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Review

The Impact of Salinity on Crop Yields and the Confrontational Behavior of Transcriptional Regulators, Nanoparticles, and Antioxidant Defensive Mechanisms under Stressful Conditions: A Review

by
Mostafa Ahmed
1,2,*,
Zoltán Tóth
3 and
Kincső Decsi
3
1
Festetics Doctoral School, Institute of Agronomy, Georgikon Campus, Hungarian University of Agriculture and Life Sciences, 8360 Keszthely, Hungary
2
Department of Agricultural Biochemistry, Faculty of Agriculture, Cairo University, Giza 12613, Egypt
3
Institute of Agronomy, Georgikon Campus, Hungarian University of Agriculture and Life Sciences, 8360 Keszthely, Hungary
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2024, 25(5), 2654; https://doi.org/10.3390/ijms25052654
Submission received: 5 February 2024 / Revised: 20 February 2024 / Accepted: 22 February 2024 / Published: 24 February 2024
(This article belongs to the Special Issue Molecular Regulatory Mechanisms of Salinity Tolerance in Plants 2.0)
Browse Figures
Review Reports Versions Notes

Abstract

:
One of the most significant environmental challenges to crop growth and yield worldwide is soil salinization. Salinity lowers soil solution water potential, causes ionic disequilibrium and specific ion effects, and increases reactive oxygen species (ROS) buildup, causing several physiological and biochemical issues in plants. Plants have developed biological and molecular methods to combat salt stress. Salt-signaling mechanisms regulated by phytohormones may provide additional defense in salty conditions. That discovery helped identify the molecular pathways that underlie zinc-oxide nanoparticle (ZnO-NP)-based salt tolerance in certain plants. It emphasized the need to study processes like transcriptional regulation that govern plants’ many physiological responses to such harsh conditions. ZnO-NPs have shown the capability to reduce salinity stress by working with transcription factors (TFs) like AP2/EREBP, WRKYs, NACs, and bZIPs that are released or triggered to stimulate plant cell osmotic pressure-regulating hormones and chemicals. In addition, ZnO-NPs have been shown to reduce the expression of stress markers such as malondialdehyde (MDA) and hydrogen peroxide (H2O2) while also affecting transcriptional factors. Those systems helped maintain protein integrity, selective permeability, photosynthesis, and other physiological processes in salt-stressed plants. This review examined how salt stress affects crop yield and suggested that ZnO-NPs could reduce plant salinity stress instead of osmolytes and plant hormones.

1. Introduction

A global scarcity of water resources, pollution, and an increase in soil and water salinization mark the beginning of the twenty-first century. A rise in human population and a decline in the land available for cultivation threaten agricultural sustainability [1]. High winds, harsh temperatures, soil salinity, drought, and flooding are only some of the environmental challenges affecting agricultural crop productivity and cultivation [2]. Regarding the quality and quantity of crops produced, soil salinity is among the worst ecological pressures [1]. A saline soil is defined as having an electrical conductivity (EC) of the saturation extract (ECe) at the root zone of more than 4 dS m−1 (about 40 mM NaCl) at 25 °C and an exchangeable salt content of 15% [3]. Most crop plants have a decreased yield at this ECe, even though many crops exhibit yield losses at lower ECes [2]. Based on estimations, high salinity has impacted around 33% of irrigated agricultural fields and 20% of the total farmed land globally [4]. Furthermore, the expansion of salinized lands at a rate of 10% per year [5] can be attributed to various factors, including insufficient precipitation, excessive surface evaporation, irrigation with salinized water, and suboptimal cultural practices. According to projections, the global proportion of arable land affected by salinization is anticipated to surpass 50% by 2050 [6].
Crop plants’ physiological and biochemical pathways are adversely affected by soil salinity through a complex mechanism [7]. When there is too much Na+ in the cell, cytosolic K+ and Ca2+ leave the cell. This upsets the balance of their homeostasis, which leads to nutritional deficiencies, oxidative stress, slowed growth, and cell death [8]. Several stomatal restrictions, such as stomatal closure [9], and non-stomatal limitations like chlorophyll dysfunction [10], the deprivation of enzymatic proteins and membranes of the photosynthetic apparatus [11], and chloroplast ultrastructure destruction [12], have been reported to have a significant negative impact on plant photosynthesis at high salinization levels; salt-affected soils demonstrate higher Na+/K+ and Na+/Ca2+ ratios due to the increased presence of Na+ in the soil solution. Consequently, a reduction in the uptake of potassium ions (K+) and calcium ions (Ca2+) might hinder cellular functioning, resulting in the destabilization of cell membranes and the impairment of enzymatic activity, which is facilitated by the enzymes [13]. The production of too many reactive oxygen substances/species (ROS) in the cytosol, chloroplast, and mitochondria is influenced by osmotic pressure and ionic toxicity, leading to oxidative damage [9,14]. These reactive oxygen species can damage plant tissues, alter the double-helical DNA, disrupt the phospholipid bilayer [15], degrade the active biomolecules like lipids and proteins, and destroy photoreceptors like phytochromes A and B [16] (Figure 1). The crops commonly employed for human and animal sustenance, including cereals such as rice and maize, forages like clover, and horticultural crops such as potatoes and tomatoes, are frequently cultivated using irrigation techniques. However, these crops are susceptible to the detrimental effects of elevated salt concentrations in irrigation water or the soil’s rhizosphere solution. In a significant proportion of farmed plant species, the productivity starts to decline even when exposed to relatively moderate levels of salinity in irrigation water (electrical conductivity of water, ECw > 0.8 dS/m) or soil (electrical conductivity of saturated soil extracts, ECse > 1 dS/m) [3]. The impact of soil salinity on the productivity of several vital crops, including Zea mays, Solanum tuberosum L., Lycopersicon esculentum Mill., and Oryza sativa L., has been shown to result in significant reductions in yield. These reductions have been reported as 19.0% for Zea mays, 12.0% for Solanum tuberosum L., 9.9% for Lycopersicon esculentum Mill., and 12% for Oryza sativa L. [17].
The upregulation of genes involved in various stress responses, including salt stress, can be controlled by transcription factors (TFs), the terminal transducers in a signaling cascade. TFs accomplish this by locating and attaching themselves to conserved cis-acting areas in the promoter of downstream genes [18,19]. Extensive research over the past few decades has led to the identification and characterization of multiple kinds of TFs. As a result, numerous experiments have been conducted to boost stress tolerance by genetically modifying these TFs. bZIP, AP2/EREBP, MYB, WRKY, NAC (NAM, ATAF, and CUC), and WRKY are among the essential TF families involved in abiotic stress tolerance [20].
Nanotechnology, a new industrial revolution, is an emerging technology undergoing rapid development [21]. Over the past decade, nanotechnology has emerged as a crucial instrument for increasing agricultural productivity. Nanotechnology has the potential to completely transform the agricultural industry in several areas, including soil management, water supply for agriculture, and the detection and treatment of plant diseases [22]. The farm industry is one of developed countries’ most important economic foundations. With an increasing global population comes a growing demand for food and agricultural products. Several factors, including plant diseases, increased environmental pollution, diminishing soil and water supplies, and climate change, make agriculture and producing enough nutrient-dense food difficult [23,24,25,26].
Generally, nanotechnology has the potential to significantly contribute to the industry’s rising prosperity by maximizing the use of agricultural inputs, including water, fertilizer, and pesticides, while lowering effluents and pollution [27]. The total effectiveness of using agricultural inputs, including water, light, and chemicals, can be improved using nanotechnology. By enhancing the microbiome, improving agricultural disease management, and reducing losses, soil and plant health and function improve, causing less environmental collateral damage. As a result, nanotechnology offers hope for the development of sustainable agriculture [28]. Abiotic stressors are environmental conditions that limit a plant’s ability to grow, thrive, and reproduce. Abiotic stressors that naturally affect plants include many types, such as heat, cold, salinity, drought, and heavy metals [29]. Since plants are sessile organisms, they have various coping mechanisms that allow them to adapt to changes in their growing settings and display essential flexibility in responding to environmental challenges without impairing cellular, physiological, or developmental processes [30].
Growing more resilient crops to abiotic stressors is one of sustainable agriculture’s main challenges. ROS accumulate in plant cells to dangerous levels in reaction to abiotic stresses. Excess ROS leads to cellular toxicity, membrane proteins and lipids disintegrating, and a reduction in plant growth. The antioxidant defense system scavenges ROS to lower oxidative stress [31]. Nanoparticles have garnered attention in technological applications due to their distinct properties, such as their diminutive size, expansive surface area, enhanced solubility, and heightened reactivity compared to bulk materials [31]. Metallic nanoparticles (MNPs), including Zn, Fe, Ti, Ag, and Cu-NPs, have garnered significant attention due to their potential application in agriculture without causing adverse environmental effects [32]. They have lately been used to test a variety of plants for stress tolerance, plant development, and germinating seeds [33,34].
This review article aimed to investigate the various adverse effects of salt stress on crop yield, and to gain a deeper understanding of the regulatory and mitigating mechanisms of salt stress in the case of the use of metal oxide nanoparticles—especially zinc oxide nanoparticles—during a stressed state, and to understand the relationship between these artificially produced zinc oxide nanoparticles and transcriptional regulators.

2. The Presence of High Salinity Levels Has Been Observed to Result in a Decrease in Biomass Production and Subsequent Yield Losses

When the growth requirements of crop plants are appropriately met, including with effective management practices throughout the growing season, as well as the proper management of nutrients, water, light, and temperature to align with their optimal growth conditions, these plants are capable of yielding high quantities of high-quality grain, fiber, and substances with high sugar, oil, or protein contents. In the context of plant development, it has been observed that abiotic stressors such as salt or drought have an inverse correlation with yield-related characteristics [35]. If salt stress inhibits the growth of plants during the early stages of development, it can significantly reduce the yield and negatively impact the quality and quantity of plant products [36]. While the visible effects of salt may not always be immediately evident, it is crucial to remember that salinity can lead to reductions in agricultural production. A specific crop’s salt tolerance and sensitivity are determined by its ability to extract water and nutrients from saline soils and its capacity to prevent the accumulation of salt ions in its tissues [37,38].
Elevated levels of sodium ions (Na+) and chloride ions (Cl) can have detrimental effects on plants, especially when they accumulate within the cytoplasm [39]. Despite the significance of the topic, there remains a limited understanding regarding the specific cytosolic processes that are negatively affected by elevated levels of salt ions, and the potentially harmful effects of chloride in the cytosol remain uncertain [40]. Additionally, the accumulation of deleterious ions in photosynthetically active tissues can accelerate the aging process of transpiring leaves while reducing the availability of essential nutrients required for optimal health [41]. The plant’s capacity to acquire nutrients and energy through photosynthesis or to metabolically utilize them can be limited at any moment [42]. Plants allocate a significant portion of their power to essential processes such as maintenance, vegetative development, and generative growth in the absence of stressors. Nevertheless, with an increasing focus on mitigating stress, resources are reallocated in response to escalating salinity levels.
The energy expenditure is necessary for stress mitigation, growth, and maintenance [43]. The relative proportions of plant constituents vary based on the plant’s developmental stage and susceptibility to salt stress. Plants that are allowed to attain more significant sizes will want increased levels of care and attention. An increase in salinity levels can lead to a decrease in the rate of photosynthesis due to induced stomatal closure, a reduction in gas exchange (CO2 input decreased), a reduction in the size and frequency of stomata (after prolonged exposure), the degradation of the chlorophylls, damaging the chloroplast ultrastructure, and the inhibition of photophosphorylation and carbon reactions (enzyme reactions). As a consequence, there will be a reduction in the total energy acquired. To effectively cope with the elevated salt content in the soil, the plant must allocate additional resources toward various processes [2]. These include incurring higher energy investment for ion exclusion or compartmentalization, maintaining ion homeostasis, and detoxifying ROS. These examples are limited in number. Mechanisms related to stress tolerance exemplify this category. Plant growth is impeded by high salinity due to the equilibrium between the losses incurred by the plant and the energy acquired by the plant [44]. The occurrence of tissue senescence is attributed to an imbalance between plant composition and demolishing processes, whereby the latter surpasses the former [45]; this is the reaction of a crop that exhibits both sensitivity and tolerance to elevated soil salt levels [46]. Each type of crop has a different response to saltiness, which can be broken down into three stages [47]: homeostasis, which keeps the rate of growth healthy; eustress, which turns on defense genes; and distress, which slows down metabolism and eventually leads to death. Plant species that exhibit both sensitivity and intolerance may possess the ability to flourish within a limited range of salinity tolerance [48]. In the context of safeguarding vulnerable crops, defensive mechanisms are thought to be triggered at an earlier stage and with a reduced intensity [49], but what occurs is that the defensive ability of tolerant/resistant plant species is more precise because they react faster. They start producing protective compounds more quickly and keep the number of compounds higher. Susceptible plants respond later and produce protective compounds more slowly and for a shorter period of time [50].

3. The Negative Effects of Soil Salinity on Crops

Compared to other abiotic stresses that reduce the productivity of agricultural output in dry and semi-arid regions, salinity stress stands out as a challenging obstacle to overcome. This is mainly attributable to the natural conditions in these regions, which promote salinization due to insufficient precipitation to enable the leaching of salts. In other words, these factors cause salinization to occur [26]. In the biphasic model of growth reduction caused by salinization, the bad effects of salt-affected soils are shown by a drop in osmosis and ion cytotoxicity in the first phase. This is followed by the production of ROS and programmed cell death (PCD) in the second phase [51]. These effects are further compounded by the generation of reactive oxygen species (ROS) and disturbances in nutrient equilibrium. This aligns with the theoretical proposition that salt induces a decrease in osmosis during the initial stage and an increase in ion cytotoxicity during the subsequent stage [52].

3.1. The Effects of Salinity on the Agricultural Value Measuring Properties of Plant Species

Several elements, including the amount of salt present, the amount of time that has passed, the plant species and variation, the photochemical quenching capability, the plant growth stage, the type of stress, the gas exchange characteristics, and the photosynthetic pigments, all contribute to the retardation of plant development that occurs under salt stress [53]. In several studies on corn (Zea mays L.) [54], rice (Oryza sativa L.) seedlings [55], Vigna unguiculata L. [56], and rapeseed (Brassica campestris L.) [57], it was discovered that increasing plant height with even a slight quantity of salinization was beneficial.
The observed increase in plant height can be attributed to fewer soluble salts in the growth control medium; in the beginning, the nutrient salts added to the medium act as eustress on the plant, with a stimulating effect. Conversely, the decrease in plant height can be attributed to the adverse effects of excessive salts on various physiological processes. These effects include a reduction in photosynthetic rate and decreased levels of carbohydrates and growth hormones, which inhibit growth, and decreased protein synthesis due to alterations in antioxidant enzyme activities [58].
Salinity levels of up to 8 dS/m substantially influenced various plant parameters, including fresh and dry weight, leaf area, and leaf count [59,60,61]. Numerous researchers have observed that the reduction in dry matter production and deceleration of plant growth in soils influenced by salinity can be attributed to the hindrance of cell elongation [53] through the direct suppression of the activities of transport proteins like proton (H+)-ATPase [62]. Salt stress has been found to have detrimental effects on photosynthesis, leading to constraints in both plant and leaf growth and reductions in chlorophyll levels, as the central core of chlorophyll contains magnesium [63]. The absorption or uptake of magnesium is inhibited by acidic pH. [64]. Furthermore, when subjected to salinity stress, the fresh and dry biomass of Brassica napus L. cv. exhibited a significant reduction, with shoot growth being more severely damaged compared to root growth [59]. Based on a conceptual framework, it is hypothesized that salinization causes a reduction in the rate of root growth as well as a restriction in the amount of leaf area expansion that can occur as a result of decreased water uptake efficiency. This process helps maintain an appropriate soil moisture level and prevents an excessive buildup of soluble salts within the soil [59].
The phenomenon of stomatal closure in plants, leading to a decrease in photosynthetic activity and a subsequent reduction in carbon assimilation, could potentially be an additional determinant of the reduced growth rate observed in saline conditions. Based on the results of several investigations, it has been observed that a significant presence of sodium (Na+) and chloride (Cl) ions within the cell sap creates a subtle osmotic gradient within the nutrient-rich environment. Consequently, this phenomenon reduces the plant’s water absorption capacity, altering its morphological traits [65]. Previous studies have shown evidence that an increased concentration of salt negatively affects nitrogen accumulation in plants due to the interplay between chloride ions (Cl) and nitrate ions (NO3), as well as sodium ions (Na+) and ammonium ions (NH4+). Consequently, this phenomenon results in a decrease in the quantity of plant growth and agricultural productivity [66]. Research has shown evidence that salinity stress has a secondary impact on plant feeding, leading to a notable decline in nutrient absorption due to a fall in osmotic pressure [67].

3.2. Physiological Processes Whose Characteristics Are Influenced by Salinity Stress

Recent research indicates that the physiological characteristics of cereal crops, including wheat (Triticum aestivum L.) and mung bean (Vigna radiata L.), are negatively impacted by soil salinity stress [8,68,69]. Decreasing leaf photosynthetic capacity and concentration of carotenoids and other photosynthetically active pigments, as well as altered energy in the mechanisms of ion exclusion, osmotic adjustment, and nutritional imbalance, may all be contributing factors to the loss in plant growth and output caused by soil salinity [70]. Crops are often impacted by salt-affected soils in one of three ways: oxidative damage, ion imbalance, or osmotic stress [71]. The harmful effects of sodium (Na+) and chloride (Cl) ion buildup in plant tissues are the predominant reaction of salt-affected soils [71,72]. It has been demonstrated that plants under salinity stress collect more Na+ ions, disturb the ionic balance, modify plant metabolism, and increase oxidative damage. In contrast, the K+ ion status in plant tissues aids in the development of soil salt tolerance in plants [73].
When rice (Oryza sativa L.) was cultivated in salt-affected soil, the K+ ion concentration was only marginally changed; however, the Na+ content in the leaves was dramatically increased, and the K+/Na+ ratio was significantly decreased [71,72]. A notable decline in strawberry plant growth was noted [74]. These growth delays may partly be explained by decreased photosynthetic activity brought on by lower levels of Chl a and Chl b under varying salinity conditions [75]. Ion imbalance in plants and soil is brought on by the entry of Na+ and Cl ions, and this imbalance in the plant’s ions may lead to severe physiological issues [76]. The high salt content in the soil profile may result in physiological dryness as a result of decreased water uptake, salt accumulation in the root zone of the plant, a reduction in plant osmotic potential, and the subsequent disruption of cell metabolic processes as a result of ion toxicity [76,77]. Excessive Na+ in plants damages the cell membrane and organelles and impairs physiological processes that result in the death of plant cells [72,78,79]. These physiological processes include the net photosynthetic rate (Pn), stomatal conductance (Gs), transpiration rate (Tr), intracellular carbon dioxide (Ci) concentration, and soil plant analysis development (SPAD) chlorophyll value.
The disturbance of the selective permeability of the cell membrane, which makes it difficult for the plant to detoxify the ROS in the cytoplasm, a decrease in the rate of photosynthetic activity, and alterations in the antioxidant enzymes, may also occur as a result of these physiological changes [78]. These oxidative systems can interfere with dynamic cellular operations in plants under abiotic stress—particularly soil salinity—by disrupting the normal functions of numerous plant cellular components such as proteins, DNA, and lipids [80]. Additionally, plants raised in salty environments may impede chlorophyll production and cause considerable changes to the activities and structure of the pigment–protein complex [81]. The decreased activity of several enzymes, including porphyrinogen IX oxidase, porphobilinogen deaminase, coproporphyrinogen III oxidase, 5-aminolevulinic acid dehydratase, protochlorophyllide oxidoreductase, and Mg-chelatase, may be the cause of the inhibition of chlorophyll pigment synthesis under salt stress [82]. These enzymes, in turn, are in charge of either an increase in chlorophyllase activity [83] or a decrease in leaf water potential, N absorption, and, consequently, the reduced ability of plants to synthesize oxygen [69]. Salinity-induced superoxide radicals and hydrogen peroxide (H2O2), which deteriorate the membranes of thylakoids and chloroplasts, may also be responsible for chlorophyll degradation [84].

3.3. The Variant Effects of Salinity on Enzymatic and Non-Enzymatic Antioxidants in Plants

The effects of soil salinity stress, which inhibits plant growth and development, are accompanied by a significant accumulation of ROS. ROS (O2, O2, H2O2, and OH) production under stressful conditions (biotic and abiotic) is a stress indicator at the cellular level and is referred to as a secondary messenger. ROS play their role in the biological activities of plants, ranging from gene expression and translocation to enzymatic chemistry [85,86]. ROS may eventually disrupt the average plant metabolism because of lipids, proteins, and nucleic-acid structure changes [87]. According to some reports, soil salinity-stimulated oxidative stress brought on by the accumulation of increased levels of H2O2 may cause DNA breakage, chromatin condensation, apoptosis, and cell shrinkage [88]. Higher levels of ROS production during salinity stress may cause the thylakoid membranes to produce more malondialdehyde (MDA). Calculating the lipid peroxidation of plant cells involves using MDA concentration, which is recognized to be a reliable indication of lipid peroxidation [89]. The degree of collateral damage to these molecules involved in plant metabolism is determined by the balance between ROS generation and their removal by the antioxidative defense mechanism [90].
Additionally, soil salinization results in acute oxidative damage to plant tissues. As a result, plants create their own sophisticated natural antioxidant defense mechanism to counteract the oxidative stress caused by salinity. The cell-structural harm brought on by salinity-induced ROS is prevented by antioxidant enzymes [91]; these crop plants that have increasing tolerance to osmotic stress and efficient Na+ and Cl exclusion are thought to be better at withstanding salt than other plant kinds because they have an effective antioxidant system. The varied effects of salinity stress on antioxidative enzymatic and non-enzymatic activities in Tanacetum parthenium L. [61], Brassica napus L. [59], Oryza sativa L. [92], and Glycine max L. [93] have previously been documented by many studies. Carotenoids, ascorbic acid (vitamin C), α-tocopherol (vitamin E), flavonoids, and phenolics comprise most of the non-enzymatic antioxidant system. In contrast, peroxidase (POD), superoxide dismutase (SOD), ascorbate peroxidase (APX), glutathione reductase (GR), polyphenol oxidase (PPO), and other enzymes make up the enzymatic antioxidant system. The primary function of the enzymatic antioxidative system is to remove the harmful radicals generated during oxidative stress, aiding agricultural plants in withstanding abiotic stress like salinity [86]. Nearly every component of the plant has some natural antioxidants. These natural antioxidants include vitamins, carotenoids, phenols, dietary glutathione, flavonoids, and endogenous metabolites [94]. Plants’ first line of defense against oxidative stress in soils influenced by salt is the synthesizing and scavenging these antioxidants.

4. Different Pathways of Salt Tolerance in Plants

4.1. Osmotic Adjustment

Salinity tolerance varies widely among plants, affecting their growth responses. Many salt-tolerant plants adjust mechanisms to counteract water stress (Figure 2) [9]. Plants may need osmotic adjustment to survive excessive salinity [95]. The plant must maintain low cytosolic Na+ concentrations, high K+/Na+ ratios, and cellular turgor at low osmotic potentials to grow in salty soil. These properties support K+-dependent metabolic processes through osmotic adjustment [9]. Many appropriate solutes contain nitrogen. These N-containing compounds include glycine betaine, proline, and polyamines [96,97]. Thus, nitrogen metabolism matters under stress.

4.2. The Exclusion, Redistribution, or Inclusion/Sequestration of Salt Facing the Ion Toxicity

Some transporters work to prevent Na+ from building up and to neutralize its harmful effects in the cytosol. In return for an H+, the vacuolar Na+/H+ antiporter (NHXs) sequesters a sodium ion into the vacuole [98]. Keeping cytosolic Na+ levels low at the cellular level and keeping Na+ concentrations low at the whole-plant level are efficient ways for glycophytes to deal with salinity stress. Apart from these variables, it was discovered that K+ uptake and maintenance significantly affected plants’ ability to withstand salt [99]. It has been strongly suggested that maintaining high cytosolic K+/Na+ ratios, particularly in shoots, is essential for glycophyte plants to be salt-tolerant [100].
“Sodium exclusion” is frequently used interchangeably with “preventing its accumulation in the shoot”. Na+ extrusion from the root thus has an actual role. In animal cells, Na+/K+-ATPase releases three Na+ ions in return for two K+ ions [101]. While Na+ can be more easily extruded in lower plants by sodium ATPase (PpENA1), in higher plants, the Na+/H+ antiporter Salt Overly Sensitive 1 (SOS1) is still the only transporter that is known to keep Na+ out of the cytosol and into the apoplast [102]. The authors of [103] confirmed that a 10- to 20-fold higher Na+ extrusion ability was observed in their study on wheat (under the same considerations) in the root extension zone, with net Na+ fluxes ranging from –284 ± 39 nmol m–2 s−1 to –1584 ± 237 nmol m−2 s−1, compared with the study by the authors of [104] that reported that mature root zone Na+ efflux mostly ranged between –20 nmol m−2 s–1 and –70 nmol m–2 s–1.
The mature root zone, which makes up most of the root and can lower the Na+ load in the shoot, may provide the physiological explanation for the sequestration phenomena [103]. It has been extensively shown that decreased Na+ buildup in the shoot is associated with the high-affinity K+ transporter (HKT)-mediated retrieval of Na+ from the xylem [105], and last, wheat’s resistance to salt occurs [106]. HKT transporters are constituents of the Trk/Ktr/HKT superfamily and are frequently denoted as monovalent cation transporters. Extensive research has been conducted on these entities across several plant species, revealing their vital role in enhancing salt tolerance. Their primary function involves preventing the infiltration of Na+ ions into the vulnerable shoot tissues of plants [107]. There is not much physiological justification for intentionally loading Na+ in the shot and retrieving it. By instantly depositing a salt load in the root cortex of the mature zone, this pointless cycle can be broken, and the same result can be obtained at a lesser cost [104]. Notably, wheat’s vacuolar fluorescence Na+ signal has a notably higher intensity in the root elongation zone than in the mature zone, implying that Na+ may be transferred from the mature root zone to the expanded zone [103].

4.3. The Activation of Redox Responses

One of the critical mechanisms by which plants are damaged during adverse environmental conditions is the excess production of reactive oxygen species (ROS) (Figure 3)—the salt-induced ROS that most likely originate from the mitochondrial and chloroplast electron transport chains [98]. Eliminating harmful ROS species is the most crucial component of an effective acclimatization response in salt stress. Reduced stomatal conductance is how plants react to salt stress to prevent excessive water loss. Consequently, this lowers internal CO2 concentrations (Ci) and slows down the Calvin cycle’s elimination of CO2 [108], causing photorespiration, especially in C3 plants, which causes the peroxisome to produce more H2O2 [109]. Numerous findings suggest that various chemicals, pigments, and enzymes have defensive functions that reduce oxidative damage and improve plant tolerance to salt by eliminating hazardous ROS. The antioxidant enzymes are SOD, CAT, POX, and APX, while the nonenzymatic antioxidant compounds are glutathione (GSH), ascorbates (ASC), and carotenoids [110]. Some other types of antioxidants are called anthocyanins; they are flavonoids known to accumulate in plants subjected to salt stress [98].

5. Exploring Nanoparticle Kinds and Their Ability to Reduce Abiotic Stress

The exceptional characteristics of nanoparticles (NPs), which include their heightened reactivity, enhanced surface activity, and large surface-to-volume ratio, comprise both the nanoparticles’ physical and chemical properties [111]. Typical classifications of nanoparticles (NPs) include many kinds that are typically divided according to concepts like the synthesis method and the compounds or elements used in the synthesis. Many studies on metal and metal oxide-based nanoparticles (NPs) have been conducted in agricultural settings over the past decade [112,113,114]. These research studies have been carried out in several different countries with the goals of increasing crop output and enhancing plants’ flexibility and resilience in the face of abiotic stresses [115,116,117,118]. Researchers have shown a great interest in metal-based nanoparticles and the oxides that correspond to them. These nanomaterials include a wide variety of metals, such as gold, silver, copper, aluminum, and iron; in addition, they form a variety of metal oxides, such as titanium dioxide (TiO2; titanium has an oxidation state “OS” = Ti4+), cerium oxide (CeO2; cerium has an OS = Ce4+), iron oxide (FeO; iron has an OS = Fe2+), aluminum oxide (Al2O3; aluminum has an OS = Al3+), and zinc oxide (ZnO; zinc has OS = Zn+2) [33,34,119].
Plants have significant challenges regarding their capacity for growth and productivity when subjected to abiotic stressors such as heat, cold, humidity, and the toxic effects of heavy metals [30]. Plants exhibit responses to abiotic stressors through several mechanisms, encompassing molecular, morphological, physiological, and biochemical alterations. Scientists have employed the concentration-dependent impacts of magnetic nanoparticles (MNPs) on the growth and development of plants to illustrate their potential in helping plants endure abiotic challenges [120]. Depending on the particular mechanism of action that MNPs possess, they can be applied to plants in various ways, including as a seed-priming agent, soil treatment, or foliar applications. Several studies have shed light on the positive effects that specific ZnO-NPs have on certain plant species when those plants are subjected to various abiotic stresses (Table 1). It has been discovered that zinc oxide nanoparticles (ZnO-NPs) can improve nutrient absorption, regulate the Na+/K+ ratio, maintain water balance, facilitate ion accumulation, and buffer the adverse effects of abiotic stressors. The elevation of flavonoid, anthocyanin, phenolic, and photosynthetic pigment levels and the overexpression of antioxidant enzymes are all responsible for these benefits. In addition, ZnO-NPs have been shown to reduce the expression of stress markers such as malondialdehyde (MDA) and hydrogen peroxide (H2O2) while also affecting transcriptional factors.
Foliar Zinc can increase wheat yield in alkaline soils [135]. A study examined how foliar ZnO and its nanoparticle treatments affected safflower growth and yield under various watering regimens [136]. ZnO foliar treatments increased safflower yield. The optimal spraying concentration was found to be 5–10 g L−1. The authors discovered that applying ZnO increased crop productivity under various stress scenarios. Photosynthesis and dry matter accumulation increased biomass yield. ZnO foliar treatments increased the number of capitula per plant and the number of seeds.
Nano-fertilizers improve product growth and performance while being environmentally friendly. Thus, molecular strategies using NPs can improve plant nutrition and stress resistance [136]. Nano-fertilizers increase nutrient-use efficiency, reduce chemical fertilizer environmental impact, and minimize fertilization frequency [137]. The study found that safflower morphology and physiology have improved, especially in drought. Addressing Zn shortage, developmental signals like seed oil content increases could explain this production increase [138]. The study revealed that nanomaterials applied by foliar spraying increased growth and yield. This relates to nanomaterial characteristics. After spraying nanoparticles on the plant, they assimilate quickly. Few researchers have examined how nanoparticles affect plant development or stress response, and the behavior of different NPs in plants is unknown [138]. The study discovered that 10 g L−1 ZnO-NPs enhanced safflower growth, especially with extended irrigation intervals. This shows that safflower absorbs ZnO-NPs better than their conventional form. Because of their tiny size (1–100 nm), ZnO-NPs are more available to plants than regular ZnO [139].

6. Various Nanoparticles and Their Impact on the Genes Responsible for Plant Salt Tolerance: Enzymatic Expression

Nanoparticles produced in a laboratory have the potential to interact with plants in a variety of ways, including chemically and mechanically. The entities’ characteristics, such as their size, surface area, and catalytic qualities, all play a role in the interactions between them. The number of studies that have been conducted on nanoparticles’ effects on molecules is minimal [34,140,141]. Zinc oxide nanoparticles (ZnO-NPs) and other nanoparticles significantly impact numerous plant types as stimulators to the antioxidative defensive mechanisms (Figure 4) and assimilate into the soil around the plant. In contrast, others enter the leaf of the plant and accumulate in the edible sections. Environmentally harmful metal and metal oxide nanoparticles include Zn2+, Ag1+, Fe3+, Al3+, and Ti4+ [142]. Silver nanoparticles (Ag-NPs) were found to boost the amounts of antioxidant enzymes in Brassica juncea, such as guaiacol peroxidase, catalase, and ascorbate peroxidase, which in turn reduced the activity of reactive oxygen species/substances (ROS) [143]. Following the exposure of Brassica juncea to gold nanoparticles (Au-NPs), there was an observed rise in the activity levels of various enzymes, including superoxide dismutase (SOD), catalase (CAT), guaiacol peroxidase, ascorbate peroxidase, and glutathione reductase (GHR) [144].
An observation indicated that plants subjected to treatment with Au-NPs exhibit elevated concentrations of proline and H2O2. The activity of ascorbate peroxidase, glutathione reductase, and guaiacol peroxidase is enhanced by the presence of gold nanoparticles at concentrations of up to 400 ppm. Specifically, guaiacol peroxidase activity is increased by gold nanoparticles at a concentration of 200 ppm. The molecular responses of arabidopsis plants to silver nanoparticle treatment were investigated using a reverse transcription-polymerase chain reaction (RT-PCR) [145]. A whole-genome cDNA expression microarray was utilized to investigate the transcriptional responses of arabidopsis plants exposed to silver nanoparticles. As a result, a total of 286 genes that exhibited increased expression levels were identified.
Among these genes, certain ones were shown to be associated with oxidative stress and metal responses, such as the vacuolar proton exchanger, superoxide dismutase (SOD), cytochrome P450-dependent oxidase, and peroxidase. In addition to identifying genes associated with plant defense, the study also revealed the presence of around 81 genes that exhibited down-regulation. Some genes involved in regulating auxin, the ethylene signaling system, and systemic acquired resistance (SAR) were identified as being responsible for conferring improved and often enduring protection against various illnesses in the plant kingdom. Identifying proteins that exhibit a reaction to silver nanoparticles has revealed their association with several metabolic processes, such as transcription, protein degradation, the oxidative-stress response system, and the calcium-signaling pathway [146]. After treatment with zinc oxide nanoparticles, 660 up- and 826 down-regulated genes were found in Arabidopsis thaliana. Tomato germination rate and seed germination were enhanced by treatment with multi-walled carbon nanotubes, which increase the expression of genes that respond to stress [147]. The effect of synthesized ZnO-NPs on plant characteristics is presented in Figure 5.

7. Transcriptional Factors Affecting Salt Tolerance

Transcriptional factors (TFs) attach themselves to DNA regulatory sequences located in the 5′-upstream region of target genes to regulate the rate at which transcribed genes are stimulated. Consequently, by “turning on” and “off” specific genes that connect with other DNA, TFs play a crucial role. Ultimately, they regulate the manufacture of the transcriptional proteins that alter cellular activity in plant tissues. The highly conserved transcription factors (TFs) aid plants in overcoming salt stress by controlling the expression of specific genes. Gene expression is regulated via transcription factors, affecting cell development. First and foremost, as transcription factors influence alterations in gene transcription, it is critical to comprehend transcription mechanisms. RNA polymerase 2 (RNA PII) is the enzyme that carries out transcription in all eukaryotes. Namely, RNA PII is not able to move by itself. The cis-regulatory region, or the DNA sequence found within the gene, and transcription factors, which are proteins that function as trans-acting factors, regulate the activity of this enzyme. Such DNA segments are known as cis-acting elements, and they control transcription. The six significant TF families associated with stress tolerance are DREB, MYB, NAC, WRKY, and bZIP. Table 2 lists TFs that reduce salinity stress [148,149].
The recognition of the stress signal by membrane-bound receptors in the plant cell is the initial step in activating a signaling cascade in response to abiotic stress (Figure 6). Scientists have recently demonstrated that several proteins localized on the plasma membrane act as putative sensors for abiotic stress signals. These proteins include COLD1 (CHILLING-TOLERANCE DIVERGENCE 1), OSCA1 (reduced hyperosmolality-induced calcium increase1), MSLs (MscS-like proteins), CNGCs (cyclic nucleotide-gated channels), GLR (glutamate receptor-like) channels, histidine Ca2+, and reactive oxygen species (ROS), which are examples of second messengers that are transmitted downstream from these sensors after identification. A different set of ROS-modulated protein kinases (PKs) and protein phosphatases (PPs), similar to ROS, are activated by the second messengers [208].
These include MAPK (mitogen-activated protein kinase) cascades, CDPKs (calcium-dependent protein kinases), CBLs (calcineurin-B-like proteins), CIPK (CBL-interacting protein kinase), and numerous other PKs in addition to PPs like some PP2Cs (protein phosphatase 2Cs). The information is then sent downstream by these PKs and PPs, which in turn set off cascades of phosphorylation and dephosphorylation, particularly involving TFs. This ultimately results in the expression of regulatory genes that play a role in the transcriptional regulation of gene expression and signaling cascades, or indirectly in the expression of functional genes involved in cellular protection (Figure 7) [149,208,209,210,211,212,213,214,215,216].
The aforementioned stress-responsive genes are subject to the regulation of their expressions through the activation and deactivation of transcription factors via phosphorylation and dephosphorylation mechanisms. A single transcription factor can regulate a cluster of downstream target genes instead of functional genes. These qualities provide promising candidate genes for the genetic manipulation of complex stress-tolerance traits. The different types of salt-stressed responsive genes and their functions can be summarized in Figure 8.

7.1. AP2/EREBP (Apetala2/Ethylene-Responsive Element-Binding Protein) Transcription Factors

Developmental, abiotic, and biotic stress response and other physiological processes are all regulated by the broad family of transcription factors known as AP2/EREBP [217]. The AP2/ERF DNA-binding domain, which is widely conserved, is present in AP2/EREBP transcription factors. This domain is responsible for recognizing and binding to specific DNA sequences known as GCC boxes and DRE/C-repeat elements (CRT) located in the promoter region of their target genes [218]. The existence of a predetermined quantity of AP2/ERF domains has made it possible to divide the AP2/EREBP gene family into four distinct subgroups. The proteins known as DREB (dehydration-responsive element-binding proteins), AP2, RAV (related to ABI3/VP1), and ERF (ethylene-responsive element-binding factors) are all included in this category of proteins [217]. Previous studies have demonstrated that members of the AP2/EREBP gene family, specifically DREB and ERF, play a role in the tolerance of biotic and abiotic stress [151,152,153,154].

7.2. WRKY TFs

The presence of the WRKY domain distinguishes WRKY from the other members of the large family of TFs. This domain is around sixty amino acids long, has the WRKY sequence at its amino-terminal, and a putative C2H2 or C2HC zinc finger motif at each carboxyl-terminal end. In the promoter region of their target genes, WRKY transcription factors bind to conserved cis-elements known as W boxes. These W boxes are identified by the sequence (T)(T)TGAC(C/T), and they are located in the W box region [219,220]. The number of WRKY domains present in a WRKY transcription factor (TF) and the particular type of zinc finger-like motif that it possesses can be used to divide this type of transcription factor into one of three separate classes. In Group I, there are two WRKY domains, both exhibiting the C2H2 motif. In Groups II and III, however, there is only one WRKY domain, which either displays the C2H2 motif or the C2HC zinc finger-like motif. The extensive group II can be subdivided into five subgroups using the peptide sequence as the criterion. These subgroups are designated IIa, IIb, IIc, and IIe, respectively [220]. WRKY genes have been identified to play a role in the biological function of abiotic stress tolerance [221]. Based on a recent study, it was found that JcWRKY, a type II WRKY transcription factor derived from the biofuel plant Jatropha curcas, could enhance salt tolerance in transgenic tobacco plants. This enhancement was achieved by facilitating the regulation of reactive oxygen species (ROS) levels through the involvement of salicylic acid (SA) [174].

7.3. NAC TFs

The NAC family comprises a sizeable number of members and is unique to higher plants in that only they possess it. The name of the gene that encodes the NAC transcription factor (TF) comes from the combination of the names of three other genes: CUP-SHAPED COTYLEDON 2, arabidopsis transcription activation factor 1/2 (ATAF 1 and ATAF 2), and Petunia hybrid No apical meristem (NAM) (CUC 2). The N-terminal portion of these proteins is characterized by a conserved NAC domain responsible for DNA binding. In contrast, the C-terminal portion of these proteins contains a transcriptional activator domain that can take on various forms and is positioned at the C-terminus. Researchers have uncovered NAC genes in several plant species, including rice, Arabidopsis, foxtail millet (Setaria italica), and soybean (Glycine max), by a procedure known as whole-genome sequencing [222,223,224]. NAC transcription factors (TFs) have been identified as critical regulators of various biological processes, such as growth, fruit ripening, hormone signaling, and responses to both biotic and abiotic stress [225]. Furthermore, genetic manipulation has been employed to enhance the ability of NAC transcription factors (TFs) to mitigate the impact of abiotic stressors on crops [190].

7.4. bZIP TFs

The ability of the bZIP group of transcription factors to bind to DNA is facilitated by the presence of a leucine zipper motif at the C-terminus and a conserved essential region with a basic leucine zipper (bZIP) domain at the N-terminus [226]. These defining properties are located at the C-terminus and N-terminus of the factor, respectively [226]. The bZIP family of proteins has another function, which is to react to abiotic stresses such as high salt concentrations, a lack of water, and cold temperatures, among others. Several studies have shown that abscisic acid (ABA) makes it easier for specific genes to become activated [227]. The findings of the empirical study support these findings. These genes are critically important in regulating the expression of many genes involved in the stress response. Notably, they can accomplish this by identifying and interacting with conserved abscisic acid-responsive elements (ABREs) in the promoter region of these genes [228]. Numerous bZIP TFs have been specified in various plant species; for example, arabidopsis [229], rice [230], corn [231], Brassica oleracea [232], and Solanum lycopersicum [233]. bZIP TFs can be divided into 11 groups (I–XI) [230]. Members of Group A, also known as ABRE-binding factors (ABFs/AREBs), are thought to have a role in how plants react to environmental stresses such as drought and salinity [18].

8. Gene Expression and Zinc Oxide Nanoparticles

Phytohormones influence the responses of many plant species to external stimuli by modulating of the expression levels of several auxin-responsive protein (ARP) genes [211]. Auxin gradients in both spatial and temporal dimensions are frequently modulated by factors such as auxin synthesis, auxin transporters responsible for inflow and efflux, and a diverse array of interrelated hormonal signals [212,213]. In a study conducted by Hezaveh et al. (2019) [132], they applied salt and ZnO-NPs to examine the expression profile of the ARP gene. The presence of salinity induced the generation of ROS, subsequently triggering the activation of auxin oxidases. The expression of several genes associated with growth processes was anticipated to be diminished due to the increased breakdown of auxin facilitated by auxin oxidases.
The synthesis of auxin, the metabolic processes involving nitrogen, and the expansion of root cell tissue are all significantly influenced by the zinc ion, an essential nutrient because it stimulates the biosynthesis of tryptophan [234]. Indole-based auxins are synthesized from tryptophan, so your zinc nanoparticles will indirectly affect elongation growth [235]. This is because it serves as a cofactor for various enzymes, such as oxidases, dehydrogenases, and anhydrases, including peroxidases. This is how it can accomplish this [236]. The cation-exchange capacity of the root is increased via zinc, which makes it easier for the root to absorb essential nutrients, including nitrogen. This, in turn, results in a rise in the total amount of protein. Additionally, zinc is critical to the breakdown of carbohydrates and proteins throughout the metabolic process [237].
According to the findings of a study, the level of Myelocytomatosis Oncogenes (MYC) transcription factors that were noticed to be mainly produced in plants were those that had been exposed to a concentration of 20 mg/L of ZnO-NPs. These transcription factors are involved in various biological processes, including the production of anthocyanins, specific amino acids like tryptophan (Tryp), stomatal differentiation, seed germination, and endosperm degradation. They also play a critical role in activating jasmonic acid-responsive genes, which is a process that is required to produce jasmonic acid-responsive proteins. In environments with high salinity, a lower level of MYC expression was found than in environments with lower salinity. It is possible that the degeneration of the MYC progenitors is to blame for the decrease in their level of focus that occurred after they were exposed to salt [121].

9. Conclusions

A sustainable agricultural system takes into account a variety of factors, such as the protection of the natural environment, the improvement of human health, the realization of economic and spiritual benefits for both farmers and consumers, and the capacity to fulfill the requirements for food production posed by an ever-increasing global population. The existence of abiotic stress conditions in the environment presents a significant barrier to the expansion of agricultural production on a worldwide scale. The presence of salt substantially influences the ecological balance of the region and the agricultural output of the vast majority of crops. This is because salinity reduces the amount of water available for plant growth. In addition, it acts as a factor that affects the physicochemical characteristics of the ground. A decrease in agricultural output, insufficient economic gains, and harm to the land are some of the adverse effects of salt on a community. The development of saline impacts results from a complex interaction between morphological, physiological, and biochemical systems, including seed germination, plant growth, and the absorption of water and nutrients. A negative effect on the development of plants occurs when they are subjected to salt stress while still in the early stages of their growth. This finally results in a significant decrease in yield under saline circumstances, which jeopardizes both the quality and quantity of plant products. This highlights how important it is to study the various processes, such as transcriptional control, that govern the numerous physiological responses of plants when confronted with such unfavorable situations.
It has been demonstrated that incorporating particular nanoparticles, such as ZnO-NPs, can reduce the harmful effects of salt stress. It has been shown that these nanoparticles interact with a variety of transcription factors (TFs), which may be triggered or released, and also induce the production of certain hormones and substances that regulate osmotic pressure within plant cells. Consequently, these systems contribute to the maintenance of protein integrity, selective permeability, the rate of photosynthetic reactions, and various other critical physiological activities. Since soils and plants are subject to several abiotic stresses, such as salt, drought, low temperature (chilling or frost strains), and hot temperature, more research is needed to determine how plants might moderate these pressures. Salt stress depletes plant vigor and metabolic function, reducing agricultural yield. It thus emphasizes how important it is to study the multiple factors, including at the transcriptional level, that regulate the many activities of plants in these stressful situations. By working with different transcription factors (TFs) that may be released or activated, or even by inducing specific hormones and compounds that regulate osmotic pressure inside the plant cell, specific nanoparticles, like ZnO-NPs, have shown promising results in reducing salinity stress. This helps to preserve the integrity of the proteins, selective permeability, photosynthetic rate, and other vital processes.

Author Contributions

Conceptualization, M.A. and K.D.; data curation, M.A., K.D. and Z.T.; formal analysis, M.A. and K.D.; funding acquisition, Z.T.; investigation, M.A. and K.D.; methodology, M.A. and K.D.; project administration, Z.T.; resources, Z.T.; software, M.A. and K.D.; supervision, Z.T. and K.D.; validation, M.A. and K.D.; visualization, M.A.; writing—original draft, M.A. and K.D.; writing—review and editing, M.A., K.D. and Z.T. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All data are available within the manuscript.

Acknowledgments

We have deep gratitude for Donia Abdul-Hamid, B.Sc. Agric. Sci. (Biotechnology), Fac. Agric. Cairo Univ, and an analyst at the Central Laboratory for the analysis of pesticides and heavy metals in food (QCAP), Heavy Metals Dept., for her exceptional help and unwavering support throughout this research endeavor. Her insightful feedback and continuous encouragement have been invaluable in shaping the direction and outcomes of this article.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Ingrao, C.; Strippoli, R.; Lagioia, G.; Huisingh, D. Water Scarcity in Agriculture: An Overview of Causes, Impacts and Approaches for Reducing the Risks. Heliyon 2023, 9, e18507. [Google Scholar] [CrossRef]
  2. Shrivastava, P.; Kumar, R. Soil Salinity: A Serious Environmental Issue and Plant Growth Promoting Bacteria as One of the Tools for Its Alleviation. Saudi J. Biol. Sci. 2015, 22, 123–131. [Google Scholar] [CrossRef]
  3. Grigore, M.N.; Toma, C.; Grigore, M.N.; Toma, C. Saline environments; Springer International Publishing: New York, NY, USA, 2017. [Google Scholar]
  4. Negacz, K.; Malek, Ž.; de Vos, A.; Vellinga, P. Saline Soils Worldwide: Identifying the Most Promising Areas for Saline Agriculture. J. Arid. Environ. 2022, 203, 104775. [Google Scholar] [CrossRef]
  5. Nachshon, U. Cropland Soil Salinization and Associated Hydrology: Trends, Processes and Examples. Water 2018, 10, 1030. [Google Scholar] [CrossRef]
  6. Butcher, K.; Wick, A.; DeSutter, T.; Chatterjee, A.; Harmon, J. Soil Salinity: A Threat to Global Food Security. Agron. J. 2016, 108, 2189–2200. [Google Scholar] [CrossRef]
  7. Nabati, J.; Kafi, M.; Nezami, A.; Moghaddam, P.R.; Ali, M.; Mehrjerdi, M.Z. Effect of Salinity on Biomass Production and Activities of Some Key Enzymatic Antioxidants in Kochia (Kochia Scoparia). Pak. J. Bot. 2011, 43, 539–548. [Google Scholar]
  8. Ahanger, M.A.; Agarwal, R.M.; Tomar, N.S.; Shrivastava, M. Potassium Induces Positive Changes in Nitrogen Metabolism and Antioxidant System of Oat (Avena sativa L. Cultivar Kent). J. Plant Interact. 2015, 10, 211–223. [Google Scholar] [CrossRef]
  9. Munns, R.; Tester, M. Mechanisms of Salinity Tolerance. Annu. Rev. Plant Biol. 2008, 59, 651–681. [Google Scholar] [CrossRef] [PubMed]
  10. Jiang, C.; Zu, C.; Lu, D.; Zheng, Q.; Shen, J.; Wang, H.; Li, D. Effect of Exogenous Selenium Supply on Photosynthesis, Na+ Accumulation and Antioxidative Capacity of Maize (Zea mays L.) under Salinity Stress. Sci. Rep. 2017, 7, 42039. [Google Scholar] [CrossRef] [PubMed]
  11. Mittal, S.; Kumari, N.; Sharma, V. Differential Response of Salt Stress on Brassica Juncea: Photosynthetic Performance, Pigment, Proline, D1 and Antioxidant Enzymes. Plant Physiol. Biochem. 2012, 54, 17–26. [Google Scholar] [CrossRef]
  12. Gengmao, Z.; Shihui, L.; Xing, S.; Yizhou, W.; Zipan, C. The Role of Silicon in Physiology of the Medicinal Plant (Lonicera japonica L.) under Salt Stress. Sci. Rep. 2015, 5, 12696. [Google Scholar] [CrossRef] [PubMed]
  13. Quintero, J.M.; Fournier, J.M.; Benlloch, M. Na+ Accumulation in Shoot Is Related to Water Transport in K+-Starved Sunflower Plants but Not in Plants with a Normal K+ Status. J. Plant Physiol. 2007, 164, 60–67. [Google Scholar] [CrossRef] [PubMed]
  14. Abbasi, G.H.; Akhtar, J.; Ahmad, R.; Jamil, M.; Anwar-Ul-Haq, M.; Ali, S.; Ijaz, M. Potassium Application Mitigates Salt Stress Differentially at Different Growth Stages in Tolerant and Sensitive Maize Hybrids. Plant Growth Regul. 2015, 76, 111–125. [Google Scholar] [CrossRef]
  15. Noctor, G.; Foyer, C.H. Ascorbate and Glutathione: Keeping Active Oxygen Under Control. Ann. Rev. Plant Physiol. Plant Mol. Biol. 1998, 49, 249–279. [Google Scholar] [CrossRef]
  16. Pitzschke, A.; Forzani, C.; Hirt, H. Reactive Oxygen Species Signaling in Plants. Antioxid. Redox Signal 2006, 8, 1757–1764. [Google Scholar] [CrossRef]
  17. Maas, E.V. Crop Salt Tolerance. In Agricultural salinity assessment and management, ASCE Manuals and Reports on Engineering Practice; Tanji, K.K., Ed.; American Society of Civil Engineers: Reston, VA, USA, 1990. [Google Scholar]
  18. Banerjee, A.; Roychoudhury, A. Abscisic-acid-dependent basic leucine zipper (bZIP) transcription factors in plant abiotic stress. Protoplasma 2017, 254, 3–16. [Google Scholar] [CrossRef]
  19. Joshi, R.; Wani, S.H.; Singh, B. Transcription Factors and Plants Response to Drought Stress: Current Understanding and Future Directions. Front. Plant Sci. 2016, 7, 1029. [Google Scholar] [CrossRef] [PubMed]
  20. Golldack, D.; Li, C.; Mohan, H.; Probst, N. Tolerance to Drought and Salt Stress in Plants: Unraveling the Signaling Networks. Front. Plant Sci. 2014, 5, 151. [Google Scholar] [CrossRef]
  21. Handford, C.E.; Dean, M.; Henchion, M.; Spence, M.; Elliott, C.T.; Campbell, K. Implications of Nanotechnology for the Agri-Food Industry: Opportunities, Benefits and Risks. Trends Food Sci. Technol. 2014, 40, 226–241. [Google Scholar] [CrossRef]
  22. Acharya, A.; Pal, P.K. Agriculture Nanotechnology: Translating Research Outcome to Field Applications by Influencing Environmental Sustainability. NanoImpact 2020, 19, 100232. [Google Scholar] [CrossRef]
  23. Foley, J.A.; Ramankutty, N.; Brauman, K.A.; Cassidy, E.S.; Gerber, J.S.; Johnston, M. Solutions for a Cultivated Planet. Nature 2011, 478, 337–342. [Google Scholar] [CrossRef]
  24. Tuomisto, H.L.; Scheelbeek, P.F.D.; Chalabi, Z.; Green, R.; Smith, R.D.; Haines, A.; Dangour, A.D. Effects of Environmental Change on Agriculture, Nutrition and Health: A Framework with a Focus on Fruits and Vegetables. Wellcome Open Res. 2017, 2, 21. [Google Scholar] [CrossRef]
  25. Raza, A.; Razzaq, A.; Mehmood, S.S.; Zou, X.; Zhang, X.; Lv, Y.; Xu, J. Impact of Climate Change on Crops Adaptation and Strategies to Tackle Its Outcome: A Review. Plants 2019, 8, 34. [Google Scholar] [CrossRef]
  26. Dresselhaus, T.; Hückelhoven, R. Biotic and Abiotic Stress Responses in Crop Plants. Agronomy 2018, 8, 267. [Google Scholar] [CrossRef]
  27. Sekhon, B.S. Nanotechnology in Agri-Food Production: An Overview. Nanotechnol. Sci. Appl. 2014, 7, 31–53. [Google Scholar] [CrossRef]
  28. Tipu, M.M.H.; Baroi, A.; Rana, J.; Islam, S.; Jahan, R.; Miah, M.S. Potential Applications of Nanotechnology in Agriculture: A Smart Tool for Sustainable Agriculture. In Agricultural Development in Asia-Potential Use of Nano-Materials and Nano-Technology; IntechOpen: London, UK, 2021. [Google Scholar]
  29. Kumar, A.A.; Mishra, P.; Kumari, K.; Panigrahi, K. Environmental Stress Influencing Plant Development and Flowering. Front. Biosci. 2012, 4, 1315–1324. [Google Scholar]
  30. Yang, L.; Wen, K.-S.; Ruan, X.; Zhao, Y.-X.; Wei, F.; Wang, Q. Response of plant secondary metabolites to environmental factors. Molecules 2018, 23, 762. [Google Scholar] [CrossRef] [PubMed]
  31. Das, K.; Roychoudhury, A. Reactive Oxygen Species (ROS) and Response of Antioxidants as ROS-Scavengers during Environmental Stress in Plants. Front. Environ. Sci. 2014, 2, 53. [Google Scholar] [CrossRef]
  32. Rai, P.K.; Kumar, V.; Lee, S.; Raza, N.; Kim, K.-H.; Ok, Y.S. Nanoparticleplant Interaction: Implications in Energy, Environment, and Agriculture. Environ. Int. 2018, 119, 1–19. [Google Scholar] [CrossRef] [PubMed]
  33. Abdel Latef, A.A.H.; Abu Alhmad, M.F.; Abdelfattah, K.E. The Possible Roles of Priming with ZnO Nanoparticles in Mitigation of Salinity Stress in Lupine (Lupinus Termis. Plants. J. Plant Growth Regul. 2017, 36, 60–70. [Google Scholar] [CrossRef]
  34. Taran, N.; Storozhenko, V.; Svietlova, N.; Batsmanova, L.; Shvartau, V.; Kovalenko, M. Effect of Zinc and Copper Nanoparticles on Drought Resistance of Wheat Seedlings. Nanoscale Res. Lett. 2017, 12, 60. [Google Scholar] [CrossRef]
  35. Goharrizi, K.J.; Baghizadeh, A.; Kalantar, M.; Fatehi, F. Combined Effects of Salinity and Drought on Physiological and Biochemical Characteristics of Pistachio Rootstocks. Sci. Hortic. 2020, 261, 108970. [Google Scholar] [CrossRef]
  36. Hussain, S.; Cao, X.; Zhong, C.; Zhu, L.; Khaskheli, M.A.; Fiaz, S.; Zhang, J.; Jin, Q. Sodium Chloride Stress during Early Growth Stages Altered Physiological and Growth Characteristics of Rice. Chil. J. Agric. Res. 2018, 78, 183–197. [Google Scholar] [CrossRef]
  37. Ahmad, M.; Zahir, Z.A.; Naeem Asghar, H.; Asghar, M. Inducing Salt Tolerance in Mung Bean through Coinoculation with Rhizobia and Plant-Growth-Promoting Rhizobacteria Containing 1- Aminocyclopropane-1-Carboxylate Deaminase. Can. J. Microbiol. 2011, 57, 578–589. [Google Scholar] [CrossRef] [PubMed]
  38. Munns, R.; James, R.A.; Läuchli, A. Approaches to Increasing the Salt Tolerance of Wheat and Other Cereals. J. Exp. Bot. 2006, 57, 1025–1043. [Google Scholar] [CrossRef] [PubMed]
  39. Tavakkoli, E.; Rengasamy, P.; McDonald, G.K. High Concentrations of Na+ and Cl Ions in Soil Solution Have Simultaneous Detrimental Effects on Growth of Faba Bean under Salinity Stress. J. Exp. Bot. 2010, 61, 4449–4459. [Google Scholar] [CrossRef] [PubMed]
  40. Geilfus, C.-M.; Tenhaken, R.; Carpentier, S.C. Transient Alkalinization of the Leaf Apoplast Stiffens the Cell Wall during Onset of Chloride Salinity in Corn Leaves. J. Biol. Chem. 2017, 292, 18800–18813. [Google Scholar] [CrossRef] [PubMed]
  41. Ma, Y.; Dias, M.C.; Freitas, H. Drought and Salinity Stress Responses and Microbe-Induced Tolerance in Plants. Front. Plant Sci. 2020, 11, 591911. [Google Scholar] [CrossRef] [PubMed]
  42. Munns, R.; Gilliham, M. Salinity Tolerance of Crops—What Is the Cost? New Phytol. 2015, 208, 668–673. [Google Scholar] [CrossRef]
  43. Amthor, J. The McCree–de Wit–Penning de Vries–Thornley Respiration Paradigms: 30 Years Later. Ann. Bot. 2000, 86, 1–20. [Google Scholar] [CrossRef]
  44. Zhao, S.; Zhang, Q.; Liu, M.; Zhou, H.; Ma, C.; Wang, P. Regulation of Plant Responses to Salt Stress. Int. J. Mol. Sci. 2021, 22, 4609. [Google Scholar] [CrossRef] [PubMed]
  45. Childs, B.G.; Durik, M.; Baker, D.J.; van Deursen, J.M. Cellular Senescence in Aging and Age-Related Disease: From Mechanisms to Therapy. Nat. Med. 2015, 21, 1424–1435. [Google Scholar] [CrossRef] [PubMed]
  46. Werf, A.; Kooijman, A.; Welschen, R.; Lambers, H. Respiratory Energy Costs for the Maintenance of Biomass, for Growth and for Ion Uptake in Roots ofCarex diandraandCarex Acutiformis. Physiol. Plant. 1988, 72, 483–491. [Google Scholar] [CrossRef]
  47. Katerji, N.; van Hoorn, J.W.; Hamdy, A.; Mastrorilli, M. Salt Tolerance of Crops According to Three Classification Methods and Examination of Some Hypothesis about Salt Tolerance. Agric. Water Manag. 2001, 47, 1–8. [Google Scholar] [CrossRef]
  48. Al-shareef, N.O.; Tester, M. Plant Salinity Tolerance. In Encyclopedia of Life Sciences; Wiley: Hoboken, NJ, USA, 2019; pp. 1–6. [Google Scholar]
  49. Richard, B.; Qi, A.; Fitt, B.D.L. Control of Crop Diseases through Integrated Crop Management to Deliver Climate-smart Farming Systems for Low- and High-input Crop Production. Plant Pathol. 2022, 71, 187–206. [Google Scholar] [CrossRef]
  50. De-la-Cruz Chacón, I.; Riley-Saldaña, C.A.; González-Esquinca, A.R. Secondary Metabolites during Early Development in Plants. Phytochem. Rev. 2013, 12, 47–64. [Google Scholar] [CrossRef]
  51. Kamran, M.; Parveen, A.; Ahmar, S.; Malik, Z.; Hussain, S.; Chattha, M.S.; Saleem, M.H.; Adil, M.; Heidari, P.; Chen, J.-T. An Overview of Hazardous Impacts of Soil Salinity in Crops, Tolerance Mechanisms, and Amelioration through Selenium Supplementation. Int. J. Mol. Sci. 2019, 21, 148. [Google Scholar] [CrossRef]
  52. Munns, R. Physiological Processes Limiting Plant Growth in Saline Soils: Some Dogmas and Hypotheses. Plant Cell Environ. 1993, 16, 15–24. [Google Scholar] [CrossRef]
  53. Aghighi Shahverdi, M.; Omidi, H.; Tabatabaei, S.J. Plant Growth and Steviol Glycosides as Affected by Foliar Application of Selenium, Boron, and Iron under NaCl Stress in Stevia Rebaudiana Bertoni. Ind. Crops Prod. 2018, 125, 408–415. [Google Scholar] [CrossRef]
  54. Shahrajabian, M.H.; Khoshkharam, M.; Sun, W.; Cheng, Q. Germination and Seedlings Growth of Corn (Zea mays L.) to Allelopathic Effects of Rice (Oryza sativa L.). Trop. Plant Res. 2019, 6, 152–156. [Google Scholar] [CrossRef]
  55. Lee, D.G.; Park, K.W.; An, J.Y.; Sohn, Y.G.; Ha, J.K.; Kim, H.Y.; Bae, D.W.; Lee, K.H.; Kang, N.J.; Lee, B.H. Proteomics Analysis of Salt-Induced Leaf Proteins in Two Rice Germplasms with Different Salt Sensitivity. Can. J. Plant Sci. 2011, 91, 337–349. [Google Scholar] [CrossRef]
  56. Ibrahim, E.A. Seed Priming to Alleviate Salinity Stress in Germinating Seeds. J. Plant Physiol. 2016, 192, 38–46. [Google Scholar] [CrossRef]
  57. Ashraf, M. Relationships between Growth and Gas Exchange Characteristics in Some Salt-Tolerant Amphidiploid Brassica Species in Relation to Their Diploid Parents. Environ. Exp. Bot. 2001, 45, 155–163. [Google Scholar] [CrossRef]
  58. Qados, A.M.S.A. Effect of salt stress on plant growth and metabolism of bean plant Vicia faba (L.). J. Saudi Soc. Agric. Sci. 2011, 10, 7–15. [Google Scholar]
  59. Ahmadi, F.I.; Karimi, K.; Struik, P.C. Effect of Exogenous Application of Methyl Jasmonate on Physiological and Biochemical Characteristics of Brassica Napus L. Cv. Talaye under Salinity Stress. S. Afr. J. Bot. 2018, 115, 5–11. [Google Scholar] [CrossRef]
  60. Hajiboland, R.; Norouzi, F.; Poschenrieder, C. Growth, Physiological, Biochemical and Ionic Responses of Pistachio Seedlings to Mild and High Salinity. Trees Struct. Funct. 2014, 28, 1065–1078. [Google Scholar] [CrossRef]
  61. Mallahi, T.; Saharkhiz, M.J.; Javanmardi, J. Salicylic Acid Changes Morpho-Physiological Attributes of Feverfew (Tanacetum parthenium L.) under Salinity Stress. Acta Ecol. Sin. 2018, 38, 351–355. [Google Scholar] [CrossRef]
  62. Shi, Q.; Ding, F.; Wang, X.; Wei, M. Exogenous Nitric Oxide Protects Cucumber Roots against Oxidative Stress Induced by Salt Stress. Plant Physiol. Biochem. 2007, 45, 542–550. [Google Scholar] [CrossRef]
  63. Hameed, A.; Ahmed, M.Z.; Hussain, T.; Aziz, I.; Ahmad, N.; Gul, B.; Nielsen, B.L. Effects of Salinity Stress on Chloroplast Structure and Function. Cells 2021, 10, 2023. [Google Scholar] [CrossRef]
  64. Netondo, G.W.; Onyango, J.C.; Beck, E.S.; salinity, I. Gas Exchange and Chlorophyll Fluorescence of Sorghum under Salt Stress. Crop Sci. 2004, 44, 806. [Google Scholar]
  65. Sapre, S.; Gontia-Mishra, I.; Tiwari, S. Klebsiella Sp. Confers Enhanced Tolerance to Salinity and Plant Growth Promotion in Oat Seedlings (Avena sativa). Microbiol. Res. 2018, 206, 25–32. [Google Scholar] [CrossRef] [PubMed]
  66. Rozeff, N. Sugarcane and Salinity—A Review Paper. Sugar Cane 1995, 5, 8–19. [Google Scholar]
  67. Cantabella, D.; Piqueras, A.; Acosta-Motos, J.R.; Bernal-Vicente, A.; Hernández, J.A.; Díaz-Vivancos, P. Salt-Tolerance Mechanisms Induced in Stevia Rebaudiana Bertoni: Effects on Mineral Nutrition, Antioxidative Metabolism and Steviol Glycoside Content. Plant Physiol. Biochem. 2017, 115, 484–496. [Google Scholar] [CrossRef] [PubMed]
  68. Elkelish, A.A.; Soliman, M.H.; Alhaithloul, H.A.; El-Esawi, M.A. Selenium Protects Wheat Seedlings against Salt Stress-Mediated Oxidative Damage by up-Regulating Antioxidants and Osmolytes Metabolism. Plant Physiol. Biochem. 2019, 137, 144–153. [Google Scholar] [CrossRef] [PubMed]
  69. Khan, M.I.R.; Asgher, M.; Khan, N.A. Alleviation of Salt-Induced Photosynthesis and Growth Inhibition by Salicylic Acid Involves Glycinebetaine and Ethylene in Mungbean (Vigna radiata L.). Plant Physiol. Biochem. 2014, 80, 67–74. [Google Scholar] [CrossRef] [PubMed]
  70. Munns, R. Genes and Salt Tolerance: Bringing Them Together. New Phytol. 2005, 167, 645–663. [Google Scholar] [CrossRef] [PubMed]
  71. Hussain, S.; Zhang, J.H.; Zhong, C.; Zhu, L.F.; Cao, X.C.; YU, S.M.; Allen Bohr, J.; Hu, J.J.; Jin, Q.Y. Effects of Salt Stress on Rice Growth, Development Characteristics, and the Regulating Ways: A Review. J. Integr. Agric. 2017, 16, 2357–2374. [Google Scholar] [CrossRef]
  72. Hussain, S.; Zhong, C.; Bai, Z.; Cao, X.; Zhu, L.; Hussain, A.; Zhu, C.; Fahad, S.; James, A.B.; Zhang, J. Effects of 1-Methylcyclopropene on Rice Growth Characteristics and Superior and Inferior Spikelet Development Under Salt Stress. J. Plant Growth Regul. 2018, 37, 1368–1384. [Google Scholar] [CrossRef]
  73. Wang, W.; Vinocur, B.; Altman, A. Plant Responses to Drought, Salinity and Extreme Temperatures: Towards Genetic Engineering for Stress Tolerance. Planta 2003, 218, 1–14. [Google Scholar] [CrossRef]
  74. Zahedi, S.M.; Abdelrahman, M.; Hosseini, M.S.; Hoveizeh, N.F.; Tran, L.P. Alleviation of the Effect of Salinity on Growth and Yield of Strawberry by Foliar Spray of Selenium-Nanoparticles. In Environmental Pollution; Elsevier: Amsterdam, The Netherlands, 2019. [Google Scholar]
  75. Gururani, M.A.; Venkatesh, J.; Tran, L.S.P. Regulation of Photosynthesis during Abiotic Stress-Induced Photoinhibition. Mol. Plant 2015, 8, 1304–1320. [Google Scholar] [CrossRef]
  76. James, R.A.; Blake, C.; Byrt, C.S.; Munns, R. Major Genes for Na+ Exclusion, Nax1 and Nax2 (Wheat HKT1;4 and HKT1;5), Decrease Na+ Accumulation in Bread Wheat Leaves under Saline and Waterlogged Conditions. J. Exp. Bot. 2011, 62, 2939–2947. [Google Scholar] [CrossRef]
  77. Evelin, H.; Kapoor, R.; Giri, B. Arbuscular Mycorrhizal Fungi in Alleviation of Salt Stress: A Review. Ann. Bot. 2009, 104, 1263–1280. [Google Scholar] [CrossRef]
  78. Hussain, S.; Bai, Z.; Huang, J.; Cao, X.; Zhu, L.; Zhu, C.; Khaskheli, M.A.; Zhong, C.; Jin, Q.; Zhang, J. 1-Methylcyclopropene Modulates Physiological, Biochemical, and Antioxidant Responses of Rice to Different Salt Stress Levels. Front. Plant Sci. 2019, 10, 124. [Google Scholar] [CrossRef] [PubMed]
  79. Singam, K.; Juntawong, N.; Cha-Um, S.; Kirdmanee, C. Salt Stress Induced Ion Accumulation, Ion Homeostasis, Membrane Injury and Sugar Contents in Salt-Sensitive Rice (Oryza sativa L. spp. Indica) Roots under Isoosmotic Conditions. Afr. J. Biotechnol. 2011, 10, 1340–1346. [Google Scholar]
  80. Demiral, T.; Türkan, I. Comparative Lipid Peroxidation, Antioxidant Defense Systems and Proline Content in Roots of Two Rice Cultivars Differing in Salt Tolerance. Environ. Exp. Bot. 2005, 53, 247–257. [Google Scholar] [CrossRef]
  81. Levitt, J. Responses of Plants to Environmental Stresses. J. Range Manag. 1985, 38, 480. [Google Scholar] [CrossRef]
  82. Pattanayak, G.K.; Tripathy, B.C. Overexpression of Protochlorophyllide Oxidoreductase c Regulates Oxidative Stress in Arabidopsis. PLoS ONE 2011, 6, 26532. [Google Scholar] [CrossRef]
  83. Santos, M.G.; Ribeiro, R.V.; Machado, E.C.; Pimentel, C. Photosynthetic Parameters and Leaf Water Potential of Five Common Bean Genotypes under Mild Water Deficit. Biol. Plant 2009, 53, 229–236. [Google Scholar] [CrossRef]
  84. Subramanyam, K.; Laing, G.; Damme, E.J.M. Sodium Selenate Treatment Using a Combination of Seed Priming and Foliar Spray Alleviates Salinity Stress in Rice. Front. Plant Sci. 2019, 10, 116. [Google Scholar] [CrossRef]
  85. Foyer, C.H.; Noctor, G. Redox Sensing and Signalling Associated with Reactive Oxygen in Chloroplasts, Peroxisomes and Mitochondria. Physiol. Plant 2003, 119, 355–364. [Google Scholar] [CrossRef]
  86. Kamran, M.; Malik, Z.; Parveen, A.; Huang, L.; Riaz, M.; Bashir, S.; Mustafa, A.; Abbasi, G.H.; Xue, B.; Ali, U. Ameliorative Effects of Biochar on Rapeseed (Brassica napus L.) Growth and Heavy Metal Immobilization in Soil Irrigated with Untreated Wastewater. J. Plant Growth Regul. 2020, 39, 266–281. [Google Scholar] [CrossRef]
  87. Adly, A.A.M. Oxidative stress and disease: An updated review. Res. J. Immunol. 2010, 3, 129–145. [Google Scholar]
  88. Houot, V.; Etienne, P.; Petitot, A.S.; Barbier, S.; Blein, J.P.; Suty, L. Hydrogen peroxide induces programmed cell death features in cultured tobacco BY-2 cells, in a dose-dependent manner. J. Exp. Bot. 2001, 52, 1721–1730. [Google Scholar]
  89. Farmer, E.E.; Mueller, M.J. ROS-Mediated Lipid Peroxidation and RES-Activated Signaling. Ann. Rev. Plant Biol. 2013, 64, 429–450. [Google Scholar] [CrossRef] [PubMed]
  90. Asada, K. Causes of Photooxidative Stress and Amelioration of Defense Systems in Plants. In Production and Action of Active Oxygen Species in Photosynthetic Tissues; CRC Press: Boca Raton, FL, USA, 1994; pp. 77–104. [Google Scholar]
  91. Ramachandra Reddy, A.; Chaitanya, K.V.; Jutur, P.P.; Sumithra, K. Differential Antioxidative Responses to Water Stress among Five Mulberry (Morus alba L.) Cultivars. Environ. Exp. Bot. 2004, 52, 33–42. [Google Scholar] [CrossRef]
  92. Li, M.; Guo, S.; Xu, Y.; Meng, Q.; Li, G.; Yang, X. Glycine Betaine-Mediated Potentiation of HSP Gene Expression Involves Calcium Signaling Pathways in Tobacco Exposed to NaCl Stress. Physiol. Plant 2014, 150, 63–75. [Google Scholar] [CrossRef]
  93. Farhangi-Abriz, S.; Ghassemi-Golezani, K. How Can Salicylic Acid and Jasmonic Acid Mitigate Salt Toxicity in Soybean Plants? Ecotoxicol. Environ. Saf. 2018, 154, 1010–1016. [Google Scholar] [CrossRef]
  94. Krishnaiah, D.; Sarbatly, R.; Nithyanandam, R. A Review of the Antioxidant Potential of Medicinal Plant Species. Food Bioprod. Process 2011, 89, 217–233. [Google Scholar] [CrossRef]
  95. Buchanan, B.B.; Gruissem, W.; Jones, R.L. (Eds.) Biochemistry and Molecular Biology of Plants, 2nd ed.; Wiley-Blackwell:: Hoboken, NJ, USA, 2015. [Google Scholar]
  96. Ashraf, M.; Foolad, M.R. Roles of Glycine Betaine and Proline in Improving Plant Abiotic Stress Resistance. Environ. Exp. Bot. 2007, 59, 206–216. [Google Scholar] [CrossRef]
  97. Mansour, M.M.F.; Ali, E.F. Evaluation of Proline Functions in Saline Conditions. Phytochemistry 2017, 140, 52–68. [Google Scholar] [CrossRef]
  98. Balasubramaniam, T.; Shen, G.; Esmaeili, N.; Zhang, H. Plants’ Response Mechanisms to Salinity Stress. Plants 2023, 12, 2253. [Google Scholar] [CrossRef]
  99. Zhu, J.K.; Liu, J.P.; Xiong, L.M. Genetic Analysis of Salt Tolerance in Arabidopsis: Evidence for a Critical Role of Potassium Nutrition. Plant Cell 1998, 10, 1181–1191. [Google Scholar] [CrossRef]
  100. Hauser, F.; Horie, T. A Conserved Primary Salt Tolerance Mechanism Mediated by HKT Transporters: A Mechanism for Sodium Exclusion and Maintenance of High K/Na Ratio in Leaves during Salinity Stress. Plant Cell Environ. 2010, 33, 552–565. [Google Scholar] [CrossRef]
  101. Galva, C.; Artigas, P.; Gatto, C. Nuclear Na+/K+-ATPase Plays an Active Role in Nucleoplasmic Ca2+ Homeostasis. J. Cell Sci. 2012, 125, 6137–6147. [Google Scholar]
  102. Lunde, C.; Drew, D.P.; Jacobs, A.K.; Tester, M. Exclusion of Na+ via Sodium ATPase (PpENA1) Ensures Normal Growth of Physcomitrella Patens under Moderate Salt Stress. Plant 2007, 144, 1786–1796. [Google Scholar] [CrossRef]
  103. Wu, H.; Shabala, L.; Azzarello, E.; Huang, Y.; Pandolfi, C.; Su, N.; Wu, Q.; Cai, S.; Bazihizina, N.; Wang, L.; et al. Na+ Extrusion from the Cytosol and Tissue-Specific Na+ Sequestration in Roots Confer Differential Salt Stress Tolerance between Durum and Bread Wheat. J. Exp. Bot. 2018, 69, 3987–4001. [Google Scholar] [CrossRef]
  104. Cuin, T.A.; Bose, J.; Stefano, G.; Jha, D.; Tester, M.; Mancuso, S.; Shabala, S. Assessing the Role of Root Plasma Membrane and Tonoplast Na+/H+ Exchangers in Salinity Tolerance in Wheat: In Planta Quantification Methods: Cytosolic Na+ Exclusion in Wheat. Plant Cell Environ. 2011, 34, 947–961. [Google Scholar] [CrossRef] [PubMed]
  105. Byrt, C.S.; Platten, J.D.; Spielmeyer, W.; James, R.A.; Lagudah, E.S.; Dennis, E.S.; Tester, M.; Munns, R. HKT1;5-like Cation Transporters Linked to Na+ Exclusion Loci in Wheat, Nax2 and Kna1. Plant Physiol. 2007, 143, 1918–1928. [Google Scholar] [CrossRef] [PubMed]
  106. Munns, R.; James, R.A.; Xu, B. Wheat Grain Yield on Saline Soils Is Improved by an Ancestral Na+ Transporter Gene. Nature 2012, 30, 360–364. [Google Scholar] [CrossRef]
  107. Jaime-Pérez, N.; Pineda, B.; García-Sogo, B.; Atares, A.; Athman, A.; Byrt, C.S.; Olías, R.; Asins, M.J.; Gilliham, M.; Moreno, V.; et al. The Sodium Transporter Encoded by the HKT1;2 Gene Modulates Sodium/Potassium Homeostasis in Tomato Shoots under Salinity. Plant Cell Environ. 2017, 40, 658–671. [Google Scholar] [CrossRef]
  108. Hsu, S.Y.; Kao, C.H. Differential Effect of Sorbitol and Polyethylene Glycol on Antioxidant Enzymes in Rice Leaves. Plant Growth Regul. 2003, 39, 83–90. [Google Scholar] [CrossRef]
  109. Ghannoum, O. C4 Photosynthesis and Water Stress. Ann. Bot. 2009, 103, 635–644. [Google Scholar] [CrossRef]
  110. Azeem, M.; Pirjan, K.; Qasim, M. Salinity stress improves antioxidant potential by modulating physio-biochemical responses in Moringa oleifera Lam. Sci. Rep. 2023, 13, 2895. [Google Scholar] [CrossRef] [PubMed]
  111. Sukhanova, A.; Bozrova, S.; Sokolov, P.; Berestovoy, M.; Karaulov, A.; Nabiev, I. Dependence of Nanoparticle Toxicity on Their Physical and Chemical Properties. Nanoscale Res. Lett. 2018, 13, 1–21. [Google Scholar] [CrossRef] [PubMed]
  112. Dziergowska, K.; Michalak, I. Chapter 9—The Role of Nanoparticles in Sustainable Agriculture. In Smart Agrochemicals for Sustainable Agriculture; Chojnacka, K., Saeid, A., Eds.; Academic Press: Cambridge, MA, USA, 2022; pp. 225–278. ISBN 978-0-12-817036-6. [Google Scholar]
  113. Solaiman, M.A.; Ali, M.A.; Abdel-Moein, N.M.; Mahmoud, E.A. Synthesis of Ag-NPs Developed by Green-Chemically Method and Evaluation of Antioxidant Activities and Anti-Inflammatory of Synthesized Nanoparticles against LPS-Induced NO in RAW 264.7 Macrophages. Biocatal. Agric. Biotechnol. 2020, 29, 101832. [Google Scholar] [CrossRef]
  114. Rastogi, A.; Zivcak, M.; Sytar, O.; Kalaji, H.M.; He, X.; Mbarki, S.; Brestic, M. Impact of Metal and Metal Oxide Nanoparticles on Plant: A Critical Review. Front. Chem. 2017, 5, 78. [Google Scholar] [CrossRef] [PubMed]
  115. Ambrosone, A.; Mattera, L.; Marchesano, V.; Quarta, A.; Susha, A.S.; Tino, A.; Rogach, A.L.; Tortiglione, C. Mechanisms Underlying Toxicity Induced by CdTe Quantum Dots Determined in an Invertebrate Model Organism. Biomaterials 2012, 33, 1991–2000. [Google Scholar] [CrossRef] [PubMed]
  116. Nguyen, K.C.; Rippstein, P.; Tayabali, A.F.; Willmore, W.G. Mitochondrial Toxicity of Cadmium Telluride Quantum Dot Nanoparticles in Mammalian Hepatocytes. Toxicol. Sci. 2015, 146, 31–42. [Google Scholar] [CrossRef]
  117. Singh, B.R.; Singh, B.N.; Khan, W.; Singh, H.B.; Naqvi, A.H. ROS-Mediated Apoptotic Cell Death in Prostate Cancer LNCaP Cells Induced by Biosurfactant Stabilized CdS Quantum Dots. Biomaterials 2012, 33, 5753–5767. [Google Scholar] [CrossRef]
  118. Paramo, L.A.; Feregrino-Pérez, A.A.; Guevara, R.; Mendoza, S.; Esquivel, K. Nanoparticles in Agroindustry: Applications, Toxicity, Challenges, and Trends. Nanomaterials 2020, 10, 1654. [Google Scholar] [CrossRef]
  119. Alabdallah, N.M.; Alzahrani, H.S. The Potential Mitigation Effect of ZnO Nanoparticles on [Abelmoschus Esculentus L. Moench] Metabolism under Salt Stress Conditions. Saudi J. Biol. Sci. 2020, 27, 3132–3137. [Google Scholar] [CrossRef] [PubMed]
  120. Sarraf, M.; Vishwakarma, K.; Kumar, V.; Arif, N.; Das, S.; Johnson, R. Metal/Metalloid-Based Nanomaterials for Plant Abiotic Stress Tolerance: An Overview of the Mechanisms. Plants 2022, 11, 316. [Google Scholar] [CrossRef] [PubMed]
  121. Ahmed, M.; Decsi, K.; Tóth, Z. Different Tactics of Synthesized Zinc Oxide Nanoparticles, Homeostasis Ions, and Phytohormones as Regulators and Adaptatively Parameters to Alleviate the Adverse Effects of Salinity Stress on Plants. Life 2022, 13, 73. [Google Scholar] [CrossRef]
  122. El-Badri, A.M.; Batool, M.; Mohamed, I.A.; Khatab, A.; Sherif, A.; Wang, Z. Modulation of Salinity Impact on Early Seedling Stage via Nano-Priming Application of Zinc Oxide on Rapeseed (Brassica napus L.). Plant Physiol. Biochem. 2021, 166, 376–392. [Google Scholar] [CrossRef] [PubMed]
  123. Ghani, M.I.; Saleem, S.; Rather, S.A.; Rehmani, M.S.; Alamri, S.; Rajput, V.D. Foliar Application of Zinc Oxide Nanoparticles: An Effective Strategy to Mitigate Drought Stress in Cucumber Seedling by Modulating Antioxidant Defense System and Osmolytes Accumulation. Chemosphere 2022, 289, 133202. [Google Scholar] [CrossRef] [PubMed]
  124. Hassan, N.S.; Salah El Din, T.A.; Hendawey, M.H.; Borai, I.H.; Mahdi, A.A. Magnetite and zinc oxide nanoparticles alleviated heat stress in wheat plants. Curr. Nanomater. 2018, 3, 32–43. [Google Scholar] [CrossRef]
  125. Song, Y.; Jiang, M.; Zhang, H.; Li, R. Zinc Oxide Nanoparticles Alleviate Chilling Stress in Rice (Oryza sativa L.) by Regulating Antioxidative System and Chilling Response Transcription Factors. Molecules 2021, 26, 2196. [Google Scholar] [CrossRef]
  126. Venkatachalam, P.; Jayaraj, M.; Manikandan, R.; Geetha, N.; Rene, E.R.; Sharma, N. Zinc Oxide Nanoparticles (ZnONPs) Alleviate Heavy Metal-Induced Toxicity in Leucaena Leucocephala Seedlings: A Physiochemical Analysis. Plant Physiol. Biochem. 2017, 110, 59–69. [Google Scholar] [CrossRef]
  127. Rakgotho, T.; Ndou, N.; Mulaudzi, T.; Iwuoha, E.; Mayedwa, N.; Ajayi, R.F. Green-Synthesized Zinc Oxide Nanoparticles Mitigate Salt Stress in Sorghum Bicolor. Agriculture 2022, 12, 597. [Google Scholar] [CrossRef]
  128. Faizan, M.; Bhat, J.A.; Chen, C.; Alyemeni, M.N.; Wijaya, L.; Ahmad, P.; Yu, F. Zinc Oxide Nanoparticles (ZnO-NPs) Induce Salt Tolerance by Improving the Antioxidant System and Photosynthetic Machinery in Tomato. Plant Physiol. Biochem. 2021, 161, 122–130. [Google Scholar] [CrossRef] [PubMed]
  129. Soliman, M.; Elkelish, A.; Souad, T.; Alhaithloul, H.; Farooq, M. Brassinosteroid Seed Priming with Nitrogen Supplementation Improves Salt Tolerance in Soybean. Physiol. Mol. Biol. Plants 2020, 26, 501–511. [Google Scholar] [CrossRef]
  130. Gaafar, R.; Diab, R.; Halawa, M.; Elshanshory, A.; El-Shaer, A.; Hamouda, M. Role of Zinc Oxide Nanoparticles in Ameliorating Salt Tolerance in Soybean. Egypt. J. Bot. 2020, 60, 733–747. [Google Scholar] [CrossRef]
  131. Akhavan, H.; Torfeh, P.; Latifeh, R.; Fatemeh, A.H. Effects of ZnO NPs on Phenolic Compounds of Rapeseed Seeds under Salinity Stress. J. Plant Proc. Func. 2020, 8, 11–18. [Google Scholar]
  132. Hezaveh, T.A.; Pourakbar, L.; Rahmani, F.; Alipour, H. Interactive Effects of Salinity and ZnO Nanoparticles on Physiological and Molecular Parameters of Rapeseed (Brassica napus L.). Commun. Soil. Sci. Plant Anal. 2019, 50, 698–715. [Google Scholar] [CrossRef]
  133. Lalarukh, I.; Zahra, N.; Al Huqail, A.A.; Amjad, S.F.; Al-Dhumri, S.A.; Ghoneim, A.M.; Alshahri, A.H.; Almutari, M.M.; Alhusayni, F.S.; Al-Shammari, W.B. Exogenously Applied ZnO Nanoparticles Induced Salt Tolerance in Potentially High Yielding Modern Wheat (Triticum aestivum L.) Cultivars. Environ. Technol. Innov. 2022, 27, 102799. [Google Scholar] [CrossRef]
  134. Fathi, A.; Zahedi, M.; Torabian, S. Effect of Interaction between Salinity and Nanoparticles (Fe2O3 and ZnO) on Physiological Parameters of Zea mays L. J. Plant Nutr. 2017, 40, 2745–2755. [Google Scholar] [CrossRef]
  135. Khattak, S.G.; Dominy, P.J.; Ahmad, W. Effect of Zn as Soil Addition and Foliar Application on Yield and Protein Content of Wheat in Alkaline Soil. J. Natl. Sci. Found. Sri Lanka 2015, 43, 303. [Google Scholar] [CrossRef]
  136. Ghiyasi, M.; Rezaee Danesh, Y.; Amirnia, R.; Najafi, S.; Mulet, J.M.; Porcel, R. Foliar Applications of ZnO and Its Nanoparticles Increase Safflower (Carthamus tinctorius L.) Growth and Yield under Water Stress. Agronomy 2023, 13, 192. [Google Scholar] [CrossRef]
  137. Aljutheri, H.; Habeeb, K.; Al-Taey, D.; Rahman, A.; Al Tawaha, A.R.; Kadhim, F. Effect of Foliar Application of Different Sources of Nano-Fertilizers on Growth and Yield of wheatEffect of Foliar Application of Different Sources of Nano-Fertilizers on Growth and Yield of Wheat. Biosci. Res. 2018, 4, 3976–3985. [Google Scholar]
  138. Rossi, L.; Fedenia, L.N.; Sharifan, H.; Ma, X.; Lombardini, L. Effects of Foliar Application of Zinc Sulfate and Zinc Nanoparticles in Coffee (Coffea arabica L.) Plants. Plant Physiol. Biochem. 2019, 135, 160–166. [Google Scholar] [CrossRef] [PubMed]
  139. Rajput, V.D.; Minkina, T.M.; Behal, A.; Sushkova, S.N.; Mandzhieva, S.; Singh, R.; Gorovtsov, A.; Tsitsuashvili, V.S.; Purvis, W.O.; Ghazaryan, K.A.; et al. Effects of Zinc-Oxide Nanoparticles on Soil, Plants, Animals and Soil Organisms: A Review. Environ. Nanotechnol. Monit. Manag. 2018, 9, 76–84. [Google Scholar] [CrossRef]
  140. Rao, S.; Shekhawat, G.S. Phytotoxicity and Oxidative Stress Perspective of Two Selected Nanoparticles in Brassica Juncea. 3 Biotech 2016, 6, 244. [Google Scholar] [CrossRef] [PubMed]
  141. Zohra, E.; Ikram, M.; Omar, A.A.; Hussain, M.; Satti, S.H.; Raja, N.I.; Ehsan, M. Potential Applications of Biogenic Selenium Nanoparticles in Alleviating Biotic and Abiotic Stresses in Plants: A Comprehensive Insight on the Mechanistic Approach and Future Perspectives. Green. Process. Synth. 2021, 10, 456–475. [Google Scholar] [CrossRef]
  142. Munir, N.; Hanif, M.; Dias, D.A.; Abideen, A. The Role of Halophytic Nanoparticles towards the Remediation of Degraded and Saline Agricultural Lands. Environ. Sci. Pollut. Res. 2021, 28, 60383–60405. [Google Scholar] [CrossRef]
  143. Sharma, P.; Bhatt, D.; Zaidi, M.; Saradhi, P.P.; Khanna, P.; Arora, S. Silver Nanoparticle-Mediated Enhancement in Growth and Antioxidant Status of Brassica Juncea. Appl. Biochem. Biotechnol. 2012, 167, 2225–2233. [Google Scholar] [CrossRef] [PubMed]
  144. Gunjan, B.; Zaidi, M. Impact of Gold Nanoparticles on Physiological and Biochemical Characteristics of Brassica Juncea. J. Plant Biochem. Physiol. 2014, 2, 67–73. [Google Scholar]
  145. Nair, P.M.G.; Chung, I.M. Assessment of silver nanoparticle-induced physiological and molecular changes in Arabidopsis thaliana. Environ. Sci. Pollut. Res. 2014, 21, 8858–8869. [Google Scholar] [CrossRef]
  146. Mirzajani, F.; Askari, H.; Hamzelou, S.; Schober, Y.; Römpp, A.; Ghassempour, A.; Spengler, B. Proteomics study of silver nanoparticles toxicity on Oryza sativa L. Ecotoxicol. Environ. Saf. 2014, 108, 335–339. [Google Scholar] [CrossRef]
  147. Khodakovskaya, M.; Dervishi, E.; Mahmood, M.; Xu, Y.; Li, Z.; Watanabe, F.; Biris, A.S. Carbon Nanotubes Are Able to Penetrate Plant Seed Coat and Dramatically Affect Seed Germination and Plant Growth. ACS Nano 2009, 3, 3221–3227. [Google Scholar] [CrossRef]
  148. Agarwal, P.K.; Gupta, K.; Lopato, S.; Agarwal, P. Dehydration Responsive Element Binding Transcription Factors and Their Applications for the Engineering of Stress Tolerance. J. Exp. Bot. 2017, 68, 2135–2148. [Google Scholar] [CrossRef]
  149. Khan, S.-A.; Li, M.-Z.; Wang, S.-M.; Yin, H.-J. Revisiting the Role of Plant Transcription Factors in the Battle against Abiotic Stress. Int. J. Mol. Sci. 2018, 19, 1634. [Google Scholar] [CrossRef]
  150. Paul, S.; Roychoudhury, A. Transgenic Plants for Improved Salinity and Drought Tolerance. In Biotechnologies of Crop Improvement; Gosal, S., Wani, S., Eds.; Springer: Cham, Switzerland, 2018; Volume 2. [Google Scholar]
  151. Augustine, S.M.; Ashwin Narayan, J.; Syamaladevi, D.P. Overexpression of EaDREB2 and Pyramiding of EaDREB2 with the Pea DNA Helicase Gene (PDH45) Enhance Drought and Salinity Tolerance in Sugarcane (Saccharum spp. Hybrid). Plant Cell Rep. 2015, 34, 247–263. [Google Scholar] [CrossRef]
  152. Bouaziz, D.; Pirrello, J.; Charfeddine, M. Overexpression of StDREB1 Transcription Factor Increases Tolerance to Salt in Transgenic Potato Plants. Mol. Biotechnol. 2013, 54, 803–817. [Google Scholar] [CrossRef]
  153. Cai, H.; Tian, S.; Dong, H.; Guo, C. Pleiotropic Effects of TaMYB3R1 on Plant Development and Response to Osmotic Stress in Transgenic Arabidopsis. Gene 2015, 558, 227–234. [Google Scholar] [CrossRef]
  154. Cao, Z.H.; Zhang, S.Z.; Wang, R.K. Genome Wide Analysis of the Apple MYB Transcription Factor Family Allows the Identification of MdoMYB121 Gene Confering Abiotic Stress Tolerance in Plants. PLoS ONE 2013, 8, e69955. [Google Scholar] [CrossRef] [PubMed]
  155. Chen, H.; Liu, L.; Wang, L. VrDREB2A, a DREB-Binding Transcription Factor from Vigna Radiata, Increased Drought and High-Salt Tolerance in Transgenic Arabidopsis Thaliana. J. Plant Res. 2016, 129, 263–273. [Google Scholar] [CrossRef] [PubMed]
  156. Ding, Z.; Li, S.; An, X. Transgenic Expression of MYB15 Confers Enhanced Sensitivity to Abscisic Acid and Improved Drought Tolerance in Arabidopsis Thaliana. J. Genet. Genom. 2009, 36, 17–29. [Google Scholar] [CrossRef] [PubMed]
  157. He, Y.; Li, W.; J, L. Ectopic Expression of a Wheat MYB Transcription Factor Gene, TaMYB73, improves salinity stress tolerance in Arabidopsis thaliana. J. Exp. Bot. 2012, 63, 1511–1522. [Google Scholar] [CrossRef]
  158. Li, J.B.; Luan, Y.S.; Yin, Y.L. SpMYB Overexpression in Tobacco Plants Leads to Altered Abiotic and Biotic Stress Responses. Gene 2014, 547, 145–151. [Google Scholar] [CrossRef] [PubMed]
  159. Mallikarjuna, G.; Mallikarjuna, K.; Reddy, M.K.; Kaul, T. Expression of OsDREB2A Transcription Factor Confers Enhanced Dehydration and Salt Stress Tolerance in Rice (Oryza sativa L.). Biotechnol. Lett. 2011, 33, 1689–1697. [Google Scholar] [CrossRef] [PubMed]
  160. Peng, X.; Zhang, L.; Zhang, L. The Transcriptional Factor LcDREB2 Cooperates with LcSAMDC2 to Contribute to Salt Tolerance in Leymus Chinensis. Plant Cell Tissue Organ. Cult. 2013, 113, 245–256. [Google Scholar] [CrossRef]
  161. Qi, L.; Yang, J.; Yuan, Y. Overexpression of Two R2R3-MYB Genes from Scutellaria Baicalensis Induces Phenylpropanoid Accumulation and Enhances Oxidative Stress Resistance in Transgenic Tobacco. Plant Physiol. Biochem. 2015, 94, 235–243. [Google Scholar] [CrossRef]
  162. Qin, Y.; Wang, M.; Tian, Y. Over-Expression of TaMYB33 Encoding a Novel Wheat MYB Transcription Factor Increases Salt and Drought Tolerance in Arabidopsis. Mol. Biol. Rep. 2012, 39, 7183–7192. [Google Scholar] [CrossRef] [PubMed]
  163. Rong, W.; Qi, L.; Wang, A. The ERF Transcription Factor TaERF3 Promotes Tolerance to Salt and Drought Stresses in Wheat. Plant Biotechnol. J. 2014, 12, 468–479. [Google Scholar] [CrossRef] [PubMed]
  164. Shukla, P.S.; Gupta, K.; Agarwal, P. Overexpression of a Novel SbMYB15 from Salicornia Brachiata Confers Salinity and Dehydration Tolerance by Reduced Oxidative Damage and Improved Photosynthesis in Transgenic Tobacco. Planta 2015, 242, 1291–1308. [Google Scholar] [CrossRef] [PubMed]
  165. Sun, Z.-M.; Zhou, M.-L.; Xiao, X.-G. Genome-Wide Analysis of AP2/ERF Family Genes from Lotus Corniculatus Shows LcERF054 Enhances Salt Tolerance. Funct. Integr. Genom. 2014, 14, 453–466. [Google Scholar] [CrossRef]
  166. Wang, R.K.; Cao, Z.H.; Hao, Y.J. Overexpression of a R2R3 MYB Gene MdSIMYB1 Increases Tolerance to Multiple Stresses in Transgenic Tobacco and Apples. Physiol. Plant 2014, 150, 76–87. [Google Scholar] [CrossRef]
  167. Wang, T.; Tohge, T.; Ivakov, A. Salt-Related MYB1 Coordinates Abscisic Acid Biosynthesis and Signaling during Salt Stress in Arabidopsis. Plant Physiol. 2015, 169, 1027–1041. [Google Scholar] [CrossRef]
  168. Xiong, H.; Li, J.; Liu, P. Overexpression of OsMYB48-1, a Novel MYB-Related Transcription Factor, Enhances Drought and Salinity Tolerance in Rice. PLoS ONE 2014, 9, e92913. [Google Scholar] [CrossRef]
  169. Yang, G.; Yu, L.; Zhang, K. A ThDREB Gene from Tamarix Hispida Improved the Salt and Drought Tolerance of Transgenic Tobacco and T. Hispida. Plant Physiol. Biochem. 2017, 113, 187–197. [Google Scholar] [CrossRef]
  170. Yang, L.; Ji, W.; Gao, P. GsAPK, an ABA-Activated and Calcium-Independent SnRK2-Type Kinase from G. Soja, Mediates the Regulation of Plant Tolerance to Salinity and ABA Stress. PLoS ONE 2012, 7, e33838. [Google Scholar] [CrossRef]
  171. Zhai, Y.; Wang, Y.; Li, Y. Isolation and Molecular Characterization of GmERF7, a Soybean Ethylene-Response Factor That Increases Salt Stress Tolerance in Tobacco. Gene 2013, 513, 174–183. [Google Scholar] [CrossRef] [PubMed]
  172. Zhang, L.; Liu, G.; Zhao, G. Characterization of a Wheat R2R3-MYB Transcription Factor Gene, TaMYB19, Involved in Enhanced Abiotic Stresses in Arabidopsis. Plant Cell Physiol. 2014, 55, 1802–1812. [Google Scholar] [CrossRef] [PubMed]
  173. Zhang, X.; Liu, X.; Wu, L. The SsDREB Transcription Factor from the Succulent Halophyte Suaeda Salsa Enhances Abiotic Stress Tolerance in Transgenic Tobacco. Int. J. Genom. 2015, 2015, 875497. [Google Scholar]
  174. Agarwal, P.; Dabi, M.; Sapara, K.K. Ectopic Expression of JcWRKY Transcription Factor Confers Salinity Tolerance via Salicylic Acid Signaling. Front. Plant Sci. 2016, 7, 1541. [Google Scholar] [CrossRef] [PubMed]
  175. Qin, Y.; Tian, Y.; Liu, X. A Wheat Salinity-Induced WRKY Transcription Factor TaWRKY93 Confers Multiple Abiotic Stress Tolerance in Arabidopsis Thaliana. Biochem. Biophys. Res. Commun. 2015, 464, 428–433. [Google Scholar] [CrossRef]
  176. Chu, X.; Wang, C.; Chen, X. The Cotton WRKY Gene GhWRKY41 Positively Regulates Salt and Drought Stress Tolerance in Transgenic Nicotiana Benthamiana. PLoS ONE 2015, 10, e0143022. [Google Scholar] [CrossRef]
  177. Jia, H.; Wang, C.; Wang, F. GhWRKY68 Reduces Resistance to Salt and Drought in Transgenic Nicotiana Benthamiana. PLoS ONE 2015, 10, e0120646. [Google Scholar] [CrossRef]
  178. Li, J.B.; Luan, Y.S.; Liu, Z. Overexpression of SpWRKY1 Promotes Resistance to Phytophthora Nicotianae and Tolerance to Salt and Drought Stress in Transgenic Tobacco. Physiol. Plant 2015, 155, 248–266. [Google Scholar] [CrossRef]
  179. Liu, L.; Zhang, Z.; Dong, J.; Wang, T. Overexpression of MtWRKY76 Increases Both Salt and Drought Tolerance in Medicago Truncatula. Environ. Exp. Bot. 2016, 123, 50–58. [Google Scholar] [CrossRef]
  180. Niu, C.F.; Wei, W.; Zhou, Q.Y. Wheat WRKY Genes TaWRKY2 and TaWRKY19 Regulate Abiotic Stress Tolerance in Transgenic Arabidopsis Plants. Plant Cell Environ. 2012, 35, 1156–1170. [Google Scholar] [CrossRef] [PubMed]
  181. Qiu, Y.; Yu, D. Over-Expression of the Stress-Induced OsWRKY45 Enhances Disease Resistance and Drought Tolerance in Arabidopsis. Environ. Exp. Bot. 2009, 65, 35–47. [Google Scholar] [CrossRef]
  182. Song, Y.; Jing, S.J.; Yu, D.Q. Overexpression of the Stress-Induced OsWRKY08 Improves Osmotic Stress Tolerance in Arabidopsis. Chin. Sci. Bull. 2010, 54, 4671–4678. [Google Scholar] [CrossRef]
  183. Wang, C.; Deng, P.; Chen, L. A Wheat WRKY Transcription Factor TaWRKY10 Confers Tolerance to Multiple Abiotic Stresses in Transgenic Tobacco. PLoS ONE 2013, 8, e65120. [Google Scholar] [CrossRef]
  184. Wang, X.; Zeng, J.; Li, Y. Expression of TaWRKY44, a Wheat WRKY Gene, in Transgenic Tobacco Confers Multiple Abiotic Stress Tolerances. Front. Plant Sci. 2015, 6, 615. [Google Scholar] [CrossRef]
  185. Zheng, L.; Liu, G.; Meng, X. A WRKY Gene from Tamarix Hispida, ThWRKY4, Mediates Abiotic Stress Responses by Modulating Reactive Oxygen Species and Expression of Stress-Responsive Genes. Plant Mol. Biol. 2013, 82, 303–320. [Google Scholar] [CrossRef]
  186. Zhou, L.; Wang, N.N.; Gong, S.Y. Overexpression of a Cotton (Gossypium hirsutum) WRKY Gene, GhWRKY34, in Arabidopsis Enhances Salt-Tolerance of the Transgenic Plants. Plant Physiol. Biochem. 2015, 96, 311–320. [Google Scholar] [CrossRef]
  187. Chen, X.; Wang, Y.; Lv, B. The NAC Family Transcription Factor OsNAP Confers Abiotic Stress Response through the ABA Pathway. Plant Cell Physiol. 2014, 55, 604–619. [Google Scholar] [CrossRef] [PubMed]
  188. Fang, L.; Su, L.; Sun, X. Expression of Vitis amurensis NAC26 in Arabidopsis Enhances Drought Tolerance by Modulating Jasmonic Acid Synthesis. J. Exp. Bot. 2016, 67, 2829–2845. [Google Scholar] [CrossRef] [PubMed]
  189. Hao, Y.-J.; Wei, W.; Song, Q.-X. Soybean NAC Transcription Factors Promote Abiotic Stress Tolerance and Lateral Root Formation in Transgenic Plants. Plant J. 2011, 68, 302–313. [Google Scholar] [CrossRef] [PubMed]
  190. Hong, Y.; Zhang, H.; Huang, L. Overexpression of a Stress-Responsive NAC Transcription Factor Gene ONAC022 Improves Drought and Salt Tolerance in Rice. Front. Plant Sci. 2016, 7, 4. [Google Scholar] [CrossRef]
  191. Huang, Q.; Wang, Y.; Li, B. TaNAC29, a NAC Transcription Factor from Wheat, Enhances Salt and Drought Tolerance in Transgenic Arabidopsis. BMC Plant Biol. 2015, 15, 1–15. [Google Scholar] [CrossRef] [PubMed]
  192. Huang, Q.; Wang, Y. Overexpression of TaNAC2D Displays Opposite Responses to Abiotic. Front. Plant Sci. 2016, 7, 1754. [Google Scholar] [CrossRef] [PubMed]
  193. Mao, X.; Chen, S.; Li, A. Novel NAC Transcription Factor TaNAC67 Confers Enhanced Multi-Abiotic Stress Tolerances in Arabidopsis. PLoS ONE 2014, 9, e84359. [Google Scholar] [CrossRef]
  194. Rahman, H.; Ramanathan, V.; Nallathambi, J. Over-Expression of a NAC 67 Transcription Factor from Finger Millet (Eleusine coracana L.) Confers Tolerance against Salinity and Drought Stress in Rice. BMC Biotechnol. 2016, 16, 7–20. [Google Scholar] [CrossRef] [PubMed]
  195. Saad, A.S.; Li, X.; Li, H.-P. A Rice Stress-Responsive NAC Gene Enhances Tolerance of Transgenic Wheat to Drought and Salt Stresses. Plant Sci. 2013, 203–204, 33–40. [Google Scholar] [CrossRef] [PubMed]
  196. Tak, H.; Negi, S.; Ganapathi, T.R. Banana NAC Transcription Factor MusaNAC042 Is Positively Associated with Drought and Salinity Tolerance. Protoplasma 2016, 254, 803–816. [Google Scholar] [CrossRef]
  197. Yokotani, N.; Ichikawa, T.; Kondou, Y. Tolerance to Various Environmental Stresses Conferred by the Salt-Responsive Rice Gene ONAC063 in Transgenic Arabidopsis. Planta 2009, 229, 1065–1075. [Google Scholar] [CrossRef]
  198. Zhang, L.; Zhang, L.; Xia, C. The Novel Wheat Transcription Factor TaNAC47 Enhances Multiple Abiotic Stress Tolerances in Transgenic Plants. Front. Plant Sci. 2015, 6, 1174. [Google Scholar] [CrossRef]
  199. Cheng, L.; Li, S.; Hussain, J. Isolation and Functional Characterization of a Salt Responsive Transcriptional Factor, LrbZIP from Lotus Root (Nelumbo nucifera Gaertn). Mol. Biol. Rep. 2013, 40, 4033–4045. [Google Scholar] [CrossRef]
  200. Gao, S.Q.; Chen, M.; Xu, Z.S. The Soybean GmbZIP1 Transcription Factor Enhances Multiple Abiotic Stress Tolerances in Transgenic Plants. Plant Mol. Biol. 2011, 75, 537–553. [Google Scholar] [CrossRef]
  201. Liang, C.; Meng, Z.; Meng, Z. GhABF2, a bZIP Transcription Factor, Confers Drought and Salinity Tolerance in Cotton (Gossypium hirsutum L.). Sci. Rep. 2016, 6, 35040. [Google Scholar] [CrossRef]
  202. Liu, C.; Mao, B.; Ou, S. OsbZIP71, a bZIP Transcription Factor, Confers Salinity and Drought Tolerance in Rice. Plant Mol. Biol. 2014, 84, 19–36. [Google Scholar] [CrossRef]
  203. Wang, Z.; Su, G.; Li, M. Overexpressing Arabidopsis ABF3 Increases Tolerance to Multiple Abiotic Stresses and Reduces Leaf Size in Alfalfa. Plant Physiol. Biochem. 2016, 109, 199–208. [Google Scholar] [CrossRef]
  204. Xiang, Y.; Tang, N.; Du, H. Characterization of OsbZIP23 as a Key Player of the Basic Leucine Zipper Transcription Factor Family for Conferring Abscisic Acid Sensitivity and Salinity and Drought Tolerance in Rice. Plant Physiol. 2008, 148, 1938–1952. [Google Scholar] [CrossRef]
  205. Ying, S.; Zhang, D.-F.; Fu, J. Cloning and Characterization of a Maize bZIP Transcription Factor, ZmbZIP72, Confers Drought and Salt Tolerance in Transgenic Arabidopsis. Planta 2012, 235, 253–266. [Google Scholar] [CrossRef] [PubMed]
  206. Zhang, L.; Zhang, L.; Xia, C. A Novel Wheat bZIP Transcription Factor, TabZIP60, Confers Multiple Abiotic Stress Tolerances in Transgenic Arabidopsis. Physiol. Plant 2015, 153, 538–554. [Google Scholar] [CrossRef] [PubMed]
  207. Zhang, X.; Wang, L.; Meng, H. Maize ABP9 Enhances Tolerance to Multiple Stresses in Transgenic Arabidopsis by Modulating ABA Signaling and Cellular Levels of Reactive Oxygen Species. Plant Mol. Biol. 2011, 75, 365–378. [Google Scholar] [CrossRef] [PubMed]
  208. Yuan, F.; Yang, H.; Xue, Y.; Kong, D.; Ye, R.; Li, C.; Zhang, J.; Theprungsirikul, L.; Shrift, T.; Krichilsky, B.; et al. OSCA1 Mediates Osmotic-Stress-Evoked Ca2+ Increases Vital for Osmosensing in Arabidopsis. Nature 2014, 514, 367–371. [Google Scholar] [CrossRef]
  209. Asai, T.; Tena, G.; Plotnikova, J.; Willmann, M.R.; Chiu, W.-L.; Gomez-Gomez, L.; Boller, T.; Ausubel, F.M.; Sheen, J. MAP Kinase Signalling Cascade in Arabidopsis Innate Immunity. Nature 2002, 415, 977–983. [Google Scholar] [CrossRef] [PubMed]
  210. Hu, W.; Huang, C.; Deng, X.; Zhou, S.; Chen, L.; Li, Y.; Wang, C.; Ma, Z.; Yuan, Q.; Wang, Y.; et al. TaASR1, a Transcription Factor Gene in Wheat, Confers Drought Stress Tolerance in Transgenic Tobacco: The Role of TaASR1 in Drought Stress. Plant Cell Environ. 2013, 36, 1449–1464. [Google Scholar] [CrossRef] [PubMed]
  211. Kacperska, A. Sensor Types in Signal Transduction Pathways in Plant Cells Responding to Abiotic Stressors: Do They Depend on Stress Intensity? Physiol. Plant. 2004, 122, 159–168. [Google Scholar] [CrossRef]
  212. Liu, W.; Tai, H.; Li, S.; Gao, W.; Zhao, M.; Xie, C.; Li, W.-X. bHLH122 Is Important for Drought and Osmotic Stress Resistance in Arabidopsis and in the Repression of ABA Catabolism. New Phytol. 2014, 201, 1192–1204. [Google Scholar] [CrossRef]
  213. Ma, Y.; Dai, X.; Xu, Y.; Luo, W.; Zheng, X.; Zeng, D.; Pan, Y.; Lin, X.; Liu, H.; Zhang, D.; et al. COLD1 confers chilling tolerance in rice. Cell 2015, 160, 1209–1221. [Google Scholar] [CrossRef]
  214. Saibo, N.J.M.; Lourenço, T.; Oliveira, M.M. Transcription Factors and Regulation of Photosynthetic and Related Metabolism under Environmental Stresses. Ann. Bot. 2009, 103, 609–623. [Google Scholar] [CrossRef]
  215. Swarbreck, S.M.; Colaço, R.; Davies, J.M. Plant calcium-permeable channels. Plant Physiol. 2013, 163, 514–522. [Google Scholar] [CrossRef]
  216. Torres, M.A.; Dangl, J.L. Functions of the Respiratory Burst Oxidase in Biotic Interactions, Abiotic Stress and Development. Curr. Opin. Plant Biol. 2005, 8, 397–403. [Google Scholar] [CrossRef] [PubMed]
  217. Sharoni, A.M.; Nuruzzaman, M.; Satoh, K. Gene Structures, Classification and Expression Models of the AP2/EREBP Transcription Factor Family in Rice. Plant Cell Physiol. 2011, 52, 344–360. [Google Scholar] [CrossRef]
  218. Riechmann, J.L.; Meyerowitz, E.M. The AP2/EREBP Family of Plant Transcription Factors. Biol. Chem. 1998, 379, 633–646. [Google Scholar]
  219. Banerjee, A.; Roychoudhury, A. WRKY Proteins: Signaling and Regulation of Expression during Abiotic Stress Responses. Sci. World J. 2015, 2015, 807560. [Google Scholar] [CrossRef]
  220. Rushton, P.J.; Somssich, I.E.; Ringler, P.; Shen, Q.J. WRKY Transcription Factors. Trends Plant Sci. 2010, 15, 247–258. [Google Scholar] [CrossRef]
  221. Wang, H.; Wang, H.; Shao, H.; Tang, X. Recent Advances in Utilizing Transcription Factors to Improve Plant Abiotic Stress Tolerance by Transgenic Technology. Front. Plant Sci. 2016, 7, 67. [Google Scholar] [CrossRef]
  222. Le, D.T.; Nishiyama, R.; Watanabe, Y.A. Genome-Wide Survey and Expression Analysis of the Plant-Specific NAC Transcription Factor Family in Soybean during Development and Dehydration Stress. DNA Res. 2011, 18, 263–276. [Google Scholar] [CrossRef]
  223. Nuruzzaman, M.; Manimekalai, R.; Sharoni, A.M. Genome-Wide Analysis of NAC Transcription Factor Family in Rice. Gene 2010, 465, 30–44. [Google Scholar] [CrossRef]
  224. Puranik, S.; Sahu, P.P.; Mandal, S.N. Comprehensive Genome-Wide Survey, Genomic Constitution and Expression Profiling of the NAC Transcription Factor Family in Foxtail Millet (Setaria italica L.). PLoS ONE 2013, 8, e64594. [Google Scholar] [CrossRef]
  225. Puranik, S.; Sahu, P.P.; Srivastava, P.S.; Prasad, M. NAC Proteins: Regulation and Role in Stress Tolerance. Trends Plant Sci. 2012, 17, 369–381. [Google Scholar] [CrossRef] [PubMed]
  226. Arif, M.; Jan, T.; Riaz, M.; Fahad, S.; Shakoor, M.B.; Amanullah; Rasul, F. Advances in Rice Research for Abiotic Stress Tolerance; Woodhead Publishing: Duxford, UK, 2019. [Google Scholar]
  227. Liang, C.; Liu, Y.; Li, Y.; Meng, Z.; Yan, R.; Zhu, T.; Wang, Y.; Kang, S.; Ali Abid, M.; Malik, W.; et al. Activation of ABA Receptors Gene GhPYL9-11A Is Positively Correlated with Cotton Drought Tolerance in Transgenic Arabidopsis. Front. Plant Sci. 2017, 8, 1453. [Google Scholar] [CrossRef] [PubMed]
  228. Roychoudhury, A.; Chakraborty, M. Biochemical and Molecular Basis of Varietal Difference in Plant Salt Tolerance. Annu. Rev. Res. Biol. 2013, 3, 422–454. [Google Scholar]
  229. Jakoby, M.; Weisshaar, B.; Dröge-Laser, W. bZIP Transcription Factors in Arabidopsis. Trends Plant Sci. 2002, 7, 106–111. [Google Scholar] [CrossRef] [PubMed]
  230. Nijhawan, A.; Jain, M.; Tyagi, A.K.; Khurana, J.P. Genomic Survey and Gene Expression Analysis of the Basic Leucine Zipper Transcription Factor Family in Rice. Plant Physiol. 2008, 146, 333. [Google Scholar] [CrossRef]
  231. Wei, K.A.; Chen, J.U.A.N.; Wang, Y.A. Genome-Wide Analysis of bZIP-Encoding Genes in Maize. DNA Res. 2012, 19, 463–476. [Google Scholar] [CrossRef] [PubMed]
  232. Hwang, I.; Manoharan, R.K.; Kang, J. Genome-Wide Identification and Characterization of bZIP Transcription Factors in Brassica Oleracea under Cold Stress. Biomed. Res. Int. 2016, 2016, 4376598. [Google Scholar] [CrossRef]
  233. Liu, X.; Chu, Z. Genome-Wide Evolutionary Characterization and Analysis of bZIP Transcription Factors and Their Expression Profiles in Response to Multiple Abiotic Stresses in Brachypodium Distachyon. BMC Genom. 2015, 16, 1–15. [Google Scholar] [CrossRef]
  234. Chen, Z.; Yuan, Y.; Fu, D.; Shen, C.; Yang, Y. Identification and Expression Profiling of the Auxin Response Factors in Dendrobium Officinale under Abiotic Stresses. Int. J. Mol. Sci. 2017, 18, 927. [Google Scholar] [CrossRef]
  235. Hamzah Saleem, M.; Usman, K.; Rizwan, M.; Al Jabri, H.; Alsafran, M. Functions and Strategies for Enhancing Zinc Availability in Plants for Sustainable Agriculture. Front. Plant Sci. 2022, 13, 1033092. [Google Scholar] [CrossRef]
  236. Zafar, H.; Ali, A.; Ali, J.S.; Haq, I.U.; Zia, M. Effect of ZnO nanoparticles on Brassica nigra seedlings and stem explants: Growth dynamics and antioxidative response. Front. Plant Sci. 2016, 7, 535. [Google Scholar] [CrossRef] [PubMed]
  237. Fageria, V.D. Nutrient Interactions in Crop Plants. J. Plant Nutr. 2001, 24, 1269–1290. [Google Scholar] [CrossRef]
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Figure 1. Detrimental effects of salt stress on several plant stages [17]. The image of the maize crop is just an example.
Figure 1. Detrimental effects of salt stress on several plant stages [17]. The image of the maize crop is just an example.
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Figure 2. Illustration of different mechanisms that are adapted by the plants against salt stress.
Figure 2. Illustration of different mechanisms that are adapted by the plants against salt stress.
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Figure 3. Formation of hazardous ROS under salt-stress conditions.
Figure 3. Formation of hazardous ROS under salt-stress conditions.
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Figure 4. Illustration of proposed know-how of NPs in boosting the antioxidant enzymes to enhance the salt-stressed plants overcoming the harmful effects of ROS. NPs = nanoparticles, OH = hydroxyl radical, H2O = water molecule, O2 = oxygen molecule, and H2O2 = hydrogen peroxide.
Figure 4. Illustration of proposed know-how of NPs in boosting the antioxidant enzymes to enhance the salt-stressed plants overcoming the harmful effects of ROS. NPs = nanoparticles, OH = hydroxyl radical, H2O = water molecule, O2 = oxygen molecule, and H2O2 = hydrogen peroxide.
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Figure 5. How engineered nanoparticles modify ecophysiological and molecular responses in salt-stressed plants [121]. The image of the maize crop is just an example.
Figure 5. How engineered nanoparticles modify ecophysiological and molecular responses in salt-stressed plants [121]. The image of the maize crop is just an example.
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Figure 6. Modeling of signal perception, signal transduction, and gene expression and how the plant responds to salt stress. ROS = reactive oxygen species, PKs = protein kinases, PPs = protein phosphatases, Ca2+ = calcium ions, MAPK = mitogen-activated protein kinase.
Figure 6. Modeling of signal perception, signal transduction, and gene expression and how the plant responds to salt stress. ROS = reactive oxygen species, PKs = protein kinases, PPs = protein phosphatases, Ca2+ = calcium ions, MAPK = mitogen-activated protein kinase.
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Figure 7. Modeling of signal perception, signal transduction, gene expression, and plant response to salinity stress. The image of the maize crop is just an example.
Figure 7. Modeling of signal perception, signal transduction, gene expression, and plant response to salinity stress. The image of the maize crop is just an example.
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Figure 8. Different types of salt-stress-inducible gene products. CDPK = calcium-dependent protein kinase, CIPK = calcineurin-B-like interacting protein kinase, MAPK = mitogen adenosine protein kinase, LEA = late embryogenesis-abundant proteins, SOD = superoxide dismutase, CAT = catalase, APX = ascorbate peroxidase, POX = peroxidase, GPX = glutathione peroxidase, GRX = glutathione reductase, GOX = glutathione oxidase, PLC = phospholipase C, and PIP5k = phosphatidylinositol 4-phosphate 5-kinase, DREB = dehydration-responsive element-binding protein, and ABA = abscisic acid, bZIP, MYB, and NAC = groups of transcription factors to bind to DNA.
Figure 8. Different types of salt-stress-inducible gene products. CDPK = calcium-dependent protein kinase, CIPK = calcineurin-B-like interacting protein kinase, MAPK = mitogen adenosine protein kinase, LEA = late embryogenesis-abundant proteins, SOD = superoxide dismutase, CAT = catalase, APX = ascorbate peroxidase, POX = peroxidase, GPX = glutathione peroxidase, GRX = glutathione reductase, GOX = glutathione oxidase, PLC = phospholipase C, and PIP5k = phosphatidylinositol 4-phosphate 5-kinase, DREB = dehydration-responsive element-binding protein, and ABA = abscisic acid, bZIP, MYB, and NAC = groups of transcription factors to bind to DNA.
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Table 1. Investigating the adaptability of certain plant species to salt stress by utilizing zinc oxide nanoparticles (ZnO-NPs) [121].
Table 1. Investigating the adaptability of certain plant species to salt stress by utilizing zinc oxide nanoparticles (ZnO-NPs) [121].
Zinc oxide nanoparticles (ZnO-NPs)Characters (Size ~nm)PlantMode of ApplicationMorphophysiological ResponsesReferences
Spherical and hexagonal (~20 nm), Spherical (80), Spherical (30), or Hexagonal, Square, and Spherical (2–64) [122,123,124,125,126].Sorghum bicolorHydroponics, silica sand, foliar fertilization, seed treatment (priming), and foliar spray [122,123,124,125,126].Reduction in ROS accumulation and lipid peroxidation, improved antioxidant defense system, nutrient absorption, and osmolytes accumulation, seedling development through the biosynthesis of pigments, osmotic protection, reduction of ROS accumulation, adjustment of antioxidant enzymes, and improvement of the nutrient absorption, upregulation of the chilling-induced gene expression of the antioxidant system and chilling-response transcription factors, or reduced MDA content and the elevated level of antioxidant enzyme activities.[127]
Tomato (variety PKM-1)[128]
Soybean (cv. Giza111)[129]
Glycine max L.[130]
Rapeseed (Okapi cultivar)[131]
Brassica napus L.[132]
Triticum aestivum L.[133]
Zea mays[134]
Table 2. Observed transcriptional genes that exclusively augment salinity stress response in numerous plant species [150].
Table 2. Observed transcriptional genes that exclusively augment salinity stress response in numerous plant species [150].
FamilyGenesEnhanced ToleranceReferences
AP2/EREBPThDREB, VrDREB2A, SsDREB, TaERF3, EaDREB2, LcERF054, LcDREB2, GmERF7, StDREB1, OsDREB2A, SbMYB15, OsMYB91, SRM1, SbMYB2, SbMYB7, TaMYB3R1, TaMYB19-B, OsMYB48–1, MdSIMYB1, SpMYB, MdoMYB121, OsMYB2, TaMYB73, TaMYB33, and AtMYB15Mainly salinity, and they may be involved in drought, NaCl, mannitol, ABA, or cold.[151,152,153,154,155,156,157,158,159,160,161,162,163,164,165,166,167,168,169,170,171,172,173,174].
WRKYJcWRKY, MtWRKY76, GhWRKY25, GhWRKY41, GhWRKY68, SpWRKY1, TaWRKY93, TaWRKY44, GhWRKY34, TaWRKY10, ThWRKY4, TaWRKY2, TaWRKY19, OsWRKY08, and OsWRKY45Mainly salinity, and they may be involved in drought or cold[175,176,177,178,179,180,181,182,183,184,185,186].
NACVaNAC26, TaNAC47, MusaNAC042, EcNAC67, TaNAC2D, ONAC022, TaNAC29, OsNAC, TaNAC67, SNAC1, GmNAC20, GmNAC11, and ONAC063Mainly salinity, and they may be involved in drought or cold[187,188,189,190,191,192,193,194,195,196,197,198].
bZIPGhABF2, AtABF3, TabZIP60, OsbZIP71, LrbZIP, ZmbZIP72, ABP9, GmbZIP1, and OsbZIP23Mainly salinity, and they may be involved in drought or cold[199,200,201,202,203,204,205,206,207].
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Ahmed, M.; Tóth, Z.; Decsi, K. The Impact of Salinity on Crop Yields and the Confrontational Behavior of Transcriptional Regulators, Nanoparticles, and Antioxidant Defensive Mechanisms under Stressful Conditions: A Review. Int. J. Mol. Sci. 2024, 25, 2654. https://doi.org/10.3390/ijms25052654

AMA Style

Ahmed M, Tóth Z, Decsi K. The Impact of Salinity on Crop Yields and the Confrontational Behavior of Transcriptional Regulators, Nanoparticles, and Antioxidant Defensive Mechanisms under Stressful Conditions: A Review. International Journal of Molecular Sciences. 2024; 25(5):2654. https://doi.org/10.3390/ijms25052654

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Ahmed, Mostafa, Zoltán Tóth, and Kincső Decsi. 2024. "The Impact of Salinity on Crop Yields and the Confrontational Behavior of Transcriptional Regulators, Nanoparticles, and Antioxidant Defensive Mechanisms under Stressful Conditions: A Review" International Journal of Molecular Sciences 25, no. 5: 2654. https://doi.org/10.3390/ijms25052654

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