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Review

Biotechnological Interventions in Tomato (Solanum lycopersicum) for Drought Stress Tolerance: Achievements and Future Prospects

by
Ram Krishna
1,2,
Waquar Akhter Ansari
2,
P. S. Soumia
3,
Akhilesh Yadav
4,
Durgesh Kumar Jaiswal
5,
Sudhir Kumar
2,
Achuit Kumar Singh
2,
Major Singh
3 and
Jay Prakash Verma
1,6,*
1
Institute of Environment and Sustainable Development, Banaras Hindu University, Varanasi 221005, India
2
ICAR-Indian Institute of Vegetable Research, Varanasi 221305, India
3
ICAR Indian Council of Agriculture Research-Directorate of Onion and Garlic Research, Pune 410505, India
4
Department of Plant Science, University of California, Davis, CA 95616, USA
5
Department of Botany, Savitribai Phule Pune University, Pune 411007, India
6
Soil Mircobiology Lab, Department of Soil Science, Pici Campus, Federal University of Ceara, Fortaleza 60020, Brazil
*
Author to whom correspondence should be addressed.
BioTech 2022, 11(4), 48; https://0-doi-org.brum.beds.ac.uk/10.3390/biotech11040048
Submission received: 31 August 2022 / Revised: 13 October 2022 / Accepted: 14 October 2022 / Published: 19 October 2022
(This article belongs to the Special Issue New Technologies in Agricultural and Plant Biotechnology)
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Abstract

:
Tomato production is severely affected by abiotic stresses (drought, flood, heat, and salt) and causes approximately 70% loss in yield depending on severity and duration of the stress. Drought is the most destructive abiotic stress and tomato is very sensitive to the drought stress, as cultivated tomato lack novel gene(s) for drought stress tolerance. Only 20% of agricultural land worldwide is irrigated, and only 14.51% of that is well-irrigated, while the rest is rain fed. This scenario makes drought very frequent, which restricts the genetically predetermined yield. Primarily, drought disturbs tomato plant physiology by altering plant–water relation and reactive oxygen species (ROS) generation. Many wild tomato species have drought tolerance gene(s); however, their exploitation is very difficult because of high genetic distance and pre- and post-transcriptional barriers for embryo development. To overcome these issues, biotechnological methods, including transgenic technology and CRISPR-Cas, are used to enhance drought tolerance in tomato. Transgenic technology permitted the exploitation of non-host gene/s. On the other hand, CRISPR-Cas9 technology facilitated the editing of host tomato gene(s) for drought stress tolerance. The present review provides updated information on biotechnological intervention in tomato for drought stress management and sustainable agriculture.

1. Introduction

Cultivated tomato, Solanum lycopersicum [1] (old name: Lycopersicon esculentum Mill), originated and domesticated in Western South America and Central America from Mexico to Peru [2]. Tomato is a member of division Magnoliophyte, class Magnoliopsida, sub-class Asteridae, order Solanales, and family Solanaceae. Tomato is unquestionably the most popular garden crop worldwide [3], botanically classified as fruit (berry) but often consumed as vegetable (raw, cooked and/or in processed form), next to potato [4,5]. Although the cultivated tomato is a tropical plant, it requires moderate growing conditions and is widely adapted to different climates, thus making it cosmopolitan. China, USA, India, Turkey, Egypt, and Italy are some of the major tomato-producing countries [5]. India ranks third among the top tomato-producing countries, and it is cultivated in 6.34 million ha, with a total production of 12,433,200 tonnes and average productivity of 19,598 kg/ha [5]. The largest tomato-producing states in India include Maharashtra, Bihar, Karnataka, Uttar Pradesh, Odisha, Andhra Pradesh, Madhya Pradesh, and Assam [6]. Worldwide, more than a thousand cultivars of tomato are grown, selected based on fruit size, shapes, and growth pattern in different environments [3]. Plants of tomato are diploid (2n = 2x = 24), determinate to indeterminate growth habit, herbaceous with bisexual flowers, annual to perennial, self-pollinated, and are commonly propagated by seeds. Generally, seedlings of 4–5 weeks old are transplanted, prior to which hardening should be performed by withholding water for up to 4–5 days [7,8]. With proper water supply, tomato can be cultivated in different soil types, such as clay, black soil, and red soil; nonetheless, organic-matter-rich sandy loam soil is ideal. Tomato can also tolerate moderate saline and acidic soils. Temperature of 15–27 °C is found to be optimum for its cultivation; however, day temperatures exceeding 38 °C may adversely affect fruit set. In general, tomato is a self-pollinated crop; however, 30% cross-pollination has been recorded in some cases [8,9]. Most tomato genotypes have compound leaves, pinnately dissected with 5–9 leaflets on petioles. The inflorescence is a cyme with monochasial or dichotomous branching patterns. Flowers are bisexual and usually yellow in colour; the male part of flower is the stamens, consisting of anther borne on a filament. Anthers join laterally to form a flask-shaped cone with a prolonged sterile tip at the apex. The female flower part is the pistil, consisting of stigma, style, and ovary, and is situated in the flower’s centre, encircled by the stamens. Though tomato is commonly classified as a vegetable, it is really a fruit; berry. Most cultivated varieties, except cherry tomatoes, are either bilocular or multilocular with 4–5 locules [10]. Fruits come in a variety of shapes (globose, round, oval, flattened, elongated, or heart-shaped) and colours (golden, yellow, red, pink, purple, green, striped to white) [11]. Tomato fruits are rich in vitamin A, vitamin C, vitamin E, potassium, dietary fibre, β-carotene, and lycopene. Upon ripening, fruits develop a characteristic deep-red colour due to the pigment lycopene [12]. Among dietary carotenoids, lycopene is one of the most powerful antioxidants that protects against free radicals and is also known to prevent cancer [12]. Besides its nutritional and therapeutic properties, tomato is used for its distinct flavour and as a food colourant. Tomato fruits are also used to make a range of value-added products, such as whole-peeled tomatoes, diced products, paste, sauce, juice, and soups [13,14]. Tomato’s projected genome size is 900 megabases (Mb), containing 34,727 protein-coding genes [15]. Genes are mostly located in the euchromatin region, which accounts for less than a quarter of total genomic DNA [16]. Relatively small genome size makes tomato a genetic model for crop improvement [8] and, also, a suitable system for studying functional genomics, proteomics, and metabolomics. Further, it has been widely used for studies of various biotic and abiotic responses due to availability of various resistant genes and adaptation to a wide environmental condition and photoperiod insensitivity [17,18,19,20,21]. The tomato genome consortium sequenced the whole tomato genome as a key model plant for speeding genomic research in the Solanaceae family because it has the same haploid set of chromosomes and conserved genome structure (a high level of synteny) as other Solanaceous plants. Tomato was the first transgenic food (Flavr Savr Tomato) crop released for commercial cultivation in 1992 in U.S.A., genetically engineered to increase the shelf-life of fruits [22]. Being a model crop for molecular study and genetic manipulation, tomato is the highest studied crop among the vegetable crops. To date, numerous transgenes were transferred in tomato and evaluated against the biotic (virus, bacteria, fungi, and insect) and abiotic (drought, salt, heat, cold, and water logging) stress tolerance and quality improvement. Among abiotic stresses, drought is the most important stress. Drought is the inadequacy of water, which restricts tomato growth and yield [14,23]. Globally, only 14.51 percent agricultural land is well irrigated and the rest is moderately to highly drought susceptible (FAO, 2012). Drought stress primarily affects the crops by generating reactive oxygen species (ROS), which disturbs the cellular homeostasis [14,23]. In order for normal growth and development, crop must constantly adapt to climatic conditions. The water loss management in crop and detoxification of ROS are the key strategies in drought stress management. In tomato, for drought stress management, numerous transgenic tomatoes were developed. In the present study, we are providing an update of transgenic tomatoes for drought stress tolerance, which will be helpful to fulfil the research gap in tomato production under drought stress.

2. Drought Stress

Any altered physiological condition that tends to disrupt plants’ homeostatic equilibrium is termed as stress [9,13,19,24,25]. Homeostasis is, in turn, a fixed value for metabolism under standard conditions, which is hardly attained by plants, as most of them are exposed to various types of stresses [24]. Drought, heat, cold, salt, high temperature and light, oxidative stress, heavy metal toxicity, radiations, and UV light are some of the constant threats to plants worldwide. The effect of biotic and abiotic factors on plants is determined by the quantity, intensity, duration, and methods of application on plants. Furthermore, plants have evolved a wide range of physiological and biochemical changes to fit and adapt to a variety of environmental challenges. Nevertheless, globally abiotic stresses are considered as the primary factor for the crop loss which roughly estimates to ~70% of yield reduction [2,24,25]. Water deficit is the most critical abiotic stress that affects many physiological parameters of plants, particularly photosynthetic capability. During drought, dehydration of the plant cells and tissues causes diminished plant growth and productivity (Figure 1). Thus, water deficit works as a limiting factor in agriculture for production by inhibiting the crop from performing its genetic yield potential [20]. Drought is characterised by inadequate availability of water, due to precipitation variability, evaporation, and soil moisture holding capacity; high water requirement by plants or a combination of all these factors restricts the plants from achieving their full genetic potential. Metrologically, drought is described as a period of below-normal precipitation that limits plant productivity in an agricultural or natural system [26]. Nearly two thirds of geographical area of India receives low (>1000 mm) or erratic rainfall. Out of 140 million hectares of cultivated area, about 68% is vulnerable to drought stress and ~34% is classified as “severe”, where the drought frequency is nearly periodic. Drought stress affects around 68% of the 140 million hectares of cultivated land, with ~34% categorised as “severe”, indicating the drought frequency being nearly periodic. Among the abiotic stresses, drought is the most severe and pervasive environmental factor [9,13,24]. Plants do expedite the detoxification and repair processes in response to stress (Figure 2), which may include alterations in the expression of ROS scavenging enzymes, late embryogenesis abundant (LEA)/dehydrin-type genes, and the synthesis of molecular chaperones, proteinases, and other detoxification proteins [9,27,28].

2.1. Drought-Responsive Transcription Factor Genes in Tomato

Drought stress causes a rise in the levels of endogenous ABA in plants [29], and a concomitant altered numerous gene expression [30] in cultivated tomato leaves. Wild relatives of S. lycoperscum are resistant to many biotic and abiotic stresses. S. pennellii (syn. L. pennellii), a wild relative of tomato, grows and reproduces with minimal water, higher water use efficiency, and resistance to wilt [31]. Martin and Thorstenson [32] used carbon isotope composition and season-long water use efficiency measures to confirm drought resistance in S. pennellii. Kahn et al. [33] discovered and isolated four tomato genes (le4, le16, le20, and le25) in response to increased levels of endogenous ABA. Kahn et al. [33] investigated the expression of these genes in S. pennellii to gain a better idea of their function during drought stress. All four ABA-sensitive S. lycopersicum genes had homologous counterparts in S. Pennellii. In S. pennellii, the increase usually occurs after a prolonged duration of drought compared to that in S. lycopesocum.
However, only three of the four genes (le76, le20, and le2.5) were expressed in S. pennellii in response to exogenous ABA treatment. The expression patterns of these genes in S. pennellii were usually parallel to those in S. lycopersicum, indicating a similar but undetermined function in both genotypes rather than having genes that are responsible for improved drought tolerance in S. pennellii. Members of the abscisic-acid-responsive element binding protein (AREB)/abscisic acid element binding factor (ABF) subfamily of basic leucine zipper (bZIP) transcription factors have been involved in the response to ABA and abiotic stress. In Arabidopsis, AREB1 and AREB2 functional evaluation against ABA, drought, and salinity stress conditions are revealed [34,35]; however, the tomato AREB function and transcriptional regulation remain unknown [36]. Yaez et al. [37] identified a basic leucine zipper (bZIP) transcription factor in Solanum lycopersicum (SlAREB1), Solanum chilense (ScAREB1), and Solanum peruvianum (SpAREB1). The three proteins’ deduced amino acid sequences were 97% similar and exhibited strong homology with the ABF/AREB subfamily of transcription factors which was demonstrated in other plant species, such as Arabidopsis (ABF2, 54% similar) and tobacco (PHI-2, 50% similar). The induced SlAREB1 expression was reported in S. lycopersicum by abscisic acid, cold, and drought. For a quick investigation of genes controlled by SlAREB1 in tomato and tobacco, a simple transient expression assay using Agrobacterium-mediated transformation was performed. Tobacco leaves expressing SlAREB1 exhibited upregulation of stress-responsive genes, such as rd29B, LEA ERD10B, TAS14, PHI-2, and trehalose-6-phosphate phosphatase [37]. These findings imply that bZIP has a function in abiotic stress response in Solanum species. In the case of S. lycopersicum, [38] Orellana et al. identified SlAREB1 and SlAREB2 are induced in leaf as well as in root tissue by drought and salinity, but the effect on SlAREB1 was more than that on SlAREB2. The SlAREB1 overexpression in transgenic tomato plants improved salt and water stress tolerance compared to non-transgenic tomato plants. SlAREB1 target gene microarray and cDNA-amplified fragment length polymorphism (AFLP) analyses revealed that genes coding for oxidative-stress-related proteins, lipid transfer proteins (LTPs), transcription regulators, and LEA proteins were found to be upregulated in SlAREB1-overexpressing tomato lines, especially in aerial tissue. The findings indicate that bZIP transcription factor (SlAREB1) is associated with ABA signal pathway that contributes to abiotic stress, as well as in pathogen response [38]. Hsieh et al. [36] found AREB gene, a SlAREB transcription factor, using a tomato cDNA microarray. Electrophoretic mobility shift tests revealed that the chimeric DNA-binding domain of SlAREB proteins can bind to the promoter regions of Atrd29A and SlLAP. However, an ABA-dependent post-translational alteration is required for the SlAREB protein trans-activation [36].
SlAREB constitutive expression improves tolerance to drought and salt stressors in Arabidopsis and tomato plants, preserving PSII, membrane integrity, and water availability in plants. Stress-related genes AtCOR47, Atrd29A, and SlCI7-like dehydrin were regulated by SlAREB overexpression in A. thaliana and tomato plants subjected to abiotic and ABA stress. Hsieh et al. [36] found that SlAREB regulates some genes involved in stress response and its overexpression improves plant tolerance to drought and salt stress. Islam and Wang [39] isolated full-length LeDREB3 cDNA from tomato, investigated the pattern of expression in tomato under various abiotic stresses, and suggested that the LeDREB3 gene may be responsible for tomato plant stress tolerance. LeDREB3 is present in duplicate copies in the tomato genome and has considerable sequence match to DREB proteins belonging to various species of plant family. The LeDREB3 constitutive expression reported in all the tested organs, which was especially higher in flower. Drought, low temperature, salt, and H2O2 were shown to probably enhance LeDREB3 expression, which is expected to provide tolerance to these stresses. However, they did not evaluate its constitutive transgenic expression in tomato or any other plant species.
Investigating the ethylene response factor (ERF) protein demonstrates how it affects the expression of downstream genes in plants under stress by interacting with the GCC box, dehydration-responsive element, and C-repeat [40]. By inhibiting antisense TERF2/LeERF2, the ethylene-inducible ERF protein TERF2/LeERF2 demonstrates the positive control of ethylene production in tomatoes [41]. According to Zhang and Huang [40], increased freeze tolerance in tomato and tobacco is associated with the control of TERF2/LeERF2, and cold gradually triggers the expression of TERF2/LeERF2. Similar to Arabidopsis CBF13 genes, tomato encodes LeCBF13 (L. esculentum CBF13), three homologs that are tandemly present within the genome [42]. However, only tomato LeCBF1 gene is reported to be induced by cold. LeCBF1-3 transcripts did increase in response to mechanical agitation, similar to Arabidopsis CBF1-3, but not in response to ABA, drought, or high salt. LeCBF1 is a homolog of the functional proteins CBF1-3 in Arabidopsis, and its constitutive overexpression in transgenic Arabidopsis increased the expression of CBF-targeted genes and improved tolerance to freezing. Tomato harbours an absolute CBF cold response pathway, according to Zhang et al. [43]. However, the tomato CBF regulon differs from that of Arabidopsis and seems to be substantially smaller and less functionally diverse. A number of dehydration-responsive elements-binding proteins (DREBs) in plants have been identified, and it has been suggested that both abiotic and biotic stressors can activate them. Recently, Guo and Wang [44] isolated a DREB gene from tomato and designated it as LeDREB2.
LeDREB2 is classified in DREB family with the AP2 group. Being a single-copy gene of the tomato genome, it expresses strongly in young leaves and roots but shows weak expression in shoots and mature leaves. Various environmental stresses, such as cold and draught, induce the transcription of LeDREB2. Different studies demonstrate the expression analysis inducing the transcription of LeDREB2 gene due to various stresses (H2O2, salt, ABA, and methyl viologen) in tomato. Guo and Wang [44] found that LeDREB2 gene is a DREB transcription factor involved with oxidative and abiotic stress in tomato. Recently, Li et al. [45] cloned SlDREB from cultivated tomato M82, a transcription factor, and found that it plays a negative role in architecture of tomato plant, and elevates tolerance against drought. Expression profiles indicate that SlDREB expression is mainly expressed in leaf and stem and is unable to induce by abscisic acid (ABA) but is suppressed by ethylene and GA. The activity of yeast assay exhibited that SlDREB exclusively binds to dehydration responsive element/C-repeat (DRE/CRT) of the SlCPS promoter region. When constitutively overexpressed, the SlDREB altered plant morphology by regulating leaf and internode elongation, and the consequent dwarfism of tomato plants could be reversed by adding gibberellic acid (GA3) exogenously. The findings of Hsieh et al. [36] showed constitutive overexpression of SlAREB in tomato induced dwarfism that could be alleviated by exogenous GA3 treatment, which were comparable to findings of [45]. Transcript level analysis of transgenic plants disclosed that SlDREB overexpression resulted in dwarf phenotype by downregulating key GA biosynthesis genes involved, such as ent-copalyldiphosphate synthase (SlCPS) and GA 20-oxidases (SlGA20ox1, -2, and -4), thereby reducing endogenous GA levels of application in transgenic plants.

2.2. Genetic Engineering of Tomato for Improved Drought Stress Tolerance

In the last century, efforts through classical breeding have resulted in improved agronomic traits, as well as nutritional value of cultivated tomato. However, traditional breeding has not been very successful in enhancing drought tolerance in tomato cultivars due to the limited genetic variation within S. lycopersicum species. It is evaluated that just ~5% of the complete genetic variability inside the tomato family can be found within S. lycopersicum (100 Tomato Genome Sequencing Consortium, 2014). The genes related to different required agricultural traits, including drought resistance, do not exist in this cultivated species [13]. However, fortunately, related wild tomato species, including S. pimpinellifolium, S. chilense, S. peruvianum, S. pennellii, and S. hirsutum, have shown to be a rich source of the genes and traits needed to increase resistance to various abiotic stresses. Due to the intricacy of abiotic stress tolerance mechanisms, transferring these traits from wild relatives of S. lycopersicum is challenging and takes a lot of effort; therefore, they have not been fully utilised [13]. The genetic base for resistance and tolerance against abiotic stress in species of wild tomato are hereditary as quantitative traits; thus, it is also unlikely that a single gene from wild tomato species expressed in cultivated species will confer drought tolerance [46]. For such reasons, developing stress-tolerant transgenic tomato taking regulatory genes from related or distant species is a workable approach to improve drought tolerance of tomato. Therefore, genetic engineering is a relatively quick, precise, and frequently successful method of improving abiotic stress resistance in many plant species.
Considering the problem of drought stress in tomato, attempts have been made to enhance drought tolerance by incorporating single genes from distant plant species [8,19,20,24,27,47], as well as some microbes, governing drought and other water-deficit stress tolerance. Constitutive overexpression of Arabidopsis CBF1 in tomato brought about upgraded plant resistance to cold, dry season, and salt burdens. In any case, this upgraded resistance included some significant pitfalls, causing decreased plant development and yield [19]. The transgenic tomatoes showed improved resilience to dry season, cold, and salt stress when a related gene (CBF1) was expressed using an ABA/stress-inducible ARBC1 promoter from the barley HAV22 gene. Additionally, the use of the inducible promoter eliminated the negative effects of the ectopic expression of CBF1 on plant growth and yield [19,27]. By ensuring various proteins, boiling stable proteins (BSP), have been involved in parching resistance against drought stress. Drought stress resistance of transformed tomato plants was attempted with a special 66-kD BSP from Populus tremula using polyethylene glycol (PEG) study, biomass investigation, proline assay, and electrolyte leakage measurement. These plants displayed slightly increased drought stress tolerance [48]. S. lycopersicum was found to contain the basic leucine zipper (bZIP) transcription factor SlAREB1 [37]. Uncomplicated transitory expression analysis was implemented for fast study of genes controlled by SlAREB1 in tobacco and tomato recommended regarding the group of bZIP that performs a role in abiotic stress reaction in the Solanum genus. Zhang et al. [49] developed marker-free selectable transgenic tomato plants exhibiting increased resistance to drought, cold, and oxidative stresses, which constitutively expressed AtIpk2b, an inositol polyphosphate 6-/3-kinase gene from A. thaliana. Tobacco osmotin gene driven by CaMV35S promoter was transferred to tomato and physiological analysis at T1 and T2 generations was used to test for resistance against drought and salt stress. Increased resistance to drought and salt stress was observed during NaCl stress and when water was withheld [47]. Tomato plants were transformed with the mannitol-1-phosphate dehydrogenase (mtlD; EC1.1.1.17) gene from bacteria, which is controlled by the CaMV35S promoter. Drought, cold, and salinity resistance study showed that transgenic lines perform a better resistance against abiotic stresses [50]. The SlAREB1-overexpressing transgenic tomato plants exhibited increased resistance against drought and salt stress, as analysed by various physiological parameters, such as relative water content, damage by lipoperoxidation, and chlorophyll fluorescence [38].
By offering the codA gene expressing a choline oxidase from Arthrobacter globiformis, Goel et al. [51] modified tomato for increased resistance to salt and water stress with the capacity to assimilate glycine betaine. The codA transgenic plants demonstrated increased resistance to salt stress during seed germination and ensuing development of young seedlings compared to wild varieties of plants. Developed codA transgenic plants had uncovered more elevated levels of relative water content, chlorophyll concentration, and proline level. Rai et al. [19,24] developed transgenic tomato cv. Kashi Vishesh (H-86) for improved drought tolerance by using the BcZAT12 gene coding sequence regulated through Bclea1a promoter. BcZAT12 expresses a C2H2 type zinc finger protein that is known to confer multiple abiotic stress tolerance to plants. Analysis of RWC, EL, CCI, H2O2 and superoxide anion level, and antioxidant enzyme activities suggested that BcZAT12 tomato transformants had increased levels of drought tolerance. Transgenic plants with the A. thaliana transcription factor ATHB-7 gene inserted displayed reduced stomatal density and increased tolerance to drought stress [52]. However, AtATHB-7 was established to be expressed increasingly under drought stress; thus, it performs as a negative growth regulator. The integration of drought-stress-tolerant genes from unrelated species into tomato has been the focus of intense research efforts from scientists all over the world (Table 1) [47,48,49,50,51,52,53,54].

2.2.1. DREB1A/CBF3 Gene in Stress Tolerance

Tolerance to abiotic stress in Arabidopsis [72,73], maize [74], and rice [75] is often achieved by modifying endogenous plant pathways, frequently by manipulating the overexpression of important regulatory proteins or transcription factors. Numerous transcription factors are part of large families [13,30]. Manipulating abiotic stress tolerance traits is complicated, as the interaction of plants with the environment is a continuous and intricate process. A large number of TFs are present in the plant genome. About 5.9% of Arabidopsis genome is devoted to coding more than 1500 TFs. On the basis of the composition of their binding domains, these TFs may be divided into a number of families [76]. Many of these TFs, including MYB, AP2/EREBP, bZIP, and WRKY, are members of large multi-gene families. However, certain stress-sensitive genes may share the same TFs, as demonstrated by the significant overlap of the gene expression profiles that are activated in response to diverse stress stimuli. Individual members of the same family may respond differentially to distinct stress stimuli [19,21,24,28].
The transcription factors (TFs) associated with the drought and cold stress tolerance are ABA-triggered and come from a variety of classes, including the bZIP, Zinc finger, homeodomain Leu zipper (or HD-Zip), MYC/MYB, and ABI3/VP1 families [24]. The bZIP TFs form dimers with ABA response elements (ABREs); however, a second “cis element” or “coupling element” is often needed for optimum ABA responsiveness [1]. Sometimes this CE element and the dehydration-responsive element (DRE/CRT) are comparable [27]. According to [77], the DRE/CRT-binding AP2s and the ABRE-binding bZIPs may interact to regulate the ABA-regulated gene expression. The CRT binding factors are one class of AP2 TFs that are essential in both the ABA-dependent and ABA-independent pathways (DREB1s or CBFs; [20]). In Arabidopsis, cold induction CBF1-3 genes are ABA-independent; however, ABA is required for the dehydration-induced activation of the CBF4 gene [21]. The expression of all CBF genes in Arabidopsis is low under normal growth conditions, but it quickly rises in response to water stress [78].
There are regulators of the CBF genes also: [79] identified ICE1 in Arabidopsis, a bHLH TF, which specifically binds to MYC detection sequences within CBF3 promoter and triggers expression of CBF3 in the cold. SFR6 could collaborate with the CBFs or DREB2s, as shown by the Arabidopsis sfr6 mutant’s lack of COR gene expression that is controlled by CRT/DRE in response to osmotic stress, cold, or exogenous ABA administration [80]. Quite the opposite to the ICE1 and SFR6, the HOS1 is identified as a negative regulator of CBF2 and CBF3 that encodes for a RING finger protein, which is capable of work in ubiquitin-based nuclear protein breakdown and can cause increase in ICE proteins turnover [81] (Sarkar et al., 2019). The RAV1 (AP2; Lehti-Shiu et al., [82]) and ZAT12 (Zn finger; Rai et al., [24]) have similar expression patterns to those of CBF13, and are known to operate in parallel pathways to those of the CBFs [27]. The DREB2 and AP2, two other transcription factors, play a role in adaptation to drought in an ABA-independent mode [83]. In contrast, RAP2.6 and RAP2.1, which are AP2 domain proteins, induced only after the initial inductions of CBF13, RAV1, and ZAT12, indicating that these are downstream TFs [84]. Medina et al. [85] indicated that the RAP2.1 might be a target of the CBF13 activators, and RAP2.1 promoter sequence consists of two copies of the CRT/DRE core sequences. Plants’ drought adaptation mechanism is heavily regulated by the transcription process [42].
Therefore, one of the ideal targets to design plants for better drought tolerance is such transcription factor genes that regulate the drought adaptation process. However, not every TF engaged in signal transduction of drought is an appropriate target for deployment in transgenics. Some proteins require post-translational modification for its function in transgenic plants [86]. For instance, despite the possibility that the DREB2 TFs play a crucial role in the gene expression that is controlled by drought, the overexpression of DREB2 cDNAs in transgenic plants only leads to poor induction of the downstream genes and does not result in drought tolerance [58]. The AP2/EREBP family of transcription factors that can bind to the DRE element was discovered, and these factors were given the names CBF1/DREB1B, CBF2/DREB1C, and CBF3/DREB1A [83,85]. To develop abiotic stress tolerance, many plant species have been successfully transformed using DREB/CBF genes. The orthologs of CBF genes are present in most crop plants, including apple, canola, tomato, rye, strawberry, barley, rice, wheat, corn, sweet cherry, ryegrass, chrysanthemum, and broccoli [86,87,88,89,90,91,92,93,94,95,96,97].
Functional analyses of a number of putative orthologs have helped to identify the pathway for conservation in those plant species. Arabidopsis [98], tomato [19], chrysanthemum [99], peanut, and many other plant species have increased drought tolerance when the Arabidopsis DREB/CBF genes are expressed constitutively. Similar to this, constitutive overexpression of the rice ortholog CBF (OsDREB1) in Arabidopsis demonstrated tolerance to salt, cold, and drought [90]. Similarly, constitutive ZmCBF gene overexpression in maize also showed enhanced cold tolerance. It was noted that DREB/CBF constitutive expression effected increase in stress tolerance, but the ectopic overexpression of CBF genes produced dark-green and dwarf plants [53,54]. Stress-inducible promoters have been combined with the DREB/CBF genes to solve these issues [18,19,100]. These promoters’ expression is very low under normal growth condition and achieves enhanced stress tolerance without retarding growth characteristics.
Stress can induce the CBF/DREB1 family members CBF1, CBF2, and CBF3 (or DREB1B, DREB1C, and DREB1A). The AtCBF1-3 genes are arranged in a direct repeat on Arabidopsis chromosome 4. Cor6.6, Cor15a, Erd10, Kin1, Kin2, Rd29, Rd17, and other genes are arbitrated by DREB/CBF proteins, which are encoded by the AP2/EREBP multi-gene complex. The promoter region of CBF genes does not contain the DRE sequence; therefore, CBFs are not subjected to auto-regulation. In Arabidopsis, the expression levels of CBF increases with several minutes of stress exposure, followed by accumulation of COR and dehydration-responsive genes at about 2 h [101].
Single TF overexpression in transgenic Arabidopsis plants may have improved stress tolerance. When Arabidopsis was transformed with the DREB1A gene [102], cauliflower mosaic virus (CaMV35S), or by a DRE-containing promoter from the dehydration-induced genes (rd29A), it displayed a distinctly increased tolerance to drought, freezing, and salt stress. Additionally, CBF3 overexpression in Arabidopsis improved resistance to freezing and, more intriguingly, demonstrated numerous biochemical changes related to acclimatisation to the cold, including increased proline and total soluble salt levels [98]. It is clear from the elevated P5CS transcript level found in plants overexpressing CBF3 that the increase in proline levels is the result of increased expression of a crucial proline biosynthesis enzyme.

2.2.2. ZFP (ZAT) Gene in Stress Tolerance

Several plant (Arabidopsis) genomic and cDNA clones encoding potential ZFPs were isolated as a result of knowledge of the C2H2 zinc finger protein (ZFP) gene family, the largest group of regulatory proteins crucial for growth and development in animals [103,104,105]. Today several classes of ZFPs are reported in plants, which are either single-finger C2H2 ZFP gene, as in Arabidopsis [106], or two-fingered C2H2 ZFP gene in petunia and wheat [107,108], or three-fingered C2H2 ZFP gene in Arabidopsis [103], or the ZFPs which are not C2H2 type [109]. Sequence comparison of these different C2H2-ZFPs in Arabidopsis showed that the first finger always contained the amino acid motif (F/Y) QALGGH [103]. Moreover, studies have revealed that C2H2-type ZFP gene overexpression caused both the activation of stress-responsive genes and increased salt tolerance, dehydration, cold stress and/or heat stress [110,111,112,113].
Meissner and Michael [103] were the first to isolate and characterise a diverse family of C2H2-type zinc finger proteins in Arabidopsis. These workers used a PCR approach for the ZFPs with an encoding potential and reported that there existed two- as well three-fingered plant C2H2 ZFP having an evolutionary origin. The PCR products of ZFP gene resulted in eight ZAT1, ZAT2, ZAT (3, 4, and 5), ZAT7, ZAT8, and ZAT9 clones. Further search of the database using Pszf1 as reference for the potential C2H2-ZFP clones resulted in one cDNA corresponding to ZAT12 and two new clones, which were named by these workers as ZAT10 and ZAT11 [103]. The ZAT10 and ZAT12 cDNA sequences had an absence of upstream in-frame stop codons, suggesting that they are different from the other ZAT genes. There is also a possibility that there is N-terminal extension to the open reading frame to ZAT10 and ZAT12 genes. Similar genomic clones were also obtained and, by comparison of the genomic sequences and cDNA clones, these researchers reported the absence of introns in the gene. ZAT10 and ZAT12 genes were widely expressed when mRNA transcripts were studied, specifically under exposure to light stress, suggesting that they are stress inducible. The comparison of ZFPs (ZAT12) from Arabidopsis showed two main families characterised by TF EPF2 and EPF1.
Several members of the zinc-finger protein (ZFP) family, such as ZAT7, ZAT10, and ZAT12, respond to a variety of abiotic and biotic stimuli, despite the fact that many signalling and regulatory genes are believed to be stress-specific [110,111]. In Arabidopsis, ZAT12 is crucial for abiotic stress and reactive oxygen signalling [110]. Davletoava et al. [110] also verified that stimulation of ZAT12 expression under various abiotic conditions is activated at the transcriptional level when using a fusion between the ZAT12 promoter and luciferase gene.
Using ZAT12 gain- and loss-of-function lines, these workers confirmed ZAT12 function during high light and heat stresses, oxidative, osmotic, and salt stress. Transcriptional profiling of ZAT12-overexpressing transgenic and wild-type plants subjected to H2O2 stress showed that, in Arabidopsis, ZAT12 constitutive expression results in the increased oxidative and light-stress-responsive transcript expression [114]. Therefore, ZAT12 under specific growth conditions accelerated to govern transcript accumulation involved in response to high light and oxidative stress in Arabidopsis. These researchers validated ZAT12 function under conditions of high light, heat, oxidative, osmotic, and salt stress using ZAT12 gain- and loss-of-function lines. Transcriptional profiling of ZAT12-overexpressing transgenic and wild-type plants overexpressing ZAT12 in response to H2O2 stress showed increased expression of oxidative- and light-stress-responsive genes in Arabidopsis ZAT12 [114]. ZAT12 thereby increased transcript accumulation in response to high light and oxidative stress in Arabidopsis under specific growth conditions.
According to functional study of a C2H2-type zinc finger protein, the ZFP179 (ZAT12) protein has implications for various cellular processes involved in plant growth and stress responses in rice [111]. These researchers used transgenic rice to examine how well it tolerated oxidative stress, salt stress, drought stress, and auxin treatment. They found that the transgenic line carrying a transgene from the ZFP179 family displayed significantly increased oxidative stress tolerance, ROS scavenging ability, and expression levels of several stress-related genes, including OsDREAB2A, OSP5CS, OsProT, and Oshea3, under salt stress.
In the transgenics, proline and soluble sugars accumulated as well, according to Sun et al. [111], indicating that the rice ZFP179 promoter is sensitive to salt stress. Rai et al. [24,27] showed that, under drought stress, the ectopic overexpression of BcZAT12 gene in tomato had low electrolyte leakage, high relative water content, chlorophyll and antioxidative enzymes (APX, CAT, SOD, GR, and POD) activity, and, also, the lower accumulation of ROS. The upregulation of the drought-responsive ZAT10 gene was shown by transcriptome analysis in drought-tolerant transgenic plants overexpressing TF ABF3 from Arabidopsis [115]. Additionally, the drought response did not activate an unexpected gene network (pleiotropic effects).

2.2.3. Multigenic Transgenic Approach for Abiotic Stress Management

Both biotic (virus, bacteria, fungi, and insect) and abiotic (drought, salt, heat, cold, and water logging) stresses cause direct as well as indirect damages to plant growth and development by affecting various molecular pathways. These pathways are regulated by a cascade of numerous genes and, hence, targeting a single gene may not solve the issue. Transgenic crops with stacked traits are those which have multiple characters within the same plant conferred by multiple gene introduction with the help of genetic engineering. In 2018, genetically modified crops with a combined trait occupied about 42% global biotech crop cultivation area, most commonly in the United States and Brazil (ISAAA, 2019). For example, stacked soybean event, MON87701 × MON89788 (trade named Intacta™ Roundup Ready™ 2 Pro), harbours cp4 epsps and cry1Ac genes, respectively, for glyphosate herbicide and Lepidopteran resistance. Furthermore, many crop plants have been developed by stacking multiple transgenes for harbouring resistance against various insect pests and/or herbicide tolerance by various mechanisms. The multiple transgenic stacked maize, event MON-89-34 × DAS-15-7 × MON-88-17 × DAS-59122 (trade name Genuity® SmartStaxTM), carries the cp4 epsps and pat genes for herbicide glyphosate and glufosinate-ammonium tolerance, as well as the cry1Fa2, cry2Ab2, cry1A.105 and cry35Ab1 genes, respectively, for Lepidopteran and Coleopteran resistance (ISAAA, 2019). Nevertheless, number of molecular pathways and important gene(s) involved in abiotic stresses from different plants were identified and used in the development of double, triple and/or multitransgenic plants [116,117,118,119,120,121,122]. To cope with multiple abiotic stresses, multigenic transgenic crops, such as rice, cotton, soybean, sweet potato, tobacco, tomato, sugarcane, etc., have been developed [123,124,125,126,127]. For the first time, Zhao et al. [123] coexpressed the SsNHX1 and APV1 gene, respectively, from Suaeda salsa and Arabidopsis in rice for salt stress tolerance. They reported a greater salt tolerance in SsNHX1 and APV1 gene co-expressing three-week-old rice seedling than SsNHX1 gene alone in 300 mM NaCl in field growth condition and 150 mM NaCl concentration in MS medium. They also reported increased photosynthesis and root proton exportation capability and reduced H2O2 formation under salt stress in SsNHX1 and APV1-gene-co-expressing seedlings. After this, many genes from different sources were co-expressed in various important crops to manage different abiotic stresses (Table 1). Bhaskaran and Savithramma [117] developed the double transgenic tomato plants co-expressing PgNHX1 and AtAVP1, respectively, from Pennisetum glaucum and Arabidopsis thaliana for salt stress tolerance. The tomato plants harbouring both PgNHX1 and AtAVP1 gene exhibited greater salt tolerance than PgNHX1 and AtAVP1 single-gene transgenic plants. They reported that, at 200 mM NaCl concentration, PgNHX1 and AtAVP1 co-expressing plants grow well, while single transgenic and wild-type plants showed chlorosis and fail to survive within three weeks. The transgenic tomato lines harbouring PgNHX1 and AtAVP1 genes showed higher chlorophyll and proline accumulation 1.4 times higher under salt stress compared to single-gene transformants. Furthermore, the double transgenic plants showed 1.5 times higher accumulation of Na+ content in their leaf compared to single-gene transformants. The PgNHX1 and AVP1 co-expression enhanced the osmoregulatory capability of double transgenic lines by enhancing ion sequestration into the vacuole by increasing the proton availability and, thus, reducing the Na+ toxic effect. Recently, Viveros et al. [118] co-expressed the BjGlyI and PgGlyII genes in tomato, cv. Ailsa Craig, respectively, from Brassica juncea and Pennisetum glaucum to enhance salt tolerance. The GlyI and GlyII overexpressing double transgenic lines under 800 mM NaCl concentration showed decreased H2O2 accumulation and lipid peroxidation in leaf tissues. They also reported a significant decrease in the chlorophyll a and b content in wild-type (WT) than the line co-overexpressing GlyI and GlyII. The GlyI and GlyII gene are a component of the glyoxalase system, which plays a significant role in different physiological processes and enhances abiotic stress tolerance, including salt, by reducing oxidative damage. Baghour et al. [128] developed LeNHX2 and SlSOS2 co-overexpressing tomato, cv. MicroTom, respectively, from Solanum esculentum and Solanum lycopersicum to increase salt tolerance and production. The double transgenic tomato co-overexpressing LeNHX2 and SlSOS2 exhibited greater salt tolerance than LeNHX2- or SlSOS2-expressing tomato lines at 120 mM NaCl concentration in hydroponics and, also, in pot experiment with successive salt irrigation (120 mL of 75 mM NaCl thrice per week for eight weeks). They observed enhanced physicochemical performance of double transgenic tomato lines under salt stress. Earlier, we pyramided [14,23] AtDREB1A and BcZAT12 gene under the control of ectopic promoter rd29 and lea1, respectively. We noted that the tomato lines independently expressing AtDREB1A and BcZAT12 genes showed higher drought stress tolerance compared to the tomato expressing individual genes, either AtDREB1A or BcZAT12. The findings of Krishna et al. [14,23] also suggest that the multigenic transgenic tomato can be a potential tool against the drought stress as they regulate different regulatory pathways under drought stress.

2.2.4. Genome Editing in Tomato for Drought Stress Tolerance

Recently, the development of clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein (Cas) (CRISPR/Cas9)-mediated genome editing opened the new avenue of vegetable improvement for virus resistance. CRISPR–Cas9 is the most studied system, and the endonucleolytic complex (Cas9-guide RNA (gRNA)-tracer RNA (tracRNA) is programmable for the site-specific dsDNA cleavage. Any target in the DNA sequence followed by NGG (the protospacer adjacent motif, PAM) can be cleaved by Cas9–sgRNA (engineered single-guide RNA) complex [129,130]. The 20 nt sequence of the sgRNA complementary to the target DNA works as a guide and the stem-loop scaffold binds and activates Cas9 for sequence-specific nuclease activity. The CRISPR/Cas9 edits the host tomato plant gene(s) and provides molecular immunity against the drought stress. In host tomato plant, there are many genes reported which positively regulate drought stress tolerance by encoding protein(s), which facilitates [130,131,132] edited tomato SlNPR1 gene via CRISPR/Cas9 and reported a higher drought stress tolerance in SlNPR1 edited lines. The SlNPR1 gene encodes for nonexpressor of pathogenesis-related protein 1, its regulatory mechanisms are well studied in the case of biotic stresses; however, in case of drought stress, it is still unexplored. Recently, Liu et al. [130] edited tomato SlLBD40 gene and found that the mutants were displaying drought tolerance even after stopping irrigation for 10 days. Tomato SlLBD40 is a plant-specific transcription factor, which regulates stomatal conductance. The mutation in SlLBD40 reduces the stomatal conductance. Earlier, Chen et al. [132] mutated tomato SlARF4 gene, a gene encoding auxin response factors using CRISPR/Cas9 and they reported that mutants were showing higher drought tolerance after stopping irrigation for 12 days. The tomato SlARF4 plays important roles in different physiological processes of tomato plants, although the exact function of SlARF4 still unknown under drought stress. The genome editing in tomato is underway for the development of drought stress tolerance and there are very few reports available on tomato. Therefore, there is need for the identification of tomato gene(s) and their pathway for drought stress tolerance. The identification of gene(s) and pathways will facilitate the multigene editing for drought stress tolerance.

3. Yield Potential of Transgenic Tomato under Drought Stress

Being frequent and uncertain, drought stress potentially reduces the tomato yield and quality. To fulfil global tomato demands and ensure tomato fruit quality, transgenic technology is applied. The ultimate goal of introducing transgenic technology is to maintain genetically predetermined yield and quality in tomatoes. The development of fruits in tomato is itself a very complex biological process and governed by genes of auxins, gibberellins, and ethylene and the yield of tomato mainly depends on the expression of OVATE, SUN, EJ2, CNR, SlKLUH, and CSR genes, which regulate fruit shape and weight [133]. Drought reduces yield in tomato by delaying physiological processes; to overcome this, a number of transgenes have been introduced in tomato having different modes of action, such as ROS detoxification, osmoprotective, water use efficiency, water loss reduction, etc. [13]. In 2003, AtCBF1 regulated by ABA/stress-inducible promoter was transformed in tomato by [134] to discover the yield potentiality and survival under drought stress. After four-week exposure to drought by withholding irrigation, they found that transgenic tomato lines viz. AC1, AC2, and AC3 yielded 102.2, 115.0, and 101.0 g per plant, respectively, while, under the same condition, wild type yielded only 32.0 g. Furthermore, transgenic tomato lines also excellently survived compared to wild type AC1, 25; AC2, 28; AC3, 29; and wild type, 0 plants out of 30 plants. The CBF1 is a transcription factor that regulates multiple molecular pathways under drought stress to modulate the drought and improve plant growth and development. Tomato variety Yaxin 87−5 was transformed by using Christolea crassifolia HARDY, a AP2/ERF-like tanscritpion factor (HARD gene), by Guo et al. [65]; they reported that the transgenic tomato lines expressing HARDY have better plant growth attributes and yielded 38.65–44.65% higher compared to the wild type, respectively, after 16 days of drought stress. Wang et al. [135] developed transgenic tomato by using MdPIP1;3 an aquaporin gene from Malus domesticus, and they evaluated yield potential of transgenic tomato under artificially induced drought by stopping irrigation for 20 days (control 43–45% soil moisture content and drought 0.5 to 1%) and reirrigated to maintain 43–45% soil moisture. They reported that the fruits of transgenic tomatoes are heavier and larger than wild type and the yield was approximately 1.2% higher under drought stress than wild type. They also reported that 77% of transgenic lines’ tomato stomata became closed, while, in wild type, 65% stomata remained open. Thus, transgenic tomato managed drought stress and the aquaporin translocated more water in fruits during developmental stages. Improving water use efficiency in tomato is considered as a potential tool to cope with drought stress. Kelly et al. [136] transformed tomato (cv. MP-1) with A. thaliana guard-cell hexokinase (AtHXK1) and they reported that the expression of AtHXK1 in tomato gourd cell improved water use efficiency by 10–20% under drought stress. Earlier, we [14] evaluated transgenic tomato expressing AtDREB1A and BcZAT12 individually and in pyramided form (AtDREB1AXBcZAT12) for yield potential under drought stress (0, 7, 14, and 21 days of irrigation withholding; soil moisture contents were 80, 40, 25, and 15% of the field capacity, respectively). We reported that the increasing intensity of drought potentially reduced the tomato yield in all the transgenic lines and wild type, but the decrease was high in wild type. Under 25% moisture content AtDREB1A and BcZAT12 transgenic tomato lines yielded approximately 1.8 times, and AtDREB1AXBcZAT12 lines approximately 3 times higher yield than wild type at similar moisture content. This higher yield in AtDREB1AXBcZAT12 lines were probably due to independent mechanisms of molecular pathway regulation by AtDREB1A and BcZAT12 genes. Thus, the transgenic tomato plants have yield potential under drought stress and can play an important role in water management and fulfilling tomato needs. Furthermore, the transgenic tomatoes must be scientifically evaluated for bio and environment safety to resolve social and ethical issues related to the transgenic tomatoes.

4. Conclusions and Future Prospects

Due to climate change, the frequency of uncertain and uneven rain fall increasing over time, this phenomenon will make drought very severe in coming times. Drought stress affects almost every crop, including tomato. Being a plant model system, tomatoes are extensively utilized to understand plant biological processes, such as functional genomics, proteomics, and metabolomics. In recent years, extensive work has been carried out in tomato at the molecular level to cope with drought stress and numerous transgenic tomatoes developed by utilizing microbial and nonhost plant gene(s). Recently developed CRISPR/Cas9-mediated genome editing in tomato avoids introduction of transgene and can edit the host plant genome for specific gene(s) up- or downregulation for the drought stress tolerance; hence, it is safer than transgenic technology. The CRISPR–Cas9-mediated genome editing for drought stress tolerance will insure ecologically and economically friendly quality tomato production under drought stress and will be helpful for food and nutritional security.
In future, to fulfil continuous tomato fruit demand, there is need for modification of the tomato genome through transgenic technology and genome editing approaches. It is well established that manipulation of single or multiple genes in tomato improved the drought stress tolerance. Furthermore, targeting drought-stress-related gene(s) will not be enough to ensure sustainable tomato production, as other abiotic stresses, such as salt, heat, and cold, also share water scarcity due to different physiological phenomena. Therefore, multiple abiotic stresses should be targeted to ensure tomato survival under adverse environmental conditions and give potential yield. There is also a need for better understanding about the different molecular, biochemical, and metabolite(s) identification involved in different abiotic stresses. A deeper understanding of stress tolerance mechanism in tomato by metabolomics is required, which could open new avenues of metabolic pathway manipulation to develop abiotic stress tolerance in tomato. The manipulation of metabolic pathways is quite difficult due to the majority of proteins of a pathway interacting with the proteins of other pathways. Therefore, metabolic pathway manipulation will only be possible by controlling multiple genes of the same pathway or other interlinked pathways. Transgenic crops have been cultivated in United States of America for more than two decades, and one decade in India, without any reported harmful impact on human beings and the environment but the path of new genetically modified tomatoes to a farmer’s field is not smooth. The transgenic tomatoes have survival and yield potential under drought stress but their global acceptance is under question at the global level because of social, ethical, and political issues. Therefore, there is need for in-depth understanding about science, mode of action behind the transgenes, and all the possible studies related to the safety of transgenes and their harmlessness. Hence, there is urgent need to raise awareness among the farmers and citizens about the benefits of transgenic crops on a scientific basis. It also important to develop understanding among the public that the transgenic crops are safe for both human beings and the environment with the help of facts and biosafety data recorded on transgenic crops. The commercial release of Bt brinjal in Bangladesh is an excellent example of tackling such hurdles successfully by inviting a representative of the opposing organisations at every developmental stage of Bt brinjal and scientific clarification of their doubts. Such type of activities would raise awareness about the safety process evaluation of transgenic crops. The scientific document should bring in the public domain, answering each and every doubt of opponents and farmers in an easy form. Finally, great efforts are needed for harvesting the fruits of this wonderful technology in coming time.

Author Contributions

R.K.; J.P.V.; A.K.S. and M.S. conceptualize the manuscript’s contents; R.K.; W.A.A.; P.S.S.; A.Y.; D.K.J. and S.K. helped in data collection and preparation of the first draft. R.K.; W.A.A.; A.K.S.; J.P.V. and M.S. did the final editing of the manuscript. 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

This study is a review article and contents no supporting data, all the literatures were cited within the manuscript from where the details were taken.

Conflicts of Interest

All authors are aware of this communication. This is an original review article and there is no conflict of interest among the authors with each other.

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Figure 1. The overall impact of drought stress on tomato plant growth.
Figure 1. The overall impact of drought stress on tomato plant growth.
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Figure 2. Mechanism involved in drought stress tolerance.
Figure 2. Mechanism involved in drought stress tolerance.
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Table
Table 1. Transgenes used for development of drought stress tolerance, their function, and mechanism of action.
Table 1. Transgenes used for development of drought stress tolerance, their function, and mechanism of action.
S. No.GeneFunctionMechanism of ActionReference
1CBF1Stress-inducible transcription factorsExpression of stress-responsive gene[55]
2H1-S, drought induced linker histoneDNA packaging and organisation of chromosomes in the nucleusModulation of mechanisms related to the stomatal function[56]
3AtCBF-1Stress-inducible transcription factorsExpression of stress-responsive gene[57]
4H+-pyrophosphataseFacilitate auxin fluxesEnhance pyrophosphate-driven
cation transport into root vacuolar fractions 		[58]
5bspAProtein protectionEnhance desiccation tolerance by protecting proteins in membranes and cytosol[48]
6codaAccumulation of glycine betaineOsmolyte accumulation to protect against oxidative damage.[59]
7LeNCED1Increase in abscisic acid
(ABA) accumulation		Stomatal closure and increased water-use efficiency (WUE)[59]
8OsmotinStress-responsive multifunctional proteinOsmotin provides protection via different mechanisms related with programmed cell death[47]
9PtADCInduce the stress-responsive geneImproves dehydration and drought tolerance[60]
10DREBs/
CBFs; ABF3		Stress-induced transcription factorsEnhanced expression of downstream stress-related genes confers drought tolerance.[19]
11ZAT12Stress-induced transcription factorsEnhanced expression of downstream stress-related genes confers drought[27]
12AtGAMT1Suppress gibberellinGAMT1 overexpression inhibited the expansion of leaf epidermal cells.[61]
13SlNAC4Stress-responsive transcription factorModulation of ABA-independent signaling networks[62]
14GalURGalUR encodes Lgalactono-
1,4-lactone as a precursor of ascorbic acid		Ascorbic acid detoxifies superoxide anion radical and hydroxyl radical and also plays a crucial role in scavenging
ROS		[63]
15EgDREB1Enhances the expression of DRE/CRT and DRE/CRT-containing genesElevated level of antioxidative enzymes scavenge the superoxide radical and accumulation of nonenzymatic antioxidants maintains the cell basic structure under drought and cold stress [64]
16CcHRDAP2/ERF-like tanscritpion factorRegulate many pathways involved in stress tolerance[65]
17SlMAPK1Encodes for mitogen-activated protein kinasesSlMAPK1 improves drought stress tolerance by activating antioxidant enzymes, reducing oxidative damage, and modulating transcription of stress-related genes.[66]
18SiDHNEncodes for Dehydrins (DHNs) commonly
hydrophilin LEA proteins		Increased chlorophyll a and b, carotenoid and relative water, proline
and soluble sugar content and improve photosynthetic efficiency and suppress the formation of malondialdehyde
H2O2 and O2		[67]
19MdSWEET17Sugar transportersEnhances accumulation of sugars, such as glucose and fructose, which act as osmoprotestants and carbon source under drought stress[68]
20SlSAMS1S-adenosylmethionine synthetase (SAMS)SlSAMS1 modulates the production of polyamines and H2O2 and maintains the cellular homeostatasis[69]
21AtDREB1A and BcZAT12Encodes for transcription factorsIndependent expression of AtDREB1A and BcZAT12 gene enhances drought tolerance in tomato[14,23]
22SlGATA17Improves phenylpropanoid biosynthesis pathway activityDNA-binding domain of GATA
TFs regulates many pathways in plants and enhances drought stress tolerance		[70]
23CsECREncodes for enoyl-CoA reductase (ECR) enzyme, which is involved in biosynthesis of cuticular waxes and catalyses the last step of very long-chain fatty acids (VLCFAs) elongationEctopic overexpression of CsECR increased the contents of total waxes and aliphatic wax leaves and fruits of the transgenic tomato and improves drought tolerance[71]
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Krishna, R.; Ansari, W.A.; Soumia, P.S.; Yadav, A.; Jaiswal, D.K.; Kumar, S.; Singh, A.K.; Singh, M.; Verma, J.P. Biotechnological Interventions in Tomato (Solanum lycopersicum) for Drought Stress Tolerance: Achievements and Future Prospects. BioTech 2022, 11, 48. https://0-doi-org.brum.beds.ac.uk/10.3390/biotech11040048

AMA Style

Krishna R, Ansari WA, Soumia PS, Yadav A, Jaiswal DK, Kumar S, Singh AK, Singh M, Verma JP. Biotechnological Interventions in Tomato (Solanum lycopersicum) for Drought Stress Tolerance: Achievements and Future Prospects. BioTech. 2022; 11(4):48. https://0-doi-org.brum.beds.ac.uk/10.3390/biotech11040048

Chicago/Turabian Style

Krishna, Ram, Waquar Akhter Ansari, P. S. Soumia, Akhilesh Yadav, Durgesh Kumar Jaiswal, Sudhir Kumar, Achuit Kumar Singh, Major Singh, and Jay Prakash Verma. 2022. "Biotechnological Interventions in Tomato (Solanum lycopersicum) for Drought Stress Tolerance: Achievements and Future Prospects" BioTech 11, no. 4: 48. https://0-doi-org.brum.beds.ac.uk/10.3390/biotech11040048

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