Abstract
In natural environment, plants are subjected to encounter various kinds of abiotic stresses. Drought stress is the inevitable factor that onsets without the identification of any borders or without any warning. It is the most significant environmental stress brought on by fluctuations in temperature, light intensity, and low rainfall. It deteriorates plant biomass production, quality, and energy, leading to adverse effects on the growth and production of plants. Abiotic stress causes physical damage, physiological and biochemical disruptions, and molecular changes. Depending on the species, plants have developed a variety of intricate resistance and adaptive mechanisms, including physiological and biochemical responses, to deal with this stress. Plants have acquired a variety of strategies to deal with drought stress, including altered stomatal conductance and distribution, altered growth pattern and structural dynamics, reduced transpiration loss, increased root length, accumulation of compatible solutes, increased transpiration efficiency, osmotic and hormonal regulation, and delayed senescence. Breeding strategies, molecular and genomics perspectives, emphasizing the alteration of omics technology metabolomics, proteomics, genomics, transcriptomics, genomics, and phenomics that improve plant stress tolerance, and marker-assisted selections are the major drought stress alleviation measures. Additionally, CRISPR-Cas method has opened up new dimensions and promises in developing drought tolerant plants. In the present chapter, the evidence on plant responses to drought stresses are explained and their possible defense measures are discussed.
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10.1 Introduction
During the growth and development phase, plants inevitably face several stresses which may be due to agricultural and natural conditions. Among all the stresses the plants face, drought is one of the most severe environmental stresses affecting the plants’ productivity and growth. The plant body mass comprises about 80–95% of water which plays an important role in several physiological processes (Abbasi and Abbasi 2010; Brodersen et al. 2019). Due to the rapid growth in population and increasing demand for food, drought stress has become problematic in the field of agriculture (O’Connell 2017). Drought condition is very unpredictable, it depends on various factors such as water holding capacity around the rhizosphere, uneven distribution of rainfall, and evapotranspiration, while in some cases it has been found that plants are not able to uptake water from the soil, even there is enough moisture present near the root zone (Seleiman et al. 2021). Such a phenomenon is called physiological or pseudo-drought (Salehi-Lisar and Bakhshayeshan-Agdam 2020). When plants face such evolving conditions, it becomes necessary to enhance the ability of plants to withstand drought. In order to improve water-use efficiency, mere physical adaptations of roots and leaves may prove insufficient. This is where molecular signals come into play, particularly a specific gene encoding regulatory proteins that govern the expression of numerous other genes. These molecular signals engage in crosstalk through various regulatory mechanisms, enabling the plant to respond effectively to drought conditions (Shahid et al. 2020; Yadav et al. 2020). Here, the fundamental reactions of agricultural plants to drought stress are addressed, as well as the management strategies are discussed which can be followed in order to reduce the negative consequences of this abiotic stress.
10.2 Environmental Factors Responsible for Drought Stress in Plants
The ongoing increase in air temperature and atmospheric CO2 levels is anticipated to intensify global climate change, leading to significant alterations in rainfall patterns and distribution (Yang et al. 2019; Yin et al. 2018). While insufficient rainfall is typically the primary factor contributing to drought stress, the situation can be exacerbated by the evaporation of water from soils. This evaporation is primarily influenced by high temperatures, intense light, and dry winds, and it can intensify an ongoing drought event (Cohen et al. 2021). The effects of global climate change often led to widespread drought stress across large regions on a global level. In addition to drought, salinity stress is also recognized as a major factor contributing to water deficits in plants (Adnan et al. 2020; Mostofa et al. 2018; Tariq et al. 2020). There are several factors that are responsible for drought stress in plants.
10.2.1 Global Warming
Certain consequences arising from climate change may have positive impacts on agricultural productivity. One such example is the potential increase in photosynthesis rates observed under elevated CO2 levels. Consequently, the higher concentrations of CO2 in the atmosphere could potentially enhance grain yields in the future (Brown et al. 2018). Usually, climate change brings about adverse consequences for both natural and agricultural ecosystems. Rising air temperatures can lead to the melting of glaciers, which in turn poses a risk of flooding agricultural lands, particularly those with low or negligible slopes (Cook et al. 2014). Furthermore, the diminishing glaciers are resulting in the reduction of water reservoirs, thereby restricting the availability of water for crops. This trend is progressively worsening over time. In fact, numerous rain-fed agricultural regions worldwide have been experiencing reduction in annual accumulated precipitation because of global warming (Sultan et al. 2019). The impact of global warming extends beyond water loss in the soil, affecting water loss at the plant level as well. Increased temperatures resulting from global warming led to significant transpiration of internal water within plants, intensifying the pre-existing water deficit challenges in diverse agricultural systems worldwide. If the anticipated rise in air temperature reaches approximately 2 degrees Celsius above present levels by the end of this century, an estimated one-fifth of the global population will face severe water deficits, highlighting the extensive impact of such conditions (Ray et al. 2019).
10.2.2 Irregular Rainfall
Areas reliant solely on rainfall for crop production are anticipated to face greater stress compared to regions that have access to irrigation systems such as canals and rivers. In rain-fed areas, drought episodes are closely linked to the distribution of rainfall throughout the year, leading to heightened risks of water stress occurring periodically over specific timeframes (Konapala et al. 2020). The prominent human activities of industrialization, deforestation, and urbanization have significant impacts on rainfall patterns, thereby influencing the availability of water to plants. These activities play a role in climate change, ultimately affecting the overall water availability for plant growth and development (Fatima et al. 2020). During the summer season, various factors contribute to the exacerbation of drought stress on plant growth and development. These include increased atmospheric water demand by plants, higher rates of evaporation and transpiration, and reduced availability of rainfall. The distribution and intensity of rainfall within and across years significantly influence both the management of water resources for plants and the occurrence of drought stress in most scenarios (Karandish and Šimůnek 2017; Seleiman et al. 2021).
10.2.3 Change in Monsoon Patterns
In numerous regions across the world, the monsoon system serves as a crucial source of rainfall, particularly during the summer season. The occurrence of the monsoon is closely tied to temperature, as it acts as the primary driving force behind its formation and dynamics (Ali and Anjum 2016). If current conditions persist, it is anticipated that rain-fed areas will experience a substantial decline of approximately 70% in summer precipitation levels by the beginning of the twenty-second century (Yu et al. 2013). Estimations suggest that the linear rise in atmospheric CO2 concentration will contribute to increased rainfall, posing adverse effects on crop production. This rise in rainfall levels is anticipated to result in widespread flooding and significant economic losses within the agriculture sector of densely populated countries (Guo et al. 2015; Reddy 2015). In such scenarios, the variability in monsoon rainfall plays a crucial role and will continue to influence the moisture levels of the rhizosphere. This, in turn, significantly impacts plant productivity in specific regions of the world, primarily through changes in the intensity, occurrence, and duration of rainfall. Notably, the shifts in monsoon patterns have led to extreme variations between dry and wet seasonal rainfalls, resulting in significant food insecurity for approximately two-thirds of the global population (Prakash et al. 2020). In addition to the inherently random and unpredictable nature of rainfall patterns, recent climate changes have further contributed to the potential shortening or lengthening of the rainy season. This variability can exacerbate existing and future scenarios, leading to challenges of both water deficit and water excess in certain climatic zones. Given the agricultural context, it is imperative to adapt crop production practices to align with the behavior of the monsoon season and transition towards sustainable crop production methods. Implementing proper management techniques and effective crop planning are two key strategies to address the quantitative shifts experienced during monsoon patterns, whether they involve water deficiency or excessive rainfall (Seleiman et al. 2021).
10.3 Impact of Drought Stress on Plants
Plants that are under drought stress may experience severe effects on their growth, development, and overall health. The plant undergoes changes such as reduction in turgor pressure, closure of stomata during the day, disruption of water potential gradients, change in membrane integrity, leaf rolling, and a decrease in cell development and growth, which are vital for maintaining life processes (Zargar et al. 2017). The drought stress affecting the plant is briefly mentioned and is shown in Fig. 10.1: water deficiency, reduced photosynthesis, stomatal closure, oxidative stress, nutrient imbalance, reduced growth and development, increased susceptibility to diseases and pests, stem extension, and root proliferation (Fig. 10.1).
10.3.1 Water Deficiency
Water scarcity is a major environmental barrier to plant growth and development. The most obvious effect of drought stress is the limited availability of water in the soil. Water is necessary for several physiological functions of plants, such as photosynthesis, nitrogen intake, and transpiration. Drought stress leads to water deficit in plant tissues, disrupting these essential processes. Water scarcity outbreaks are due to the occurrence of less or the absence of rainfall resulting in low soil moisture content and low water potential in aerial parts of the plant such as leaves and stems (Ristvey et al. 2019). In arid environments, the rate at which water is lost by transpiration from leaves outpaces the rate at which water is absorbed by roots. Seed germination is one of the most important phases in the life cycle of a plant, and is highly responsive to its existing surrounding environment (Bahrami et al. 2012). For the success or failure of plant establishment in soil, the prime requirement for germination is the presence of water (Hasanuzzaman et al. 2013).
10.3.2 Reduced Photosynthesis
Photosynthesis is one of the main processes affected by water stress. Leaf photosynthetic products are the material basis of plant growth. (Yang et al. 2021). Drought stress negatively affects photosynthesis, the process by which plants convert light energy into chemical energy. Insufficient water reduces the availability of CO2, leading to decreased photosynthetic rates. By lowering both leaf area and photosynthetic rate per unit leaf area, drought stress is known to limit photosynthesis. Continued photosynthetic light reactions during drought stress under limited intercellular CO2 concentration result in the accumulation of reduced photosynthetic electron transport components, which can potentially reduce molecular oxygen, resulting in the production of reactive oxygen species (Basu et al. 2016).
10.3.3 Stomatal Closure
Plants close their stomatal aperture as the first response at the onset of drought to maintain the leaf water potential (Laxa et al. 2019). To conserve water during drought, plants often close their stomata (small openings on the leaf surface that regulate gas exchange). Stomatal closure or metabolic impairment is the major cause of a decreased photosynthetic rate (Basu et al. 2016). Stomatal closure reduces the uptake of carbon dioxide (CO2) required for photosynthesis and limits the release of oxygen (O2). Stomatal closure limits leaf absorption of CO2 and prevents transpiration water loss due to turgor pressure and/or reduced water potential (Yang et al. 2021). This can significantly impair a plant’s ability to produce energy and growth. This results in reduced plant productivity, stunted growth, and decreased crop yields.
10.3.4 Oxidative Stress
Most abiotic stressors lead to an increase in ROS production. Reactive oxygen species (ROS) are frequently produced by various plant species growing under different conditions under drought stress (Hasanuzzaman et al. 2012; Hasanuzzaman et al. 2013). During normal circumstances, plants synthesize reactive oxygen species (ROS) as the by-product of different vital physiological phenomena such as photosynthesis and photorespiration (Corpas et al. 2020). These reactive species involved in cellular regulation, act as secondary messengers and as a signaling molecule for different metabolic pathways, including seed germination, senescence, plant growth and development (Gonzalez-Gordo et al. 2020) The production of dangerous ROS like O2*−, H2O2, 1O2, and OH* beyond the plant’s scavenging capacity and causing oxidative stress (Li et al. 2010). According to many researches, chloroplast photochemistry alterations result in an excessive synthesis of highly reactive ROS species (Hasanuzzaman et al. 2020). These detrimental ROSs that are produced cause damage to the cell's proteins, lipids, carbohydrates, and nucleic acids as well as alter cellular homeostasis, which can sometimes result in cell death. So, oxidative stress leads to disrupting normal cellular functioning, impairing plant growth and development.
10.3.5 Nutrient Imbalances
A nutritional imbalance can have an impact on several biological processes. Mineral nutrients help to synthesize vital organic molecules like amino acids and proteins in plants. Mineral uptake by plants is a very effective process due to the large surface area of the roots and their ability to absorb inorganic ions at low concentrations in the soil solution (da Silva et al. 2011). Drought stress affects nutrient uptake by plants. Water deficit situations usually reduce the overall soil nutrient accessibility, root nutrient translocation and ultimately lessen the ion contents in various plant tissues (Kheradmand et al. 2014). The decline in the K was attributable to reduced K mobility, declined transpiration rate, and weakened action of root membrane transporters (Hu and Schmidhalter 2005; Hu et al. 2013.) The stomatal guard cells experience an ionic imbalance between K+ , Cl, and H+ due to drought. This ionic imbalance dominates the turgor pressure in the guard cells, which subsequently controls the closing of the stomata. The strict regulation of stomatal conductance under water deficiency enables plants to minimize water loss through evaporation or transpiration (Mukarram et al. 2021). Nutrient imbalances can result in nutrient deficiencies or toxicities, thus further affecting plant health and productivity.
10.3.6 Reduced Growth and Development
Cell growth is considered one of the most drought-sensitive physiological processes due to the reduction in turgor pressure (Anjum et al. 2011). Meristematic cell divisions produce daughter cells, and the resulting tremendous proliferation of the new cells is what leads to growth. Under severe water deficiency, cell elongation of higher plants can be inhibited by interruption of water flow from the xylem to the surrounding elongating cells. Drought stress causes impaired mitosis; inhibits cell expansion and division, leading to reduced plant growth (Taiz and Zeiger 2010). It affects the development of leaves, stems, and roots, resulting in smaller plant size, decreased biomass, and shorter root systems. In addition to reducing the production of flowers and fruits, drought stress can also result in early leaf senescence (yellowing and shedding).
10.3.7 Increased Susceptibility to Pests and Diseases
Plants are drought susceptible to secondary stresses including pests and pathogens. The impacts of these factors may lead to acute or chronic responses and hosts may respond in different ways in terms of time and space depending on the timing and strength of the stress. There are complex processes involved in tree performance and mortality, and often it can be difficult to identify the leading cause of growth decline and death (Whyte et al. 2016). Plants are less able to tolerate and recover from pest infestations and disease attacks because their defensive systems have been impaired, as well as their physiological processes.
10.4 Plant Response to Drought Stress
Plants in their natural environments respond to environmental drought stress in several ways, from temporary reactions to low soil moisture to significant survival strategies, such as early blooming in the absence of seasonal rainfall. The chart given below provides a brief about the responses involved in drought stress and the factors present in the plants which show response to the stress.
Plants exhibit a range of physiological, biochemical, morphological, and molecular level responses to drought stress are observed in plants. These responses collectively enable plants to survive and adapt to drought stress. By conserving water, adjusting their metabolism, and protecting cellular components, plants increase their chances of enduring water-limited conditions and resuming growth and development when water availability improves (Fig. 10.2).
10.4.1 Stomatal Regulation
The closing of stomata is one of the main reactions of plants to drought stress. In addition to allowing for the exchange of gases such as carbon dioxide and oxygen, stomata on the surface of leaves also permit the release of water vapor through transpiration. Plants have a complex signaling system to regulate stomatal opening mediated by the uptake and intracellular synthesis of solutes that reduces the water potential in guard cells and creates a driving force for water uptake (Zhao et al. 2018). To reduce the effects of the drought and prevent excessive transpiration water loss, the stomatal aperture must be dynamically regulated. Stomatal behavior plays a critical role during drought sensing and signaling, yet its modus operandi and crosstalk with other plant phenomena are complex and debatable (Golldack et al. 2014; Lawson and Matthews 2020). During drought, plants close their stomata to reduce water loss. This closure is mediated by hormonal signals, such as abscisic acid (ABA), which is produced in response to water stress.
10.4.2 Leaf Modifications
Plants experiencing drought stress often reduce their leaf area to minimize water loss through transpiration. This can occur through leaf abscission, where older leaves are shed, or through a decrease in leaf expansion and growth. By reducing the overall leaf surface area, plants can conserve water and maintain water balance more effectively. Plants may exhibit various leaf modifications to cope with drought stress. Some plants respond to drought stress by developing leaf pubescence, which is the presence of fine hairs or trichomes on the leaf surface. Trichomes create a layer of boundary air that reduces air movement and thus decreases transpiration rates. They also reflect sunlight, reducing leaf temperature and water loss through evaporation. To reduce water loss through transpiration, plants may exhibit leaf rolling or folding. This morphological response reduces the exposed leaf surface area and creates a protective microenvironment that reduces water loss. Leaf rolling can be observed in grasses, while leaf folding is seen in plants like legumes. Some plants have thick cuticles, which are waxy layers on the leaf surface that reduce water loss through transpiration. Others have smaller or fewer leaves, which helps to decrease the overall surface area for transpiration. In extreme cases, plants may shed their leaves entirely (deciduous plants) to conserve water.
10.4.3 Root Adaptations
The root system detects drought stress first. Even though under these circumstances shoot development is impeded, it continues to grow beneath the earth. Although the growth of the primary root is not affected by drought stress, the growth of lateral roots is significantly reduced, mainly by suppression of the activation of the lateral root meristems (Hasanuzzaman et al. 2013). Plants respond to drought stress by altering their root growth and architecture. They might extend their current roots or create deeper, taproot-like structures to delve deeper into the earth in quest of water. This makes it possible for plants to utilize water supplies that are not present close to the soil surface. Additionally, plants may increase the density of root hairs, which are small outgrowths on the root surface that enhance water absorption.
10.4.4 Antioxidant Production
Drought stress often leads to the generation of reactive oxygen species (ROS), which can cause oxidative damage to plant cells. The well-known antioxidant enzymes in plants include glutathione reductase (GR), monodehydroascorbate reductase (MDHAR), dehydroascorbate reductase (DHAR), glutathione peroxidase (GPX), guaiacol peroxidase (GOPX), glutathione-S-transferase (GST), superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX), glutathione reductase (GR), monodehydroascorbate reductase (MDHAR), dehydroascorbate reductase (DHAR), glutathione peroxidase (GPX), guaiacol peroxidase (GOPX), glutathione-S-transferase (GST), and so on (Gill and Tuteja 2010). These are divided into enzymatic and non-enzymatic defense systems that function together to control the flow of uncontrolled oxidation under various stress conditions and protect plant cells from oxidative damage by scavenging ROS (Hasanuzzaman et al. 2013). Production of these antioxidants in plants, scavenge ROS and protect cells from oxidative stress.
10.4.5 Osmotic Adjustments (OA)
Osmotic adjustment is a mechanism to maintain water relations under osmotic stress. Drought stress can cause cellular dehydration due to water loss. OA has been linked to sustaining stomatal conductance, photosynthesis, leaf water volume, and growth during drought stress. In response, plants may accumulate osmolytes, such as sugars, amino acids, and proline, which help maintain cellular hydration and protect proteins and membranes (Farooq et al. 2009). These osmolytes increase the osmotic potential of cells, allowing them to retain water and prevent damage.
10.4.6 Hormonal Regulations
Plant hormones play a crucial role in regulating plant responses to drought stress. Major phytohormones, such as abscisic acid (ABA), cytokinin (CK), gibberellic acid (GA), auxin, and ethylene, regulate diverse processes which enable plant adaptation to drought stress (Wilkinson et al. 2012). These hormones regulate a range of physiological and biochemical changes in plants, including stomatal closure, root development, and the activation of genes that respond to stress. The net outcome of the drought stress response is regulated by a balance between hormones that promote and those that inhibit the trait, rather than the individual action of the hormones (Basu et al. 2016).
10.5 Molecular Methods to Mitigate the Adverse Effect of Drought Stress
Drought stress is an inescapable factor that crosses boundaries and has a negative impact on plant growth, quality, and energy production. It is a substantial environmental stress induced by temperature fluctuations, light intensity, and a lack of rainfall. It is a complicated process that drastically modifies many aspects of plants, including their physical structure, functioning, chemical composition, and molecular features, resulting in a reduction in their ability to perform photosynthesis. Vegetation has developed complicated strategies to withstand and adjust to water deprivation, requiring species-specific anatomical and biochemical reactions (Seleiman et al. 2021).
Researchers are particularly interested in using microbes, hydrogels, nanoparticles, and metabolic engineering techniques to improve plants’ drought tolerance. These measures include techniques such as controlling antioxidant enzyme activity, maintaining cellular homeostasis, and minimizing the negative effects of water stress. The goal is to increase plant resilience to drought conditions and lessen the negative effects of water scarcity (Seleiman et al. 2021).
By implementing optimal management practices for planting timing, plant density, plant types, and soil and nutrient management, yield losses in field crops exposed to drought stress can be effectively reduced (Parry et al. 2005; Adeyemi et al. 2020). However, as a notable technique for relieving drought stress, the use of genetically engineered plants possessing drought-tolerant characteristics has attracted substantial attention. Drought-tolerant plants are being developed using a variety of methodologies, including classic breeding techniques, and molecular and genomic approaches (Oliveira et al. 2020), where efforts are primarily focused on boosting water extraction efficiency, water consumption efficiency, stomatal conductance, osmotic adjustments, and other features with the objective of improving the plant’s ability to endure drought conditions (Naeem et al. 2020). Other techniques include the use of contemporary and more efficient irrigation technologies, proper planting practices, mulching, contouring, the use of osmoprotectants, and the inoculation of plants with specific microbes proven to improve drought tolerance (Solis et al. 2018).
10.5.1 Selection and Breeding Strategies
Until now, traditional breeding procedures have depended on empirical selection based on yield (Galaitsi et al. 2016). The quantitative trait of yield in key staple crops is predominantly impacted by low heritability and considerable genotype-environment interaction (Scopel et al. 2013). As a result, conventional breeding practices are currently being used to increase production (Aslam et al. 2015). Understanding plant physiological processes is required for identifying quantitative trait loci, locating gene sequences, and breeding in quantitative trait loci (Medici et al. 2014). Due to the irregular, unstable, and unpredictable character of drought response, screening for resistant cultivars under open conditions is not practical. However, such screening can be carried out in shielded and/or regulated situations (Ali et al. 2017).
Classical breeding, on the other hand, refers to the effective method of evaluating randomly selected progenies for better drought resistance across varied habitats (Araujo et al. 2015). Under normal conditions, cultivars with low transpiration rates and unchanged water use efficiency (WUE) have little effect on the final yield (Tejero et al. 2018). As part of their examination, researchers are currently conducting genetic analyses of root architecture, relative water content, and osmotic potential (Bertolino et al. 2019). It is critical to prioritize yield-contributing traits with high heredity that affect grain output under drought conditions, even if they do not have the same effect under ideal conditions. This prioritization is based on the ease with which these attributes may be measured (Shavrukov et al. 2017). However, in agricultural systems with restricted water supply, these variables exhibit broad-sense heritability for yield and frequently do not interact with grain production (Curin et al. 2020). In cases of drought stress, the first and most important element that emerges is a decrease in water use efficiency (WUE), which might vary between types and cultivars (Vishwakarma et al. 2017). In such cases, plants respond by reducing the number of stomata and the size of their leaves, which aids in minimizing water loss and maintaining internal water balance (Ding et al. 2021). As a result, certain genotypes and cultivars are susceptible to drought and are unable to adjust to environmental conditions, resulting in low Water Use Efficiency (WUE) (Tardieu et al. 2018). As a result, using a breeding strategy can help to improve WUE, ultimately boosting sustainable agricultural productivity by itemizing biomass produced per unit of water used (Fang and Xiong 2015).
Drought resistance in crop species can be accomplished directly or indirectly through trait genetic diversity, which allows for improvement through selective breeding. Marker-assisted selection (MAS) and genomic selection (GS) are the two basic methodologies used in genomic-assisted breeding. The initial stage in MAS is to find molecular markers linked to the target trait, which is required for selection in breeding programs. GS, on the other hand, is based on the building of selection models based on genetic markers found throughout the genome, as well as the selection of genome-estimated breeding values (GEBVs) in breeding populations via phenotyping the training population. For several decades, MAS has been an important component of many crop breeding programs, whereas GS is a relatively new technology that has just recently been applied to crops (Seleiman et al. 2021).
Molecular markers contribute to marker-assisted selection (MAS) by being situated near quantitative trait loci (QTL) or specific genes linked to a certain target trait. These indicators can be used to identify people who have favorable alleles (Varshney et al. 2014). Using accurate and reliable trait evaluations and a dense set of molecular markers, QTL mapping or genome-wide association techniques are used to choose markers that are related to traits. These approaches have been used to find QTLs linked to drought resilience in a variety of crops, including wheat (Kollers et al. 2013), maize (Brown et al. 2011), sorghum (Huang et al. 2010), rice (Morris et al. 2012), soybean (Hwang et al. 2014), pearl millet (Bidinger et al. 2007) and many other crops.
Genomic Selection (GS) uses all available markers to pick elite lines from a population of genome-estimated breeding values (GEBVs), and GS models are used to select elite lines without the necessity for phenotyping. Unlike MAS, knowledge of QTLs is not required for GS (Nakaya and Isobe 2012). Nonetheless, genomic selection (GS) requires more marker data than marker-aided selection (MAS). This increased density is made possible by using low-cost genotyping technologies that cover markers across the entire genome (Hayes and Goddard 2001). The international maize and wheat improvement center (CIMMYT) is currently using GS in the development of drought-resistant maize (Crossa et al. 2014). Similar research efforts are underway in other crops such as sugarcane, legumes, and wheat, with the goal of implementing this strategy to improve drought tolerance (Gouy et al. 2013; Varshney et al. 2013; Rutkoski et al. 2010).
10.5.2 Molecular and Genomic Strategies
Biochemical and molecular components contribute to the initiation of mechanisms that mitigate the harmful consequences of water stress. Transcription, stress-responsive genes (as indicated in Table 10.1), and the hormone abscisic acid are among these variables (Osakabe et al. 2020). In addition to improving drought resistance, breeding programs aim to improve stress management by introducing transgenic expression of several stress-responsive genes (Rai and Rai 2020; Liu et al. 2020). However, overexpression of these genes frequently leads to a decrease in plant growth rate, limiting their practical application. To effectively address these difficulties, it is critical to continue to focus on the molecular and genetic basis of drought resilience (Hussain et al. 2018).
Genomic and related technology methods can aid in the identification of genes that ameliorate the effects of stress, allowing efforts to preserve and incorporate these genes into future breeding programs (Medina et al. 2016). Stress-tolerant genes work at the molecular level and interact with quantitative loci traits, emphasizing the need of studying their interactions and cloning stress-related genes (Nakashima et al. 2014). In the field of genetic engineering, it is commonly agreed that a combined approach including marker-based selection, molecular approaches, and traditional breeding is the most effective option for increasing plant tolerance to abiotic stress (Bhatnagar-Mathura et al. 2008; Cho and Hong 2006).
The clustered regularly interspaced short palindromic repeats and CRISPR-associated protein 9 (CRISPR–Cas) system of genome editing is a recently developed molecular technique which has been appreciated for its adaptability and ease of operation. CRISPR–Cas-based genome editing is applied in several economically important crops, including cotton, rice, wheat, maize, soybean, potato, and in biofuel crops (Sami et al. 2021; Tiwari et al. 2021)). CRISPR–Cas system has been proved useful in developing resistance to multiple abiotic environmental stresses, including salinity, drought, heavy metals etc. Different types of CRISPR/Cas technology have been successfully used to develop drought tolerance by altering genetic features in diverse plant species. By targeting certain agronomically relevant gene regulators, CRISPR–Cas could significantly improve plant tolerance to drought stress and is able to increase average crop production. For example, it was shown that the maize variants modified using CRISPR method were found to be more tolerant towards drought (Shi et al. 2017). Other such experiments also showed that CRISPR–Cas9 method can be effectively implemented to induce novel allelic modifications for developing drought-tolerant crop varieties. However, relatively few studies have explored the application of CRISPR–Cas-methods to improve crop tolerance of drought stress, compared to other abiotic stresses. The research gaps in development of genome-edited crops are the discovery of target genes, effective delivery of CRISPR machinery to the appropriate cells and regeneration of various crops. Particular attention should be given on drought stress response genes and drought stress-induced transcriptional networks to address the issue of target discovery (Joshi et al. 2020). Additionally, a thorough comparative genome-wide analysis can develop a solid baseline for further identification of the potential target genes in crops (Table 10.1).
10.6 Conclusion
Climate change has led to increased biotic and abiotic stresses, posing serious threats to global food security and plant production sustainability. Drought, an abiotic stress, is particularly concerning due to its adverse impact on plant growth, development, and yield, leading to food insecurity worldwide. Drought stress affects plants throughout their life cycle, from germination to maturity, and disrupts various physiological, metabolic, and biochemical processes, hampering plant productivity. However, plants have developed mechanisms to enhance drought tolerance and mitigate its adverse effects.
To address the challenges posed by drought stress, it is essential to explore untapped adaptive traits in different plant species and incorporate them into genotypes that can tolerate water scarcity without compromising productivity. Breeding technologies offer great potential for improving plant performance under water deficit conditions, and various approaches are being explored for drought adaptation in arid and semi-arid environments. Several strategies can be employed by plants to enhance drought tolerance, including modifying growth patterns, reducing transpiration loss through stomatal conductance alteration and distribution, leaf rolling, adjusting root-to-shoot ratio dynamics, increasing root length increment, accumulating compatible solutes, improving transpiration efficiency, regulating osmotic and hormonal responses, and delaying senescence. To overcome the adverse effects of drought stress, researchers need to work further on developing some innovative methods like changes in breeding strategies, alterations in omics technology or novel approaches related to CRISPR/Cas through which a better understanding can be developed about plant responses to drought stress. This can further potentially increase plant productivity in dry environments, and thus can reduce the threats to global food security.
References
Abbasi T, Abbasi SA (2010) Biomass energy and the environmental impacts associated with its production and utilization. Renew Sustain Energy Rev 14(3):919–937. https://doi.org/10.1016/j.rser.2009.11.006
Adeyemi O, Keshavarz-Afshar R, Jahanzad E, Battaglia ML, Luo Y, Sadeghpour A (2020) Effect of wheat cover crop and split nitrogen application on corn yield and nitrogen use efficiency. Agronomy
Adnan M, Fahad S, Zamin M, Shah S, Mian IA, Danish S, Zafar-ul-Hye M, Battaglia ML, Naz RMM, Saeed B, Saud S, Ahmad I, Yue Z, Brtnicky M, Holatko J, Datta R (2020) Coupling phosphate-solubilizing bacteria with phosphorus supplements improve maize phosphorus acquisition and growth under lime induced salinity stress. Plants 9(7). https://doi.org/10.3390/plants9070900
Aharoni A, Dixit S, Jetter R, Thoenes E, Van Arkel G, Pereira A (2004) The SHINE clade of AP2 domain transcription factors activates wax biosynthesis, alters cuticle properties, and confers drought tolerance when overexpressed in Arabidopsis. Plant Cell 16(9):2463–2480
Ali N, Anjum MM (2016) Drought stress: major cause of low yield and productivity. Austin Environ Sci 1:10–12
Ali F, Ahsan M, Ali Q, Kanwal N (2017) Phenotypic stability of Zea mays grain yield and its attributing traits under drought stress. Front Plant Sci 8
Anjum SA, Xie X, Wang LC, Saleem MF, Man C, Lei W (2011) Morphological, physiological and biochemical responses of plants to drought stress. Afr J Agric Res 6(9):2026–2032
Araujo SS, Beebe S, Crespi M, Delbreil B, Gonzalez EM, Gruber V, Lejeune-Henaut I, Link W, Monteros MJ, Prats E (2015) Abiotic stress responses in legumes: strategies used to cope with environmental challenges. Crit Rev Plant Sci 34:237–280
Aslam M, Maqbool MA, Cengiz R (2015) Drought stress in maize (Zea mays L.) effects, resistance mechanisms, global achievements and biological strategies for improvement. Springer, Berlin/Heidelberg, Germany
Bahrami H, Razmjoo J, Jafari AO (2012) Effect of drought stress on germination and seedling growth of sesame cultivars (Sesamum indicum L.). Int J AgriSci 2(5):423–428
Basu S, Ramegowda V, Kumar A, Pereira A (2016) Plant adaptation to drought stress [version 1; referees: 3 approved]. F1000Research 5:1–10
Bertolino LT, Caine RS, Gray JE (2019) Impact of stomatal density and morphology on water-use efficiency in a changing world. Front Plant Sci 10:225
Bhatnagar-Mathur P, Vadez V, Sharma KK (2008) Transgenic approaches for abiotic stress tolerance in plants: retrospect and prospects. Plant Cell Rep 27:411–424
Bidinger FR, Nepolean T, Hash CT, Yadav RS, Howarth CJ (2007) Quantitative trait loci for grain yield in pearl millet under variable post-flowering moisture conditions. Crop Sci 47:969–980
Brodersen CR, Roddy AB, Wason JW, McElrone AJ (2019) Functional status of xylem through time. Annu Rev Plant Biol 70(1):407–433. https://doi.org/10.1146/annurev-arplant-050718-100455
Brown PJ, Upadyayula N, Mahone GS, Tian F, Bradbury PJ, Myles S, Holland JB, Flint-Garcia S, McMullen MD, Buckler ES (2011) Distinct genetic architectures for male and female inflorescence traits of maize. PLoS Genet 7
Brown S, Nicholls RJ, Lázár AN, Hornby DD, Hill C, Hazra S, Appeaning Addo K, Haque A, Caesar J, Tompkins EL (2018) What are the implications of sea-level rise for a 1.5, 2 and 3 °C rise in global mean temperatures in the Ganges-Brahmaputra-Meghna and other vulnerable deltas? Reg Environ Change 18(6):1829–1842. https://doi.org/10.1007/s10113-018-1311-0
Cho EK, Hong CB (2006) Over-expression of tobacco NtHSP70-1 contributes to drought-stress tolerance in plants. Plant Cell Rep 25:349–358
Cohen I, Zandalinas SI, Huck C, Fritschi FB, Mittler R (2021) Meta-analysis of drought and heat stress combination impact on crop yield and yield components. Physiol Plant 171(1):66–76. https://doi.org/10.1111/ppl.13203
Cook BI, Smerdon JE, Seager R, Coats S (2014) Global warming and 21st century drying. Clim Dyn 43(9):2607–2627. https://doi.org/10.1007/s00382-014-2075-y
Corpas FJ, González-Gordo S, Palma JM (2020) Plant peroxisomes: a factory of reactive species. Front Plant Sci 11:853
Crossa J, Perez PEO, Hickey J, Burgueno J, Ornella L, Ceronrojas JJ, Zhang X, Dreisigacker S, Babu R, Li Y (2014) Genomic prediction in CIMMYT maize and wheat breeding programs. Heredity 112:48–60
Curin F, Severini AD, González FG, Otegui ME (2020) Water and radiation use efficiencies in maize: breeding effects on single-cross Argentine hybrids released between 1980 and 2012. Field Crop Res 246:107–683
da Silva EC, Nogueira RJMC, da Silva MA, de Albuquerque MB (2011) Drought stress and plant nutrition. Plant Stress 5(1):32–41
Ding Z, Ali EF, Elmahdy AM, Ragab KE, Seleiman MF, Kheir AMS (2021) Modeling the combined impacts of deficit irrigation, rising temperature and compost application on wheat yield and water productivity. Agric Water Manag 244
El-Esawi MA, Alayafi AA (2019) Overexpression of StDREB2 transcription factor enhances drought stress tolerance in cotton (Gossypium barbadense L.), Genes 10(2):142
Fang Y, Xiong L (2015) General mechanisms of drought response and their application in drought resistance improvement in plants. Cell Mol Life Sci 72:673–689
Farooq M, Wahid A, Kobayashi NSMA, Fujita DBSMA, Basra SMA (2009) Plant drought stress: effects, mechanisms and management. Sustain Agric 153–188
Fatima A, Farid M, Safdar K, Fayyaz A, Ali SM, Adnan S, Zubair M (2020) Loss of agro-biodiversity and productivity due to climate change in continent Asia: a review. In: Plant ecophysiology and adaptation under climate change: mechanisms and perspectives. Springer, pp 51–71
Galaitsi SE, Russell R, Bishara A, Durant JL, Bogle J, Huber-Lee A (2016) Intermittent domestic water supply: a critical review and analysis of causal-consequential pathways. Water 8:274
Gill SS, Tuteja N (2010) Reactive oxygen species and antioxidant machinery in abiotic stress tolerance in crop plants. Plant Physiol Biochem 48(12):909–930
Golldack D, Li C, Mohan H, Probst N (2014) Tolerance to drought and salt stress in plants: unraveling the signaling networks. Front Plant Sci 5:81686. https://doi.org/10.3389/fpls.2014.00151
González-Gordo S, Rodríguez-Ruiz M, Palma JM, Corpas FJ (2020) Superoxide radical metabolism in sweet pepper (Capsicum annuum L.) fruits is regulated by ripening and by a NO-enriched environment. Front Plant Sci 11:485
Gouy M, Rousselle Y, Bastianelli D, LeComte P, Bonnal L, Roques D, Efile J-C, Rocher S, Daugrois J-H, Toubi L (2013) Experimental assessment of the accuracy of genomic selection in sugarcane. Theor Appl Genet 2575–2586
Guo H-D, Zhang L, Zhu L-W (2015) Earth observation big data for climate change research. Adv Clim Chang Res 6(2):108–117. https://doi.org/10.1016/j.accre.2015.09.007
Hasanuzzaman M, Bhuyan MB, Zulfiqar F, Raza A, Mohsin SM, Mahmud JA, Fotopoulos V (2020) Reactive oxygen species and antioxidant defense in plants under abiotic stress: revisiting the crucial role of a universal defense regulator. Antioxidants 9(8):681
Hasanuzzaman M, Hossain MA, da Silva JAT, Fujita M (2012) Plant response and tolerance to abiotic oxidative stress: antioxidant defense is a key factor. In: Crop stress and its management: perspectives and strategies. pp 261–315
Hasanuzzaman M, Nahar K, Gill SS, Fujita M (2013) Drought stress responses in plants, oxidative stress, and antioxidant defense. In: Climate change and plant abiotic stress tolerance. pp 209–250
Hayes BJ, Goddard ME (2001) Prediction of total genetic value using genome-wide dense marker maps. Genetics 157:1819–1829
Hu Y, Schmidhalter U (2005) Drought and salinity: a comparison of their effects on mineral nutrition of plants. J Plant Nutr Soil Sci 168(4):541–549
Hu L, Wang Z, Huang B (2013) Effects of cytokinin and potassium on stomatal and photosynthetic recovery of Kentucky bluegrass from drought stress. Crop Sci 53(1):221–231
Huang X, Wei X, Sang T, Zhao Q, Feng Q, Zhao Y, Li C, Zhu C, Lu T, Zhang Z (2010) Genome-wide association studies of 14 agronomic traits in rice landraces. Nat Genet 42:961–967
Hussain HA, Hussain S, Khaliq A, Ashraf U, Anjum SA, Men S, Wang L (2018) Chilling and drought stresses in crop plants: Implications, cross talk, and potential management opportunities. Front Plant Sci 9
Hwang E-Y, Song Q, Jia G, Specht JE, Hyten DL, Costa J, Cregan PB (2014) A genome-wide association study of seed protein and oil content in soybean. BMC Genom 15:1
Joshi RK, Bharat SS, Mishra R (2020) Engineering drought tolerance in plants through CRISPR/Cas genome editing. 3 Biotech 10(9):400. https://doi.org/10.1007/s13205-020-02390-3
Karandish F, Šimůnek J (2017) Two-dimensional modeling of nitrogen and water dynamics for various N-managed water-saving irrigation strategies using HYDRUS. Agric Water Manag 193:174–190. https://doi.org/10.1016/j.agwat.2017.07.023
Kheradmand MA, Fahraji SS, Fatahi E, Raoofi MM (2014) Effect of water stress on oil yield and some characteristics of Brassica napus. Int Res J Appl Basic Sci 8(9):1447–1453
Kollers S, Rodemann B, Ling J, Korzun V, Ebmeyer E, Argillier O, Hinze M, Plieske J, Kulosa D, Ganal MW (2013) Whole genome association mapping of Fusarium head blight resistance in European winter wheat (Triticum aestivum L.). PLoS ONE 22
Konapala G, Mishra AK, Wada Y, Mann ME (2020) Climate change will affect global water availability through compounding changes in seasonal precipitation and evaporation. Nat Commun 11(1):1–10. https://doi.org/10.1038/s41467-020-16757-w
Lawson T, Matthews J (2020) Guard cell metabolism and stomatal function. Annu Rev Plant Biol 29:273–302. https://doi.org/10.1146/annurev-arplant-050718-100251
Laxa M, Liebthal M, Telman W, Chibani K, Dietz KJ (2019) The role of the plant antioxidant system in drought tolerance. Antioxidants 8(4):94
Li L, Du Y, He C, Dietrich CR, Li J, Ma X, Wang R, Liu Q, Liu S, Wang G, Schnable PS (2019) Maize glossy6 is involved in cuticular wax deposition and drought tolerance. J Exp Bot 70(12):3089–3099
Li CH, Li Y, Wuyun TN, Wu GL, Jiang GM (2010) Effects of high concentration ozone on soybean growth and grain yield. Ying Yong Sheng tai xue bao= J Appl Ecol 21(9):2347–2352
Liu Y, Liu X, Wang X, Gao K, Qi W, Ren H, Hu H, Sun D, Bai J, Zheng S (2020) Heterologous expression of heat stress responsive AtPLC9 confers heat tolerance in transgenic rice. BMC Plant Biol 20:1–11
Medici LO, Reinert F, Carvalho DF, Kozak M, Azevedo RA (2014) What about keeping plants well-watered? Environ Exp Bot 99:38–42
Medina S, Vicente R, Amador A, Araus JL (2016) Interactive effects of elevated [CO2] and water stress on physiological traits and gene expression during vegetative growth in four durum wheat genotypes. Front Plant Sci 7:1738
Morris GP, Ramu P, Deshpande SP, Hash CT, Shah T, Upadhyaya HD, Riera-Lizarazu O, Brown PJ, Acharya CB, Mitchell SE (2012) Population genomic and genome-wide association studies of agroclimatic traits in sorghum. Proc Natl Acad Sci USA 110:453–458
Mostofa MG, Ghosh A, Li Z-G, Siddiqui MN, Fujita M, Tran L-SP (2018) Methylglyoxal—a signaling molecule in plant abiotic stress responses. Free Radical Biol Med 122:96–109. https://doi.org/10.1016/j.freeradbiomed.2018.03.009
Mukarram M, Choudhary S, Kurjak D, Petek A, Khan MMA (2021) Drought: sensing, signalling, effects and tolerance in higher plants. Physiol Plant 172(2):1291–1300
Naeem M, Iqbal M, Shakeel A, Ul-Allah S, Hussain M, Rehman A, Zafar ZU, Ashraf M (2020) Genetic basis of ion exclusion in salinity stressed wheat: implications in improving crop yield. Plant Growth Regul 479–496
Nakashima K, Yamaguchi-Shinozaki K, Shinozaki K (2014) The transcriptional regulatory network in the drought response and its crosstalk in abiotic stress responses including drought, cold, and heat. Front Plant Sci 5:170
Nakaya A, Isobe SN (2012) Will genomic selection be a practical method for plant breeding? Ann Bot 110:1303–1316
O’Connell E (2017) Towards adaptation of water resource systems to climatic and socio-economic change. Water Resour Manage 31(10):2965–2984. https://doi.org/10.1007/s11269-017-1734-2
Oliveira ICM, Guilhen JHS, de Oliveira Ribeiro PC, Gezan SA, Schaffert RE, Simeone MLF, Pastina MM (2020) Genotype-by environment interaction and yield stability analysis of biomass sorghum hybrids using factor analytic models and environmental covariates. Field Crop Res 257:107–929
Osakabe Y, Yamaguchi-Shinozaki K, Shinozaki K, Tran LSP (2020) ABA control of plant macro element membrane transport systems in response to water deficit and high salinity. New Phytol 202:35–49
Parry MAJ, Flexas J, Medrano H (2005) Prospects for crop production under drought: research priorities and future directions. Ann Appl Biol 147:211–226
Prakash J, Tek A, Ritika BS (2020) Climate change and agriculture in South Asia : adaptation options in smallholder production systems. In: Environment, development and sustainability, vol 22, Issue 6. Springer, Netherlands. https://doi.org/10.1007/s10668-019-00414-4
Rai KK, Rai AC (2020) Recent transgenic approaches for stress tolerance in crop plants. Sustainable agriculture in the Era of climate change. Springer, Berlin/Heidelberg, Germany, pp 533–556
Ray DK, West PC, Clark M, Gerber JS, Prishchepov AV, Chatterjee S (2019) Climate change has likely already affected global food production. PLoS ONE 14(5):1–18. https://doi.org/10.1371/journal.pone.0217148
Reddy P (2015) Climate resilient agriculture for ensuring food security. Springer
Ristvey AG, Belayneh BE, Lea-Cox JD (2019) A Comparison of irrigation-water containment methods and management strategies between two ornamental production systems to minimize water security threats. Water 11(12):2558
Rutkoski JE, Heffner EL, Sorrells ME (2010) Genomic selection for durable stem rust resistance in wheat. Euphytica 179:161–173
Salehi-Lisar SY, Bakhshayeshan-Agdam H (2020) Agronomic crop responses and tolerance to drought stress BT–agronomic crops. In: Hasanuzzaman M (ed) Stress responses and tolerance, vol 3. Springer, Singapore, pp 63–91. https://doi.org/10.1007/978-981-15-0025-1_5
Sami A, Xue Z, Tazein S, Arshad A, He Zhu Z, Ping Chen Y, Hong Y, Tian Zhu X, Jin ZK (2021) CRISPR-Cas9-based genetic engineering for crop improvement under drought stress. Bioengineered 12(1):5814–5829. https://doi.org/10.1080/21655979.2021.1969831
Scopel E, Triomphe B, Affholder F, Da Silva FAM, Corbeels M, Xavier JHV, Lahmar R, Recous S, Bernoux M, Blanchart E (2013) Conservation agriculture cropping systems in temperate and tropical conditions, performances and impacts. A review. Agron Sustain Dev 113–130
Seleiman MF, Al-Suhaibani N, Ali N, Akmal M, Alotaibi M, Refay Y, Dindaroglu T, Abdul-Wajid HH, Battaglia ML (2021) Drought stress impacts on plants and different approaches to alleviate its adverse effects. Plants 10(2):1–25. https://doi.org/10.3390/plants10020259
Shahid MJ, Ali S, Shabir G, Siddique M, Rizwan M, Seleiman MF, Afzal M (2020) Comparing the performance of four macrophytes in bacterial assisted floating treatment wetlands for the removal of trace metals (Fe, Mn, Ni, Pb, and Cr) from polluted river water. Chemosphere 243:125353. https://doi.org/10.1016/j.chemosphere.2019.125353
Shavrukov Y, Kurishbayev A, Jatayev S, Shvidchenko V, Zotova L, Koekemoer F, de Groot S, Soole K, Langridge P (2017) Early flowering as a drought escape mechanism in plants: How can it aid wheat production? Front Plant Sci 8
Shi J, Gao H, Wang H et al (2017) ARGOS 8 variants generated by CRISPR-Cas9 improve maize grain yield under field drought stress conditions. Plant Biotechnol J 15(2):207–216
Shou H, Bordallo P, Wang K (2004) Expression of the Nicotiana protein kinase (NPK1) enhanced drought tolerance in transgenic maize. J Exp Bot 55(399):1013–1019
Solis J, Gutierrez A, Mangu V, Sanchez E, Bedre R, Linscombe S, Baisakh N (2018) Genetic mapping of quantitative trait loci for grain yield under drought in rice under controlled greenhouse conditions. Front Chem 129
Sultan B, Defrance D, Iizumi T (2019) Evidence of crop production losses in West Africa due to historical global warming in two crop models. Sci Rep 9(1):1–15. https://doi.org/10.1038/s41598-019-49167-0
Taiz L, Zeiger E (2010) Plant physiology, 5th edn. Sinauer Associates Inc., Publishers, Massachusetts
Tardieu F, Simonneau T, Muller B (2018) The physiological basis of drought tolerance in crop plants: a scenario-dependent probabilistic approach. Annu Rev Plant Biol 69:733–759
Tariq M, Khan F, Shah AH, Fahad S, Wahid F, Ali J, Adnan M, Ahmad M, Irfan M, Zafar-ul-Hye M, Battaglia ML, Zarei T, Datta R, Saleem IA, Hafeez-u-Rehman, Danish S (2020) Effect of micronutrients foliar supplementation on the production and eminence of plum (Prunus domestica L.). Qual Assur Saf Crops Foods 12(SpecialIssue 2):32–40. https://doi.org/10.15586/qas.v12iSP1.793
Tejero IFG, Moriana A, Pleguezuelo CRR, Zuazo VHD, Egea G (2018) Sustainable deficit-irrigation management in almonds (Prunus dulcis L.): different strategies to assess the crop water status. In: Water scarcity and sustainable agriculture in semiarid environment. Academic Press, Cambridge, MA, USA, pp 271–298
Tiwari M, Kumar Trivedi P, Pandey A (2021) Emerging tools and paradigm shift of gene editing in cereals, fruits, and horticultural crops for enhancing nutritional value and food security. Food Energy Sec 10(1):e258
Varshney RK, Mohan SM, Gaur PM, Ganga Rao N, Pandey MK, Bohra A, Sawargaonkar SL, Chitikineni A, Kimurto PK, Janila P (2013) Achievements and prospects of genomics-assisted breeding in three legume crops of the semi-arid tropics. Biotechnol Adv 31:1120–1134
Varshney RK, Terauchi R, McCouch SR (2014) Harvesting the promising fruits of genomics: applying genome sequencing technologies to crop breeding. PLoS Biol 10
Vishwakarma K, Upadhyay N, Kumar N, Yadav G, Singh J, Mishra RK, Kumar V, Verma R, Upadhyay RG, Pandey M (2017) Abscisic acid signaling and abiotic stress tolerance in plants: a review on current knowledge and future prospects. Front Plant Sci 161
Whyte G, Howard K, Hardy GSJ, Burgess TI (2016) The tree decline recovery seesaw; a conceptual model of the decline and recovery of drought stressed plantation trees. For Ecol Manage 370:102–113
Wilkinson S, Kudoyarova GR, Veselov DS, Arkhipova TN, Davies WJ (2012) Plant hormone interactions: innovative targets for crop breeding and management. J Exp Bot 63(9):3499–3509
Yadav S, Modi P, Dave A, Vijapura A, Patel D, Patel M (2020) Effect of abiotic stress on crops. In: Hasanuzzaman M, Filho MCMT, Fujita M, Nogueira TAR (eds.). Ch. 1. IntechOpen. https://doi.org/10.5772/intechopen.88434
Yang J, Zhao S, Zhao B, Li C (2018) Overexpression of TaLEA3 induces rapid stomatal closure under drought stress in Phellodendron amurense Rupr. Plant Sci 277:100–109
Yang X, Lu M, Wang Y, Wang Y, Liu Z, Chen S (2021) Response mechanism of plants to drought stress. Horticulturae 7(3):50
Yang H, Huntingford C, Wiltshire A, Sitch S, Mercado L (2019) Compensatory climate effects link trends in global runoff to rising atmospheric CO2 concentration. Environ Res Lett 14(12). https://doi.org/10.1088/1748-9326/ab5c6f
Yin J, Gentine P, Zhou S, Sullivan SC, Wang R, Zhang Y, Guo S (2018) Large increase in global storm runoff extremes driven by climate and anthropogenic changes. Nat Commun 9(1). https://doi.org/10.1038/s41467-018-06765-2
Yu W, Yang Y, Savitsky A, Alford D, Brown C, Wescoat J, Debowicz D, Robinson S (2013) The indus basin of pakistan: the impacts of climate risks on water and agriculture. https://documents1.worldbank.org/curated/en/650851468288636753/pdf/Indus-basin-of-Pakistan-impacts-of-climate-risks-on-water-and-agriculture.pdf
Zargar SM, Gupta N, Nazir M, Mahajan R, Malik FA, Sofi NR, Salgotra RK (2017) Impact of drought on photosynthesis: molecular perspective. Plant Gene 11:154–159
Zhang YL, Zhang CL, Wang GL, Wang YX, Qi CH, You CX, Li YY, Hao YJ (2019) Apple AP2/EREBP transcription factor MdSHINE2 confers drought resistance by regulating wax biosynthesis. Planta 249(5):1627–1643
Zhao Y, Zhang Z, Gao J, Wang P, Hu T, Wang Z, Hou YJ, Wan Y, Liu W, Xie S, Lu T, Xue L, Liu Y, Macho AP, Tao WA, Bressan RA, Zhu JK (2018) Arabidopsis duodecuple mutant of PYL ABA receptors reveals PYL repression of ABA-independent SnRK2 activity. Cell Rep 23(11):3340–3351.e5. https://doi.org/10.1016/j.celrep.2018.05.044
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Ranjan, S. et al. (2023). Effects of Drought Stress on Agricultural Plants, and Molecular Strategies for Drought Tolerant Crop Development. In: Aftab, T. (eds) New Frontiers in Plant-Environment Interactions. Environmental Science and Engineering. Springer, Cham. https://doi.org/10.1007/978-3-031-43729-8_10
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