline (10 and 20 mM) or sodium nitroprusside (25 and 50 μM) and evaluated after exposure to water deficit (FC of 20±5%). Plants cultivated under water deficit without pretreatment showed reductions in the variables of water relations, gas exchange and growth. Proline and sodium nitroprusside were effective in maintaining less negative water potential, contributing to improvements in gas exchange, such as CO₂ assimilation, stomatal conductance and transpiration. Thus, it was possible to measure greater tolerance to water deficit in pretreated plants and, consequently, greater biomass accumulation. It appeard that pretreatment of proline and sodium nitroprusside can have a priming effect against water deficit in P. peruviana plants.

Index terms:
Abiotic stress; water deficit mitigation; goldenberry.

RESUMO

O déficit hídrico é o principal promotor de estresse abiótico ao qual as plantas estão suscetíveis, sejam as cultivadas ou aquelas subexploradas, como as fisális. A busca por ferramentas que contribuam para a gestão do déficit hídrico em plantas é fundamental para a manutenção da agricultura, sobretudo em zonas áridas e semiáridas ao redor do mundo. Dessa forma, o objetivo deste trabalho foi avaliar o efeito do priming químico com prolina e nitroprussiato de sódio como promotores do aumento da tolerância ao déficit hídrico em plantas de Physalis peruviana. Assim, plantas cultivadas em condições bem hidratadas (FC de 70±5%) foram pulverizadas com prolina (10 e 20 mM) ou nitroprussiato de sódio (25 e 50 µM) e avaliadas após a exposição ao déficit hídrico (FC de 20±5%). Plantas cultivadas sob déficit hídrico sem pré-tratamento apresentaram reduções para as variáveis de relações hídricas, trocas gasosas e de crescimento. O uso de prolina e nitroprussiato de sódio foram eficazes na manutenção do potencial hídrico menos negativo, contribuindo para melhorias nas trocas gasosas, como assimilação de CO₂, condutância estomática e transpiração. Dessa forma, foi possível mensurar maior tolerância ao déficit hídrico nas plantas pré-tratadas e, consequentemente, maior acúmulo de biomassa. O uso de prolina e nitroprussiato de sódio em pré-tratamento podem ter efeito priming contra o déficit hídrico em plantas de P. peruviana.

Palavras-chave:
Estresse abiótico; atenuação do déficit hídrico; fisális

INTRODUCTION

In order to meet the food demands of a growing world population, it is necessary to improve agricultural production, an indispensable task in the face of climate change (Rodrigues et al., 2019RODRIGUES, J. et al. Source-sink regulation in crops under water deficit. Trends in Plant Science, 24(7):652-663, 2019. ), especially for intensifying abiotic stresses. Terrestrial plants are exposed to a variety of unfavorable conditions, such as temperature extremes, high salinity, and deficient or excessive water (He; He; Ding, 2018HE, M.; HE, C. Q.; DING, N. Z. Abiotic stresses: General defenses of land plants and chances for engineering multistress tolerance. Frontiers in Plant Science , 9:1771, 2018. ). Among these factors, water deficit is the main responsible for reducing yield in agroecosystems worldwide (Leite et al., 2021LEITE, R. S. et al. Chemical priming agents controlling drought stress in Physalis angulata plants. Scientia Horticulturae, 275:109670, 2021a. a).

Plants can temporarily overcome water deficit through joint or combined responses, such as stomatal closure and morphophysiological changes, which include inhibition of leaf expansion, leaf abscission and modifications in root architecture (Simontacchi et al., 2015SIMONTACCHI, M. et al. Plant survival in a changing environment: The role of nitric oxide in plant responses to abiotic stress. Frontiers in Plant Science , 6:977, 2015. ), in addition to biomolecular changes and changes in water relations. However, these responses can compromise plant production as a function of stress duration and intensity, making it a great challenge to maintain plant performance under these conditions.

Searching for tools that contribute to the management of water deficit in plants is fundamental for the maintenance of agriculture, especially in arid and semi-arid areas. In recent decades, research has sought to highlight the use of drought-tolerant species and genotypes, as well as the use of biostimulants and osmoprotectants to reverse the negative effects of stress (Nazari; Pakniyat, 2010NAZARI, L.; PAKNIYAT, H. Assessment od drought tolerance in barley genotypes. Journal of Applied Sciences, 10(2):151-156, 2010.; Terra et al., 2015TERRA, T. G. R. et al. Características de tolerância à seca em genótipos de uma coleção nuclear de arroz de terras altas. Pesquisa Agropecuária Brasileira, 50(9):788- 796, 2015.; Irani; Valizadehkji; Naeini, 2021IRANI, H.; VALIZADEHKAJI. B.; NAEINI, M. R. Biostimulant-induced drought tolerance in grapevine is associated with physiological and biochemical changes. Chemical and Biological Technologies in Agriculture, 8:5, 2021.). More recently, the chemical priming technique has been shown to be efficient for increasing tolerance to abiotic stresses in various crops (Fleming et al., 2019FLEMING, T. R. et al. Biostimulants enhance growth and drought tolerance in Arabidopsis thaliana and exhibit chemical priming action. Annals of Applied Biology, 174(2):153-165, 2019. ; Gohari et al., 2020GOHARI, G. et al. Interaction between hydrogen peroxide and sodium nitroprusside following chemical priming of Ocimum basilicum L. against salt stress. Physiologia Plantarum, 168(2):361-373, 2020. ; Hameed et al., 2020HAMEED, A. et al. Alleviation of cadmium toxicity by mercapto-triazole priming in wheat. Archives of Agronomy and Soil Science, 66(11):1467-1480, 2020. ). In this strategy, before exposure to stress, plants are treated with natural or synthetic chemical compounds, which act as signal transducers, activating plant defense systems (primed state) and promoting greater tolerance to the stress factor compared to untreated plants (Antoniou et al., 2020ANTONIOU, C. et al. Exploring the potential of nitric oxide and hydrogen sulfide (NOSH)-releasing synthetic compounds as novel priming agents against drought stress in Medicago sativa plants. Biomolecules, 10(1):120, 2020. ; Sako; Nguyen; Seki, 2021SAKO, K.; NGUYEN, H. M.; SEKI, M. Advances in chemical priming to enhance abiotic stress tolerance in plants. Plant and Cell Physiology, 61(12):1995-2003, 2021. ).

Different molecules are used to perform priming, among which nitric oxide and proline stand out. Nitric oxide (NO) is a gas that acts as a signaling molecule in plants under abiotic stress conditions (Rahimian Boogar; Salehi; Jowkar, 2014RAHIMIAN BOOGAR, A.; SALEHI, H.; JOWKAR, A. Exogenous nitric oxide alleviates oxidative damage in turfgrasses under drought stress. South African Journal of Botany, 92:78-82, 2014. ). The role of NO in mitigating the effects of water stress has been observed in several plant species, including grains, legumes, fruit trees, medicinal plants and underexploited species (Lau et al., 2021LAU, S. E. et al. Plant nitric oxide signaling under drought stress. Plants, 10(2):360, 2021. ; Leite et al., 2021LEITE, R. S. et al. Chemical priming agents controlling drought stress in Physalis angulata plants. Scientia Horticulturae, 275:109670, 2021a. a), and its effects are related to the NO donor used, exposure time and the evaluated species.

Sodium nitroprusside is the main nitric oxide donor in plant experiments. The application of SNP in plants under water deficit acts in the maintenance of water status (Gupta; Srivastava; Seth, 2017GUPTA, P.; SRIVASTAVA, S.; SETH, C. S. 24-Epibrassinolide and Sodium Nitroprusside alleviate the salinity stress in Brassica juncea L. cv. Varuna through cross talk among proline, nitrogen metabolism and abscisic acid. Plant and Soil, 411:483-498, 2017.), stomatal regulation (Shao; Wang; Shangguan, 2010SHAO, R.; WANG, K.; SHANGGUAN, Z. Cytokinin-induced photosynthetic adaptability of Zea mays L. to drought stress associated with nitric oxide signal: Probed by ESR spectroscopy and fast OJIP fluorescence rise. Journal of Plant Physiology, 167(6):472-479, 2010.; Solangi et al., 2022SOLANGI, K. A. et al. Can electrophysiological information reflect the response of mangrove species to salt stress? A case study of rewatering and Sodium nitroprusside application. Plant Signaling & Behavior, 17(1):2073420, 2022.) and increase of photosynthesis whether by stimulating the transport of electrons in photosystem II (Procházková et al., 2013PROCHÁZKOVÁ, D. et al. Effects of exogenous nitric oxide on photosynthesis. Photosynthetica, 51:483-489, 2013. ) or by increasing the activity of the enzyme Ribulose-1,5-Bisphosphate Carboxylase / Oxygenase - RuBisCO (Siddiqui et al., 2020SIDDIQUI, M. H. et al. Exogenous nitric oxide alleviates sulfur deficiency-induced oxidative damage in tomato seedlings. Nitric Oxide, 94:95-107, 2020.). Other compounds, such as proline, are studied as potential promoters of increased tolerance in plants.

Proline is an amino acid with several functions in the plant-environment interaction, such as protection of cellular structure during dehydration, osmotic adjustment and removal of reactive oxygen species (Verslues; Sharma, 2010VERSLUES, P. E.; SHARMA, S. Proline metabolism and its implications for plant-environment interaction. Arabidopsis Book, 8:e0140, 2010.). Although proline is produced by the plant itself, recent studies have shown the beneficial role of its supply in several species under conditions of water deficit and other abiotic stresses (Merwad; Desoky; Rady, 2018MERWAD, A. R. M. A.; DESOKY, E. S. M.; RADY, M. M. Response of water deficit-stressed Vigna unguiculata performances to silicon, proline or methionine foliar application. Scientia Horticulturae , 228:132-144, 2018. ; Hanif et al., 2021HANIF, S. et al. Biochemically triggered heat and drought stress tolerance in rice by proline application. Journal of Plant Growth Regulation, 40:305-312, 2021. ; Tonhati et al., 2020TONHATI, R. et al. L-proline alleviates heat stress of tomato plants grown under protected environment. Scientia Horticulturae , 268:109370, 2020. ). The accumulation of proline induced by water deficit, observed in many plant species, has led to the hypothesis that additional increments in proline accumulation would promote drought tolerance (Bhaskara; Yang; Verslues, 2015BHASKARA, G. B.; YANG, T. H.; VERSLUES, P. E. Dynamic proline metabolism: Importance and regulation in water limited environments. Frontiers in Plant Science, 6:484, 2015. ). For example, proline application improves growth and photosynthetic efficiency in onions (Semida et al., 2020SEMIDA, W. M. et al. Exogenously applied proline enhances growth and productivity of drought stressed onion by improving photosynthetic efficiency, water use efficiency and up-regulating osmoprotectants. Scientia Horticulturae , 272:109580, 2020. ) and yield in beets (Ghaffari et al., 2021GHAFFARI, H. et al. Investigation of the proline role in controlling traits related to sugar and root yield of sugar beet under water deficit conditions. Agricultural Water Management, 243:106448, 2021. ) under water deficit. Thus, its application was also proposed in this study as a possible priming agent in Physalis peruviana L. plants.

A promising way of evaluating the effect of priming treatments on plants is through spectral analysis. Infrared spectroscopy with Fourier Transform (FTIR) offers a fast and non-destructive way to obtain a biochemical fingerprint of the samples, where the main functional groups and connections can be identified, providing structural information about the chemical compounds present (Palacio et al., 2014PALACIO, S. et al. Gypsophile chemistry unveiled: Fourier Transform infrared (FTIR) spectroscopy provides new insight into plant adaptations to gypsum soils. PLoS One, 9(9):e107285, 2014.). In addition, it is a viable tool to analyze variations in the proportions of the main organic compounds in plants as a function of environmental conditions (Durak; Depciuch, 2020DURAK, T.; DEPCIUCH, J. Effect of plant sample preparation and measuring methods on ATR-FTIR spectra results. Environmental and Experimental Botany, 169:103915, 2020.). For example, changes on biomolecular composition in plant organs of Physalis angulata L. under nitrogen deficiency have already been evaluated (Leite et al., 2018LEITE, R. S. et al. Nitrogen fertilization affects fourier transform infrared spectra (FTIR) in Physalis L. species. Computers and Electronics in Agriculture, 150:411-417, 2018a. a; 2021bLEITE, R. S. et al. Physiological responses of Physalis angulata plants to water deficit. Journal of Agricultural Science, 10(10):287-297, 2018b. )

Physalis L. is an American genus of agricultural importance, with P. peruviana L. (Figure 1) as the main cultivated species (Leite et al., 2021LEITE, R. S. et al. Nitrogen influenced biomolecular changes on Physalis L. species studied using 2DCOS spectral analysis coupled with chemometric and Receiver operation characteristics analysis. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy, 249:119220, 2021b. b; Vargas-Ponce et al., 2016VARGAS-PONCE, O. et al. Traditional management of a small-scale crop of Physalis angulata in Western Mexico. Genetic Resources and Crop Evolution, 63:1383-1395, 2016. ). In addition to the commercialization of its fruits, P. peruviana is a medicinal plant capable of eliminating reactive oxygen species (ROS) and increasing the antioxidant system in the human body (El-Beltagi et al., 2019EL-BELTAGI, H. S. et al. Chemical composition and biological activity of Physalis peruviana L. Gesunde Pflanzen, 71:113-122, 2019. ), acting as a natural product with anticancer potential (Yu et al., 2021YU, T. J. et al. Physalis peruviana-derived physapruin A (PHA) inhibits breast cancer cell proliferation and induces oxidative-stress-mediated apoptosis and DNA damage. Antioxidants, 10(3):393, 2021.). In addition, fruit calyxes can be used as herbal medicines, nutraceuticals or as low-cost cosmetic ingredients (Medina et al., 2019MEDINA, S. et al. Potential of Physalis peruviana calyces as a low-cost valuable resource of phytoprostanes and phenolic compounds. Journal of the Science of Food and Agriculture, 99(5):2194-2204, 2019. ).

Figure 1:
Physalis peruviana plants under water deficit (a) and details of the flower (b) and fruit enclosed by the calyx (c).

The cultivation of P. peruviana in Brazil is underexploited. In addition, research evaluating the performance of the species under water deficit conditions is scarce in the country, especially studies conducted with the non-cultivated native species Physalis angulata L. (Leite et al., 2018LEITE, R. S. et al. Physiological responses of Physalis angulata plants to water deficit. Journal of Agricultural Science, 10(10):287-297, 2018b. b; Leite et al., 2019LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019. ). Thus, the objective of the present study was to evaluate the effect of proline and sodium nitroprusside as promoters of increased tolerance to water deficit through chemical priming in P. peruviana plants.

MATERIAL AND METHODS

Plant material and cultivation conditions

Physalis peruviana plants were grown in a greenhouse at the State University of Feira de Santana (UEFS), Feira de Santana, Bahia, Brazil (12°16’7.99”S, 38°56’21.63”W, 258 m asl), from January to April 2020. During the experiment, maximum and minimum daily values of temperature and relative humidity were measured using a thermohygrometer installed inside the greenhouse (Figure 2), and the plants were maintained under 50% of light retention in natural photoperiod. The seedlings used were obtained from seeds supplied by the UEFS research collection and cultivated in soil with the following physical and chemical characteristics (Table 1). Other conditions of cultivation, cultural practices and fertigation were in accordance with previous studies (Leite et al., 2019LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019. ).

Figure 2:
Maximum and minimum temperature and humidity during 30 days of conducting the experiment. The period of sensitization (primed state) and exposure to water deficit are indicated in the graph.

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Table 1:
Physical and chemical characteristics of the soil used in the experiment.

Application of chemical priming

Soil water storage capacity (Fc) was calculated based on a test described by Leite et al. (2019LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019. ) and Bonfim-Silva et al. (2011)BONFIM-SILVA, E. M. et al. Desenvolvimento inicial de gramíneas submetidas ao estresse hídrico. Revista Caatinga, 24(2):180-186, 2011. . The pots used had a volume of 8 dm³ and were filled with 8 kg of air-dried soil, saturated, sealed with a polyvinyl chloride (PVC) film and suspended to drain excess water. The drainage time was 48 hours, and maximum water storage capacity was determined based on the difference of weights. Irrigation was performed by the gravimetric method based on the daily weights of the pots of each treatment and disregarding the increment of weight due to plants.

All plants were kept under hydrated conditions with Fc of 70±5% during the application of chemical priming at 10 days after transplanting. The plants were separated into different treatments and sprayed with 100 mL m^-2 proline - Pro (C₅H₉NO₂) at 10 mM and 20 mM, sodium nitroprusside - SNP (Na² [Fe(CN)₅NO]·2H₂O) at 25 μM and 50 μM; and distilled water (H₂O) as control. After chemical sensitization, the soil was maintained with Fc of 70±5% for 5 days. Then, irrigation was suspended in sensitized plants and water availability was monitored until reaching Fc of 20±5% after 15 days, when plants exposed to water deficit were assessed for any priming effect. The following treatments were evaluated in P. peruviana plants: Fc of 70% + H₂O; Fc of 20% + H₂O; Fc of 20% + Proline at 10 mM; Fc of 20% + Proline at 20 mM; Fc of 20% + SNP at 20 μM; Fc of 20% + SNP at 50 μM.

Experimental determinations

Relative water content and leaf water potential

Leaf water potential (ψ_{w leaf}) was determined in the early morning period using a Scholander pressure chamber (PMS 1000, PMS Instrument, Corvallis, USA). For this, leaves were collected from the middle third of the plants and immediately subjected to the reading of equilibrium pressure (MPa) after pressurization with compressed N₂, until the sap exited at the open end of the petiole.

Relative water content was calculated based on the weight of leaf sections according to Weatherley (1950). The discs were collected from fully expanded leaves located in the middle third of the plants and immediately sealed in airtight packages. The time of hydration in distilled water was six hours at room temperature and the time in a forced air circulation oven at 60 °C to determine dry matter was 24 hours. For both variables, three plants were evaluated per treatment.

Gas exchange

Gas exchange was measured in fully expanded leaves located in the middle third of the plants with a portable photosynthesis meter - InfraRed Gas Analyzer (IRGA, CIRAS-3 model, PPSystems, Amesbury, USA). The parameters evaluated were: CO₂ assimilation (A, μmol CO₂ m^-2 s^-1); stomatal conductance (gs, mmol H₂O m² s^-1) and transpiration rate (E, mmol H₂0 m^-2 s^-1); internal carbon concentration (Ci, μmol mol^-1) and water use efficiency (WUE, mmol CO₂ mol^-1 H₂O). Measurements were performed in four plants per treatment between 09:00 and 10:00 hours, with the following configurations: photon flux of 800 μmol m^-2 s^-1, reference CO₂ of 400 μmol mol^-1 and constant temperature (25 °C).

Growth parameters and drought tolerance index

Plants were sectioned into fractions of leaves, stems and roots and kept in a forced air circulation oven at 60 °C until reaching constant weight, to obtain the dry matter. Absolute growth rate and relative growth rate were determined according to Cairo, Oliveira and Mesquita (2008CAIRO, P. A. R.; OLIVEIRA, L. E. M.; MESQUITA, A. C. Análise de crescimento de plantas. Vitória da Conquista: Editora UESB, 2008. 72p.). Leaf area was determined using the method of leaf discs (Leite et al., 2019LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019. ). For growth variables, five plants were evaluated per treatment.

Drought tolerance index (DTI) (Blum; Jordan, 1985BLUM, A.; JORDAN, W. R. Breeding crop varieties for stress environ-ments. Critical Reviews in Plant Sciences, 2:199-238, 1985.) was calculated using the data of total dry matter of plants (TDM) of water deficit treatments compared to well hydrated plants, according to the following equation: DTI= (TDM treatment under deficit / TDM well hydrated treatment).

Spectral analysis

Leaf dry matter samples were crushed in liquid nitrogen and homogenized in a 1 - mm - mesh sieve. The samples were characterized by Attenuated Total Reflection-Fourier Transform Infrared (ATR-FTIR) spectroscopy using Thermo Nicolet iS50 spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). The spectra were recorded in the medium infrared range (4000-400 cm^-1) at a spectral resolution of 4 cm^-1, with 64 scans per sample. Spectral analyses were performed at the Laboratory of Instrumental Techniques, Universidad de Valladolid, Spain.

Statistical analysis

The experimental design adopted was completely randomized with 8 replicates, considering each pot as an experimental unit. The data were subjected to analysis of variance (ANOVA) at 5% significance level. The results were expressed with the mean ± standard error (SE) and Tukey means comparison test. The obtained data of the analyzed parameters were statistically evaluated using the statistical program Sisvar.

Vibration data were analyzed with SigmaPlot 14.0 software (Systat Software Inc., Chicago, USA). Comparisons in relation to the FTIR spectral peaks and analysis of the corresponding functional groups were performed.

RESULTS AND DISCUSSION

Water deficit reduced the leaf water potential of the evaluated plants, but the pretreatment attenuated this effect (Figure 3; p<0.001). Despite that, there were no statistical differences between treatments for relative water content (p=0.2311). The most negative potentials were measured in plants under water deficit without treatment (-0.56 MPa) and pretreated with Pro 10 mM (-0.56 MPa) (Figure 3). Pretreatments with Pro 20 mM (-0.38 MPa), SNP 25 μM (-0.41 MPa) and SNP 50 μM (-0.35 MPa) were the most effective in maintaining a less negative water potential, indicating the priming effect of the substances used at these concentrations (Figure 3). In recent studies, micromolar concentrations of SNP and millimolar concentrations of proline have resulted in increased Ψ_{w leaf} in Physalis angulata plants under water deficit (Leite et al., 2019LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019. , 2021aLEITE, R. S. et al. Chemical priming agents controlling drought stress in Physalis angulata plants. Scientia Horticulturae, 275:109670, 2021a. ) as well as for other species, such as tomato and fennel (Jangid; Dwivedi, 2017JANGID, K. K.; DWIVEDI, P. Physiological and biochemical changes by nitric oxide and brassinosteroid in tomato (Lycopersicon esculentum Mill.) under drought stress. Acta Physiologiae Plantarum, 39:73, 2017. ; Gholami Zali; Ehsanzadeh, 2018GHOLAMI ZALI, A.; EHSANZADEH, P. Exogenous proline improves osmoregulation, physiological functions, essential oil, and seed yield of fennel. Industrial Crops and Products, 111:133-140, 2018. ). The supply of these substances can stimulate the accumulation of proline and promote osmotic adjustment (Verslues; Sharma, 2010VERSLUES, P. E.; SHARMA, S. Proline metabolism and its implications for plant-environment interaction. Arabidopsis Book, 8:e0140, 2010.), contributing to the maintenance of turgor and keeping the other physiological processes, such as gas exchange, stable.

Figure 3:
Leaf water potential in Physalis peruviana plants under well hydrated conditions (WH) and exposed to water deficit (WD) after spraying with proline at 10 and 20 mM (Pro 10 mM and Pro 20mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM). The data are expressed by the mean ± standard error. Means sharing the same letters show no significant differences at 5% significance level.

In plants not sensitized by chemical agents, water deficit resulted in wilting and leaf abscission, evidencing the negative effects characteristic of this stress. Nevertheless, mitigating effects were observed in plants pretreated with Pro 20 mM and SNP 50 μM, evident by the maintenance of leaf turgor and color. However, plants pretreated with Pro 10 mM and SNP 25 μM exhibited symptoms similar to those of control plants under water deficit. It is important to mention that there was no expression of phenotypic characteristics of toxicity of the substances at the concentrations used. Leaf water potential data, in association with other physiological parameters evaluated, corroborate phenotypic observations (Figure 3, on top).

Water deficit and pretreatment with chemical agents significantly influenced the CO₂ assimilation (A, p<0.0001), stomatal conductance (gs, p<0.05) and transpiration (E, p <0.001) (Figure 4). However, there were no statistical differences between treatments for internal carbon concentration (p=0.9564) and water use efficiency (p=0.1119). The imposition of water deficit severely reduced CO₂ assimilation in P. peruviana plants, causing a reduction of 64.4% compared to plants under well hydrated conditions (17.95 μmol CO₂ m^-2 s^-1; Figure 4a). Despite that, pretreatment with both doses of SNP was able to keep assimilation levels statistically equal to those of well hydrated plants. These plants showed mean values of A equal to 17.30 and 16.85 μmol CO₂ m^-2 s^-1, with SNP at 25 and 50 μM, respectively. Increases in this variable were also observed in plants sensitized with proline (Figure 4a).

Figure 4:
CO₂ assimilation (a), stomatal conductance (b) and transpiration (c) of Physalis peruviana plants under well hydrated conditions (WH) and exposed to water deficit (WD) after spraying with proline at 10 and 20 mM of (Pro 10 mM and Pro 20 mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM). Data are expressed by the mean ± standard error. Means sharing the same letters show no significant differences at 5% significance level.

The reduction of CO₂ assimilation in plants under water deficit conditions occurs, among other factors, due to stomatal closure. This finding has been demonstrated in several studies in the recent literature (Pazzagli; Weiner; Liu, 2016PAZZAGLI, P. T.; WEINER, J.; LIU, F. Effects of CO2 elevation and irrigation regimes on leaf gas exchange, plant water relations, and water use efficiency of two tomato cultivars. Agricultural Water Management , 169:26-33, 2016. ; Wang; Wang; Shangguan, 2016WANG, X.; WANG, L.; SHANGGUAN, Z. Leaf gas exchange and fluorescence of two winter wheat varieties in response to drought stress and nitrogen supply. PLoS ONE , 11(11):e0165733, 2016. ; Leite et al., 2018LEITE, R. S. et al. Physiological responses of Physalis angulata plants to water deficit. Journal of Agricultural Science, 10(10):287-297, 2018b. b). However, the use of SNP in pretreatment attenuated the negative effects of water deficit on CO₂ assimilation. This is because SNP is considered the only NO donor capable of stimulating electron transport during the photochemical phase of photosynthesis (Procházková et al., 2013PROCHÁZKOVÁ, D. et al. Effects of exogenous nitric oxide on photosynthesis. Photosynthetica, 51:483-489, 2013. ; Antoniou et al., 2020ANTONIOU, C. et al. Exploring the potential of nitric oxide and hydrogen sulfide (NOSH)-releasing synthetic compounds as novel priming agents against drought stress in Medicago sativa plants. Biomolecules, 10(1):120, 2020. ). In addition, the exogenous supply of NO promotes increments in the activity of the enzyme ribulose-1,5-bisphosphate carboxylase / oxygenase - RuBisCO (Siddiqui et al., 2020SIDDIQUI, M. H. et al. Exogenous nitric oxide alleviates sulfur deficiency-induced oxidative damage in tomato seedlings. Nitric Oxide, 94:95-107, 2020.), contributing to the improvement of CO₂ assimilation.

The mean stomatal conductance measured in well hydrated plants was 68.1% higher than that of untreated plants under water deficit, which indicates the state of stress for this second group. Despite that, both priming treatments used stimulated the increase in stomatal conductance, acting in the maintenance of gs at levels statistically equal to those of plants under well hydrated conditions, ranging from 352.25 to 525 mmol H₂O m^-2 s^-1 (Figure 4b). Similar performance for the use of chemical agents was observed in leaf transpiration, which was maintained at levels between 5.37 and 5.65 mmol H₂O m^-2 s^-1 (Figure 4c). Although the results show that the chemical agents stimulated stomatal opening, it is important to highlight that there was also improvement in the water status of the plants (Figure 3). The use of proline and SNP is reported to improve gas exchange in plants under abiotic stresses, for instance increasing stomatal conductance (Faraji; Sepehri, 2020FARAJI, J.; SEPEHRI, A. Exogenous nitric oxide improves the protective effects of tio2 nanoparticles on growth, antioxidant system, and photosynthetic performance of wheat seedlings under drought stress. Journal of Soil Science and Plant Nutrition, 20:703-714, 2020. ) and transpiration in plants (Zouari et al., 2016ZOUARI, M. et al. Exogenous proline mediates alleviation of cadmium stress by promoting photosynthetic activity, water status and antioxidative enzymes activities of young date palm (Phoenix dactylifera L.). Ecotoxicology and Environmental Safety, 128:100-108, 2016.).

Priming treatments stimulated the growth of P. peruviana plants when exposed to water deficit (Figures 5, 6 and 7). There was no statistical difference for the mean absolute growth rate (AGR) between plants that were exposed to water deficit and sensitized with chemical agents (Figure 5a). Nevertheless, plants pretreated with SNP at 25 and 50 μM showed an increase in AGR, incorporating 0.14 and 0.15 g.day^-1, respectively, corresponding to increments of 31% and 36% compared to untreated plants under water deficit (p<0.0001; Figure 5a). Pretreatment with proline and SNP maintained the relative growth rate (RGR) with average values above 0.19 g g^-1 day^-1 (p<0.0001) (Figure 5b). Thus, the improvement of physiological processes promoted by the pretreatments, such as in water relations and gas exchange, contributed to the maintenance of plant growth under water deficit, although at lower levels compared to plants under well hydrated conditions.

Figure 5:
Absolute growth rate (a) and relative growth rate (b) of P. peruviana plants under well hydrated conditions (WH) and exposed to water deficit (WD) after spraying with proline at 10 and 20 mM (Pro 10 mM and Pro 20 mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM). Data are expressed by the mean ± standard error. Means sharing the same letters show no significant differences at 5% significance level.

Water deficit reduced the leaf area (LA) of non-sensitized plants by 81.9%, compared to well hydrated plants (Figure 6), which is a common response in plants under this stress (Shawon et al., 2020SHAWON, R. A. et al. Influence of drought stress on bioactive compounds, antioxidant enzymes and glucosinolate contents of Chinese cabbage (Brassica rapa). Food Chemistry, 308:125657, 2020. ; Leite et al., 2021LEITE, R. S. et al. Chemical priming agents controlling drought stress in Physalis angulata plants. Scientia Horticulturae, 275:109670, 2021a. a). Pretreatment with both doses of proline was not able to mitigate the effects of water deficit for this variable, while plants pretreated with SNP at 25 and 50 μM showed increments in LA of 46.2% and 34.4%, respectively, compared to non-sensitized plants, indicating efficiency in the application of priming (p<0.0001; Figure 6).

Figure 6:
Leaf area of P. peruviana plants under well hydrated conditions (WH) and exposed to water deficit (WD) after spraying with proline at 10 and 20 mM (Pro 10 mM and Pro 20 mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM). Data are expressed by the mean ± standard error. Means sharing the same letters show no significant differences at 5% significance level.

Biomass accumulation was reduced by water deficit in P. peruviana plants (Figure 7), as reported in other studies (Ozaslan et al., 2016OZASLAN, C. et al. Invasion potential of two tropical Physalis species in arid and semi-arid climates: Effect of water-salinity stress and soil types on growth and fecundity. PLoS ONE, 11(10):e0164369, 2016.; Leite et al., 2019LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019. ). Leaf dry matter showed a drastic reduction with the imposition of water deficit, decreasing by 72.9% compared to well hydrated plants. This effect was attenuated in plants pretreated with both doses of SNP and Pro 20 mM (p<0.0001; Figure 7a). However, the use of these substances was not able to mitigate the effects of water deficit on the stem dry matter of the evaluated plants, differing only from those that were well hydrated (p<0.0001; Figure 7b). For root dry matter, pretreatment with SNP 25 mM was the most effective for biomass accumulation in plants under water deficit (p<0.0001; Figure 7c). The total dry matter in plants sprayed with SNP 25 μM and 50 μM differed from that of plants without pretreatments under water deficit and maintained mean values above 2.86 g, showing the priming effect (p<0.0001; Figure 7 d, e).

Figure 7:
Leaf dry matter (a), stem dry matter (b), root dry matter (c) and total dry matter (d) and heat-map (e) of P. peruviana plants under well hydrated conditions (WH) and exposed to water deficit (WD) after spraying with proline at 10 and 20 mM (Pro 10 mM and Pro 20 mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM). Data are expressed by the mean ± standard error. Means sharing the same letters show no significant differences at 5% significance level.

Pretreatments with NO donor (25 and 50 μM) and proline (20 mM) were able to improve hydration in plants under water deficit, acting in the maintenance of the photosynthetic process, and consequently stimulated biomass accumulation in plants under water deficit (Figure 7) and increased tolerance to stress (Figure 8). Reduced plant growth is one of the main processes caused by water deficit, as it reduces cell expansion (Salisbury; Ross, 2012SALISBURY, F. B.; ROSS, C. W. Fisiologia das Plantas. São Paulo: Cengage Learning, 2012, 792p.). The maintenance or improvement, natural or induced, in the growth rates of plants when grown under adverse conditions is a characteristic that may represent greater tolerance to the stressful factor.

Figure 8:
Drought tolerance index in P. peruviana plants exposed to water deficit (WD) and after spraying with proline at 10 and 20 mM (Pro 10 mM and Pro 20 mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM). Data are expressed by the mean ± standard error. Means sharing the same letters show no significant differences at 5% significance level.

Water deficit and the application of pretreatments also altered infrared spectra in P. peruviana leaves (Figure 9). Figure 9a shows the FTIR spectrum in the region of 4000-400 cm^-1 typical of the leaves of P. peruviana plants cultivated under well hydrated conditions and under water deficit without pretreatment. Strong absorptions were observed in the spectra of plants under water deficit, with peaks common to well hydrated plants. In the region of 3500-3000 cm^-1, the peaks found were associated with the stretching of O-H bands (Jones, 2012JONES, F. Infrared investigation of barite and gypsum crystallization: Evidence for an amorphous to crystalline transition. CrystEngComm, 14:8374-8381, 2012.); lipid bands due to C-H stretching vibration occurred in the region of 3000-2800 cm^-1 (Skotti et al., 2014SKOTTI, E. et al. FTIR spectroscopic evaluation of changes in the cellular biochemical composition of the phytopathogenic fungus Alternaria alternata induced by extracts of some greek medicinal and aromatic plants. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy , 127:463-472, 2014.), peaking at 2914 cm^-1, and in the range of 1800-800 cm^-1, which is the fingerprint region, in which most variations in infrared absorption occur (Carrión-Prieto et al., 2017CARRIÓN-PRIETO, P et al. Mediterranean shrublands as carbon sinks for climate change mitigation: New root-to-shoot ratios. Carbon Management, 8(1):67-77, 2017. ) (Figure 9b).

Figure 9:
Infrared spectra with Fourier transform of Physalis peruviana leaves: (a) well hydrated plants (WH) and plants exposed to water deficit (WD); (b) characterization of the fingerprint region of plants under WH, WD and after spraying with proline at 10 and 20 mM (Pro 10 mM and Pro 20 mM) and sodium nitroprusside at 25 and 50 μM (SNP 25 μM and SNP 50 μM).

According to the fingerprint region, the bands from 1750 to 1250 cm^-1 and from 1250 to 900 cm^-1 correspond to amides and carbohydrates (Ogbaga et al., 2017OGBAGA, C. C. et al. Fourier transform infrared spectroscopic analysis of maize (Zea mays) subjected to progressive drought reveals involvement of lipids, amides and carbohydrates. African Journal of Biotechnology, 16(18):1061-1066, 2017.), respectively, which had higher absorptions in plants under water deficit and other pretreatments (Figure 9b). Thus, variations induced in plant metabolism by environmental factors, such as water deficit, or any stressful situations may affect spectral peaks (Kumar et al., 2016KUMAR, V. S. A. et al. FTIR spectroscopy data as a fingerprint of Withania somnifera root tissues: A case study with accessions of the species from Kerala, South India. Indo American Journal of Pharmaceutical Research, 6:5748-5756, 2016.). It is possible to notice that among plants subjected to pretreatments, the use of both doses of SNP induced higher absorption in the spectra corresponding to amides and carbohydrates, which may indicate greater accumulation of these substances in physiological processes such as osmoregulation. The spectra of leaves of plants pretreated with proline showed intermediate absorptions between plants under water deficit without pretreatment and plants under well hydrated conditions, indicating that this substance reduced the effects of water stress.

CONCLUSIONS

The use of proline and sodium nitroprusside has a priming effect on Physalis peruviana plants cultivated under water deficit, being indicated for increased tolerance to this stress factor. Foliar spraying with these substances in pretreatment, under the conditions indicated in this study, can promote improvements in water relations, gas exchange, growth rates, biomass and biomolecular composition. Given the emergence of the concept of sustainability, studies with underexploited species, especially those with food potential, stand out. Thus, the use of strategies that contribute to the maintenance and conservation of plant genetic resources are important. In this perspective, the use of chemical priming may emerge as an effective and strategic resource in agricultural cultivation, especially in places where severe water deficit is verified, such as semiarid regions.

AUTHOR CONTRIBUTION

Conceptual Idea: Leite, R. S.; Methodology design: Leite, R. S.; Nascimento, M. N.; Hernández-Navarro, S.; Potosme, N. M. R.; Data collection: Leite, R. S.; Silva, A. L.; Santos, R. J.; Data analysis and interpretation: Leite, R. S.; Hernández-Navarro, S.; Nascimento, M. N.; Potosme, N. M. R.; Silva, A. L.; Santos, R. J., and Writing and editing: Leite, R. S.; Hernández-Navarro, S.; Nascimento, M. N.; Potosme, N. M. R.; Silva, A. L.; Santos, R. J.

ACKNOWLEDGEMENTS

This study was financed in part by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001.

REFERENCES

ANTONIOU, C. et al. Exploring the potential of nitric oxide and hydrogen sulfide (NOSH)-releasing synthetic compounds as novel priming agents against drought stress in Medicago sativa plants. Biomolecules, 10(1):120, 2020.
BHASKARA, G. B.; YANG, T. H.; VERSLUES, P. E. Dynamic proline metabolism: Importance and regulation in water limited environments. Frontiers in Plant Science, 6:484, 2015.
BLUM, A.; JORDAN, W. R. Breeding crop varieties for stress environ-ments. Critical Reviews in Plant Sciences, 2:199-238, 1985.
BONFIM-SILVA, E. M. et al. Desenvolvimento inicial de gramíneas submetidas ao estresse hídrico. Revista Caatinga, 24(2):180-186, 2011.
CAIRO, P. A. R.; OLIVEIRA, L. E. M.; MESQUITA, A. C. Análise de crescimento de plantas. Vitória da Conquista: Editora UESB, 2008. 72p.
CARRIÓN-PRIETO, P et al. Mediterranean shrublands as carbon sinks for climate change mitigation: New root-to-shoot ratios. Carbon Management, 8(1):67-77, 2017.
DURAK, T.; DEPCIUCH, J. Effect of plant sample preparation and measuring methods on ATR-FTIR spectra results. Environmental and Experimental Botany, 169:103915, 2020.
EL-BELTAGI, H. S. et al. Chemical composition and biological activity of Physalis peruviana L. Gesunde Pflanzen, 71:113-122, 2019.
FARAJI, J.; SEPEHRI, A. Exogenous nitric oxide improves the protective effects of tio2 nanoparticles on growth, antioxidant system, and photosynthetic performance of wheat seedlings under drought stress. Journal of Soil Science and Plant Nutrition, 20:703-714, 2020.
FLEMING, T. R. et al. Biostimulants enhance growth and drought tolerance in Arabidopsis thaliana and exhibit chemical priming action. Annals of Applied Biology, 174(2):153-165, 2019.
GHAFFARI, H. et al. Investigation of the proline role in controlling traits related to sugar and root yield of sugar beet under water deficit conditions. Agricultural Water Management, 243:106448, 2021.
GHOLAMI ZALI, A.; EHSANZADEH, P. Exogenous proline improves osmoregulation, physiological functions, essential oil, and seed yield of fennel. Industrial Crops and Products, 111:133-140, 2018.
GOHARI, G. et al. Interaction between hydrogen peroxide and sodium nitroprusside following chemical priming of Ocimum basilicum L. against salt stress. Physiologia Plantarum, 168(2):361-373, 2020.
GUPTA, P.; SRIVASTAVA, S.; SETH, C. S. 24-Epibrassinolide and Sodium Nitroprusside alleviate the salinity stress in Brassica juncea L. cv. Varuna through cross talk among proline, nitrogen metabolism and abscisic acid. Plant and Soil, 411:483-498, 2017.
HAMEED, A. et al. Alleviation of cadmium toxicity by mercapto-triazole priming in wheat. Archives of Agronomy and Soil Science, 66(11):1467-1480, 2020.
HANIF, S. et al. Biochemically triggered heat and drought stress tolerance in rice by proline application. Journal of Plant Growth Regulation, 40:305-312, 2021.
HE, M.; HE, C. Q.; DING, N. Z. Abiotic stresses: General defenses of land plants and chances for engineering multistress tolerance. Frontiers in Plant Science , 9:1771, 2018.
IRANI, H.; VALIZADEHKAJI. B.; NAEINI, M. R. Biostimulant-induced drought tolerance in grapevine is associated with physiological and biochemical changes. Chemical and Biological Technologies in Agriculture, 8:5, 2021.
JANGID, K. K.; DWIVEDI, P. Physiological and biochemical changes by nitric oxide and brassinosteroid in tomato (Lycopersicon esculentum Mill.) under drought stress. Acta Physiologiae Plantarum, 39:73, 2017.
JONES, F. Infrared investigation of barite and gypsum crystallization: Evidence for an amorphous to crystalline transition. CrystEngComm, 14:8374-8381, 2012.
KUMAR, V. S. A. et al. FTIR spectroscopy data as a fingerprint of Withania somnifera root tissues: A case study with accessions of the species from Kerala, South India. Indo American Journal of Pharmaceutical Research, 6:5748-5756, 2016.
LAU, S. E. et al. Plant nitric oxide signaling under drought stress. Plants, 10(2):360, 2021.
LEITE, R. S. et al. Nitrogen fertilization affects fourier transform infrared spectra (FTIR) in Physalis L. species. Computers and Electronics in Agriculture, 150:411-417, 2018a.
LEITE, R. S. et al. Physiological responses of Physalis angulata plants to water deficit. Journal of Agricultural Science, 10(10):287-297, 2018b.
LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019.
LEITE, R. S. et al. Chemical priming agents controlling drought stress in Physalis angulata plants. Scientia Horticulturae, 275:109670, 2021a.
LEITE, R. S. et al. Nitrogen influenced biomolecular changes on Physalis L. species studied using 2DCOS spectral analysis coupled with chemometric and Receiver operation characteristics analysis. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy, 249:119220, 2021b.
MEDINA, S. et al. Potential of Physalis peruviana calyces as a low-cost valuable resource of phytoprostanes and phenolic compounds. Journal of the Science of Food and Agriculture, 99(5):2194-2204, 2019.
MERWAD, A. R. M. A.; DESOKY, E. S. M.; RADY, M. M. Response of water deficit-stressed Vigna unguiculata performances to silicon, proline or methionine foliar application. Scientia Horticulturae , 228:132-144, 2018.
NAZARI, L.; PAKNIYAT, H. Assessment od drought tolerance in barley genotypes. Journal of Applied Sciences, 10(2):151-156, 2010.
OGBAGA, C. C. et al. Fourier transform infrared spectroscopic analysis of maize (Zea mays) subjected to progressive drought reveals involvement of lipids, amides and carbohydrates. African Journal of Biotechnology, 16(18):1061-1066, 2017.
OZASLAN, C. et al. Invasion potential of two tropical Physalis species in arid and semi-arid climates: Effect of water-salinity stress and soil types on growth and fecundity. PLoS ONE, 11(10):e0164369, 2016.
PALACIO, S. et al. Gypsophile chemistry unveiled: Fourier Transform infrared (FTIR) spectroscopy provides new insight into plant adaptations to gypsum soils. PLoS One, 9(9):e107285, 2014.
PAZZAGLI, P. T.; WEINER, J.; LIU, F. Effects of CO2 elevation and irrigation regimes on leaf gas exchange, plant water relations, and water use efficiency of two tomato cultivars. Agricultural Water Management , 169:26-33, 2016.
PROCHÁZKOVÁ, D. et al. Effects of exogenous nitric oxide on photosynthesis. Photosynthetica, 51:483-489, 2013.
RAHIMIAN BOOGAR, A.; SALEHI, H.; JOWKAR, A. Exogenous nitric oxide alleviates oxidative damage in turfgrasses under drought stress. South African Journal of Botany, 92:78-82, 2014.
RODRIGUES, J. et al. Source-sink regulation in crops under water deficit. Trends in Plant Science, 24(7):652-663, 2019.
SAKO, K.; NGUYEN, H. M.; SEKI, M. Advances in chemical priming to enhance abiotic stress tolerance in plants. Plant and Cell Physiology, 61(12):1995-2003, 2021.
SALISBURY, F. B.; ROSS, C. W. Fisiologia das Plantas. São Paulo: Cengage Learning, 2012, 792p.
SEMIDA, W. M. et al. Exogenously applied proline enhances growth and productivity of drought stressed onion by improving photosynthetic efficiency, water use efficiency and up-regulating osmoprotectants. Scientia Horticulturae , 272:109580, 2020.
SHAO, R.; WANG, K.; SHANGGUAN, Z. Cytokinin-induced photosynthetic adaptability of Zea mays L. to drought stress associated with nitric oxide signal: Probed by ESR spectroscopy and fast OJIP fluorescence rise. Journal of Plant Physiology, 167(6):472-479, 2010.
SHAWON, R. A. et al. Influence of drought stress on bioactive compounds, antioxidant enzymes and glucosinolate contents of Chinese cabbage (Brassica rapa). Food Chemistry, 308:125657, 2020.
SIDDIQUI, M. H. et al. Exogenous nitric oxide alleviates sulfur deficiency-induced oxidative damage in tomato seedlings. Nitric Oxide, 94:95-107, 2020.
SIMONTACCHI, M. et al. Plant survival in a changing environment: The role of nitric oxide in plant responses to abiotic stress. Frontiers in Plant Science , 6:977, 2015.
SKOTTI, E. et al. FTIR spectroscopic evaluation of changes in the cellular biochemical composition of the phytopathogenic fungus Alternaria alternata induced by extracts of some greek medicinal and aromatic plants. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy , 127:463-472, 2014.
SOLANGI, K. A. et al. Can electrophysiological information reflect the response of mangrove species to salt stress? A case study of rewatering and Sodium nitroprusside application. Plant Signaling & Behavior, 17(1):2073420, 2022.
TERRA, T. G. R. et al. Características de tolerância à seca em genótipos de uma coleção nuclear de arroz de terras altas. Pesquisa Agropecuária Brasileira, 50(9):788- 796, 2015.
TONHATI, R. et al. L-proline alleviates heat stress of tomato plants grown under protected environment. Scientia Horticulturae , 268:109370, 2020.
VARGAS-PONCE, O. et al. Traditional management of a small-scale crop of Physalis angulata in Western Mexico. Genetic Resources and Crop Evolution, 63:1383-1395, 2016.
VERSLUES, P. E.; SHARMA, S. Proline metabolism and its implications for plant-environment interaction. Arabidopsis Book, 8:e0140, 2010.
WANG, X.; WANG, L.; SHANGGUAN, Z. Leaf gas exchange and fluorescence of two winter wheat varieties in response to drought stress and nitrogen supply. PLoS ONE , 11(11):e0165733, 2016.
YU, T. J. et al. Physalis peruviana-derived physapruin A (PHA) inhibits breast cancer cell proliferation and induces oxidative-stress-mediated apoptosis and DNA damage. Antioxidants, 10(3):393, 2021.
ZOUARI, M. et al. Exogenous proline mediates alleviation of cadmium stress by promoting photosynthetic activity, water status and antioxidative enzymes activities of young date palm (Phoenix dactylifera L.). Ecotoxicology and Environmental Safety, 128:100-108, 2016.

Publication Dates

Publication in this collection
23 Sept 2022
Date of issue
2022

History

Received
16 Mar 2022
Accepted
27 July 2022

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

[1] ANTONIOU, C. et al. Exploring the potential of nitric oxide and hydrogen sulfide (NOSH)-releasing synthetic compounds as novel priming agents against drought stress in Medicago sativa plants. Biomolecules, 10(1):120, 2020.

[2] BHASKARA, G. B.; YANG, T. H.; VERSLUES, P. E. Dynamic proline metabolism: Importance and regulation in water limited environments. Frontiers in Plant Science, 6:484, 2015.

[3] BLUM, A.; JORDAN, W. R. Breeding crop varieties for stress environ-ments. Critical Reviews in Plant Sciences, 2:199-238, 1985.

[4] BONFIM-SILVA, E. M. et al. Desenvolvimento inicial de gramíneas submetidas ao estresse hídrico. Revista Caatinga, 24(2):180-186, 2011.

[5] CAIRO, P. A. R.; OLIVEIRA, L. E. M.; MESQUITA, A. C. Análise de crescimento de plantas. Vitória da Conquista: Editora UESB, 2008. 72p.

[6] CARRIÓN-PRIETO, P et al. Mediterranean shrublands as carbon sinks for climate change mitigation: New root-to-shoot ratios. Carbon Management, 8(1):67-77, 2017.

[7] DURAK, T.; DEPCIUCH, J. Effect of plant sample preparation and measuring methods on ATR-FTIR spectra results. Environmental and Experimental Botany, 169:103915, 2020.

[8] EL-BELTAGI, H. S. et al. Chemical composition and biological activity of Physalis peruviana L. Gesunde Pflanzen, 71:113-122, 2019.

[9] FARAJI, J.; SEPEHRI, A. Exogenous nitric oxide improves the protective effects of tio2 nanoparticles on growth, antioxidant system, and photosynthetic performance of wheat seedlings under drought stress. Journal of Soil Science and Plant Nutrition, 20:703-714, 2020.

[10] FLEMING, T. R. et al. Biostimulants enhance growth and drought tolerance in Arabidopsis thaliana and exhibit chemical priming action. Annals of Applied Biology, 174(2):153-165, 2019.

[11] GHAFFARI, H. et al. Investigation of the proline role in controlling traits related to sugar and root yield of sugar beet under water deficit conditions. Agricultural Water Management, 243:106448, 2021.

[12] GHOLAMI ZALI, A.; EHSANZADEH, P. Exogenous proline improves osmoregulation, physiological functions, essential oil, and seed yield of fennel. Industrial Crops and Products, 111:133-140, 2018.

[13] GOHARI, G. et al. Interaction between hydrogen peroxide and sodium nitroprusside following chemical priming of Ocimum basilicum L. against salt stress. Physiologia Plantarum, 168(2):361-373, 2020.

[14] GUPTA, P.; SRIVASTAVA, S.; SETH, C. S. 24-Epibrassinolide and Sodium Nitroprusside alleviate the salinity stress in Brassica juncea L. cv. Varuna through cross talk among proline, nitrogen metabolism and abscisic acid. Plant and Soil, 411:483-498, 2017.

[15] HAMEED, A. et al. Alleviation of cadmium toxicity by mercapto-triazole priming in wheat. Archives of Agronomy and Soil Science, 66(11):1467-1480, 2020.

[16] HANIF, S. et al. Biochemically triggered heat and drought stress tolerance in rice by proline application. Journal of Plant Growth Regulation, 40:305-312, 2021.

[17] HE, M.; HE, C. Q.; DING, N. Z. Abiotic stresses: General defenses of land plants and chances for engineering multistress tolerance. Frontiers in Plant Science , 9:1771, 2018.

[18] IRANI, H.; VALIZADEHKAJI. B.; NAEINI, M. R. Biostimulant-induced drought tolerance in grapevine is associated with physiological and biochemical changes. Chemical and Biological Technologies in Agriculture, 8:5, 2021.

[19] JANGID, K. K.; DWIVEDI, P. Physiological and biochemical changes by nitric oxide and brassinosteroid in tomato (Lycopersicon esculentum Mill.) under drought stress. Acta Physiologiae Plantarum, 39:73, 2017.

[20] JONES, F. Infrared investigation of barite and gypsum crystallization: Evidence for an amorphous to crystalline transition. CrystEngComm, 14:8374-8381, 2012.

[21] KUMAR, V. S. A. et al. FTIR spectroscopy data as a fingerprint of Withania somnifera root tissues: A case study with accessions of the species from Kerala, South India. Indo American Journal of Pharmaceutical Research, 6:5748-5756, 2016.

[22] LAU, S. E. et al. Plant nitric oxide signaling under drought stress. Plants, 10(2):360, 2021.

[23] LEITE, R. S. et al. Nitrogen fertilization affects fourier transform infrared spectra (FTIR) in Physalis L. species. Computers and Electronics in Agriculture, 150:411-417, 2018a.

[24] LEITE, R. S. et al. Physiological responses of Physalis angulata plants to water deficit. Journal of Agricultural Science, 10(10):287-297, 2018b.

[25] LEITE, R. S. et al. Alleviation of water deficit in Physalis angulata plants by nitric oxide exogenous donor. Agricultural Water Management , 216:98-104, 2019.

[26] LEITE, R. S. et al. Chemical priming agents controlling drought stress in Physalis angulata plants. Scientia Horticulturae, 275:109670, 2021a.

[27] LEITE, R. S. et al. Nitrogen influenced biomolecular changes on Physalis L. species studied using 2DCOS spectral analysis coupled with chemometric and Receiver operation characteristics analysis. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy, 249:119220, 2021b.

[28] MEDINA, S. et al. Potential of Physalis peruviana calyces as a low-cost valuable resource of phytoprostanes and phenolic compounds. Journal of the Science of Food and Agriculture, 99(5):2194-2204, 2019.

[29] MERWAD, A. R. M. A.; DESOKY, E. S. M.; RADY, M. M. Response of water deficit-stressed Vigna unguiculata performances to silicon, proline or methionine foliar application. Scientia Horticulturae , 228:132-144, 2018.

[30] NAZARI, L.; PAKNIYAT, H. Assessment od drought tolerance in barley genotypes. Journal of Applied Sciences, 10(2):151-156, 2010.

[31] OGBAGA, C. C. et al. Fourier transform infrared spectroscopic analysis of maize (Zea mays) subjected to progressive drought reveals involvement of lipids, amides and carbohydrates. African Journal of Biotechnology, 16(18):1061-1066, 2017.

[32] OZASLAN, C. et al. Invasion potential of two tropical Physalis species in arid and semi-arid climates: Effect of water-salinity stress and soil types on growth and fecundity. PLoS ONE, 11(10):e0164369, 2016.

[33] PALACIO, S. et al. Gypsophile chemistry unveiled: Fourier Transform infrared (FTIR) spectroscopy provides new insight into plant adaptations to gypsum soils. PLoS One, 9(9):e107285, 2014.

[34] PAZZAGLI, P. T.; WEINER, J.; LIU, F. Effects of CO2 elevation and irrigation regimes on leaf gas exchange, plant water relations, and water use efficiency of two tomato cultivars. Agricultural Water Management , 169:26-33, 2016.

[35] PROCHÁZKOVÁ, D. et al. Effects of exogenous nitric oxide on photosynthesis. Photosynthetica, 51:483-489, 2013.

[36] RAHIMIAN BOOGAR, A.; SALEHI, H.; JOWKAR, A. Exogenous nitric oxide alleviates oxidative damage in turfgrasses under drought stress. South African Journal of Botany, 92:78-82, 2014.

[37] RODRIGUES, J. et al. Source-sink regulation in crops under water deficit. Trends in Plant Science, 24(7):652-663, 2019.

[38] SAKO, K.; NGUYEN, H. M.; SEKI, M. Advances in chemical priming to enhance abiotic stress tolerance in plants. Plant and Cell Physiology, 61(12):1995-2003, 2021.

[39] SALISBURY, F. B.; ROSS, C. W. Fisiologia das Plantas. São Paulo: Cengage Learning, 2012, 792p.

[40] SEMIDA, W. M. et al. Exogenously applied proline enhances growth and productivity of drought stressed onion by improving photosynthetic efficiency, water use efficiency and up-regulating osmoprotectants. Scientia Horticulturae , 272:109580, 2020.

[41] SHAO, R.; WANG, K.; SHANGGUAN, Z. Cytokinin-induced photosynthetic adaptability of Zea mays L. to drought stress associated with nitric oxide signal: Probed by ESR spectroscopy and fast OJIP fluorescence rise. Journal of Plant Physiology, 167(6):472-479, 2010.

[42] SHAWON, R. A. et al. Influence of drought stress on bioactive compounds, antioxidant enzymes and glucosinolate contents of Chinese cabbage (Brassica rapa). Food Chemistry, 308:125657, 2020.

[43] SIDDIQUI, M. H. et al. Exogenous nitric oxide alleviates sulfur deficiency-induced oxidative damage in tomato seedlings. Nitric Oxide, 94:95-107, 2020.

[44] SIMONTACCHI, M. et al. Plant survival in a changing environment: The role of nitric oxide in plant responses to abiotic stress. Frontiers in Plant Science , 6:977, 2015.

[45] SKOTTI, E. et al. FTIR spectroscopic evaluation of changes in the cellular biochemical composition of the phytopathogenic fungus Alternaria alternata induced by extracts of some greek medicinal and aromatic plants. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy , 127:463-472, 2014.

[46] SOLANGI, K. A. et al. Can electrophysiological information reflect the response of mangrove species to salt stress? A case study of rewatering and Sodium nitroprusside application. Plant Signaling & Behavior, 17(1):2073420, 2022.

[47] TERRA, T. G. R. et al. Características de tolerância à seca em genótipos de uma coleção nuclear de arroz de terras altas. Pesquisa Agropecuária Brasileira, 50(9):788- 796, 2015.

[48] TONHATI, R. et al. L-proline alleviates heat stress of tomato plants grown under protected environment. Scientia Horticulturae , 268:109370, 2020.

[49] VARGAS-PONCE, O. et al. Traditional management of a small-scale crop of Physalis angulata in Western Mexico. Genetic Resources and Crop Evolution, 63:1383-1395, 2016.

[50] VERSLUES, P. E.; SHARMA, S. Proline metabolism and its implications for plant-environment interaction. Arabidopsis Book, 8:e0140, 2010.

[51] WANG, X.; WANG, L.; SHANGGUAN, Z. Leaf gas exchange and fluorescence of two winter wheat varieties in response to drought stress and nitrogen supply. PLoS ONE , 11(11):e0165733, 2016.

[52] YU, T. J. et al. Physalis peruviana-derived physapruin A (PHA) inhibits breast cancer cell proliferation and induces oxidative-stress-mediated apoptosis and DNA damage. Antioxidants, 10(3):393, 2021.

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In water	mg dm^-3			Cmol c/dm^-3					%
pH	Organic matter	P	K	Ca+Mg	Al	Na	S	CEC	Base saturation
6.67	1.13	24	77	7.0	0.0	0.18	7.37	8.33	88.47

Brasil