Abstract
Abiotic stresses greatly influenced wheat productivity executed by environmental factors such as drought, salt, water submergence and heavy metals. The effective management at the molecular level is mandatory for a thorough understanding of plant response to abiotic stress. Understanding the molecular mechanism of stress tolerance is complex and requires information at the omic level. In the areas of genomics, transcriptomics and proteomics enormous progress has been made in the omics field. The rising field of ionomics is also being utilized for examining abiotic stress resilience in wheat. Omic approaches produce a huge amount of data and sufficient developments in computational tools have been accomplished for efficient analysis. However, the integration of omic-scale information to address complex genetics and physiological questions is still a challenge. Though, the incorporation of omic-scale data to address complex genetic qualities and physiological inquiries is as yet a challenge. In this review, we have reported advances in omic tools in the perspective of conventional and present day approaches being utilized to dismember abiotic stress tolerance in wheat. Attention was given to methodologies, for example, quantitative trait loci (QTL), genome-wide association studies (GWAS) and genomic selection (GS). Comparative genomics and candidate genes methodologies are additionally talked about considering the identification of potential genomic loci, genes and biochemical pathways engaged with stress resilience in wheat. This review additionally gives an extensive list of accessible online omic assets for wheat and its effective use. We have additionally addressed the significance of genomics in the integrated approach and perceived high-throughput multi-dimensional phenotyping as a significant restricting component for the enhancement of abiotic stress resistance in wheat.
Keywords: abiotic stresses, GWAS, ionomics, omics, phenomics, QTL
1. Introduction
Wheat is the 3rd most cultivated cereal crop throughout the globe (Acevedo et al. 2002) covering 22% of the cultivated land. It belongs to the family of the Gramineae (Poacea). It mainly grows in the temperate zones with cool weather (12–25 °C temperature) and having 250–1750 mm annual precipitation [1]. In case of winter wheat, it is widely planted at the end of autumn season as it needs the cold treatment for flower initiation, which is called vernalization process [2]. A recessive allele of Vrn genes on 5A, 5B and 5D genomes is responsible to control this growth habit of winter wheat, which requires 40 °C temperature prior to tillering and elongation stage [2,3]. Both genotype and photoperiod are major factors to control the flowering pattern in wheat, which lack photoperiod insensitivity genes (Ppd) need exposure to long growing days [4].
Abiotic stress is one of the key factors limiting the crop production. Environmental stresses like drought stress, salt stress, heavy metal stress as well as water submergence stress influenced the crop yield in a different manner. To overcome such problems, local cultivars should be modified by making molecular changes in specific genes [5]. Although the multi-selection field trial method has been widely used for direct selection of tolerant varieties for any harsh environment, this selection method does not provide significant results for the abiotic stress related traits that are highly influenced by environmental conditions and low heritability [6]. In addition, this direct selection approach is quite laborious as well as time consuming. The genetic variation in different yielding crops could lead to the development of tolerant cultivars but there is a knowledge gap which needs strong effort to find specific molecular markers [7]. The development of molecular markers will provide the new and latest sequenced genomes and organelles in crops [8].
Recently, the development of molecular markers to characterize the complete genome sequence plays a crucial role in marker-assisted breeding [9]. The availability of high density markers helps to identify different alleles involved in agronomic traits and also helps in haplotype analysis [10]. In addition, marker-assisted breeding has been accomplished for the simple traits, which are controlled by a single or few loci [11,12] however, such breeding also suffers due to unsought genetic strains [11]. The phenotypic expression of the newly identified genes is controlled by the genetic makeup of the repeated parents, which is mainly due to epistatic interaction [13] and this epistatic interaction in mostly unpredictable in case of multiple complex traits, unless some proper evidence is available about the molecular processes involved during the developments of new traits. Current improvement in the genomics can easily predict the factors involved in their genetic variation, traits developments, distribution as well as interaction with the host environment [14]. Genetic Engineering is an advanced approach mainly used for the genetic enhancement of the plants. Interestingly, genetically modified (GM) plants have been proven to be successful for herbicide and insect resistance and widely used throughout the world [15]. A combination of multi-disciplinary knowledge is required for the development of an ideal plant, which could provide better yield even in adverse climatic conditions. This review has been written to explain the recent achievements in various “omics” approaches and to elaborate the future outcomes for the development of abiotic stress tolerant varieties.
Advances in technology have additionally given a high-throughput, effective and quick array-based genotyping stages. The single nucleotide polymorphism SNP array advancement requires starting data about SNPs, luckily, data around a large number of SNPs is now accessible in the general population space (Table 1). The Illumina Infinium array (SoySNP50K iSelect BeadChip) for ~50,000 SNPs has been effectively created and utilized for the genotyping of a few soybean plant presentation (PI) lines [16]. Advances in technology beyond this make it conceivable to resequence several lines in a cost effective way and has begun a new era of genotyping by re-sequencing [17]. Presently, the challenge for plant scientists is how to successfully utilize these assets for marker-assisted applications.
Table 1.
S.No. | QTL | Linked Markers | Position | Env. a | PVE (R2) b | References |
---|---|---|---|---|---|---|
Agronomic traits | ||||||
A. Grain Yield | ||||||
1 | qGYWD.3B.2 | Xgpw7774 | 97.6 | 7/4 | 19.6 | [41] |
2 | 4A | Xwmc420 | 90.4 | Mean/2 | 20 | [42] |
3 | 4A-a | Xgwm397 | 6 | 7/5 | 23.9 | [43] |
4 | Qyld.csdh.7AL | Xgwm322 | 155.9 | 21/11 | 20.0 * | [44] |
B. 1000-Grain weight | ||||||
1 | 3B | Xbarc101 | 86.1 | Mean/2 | 45.2 | [45] |
2 | QTgw-7D-b | XC29-P13 | 12.5 | 11/10 | 21.9 | [46] |
C. Days to Heading | ||||||
1 | QDh-7D.b | XC29-P13 | 12.5 | 11/11 | 22.7 | [47] |
2 | QHd.idw-2A.2 | Xwmc177 | 46.1 | 13/16 | 32.2 | [46] |
D. Days to Maturity | ||||||
1 | QDm-7D.b | X7D-acc/cat-10 | 2.7 | 11/10 | 22.7 | [48] |
Physiological Traits | ||||||
A. Stem Reserve Mobilization | ||||||
1 | QSrm.ipk-2D | Xgwm249a | 142 | 2/2 | 42.2 | [48] |
2 | QSrm.ipk-5D | Xfbb238b | 19 | 2/2 | 37.5 | [48] |
3 | QSrm.ipk-7D | Xfbb189b | 338 | 2/2 | 21 | [48] |
B. Water Soluble Carbohydrate | ||||||
1 | QWsc-c.aww-3A | Xwmc0388A | 64.9 | 2/2 | 19 | [49] |
C. SPAD/Chlorophyll Content | ||||||
1 | Qchl.ksu-3B | Xbarc68 | 67.2 | 3/2 | 59.1 | [50] |
a Number of environments in which QTL was detected/number of total environments; b highest PVE (R2) values under drought/water stress, * with >20% higher yield per ear.
2. Omics Approaches in the Technological Era
When genetics, nutritional or environmental conditions are changed a diverse mix of technologies fulfil the understanding of the changes that occur. Omics are useful in the understanding of species and thus providing insight into modification of the plant metabolism which results through contact with environment. The era of genomics had been started with the development of automated sequencing methods and led to first whole genome sequencing of Arabidopsis thaliana. The genome sequencing has been stretched out to major crop plants such as rice [18,19], soybean [20], maize [21]. The emergence of high throughput “Omics” approaches has begun a successful period of plant molecular techniques for adjusting to changes in the environment. Recent development in ‘omics’ after post genomic era such as next generation sequencing, genome scale molecular analysis, modeling of different physiological and molecular understanding and correlation of these observations with physiology of the plant provides an accomplished move to adaptability and productivity under stress. Latest advent of next generation sequencing methods made possible sequencing the plant species quite useful [22]. Allohexaploid bread wheat (2n = 6x = 42, AABBDD genomes) is one of the most complicated genomes in which homologous chromosomes having similar genes complicates the reconstructing process of biological networks. A draft of the wheat genome is completed which shows more than 124,000 gene loci which covers all the sub-genomes (A, B and D) and proves useful in identifying genes which control biological process. Further, modern utilization of transcriptomics (RNA-seq) and proteomics (targeted vs. non-targeted proteins) will help in defining their functions at the gene and protein level respectively. As all genes are not always turned on at the same time, therefore the metabolism becomes quite dynamic in phenotype which cannot be derived from the genotype. Thus, the successful integration of the transcriptomics (gene), proteomics (proteins), metabolomics (metabolite), ionomics (analysis of elemental compositions), epigenomics (inheritance), interactomics (protein-protein or protein-DNA interactions) will facilitate the breeder to select the potential candidates and best traits to generate and improve the crop productivity under abiotic stress (Figure 1).
3. Genomics Progresses for Abiotic Stress Tolerance in Wheat
Genomics emphasis on the genome physical structure, aiming to recognize, detect and order genomic structures along chromosomes. Here we discuss some of genomic progresses to understand abiotic stress tolerance in wheat.
3.1. Molecular Marker Resources
The emergence of genomic technology has opened a new window in genetic enhancement of complicated traits such as salt and drought tolerance. The amalgam of genomic approaches along with marker assisted selection (MAS) can be helpful in the identification of specific genes at a much faster rate in the breeding population as compared to classical breeding [23,24,25,26]. Developments in MAS for wheat has lagged behind other crops due to limited genomic data but recent progress in DNA sequencing and genotyping techniques have developed genome datasets which are very useful in designing sequence based simple sequence repeats (SSRs) and SNP markers [27,28,29]. SNPs are frequently used for genome mapping and germplasm characterization as compared to other molecular markers. As SNPs are high-throughput, rapid, cost-effective, co-dominant, sequence tagged and highly abundant, they are appropriate for division of complex traits using highly multiplexed marker microarrays such as the Affymetrix GeneChip [29,30]. For instance, Axiom Wheat Breeders’ genotyping array, a robust system for screening large wheat population, is developed recently. It is a cost effective and efficient genotyping method having 35,143 pre-validated SNPs which covered all wheat chromosomes and have the ability to genotype 384 samples at once. In durum wheat, it has been applied recently in the development at linkage maps of high density and also in identifying the genomic areas of complex traits such as drought tolerance [31].
3.2. Quantitative Trait Loci (QTL) Mapping for Abiotic Stress
For agronomically important traits, linkage maps are necessary for mapping the QTLs as they are constructed from genotype data from multiplexed marker assays [32,33,34,35]. High-density linkage maps also offer a genomic resource for positional cloning of significant genes. They can also be applied in comparative genomics to assess the chromosomal organization and evolution as they are constructed from sequence tagged markers. In the linkage map, markers are helpful in identifying regions having QTLs of selected traits and several QTLs have mapped previously for salt tolerance [17,35,36] and drought tolerance [37,38,39] in wheat cultivars (Table 1).
Advances in genomics and phenomics provide us more precise and broad characterization of the QTLs that control a targeted trait known as QTLome. The vast knowledge on QTLome put a responsibility on breeders to utilize this knowledge in an effective way. Enhanced QTL meta-analysis, valuation of QTL effects and upgraded crop modeling will allow an actual utilization of the QTLome [40].
3.3. Genome Wide Association Studies
Another approach to overcome these limitations is association mapping that uses the historical meiosis in the diversity panel and provides more precision [51]. It is quite feasible and cost effective to establish an association mapping in compared to recombinant inbred line (RIL) development. In association mapping, experimental structures and statistical evaluation are constantly fluctuating to diminish the results of confounding factors, decrease false positives and also control minor allele effects (Figure 2). Genetic interaction and population designs confound marker-trait relations results in the disequilibrium without true linkages [52]. To decrease false positives and minor allele QTL effects, several diagnostic and precise statistical analyses have been developed. Studies have been carried out at the correct genomic locations of developmental genes such as reduced height (Rht), vernalization (Vrn) and photoperiod responsiveness (Ppd) and used as a standard measure in order to incorporate phenotypic diversity and markers present in the study [3]. As a genetic reference, these genes possess the stress adaptive capability by changes heading date, plant height, maturity and other physiological processes [53].
3.4. Genomic Selection
The emergence of model based association and easy availability of molecular markers, a correlated concept known as genomic selection has emerged to assess genotypes breeding value [54]. This technique is utilized to minimize the shortcomings of map based genetic analysis that identify very few QTL to explicate the divergence in targeted traits [54]. The concrete significance of evaluating the QTL effect and linkage disequilibrium based on the genetic relatedness and the divergence of the population under study. Populations that show the more allelic variation of targeted traits display more precise evaluation of QTL effect compared to populations which are more closely related. Linkage disequilibrium is often overvalued in closely related inter-mating individuals and diminish in further meiotic events [55]. Genomic breeding value can be predicted by genomic selection by transforming marker assisted selection with the help of markers. A model that is established and evaluated using genotypic and phenotypic data of study population will be utilized to assess phenotypic variation of sample population based on their genetic composition only. This will enhance genetic gain in comparison to both QTL and phenotype-based selection [56].
Statistical methods are used to develop genomic selection models that explain the properties of various markers and traits [57]. The distribution of marker effects and random sampling of germplasm from selected population is being considered by the multiple regression models [58]. Genomic best linear unbiased prediction evaluates genetic relatedness among individuals on the basis of molecular marker composition similarity and also assess their phenotypic performance. Such a model is similar to estimation of breeding value (BV) from heritability and phenotypic performance of related genotypes in a pedigree [54]. Statistical analyses show that forward and mixed type regression models have ability to remove markers on the basis of their relative significance effect. Ridge regression has an additional feature of incorporating penalty parameter in the design of the markers in excess of the statistically accepted number (>number of genotypes) [59].
3.5. Transcriptome Profiling for Abiotic Stress Tolerance
In wheat, expressed sequence tag databases showed that homologous genes can show expression in one but remain silent in one or both of the remaining genomes in the analysis of gene expression [60]. For the cereals, various microarray and macroarray platforms have been developed. There are various significant arrays like 10,000 cDNA array reported by Leader [61] and Affymatrix arrays have been developed for wheat and barley recently [62]. In abiotic stress conditions in a variety of plants, the microarray is one of the successful methods for the genome wide transcript expression profiling and is being widely used to generate transcriptional profiles (Figure 3). Studies have been carried out in barely in response to salt stress [63,64] and the model cereal Brachypodium [65] but there is limited research on wheat due to its polyploidy genome [66]. The high-throughput analysis of gene expression is being enabled by deep genome sequencing technology (RNA-Seq) which proves to be a successful technique to identify precise changes in the genome. Next-generation sequencing technology is in the emerging phase in plant studies but it is predicted to replace the microarray technique due to its accurate results. Due to the lack of fully sequenced and complex genome (hexaploid) in wheat present many difficulties to “OMICS” studies. Meng et al. [67] assessed alkalinity stress by digital expression tag profiling method in wheat. Poersch-Bortolon et al. [68] assessed the extreme drought stress in roots and leaves by examining their expression profiles which prove to be helpful in marker development and selecting the significant important genes. These expression profiles are also proving useful in wheat drought stress by examining their metabolic processes. Ma et al. [69] conducted an RNA-seq analysis to analyze the effect of drought on the wheat genome during reproductive stages. Salt stress responsive gene networks and functional annotation were identified by differential root transcriptome analysis, which prove to be helpful in understanding the process and genes role in salt tolerance as analyzed by Goyal et al. [70].
4. Proteomics in Wheat
It is imperative to study proteome alterations at various stress conditions as proteins play a role in plant stress response. The initial plant response to stress conditions is the cellular processes of stress sensing and signaling processes. In order to understand the stress coping mechanisms in plants, effective characterization and isolation of stress responsive proteins is required. Understanding post-translational modification of proteins is necessary in plant stress conditions. Study of proteomics provides vast information on the fine-tuning of cellular pathways that once took part in stress mitigation. The significant data related to changes in response to abiotic stress and their major role in differential stress response are elaborated in Table 2.
Table 2.
Stress/Conditions | Treatment Time and Dose | Cultivar | Organ/Organelle | Proteomic Technologies | Stress Induced Modulation of Metabolic Pathways | Differentially Expressed Protein Classification | References | |
---|---|---|---|---|---|---|---|---|
Functions | Localizations | |||||||
Flooding | 7 d | Bobwhite line SH 9826 | Seminal root | 2-DE, nano LC-MS/MS | Antioxidant defense | StrRes | - | [71] |
Flooding | 2 d | Shiroganekomugi | Root | 2-DE, nano LC-MS/MS | Carbohydrate (Glycolysis) | EnMet, ProtMet, SigTran, Tranp | Cell wall | [72] |
Drought | 100 d | Opata, Nesser | Root | iTRAQ | Energy metabolism, Replication, Repair | EnStr, Oxired, Trans | Mem, Cyto, Cell wall, Mito, Nucl, Plast, Vacu | [73] |
Drought | 7 d | Ofanto | Leaf | 2-DE, MALDI-TOF | Carbohydrate (Glycolysis, gluconeogenesis) | PTR, StrRes, TCA, ROSsca, AAB, GG | - | [74] |
Drought | 7 d | Katya, Sadovo, Zlatitza, Miziya | Leaf | SDS-PAGE, 2-DE | Energy (photosynthesis) | EnMet, EnvDevS | Chlo | [75] |
Drought | 9 d | Keumkang | Leaf | 2-DE, MALDI-TOF/TOF | Energy (photosynthesis) | Photo | Chlo | [76] |
Drought | 10, 15, 20 and 25 d | Janz, Kauz | Seed | 2-DE, MALDI-TOF | Carbohydrate metabolism | ROSsca, CarMet, SigTran | - | [77] |
Drought | 14, 24 d | Kukri, Excalibur | Leaf | iTRAQ | Energy (photosynthesis) | Photo, GG, ProtF, Tranp, EnStr | - | [78] |
Drought | 20% PEG | Hanxuan 10 and Ningchun 47 | Leaf | nano LC-MS/MS | Antioxidant defense | DRM, SigTran, StrRes, ROSsca | - | [79] |
Heat and Drought | 10 d | Vinjett | Kernel | 2-DE, MALDI-TOF | Carbohydrate (Glycolysis) | CarboMet, STP | - | [80] |
High Temperature | 37 °C d, 28 °C N/10 d, 20 d | Butte 86 | Endosperm | 2-DE, QSTAR PULSAR-TOF | Carbohydrate metabolism | CarboMet, NitMet, ProtMet, StrRes, STP, SigTran, Tranp, Trans | - | [81] |
Salt | 150 mM NaCl/1 d, 2 d, 3 d | Keumkang | Leaf | 2-DE, LTQ-FTICR-MS | Energy (photosynthesis) | Photo, StrRes | Chlo | [82] |
Salt | 1.0, 1.5, 2.0 and 2.5% NaCl in HS/2 d | Zhenhmai 9023 | Leaf | 2D-DIGE/Q-TOF-MS | Carbohydrate metabolism | CarMet, ProtF, Tranp, ROS, ATP | - | [83] |
Salt | 200 mM | Wyalkatchem, Janz | Shoot | 2-DE, LC-MS/MS | - | - | Mito | [84] |
Aluminum | 250 µM/2 d, 3 d | Atlas-66, Fredrick | Root | SDS-PGE, Immunoblot | Signaling pathway | Oxi | - | [85] |
Aluminum | 100, 150 µM/5 d | Keumkang | Root | 2-DE, LTQ-FTICR-MS | Energy (Glycolysis) | Gly, Tranp, SigTran, StrRes, EnMet | - | [86] |
Copper | 100 µM/3 d | Yumai 34 | Root, Leaf | 2-DE, HPLC-Chip/ESI-Q-TOF/MS/MS | Energy (photosynthesis), antioxidant defense | StrRes, SigTran, ProtMet, CarMet, Photo, EnMet | - | [87] |
Protein Profiling | 20 d | Keumkang | Leaf | SDS-PAGE, LTQ-FTICR | Energy (photosynthesis) | COB, DevPro, DRM, ProtF, ProtMet, StrRes, Tranp, Trans | Chlo | [88] |
Protein Profiling | Mature seed | Wild type (AA, BB, DD genome) | Seed | SDS-PAGE, nano LC-MS/MS | Carbohydrate metabolism | StrRes, EnMet, ProtS, CGD, COD, ProtF, SigTran, STP, Tranp | - | [89] |
Cadmium | 10, 100 and 200 µM | Yangmai 15 | Leaf | IPG, MALDI-TOF | Energy (photosynthesis) | Oxi, ProtMet, Photo | - | [90] |
Cadmium | 0.5 mM/L | Yangmai 13 | Leaf | IPG, MALDI-TOF | Antioxidant defense | ROSsca | - | [91] |
AAB—Amino acid biosynthesis; ATP—ATP synthase; CarMet—Carbohydrate metabolism; CGD—Cell growth and division; COB—Cell organization; COD—Cellular organization and development; DevPro—Developmental process; DRM—DNA and RNA metabolism; EnMet—Energy metabolism; EnStr—Environmental stress; EnvDevs—Environmental and developmental signals; GG—Glycolysis and gluconeogenesis; Gly—Glycolysis; NitMet—Nitrogen metabolism; Oxi—Oxidative stress; OxiRed—Oxidation-reduction process; Photo—Photosynthesis; ProtF—Protein folding; ProtMet—Protein metabolism; ProtS—Protein synthesis; PTR—Post-transcriptional regulations; ROSsca—ROS scavenging; SigTran—Signal transduction; STP—Storage proteins; StrRes—Stress response; TCA—Calvin cycle; Tranp—Transport, Trans—Translation; Chlo—Chloroplast; Mem—Membrane; Cyto—Cytoplasm; Nucl—Nucleus; Mito—Mitochondria; Plast—Plastid; Vacu—Vacuole; HS—Hoagland solution; d: days.
5. Metabolomics Advances for Abiotic Stress
Metabolites provide the energy which is necessary for metabolism and growth of protoplasm as they are the basic elements of various structural and enzymatic molecules. Metabolites not only serve as a link between phenotype and genetic information but also play a role in determining the physiological condition of organism. Metabolomics along with other disciplines played a significant role in understanding the interrelated biological processes linked to phenotypes. In functional genomics, metabolic profiling is an emergent tool [92]. The co-existence of gene transcript and metabolites provides a foundation for generating data-driven theoretical models of the biological phenomenon [93,94,95]. In the study of mutants and transgenic lines, metabolomics not only help in understanding metabolism systems but also give information about candidate genes [96,97,98]. The metabolic study also explains how particular genes affect the metabolic pathway and its interaction with other pathways, which is not possible with other techniques such as microarray [99,100].
The advances in metabolomics, the availability of whole genome sequence, genome-wide genetic variants and cost-effective genotyping assays has opened exciting doors to blend metabolomics with crop breeding programs [101,102]. Mass spectrometry (MS) and nuclear magnetic resonance (NMR) spectrometry proved to be successful technologies in wheat. Metabolomics cover not only familiar metabolites but also unfamiliar metabolites as confirmed by wide scale metabolite assessments but managing the ample data is still a challenge [103,104]. Metabolic annotations can be progressed through metabolomics approaches when coupled with advance Bioinformatics techniques, for instance, in case of model plant Arabidopsis [105,106]. Genomic data can also be improved through the sequencing of DNA, RNA and MS quantification of proteins and metabolites which helped in the improving of targeted traits [107]. A number of studies have been conducted on agriculturally useful crops to evaluate the effect of salinity and drought on metabolic activity of the crop in studying stress responses [108,109]. The enhanced tolerance of particular genes may be due to different phenotypic responses which explains the specific metabolic changes. Improvement of breeding material and selection of superior traits can be facilitated through metabolomics approaches [110]. In the bread wheat genome, the polyploid nature is quite distinctive as it has the ability to tolerate considerable chromosomal aberrations and allowing phenotypic assessment as a result of multiple gene loss. Aneuploid genetic lines of wheat proved to be an effective experimental design for the assessment of genetic networks, as they are helpful in identifying those genes which control phenotypes [111,112]. Michaletti et al. [113] concluded that the study of metabolomics and proteomics reveal drought stress responses of leaf tissue from spring wheat and provide a better framework for understanding the mechanisms that control plant cell responses to drought stress while providing knowledge of molecules that can be used for crop improvement programs.
6. Ionomics for Wheat
Ionomics is a high-throughput elemental profiling method to study the molecular systematic basis essential mineral nutrient and trace element composition of living systems. It also represents the inorganic component of cellular and organismal systems [114]. Its wide role in forward and reverse genetics, screening of mutants, uncovering the mechanisms of ion uptake, compartmentalization, transport and exclusion are useful in understanding the processes of abiotic stresses in plants [115]. Ionomics along with relevant genomic data can identify the cellular changes during abiotic stresses as well as the basic processes involved. It can thus help in understanding the gene networks controlling the ion accumulation at different growth stages under abiotic stress. It is proving to be helpful in understanding the gene networks which control ion accumulation of varied growth steps under the conditions of abiotic stress [116]. The literature available on ionomics approaches is limited, however, the highly effective ion profiling will open new doors in understanding the signaling mechanisms for abiotic stress tolerance.
7. Phenomics Prospective in Wheat
Phenomics is the study of high-throughput phenotypic analysis. It has become possible to predict genotypes that are susceptible to abiotic stress through phenotyping approaches [117]. For high throughput plant phenotyping, the automated Greenhouse system is a successful procedure. This system permits the non-destructive screening of plants over a particular period with the help of image acquisition techniques. The different images of each plant are recorded and then evaluated using advanced image analysis algorithms to predict plants with certain phenotypes [118]. The plants with tolerant phenotypes proved to be good sources of genomic resources and also became targets for different molecular approaches including high-throughput sequencing to identify the alleles of interest. However, phenomics also has some disadvantages as it did not provide accurate correlation among the values obtained in the pot culture versus field experiment.
8. Role of Online Databases for Effective Integration of Omics Platforms
The emerging progress in omic approaches has established a huge amount of data which prove to be helpful in a number of research activities. Computational resources have helped to store, catalog and analyze data and make it easily available through user friendly “databases”.
A number of databases have been developed for wheat (Table 3). The most reliable database is (http://www.gramene.org) which gives wide information for omics data from a number of other sources. These databases provide useful information regarding wheat translational genomics and molecular breeding research. It comprises genes, proteins, microRNAs, sRNAs, metabolites, molecular markers and phenomic information of wheat plant introductions (PI). Integration of multi-omics data sets information is also presented in these databases. For example, genes in the QTL region can be retrieved very easily along with the functional annotations, associated protein information in respect of structure and functional features, syntenic information with other model plants, sequence variation among different cultivars, gene expression data including tissue specific variations and many other types of information for wheat.
Table 3.
Resources | Description/URL |
---|---|
Genome sequence | Coordinated effort underway by the IWGSC (http://www.wheatgenome.org) Recognized as a priority by the research community (http://www.csrees.usda.gov/nea/plants/pdfs/wheat_conference_summary.pdf) |
ESTs 1 | 1,050,791 entries |
Oligonucleotide microarray | 1,050,791 entries |
cDNA microarray | Multiple including ~9 K array |
Tiling microarray | Not currently available |
Serial Analysis of Gene Expression (SAGE) | Applied for studying, developing wheat caryopsis |
Massively Parallel Signature Sequencing (MPSS) | Not reported |
Sequencing-by-synthesis | Roche 454 cDNA sequencing [119] |
Deletion and aneuploid genetic stocks | Roche 454 cDNA sequencing [119] |
Transformation | Biolistic- and Agrobacterium-mediated DNA delivery systems |
Gene knockdown | RNA interference Viral-induced gene silencing |
Databases/tools | Graingenes (http://wheat.pw.usda.gov) Gramene (http://www.gramene.org) TIGR Genome Database (http://www.tigr.org/tdb/e2k1/tae1) Wheat Genome Project (http://wheat.pw.usda.gov/NSF/htmlversion.html) Wheat Genome Project (http://wheat.pw.usda.gov/NSF/htmlversion.html) wEST (http://wheat.pw.usda.gov/wEST) CerealsDB (http://www.cerealsdb.uk.net) HarvEST Wheat (http://harvest.ucr.edu) PLEXdb (http://plexdb.org) Gene Expression Omnibus (http://www.ncbi.nlm.nih.gov/geo) ArrayExpress (http://www.ebi.ac.uk/microarray-as/ae) GrainSAGE (http://www.scu.edu.au/research/cpcg/igfp/index.php) Wheat SNP Project (http://wheat.pw.usda.gov/SNP/new/index.shtml) [120] |
Esterase, 1 ESTs listed in the National Center for Biotechnology Information (NCBI) EST database (GenBank dbEST) (8 August 2008; http:// www.ncbi.nlm.nih.gov/dbEST/dbEST_summary.html).
9. Conclusions and Future Perspectives
Diverse omics tools have been utilized to understand how wheat plants react to abiotic stress conditions. We understand that the studies to integrate various omics approaches are restricted in wheat because of the expanded cost and potential challenging integrated omic scale investigation. Ongoing improvements in computational assets, statistical tools and instrumentation have brought down the cost of omics in the numerous folds, however integrated analysis needs novel devices and technical wizards. The complete idea of multiomic studies provides a totally new road and future research projects should plan to adjust appropriately. In wheat, genomics and transcriptomics have developed as expected but the other major omic branches like proteomics, metabolomics and phenomics are as yet lingering behind. These omic branches are similarly vital to get clear photo of the organic framework. Eminently, phenomic studies should be widely utilized along with alternate omics approaches. Desired phenotype is the ultimate aim of crop sciences; therefore, it needs to be understood intensely. Diverse omic tools and integrated methodologies examined in the present review will give looks of current situations and future viewpoints for the successful management of abiotic stress resilience in wheat.
A major focus in the future will be the combining and comparative analysis of transcriptome information between specialists. Specifically, there are huge assets of wheat microarray information now accessible, which give opportunities for gene co-expression network analysis. The merging of information got from a standardized platform, for example, the Affymetrix Wheat GeneChip, will be much easier than cross-platform merging. For instance, the authors of this review have partaken in four studies of the wheat transcriptional response to rust pathogens utilizing the Affymetrix Wheat GeneChip platform. The information from these four studies will be integrated to perform a gene expression network analysis that can possibly recognize key gene expression signatures engaged in rust resistance. This kind of analysis has been effective in associating abiotic stress phenotypes in A. thaliana with fundamental normal and unique gene expression pathways and marker genes [121]. The linking of gene expression information to genetic data is also of extraordinary significance to comprehend the interchange among genome, transcriptome and phenotype. Synchronous studying of the genome and transcriptome on a single platform through, for instance, the ELPs and SFPs discussed earlier, is a significant strategy for revealing genetic components that impact the transcriptome. In general, wheat transcriptomics is advancing quickly and later on we will see an entire systematical approach that coordinates the transcriptome with genome, proteome and metabolome. Furthermore, gene expression databases will expand and become more standardized, which will quicken the revelation and characterization of all genes in the wheat genome.
Acknowledgments
We are very thankful to all staff of the Graduate School of Chinese Academy of Agricultural Sciences and Oil Crops Research Institute, Wuhan for their support and motivation. This research was funded by the National Natural Science Foundation of China (31301361, 31171589).
Author Contributions
T.S. wrote the manuscript, J.X. help in literature; Xi.Z. helped in making diagrams; Y.C. give idea about omics technologies; M.N. helped in incorporation of comments and Xue.Z. read the paper.
Conflicts of Interest
The authors declare no conflict of interest.
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