Abstract
Salinity stress adversely affects plant growth and causes considerable losses in cereal crops. Salinity stress tolerance is a complex phenomenon, imparted by the interaction of compounds involved in various biochemical and physiological processes. Conventional breeding for salt stress tolerance has had limited success. However, the availability of molecular marker-based high-density linkage maps in the last two decades boosted genomics-based quantitative trait loci (QTL) mapping and QTL-seq approaches for fine mapping important major QTL for salinity stress tolerance in rice, wheat, and maize. For example, in rice, ‘Saltol’ QTL was successfully introgressed for tolerance to salt stress, particularly at the seedling stage. Transcriptomics, proteomics and metabolomics also offer opportunities to decipher and understand the molecular basis of stress tolerance. The use of proteomics and metabolomics-based metabolite markers can serve as an efficient selection tool as a substitute for phenotype-based selection. This review covers the molecular mechanisms for salinity stress tolerance, recent progress in mapping and introgressing major gene/QTL (genomics), transcriptomics, proteomics, and metabolomics in major cereals, viz., rice, wheat and maize.
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Introduction
Crop plants experience many biotic and abiotic stresses at different stages during their life cycle. Like other major abiotic stresses (drought and heat), soil salinity threatens global food security, affecting one-quarter to one-third of global crop production (Munns 2002; Abbasi et al. 2015). Soil salinity affects plant growth and development, decreasing agricultural production worldwide (Zhu 2001; Wang et al. 2019; Zhang et al. 2021). More than 800 million hectares of land are affected by salinity, accounting for 6% of the earth’s total land area and 20% of the total cultivated land area (Munns and Tester 2008; Sandhu et al. 2020; Zhang et al. 2021). The saline area is expected to increase due to the application of high salt irrigation water owing to insufficient rainfall and poor agricultural practices (Luo et al. 2017; Zhang et al. 2021), particularly in arid and semi-arid areas with higher evapotranspiration than precipitation (Hanin et al. 2016; Kashyap et al. 2017; Jha et al. 2019). In addition, the climate change-induced rise in mean sea level results in flooding, especially in coastal areas causing soil salinity (Nicholls et al. 2011; Church et al. 2003). Salt-affected land is estimated to reach 50% of the total arable area by 2050 (Wang et al. 2003; Shrivastava and Kumar 2015; Kumar and Sharma 2020), making it challenging to meet the projected food production needs for the increasing human population (Tnay 2019).
Rice, wheat, and maize are the most important cereal crops, accounting for >50% of the world’s calorie consumption (Gibbon 2012; Luo et al. 2019). Human consumption accounts for 85% of total rice, 72% of total wheat, and 19% of total maize production (http://www.knowledgebank.irri.org). Globally, wheat is ranked first for area planted, maize for production, and rice for production value (Benavente and Giménez 2021). The demand for major cereal crops will increase threefold by 2050 to feed nine billion people. However, salt stress is a major concern for cereal crop production globally as it affects different plant growth stages and leads to abnormalities at the phenotypic, morphological, biochemical, and physiological levels (James et al. 2011). Rice is more sensitive to salt stress than maize (moderately sensitive) and wheat (moderately tolerant). Hence, to address yield losses due to salinity, development of salt-tolerant cultivars (without yield penalty under salt-stressed conditions) is an important requirement (Kashyap et al. 2017; Jha et al. 2019). Conventional breeding has had limited success due to the complex genetic nature of salt tolerance. Recent advances in ‘omics’ technologies, such as genomics, transcriptomics, metabolomics, and QTLomics, can help identify key genes and biomolecules regulating salt tolerance (Ahmad et al. 2016).
Several studies have reviewed various aspects of salt tolerance in different crops (Jha et al. 2019; Gupta et al. 2020; Chen et al. 2021b; Singh et al. 2021), but none have comprehensively integrated the literature on the application of all omics approaches for salt stress tolerance in major cereal crops, viz., rice, wheat, and maize. Here, we review, the impact of salinity on the growth and development of rice, wheat and maize, the adaptive mechanisms involved, and progress in genomic-assisted breeding for salinity stress tolerance in cereal crops. Recent progress in transcriptomics and proteomics is also discussed to reveal the candidate genes and proteins imparting salinity stress tolerance in wheat, maize and rice. The comparative assessment of candidate genes or proteins across the major cereal crops revealed key common genes imparting salinity stress tolerance. Hence, this comprehensive review will serve as a useful guide for salinity breeders to understand the common genes/proteins imparting salinity stress tolerance.
Impact of soil salinity on cereal crops
Soil salinity is defined as a high concentration of solute salts in soils, causing more than 4 dS/m electric conductivity. Salinity adversely affects plant growth and development through its effect on physiological and biochemical pathways (Nabati et al. 2011), severely constraining major cereal crop production, with yield losses of 60% in wheat (Triticum aestivum L.) (El-Hendawy et al. 2017) and 50% in rice (Oryza sativa L.) (Van Genuchten and Gupta 1993), and reductions of 51.43% dry weight and 53.18% leaf area, in maize (Zea mays L.) (Hussein et al. 2007). However, the extent of crop damage varies with salt-stress timing, crop growth stage, plant type and genotype, and climatic conditions (Shahverdi et al. 2018). Each crop has a salt tolerance threshold level measured as the electrical conductivity of a saturated paste of soil (ECe). Rice is the most sensitive crop to salinity (3 dS/m) (Munns and Tester 2008), maize is moderately sensitive (1.8 dS/m) (Rhoades et al. 1992), and wheat is moderately tolerant (6 dS/m). However, the threshold varies depending on the target trait and crop growth stage (Fig. 1b).
Rice is sensitive to salinity particularly at the seedling and panicle initiation to flowering stages (Moradi et al. 2003), whereas wheat is the most vulnerable to salinity during early development (i.e., germination) (Oyiga et al. 2016), hampering water and nutrient uptake, and thus affecting crop growth (Meena et al. 2020). Maize is most vulnerable to salinity stress during germination and seedling establishment; however, at later stages, salinity stress results poor kernel set and reduced grain weight and number, reducing overall yield (Farooq et al. 2015). Under saline conditions, the high concentration of sodium (Na+) ions leads to unbalanced cellular homeostasis, nutrient deficiency, and oxidative stress, affecting growth and causing cell death (Ahanger and Agarwal 2017). Salinity drastically hampers photosynthesis, causing stomatal closure (Munns and Tester 2008), chlorophyll malfunctioning (Jiang et al. 2012), and disrupting the enzymatic machinery of photosynthetic apparatus (Mittal et al. 2012), and chloroplast structure (Quintero et al. 2007; Gengmao et al. 2015). Various studies have revealed that high concentrations of Na+ and Cl– ions in cell sap stimulate a lower osmotic gradient in the nutrient medium, reducing water and nutrient uptake and drastically affecting plant morphological traits (Cantabella et al. 2017; Sapre et al. 2018).
Adaptive mechanisms for salinity stress tolerance
Several physiological, biochemical, and molecular mechanisms are involved in the crop response to salt stress (Munns and Tester 2008, Jha et al. 2019) which can be classified into three main categories (Fig. 2): (1) osmotic tolerance—long-distance signals that reduce shoot growth and positively regulate the production of compatible solutes to maintain leaf expansion and stomatal conductance (Blum 2017); (2) ion exclusion—Na+ transport mechanism in roots that prevents Na+ accumulation reaching to toxic levels in leaves (Munns and Tester 2008); (3) tissue tolerance—high salt concentrations present in leaves but Na+ compartmentalize at the cellular and intracellular level (especially in vacuoles). Osmoprotectant mechanisms include proline and glycine betaine accumulation in maize (Farooq et al. 2015; Iqbal et al. 2020) and reactive oxygen species (ROS) scavenging, glycine betaine accumulation, and hormone modulation in wheat (Shahid et al. 2020). The major genes involved in salt exclusion are salt overlay sensitive (SOS) homologs (OsSOS1, OsCIPK24, and OsCBL4) in rice (Martínez-Atienza et al. 2007), TaSOS1 and TdSOS1 in wheat (Xu et al. 2008; Feki et al. 2011) and ZmNHX7 as a Na+/H+ antiporter in maize (Bosnic et al. 2018). The NHX group of tonoplast-based Na+/H+ exchangers render the vacuolar sequestration of Na+. Overexpression of OsNHX1 and OsVP1 improved salinity tolerance in rice. Similarly, several Na+ sequestration NHX genes were characterized in the vacuoles, including five NHX genes in rice (OsNHX1 to OsNHX5) (Fukuda et al. 2011), four in wheat (TaNHX1, TaNHX2, TaNHX3, and TaNHX4-B) (Brini et al. 2007; Lu et al. 2014; Sharma et al. 2020) and six in maize (ZmNHX1 to ZmNHX6) (Zörb et al. 2005). High-affinity potassium (HAK) transporters also help to induce salt tolerance; 27 HAK genes in rice and maize (Yang et al. 2014, 2020; Zhang et al. 2012), and 56 in wheat were reported (Cheng et al. 2018; Amirbakhtiar et al. 2019). Besides ionic mechanisms, phytohormone-mediated salt tolerance mechanisms are well documented in rice, wheat, and maize, such as abscisic acid, salicylic acid, and jasmonic acid in rice (Yang and Guo 2018; Quilis et al. 2008; Kurotani et al. 2015), wheat (Shakirova et al. 2003) and maize (Iqbal et al. 2020; Ahmad et al. 2019).
Genomics-assisted breeding for salinity stress tolerance
Genomics-assisted breeding involves genomic mapping and subsequent introgression to develop improved cultivars. Mapping quantitative trait loci (QTL) is an important approach for understanding the genetic basis of different complex traits governed by multiple genes. Salinity stress tolerance is controlled by polygenes and hence exhibits quantitative inheritance (Jha et al. 2019; Ganie et al. 2019). The availability of molecular markers, mainly microsatellites or simple sequence repeats (SSRs) and, more recently, single nucleotide polymorphism (SNP), facilitate mapping studies. QTL mapping and other mapping approaches, such as association mapping and Bulk-seq/QTL-seq (using extreme, i.e., low and high performing, bulks), have been used extensively to map salt tolerance associated traits, particularly in rice (Prakash et al. 2020).
Mapping major QTL: current status
Numerous minor QTL have been identified using bi-parental mapping populations and association panels, but major QTL are limited (see Tables 1 and 2). Various component traits govern salt tolerance at the seedling stage in rice, particularly root and shoot Na+ and potassium (K+) concentrations, Na+ and K+ uptake, root and shoot length, and leaf chlorophyll concentration (Van Zelm et al. 2020). At the reproductive stage, traits such as root and shoot biomass, grain and straw yield, leaf chlorophyll content, days to flowering, tiller number, and spikelet fertility are typically considered important (Hernández 2019; VanZelm et al. 2020). Several standard visual scoring methods or selection indices (based on key traits), such as the stress susceptibility index (SSI), salt tolerance score (STS), salt injury score (SIS) and salt tolerance ranking (STR) reflect overall plant growth and development, and hence can be used to classify germplasm.
Bulk segregant analysis (BSA)
BSA-based approaches are quick and effective for mapping major QTL, as evident in rice (Michelmore et al. 1991; Choudhary et al. 2019). Tiwari et al. (2016) performed BSA-based mapping using 6068 polymorphic SNPs in CSR11 and MI48 based recombinant inbred line (RIL) populations to identify 21 QTL associated with salt tolerance. Recently, Wu et al. (2020) performed BSA-based QTL mapping to map the loci qST1.1 contributing to salt- tolerance in ‘Sea Rice 86’. Sun et al. (2019) used a QTL-seq approach and two extreme bulks from a segregating population of ‘Changmaogu’ (salt-tolerant) and ‘Zhefu802’ (salt-susceptible) to identify six candidate genes associated with salt tolerance on rice chromosome 1. They identified OsPP2C8 (Os01g0656200) as a candidate gene with sequence polymorphism in ORFs, differentially expressed at the seedling stage. Lei et al. (2020) mapped a major QTL qRSL7 for relative shoot length on chromosome 7 using a QTL-seq approach in an F2:3 population (‘IR36’ × ‘Weiguo’). Furthermore, Lei et al. (2020) identified a candidate gene Os07g0569700 (OsSAP16) using an RNA-seq and sequence variation approach for salt tolerance. In wheat, Shamaya et al. (2017) conducted BSA using 9K SNP markers to map two major loci for third leaf Na+ concentration on chromosomes 3B and 4B, with the gene on 4B likely to be a high-affinity K+ transporter (HKT1;5-B1).
QTL mapping: Classical approach
Rice
QTL mapping for salt tolerance at the seedling and reproductive stages in rice used mapping populations derived from a cross between salt-tolerant and salt-sensitive genotypes (Singh et al. 2007). Several salt-tolerant rice genotypes, including ‘Nona Bokra’ (Puram et al. 2018), ‘Jiucaiqing’ (Wang et al. 2012), ‘CSR27’ (Pandit et al. 2010), ‘Pokkali’ (Chen et al. 2019), ‘Gharib’ (Ghomi et al. 2013), ‘Changbai10’ (Zheng et al. 2015), ‘Capsule’ (Rahman et al. 2019), ‘Changmaogu’ (Sun et al. 2019), ‘Kalajoha’ (Mazumder et al. 2020), ‘Sea Rice 86’ (Wu et al. 2020) and ‘Hasawi’ (Rahman et al. 2017), have been used to map traits associated with seedling stage salt tolerance (Table 1).
‘Hasawi’ (Bimpong et al. 2014), ‘Pokkali’ (Khan et al. 2015), and ‘CSR10’ (Pundir et al. 2021) were used as the tolerant parent for mapping salt-tolerance associated traits at the reproductive stage. ‘Pokkali’ is salt-tolerant at the seedling and reproductive stage (Table 1). QTL have been identified in the mapping populations using QTL mapping or a whole-genome resequencing-based QTL-seq approach (Krishnamurthy et al. 2020). In rice, ‘Saltol’ on chromosome 1 is the most commonly occurring QTL governing salt tolerance at the seedling stage (Babu et al. 2017b). The ‘Saltol’ genomic region has been well characterized in several landraces and genotypes (Manohara et al. 2021). A major QTL, qSSISFH8.1, on chromosome 8 (flanked by HvSSR08-25 and RM3395) governing SSI for spikelet fertility under salinity stress at the reproductive stage can be used to impart salt tolerance (Pandit et al. 2010; Pundir et al. 2021). Identified QTL on chromosomes 2, 3, 4, 9, 10, and 11 at the seedling and reproductive stage indicate that these chromosomes are relatively more important for harboring genes for seedling and reproductive stage salinity tolerance in rice (Table 1).
Wheat
QTL mapping efforts in wheat identified >500 QTL (distributed over 21 chromosomes) for salinity tolerance associated traits, with a few dozen major QTL explaining more than 10% of the phenotypic variance (Gupta et al. 2020; Singh et al. 2021). Since 2011, 16 QTL mapping studies have been published, most focusing on salt tolerance at the seedling stage (Table 1). Hussain et al. (2017) reported a major QTL, qSNAX.7A.3, for shoot dry weight, a commonly used direct measure of salinity stress tolerance. Asif et al. (2018) detected three major QTL, QG(1–5), asl-7A (relative growth rate), QNa.asl-7A (leaf Na+ concentration), and QK.asl-5A (leaf K+ concentration), in an ‘Excalibur’ × ‘Kukri’ doubled haploid (DH) population. QK.asl-5A was in the vicinity of the vernalization response gene (Vrn-A1), but QG(1–5).asl-7A was the prominent QTL, present in six of 44 Australian bread and durum wheat cultivars. Devi et al. (2019) identified 25 QTL under sodic conditions using RILs derived from ‘HD2009’ and ‘Kharchia 65’. The study revealed the linkage of SSR marker gwm 26 for K+ content (QSK+.iiwbr-2D) and cfd 84 for tiller number (QStn.iiwbr-4D) and earhead number (QSne.iiwbr-4D). Ilyas et al. (2020) mapped 60 QTL; four (for total chlorophyll, water potential, and Na+ content) were located on chromosome 6B in the vicinity of gwm70 and Xbarc361 markers; hence, chromosome 6B is a good source of salinity stress tolerance in wheat. Recently, Luo et al. (2021) used a wheat 55K SNP array to map 90 stable QTL for 15 agronomic traits in a ‘Zhongmai 175’ × ‘Xiaoyan 60’ RIL population screened under low and high levels of salt stress at the adult stage. Eight QTL from four QTL clusters were validated in natural populations, and competitive allele-specific PCR (KASP) markers were designed for three QTL clusters. Hence, many major QTL are now available in wheat (more than maize but fewer than rice) (Table 1). In wheat, chromosomes 3A, 5B, and 6B possess QTL for salt-tolerance-associated traits at the seedling and adult stage (Table 1), which are relatively anticipated to harbor multi-stage tolerance.
Maize
There are limited QTL mapping studies on salinity stress tolerance in maize (Table 1). Two major QTL, QFgr1 and QFstr1, for field germination rate and field tolerance ranking, respectively, were mapped on chromosome 1 using ‘F63’ × ‘F35’ based RILs phenotyped under saline field conditions. Nine conditional QTL for shoot fresh weight, tissue water content, shoot Na+ concentration, shoot K+ concentration, and shoot K+/Na+ ratio were mapped on chromosomes 1, 3, 4, and 5 (Cui et al. 2015b). Luo et al. (2017) identified a major QTL for plant height, qSPH1 (with phenotypic variance of 31%), on chromosome 1 under saline conditions. The study also identified a major QTL for a plant-height-based salt tolerance index on the same chromosome and two candidate genes, GRMZM2G007555 and GRMZM2G098494, that code for ion homeostasis regulation likely associated with salt tolerance. A major QTL, ZmNC1 conferring leaf Na+ concentration, was reported on chromosome 3 in RILs derived from crossing ‘Zheng58’ and ‘Chang7-2’ (Zhang et al. 2018). The authors also performed transcriptomic analysis to identify a plasma-membrane-localized class I HKT ion transporter (ZmHKT1) as a putative candidate gene for ZmNC1. Later, 65 QTL were mapped for biomass-related traits under salinity stress, with 13 major QTL (for nine salt-tolerance-related traits) on chromosome 1, explaining more than 21% of the phenotypic variation (Luo et al. 2019). Hence, the 17 QTL identified on chromosome 1 can be targeted for introgression to develop salt-tolerant maize cultivars.
Association mapping to identify candidate genes for salinity stress tolerance
The exploitation of historical recombination events through association mapping (AM) or genome-wide association studies (GWAS) has been instrumental in identifying genomic regions responsible for specific traits in various crop species, and salt tolerance is not an exception (Table 2). GWAS has been used widely in cereal crops (Gupta et al. 2014) to identify genes related to abiotic stress tolerance (Kumar et al. 2015; Frouin et al. 2018; Gupta et al. 2020). More GWAS studies for salinity stress tolerance have been conducted in rice than wheat or maize, as rice is the most salt-sensitive (Table 2).
Rice
In an AM panel of 220 rice accessions, mostly indica type, Kumar et al. (2015) identified novel salt-tolerance-related marker-trait associations (MTAs) on chromosomes 1, 4, 6, and 7. Another AM panel of 208 rice accessions from the mini core collection was used (Naveed et al. 2018) to identify 20 MTAs associated with 11 salt-tolerance-related traits. Mild seedling stage salinity stress tolerance was used to map associated genes in a panel of 235 temperate japonica rice accessions (Frouin et al. 2018). After the release of the 3K rice genome sequence, Batayeva et al. (2018) used 203 temperate japonica rice accessions to identify 26 MTAs for nine salt-tolerance-related traits at the seedling stage. Most of the QTL were located close to the genes governing kinase and calcium signaling and metabolism. In another study using a large panel of 708 rice accessions, five known (OsSUT1, OsMYB6, OsHKT1;4, OsGAMYB, and OsCTR3) and two novel (LOC_Os02g49700 and LOC_Os03g28300) genes were significantly associated with yield and related traits under salinity stress at the seedling stage (Liu et al. 2019). A panel of 104 Thai rice accessions of indica rice was evaluated to identify candidate genes related to salinity stress tolerance at the flowering stage; the genes were mainly distributed on chromosomes 1, 2, 8, and 12 (Lekklar et al. 2019). A study using a large panel of 664 accessions from the 3K Rice Genome Project and high-density genotypic data of 17 million SNPs identified 21 QTL with two candidate genes (OsSTL1 and OsSTL2) confirmed via sequence analysis (Yuan et al. 2020). An evaluation of accessions under hydroponic and soil media identified 97 and 74 QTL, respectively, with 11 QTL common to both (Chen et al. 2020). The most significant QTL on chromosome 1 harbored two post-translational modification genes, OsSUMO1 and OsSUMO2. Warraich et al. (2020) identified genomic locations responsible for several salt-tolerance-associated traits, including Na+, K+, Ca2+, and Mg2+ content, in leaves and stems at the reproductive stage. Recently, Nayyeripasand et al. (2021) identified 29 genomic regions for salinity stress tolerance in a panel of 155 rice varieties, including two and three novel candidate genes on chromosomes 8 and 1, respectively. The above GWAS studies involved different mapping panels, which should help better understand the mechanisms of salinity stress tolerance in rice.
Wheat
Using natural recombination events, a panel of 150 wheat accessions was genotyped with the 90K SNP chip identified 37 QTL for salt-tolerance-related traits at three growth stages, i.e., germination, seedling, and adult (Oyiga et al. 2018). In another mapping panel of 100 bread wheat, seven SNPs were associated with genes (four candidate genes) linked to Na+ accumulation/exclusion. Hu et al. (2021) conducted GWAS at the adult plant stage using a panel of 191 accessions to establish 11 QTL for salt-tolerance-related traits. Significant SNPs were validated using two RIL populations.
Maize
Fewer studies on salinity stress tolerance have been conducted in maize than rice or wheat (Table 2). In a candidate-gene-based AM approach, a panel of 54 diverse Chinese inbred lines was used to find associations with sequence variation (two SNPs within the coding region) in the ZmHKT1-5 gene for salinity stress tolerance (Jiang et al. 2018). In another study, 57 SNPs had significant associations with early-vigor-related traits, with 40 associated with shoot-biomass-related traits (Sandhu et al. 2020). Cao et al. (2020) genotyped a panel of 419 inbred lines with 55K chip-based SNPs to reveal two closely located SNPs significantly associated with shoot Na+ content (candidate gene ZmNSA1 conferring shoot Na+ content variation). Recently, Liang et al. (2021) conducted metabolic GWAS to identify 37 metabolite biomarkers and 10 candidate genes for salt-induced osmotic stress tolerance.
Genomic selection for salinity stress tolerance in cereals
Genomic selection (GS) is an efficient tool for assessing the breeding value of a genotype based on its sequence information (Goddard and Hayes 2007). It is a practical breeding tool for selecting superior genotypes among the available diversity and is a better solution than marker-assisted selection (MAS), especially for complex traits such as salinity stress tolerance (governed by several genes and metabolic pathways), due to the inclusion of minor genes for determining the worth of the genotype. As far as rice, wheat and maize are concerned, there have been no systematic GS efforts for salinity stress tolerance. However, a haplotype-based GS approach can be used to charter customized varieties suitable for a particular region with a specific stress type and consumer quality preferences (Sinha et al. 2020). The publicly available 3K rice genome sequence information can be used to predict haplotypes suitable for salinity stress and design a breeding strategy.
Transcriptomics for salinity tolerance
Advances in high-throughput methods for next-generation sequencing offer a better understanding of salinity stress tolerance in crops by identifying salt-responsive genes using genomics and transcriptomics (Egan et al. 2012; Duarte-Delgado et al. 2020; Kashyap et al. 2020). Transcriptomics can identify stress-associated essential transcripts, the transcriptional structure of genes, their functional pathways, and other post-transcriptional modifications (Wang et al. 2009). RNA-seq and microarray are gene expression approaches (Table 3) with the former being more popular due to its precise transcript measurement ability (Wang et al. 2009).
Rice
Kumari et al. (2009) first reported 1,194 salinity-regulated cDNA between two contrasting genotypes, ‘IR64’ and ‘Pokkali’. The latter exhibited enhanced gene expression in the GST, LEA, CaMBP V-ATPase, and OSAP1 zinc finger protein families. Later, in transcriptomic studies involving ‘IR64’ and ‘Pokkali’ under salt stress, Shankar et al. (2016) reported that the upregulation of transcripts was involved in wax and terpenoid metabolism. Whole-genome resequencing and transcriptome analysis of ‘Sea Rice 86’ identified several candidate genes for salt adaptation (Chen et al. 2017). Li et al. (2018) concluded that ‘Pokkali’ (tolerant) has more stable mRNA and can stably load mRNA on polysomes during salt stress than ‘IR29’ (sensitive). Chandran et al. (2019) used RNA-seq based transcriptomic analysis in japonica rice cultivar ‘Chilbounder’ screened under stress and non-stress conditions to identify 447 differentially expressed genes (DEGs), which were mainly involved in carbohydrate and amino-acid metabolic processes. Recently, Xie et al. (2021) reported that the AP2/EREBP-HB-WRKY cascade is activated by stress, imparting melatonin-mediated salt tolerance in rice.
Wheat
Numerous transcriptomics studies have been conducted in wheat using different plant parts (roots, shoots, both or total plant) to understand salt stress tolerance (Table 3). Diacylglycerol kinase encoding gene, signal transduction module gene, and GST were upregulated for stress tolerance in wheat (Liu et al. 2012). Under salt stress, the salt-stress tolerant gene, TaMYB73, was upregulated in roots but downregulated in leaves. However, overexpression of the gene in Arabidopsis improved stress tolerance (He et al. 2012). Mahajan et al. (2020) found that root-growth-enhancing genes encoding expansin, xyloglucan endotransglucosylase/hydrolase, dehydrins, and peroxidases improve salt stress tolerance. Additionally, the study identified 10,805 unigenes in ‘Kharchia Local’ roots at anthesis, and WRKY, MYB, NAC, bHLH, AP2/ERF transcription factors (TFs) were upregulated during salt stress. For the first time, Amirbakhtiar et al. (2019) identified 26,171 novel transcripts from the roots of ‘Chinese Spring’ seedlings using RNA-seq. Under stress conditions, Ta.ABAC15, an ABC transporter gene, was significantly upregulated. Cytosolic-calcium-level controlling genes Ta.ANN4, Ta.ACA7, and Ta.NCL2,29 NAC genes, and 48 MYB TFs also increased under salt stress. Besides differentially expressed TFs, miRNAs also contribute to stress tolerance, regulating transcription and translation. In wheat roots, 16 novel salt-stress-associated miRNAs were identified. Stress-responsive miRNAs, athmiR5655, osamiR172b and osamiR444b.2, regulated TFs, bHLH135like, AP2/ERBP, and MADS box, respectively (Eren et al. 2015). Duarte-Delgado et al. (2020) found 50 calcium-binding genes and 18 xyloglucans:xyloglucosyl transferase (cell wall genes) that reduce osmotic stress; subgenome D had the most (35.8 ± 1.7%) salt-responsive genes, with TraesCS2A02G395000 the strongest salt-responsive gene. Ma et al. (2020) reported the upregulation of TaCYP450 and six ethylene-dependent genes during salt stress. Upregulation of genes associated with LEA, dehydrin, and potassium transportation, and sodium/cation exchange and aquaporin in roots and shoots, respectively, enhanced salt stress tolerance (Bhanbhro et al. 2020). A reduction in ethylene sensitivity enhances salt tolerance. Upregulation of nine novel ETHYLENE RESPONSE FACTORs (ERFs) (TaERF1, 2, 3, 4, and 6) reduced ethylene sensitivity and improved salt tolerance in wheat (Ma et al. 2021).
Maize
In maize, a reasonable number of transcriptomics studies are available (Table 3). Using RNA-seq analysis, Li et al. (2017) reported 1661 DEGs between the salt stress and control treatments at the seedling stage, which were associated with hormone metabolism, signaling, TFs, fatty acid biosynthesis, and lipid signaling. Chen et al. (2020) reported 219 upregulated and 153 downregulated DEGs in salt-sensitive and tolerant lines, respectively, which were associated with ion homeostasis, strong signal transduction activation, and increased ROS scavenging and different TFs (MYB, MYB-related, AP2-EREBP, bHLH, and NAC families). Similarly, Zhang et al. (2021) identified 459 DEGs, of which Aux/IAA, SAUR, and CBL-interacting kinase reportedly regulate salt tolerance. In addition, WRKY, bZIP, and MYB TFs act as regulators in the salt-responsive regulatory network of maize roots. Comparing transcriptomics studies in wheat, maize, and rice revealed some common TF families, such as WRKY, MYB, AP2/ERF, and NAC, important for imparting salinity stress tolerance (Table 3). These TFs maintain cellular homeostasis and osmotic balance in plants by regulating the expression of salt-stress responsive genes and need to be explored to understand their specific modes of action.
Proteomics for salinity stress tolerance
Proteomics helps to capture insights into salt-stress tolerance by identifying protein modulations and pathway modifications (Parvaiz et al. 2016). Proteomics/metabolomics studies for salt tolerance have been mostly conducted in wheat followed by maize and rice (Table 4).
Rice
Nam et al. (2015) performed metabolic profiling of 38 rice genotypes using H-NMR spectroscopy and found glutamine and allantoin positively correlated with salt tolerance. Wang et al. (2021) undertook metabolic profiling of rice genotypes to confirm the role of several metabolites, including amino acids (valine and proline) and organic acids (phosphoenolpyruvic acid, glyceric acid, ascorbic acid), in imparting salt tolerance.
Wheat
Phosphoproteomics identified the salt-stress response and defense biomarkers [cp31BHv, betaine-aldehyde dehydrogenase (BADH), cytosolic (GS1), Cu/Zn superoxide dismutase (SOD), MAT3, leucine aminopeptidase 2 (LAP2), and 2-Cys peroxiredoxin BAS1] in wheat (Lv et al. 2016). Cu/Zn SODs, GSTs, DHNs, and V-ATPase were upregulated in roots, and Cu/Zn SODs, LEA, and DHN in leaves (Lv et al. 2016). Jiang et al. (2017) analyzed wheat seedling roots and reported three salt-tolerance-associated proteins: a pyruvate orthophosphate dikinase (PPDK) and two late embryogenesis-abundant (LEA) encoded by TaPPDK, TaLEA1, and TaLEA2, respectively. Ubiquitination-related and pathogen-related proteins, membrane intrinsic protein transporters, TFs, and antioxidant enzymes imparted salt-stress tolerance through single cellular homeostasis in roots. Protecting cell structure during salt stress is an important strategy for stress tolerance. Singh et al. (2017) reported the upregulation of tubulin, profilin, retinoblastoma, casparian strip membrane protein, xyloglucan endotransglycosylase, and ion transporter proteins (e.g., malate transporter) for enhanced salt tolerance. Three genes, TraesCS6A01G336500.1, TraesCS4B01G254300.1, and TaABCF3, encoding OPAQUE1, NRAMP-2, and transporter genes, respectively, enhanced salt stress tolerance by balancing the shoot Na+/K+ ratio, specific energy fluxes for absorption, dissipation, and shoot Na+ uptake (Oyiga et al. 2019). Han et al. (2019) reported the upregulation of five SODs, three malate dehydrogenases and dehydrin proteins, and one V-ATPase protein in roots, and two Cu/Zn, one LEA protein, and DHN proteins in leaves under salt stress. Ethylene modifies or activates ribosomal proteins (RPs) in wheat, reducing ROS accumulation and improving stress tolerance. Eight and 49 differentially expressed proteins (DEPs) were found in roots and shoots, respectively, and 48 RPs in roots (Ma et al. 2020). In chloroplasts of wheat seedling leaves, 117 upregulated differentially accumulated proteins (DAPs) were associated with the Calvin cycle, amino-acid metabolism, carbon and nitrogen metabolism, transcription and translation, and antioxidation (Zhu et al. 2021).
Maize
Protein analysis of ‘F63’ (tolerant) and ‘F35’ (sensitive) maize genotypes using the iTRAQ approach identified 28 salt-responsive proteins, of which 22 were expressed explicitly in ‘F63’ (Cui et al. 2015a). Similarly, Soares et al. (2018) reported 1747 proteins, of which 209 were abundant in response to salt stress and mainly associated with oxidative stress, dehydration, respiration, and translation. Chen et al. (2019) identified 1056 DEPs, of which 626 and 473 were specific to tolerant and sensitive maize inbred lines, respectively. DEPs expressed in the tolerant lines under salt stress were associated with phenylpropanoid biosynthesis, starch and sucrose metabolism, and the MAPK signaling pathway, while those in the sensitive lines were related to the nitrogen metabolism pathway only (Chen et al. 2019). Hence, under salt stress, glucose metabolism is mainly induced in salt-tolerant lines, while nucleic acid metabolism is induced in salt-sensitive lines at the seedling stage.
Comparing proteomics studies across rice, wheat, and maize highlights glutamine as a common, key amino acid (via upregulation of glutamine synthetase) for imparting salinity stress tolerance in salt-tolerant lines (Table 4). Glutamine synthetase enhances salt tolerance in the tolerant cultivars by imparting better photorespiration capacity (Kamal et al. 2012; Nam et al. 2015; Luo et al. 2018). Studies have shown that enhanced proline in rice and wheat, and RPs in wheat and maize impart salt tolerance (Table 4). Hence, these key amino acids can be used as metabolite markers in salinity stress breeding programs in cereal crops.
Meta-analysis for salinity stress tolerance
With the availability of numerous QTL and transcriptomics studies, meta-analysis is the best approach for identifying or predicting consensus genomic regions (candidate genes and meta-QTL i.e., genomic intervals containing two or more QTL from independent studies) for subsequent use in plant breeding programs (Sinha et al. 2021). Meta-analysis can be performed with expression datasets (microarray or RNA-seq) and QTL datasets. For example, Kaur et al. (2016) performed a meta-analysis using a publicly available microarray data set and RNA-seq data to identify 31 candidate genes associated with salt tolerance in rice. Later, Buti et al. (2019) performed a meta-analysis of RNA-seq data in rice to identify chilling, osmotic and salt stress tolerant genes. Later, Islam et al. (2019) predicted 11 meta-QTL for SIS and shoot Na+ and K+ concentrations and identified related candidate genes (using gene expression studies and gene ontology prediction). Kong et al. (2019) performed a meta-analysis of the salt stress transcriptomic response in rice (based on 96 publicly available microarray datasets) and identified 5559 DEGs, with most related to the mitogen-activated protein kinase (MAPK) cascade, Ca2+ signal transduction, hormone signals, TFs and regulators. Recently, Mansuri et al. (2020) used published transcriptomic and QTL mapping studies to predict 3449 DEGs in 46 meta-QTL, with most involved in functions of ion transport, cell wall organization, transcriptional regulation, cell response to stress, transporter activity, TFs, and oxidoreductase.
Epigenomics and genome editing approaches for salt tolerance: recent progress
Recent progress in the technological advances of epigenetics and transgenics is promising for delivering climate-resilient genotypes. The epigenetic changes include chromatin modification, several post-transcriptional histone modifications and DNA methylation which play an important role in imparting salt stress tolerance in crops. The hypermethylation of cytosines at HKT genes in shoots and roots imparted salt tolerance in wheat (Kumar et al. 2017). Wang et al. (2011) reported altered DNA methylation in salt-sensitive and salt-tolerant rice genotypes. Subsequently, methylation-sensitive amplification polymorphism analysis revealed the role of DNA methylation for salt tolerance in rice, evident from enhanced DNA methylation and differential gene expression under high salinity conditions (Karan et al. 2012). Similarly, overexpression of miR156 reduced the expression of TFs (SPL9 and DFR), imparting salt tolerance in rice (Cui et al. 2014). Furthermore, high-throughput sequencing (MeDIP-seq) technologies resolved the differentially methylated regions at the whole-genome level in salt-tolerant rice (Ferreira et al. 2015) and maize (Sun et al. 2018). Recently, Rajkumar et al. (2020) reported cultivar-specific DNA methylation with hypermethylation prominent in salt-tolerant rice cultivar ‘Pokkali’ and hypomethylation in drought-tolerant cultivar ‘Nagina22’ under salt stress. These recent findings indicate the potential role of epigenetic factors in imparting salinity tolerance in rice, wheat and maize.
In recent years, advancements in CRISPR/Cas technology have provided a new avenue for genome editing, enabling target site-editing of desirable alleles to produce desirable phenotypes (Kumar et al. 2020). Salinity tolerance in rice was induced by editing the OsRR22 gene using CRISPR-Cas9 (Zhang et al. 2019). Kumar et al. (2020) used CRISPR-Cas9 based gene editing to produce a mutant Cas9-freedst Δ184–305 in indica rice cultivar ‘MTU1010’, which showed a moderate level of osmotic stress under seedling-stage salt stress. Further, several transgenes were used to induce salinity tolerance in rice for salt exclusion and Na+ compartmentation viz., PpENA1, PyKPA1, SOD2, AtHKT1;1, HmHKT1;5, HvHKT1;5, OsVP1, OsNHX1, CgNHX1, AdNHX1, OsNHX1, PgNHX1 and AtNHX1 (Kotula et al. 2020). The use of genome editing for salt stress tolerance is limited but has the potential for developing salt-tolerant cereal crops.
Genomics-assisted bred salt-tolerant cultivars: achievements
Crop responses to salinity and their tolerance to salinity are complex genetic and physiological phenomena. Only major QTL can be targeted through marker-assisted backcrossing (MABC) as evident in rice (Krishnamurthy et al. 2020). Maize and wheat lack introgression studies for major QTL, which may be due to complex genome size or lack of validation of functionality of identified QTL. However, one successful example is ‘Line149’ in wheat (Munns et al. 2012) developed through introgressing TmHKT1;5-A, a gene from Triticum monococcum that confers Na+ exclusion. Dominant markers, gwm410 and gwm291 and co-dominant marker, cslinkNax2 were used to select favorable lines (Munns et al. 2012). In contrast, there have been remarkable achievements in introgressing major QTL for salinity stress tolerance in rice. ‘Saltol’ is the most celebrated and widely used genomic region for seedling-stage salt tolerance, adapted from ‘FL478’ (derived from local landrace ‘Pokkali’ from Kerala, India) (Bonilla et al. 2002). Fine mapping of this region revealed a major gene, SKC1, which stabilizes K+ homeostasis in the salt-tolerant variety (Ren et al. 2005). SKC1 encodes an HKT-type transporter that is Na+ selective, and maintains K+/Na+ homeostasis under salt stress. ‘FL478’ was used as a universal donor for ‘Saltol’ QTL in the MABC program to improve seedling-stage salt tolerance in several commercial cultivars (Krishnamurthy et al. 2020). In India, several ‘Saltol’ introgression lines, (i.e., near-isogenic lines) have been developed in popular released cultivars, including ‘Sarjoo52’, ‘Pusa Basmati-1’, ‘Pusa Basmati 1121’, and ‘Pusa 1509’, with yields on par with the original variety under non-stressed conditions and better in salinity prone areas (Krishnamurthy et al. 2020; Singh et al. 2018; Babu et al. 2017a). Rana et al. (2019) used the hitomebore salt-tolerant-1 (hst1) gene from an EMS mutant line governing the seedling and reproductive stage to develop the salt-tolerant variety, ‘Kaijin’, which was used to introgress the hst1 gene in ‘Yukinko-mai’ to develop ‘YNU31-2-4’, a salt-tolerant cultivar. The Hst1 gene encodes a B-type response regulator called OsRR22 (Os06g0183100). A substitution mutation in the third exon of this gene governs salt tolerance in this genotype. Marker-assisted recurrent selection (MARS) was recently used to improve drought and salt tolerance in the ‘IR58025B’ genetic male sterile maintainer line, the most common maintainer line used for hybrid rice development in India (Suryendra et al. 2020). The complete list of improved rice lines/cultivars using genomics-assisted breeding is presented in Table 5. The physiological mechanisms of salt tolerance at the reproductive stage in rice differ from those at the seedling stage; hence, a separate breeding strategy should be followed (Pundir et al. 2021; Singh et al. 2021).
Conclusion and future perspectives
Salinity is a major abiotic stress that adversely affects crop growth and development, resulting in yield losses. The reclamation of saline ecologies is a time-consuming and challenging task. Developing salt-tolerant cultivars of rice, wheat, and maize, the staple food crops, is a sustainable and cost-effective approach to safeguard food security. The availability of molecular markers, modern breeding tools, and omics techniques can help to understand the genetic basis of salt tolerance by identifying relevant genomic regions for the quick development of tolerant cultivars instead of the time-consuming conventional breeding approach. A systems biology approach that integrates all omics approaches (genomics, transcriptomics, proteomics, metabolomics and phenomics) is necessary to understand salt-stress tolerance mechanisms in different crops. However, a pre-breeding approach (using wild relatives and landraces) is needed to broaden the genetic base of germplasm for traits associated with salinity stress tolerance, as most crop breeding programs are based on a few donor lines. Rice has witnessed remarkable success, particularly with the Saltol QTL. Similar success is expected in wheat and maize considering the availability of major QTL and emphasis on salinity stress studies. The availability of multi-parent mapping populations in these crops will help identify novel alleles for salinity stress tolerance (Gireesh et al. 2021). Using molecular breeding approaches combined with omics and rapid generation techniques, such as speed breeding to shorten generations and genome editing to edit the target gene, will further hasten the development of salt-tolerant cultivars (Watson et al. 2018; Kumar et al. 2020). Recently, rice witnessed the use of CRISP-Cas for salinity improvement by targeting the OsRR22 and OsDST genes; wheat and maize will likely witness the success of genome-edited cultivars in the near future. Using a pangenomics approach and wild relatives will help identify the core and unique genes for salinity stress adaptation in rice, wheat, and maize (Khan et al. 2020). Identifying cross-tolerance for multiple abiotic stresses and stress memory development is another worth exploring area to develop multi-stress tolerant cultivars (Choudhary et al. 2021). Considering the worldwide salinity crisis, better policies, and allocation of grants and funding for salinity stress research will assist in the sustainable development of salt-tolerant elite cultivars.
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The authors thank the Indian Council of Agricultural Research (ICAR) for support received in preparing the manuscript. The first author thanks the Science and Engineering Research Board (SERB) Government of India for financial support through the EEQ (2018/001394) scheme.
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PK and MC conceptualized the manuscript. PK, MC, TH, NRP, VS, VTV, SS, NL and RKT interpreted the literature and drafted the manuscript: section wise. SR and KHMS critically edited the manuscript. PK, MC and NRP contributed equally in the manuscript.
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Kumar, P., Choudhary, M., Halder, T. et al. Salinity stress tolerance and omics approaches: revisiting the progress and achievements in major cereal crops. Heredity 128, 497–518 (2022). https://doi.org/10.1038/s41437-022-00516-2
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DOI: https://doi.org/10.1038/s41437-022-00516-2
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