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Article

Morpho-Physiological and Molecular Evaluation of Drought and Recovery in Impatiens walleriana Grown Ex Vitro

by
Marija Đurić
1,*,
Angelina Subotić
1,
Ljiljana Prokić
2,
Milana Trifunović-Momčilov
1,
Aleksandar Cingel
1,
Milorad Vujičić
3 and
Snežana Milošević
1
1
Department of Plant Physiology, Institute for Biological Research “Siniša Stanković”, National Institute of Republic of Serbia, University of Belgrade, Bulevar despota Stefana 142, 11060 Belgrade, Serbia
2
Department for Agrochemistry and Physiology of Plants, Faculty of Agriculture, University of Belgrade, Nemanjina 6, 11080 Belgrade, Serbia
3
Department of Plant Physiology, Faculty of Biology, University of Belgrade, Studentski trg 16, 11000 Belgrade, Serbia
*
Author to whom correspondence should be addressed.
Plants 2020, 9(11), 1559; https://doi.org/10.3390/plants9111559
Submission received: 13 October 2020 / Revised: 3 November 2020 / Accepted: 10 November 2020 / Published: 13 November 2020
(This article belongs to the Section Plant Response to Abiotic Stress and Climate Change)
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Versions Notes

Abstract

:
This study was carried out to examine the drought effect on development, physiological, biochemical and molecular parameters in Impatiens walleriana grown ex vitro. Experiment design included three treatments: Control plants—grown under optimal watering (35%–37% of soil moisture content), drought-stressed plants—non-irrigated to reach 15% and 5% of soil moisture content and recovery plants—rehydrated for four days to reach optimal soil moisture content. Drought reduced fresh weight, total leaf area, as well as dry weight of I. walleriana shoots. Drought up-regulated expression of abscisic acid (ABA) biosynthesis genes 9-cis-epoxycarotenoid dioxygenase 4 (NCED4) and abscisic aldehyde oxidase 2 (AAO2) and catabolic gene ABA 8′-hydroxylase 3 (ABA8ox3) which was followed by increased ABA content in the leaves. Decrement in water potential of shoots during the drought was not accompanied with increased amino acid proline content. We detected an increase in chlorophyll, carotenoid, total polyphenols and flavonols content under drought conditions, as well as malondialdehyde, hydrogen peroxide and DPPH (1,1′-diphenyl-2-picrylhydrazyl) activity. Increased antioxidant enzyme activities (superoxide dismutase, peroxidase and catalase) throughout drought were also determined. Recovery treatment was significant for neutralizing drought effect on growth parameters, shoot water potential, proline content and genes expression.

1. Introduction

Drought is an abiotic stress factor that adversely affects plant growth and development, manifesting its effects from the cell to the whole organism level. Moreover, the drought is considered to be crucial in reducing plant productivity compared to all other environmental factors [1,2,3,4].
Reduced cell water potential and turgor, photosynthesis, transpiration, nutrient uptake and numerous metabolic processes are common consequences of drought effects on plant growth and development [1]. Decreased content of photosynthetic pigments during drought limit photosynthesis and certainly represent the interest in almost all research on this subject [5,6]. Drought-induced production of reactive oxygen species (ROS) plays an important role in oxidation of proteins, membrane lipids, DNA and RNA [2]. The imbalance between production and removal of ROS forms as a consequence of oxidative stress, is caused by a large number of primary stress factors, such as drought [2,7]. Reactive oxygen species include hydrogen peroxide (H2O2), superoxide anion radicals (O2−), hydroxyl radicals (OH•), singlet oxygen (1O2) and nitric oxide (NO) [2,7]. Of all stated, the hydroxyl radical is the most reactive and is produced in the Haber–Weiss reaction from O2− and H2O2, and in the Fenton reaction of H2O2 in the presence of bivalent iron [7]. As there is no enzymatic reaction that can eliminate this radical, O2− and H2O2 content in the cells must be strictly controlled by the activity of antioxidant system defense. One of the most studied ROS effects on the structure and function of cells is the peroxidation of membrane lipids. Malondialdehyde (MDA), one of the end products of lipid peroxidation, is considered as an indicator of oxidative stress in cells and its content reflects the degree of membrane lipid damage [7]. In addition to toxicity, ROS are important signaling molecules that participate in plant responses to abiotic stresses [8].
The sensitivity of plants to drought depends on stress degree, stress duration, effects of other stress factors, plant species and their developmental stages [4]. Plants have evolved three major drought resistance mechanisms: Drought escape, drought avoidance and drought tolerance [9,10]. Resistance mechanisms lead to adaptive changes in plant growth and physio-biochemical and molecular processes. Using these different strategies, plants try to cope with drought and survive unfavorable periods and often combine strategies to confer drought resistance. Many plants complete their life cycle before encountering local or seasonal drought, and in that way “escape” from stress. Drought avoidance means the ability of a plant to maintain high water potential in tissues even in the drought period. This is accomplished through rapid stomatal closure, reducing leaf area and enhancing the water uptake through well-developed root system [4,10,11]. In seed plants, particularly angiosperms, regulation of stomatal movement and transpiration is controlled by plant hormone abscisic acid (ABA) [12,13]. During drought, increase in ABA content could be the result of increased ABA biosynthesis and/or decreased ABA catabolism [14,15]. Biosynthesis of ABA is well established and branches from the terpenoid biosynthesis pathway in plastids [14]. The main regulatory step in ABA biosynthesis is encoded by 9-cis-epoxycarotenoid dioxygenase (NCED) gene. The product of NCED gene expression is the enzyme 9-cis-epoxycarotenoid dioxygenase that cleaves the carotenoid precursors cis-violaxanthin and cis-neoxanthin to produce xanthoxin, first C15 precursor of ABA. Through oxidation, xanthoxin is then converted to ABA aldehyde in cytoplasm. Abscisic aldehyde oxidase, product of abscisic aldehyde oxidase (AAO) gene, catalyzes the final step in ABA biosynthesis converting ABA aldehyde in the biologically active form ABA. Likewise, during drought ABA could be released from sugar-conjugated forms such as ABA glucosyl estars by β-glucosidase activity. Conjugation is a way of inactivating ABA in plant cells [16]. Hydroxylation of ABA to phaseic acid is the main ABA catabolic pathway catalyzed by ABA 8′-hydroxylase enzymes which are encoded by cytochrome P450 monooxygenase gene family, CYP707A [14,15]. The processes of ABA biosynthesis, conjugation and catabolism act in a coordinated manner to control the ABA level in plants. During drought ABA induces stomatal closure, thereby reducing transpirational water loss. Increased ABA content during drought affects the stomatal closure by regulating the ionic transport in the guard cells through Ca2+ dependent or Ca2+ independent pathways [17]. In both cases, the plasma membrane of guard cells is depolarized through inhibition of H+-ATPase activity, inhibition of K+ influx channels, and activation of the anion channel [18,19]. Moreover, depolarization activates K+ efflux channels which in turn leads to a decrease in net ion concentration in guard cells. Fewer ions increase water potential in guard cells, which becomes higher than in surrounding cells. A gradient in water potential between the guard and surrounding cells enables water transport from guard to surrounding cells [19]. Losing water from guard cells decreases the cell turgor pressure which is followed by the closure of the stomata apparatus. The opposite effect of drought on plants stomatal behavior and ABA content has a rehydration process [20]. Drought tolerance implies the ability of a plant to maintain normal physiological functions even at the prolonged drought period and lower water potential in tissues. This is achieved mainly by the expression of specific genes that provide the accumulation of osmoprotectants and the components of the antioxidant system defense [1]. The accumulation of a large number of these components during drought is increased, including the amino acid proline [21], carotenoids [22], phenolic compounds [23,24] and antioxidant enzymes [25]. Antioxidant enzymes, such as superoxide dismutase (SOD), peroxidase (POX) and catalase (CAT) remove ROS from cells and reduce oxidation [7]. These enzymes are crucial to control O2− and H2O2 level in cells, preventing forming of the most harmful hydroxyl radicals.
Impatiens walleriana (Balsaminaceae) is one of the three Impatiens species (beside Impatiens hawkeri and Impatiens balsamina) which are commercially produced in Serbia for many years. Due to its decorative traits and long flowering period, I. walleriana belongs to the most popular horticultural species all over the world [26]. Plants have high requirements for the presence of water in the substrate, which deficiency leads to a rapid drop in cell turgor pressure and tissue dehydration. This is the main problem in commercial production and market placement of these plants. Drought has detrimental effects on I. walleriana growth and development [27,28,29,30,31,32]. In this work, we have investigated the drought and recovery effect on growth, tissue water potential and proline and antioxidants content as well as activity of antioxidant enzymes in I. walleriana grown ex vitro. Similarly, we examined the effects of drought stress and recovery treatment on ABA content and expression of ABA metabolic genes. As plants responses to drought depend on many factors, in the present work we hypothesized differences in I. walleriana response to drought and recovery treatments on morpho-physiological, biochemical and molecular level.

2. Results

2.1. Soil Moisture Content Changes after the Onset of Drought Stress

Changes in soil moisture content after the imposition of drought stress are presented in Figure 1. Drought stress was imposed on 44 days old I. walleriana and soil moisture content amounted 37% at this point. As shown in the Figure 1, control plants were grown on well-watered soil constantly during the experimental period while the two other plant groups were not irrigated to reach targeted soil moisture percentage (15% and 5%). From optimal soil moisture content in control plants (35%–37%) it was necessary for 9 days to achieve 15%, and 20 days to get 5% of soil moisture content. Recovery of drought-stressed plants was achieved with four days watering for two drought point (15% and 5%).

2.2. Changes in the Fresh Weight (FW), Total Leaf Area and Dry Weight (DW) in I. walleriana Subjected to Drought Ex Vitro

Reduced FW of shoots under drought was observed at both drought points, with the most expressed effects at 5% of soil moisture content (Figure 2a). At this point, FW was reduced by 63.91% in comparison to the control plants. Furthermore, at the lowest amount of water in a substrate, the effects of drought on total plant leaf area were the most pronounced. Leaf area of plants at 5% of soil moisture content was lesser by 3.17 times in comparison to the control plants (Figure 2b). Measurement of DW point to an expected decrease of DW in drought-stressed I. walleriana (Figure 2c) and DW was reduced for 54.96% in I. walleriana at 5% of soil moisture content. Recovery treatment had a positive impact on growth parameters in drought-stressed I. walleriana. FW, total leaf area and DW increased for 1.43, 1.63 and 1.44 times, respectively, in I. walleriana recovered from 5% of soil moisture content.
Drying to 15% and 5% of soil moisture content induced morphological changes in I. walleriana (Figure 3) measured through above mentioned growth parameters (Figure 2). Control plants for two drought point (Figure 3b,e) had higher biomass comparing to stressed plants (15% and 5%) (Figure 3c,f) while the recovery plants of two drought point (Figure 3d,g) had a higher biomass than stressed plants. In comparison to control, height was reduced, and flowering was delayed in stressed plants (unmeasured, just noticed parameters). Further, at 5% of soil moisture, leaves of drought-stressed I. walleriana had changed morphology manifested through the wilting and rolling (Figure 3f).

2.3. ABA Content in Drought-Stressed I. walleriana

With increasing drought intensity endogenous ABA content also increased (Figure 4). In drought-stressed plants ABA content was higher for 2.92 and 4.3 times (respectively for 15% and 5% of soil moisture content) than in control plants. Recovery treatment for four days did not induce a statistically significant reduction in ABA content, in comparison to the drought-stressed plants.

2.4. Expression of ABA Metabolic Genes in Drought-Stressed I. walleriana

Expression analysis of ABA metabolic genes (9-cis-epoxycarotenoid dioxygenase 4 (NCED4), abscisic aldehyde oxidase 2 (AAO2) and ABA 8′-hydroxylase 3 (ABA8ox3)) revealed amplification of specific fragments in I. walleriana leaves (Figure 5). At 15% of soil moisture content the number of NCED4 transcript copies were drastically increased, while on 5% of soil moisture content transcript number decreased but still was higher than in control plants. On the other hand, AAO2 gene expression was the most pronounced at 5% of soil moisture content. Number of copies of NCED4 transcript per 1 ng RNA varied from 759 to 590 at 15% and 5% of soil moisture, respectively. For AAO2 gene number of transcript copies varied from 32 to 75, respectively, for two drought points. Likewise, the number of copies for ABA8ox3 in drought was lower in comparison with NCED4 and AAO2 expression. At 15% and 5% of soil moisture content number of copies of ABA8ox3 varied from 16 to 40 per 1 ng of RNA. Recovery treatment decreased NCED4 transcript number at both drought points in I. walleriana, while effects on AAO2 transcript number reduction was most pronounced at 5% of soil moisture. Recovery was slightly induced and then decreased ABA8ox3 transcript number at 15% and 5% of soil moisture, respectively.

2.5. Shoot Water Potential and Proline Content in Drought-Stressed I. walleriana Grown Ex Vitro

Shoot water potential decreased in drought by 1.73 and 1.85 times below control values at two drought points in I. walleriana, respectively (Figure 6a). On the other hand, recovery treatment increased shoot water potential of drought-stressed plants to the control values. In order to determine the degree of osmotic adaptation of I. walleriana under drought conditions, the content of the amino acid proline in leaves was evaluated. Before beginning the drying period proline content was the highest (6.94 μM g−1 FW) and decreased with the duration of experimental period. Compared to the control plants, an unusual decrement in proline content in I. walleriana was observed at both induced drought points (Figure 6b). Proline content was lower by 48.22% and 26.46% in comparison to control plants at 15% and 5% of soil moisture content, respectively. Recovery of plants completely increased proline content up to the level of control values for both drought points.

2.6. Total Polyphenols, Flavonols and 1,1′-diphenyl-2-picrylhydrazyl (DPPH) Activity in Drought-Stressed I. walleriana

Total polyphenols content in I. walleriana increased during drought (Figure 7a). In comparison with control plants total polyphenol content was higher by 64.02% and 24.87% at 15% and 5% of soil moisture, respectively. In I. walleriana recovered from first drought point total polyphenols content increased by 24.99% and decreased by 59.59% in plants recovered from second drought point, compared to drought-stressed plants. Recovered plants from second drought point had a lower total polyphenol content than control plants group. As shown on Figure 7b, drought stress also induced increment in flavonols content in leaves of I. walleriana grown ex vitro. Flavonols content was higher by 20.41% and 18.54% at 15% and 5% of soil moisture content, respectively, in comparison to the control plants. The rehydration process decreased flavonols content to slightly below the control values after the most pronounced drought stress. Drought stress also induced increment in antioxidant activity measured by DPPH method. Antioxidant activity was higher with 5.60% and 11.50% at 15% and 5% of soil moisture compared to control plants, while in recovered plants noticed a similar trend as for total polyphenol and flavonols content (Figure 7c). Plants recovered from first drought point increased antioxidant activity for 3.84% in comparison to drought-stressed plants, while recovery from second drought point decreased antioxidant activity for 20.35% (lower than in control plants for 8.86%).

2.7. Spectrophotometrical Quantification of Photosynthetic Pigments, Hydrogen Peroxide and Malondialdehyde in Drought-Stressed I. walleriana Grown Ex Vitro

Spectrophotometrical analysis showed that drought induced changes in total chlorophyll and carotenoids content in I. walleriana (Figure 8a,b). Drought-induced changes in both, chlorophyll and carotenoid content, had a similar trend. The increment in the content of the total amount of chlorophyll and carotenoid in I. walleriana was observed at both drought points. Compared to the control plants, chlorophyll increment was 29.85% higher at 5% of soil moisture content (Figure 8a), while the carotenoid increment at the same soil moisture content was more pronounced. Carotenoid content was 2.23 times higher in I. walleriana leaves at 5% of soil moisture content than in control plants (Figure 8b). The recovery of plants had a similar effect on the chlorophyll and carotenoid content in the leaves of drought-stressed I. walleriana. Recovery from the first drought point (15%) slightly increased chlorophyll and carotenoid content, while the recovery from the second drought point (5%) decreased chlorophyll and carotenoid content in I. walleriana.
As the production of ROS increased during drought, the content of H2O2 was also determined (Figure 8c). A statistically significant increment in H2O2 content in I. walleriana was observed by exposing the plants to the progressive drought (Figure 8c). Compared to control plants, the H2O2 content was increased by 34.41% at 5% of soil moisture while recovery treatment reduced H2O2 content below the control level at this point. The effect of different drought intensities on the degree of lipid peroxidation in I. walleriana was determined based on the MDA content (Figure 8d). As in the case of proline content (Figure 6b), very high MDA content in I. walleriana leaves was observed at the start point of imposition of drought stress. A significant increment in MDA content was observed when the soil moisture in the substrate reached 15%. The increment in MDA content was 25.13% higher in comparison to control plants. With increasing drought intensity, the MDA content dropped to a level similar to that of control plants. From the first drought point (15%), recovery managed to lower the MDA content in comparison to control plants, but from the second drought point (5%), recovery induced a slight jump (for 14.69%) in MDA compared to control group of plants.

2.8. Superoxide Dismutase, Catalase and Peroxidase Activity in Drought-Stressed I. walleriana

The effects of drought on total SOD activity of I. walleriana are shown on Figure 9a, while on Figure 9b are presented SOD isoforms and their relative expression. At 15% moisture content in the substrate, plants drastically increased SOD activity, which was 1.65-fold higher than control values. With drought stress progression, SOD activity decreased in comparison to control plants. Recovery of plants contributed to the reduction of SOD activity to the level in control plants at 15% of soil moisture content. I. walleriana expressed one Mn-SOD and two Cu/Zn-SOD (A and B) isoforms in all treatments with the strongest activity of Cu/Zn-SOD B isoform.
At the drought stress start point, higher POX (Figure 9c) and CAT (Figure 9e) activities were observed in comparison to both controls. These results correspond with proline (Figure 6b) and MDA content changes (Figure 8d) at the same point. There were no significant changes in POX activity between control and drought-stressed I. walleriana plants at 15% of soil moisture content, while the CAT activity at the same point was higher for 29.77% in drought-stressed plants. The opposite trend was observed in plants at 5% of soil moisture content. In drought-stressed plants POX activity was almost two time higher while the CAT activity was not significantly changed in comparison to control plants. Recovery from the first drought point decreased POX and CAT activities, while recovery from the second drought point decreased POX activity and, at the same time, increased CAT activity. Different POX isoforms in I. walleriana subjected to drought are presented in Figure 9d. Total four POX isoforms were detected on gel and, among them, D isoforms are specific for non-stressed I. walleriana plants.

3. Discussion

The drought is considered as the most represented problem in horticulture, agriculture and forestry. Initially, plants response to drought in a similar way, and that is manifested through inhibition of various parameters of growth and development [10,33]. In this work, we defined the effects of two drought points and recovery on the morphological, physiological, biochemical and molecular parameters of the I. walleriana grown under controlled ex vitro conditions.
It is widely known that drought reduces plant growth primarily due to the inhibition of cell division and enlargement, which is considered as one of the most sensitive processes during drought. With increasing drought intensities, FW and DW of I. walleriana were reduced. Similar results for I. walleriana were described by authors [28,29,32], as well as for I. balsamina [34] and petunia [35]. Drought significantly reduced the total leaf area of I. walleriana cultivated ex vitro, as previously was recorded in petunia and cut rose [35,36]. Leaf area reduction is a strategy that prevents excessive water loss from tissues during drought stress. Reduced leaf area mostly means less water wasted by transpiration through stomata. Similarly, to avoid or mitigate the drought effects, many plants completely reject leaves or reduce the transpiration surface in a different way, e.g., by curling leaves [11]. In this experimental work was noticed that flowering was delayed in drought-stressed I. walleriana which reduced reproductive capacity. Authors [27] and [28] previously described that drought-stressed I. walleriana grown in the greenhouse conditions reduced number of flowers.
With increment in drought intensities, ABA content also increased in I. walleriana leaves. ABA increment during drought is generally expected, considering ABA’s roles in the stomatal conductance and transpiration rate control during drought [37,38]. Increment in ABA content in I. walleriana leaves was correlated with gene expression analysis of ABA biosynthesis and catabolic genes. Up-regulated NCED4 and AAO2 genes in drought-stressed I. walleriana were observed, as well as ABA8ox3 gene expression. Up-regulated catabolic gene ABA8ox3 in drought-stressed I. walleriana may be resulted from the feed-back regulation by the increasing of ABA content and NCED4 and AAO2 expression. The similar results were previously described for many plants. Increased expression of ABA biosynthesis genes NCED and TAO1 (AAO gene family) were observed in drought-stressed tomato [39] as well as NCED3 in drought-stressed rice [40]. Authors [40] also analyzed expression of three ABA8ox genes in drought-stressed rice and showed increased expression in drought for ABA8ox3. Rehydration decreased expression for NCED3 but ABA8ox3 was instantly induced in rice. This relationship in expression of ABA biosynthesis and catabolism in the rehydration process allowed decreased ABA content in rice leaves. In study with Pisum sativum [41] it was observed that rapidly imposed drought stress did not induce expression of PsAAO3 gene, while its expression is stimulated under progressively imposed drought by withholding watering. On the other hand, high level of NCED2 and NCED3 genes transcripts was observed in both drought treatments with differences in organ-specific expression. Recent study of drought effect on ABA content and ABA metabolic genes expression in Pinus sylvestris and Picea abies showed that ABA content during drought was not regulated on transcriptional, but more likely on posttranscriptional level [42]. Authors concluded that ABA level in roots and needles were not determined by the levels of ABA biosynthetic genes expression. Recovery treatment for four days did not restore ABA content in drought-stressed I. walleriana, but we suppose that ABA content in recovering plants would certainly drop to the control level during the time. Similar rehydration results in relationship to ABA content are described previously in the early nineties [43] and later for grapevines [44], and characterized as ABA “after effect” on stomata and transpiration rate. This means that ABA synthesized during drought could control stomatal conductance and transpiration rate in early recovery phases until the moment when its content starts to decrease. When ABA content starts to decrease in the rehydration process, stomatal conductance and transpiration rate starts to increase. Relationship between expression of ABA biosynthesis and catabolism genes in recovery treatment could be the reason for unchanged ABA content in leaves of drought-stressed and recovered I. walleriana. It could be expected that ABA8ox3 gene expression increased after certain period of watering to reduce ABA content, but as well, main catabolism role could have another gene from the CYP707A family in I. walleriana. Moreover, ABA may be inactivated by sugar-conjugation and forming ABA glucosyl esters.
In addition to the role in transpiration rate control, ABA’s role in drought tolerance could express through up-regulation of different genes involved in plants adaptive response to drought such as genes for water transporters—aquaporins (AQP), phenolic and antioxidant compounds [45,46,47].
Decreased shoot water potential was observed in I. walleriana exposed to drought. The reduction of water potential during drought was also recorded in cotton [48] and Chromolaena odorata leaves [49]. For the water trending in the direction of the substrate → root → stem → leaf → atmosphere, it is necessary to have a difference in water potential between these parts. Drought can reduce the water potential in the substrate below the water potential value in the root xylem, thereby preventing its adoption. During the evolution, plants have evolved mechanisms of tolerance for various types of stress, which include, among others, mechanisms that provide water retention in tissues during dehydration [50]. To allow the absorption and movement of water, many plant species accumulate specific metabolites that further lower the water potential in cells that can reach values below the water potential of the substrate [51]. In this way, a gradient is created in the water potential between the substrate and the root, which ensures the water flow through the plant. Such substances are generally accepted as compatible solutes or osmoprotectants. The osmoprotectants include amino acids, sugars, sugar alcohols (xylitol, sorbitol and mannitol), polyamines and quaternary ammonium compounds [50,51]. Osmoprotectants also protect cellular structures, enzymes and scavenge ROS [51]. Amino acid proline is often considered as a stress indicator because in most plant species increased proline accumulation is associated with plant responses to different types of abiotic stress [51]. Increased proline content during drought was observed in many plant species [52,53] but our results demonstrated that proline has no significant osmoprotectant role in drought-stressed I. walleriana. Drought stress could negatively regulate the proline biosynthesis affecting the activity of enzymes involved in the biosynthesis of this amino acid. Nevertheless, the absence of a positive correlation between proline content and drought stress in I. walleriana may reflect the predominance of some other osmotic adjustment mechanism.
Polyphenols are the largest group of plant secondary metabolites with different roles in plants growth and development, including plants responses to biotic and abiotic stress factors [24]. Members of polyphenols are involved in seed germination, cell division, nutrient uptake, pollen development, signal transduction and plant interaction with environment. All polyphenols originated from phenylalanine and, on basis of the presence of multiple phenolic structural units, are divided into several groups (phenolic acid, flavonoids, stilbenes and lignans). As antioxidants, polyphenols are very important in scavenging ROS forms in stressful conditions and preventing molecules oxidation and membranes peroxidation [24]. Increased accumulation of polyphenols in responses to drought was observed for many plants. Recent researches showed that drought induced increase in polyphenols and flavonoids in Triticum aestivum [54], three Achillea species [55], Tymus vulgaris [56], Achilea pachycephala [57] and Hordeum vulgare [58]. Increment in total polyphenols and flavonols (subgroup of flavonoids) in I. walleriana, indicated that drought positively regulates biosynthesis of phenolic compounds which plays important role in elimination of ROS and plant defense against drought. It is widely known that drought regulates many genes of phenylpropanoid metabolism to increase accumulation of phenolic compounds in plants [24]. Increased accumulation of total polyphenols and flavonols was accompanied with enhanced resistance of I. walleriana to oxidative stress. Similar pattern of accumulation of these secondary metabolites in recovered I. walleriana is dependent of previously imposed drought stress intensity.
Antioxidative activity of secondary metabolites in drought-stressed I. walleriana was showed through DPPH radical scavenging method. DPPH method is characterized as a rapid, simple and economic method, and is often used for evaluating antioxidative potential of antioxidants in different biological sources [59]. Antioxidants react with free radical to prevent oxidative process in its initiation, propagation or termination. Increased antioxidant activity based on DPPH assay was noticed in drought-stressed I. walleriana as well as in Serbian melliferous species [60], Saccharum officinarum [61], Achillea species [57], Silybum marinum [62] and many others.
Chlorophyll increment during drought is unusual because the lack of water in the tissues generally disturb chlorophyll biosynthesis. However, authors [63] have described chlorophyll increment in osmotic stress induced by polyethylene glycol in grass Bouteloua gracilis while in some ornamental plants, drought stress did not affect chlorophyll content [64]. We also observed an increase of chlorophyll content in drought-stressed I. walleriana. Theoretically, increased chlorophyll content may enhance the rate of photosynthesis. Obviously, that is not enough to overcome the problem of drought in the context of plant productivity, but resources can be used in the biosynthesis of various components in chloroplasts, such as osmoprotectants, fatty acids, starch or other compounds with a protective role in stress. Likewise, first reactions in ABA biosynthesis take place in chloroplasts, so maybe these protective mechanisms allow an increment in chlorophyll in drought. Similar explanation for unusual chlorophyll increment in Bouteloua gracilis under osmotic stress was provided by [63]. Since carotenoids have a photoprotective or an antioxidant role in plants, increased carotenoid content during drought is not unexpected. As in this experiment, increased carotenoid content during drought was also previously observed in Helianthus annuus [65] and Vataire macrocarpa [22].
Increased H2O2 content in stress conditions is considered as an indicator of the degree of oxidative stress in plants. In I. walleriana plants exposed to progressive drought, a drastic increment of H2O2 was observed. The similar results have also been described in Achilea sp. [55] and Amaranthus tricolor [66] exposed to drought stress. H2O2 is a non-radical ROS form that is synthesized in all cell compartments, including chloroplasts, peroxisomes, mitochondria, plasma membranes and apoplast. Plant cells, unlike animals, are tolerant to high concentrations of H2O2 and H2O2 treatments often increase the resistance of plants to different types of abiotic stresses [67,68]. The toxicity of H2O2 in the plant cells is reflected in its ability to form OH• [3]. In some plant species, such as the epiphyte Guzmania monostachia, there was observed a decline in the H2O2 content during drought [69]. The reason for this is the presence of crassulacean acid metabolism (CAM) metabolism at G. monostachia, which allows the accumulation of malate and reduction of photorespiration as a source of H2O2. In addition, very high glutathione reductase activity was observed in water deficit conditions in these epiphytes. Through lipid peroxidation, ROS disrupt the integrity and functionality of biological membranes. Lipid peroxidation products include various intermediates and final products like MDA, which is the most often mentioned and tested parameter in different stress conditions. Increased MDA content was observed in leaves of I. walleriana plants exposed to drought. The similar results have been described previously for Vigna unguiculata [70] and Eucalyptus globulus [71]. However, there are literature data describing MDA content has not changed in drought or even declined [55,72]. In this experiment, MDA content in the cells was not changed after the exposure of I. walleriana to progressive drought. Most probably, the reason for this is increased activity of antioxidative defense system whose components, both enzymatic and non-enzymatic, remove ROS forms and their products, thereby preventing cell death [73,74]. In progressive drought I. walleriana increased total polyphenol content, flavonols, DPPH activity, carotenoids, as well as POX activity. Increased content of antioxidants contributed to protection of cell membranes stability through preventing lipids disruption, which resulted in unchanged MDA content. A reason for a slight jump in MDA content after recovery from progressive drought, in comparison to MDA control values, could be attributed to I. walleriana metabolism plasticity to cope with drought stress. The components of the antioxidative defense system of plants, depending on the genotype and the causes of their induction, act in a way that at the given moment provides maximum protection [7]. Their activity may be increased, but also reduced or unchanged in stressful conditions [75]. If some component of the antioxidant protection system reduces its activity, the activity of another component increases, compensating for this initial lack of activity. In some plants in stressful conditions, the activity of non-enzymatic antioxidant factors is dominant, while in others it is attributed to enzymatic components. In any case, their functioning is complex and dynamic and depends on a large number of factors at a time, with the unchanged purpose of action.
Increased oxidative stress, altered the activity of antioxidant enzymes in I. walleriana. In most cases, elevated ROS concentration in the cells increased the activity of the enzymes that remove ROS in order to establish homeostasis in the organism. Superoxide dismutase converts the superoxide anion radical into H2O2, and present the first line of defense against ROS. Further, enzymes CAT and POX translate H2O2 to water and oxygen. Increased SOD activity was observed in I. walleriana as well as in Glycyrrhiza glabra [76], Cerasus humilis [77] and rice [78] as a response to oxidative stress. The variability in SOD activity caused by tissue dehydration, besides its increasing, also includes declining or unchanged activity [79,80]. Increased SOD in I. walleriana was followed by increased CAT activity in order to convert produced H2O2 to water and oxygen. That is actually the reason why determined H2O2 content at 15% of soil moisture was not significantly different between control and drought-stressed plants. Additionally, different SOD isoforms are expressed and detected in drought-stressed I. walleriana. SOD enzymes isoforms are classified by metal as a cofactor into three groups: Cu/Zn-SOD, Mn-SOD and Fe-SOD. In wheat, the Mn-SOD isoform plays a major role in the scavenging of superoxide radicals [81], while in sugarcane Fe-SOD were strongly induced in chloroplast during drought [82]. In this experiment three detected SOD isoforms (one Mn-SOD and two Cu/Zn-SOD) were expressed in all treatments. Differently expressed SOD isoforms during viral infection and virus elimination in I. walleriana were previously described by [26]. Catalase is considered as an energy-efficient, highly effective enzyme, not only because of its catalytic properties, but also because it is the only antioxidant enzyme that does not produce a new ROS form. Depending on the H2O2 content, CAT shows bifunctionality. When H2O2 content is lower than 1 μM, CAT has a peroxidative activity and demand for the electron donor for the reduction of H2O2. On the other hand, higher H2O2 content enabled a rapid degradation of H2O2 to water and oxygen [83]. In drought-stressed I. walleriana grown at 5% of soil moisture content, decreased SOD activity was followed by unchanged CAT activity in comparison to control plants. However, at this drought point high POX activity was observed and obviously POX has a main role in removing of high H2O2 content. Similarly, drought stress differently affects POX isoforms in I. walleriana, as described previously for I. walleriana grown in vitro under water deficit condition [32] and Trifolium sp. in a growth chamber [84]. Peroxidases have a higher affinity for H2O2 by eliminating it from different cell compartments using different electron donors. Ascorbate and glutathione peroxidase are the most involved in ROS detoxification, catalyzing the H2O2 reduction by electron donors, ascorbate and glutathione [85]. High POX activity, together with high polyphenols, flavonols and carotenoid content is a dominant defense component of antioxidant system in I. walleriana in progressive drought. In general, both enzymatic (SOD, POX, CAT) and non-enzymatic components (phenolic compounds, carotenoids) of antioxidant system defense are very important in I. walleriana adaptive responses to drought.

4. Materials and Methods

4.1. Plant Material and Experiment Design

The experiment was conducted from May to July 2018 in a growth chamber at Faculty of Agriculture, University of Belgrade. Seeds of I. walleriana (Xtreme Scarlet, Syngénta) were germinated on plates containing Klasman Potgrond H commercial substrate. The average temperature ranged from 22–25 °C (day) to 17 °C (night), with photoperiod of 16/8 h (day/night), 100% relative humidity and light intensity of 250 mmol m−1s−1. After seed germination, plants continued to grow under the same temperature, light intensity and photoperiod, but relative humidity was 55%–60%. One-month-old seedlings were transplanted into 10 by 10 by 13 cm plastic pots containing 450 g of the Klasman substrate and irrigated daily to reach an optimal soil moisture of 35%–37%. The drought stress was started after 14 days of transplanting I. walleriana growth in plastic pots under optimal watering. Control plants grow under optimal irrigation (35%–37% of soil moisture content) while two other plant groups were not irrigated to reach of 15% and 5% moisture in the substrate. There were recovery plant groups for both drought treatments, where the effects of drought on plants had been gradually neutralized. Recovery of stressed plants was achieved by watering for four days to optimal soil moisture content. The leaves were sampled from plants at “start point” (on time of beginning the drying period when soil moisture was 35%–37%), control, drought-stressed and recovered plants (seven treatment groups of I. walleriana). All samples were frozen in liquid nitrogen and then stored at −80 °C for further analyses.

4.2. Measurements of Soil Moisture Content, Flavonols, Shoots Water Potential, Fresh Weight of Shoots, Leaves Area and Dry Weight of Shoots

The soil moisture content was measured every morning (at 9 a.m.) with the Theta Probe (Type ML2x, Delta-T Devices Ltd., Cambridge, UK). The flavonols content in the leaves was measured by Dualex Scientific (FORCE-A, Orsay, France)—the optical sensor which provides a simple, fast and non-destructive measurement in plant leaves. Measurement of shoots water potential was carried out in the pressurized chamber under the pressure of nitrogen gas (Soil Moisture Equipment Corp., Santa Barbara, CA, USA). A pressure which leads to the first drops of xylem sap was used as the value of the water potential and was expressed in MPa. Subsequently, FW of shoots and total leaf area by area meter were measured (LI-3100 AREA METER, LI.COR. Lincoln, NE, USA). Shoots DW was measured after the samples drying for a few days on room temperature and then 48h at a temperature of 70 °C.

4.3. Determination of Abscisic Acid Content

ABA extraction from leaves was carried out as described by authors [39]. Measurement of ABA content was determined by ELISA method [86] using a specific MAC 252 monoclonal antibody for ABA [87]. Plate contents (Nunc: F96 Maxisorp immuno plate) were read at 405 nm by ELISA reader (Sunrise, Tecan. Männedorf, Switzerland).

4.4. Analysis of ABA Metabolic Genes Expression

4.4.1. RNA Isolation and Real Time PCR (RT-PCR)

Total RNA was isolated from I. walleriana leaves (100 mg), according to the [88]. Total RNA was quantified with a NanoDrop spectrophotometer (NanoPhotometer® N60, IMPLEN, Munich, Germany) and its quality and integrity were estimated by electrophoretic separation on 1.5% agarose gel. To eliminate traces of DNA, RNA was treated with DNase I (Thermo Fisher Scientific, Waltham, MA, USA) at 37 °C for 10 min, according to the manufacturer’s protocol. cDNAs were synthesized in reverse transcription reaction (RT) from 1 µg of total RNA. Reaction mixture for RT in volume of 21 µL, contained 10 µL of total RNA (0.1µg/µL), 25 mM MgCl2, 1 mM dNTP, inhibitor RNA-asa (20 U/µL), random hexamers (50 µM) and 15 U of MultiScribe® transcriptase.

4.4.2. Quantitative Real Time PCR (qRT-PCR)

Abscisic acid biosynthesis (NCED4 and AAO2) and catabolic (ABA8ox3) genes expression were measured by quantitative real time RT-PCR using SYBR green in QuantStudio 3 Real-Time PCR System (Applied Biosystems). Reaction mixture of 10 µL containing 1 μL of RT reaction product, appropriate forward and reverse primers and Maxima SYBR Green/Rox qPCR Master Mix (Thermo Fisher Scientific, Waltham, MA, USA). Thermal cycling conditions for qRT-PCR include: Initial denaturation on 95 °C, then 40 cycles of denaturation (95 °C for 30 s), annealing (60 °C for 30 s) and extension (72 °C for 30 s). Annealing temperature of 60 °C was the same for all used primers. For each sample, qRT-PCR was performed in triplicate. Sequences of appropriate transcripts were obtained from the sequenced leaf transcriptome of I. walleriana (www.genomix4life.com) and identified using Trinotate (combines homology search to known sequence data (BLAST/SwissProt), protein domain identification (HMMER/PFAM), protein signal peptide and transmembrane domain prediction (signalP/tmHMM) and leveraging various annotation databases (eggNOG/GO/Kegg databases). Primer-BLAST (www.ncbi.nlm.nih.gov/tools/primer-blast) was used for primer design while primer properties were checked by NetPrimer software. Primer specificity was confirmed by electrophoretic analysis of RT-PCR products, and melting curve analysis. Gene with constitutive expression—actin (ACT1), was used as an endogenous control. The forward primer 5’-CCGACGTGCCTATCTTCTCC-3´ and reverse primer 5´-CACCTCATCTCCGCCTCATC-3´ were used for NCED4 amplification (GenBank™ Accession No. MW087125); forward primer 5´-GTCTTCGCTCCAACATTCGC-3´ and reverse primer 5´- CCCCAACAGACTGCCTTCAT-3´ were used for AAO2 amplification (GenBank™ Accession No. MW087126) while forward primer 5´-CTACATCAGCCACAGCCTCC-3´ and reverse primer 5´-CTCAGGACACAACTGCCACT-3´ were used for ABA8ox3 amplification (GenBank™ Accession No. MW087127). Amplification of ACT1 (GenBank™ Accession No. MW087128) was carried out with the forward primer 5´-GTGGTGGTGAAGGAGTAGCC -3´ and reverse primer 5´-TTCAGGTGATGGTGTGAGCC-3´. Absolute quantification was done using the standards for NCED4, AAO2, ABA8ox3 and ACT1 genes obtained by GeneJET Gel Extraction Kit (Thermo Fisher Scientific, Waltham, MA, USA ) according the manufacturer’s protocol. Standards were prepared as a serial dilution in a range from 109 to 102.

4.5. Spectrophotometric Analysis of Total Polyphenol Content (Folin–Ciocalteu Test) and Antioxidant Activity in Plants (DPPH Method)

Total polyphenol content was determined using Folin–Ciocalteu test (FC test) based on previously described method [89]. Polyphenols in plant extracts react with Folin–Ciocalteu reagents, forming blue colored complex that can be spectrophotometrically quantified. For this purpose, 200 mg of plant leaves was homogenized in liquid nitrogen with 1 mL of 96% ethanol. Extract was incubated for 60 min at room temperature and then centrifuged at 12,000× g for 15 min. Supernatant was transferred in new Eppendorf tubes. FC reagents solution was prepared by adding distillated water in FC reagents in a volume ration 2:1. Reaction mixture contained 300 µL of FC reagents solution, 1340 µL of deionized H2O and 60 µL of supernatant. The mixture was quick vortexed and left at room temperature for 5 min. Then into mixture was added, 300 µL of 20% Na2CO3 and left at room temperature for 90 min in dark conditions. Absorbance was measured at 765 nm. Gallic acid was used as a standard phenol. The mean of three readings was calculated and the total polyphenol content was expressed as mmol of gallic acid equivalents/g extract.
Antioxidant activity based on the concentration of DPPH radicals in plants was determined in leaf samples of I. walleriana prepared on the same way as for FC test. DPPH radical is a stable radical with maximum absorption at about 520 nm. In reaction with antioxidants stable radical is converted in non-radical form through reduction by hydrogen ion. DPPH reagent solution was prepared with methanol (4.5 mg of DPPH with 45 mL methanol). Absorbance of the prepared DPPH reagent solution should be less than 1.0. In supernatant volume of 100 µL was added 500 µL of methanol and 400 µL of DPPH reagent solution and reaction mixture was incubated at room temperature for 60 min in dark conditions. Degree of reduction of DPPH radicals was estimated through absorbance measurement at 520 nm. The scavenging capacity of the DPPH radical was calculated using the following equation: (%) = [1 − (A1 − A0)] × 100 where A1 is the absorbance of the sample and Ao is the absorbance of the blanc reaction (methanol instead of sample).

4.6. Spectrophotometric Analysis of Proline Content, Photosynthetic Pigments, Malondialdehyde and Hydrogen Peroxide

Quantification of proline, total chlorophyll, carotenoids, as well as MDA and H2O2 content were determined spectrophotometrically according to [27].

4.7. Protein Extraction and Enzyme Assays

Total soluble protein extraction, determination of protein concentration, as well as total POX and CAT activities were done according to [21] while SOD activity was determined as described by [27]. All enzymes activities were expressed as μmol min−1 mg−1 of soluble protein (U mg−1). Separating of SOD and POX isoforms were done by electrophoresis on polyacrylamide gel as described by [21].

4.8. Statistical Analysis

StatGraphics version 4.2 was used for statistical data processing (STSC Inc. Rockville, MD, USA). Statistical differences between treatments were assessed by one-way ANOVA while the mean differences were compared using the Fischer LSD test, with a statistical significance of p ≤ 0.05. Gels were analyzed by ImageJ program package.

5. Conclusions

Drought affects I. walleriana growth and development by modulating various physiological biochemical and molecular responses. Through inhibition of growth parameters, drought induced a decline in plant productivity with obvious morphological changes. Drought increased ABA biosynthesis and ABA content which confer to I. walleriana drought resistance. Drought resistance was also accompanied with increased accumulation of phenolic compounds and carotenoids which in turn increased total antioxidant activity. Activity of antioxidant enzymes SOD, POX and CAT contributed to preventing negative effects of oxidative stress. Considering that I. walleriana often suffer from drought stress when grown in containers, this research may be relevant for overcoming this problem in the future. Furthermore, in the context of climate change, global warming and pronounced drought effects from year to year it is very important to pay attention on finding alternative ways to enhance plant productivity under drought stress.

Author Contributions

Investigation, Formal Analysis, Data Curation, Writing—Original Draft Preparation, M.Đ.; Conceptualization, Supervision, A.S.; Conceptualization, Methodology, Investigation, L.P.; Writing—Review & Editing, M.T.-M.; Formal analysis, Writing—Review & Editing, A.C. and M.V.; Investigation, Methodology, Formal analysis, Writing—Review & Editing, S.M.; All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Ministry of Education, Science and Technological Development of the Republic of Serbia, contract number: 451-03-68/2020-14/200007.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Lisar, S.Y.; Motafakkerazad, R.; Hossain, M.M. Water Stress in Plants: Causes, Effects and Responses. Water Stress 2012, 1. [Google Scholar] [CrossRef] [Green Version]
  2. Mahmood, T.; Khalid, S.; Abdullah, M.; Ahmed, Z.; Shah, M.K.N.; Ghafoor, A.; Du, X. Insights into Drought Stress Signaling in Plants and the Molecular Genetic Basis of Cotton Drought Tolerance. Cells 2020, 9, 105. [Google Scholar] [CrossRef] [Green Version]
  3. Carvalho, M.; Castro, I.; Moutinho-Pereira, J.; Correia, C.; Egea-Cortines, M.; Matos, M.; Lino-Neto, T. Evaluating stress responses in cowpea under drought stress. J. Plant Physiol. 2019, 241, 153001. [Google Scholar] [CrossRef]
  4. Kapoor, D.; Bhardwaj, S.; Landi, M.; Sharma, A.; Ramakrishnan, M.; Sharma, A. The Impact of Drought in Plant Metabolism: How to Exploit Tolerance Mechanisms to Increase Crop Production. Appl. Sci. 2020, 10, 5692. [Google Scholar] [CrossRef]
  5. Sharma, A.; Kumar, V.; Shahzad, B.; Ramakrishnan, M.; Sidhu, G.P.S.; Bali, A.S.; Handa, N.; Kapoor, D.; Yadav, P.; Khanna, K.; et al. Photosynthetic response of plants under different abiotic stresses: A review. J. Plant Growth Regul. 2019, 1–23. [Google Scholar] [CrossRef]
  6. Batra, N.G.; Sharma, V.; Kumari, N. Drought-induced changes in chlorophyll fluorescence, photosynthetic pigments, and thylakoid membrane proteins of Vigna radiata. J. Plant Interact. 2014, 9, 712–721. [Google Scholar] [CrossRef] [Green Version]
  7. Demidchik, V. Mechanisms of oxidative stress in plants: From classical chemistry to cell biology. Environ. Exp. Bot. 2015, 109, 212–228. [Google Scholar] [CrossRef]
  8. Miller, G.A.D.; Suzuki, N.; Ciftci-Yilmaz, S.U.L.T.A.N.; Mittler, R.O.N. Reactive oxygen species homeostasis and signalling during drought and salinity stresses. Plant Cell Environ. 2010, 33, 453–467. [Google Scholar] [CrossRef]
  9. Basu, S.; Ramegowda, V.; Kumar, A.; Pereira, A. Plant adaptation to drought stress. F1000Research 2016, 5. [Google Scholar] [CrossRef]
  10. Laxa, M.; Liebthal, M.; Telman, W.; Chibani, K.; Dietz, K.J. The role of the plant antioxidant system in drought tolerance. Antioxidants 2019, 8, 94. [Google Scholar] [CrossRef] [Green Version]
  11. Fang, Y.; Xiong, L. General mechanisms of drought response and their application in drought resistance improvement in plants. Cell. Mol. Life Sci. 2015, 72, 673–689. [Google Scholar] [CrossRef]
  12. Brodribb, T.J.; McAdam, S.A. Passive origins of stomatal control in vascular plants. Science 2011, 331, 582–585. [Google Scholar] [CrossRef]
  13. Brodribb, T.J.; McAdam, S.A. Evolution of the stomatal regulation of plant water content. Plant Physiol. 2017, 174, 639–649. [Google Scholar] [CrossRef] [Green Version]
  14. Nambara, E.; Marion-Poll, A. Abscisic acid biosynthesis and catabolism. Annu. Rev. Plant Biol. 2005, 56, 165–185. [Google Scholar] [CrossRef] [Green Version]
  15. Seki, M.; Umezawa, T.; Urano, K.; Shinozaki, K. Regulatory metabolic networks in drought stress responses. Curr. Opin Plant. Biol. 2007, 10, 296–302. [Google Scholar] [CrossRef]
  16. Xu, Z.J.; Nakajima, M.; Suzuki, Y.; Yamaguchi, I. Cloning and characterization of the abscisic acid-specific glucosyltransferase gene from adzuki bean seedlings. Plant Physiol. 2002, 129, 1285–1295. [Google Scholar] [CrossRef] [Green Version]
  17. Siegel, R.S.; Xue, S.; Murata, Y.; Yang, Y.; Nishimura, N.; Wang, A.; Schroeder, J.I. Calcium elevation-dependent and attenuated resting calcium-dependent abscisic acid induction of stomatal closure and abscisic acid-induced enhancement of calcium sensitivities of S-type anion and inward-rectifying K+ channels in Arabidopsis guard cells. Plant J. 2009, 59, 207–220. [Google Scholar] [CrossRef] [Green Version]
  18. Levchenko, V.; Konrad, K.R.; Dietrich, P.; Roelfsema, M.R.G.; Hedrich, R. Cytosolic abscisic acid activates guard cell anion channels without preceding Ca2+ signals. Proc. Natl. Acad. Sci. USA 2005, 102, 4203–4208. [Google Scholar] [CrossRef] [Green Version]
  19. Roychoudhury, A.; Paul, S.; Basu, S. Cross-talk between abscisic acid-dependent and abscisic acid-independent pathways during abiotic stress. Plant Cell Rep. 2013, 32, 985–1006. [Google Scholar] [CrossRef]
  20. Agehara, S.; Leskovar, D.I. Characterizing concentration effects of exogenous abscisic acid on gas exchange, water relations, and growth of muskmelon seedlings during water stress and rehydration. J. Am. Soc. Hortic. Sci. 2012, 137, 400–410. [Google Scholar] [CrossRef] [Green Version]
  21. Bhaskara, G.B.; Yang, T.H.; Verslues, P.E. Dynamic proline metabolism: Importance and regulation in water limited environments. Front. Plant Sci. 2015, 6, 484. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Vieira, E.A.; das Graças Silva, M.; Moro, C.F.; Laura, V.A. Physiological and biochemical changes attenuate the effects of drought on the Cerrado species Vatairea macrocarpa (Benth.) Ducke. Plant Physiol. Biochem. 2017, 115, 472–483. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  23. Nakabayashi, R.; Yonekura-Sakakibara, K.; Urano, K.; Suzuki, M.; Yamada, Y.; Nishizawa, T.; Michael, A.J. Enhancement of oxidative and drought tolerance in Arabidopsis by overaccumulation of antioxidant flavonoids. Plant J. 2014, 77, 367–379. [Google Scholar] [CrossRef] [PubMed]
  24. Sharma, A.; Shahzad, B.; Rehman, A.; Bhardwaj, R.; Landi, M.; Zheng, B. Response of phenylpropanoid pathway and the role of polyphenols in plants under abiotic stress. Molecules 2019, 24, 2452. [Google Scholar] [CrossRef] [Green Version]
  25. Xu, L.; Han, L.; Huang, B. Antioxidant enzyme activities and gene expression patterns in leaves of Kentucky bluegrass in response to drought and post-drought recovery. J. Am. Soc. Hortic. Sci. 2011, 136, 247–255. [Google Scholar] [CrossRef] [Green Version]
  26. Milošević, S.; Simonović, A.; Cingel, A.; Jevremović, S.; Todorović, S.; Filipović, B.; Subotić, A. Response of antioxidative enzymes to long-term Tomato spotted wilt virus infection and virus elimination by meristem-tip culture in two Impatiens species. Physiol. Mol. Plant Pathol. 2012, 79, 79–88. [Google Scholar] [CrossRef]
  27. Chyliński, W.K.; Łukaszewska, A.J.; Kutnik, K. Drought response of two bedding plants. Acta Physiol. Plant. 2007, 29, 399. [Google Scholar] [CrossRef]
  28. Blanusa, T.; Vysini, E.; Cameron, R.W. Growth and flowering of Petunia and Impatiens: Effects of competition and reduced water content within a container. HortScience 2009, 44, 1302–1307. [Google Scholar] [CrossRef] [Green Version]
  29. Andersson, N.E. The influence of water stress and air velocity on growth of Impatiens walleriana and Petunia× hybrid. Sci. Hortic. 2011, 128, 146–151. [Google Scholar] [CrossRef]
  30. Cochran, D.R.; Harkess, R.L.; Knight, P.R.; Blythe, E.K.; Tomaso-Peterson, M.; Gilliam, C.H. Antitranspirant effects on water use efficiency in impatiens©. Proc. Int. Plant Propagators Soc. 2012, 1014, 423–428. [Google Scholar] [CrossRef]
  31. Cochran, D.R.; Harkess, R.L.; Knight, P.R.; Tomaso-Peterson, M.; Blythe, E.K.; Gilliam, C.H. Evaluation of a Commercial Extract of Giant Knotweed on Drought Tolerance of Impatiens. HortScience 2014, 49, 1034–1040. [Google Scholar] [CrossRef] [Green Version]
  32. Antonić, D.; Milošević, S.; Cingel, A.; Lojić, M.; Trifunović-Momčilov, M.; Petrić, M.; Simonović, A. Effects of exogenous salicylic acid on Impatiens walleriana L grown in vitro under polyethylene glycol-imposed drought. S. Afr. J. Bot. 2016, 105, 226–233. [Google Scholar] [CrossRef]
  33. Brito, C.; Dinis, L.T.; Moutinho-Pereira, J.; Correia, C.M. Drought stress effects and olive tree acclimation under a changing climate. Plants 2019, 8, 232. [Google Scholar] [CrossRef] [Green Version]
  34. Zhang, F.; Li, F.; Tan, Y. Effects of PEG Imposed Drought Stress on the Seed Germination and Seedling Growth of Impatiens Balsamina. J. South China Normal Univ. (Nat. Sci. Ed.) 2014, 2, 021. [Google Scholar]
  35. Zarghami Moghaddam, M.; Shoor, M.; Ganjeali, A.; Moshtaghi, N.; Tehranifar, A. Effect of salicylic acid on morphological and Ornamental characteristics of Petunia hybrida at drought stress. Ind. J. Fund. Appl. Life Sci. 2014, 4, 523–532. [Google Scholar]
  36. Shi, L.; Wang, Z.; Kim, W.S. Effect of drought stress on shoot growth and physiological response in the cut rose ‘charming black’at different developmental stages. Hortic. Environ. Biotechnol. 2019, 60, 1–8. [Google Scholar] [CrossRef]
  37. Kholova, J.; Hash, C.T.; Kumar, P.L.; Yadav, R.S.; Kočová, M.; Vadez, V. Terminal drought-tolerant pearl millet [Pennisetum glaucum (L. R. Br.] have high leaf ABA and limit transpiration at high vapour pressure deficit. J. Exp. Bot. 2010, 61, 1431–1440. [Google Scholar]
  38. Tombesi, S.; Nardini, A.; Frioni, T.; Soccolini, M.; Zadra, C.; Farinelli, D.; Poni, S.; Palliotti, A. Stomatal closure is induced by hydraulic signals and maintained by ABA in drought-stressed grapevine. Sci. Rep. 2015, 5, 1–12. [Google Scholar] [CrossRef]
  39. Milosavljević, A.; Prokić, L.; Marjanovic, M.; Stikic, R.; Saboljevic, A. The effects of drought on the expression of TAO1, NCED and EIL1 genes and ABA content in tomato wild-type and flacca mutant. Arch. Biol. Sci. 2012, 64, 297–306. [Google Scholar] [CrossRef]
  40. Cai, S.; Jiang, G.; Ye, N.; Chu, Z.; Xu, X.; Zhang, J.; Zhu, G. A key ABA catabolic gene, OsABA8ox3, is involved in drought stress resistance in rice. PLoS ONE 2015, 10, e0116646. [Google Scholar] [CrossRef] [PubMed]
  41. Zdunek-Zastocka, E.; Sobczak, M. Expression of Pisum sativum PsAO3 gene, which encodes an aldehyde oxidase utilizing abscisic aldehyde, is induced under progressively but not rapidly imposed drought stress. Plant Physiol. Biochem. 2013, 71, 57–66. [Google Scholar] [CrossRef] [PubMed]
  42. Pashkovskiy, P.P.; Vankova, R.; Zlobin, I.E.; Dobrev, P.; Ivanov, Y.V.; Kartashov, A.V.; Kuznetsov, V.V. Comparative analysis of abscisic acid levels and expression of abscisic acid-related genes in Scots pine and Norway spruce seedlings under water deficit. Plant Physiol. Biochem. 2019, 140, 105–112. [Google Scholar] [CrossRef]
  43. Dörffling, K.; Tietz, D.; Streich, J.; Ludewig, M. Studies on the role of abscisic acid in stomatal movements. In Plant Growth Substances 1979, Proceedings of the 10th International Conference on Plant Growth Substances, Madison, WI, USA, 22–26 July 1979; Skoog, F., Ed.; Springer: Berlin, Germany, 1979; pp. 274–285. [Google Scholar]
  44. Lovisolo, C.; Perrone, I.; Hartung, W.; Schubert, A. An abscisic acid-related reduced transpiration promotes gradual embolism repair when grapevines are rehydrated after drought. New Phytol. 2008, 180, 642–651. [Google Scholar] [CrossRef]
  45. Mahdieh, M.; Mostajeran, A. Abscisic acid regulates root hydraulic conductance via aquaporin expression modulation in Nicotiana tabacum. J. Plant Physiol. 2009, 166, 1993–2003. [Google Scholar] [CrossRef]
  46. Wei, L.; Wang, L.; Yang, Y.; Wang, P.; Guo, T.; Kang, G. Abscisic acid enhances tolerance of wheat seedlings to drought and regulates transcript levels of genes encoding ascorbate-glutathione biosynthesis. Front. Plant Sci. 2015, 6, 458. [Google Scholar]
  47. González-Villagra, J.; Cohen, J.D.; Reyes-Díaz, M.M. Abscisic acid is involved in phenolic compounds biosynthesis, mainly anthocyanins, in leaves of Aristotelia chilensis plants (Mol.) subjected to drought stress. Physiol. Plantarum. 2019, 165, 855–866. [Google Scholar] [CrossRef]
  48. Luo, H.H.; Zhang, Y.L.; Zhang, W.F. Effects of water stress and rewatering on photosynthesis, root activity, and yield of cotton with drip irrigation under mulch. Photosynthetica 2016, 54, 65–73. [Google Scholar] [CrossRef]
  49. Naidoo, G.; Naidoo, K.K. Drought stress effects on gas exchange and water relations of the invasive weed Chromolaena odorata. Flora 2018, 248, 1–9. [Google Scholar] [CrossRef]
  50. Singh, M.; Kumar, J.; Singh, S.; Singh, V.P.; Prasad, S.M. Roles of osmoprotectants in improving salinity and drought tolerance in plants: A review. Rev. Environ. Sci. Biotechnol. 2015, 14, 407–426. [Google Scholar] [CrossRef]
  51. Zulfiqar, F.; Akram, N.A.; Ashraf, M. Osmoprotection in plants under abiotic stresses: New insights into a classical phenomenon. Planta 2020, 251, 3. [Google Scholar] [CrossRef] [Green Version]
  52. Bandurska, H.; Niedziela, J.; Pietrowska-Borek, M.; Nuc, K.; Chadzinikolau, T.; Radzikowska, D. Regulation of proline biosynthesis and resistance to drought stress in two barley (Hordeum vulgare L.) genotypes of different origin. Plant Physiol. Biochem. 2017, 118, 427–437. [Google Scholar] [CrossRef]
  53. Dash, A. Comparative Study of Relative Water, Chlorophyll and Proline Content in Drought Tolerant and Susceptible Genotypes of Lentil (Lens culinaris Medik.). Res. J. Agric. Sci. 2017, 8, 1081–1086. [Google Scholar]
  54. Ma, D.; Sun, D.; Wang, C.; Li, Y.; Guo, T. Expression of flavonoid biosynthesis genes and accumulation of flavonoid in wheat leaves in response to drought stress. Plant Physiol. Biochem. 2014, 80, 60–66. [Google Scholar] [CrossRef]
  55. Gharibi, S.; Tabatabaei, B.E.S.; Saeidi, G.; Goli, S.A.H. Effect of drought stress on total phenolic, lipid peroxidation, and antioxidant activity of Achillea species. Appl. Biochem. Biotechnol. 2016, 178, 796–809. [Google Scholar] [CrossRef]
  56. Khalil, N.; Fekry, M.; Bishr, M.; El-Zalabani, S.; Salama, O. Foliar spraying of salicylic acid induced accumulation of phenolics, increased radical scavenging activity and modified the composition of the essential oil of water stressed Thymus vulgaris L. Plant Physiol. Biochem. 2018, 123, 65–74. [Google Scholar] [CrossRef]
  57. Gharibi, S.; Tabatabaei, B.E.S.; Saeidi, G.; Talebi, M.; Matkowski, A. The effect of drought stress on polyphenolic compounds and expression of flavonoid biosynthesis related genes in Achillea pachycephala Rech. f. Phytochemistry 2019, 162, 90–98. [Google Scholar] [CrossRef]
  58. Kowalczewski, P.Ł.; Radzikowska, D.; Ivanišová, E.; Szwengiel, A.; Kačániová, M.; Sawinska, Z. Influence of Abiotic Stress Factors on the Antioxidant Properties and Polyphenols Profile Composition of Green Barley (Hordeum vulgare L.). Int. J. Mol. Sci. 2020, 21, 397. [Google Scholar] [CrossRef] [Green Version]
  59. Kedare, S.B.; Singh, R.P. Genesis and development of DPPH method of antioxidant assay. J. Food Sci. Technol. 2011, 48, 412–422. [Google Scholar] [CrossRef] [Green Version]
  60. Štajner, D.; Orlovic, S.; Popovic, B.M.; Kebert, M.; Galic, Z. Screening of drought oxidative stress tolerance in Serbian melliferous plant species. Afr. J. Biotechnol. 2011, 10, 1609–1614. [Google Scholar]
  61. Abbas, S.R.; Ahmad, S.D.; Sabir, S.M.; Shah, A.H. Detection of drought tolerant sugarcane genotypes (Saccharum officinarum) using lipid peroxidation, antioxidant activity, glycine-betaine and proline contents. J. Soil Sci. Plant Nutr. 2014, 14, 233–243. [Google Scholar] [CrossRef] [Green Version]
  62. Estaji, A.; Niknam, F. Foliar salicylic acid spraying effect’on growth, seed oil content, and physiology of drought-stressed Silybum marianum L. plant. Agric. Water Manag. 2020, 234, 106116. [Google Scholar] [CrossRef]
  63. García-Valenzuela, X.; García-Moya, E.; Rascón-Cruz, Q.; Herrera-Estrella, L.; Aguado-Santacruz, G.A. Chlorophyll accumulation is enhanced by osmotic stress in graminaceous chlorophyllic cells. J. Plant Physiol. 2005, 162, 650–661. [Google Scholar] [CrossRef] [PubMed]
  64. Chylinski, K.; Lukaszewska, A. Reaction of bedding ornamentals to drought stress. Ann. Wars. Univ. Life Sci. SGGW. Hortic. Landsc. Archit. 2008, 29, 39–44. [Google Scholar]
  65. Ghobadi, M.; Taherabadi, S.; Ghobadi, M.E.; Mohammadi, G.R.; Jalali-Honarmand, S. Antioxidant capacity, photosynthetic characteristics and water relations of sunflower (Helianthus annuus L.) cultivars in response to drought stress. Ind. Crops Prod. 2013, 50, 29–38. [Google Scholar] [CrossRef]
  66. Sarker, U.; Oba, S. Drought Stress Effects on Growth, ROS Markers, Compatible Solutes, Phenolics, Flavonoids, and Antioxidant Activity in Amaranthus tricolor. Appl. Biochem. Biotechnol. 2008, 186, 999–1016. [Google Scholar] [CrossRef]
  67. Hossain, M.A.; Bhattacharjee, S.; Armin, S.M.; Qian, P.; Xin, W.; Li, H.Y.; Burritt, D.J.; Fujita, M.; Tran, L.S.P. Hydrogen peroxide priming modulates abiotic oxidative stress tolerance: Insights from ROS detoxification and scavenging. Front. Plant Sci. 2015, 6, 420. [Google Scholar] [CrossRef] [Green Version]
  68. Farooq, M.; Nawaz, A.; Chaudhary, M.A.M.; Rehman, A. Foliage-applied sodium nitroprusside and hydrogen peroxide improves resistance against terminal drought in bread wheat. J. Agron. Crop Sci. 2017, 203, 473–482. [Google Scholar] [CrossRef]
  69. Carvalho, V.; Abreu, M.E.; Mercier, H.; Nievola, C.C. Adjustments in CAM and enzymatic scavenging of H2O2 in juvenile plants of the epiphytic bromeliad Guzmania monostachia as affected by drought and rewatering. Plant Physiol. Biochem. 2017, 113, 32–39. [Google Scholar] [CrossRef]
  70. Mafakheri, K.; Bihamta, M.R.; Abbasi, A.R. Assessment of antioxidant enzymes activity and peroxidation of membrane lipid in cowpea (Vigna unguiculata L.) genotypes under normal and drought stress condition. Iran. J. Field Crop Sci. 2016, 47, 217–232. [Google Scholar]
  71. Correia, B.; Hancock, R.D.; Amaral, J.; Gomez-Cadenas, A.; Valledor, L.; Pinto, G.C. Combined drought and heat activates protective responses in Eucalyptus globulus that are not activated when subjected to drought or heat stress alone. Front. Plant Sci. 2018, 9, 819. [Google Scholar] [CrossRef] [Green Version]
  72. Fu, J.; Huang, B. Involvement of antioxidants and lipid peroxidation in the adaptation of two cool-season grasses to localized drought stress. Environ. Exp. Bot. 2011, 45, 105–114. [Google Scholar] [CrossRef]
  73. Khaleghi, A.; Naderi, R.; Brunetti, C.; Maserti, B.E.; Salami, S.A.; Babalar, M. Morphological, physiochemical and antioxidant responses of Maclura pomifera to drought stress. Sci. Rep. 2019, 9, 1–12. [Google Scholar] [CrossRef] [PubMed]
  74. Hussain, H.A.; Men, S.; Hussain, S.; Zhang, Q.; Ashraf, U.; Anjum, S.A.; Wang, L. Maize Tolerance against Drought and Chilling Stresses Varied with Root Morphology and Antioxidative Defense System. Plants 2020, 9, 720. [Google Scholar] [CrossRef] [PubMed]
  75. Hasanuzzaman, M.; Hossain, M.A.; da Silva, J.A.T.; Fujita, M. Plant response and tolerance to abiotic oxidative stress: Antioxidant defense is a key factor. In Crop Stress and Its Management: Perspectives and Strategies; Springer: Dordrecht, The Netherlands, 2012; pp. 261–315. [Google Scholar]
  76. Hosseini, M.S.; Samsampour, D.; Ebrahimi, M.; Abadía, J.; Khanahmadi, M. Effect of drought stress on growth parameters, osmolyte contents, antioxidant enzymes and glycyrrhizin synthesis in licorice (Glycyrrhiza glabra L.) grown in the field. Phytochemistry 2018, 156, 124–134. [Google Scholar] [CrossRef] [PubMed]
  77. Ren, J.; Sun, L.N.; Zhang, Q.Y.; Song, X.S. Drought tolerance is correlated with the activity of antioxidant enzymes in Cerasus humilis seedlings. BioMed Res. Int. 2016, 9. [Google Scholar] [CrossRef] [Green Version]
  78. Lum, M.S.; Hanafi, M.M.; Rafii, Y.M.; Akmar, A.S.N. Effect of drought stress on growth, proline and antioxidant enzyme activities of upland rice. J. Anim. Plant. Sci. 2014, 24, 1487–1493. [Google Scholar]
  79. Sheoran, S.; Thakur, V.; Narwal, S.; Turan, R.; Mamrutha, H.M.; Singh, V.; Tiwari, V.; Sharma, I. Differential activity and expression profile of antioxidant enzymes and physiological changes in wheat (Triticum aestivum L.) under drought. Appl. Biochem. Biotechnol. 2015, 177, 1282–1298. [Google Scholar] [CrossRef]
  80. Guo, Y.Y.; Tian, S.S.; Liu, S.S.; Wang, W.Q.; Sui, N. Energy dissipation and antioxidant enzyme system protect photosystem II of sweet sorghum under drought stress. Photosynthetica 2018, 56, 861–872. [Google Scholar] [CrossRef]
  81. Huseynova, I.M.; Aliyeva, D.R.; Aliyev, J.A. Subcellular localization and responses of superoxide dismutase isoforms in local wheat varieties subjected to continuous soil drought. Plant Physiol. Biochem. 2014, 81, 54–60. [Google Scholar] [CrossRef]
  82. Sales, C.R.; Marchiori, P.E.R.; Machado, R.S.; Fontenele, A.V.; Machado, E.C.; Silveira, J.A.G.; Ribeiro, R.V. Photosynthetic and antioxidant responses to drought during sugarcane ripening. Photosynthetica 2015, 53, 547–554. [Google Scholar] [CrossRef]
  83. Mhamdi, A.; Queval, G.; Chaouch, S.; Vanderauwera, S.; Van Breusegem, F.; Noctor, G. Catalase function in plants: A focus on Arabidopsis mutants as stress-mimic models. J. Exp. Bot. 2010, 61, 4197–4220. [Google Scholar] [CrossRef] [Green Version]
  84. Vaseva, I.; Akiscan, Y.; Simova-Stoilova, L.; Kostadinova, A.; Nenkova, R.; Anders, I.; Demirevska, K. Antioxidant response to drought in red and white clover. Acta Physiol. Plant. 2012, 34, 1689–1699. [Google Scholar] [CrossRef]
  85. Ozyigit, I.I.; Filiz, E.; Vatansever, R.; Kurtoglu, K.Y.; Koc, I.; Öztürk, M.X.; Anjum, N.A. Identification and comparative analysis of H2O2-scavenging enzymes (ascorbate peroxidase and glutathione peroxidase) in selected plants employing bioinformatics approaches. Front. Plant Sci. 2016, 7, 301. [Google Scholar] [CrossRef] [Green Version]
  86. Asch, F. Determination of Abscisic Acid by Indirect Enzyme-Linked Immunosorbent Assay (ELISA); Technical Report; Laboratory for Agrohydrology and Bioclimatology, Department of Agricultural Sciences, The Royal Veterinary and Agricultural University: Tastrup, Denmark, 2000. [Google Scholar]
  87. Quarrie, S.A.; Whitford, P.N.; Appleford, N.E.J.; Wang, T.L.; Cook, S.K.; Henson, I.E.; Loveys, B.R. A monoclonal antibody to (S)-abscisic acid: Its characterisation and use in a radioimmunoassay for measuring abscisic acid in crude extracts of cereal and lupin leaves. Planta 1988, 173, 330–339. [Google Scholar] [CrossRef] [PubMed]
  88. Gasic, K.; Hernandez, A.; Korban, S.S. RNA extraction from different apple tissues rich in polyphenols and polysaccharides for cDNA library construction. Plant Mol. Biol. Rep. 2004, 22, 437–438. [Google Scholar] [CrossRef]
  89. Singleton, V.L.; Orthofer, R.; Lamuela-Raventós, R.M. Analysis of total phenols and other oxidation substrates and antioxidants by means of folin-ciocalteu reagent. Methods Enzymol. 1999, 299, 152–178. [Google Scholar]
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Figure 1. Changes in soil moisture content after imposition of drought stress for control, drought-stressed and recovery group of I. walleriana.
Figure 1. Changes in soil moisture content after imposition of drought stress for control, drought-stressed and recovery group of I. walleriana.
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Figure 2. Growth parameters in drought-stressed I. walleriana grown ex vitro: Changes in shoots fresh weight (FW) (a), total leaf area (b) and shoots dry weight (DW) (c) were examined at the “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
Figure 2. Growth parameters in drought-stressed I. walleriana grown ex vitro: Changes in shoots fresh weight (FW) (a), total leaf area (b) and shoots dry weight (DW) (c) were examined at the “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
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Figure 3. Morphological differences between I. walleriana at “start point“ of drought stress imposition (a); 15% of soil moisture content—control (b), drought-stressed (c) and recovered plants (d), and at 5% of soil moisture content—control (e), drought-stressed (f) and recovered plants (g).
Figure 3. Morphological differences between I. walleriana at “start point“ of drought stress imposition (a); 15% of soil moisture content—control (b), drought-stressed (c) and recovered plants (d), and at 5% of soil moisture content—control (e), drought-stressed (f) and recovered plants (g).
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Figure 4. Effect of drought on abscisic acid (ABA) content in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
Figure 4. Effect of drought on abscisic acid (ABA) content in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
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Figure 5. The effect of drought on 9-cis-epoxycarotenoid dioxygenase 4 (NCED4), abscisic aldehyde oxidase 2 (AAO2) and ABA 8′-hydroxylase 3 (ABA8ox3) gene expression in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8).
Figure 5. The effect of drought on 9-cis-epoxycarotenoid dioxygenase 4 (NCED4), abscisic aldehyde oxidase 2 (AAO2) and ABA 8′-hydroxylase 3 (ABA8ox3) gene expression in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8).
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Figure 6. The effect of drought on shoot water potential (a) and proline content (b) in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
Figure 6. The effect of drought on shoot water potential (a) and proline content (b) in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
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Figure 7. The effect of drought on total polyphenols (a) and flavonols (b) content, and 1,1′-diphenyl-2-picrylhydrazyl (DPPH) activity (c) in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
Figure 7. The effect of drought on total polyphenols (a) and flavonols (b) content, and 1,1′-diphenyl-2-picrylhydrazyl (DPPH) activity (c) in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
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Figure 8. The effect of drought on total chlorophyll (a), total carotenoid (b), H2O2 (c) and malondialdehyde (MDA) (d) content in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
Figure 8. The effect of drought on total chlorophyll (a), total carotenoid (b), H2O2 (c) and malondialdehyde (MDA) (d) content in I. walleriana grown ex vitro. The “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
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Figure 9. (a) superoxide dismutase (SOD) activity; (b) SOD isoforms and their relative expression (%); (c) peroxidase (POX) activity; and (d) POX isoforms and their relative expression (%) and catalase (CAT) activity (e) in drought-stressed I. walleriana grown ex vitro. (a,c,e)—the “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; (d,e)—the “start point” (1), 15% of soil moisture content—control (2), drought (3), recovery (4) and 5% of soil moisture content—control (5), drought (6) and recovery (7). Results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
Figure 9. (a) superoxide dismutase (SOD) activity; (b) SOD isoforms and their relative expression (%); (c) peroxidase (POX) activity; and (d) POX isoforms and their relative expression (%) and catalase (CAT) activity (e) in drought-stressed I. walleriana grown ex vitro. (a,c,e)—the “start point”, 15% and 5% of soil moisture content—0, 1 and 2, respectively; (d,e)—the “start point” (1), 15% of soil moisture content—control (2), drought (3), recovery (4) and 5% of soil moisture content—control (5), drought (6) and recovery (7). Results represent mean ± SE (n = 8). The letters indicate statistically significant differences based on the Fischer LSD test (p ≤ 0.05).
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Đurić, M.; Subotić, A.; Prokić, L.; Trifunović-Momčilov, M.; Cingel, A.; Vujičić, M.; Milošević, S. Morpho-Physiological and Molecular Evaluation of Drought and Recovery in Impatiens walleriana Grown Ex Vitro. Plants 2020, 9, 1559. https://doi.org/10.3390/plants9111559

AMA Style

Đurić M, Subotić A, Prokić L, Trifunović-Momčilov M, Cingel A, Vujičić M, Milošević S. Morpho-Physiological and Molecular Evaluation of Drought and Recovery in Impatiens walleriana Grown Ex Vitro. Plants. 2020; 9(11):1559. https://doi.org/10.3390/plants9111559

Chicago/Turabian Style

Đurić, Marija, Angelina Subotić, Ljiljana Prokić, Milana Trifunović-Momčilov, Aleksandar Cingel, Milorad Vujičić, and Snežana Milošević. 2020. "Morpho-Physiological and Molecular Evaluation of Drought and Recovery in Impatiens walleriana Grown Ex Vitro" Plants 9, no. 11: 1559. https://doi.org/10.3390/plants9111559

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