Abstract
The roles of plant growth regulators (PGRs) in plants are well documented. However, there is a little information regarding their roles in alleviating salt stress in plants, particularly peppermint. This necessitated the evaluation of the efficiency of three selected PGRs in counteracting the ill effect of salt stress by conducting a pot experiment on peppermint (Lamiaceae). Three uniform size suckers were transplanted in each pot containing proper nutrients. Thirty day old plants were subjected to 4 levels of salinity, viz. 0, 50, 100 or 150 mM NaCl. Salt stress was given at 30 days after their transplantation (DAT). Plants were sprayed twice, i.e., at 60 and 75 DAT with 10−6 M each of gibberellic acid (GA3), salicylic acid (SA) or triacontanol (Tria). The sampling was made at 100 DAT and harvesting at 120 DAT. The graded levels of salinity decreased growth, photosynthesis, carbonic anhydrase (CA) activity, NPK content, peltate glandular trichome (PGT) density, essential oil (EO) and menthol content and herb, EO and menthol yield, but increased catalase (CAT), peroxidase (POX) and superoxide dismutase (SOD) activities and proline content linearly. Spray of PGRs particularly SA improved all parameters under both salt and salt free conditions. The maximum values for yields of herb, EO and menthol were noted with 0 mM NaCl × SA. However, antioxidants, proline content, PGT density and EO content were found to be maximum with 150 mM NaCl × SA.
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Introduction
Mentha piperita L. (peppermint) is an important medicinal and aromatic plant (MAP) belonging to the family Lamiaceae. Its oil and leaves are used in traditional medicines and pharmaceutical products as also flavouring agent. Peppermint oil due to presence of terpenoids like menthol, menthone, menthyl acetate, menthofuran, isomenthone, pulegone and limonene has therapeutic, antifungal, anticholinestearic, antimicrobial and anti-oxidant activities (Lawrence 2006; Santoro et al. 2013; Barros et al. 2015). The previous studies revealed that salinity influenced osmotic and ionic imbalance in plants adversely leading to poor growth, yield and secondary metabolite products like essential oil and its components (Aziz et al. 2008; Khorasaninejad et al. 2010; Olfa et al. 2016). Ill effects of salinity may be overcome to a great extent by evolution of salt resistant varieties, balanced manuring and judicious fertilizer and PGRs application (Ondrasek et al. 2011; Jayakannan et al. 2015). Of these factors, PGR application is of quite importance. Gibberellins are natural diterpenes that are significant for their role particularly in seed germination, vegetative growth, bolting and induction of flowering, or fruit development (Sun and Gubler 2004). The hormone may induce or increase the endogenous levels of SA under abiotic stress conditions (Alonso-RamÃrez et al. 2009). SA is an endogenous signalling molecule and is involved in stress tolerance of plants by regulating physiological and biochemical processes including photosynthesis and antioxidant metabolism (Gunes et al. 2007; Horvath et al. 2007; Nazar et al. 2011; Palma et al. 2013). It helps in tolerating plant salinity stress by altering nutrient uptake, membrane functioning, water relations, inhibition of ethylene biosynthesis and lipid peroxidation (Raskin 1992; Aldesuquy et al. 1998; Rajasekaran and Blake 1999; Srivastava and Dwivedi 2000). Tria is a saturated primary alcohol and has plant growth promoting properties (Ries et al. 1977). Tria regulates of photosynthesis, water and mineral nutrient uptake by influencing the enzymes which regulate growth and metabolic processes in plants (Chen et al. 2002; Naeem et al. 2011). Tria can also up-regulate crop growth under stressful environments (Muthuchelian et al. 1996; Radhakrishnan and Kumari 2008). Keeping the importance of such hormones in view, the present study was undertaken with the hypothesis whether application of the three selected PGRs at crucial stage of growth can counteract the negative effect of salinity in peppermint. The present investigation may be helpful in making a normal crop to the moderate tolerant one.
Materials and methods
Plant material, PGRs and salt treatment
This pot experiment was conducted on peppermint during summer season in a net house of the Department of Botany, Aligarh Muslim University, Aligarh (27°52′N latitude, 78°51′E longitude, 187.45 m altitude). During this experimental period, there were a 12 h photoperiod of natural daylight, maximum and minimum temperature of 37.5 and 15 °C, respectively and relative humidity of 59.5% on average, with the total rainfall being 125.00 mm. Prior to transplantation, soil samples were randomly collected from each pot filled with a homogenous mixture of 4 kg soil and 1 kg organic manure (4:1) for their analysis. Physio-chemical characteristics of the experimental soil were, texture-sandy loam, pH (1:2) 7.6, E.C. (1:2) 0.58 dS m−1, available N, P and K 98.5, 78.5 and 148.1 mg kg−1 soil, respectively. The soil was maintained at sufficient moisture to ensure optimum growth of plants. A recommended basal dose of N, P and K (N80 P40 K40) kg ha−1 (Singh et al. 2012), i.e., 36 mg N + 17.9 mg P2O5 and 17.9 mg K2O kg−1 soil (Gupta 2004) was applied in the form of urea, single superphosphate and muriate of potash, respectively at the time of transplanting. Healthy peppermint suckers of uniform size and age obtained from the Central Institute of Medicinal and Aromatic Plants, Lucknow (India) were transplanted at the rate of 3 suckers pot−1. Plants were subjected to four graded levels of salt stress (0, 50, 100 or 150 mM NaCl) at 30 days after transplanting (DAT). Two sprays of dilute solution (10−6 M) each of the three PGR’s (GA3, SA or Tria) were applied to the foliage of plants using a hand sprayer at the interval of 15d with the first spray giving at 60 DAT. The control plants were sprayed with the double distilled water (DDW). The experiment was conducted according to a factorial randomized design. In all, there were 16 treatments. Each treatment was replicated five times. The standard cultural practices were adopted for growing the crop. The performance of the crop in respect of growth, physio-biochemical, yield and quality-parameters were studied at 100 DAT. Harvesting of the crop was done at 120 DAT.
Determination of growth parameters
Shoot and root length of the plants were determined in cm and fresh weight of the plants in g. After drying at 80 °C for 48 h in an oven, dry weights of per plant were obtained in g. After counting leaves, leaf area of the upper third fully expanded leaf of each plant (cm2) was determined by a leaf area meter (ADC Bioscientific, Hoddesdon, Herts, UK).
Determination of physiological and biochemical parameters
SPAD chlorophyll
Estimation of leaf chlorophyll was accomplished with the help of the SPAD-502 (KMS Inc. Japan).
Leaf gas exchange parameters
Gas exchange parameters were determined using an infrared gas. Net photosynthetic rate (PN) and its related attributes [stomatal conductance (gs), internal CO2 concentration (Ci) and transpiration rate (E)] were evaluated by a portable system (LI-COR 6400, LICOR, Lincoln, NE, USA). The conditions as temperature, RH, CO2 concentration, and photon flux density in the leaf chamber of the system were at 25 °C, 85%, 600 µmol mol−1, and 800 µmol m−2 s−1, respectively.
Carbonic anhydrase activity
Leaf carbonic anhydrase (CA) activity in the leaves was measured following the method described by Dwivedi and Randhawa (1974). Leaves (200 mg) were cut into small pieces in 10 mL cysteine hydrochloride solution (0.2 M). These leaf samples were blotted and transferred in a test tube, followed by the addition of 4 mL phosphate buffer (pH 6.8), 4 mL NaHCO3 (0.2 M in 0.02 M NaOH), 0.2 mL bromothymol blue (0.002%). This reaction was titrated against 0.5N HCl using methyl red as an indicator. The activity of the enzyme was expressed as mM CO2 kg−1 (FM) s−1.
Catalase, peroxidase, and superoxide dismutase activities
Leaf enzyme extract
For the estimation of activities of antioxidant enzyme, leaf extract was prepared by homogenizing 2 g ice cold leaves in a mixture of 6 mL phosphate buffer of pH 7.0 (50 mM), 1 mL ethylenediaminetetraacetic acid (1 mM), 1 mL phenylmethanesulfonylflouride (1 mM), 1 mL Triton X-100 (0.5% v/v) and 1 mL polyvinyl pyrollidone (2% w/v) in a pre-chilled mortar and pestle. The homogenates were centrifuged at 12,000×g for 20 min at 4 °C. The supernatant was used for determination of enzyme activities.
Catalase activity
The catalase activity was assayed by measuring the initial rate of H2O2 disappearance using the method of Aebi (1984). Leaf enzyme extract at 0.1 mL was mixed with 3 mL H2O2 (30 mM accomplished by diluting 0.34 mL 30% H2O2 to 100 mL with the phosphate buffer of pH 7). The decomposition of H2O2 was followed by decline in optical density (OD) at 240 nm. The absorbance was noted with the help of a spectrophotometer (Spectronic UV-1700 Shimadzu, Japan) at the room temperature (= 20 °C) with the interval of 30 s using a blank containing buffer solution instead of H2O2 along with the enzyme extract. The activity of the enzyme was expressed as µM H2O2 (decomposed) kg−1 FM s−1.
Peroxidase activity
The activity of peroxidase was determined by the method of Chance and Maehly (1955). The reaction mixture in a total volume of 3 mL was prepared by taking 2.10 mL DDW, 0.32 mL phosphate buffer of pH 6.0 (100 mM), 0.16 mL H2O2 (0.5%), 0.32 mL pyrogallol solution (5% w/v) and 0.1 mL leaf enzyme extract. The absorbance of the reaction mixture was read at the interval of 20 s at 420 nm with the help of the spectrophotometer using a blank. The assaying period was approximately 3 min and the time interval between two successive readings was 20 s and the temperature was 20 °C. the blank was prepared using the buffer solution instead of the leaf enzyme extract, along with the other ingredients of the mixture. The activity of the enzyme was expressed as µM pyrogallol (oxidised) kg−1 FM s−1.
Superoxide dismutase activity
The activity of the enzyme was determined by the method of Kono (1978). The reaction mixture in a total volume of 3 mL was prepared by taking 1.2 mL sodium bicarbonate of pH 10.2 (50 mM), 0.3 mL NBT (24 µM), 0.2 mL EDTA− Fe++ (0.1 mM) and 0.1 mL leaf enzyme extract. Just after the addition the enzyme extract, the absorbance was recorded for 2 min with the help of the spectrophotometer at 560 nm using a blank containing buffer solution instead of the leaf enzyme extract along with the above solutions. Using the unit of the superoxide dismutase (the amount of the enzyme required for causing 50% reduction of NBT at 25 °C) the activity of the enzyme was expressed as mM NBT (reduced) kg−1 FM s−1.
Proline content in leaves
The proline content was measured in fresh leaves following the method of Bates et al. (1973). Leaves at 0.5 g were homogenized with the help of a pestle and mortar with 10 mL 3% sulfosalicylic acid. The homogenate was filtered through Whatman No. 2 filter paper and the filtrate was collected into a test tube. The final volume of the filtrate was made to 10 mL by adding 3% aqueous sulfosalicylic acid (if required). From this extract filtrate, 2 mL were mixed with glacial acetic acid and acid ninhydrin each at 2 mL in a test tube. This mixture was heated on a boiling water bath for 1 h. The reaction was terminated by transferring the test tube to ice bath followed by the addition of 4 mL toluene with vigorous shaking for 15–20 s. The chromophore containing toluene was aspirated from the aqueous phase and was warmed to room temperature. The absorbance of the red colour was read at 520 nm against a toulene blank on the spectrophotometer. The amount of proline in the sample was calculated using a standard curve prepared from pure proline ranging from 0.1 to 36 µmol and expressed on fresh mass basis of the sample. The proline content is expressed as µmol g−1 FM.
Leaf nitrogen, phosphorus and potassium contents
The oven-dried leaf powder at 100Â mg was transferred into a 50Â mL Kjeldahl flask followed by the addition of 2Â mL analytical reagent grade concentrated sulphuric acid. After heating the contents for about 2Â h followed by cooling for about 15Â min at room temperature, 0.5Â mL hydrogen peroxide (30%) was added drop by drop and the solution was heated again till the colour of the solution changed from black to light yellow. The heating and cooling procedure was repeated until the content of the flask became colourless. The peroxide-digested material was transferred from the Kjeldahl flask into a 100Â mL volumetric flask with three washings each with 5Â mL DDW. The volume of the flask was maintained by DDW. The digested material was used for estimation of N, P and K content. Leaf N and P contents were estimated according to the method of Lindner (1944) and Fiske and Subba Row (1925), respectively. Leaf K content was analyzed using flame-photometer (Hald 1946).
Determination of secondary metabolites
Peltate glandular trichome diameter and density
Peltate glandular trichome (PGT) diameter and density were determined with the help of scanning electron microscope (SEM) of make JEOL, JSM-6510 LV, Japan. Leaves were coated with gold prior to scanning. The diameter of the PGTs was determined in micrometres (µm) using SEM. The calculations were done according to Maffei et al. (1986). The PGT diameter was expressed as µm and density as mm−2.
Essential oil content and menthol content
Essential oil (EO) content was determined by the hydro distillation method of Guenther (1972). Fresh leaves at 50Â g allowed distilling for 3Â h distillation and the EO content was expressed as % (v/w). The menthol content of EO was determined by gas chromatography. Menthol was calculated by knowing its peak area given in the chromatogram. The menthol content (%) was determined by dividing the menthol peak area by the total chromatogram and the resulting quotient was multiplied by 100 (Adams 2007).
The details for the estimation of menthol content by GC were as follows: GC, Nucon 5700, New Delhi, India was equipped with an AT-1000 stainless steel column, a flame ionization detector and an integrator. N was used as the carrier gas. The flow rates of N, H and O were maintained at 0.5, 0.5, and 5 mL s−1, respectively. The temperature of the detector was 250 °C; oven, 160 °C and injector, 250 °C. The sample size was 2 µL invariably.
Statistical analyses
The data were statistically analysed using the SPSS 16.0 for Windows Software Package and the replicate means were separated by Duncan’s multiple range tests.
Results
Growth characters
The data (Table 1) revealed that increasing levels of salinity decreased shoot and root length, leaf number, leaf area, shoot and root fresh weight and shoot and root dry weight linearly. A decrease of 16.12%, 20.89% and 25.06% in fresh weight per plant, for e.g., was noted with 50, 100 and 150 mM NaCl respectively over the water-sprayed control. A reverse relationship was observed between salinity levels and parameters namely chlorophyll content, PN, gs, Ci, E, CA activity and leaf nutrient such as N, P and K contents (Table 2). However, increasing salt levels enhanced CAT, POX, SOD and proline content continuously (Table 3). An increase of 23.77%, 32.10% and 40.03%, for e.g., in CAT activity was observed with 50, 100 and 150 mM NaCl, respectively, over the no salt treatment. The graded levels of salinity declined EO Yield, menthol content and yield and PGT diameter progressively, the lower level of salinity (50 mM NaCl) decreased both EO content and PGT density; however, 100 mM NaCl improved these parameters to some extent over 50 mM NaCl (Table 3). The highest salt level (150 mM NaCl) gave slightly higher values even than the no salt treatment.
Foliar application of PGRs in order of SA > GA3 > Tria was found to be effective in enhancing almost all growth parameters (Table 4). The spray of SA improved for instance shoot fresh weight per plant by 46.05%, GA3 by 40.42% and Tria by 33.22% over the water-sprayed control. However, foliar sprays of PGRs did not vary in their effect for root dry weight (Table 4). An almost similar trend observed for physio-biochemical parameters in respect of the effects of foliar PGR treatments (Tables 5, 6). The spray of SA enhanced, for e.g., CAT activity, by 31.46%, GA3 by 21.80%, and Tria by 30.60% over the water-sprayed control (Table 6). Similarly foliar application of PGRs in order of SA > GA3 > Tria improved all yield and quality parameters, except PGT diameter (Table 6). For e.g., the spray of SA increased EO content by 80.00%, EO yield by 154.55%, menthol content by 53.84%, menthol yield by 53.84% and PGT density by 95.05% over the water-sprayed control (Table 6).
Among interactions 0 mM NaCl × SA excelled others for all growth parameters studied (Fig. 1). This interaction increased for example fresh weight per plant by 121.15% over the lowest value giving interaction 150 mM NaCl × water (Fig. 1). In respect of physio-biochemical parameters interaction 0 mM NaCl × SA proved best for chlorophyll content, PN, gs, Ci, E, CA activity and leaf nutrient such as N and K contents, while 150 mM NaCl × SA for CAT, POX, SOD and proline content (Figs. 2, 3). The interaction 0 mM NaCl × SA increased, for e.g., PN by 89.50% over the least value giving interaction 150 mM NaCl × water. The effect of interaction was not found to be significant on CA, SOD and proline and leaf P content (Figs. 2, 3). Of interactions, 0 mM NaCl × SA excelled others for EO yield, menthol content and yield and PGT diameter (Fig. 3). However, the perusal of SEM images (Fig. 4) and gas chromatogram (Fig. 5) revealed that interaction treatment 150 mM NaCl × SA proved to be best for EO content and PGT density (Fig. 3). Interaction 0 mM NaCl × SA gave, for e.g., 453.85% higher EO yield over the lowest value giving interaction.
Discussion
This study is an attempt to understand the effect of spray of PGRs under salt stress on the performance of peppermint through the study of various phenomena using growth, biochemical analysis, scanning electron microscopy and gas chromatography. In the present study, salt stress treatments decrease growth characteristics, photosynthetic parameter, leaf nutrients as also yield and quality attributes while increased the contents of antioxidant enzymes and proline (Figs. 1, 2, 3). The decrease in fresh weight of peppermint plants resulted from the application of NaCl particularly at 150 mM over the no salt treatment can be attributed to reduced shoot and root length, leaf number and area per leaf. The reduction in these growth characters may be attributed to hyperosmotic stress caused by NaCl leading to a water potential imbalance between the apoplast and symplast. The resulted low water potential would decrease turgor pressure hence diminished growth (Bohnert et al. 1995; Timperio et al. 2008). Moreover the reduction in root length may cause comparatively less nutrient and water absorption in salt treated plants resulting in suboptimal metabolism which may cause poor plant growth including root growth as depicted in root fresh weight. The decrease in dry weight of shoots may be correlated with the poor fresh weight of treated plants. Our findings on growth in respect of salt stress broadly corroborate with the findings of Li et al. (2014) on peppermint and Gengmao et al. (2014) on red sage. The salt stress not only decrease growth characters but also photosynthetic parameters (Fig. 2). The decrease in PN due to application of salt particularly 150 mM NaCl over no salt treatment may be attributed to decreased chlorophyll content, gs and E of NaCl treated plants. The suppressed photosynthesis by salt treatment is in accordance with the result of Khan (2003) on wheat and Babar et al. (2014) on fenugreek. Salinity stressed plants especially 150 mM NaCl treated ones exhibited a decreasing trend in respect of leaf nutrient contents (Fig. 2). This decrease in leaf nutrients may be correlated with the reduced root length of treated plants on one hand and salinity mediated ionic imbalance on the other. The effect of salt on leaf nutrients are in accordance with Yildirim et al. 2008. The salt stress on the other hand increased CAT, POD and SOD activities as also proline content (Table 3). The increase in antioxidant enzyme activities and proline content may be the result of the protective mechanism. Application of NaCl increases the synthesis of harmful reactive oxygen species (ROS) through salt effected ionic imbalance in the cell. To overcome the effect of these ROS, antioxidant enzymes and proline are synthesized in an ample quantity within the cell as a result of stress adaptation (Alscher et al. 2002; Sperdouli and Moustakas 2012). These results agree with those of Tuna et al. (2008) in maize plants, Sairam and Srivastava (2002) in Cassia angustifolia plants, Agarwal and Pandey (2004) in wheat. Salt stress especially 150 mM NaCl increased EO content and PGT density (studied for the first time in respect of the salinity) but decreased herb yield, EO yield as also menthol content and its yield (Table 3.). The decrease in these attributes could be because of the observed reduction in growth characters, photosynthesis and nutrient contents. The high density of PGTs of treated plants would naturally affect the EO content hence higher value of the oil content. Most of these findings are in agreement of Tabatabaie and Nazari (2007), Aziz et al. (2008) and Khorasaninejad et al. (2010).
Exogenously leaf-applied PGRs improved growth, biochemical, yield and quality parameters (Tables 4, 5, 6). The alleviation in growth of plants due to PGRs especially SA may be traced to the fact that PGRs increase membrane permeability, cell division and cell enlargement. The favourable response of plants to PGRs has also been reported by Yildirim et al. (2008), Babar et al. (2014) and Özkan and Baydar (2016). The improvement in PN resulted from the application of PGRs particularly SA may be ascribed to the enhancement in photosynthetic attributing characters like chlorophyll content, gs and E of treated plants. These findings may be well documented with support of Popova et al. (1997), Stevens et al. (2006), Ashraf et al. (2010) and Pazoki (2015). The improvement in nutrient contents are of PGR-treated plants particularly SA treated plants may be attributed to the enhanced membrane permeability on one hand and the longer root length on the other hence higher values for nutrient contents. These findings on nutrient content more or less match with those of Gunes et al. (2005) and Yildirim et al. (2008). The explanation for the improvement in activities of antioxidant enzymes as also proline content due to hormones especially SA is not far to seek. The PGRs particularly SA is supposed to act as secondary messengers for the metabolism responsible for the improved synthesis of antioxidant enzymes and osmolytes as well. The enhanced activities of the antioxidant enzymes and proline content due to PGR application, especially SA has been observed by other workers also including Senaratna et al. (2000) and Borsani et al. (2001). Plants treated with PGRs particularly SA gave higher value not only for herb yield and PGT density but also for EO content and yield as well as menthol content and yield (Figs. 4, 5). The improvement in these secondary metabolite parameters may be related to the higher values for growth and photosynthetic characters and nutrient contents of treated plant. The higher density of PGTs of treated plants may result in higher EO content. These results might be associated with the gene mediated improved metabolism. The role of SA in increasing secondary metabolites of plants has been well documented in various literatures (Zheljazkov 2010; Shabrangi and BeigiJazi 2014; Saharkhiz and Goudarzi 2014). The beneficial effect of foliar application of PGRs especially SA on the performance of peppermint under stress conditions (Figs. 1, 2, 3) may be explained on the same as discussed above. Our findings broadly corroborate with the findings of Shakirova et al. (2003), Arzhe et al. (2015), Pazoki (2015) and Zohra et al. (2016).
Conclusion
Based on the results of the present study, it could be concluded that peppermint plants were deleteriously affected by NaCl stress. The severity of the salt damage increased with the elevating concentration of NaCl. However, exogenously leaf applied PGRs ameliorated most of the parameters studied under stress and stress free conditions. The amelioration was more pronounced when plants were free from salt stress. Application of SA was comparatively more pronounced. As a conclusion, foliar application of SA treatment may present new prospects for growing peppermint in soils even containing moderate and high amounts of NaCl.
Author contribution statement
DK carried out the experimental work, analysed and prepared the manuscript. FM had supervised the work and was involved in the design of the experiment preparation and presentation of the manuscript.
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Acknowledgements
The authors are thankful to the University Sophisticated Instrumentation Facility, Aligarh Muslim University, Aligarh, for the SEM analysis. Thanks are also due to CIMAP, Lucknow, India for providing authentic plant material.
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Funding was provided by UGC Non-Net.
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Khanam, D., Mohammad, F. Plant growth regulators ameliorate the ill effect of salt stress through improved growth, photosynthesis, antioxidant system, yield and quality attributes in Mentha piperita L.. Acta Physiol Plant 40, 188 (2018). https://doi.org/10.1007/s11738-018-2769-6
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DOI: https://doi.org/10.1007/s11738-018-2769-6