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Article

Genetic Dissection of Drought Tolerance of Elite Bread Wheat (Triticum aestivum L.) Genotypes Using Genome Wide Association Study in Morocco

by
Zakaria El Gataa
1,2,*,
Karima Samir
2 and
Wuletaw Tadesse
1
1
The International Center for Agricultural Research in the Dry Areas (ICARDA), Rabat 10080, Morocco
2
Faculty of Sciences Ben M’sick, University Hassan II of Casablanca, Casablanca 7955, Morocco
*
Author to whom correspondence should be addressed.
Plants 2022, 11(20), 2705; https://doi.org/10.3390/plants11202705
Submission received: 15 September 2022 / Revised: 1 October 2022 / Accepted: 3 October 2022 / Published: 13 October 2022
(This article belongs to the Special Issue Tools and Resources for Wheat Molecular Breeding)
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Abstract

:
Drought is one of the most important yield-limiting factors in Morocco. Identification and deployment of drought-tolerant wheat varieties are important to cope with the challenge of terminal moisture stress and increase wheat productivity. A panel composed of 200 elite spring bread wheat genotypes was phenotyped for yield and agronomic traits for 2 years (2020 and 2021) in Morocco under rainfed and irrigated environments. The panel was genotyped using 20K SNPs and, after filtration, a total of 15,735 SNP markers were used for a genome-wide association study (GWAS) using a mixed linear model (MLM) to identify marker-trait associations (MTA) and putative genes associated with grain yield and yield-related traits under rainfed and irrigated conditions. Significant differences were observed among the elite genotypes for grain yield and yield-related traits. Grain yield performance ranged from 0.97 to 6.16 t/ha under rainfed conditions at Sidi Al-Aidi station and from 3.31 to 9.38 t/h under irrigated conditions at Sidi Al-Aidi station, while Grain yield at Merchouch station ranged from 2.32 to 6.16 t/h under rainfed condition. A total of 159 MTAs (p < 0.001) and 46 genes were discovered, with 67 MTAs recorded under rainfed conditions and 37 MTAs recorded under irrigated conditions at the Sidi Al-Aidi station, while 55 MTAs were recorded under rainfed conditions at Merchouch station. The marker ‘BobWhite_c2988_493’ on chromosome 2B was significantly correlated with grain yield under rainfed conditions. Under irrigated conditions, the marker ‘AX-94653560’ on chromosome 2D was significantly correlated with grain yield at Sidi Al-Aidi station. The maker ‘RAC875_c17918_321’ located on chromosome 4A, associated with grain yield was linked with the gene TraesCS4A02G322700, which encodes for F-box domain-containing protein. The markers and candidate genes discovered in this study should be further validated for their potential use in marker-assisted selection to generate high-yielding wheat genotypes with drought tolerance.
Keywords:
wheat; drought stress; GWAS; MTA

1. Introduction

Drought is the most significant abiotic factor impacting wheat yield and production, particularly in West and South Asia, North Africa, and Sub-Saharan Africa [1]. Climate change reduces precipitation, worsens drought stress, and has a significant influence on wheat production. Drought stress affects wheat grain production and quality at all phases of development and reduces wheat grain yield by around 30% [2,3]. Understanding drought-tolerance processes and identifying loci relevant to drought tolerance are essential for developing breeding tactics that promote drought tolerance [4]. In season 2022/2021, Morocco harvested 5.06 million tons of bread wheat on 3.2 million hectares, with an average of 1.5 tons per hectare.
Using molecular markers such as single nucleotide polymorphism (SNP) and diversity array technologies (DArT), marker-assisted selection (MAS) has become an essential strategy in wheat breeding for the development of novel adapted lines to biotic and abiotic stresses. Based on linkage disequilibrium (LD), a genome-wide association study (GWAS) is a strong method for identifying marker-trait associations (MTA) and quantitative trait loci (QTL) associated with the trait of interest [5]. GWAS employed a variety of statistical models, although the Mixed Linear Model (MLM) and the General Linear Model (GLM) were the most often used. Several studies use MLM as an appropriate model because of including kinship (K) among individuals and population structure (Q) [5].
The primary goal of plant genetics and breeding research is to improve agricultural productivity and stability in order to provide food security for the world’s rapidly rising population. Plant breeding methodologies, genetic designs, genomics, statistics, and bioinformatics must all be combined to adjust adaptive, agronomic, and economic qualities to meet this challenge. Gene identification and complex trait dissection are two linked components of this effort. Complex trait dissection emphasizes genetic contribution and modes of action from numerous loci, which contributes to phenotypic variance, whereas gene identification focuses on individual genes. The two common goals of any QTL mapping in plants are: (1) to increase our biological knowledge of the inheritance and genetic architecture of quantitative traits, both within a species and across related species, and (2) to detect markers that can be used as indirect selection tools in breeding programs [6].
In recent years, significant efforts have been made to complement traditional plant breeding methods based on a phenotypic pedigree with molecular genetic techniques for the discovery and application of QTLs for marker-assisted breeding and genomic selection (GS). Linkage mapping (also known as genetic mapping) and association mapping (linkage disequilibrium (LD) mapping) are the most commonly used approaches in dissecting complex traits and identifying genes underlying trait variation in plants, animals, and humans [7].
Recently, research on association mapping in several agricultural plants has been conducted to address the constraints identified in linkage-based QTL mapping. Fast improvement in genotyping methods, such as genome sequencing and high-density single nucleotide polymorphism, allowed for the creation of association mapping, the mapping of complex characteristics, and the discovery of contributing genes [8,9]. In this study, we carried out GWAS on 200 spring bread wheat genotypes that were phenotyped for grain yield and yield-related traits and genotyped with SNP markers to identify markers as well as to identify putative genes associated with grain yield and yield-related traits under drought and irrigated conditions.

2. Results

2.1. Phenotypic Description

Figure 1 shows scatter plots of grain yield under rainfed and irrigated conditions at Sidi Al-Aidi station of 200 bread wheat genotypes grown during two seasons (2020 and 2021). The statistical analysis of 200 bread wheat genotypes for grain yield and yield-related traits is presented in Table 1. Grain yield ranged from 3.31 to 9.38 t/h with a mean of 5.93 t/h and the heritability value of 0.45 for irrigated conditions at Sidi Al-Aidi station and grain yield for a rainfed experiment at Sidi Al-Aidi station ranged from 0.97 to 6.16 t/h with a mean of 4.19 t/h and the heritability value of 0.32. While grain yield at Merchouch station ranged from 2.32 to 6.85 t/h with a mean of 4.09 and a heritability value of 0.42. Irrigated conditions at Sidi Al-Aidi station recorded the highest value of grain yield followed by rainfed conditions at Merchouch and Sidi Al-Aidi stations, respectively. All traits showed significant results, wherein the irrigated conditions at Sidi Al-Aidi the NTP value had the highest coefficient of variance (CV) with a value of 23.28% followed by biomass and NSS with a value of 22.68 and 20.59%, respectively. While days to maturity (DMA) recorded the lowest value of CV (2.41%). In the rainfed experiment at Sidi Al-Aidi station, the number of seeds per spike (NSS) had the highest CV with a value of 22.85% followed by biomass and grain yield (GY) with a value of 20.39 and 15.04%, respectively. While canopy temperature (CT) recorded the lowest value of CV (3.57%). In the rainfed experiment at Merchouch station, the GY had the highest CV with a value of 18.29% followed by biomass and number of plants in m2 (NP/m2) with a value of 16.85 and 14.39%, respectively. While DMA recorded the lowest value of CV (2.97%). Traits in irrigated conditions recorded a higher heritability than in rainfed conditions. Under irrigated conditions at Sidi Al-Aidi station, NSS recorded the highest value of heritability with 0.80 followed by biomass and plant height (PLH) with 0.77 and 0.72, respectively. While GY traits showed the lowest value of heritability. Under rainfed conditions at Sidi Al-Aidi station, PLH recorded the highest value of heritability with 0.65 followed by NSS and days to heading (DHE) with 0.63 and 0.62, respectively. While the GY trait showed the lowest value of heritability. Under rainfed conditions at Merchouch station, Biomass recorded the highest value of heritability with 0.70 followed by PLH and DHE with 0.67 and 0.64, respectively. While the GY trait showed the lowest value of heritability. The top 10 elite genotypes for grain yield are indicated in Supplementary Table S1. The genotypes G-146 (SUDAN#3/SHUHA-6/4/BOW/PRL//BUC/3/WH576) and G-145 (STAR *3/LOTUS 5//TNMU/MILAN/3/QAMAR-2) were recorded the highest grain yield under the rainfed condition with a value of 6.16 and 5.75t/h, respectively.

2.2. Principal Components Analysis (PCA) and Correlation

Principal component bi-plot analyses show the association between grain yield and yield-related traits (Figure 2). Under the rainfed regime at Sidi Al-Aidi station, the two principal components explained 20.5% and 13% of the total variation for grain yield and yield-related traits. Under the irrigated regime at Sidi Al-Aidi station, the two principal components explained 17% and 15.5% of the total variation for grain yield and yield-related traits. Under the rainfed regime at Merchouch station, the two principal components explained 22.3% and 15.8% of the total variation for grain yield and yield-related traits. Figure 3 shows four groups under rainfed and irrigated regimes at both stations. Figure 4 shows the correlation between agronomic traits under rainfed and irrigated regimes at both stations. Under the rainfed regime at Sidi Al-Aidi station, DHE was positively correlated with days to maturity with a value of 0.53 and biomass was positive with PLH and biomass with a value of 0.31. Whereas, canopy temperature showed a significant negative correlation with grain yield and biomass with values of −0.21 and −0.20, respectively. Under the irrigated regime at Sidi Al-Aidi station, days to heading and days to maturity were correlated with a value of 0.65, grain yield is correlated with biomass with a value of 0.49; also, grain yield was positively correlated with plant height with a value of 0.32. Whereas canopy temperature was negatively correlated with NPM and NSS with a value of −0.18 and −0.15, respectively, and also, grain yield was negatively correlated with days to heading with a value of −0.18.

2.3. Linkage Disequilibrium and Marker Trait Associations

Figure 5 shows the LD decay of A, B, and D genomes. Genome B had the highest linkage disequilibrium, with an average r2 value of 0.18, followed by genomes A and D with r2 = 0.17 and r2 = 0.15, respectively. Figure 6 shows the density of markers over 21 chromosomes of 200 bread wheat genotypes. For all traits under the rainfed regime at Sidi Al-Aidi station, a total of 67 significant marker-trait associations (MTAs) with p < 0.001 were found (Table 2), the A sub-genome has the most MTAs (28), followed by the B and D sub-genomes, which had 26 and 13 MTAs, respectively. For all traits under the irrigated regime at Sidi Al-Aidi station, a total of 37 significant marker-trait associations (MTAs) with p < 0.001 were found (Table 3), the A sub-genome has the most MTAs (16), followed by the D and B sub-genomes, which had 12 and 9 MTAs. For all traits under the rainfed conditions at Merchouch station, a total of 55 significant marker-trait associations (MTAs) with p < 0.001 were found (Table 3), the B sub-genome has the most MTAs (21), followed by the A and B sub-genomes, which had 20 and 13 MTAs. The GWAS results is the mean of two years (2020/2021).
The results of significant marker-trait associations for grain yield and yield-related traits under rainfed and irrigated conditions at Sidi Al-Aidi and Merchouch stations are shown in Table 2, Table 3 and Table 4, and Figure 7 as well as Supplementary Figures S1–S3. For rainfed conditions at Sidi Al-Aidi station, seventy-four MTAs were recorded (Table 2), where 11 MTAs were recorded for biomass, these markers are located on chromosomes 2B, 2D, 3A, 3B, 5D, and 6D, on the same trait the markers “BobWhite_c2988_493” and “Ex_c14755_1362” located on chromosomes 2B and 2D, respectively, with a value of −Log10(p) = 4.17. Twelve markers were significantly associated with canopy temperature located on chromosomes 1B, 2B, 3D, 5B, 6A, 6B, 6D, and 7A, where the marker “AX-94463982” recorded the highest −Log10(p) = 7.03 located on chromosome 7A, whereas the marker “BobWhite_rep_c64068_241” recorded the lowest −Log10(p) = 3.09 located on chromosome 2B. Chlorophyll content recorded three significant markers located on chromosomes 3A, 5A, and 1B. Days to heading recorded two significant markers located on chromosomes 1B and 2B. Days to maturity recorded two significant markers located on chromosomes 5B and 7D. Grain yield recorded three significant markers located on chromosomes 4A, 2B, and 2D. Fifteen MTAs were recorded for NPM, which are located on chromosomes 1A, 1D, 3A, 3D, and 4A, where the marker “Ra_c29200_300” recorded the highest −Log10(p) = 3.63 located on chromosome 1A. For the NSS trait, 11 MTAs were recorded located on chromosomes 1A, 1B, 1D, 5B, 6B, and 7D. The marker “Excalibur_c5329_1335” had the highest −Log10(p) = 4.85. The number of tillers per plant (NTP) trait recorded one significant marker located on chromosome 3B. Seven MTAs were recorded for plant height located on chromosomes 1B, 3B, 4A, 5A, 5B, 5D, and 6A. The marker “RAC875_c41731_321” located on chromosome 2A was recorded for canopy temperature and chlorophyll content.
For irrigated conditions at Sidi Al-Aidi station, forty-eight MTAs (Table 3) were recorded, where 5 MTAs were recorded for biomass, these markers are located on chromosomes 5B and 7A. Chlorophyll content recorded seven MTAs located on chromosomes 1D, 2A, 3A, 3B, 5B, and 7A, where the marker “IAAV5819” recorded the highest −Log10(p) = 3.95 located on chromosome 3B. Seven significant markers were associated with canopy temperature, where the markers were located on chromosomes 1D, 2A, 3A, 3B, 5B, and 7A. DHE recorded one significant marker located on chromosome 1D with −Log10(p) = 3.81. DMA recorded 3 MTAs located on chromosomes 2A and 2D. Six significant MTAs were recorded for NPM located on chromosomes 2A, 2D, 5A, 5B, and 6A, where the marker “Excalibur_rep_c69730_391” had the highest −Log10(p) = 4.87 located on chromosome 5B. NSS trait recorded 5 MTAs located on chromosomes 4A and 5D. NTP trait recorded two significant markers located on chromosome 1B. Plant height recorded one MTA located on chromosome 7A with −Log10(p) = 3.07. The marker “AX-94513795” located on chromosome 3A was recorded for chlorophyll content and biomass.
For rainfed conditions at Merchouch station, fifty-five MTAs were recorded (Table 4), where 3 MTAs were recorded for biomass, these markers are located on chromosomes 6A, 6B, and 6D. Chlorophyll content recorded 12 MTAs located on chromosomes 1A, 1B, 2D, 3B, 3D, 6A, 6D, and 7A, where the marker “AX-94419426” recorded the highest −Log10(p) = 4.34 located on chromosome 1B. Eleven significant markers were associated with canopy temperature, where the markers were located on chromosomes 1A, 1B, 2D, 3A, 3B, 3D, 6A, and 7A. DHE recorded 14 significant markers, the marker “IAAV2346” recorded the highest −Log10(p) = 3.63 located on chromosome 5B. DMA recorded 6 MTAs located on chromosomes 2B, 4B, 4D, 5A, and 5B. Six significant MTAs were recorded for NPM located on chromosomes 3D, 5B, and 7D, where the marker “IACX11794” had the highest −Log10(p) = 4.04 located on chromosome 7D. Thousand kernel weight (TKW) trait recorded 2 MTAs located on chromosomes 2B and 5A. The marker “BS00003816_51” located on chromosome 3A was recorded for canopy temperature and chlorophyll content.
Under rainfed conditions at Sidi Al-Aidi station, out of the two highest significant MTAs found for grain yield, BobWhite_c2988_493 and Ex_c14755_1362 located on chromosomes 2B and 2D, respectively, (Figure 8) expressed the highest frequency of favorable alleles for grain yield in the population. The results showed that wheat genotypes carrying the cytosine and guanine bases at the BobWhite_c2988_493 and Ex_c14755_1362 markers combination, respectively, significantly out-yielded the other base combinations. The combination of the cytosine and thymine bases is shown to have low-yield performance and that is linked to the low cumulative number of favorable alleles of the two significant markers. Under irrigated conditions at Sidi Al-Aidi station, two of the highest significant MTAs found for grain yield, AX-94653560 and wsnp_Ex_c6748_11659366 located on chromosomes 2D and 2B, respectively, (Figure 8) expressed the highest frequency of favorable alleles for grain yield in the population. The results showed that wheat genotypes carrying the cytosine and thymine bases at the AX-94653560 and wsnp_Ex_c6748_11659366 markers combination, respectively, significantly out-yielded the other base combinations. The combination of the thymine and cytosine bases has low-yield performance, which is linked to the low-cumulative number of favorable alleles of the two significant markers.

2.4. Gene Annotation

Forty-six putative candidate genes were discovered for all significant markers related to the grain yield and yield-related traits (Supplementary Table S2), where 34 candidate genes were recorded for rainfed conditions and 12 genes were recorded for irrigated conditions. In rainfed conditions, for biomass, the highest significant marker on chromosome 2D, ‘Ex_c14755_1362’ was linked to the TraesCS2D02G053300 gene, which encodes the Receptor-like serine/threonine-protein kinase protein involved in serine/threonine/tyrosine kinase activity. Seven genes were identified for canopy temperature, where the highest significant marker ‘AX-94463982’ on chromosome 7A was linked to the TraesCS7A02G088800 gene, which encodes Pre-mRNA-splicing factor 38 involved in the mRNA splicing, via spliceosome. In irrigated conditions, the gene TraesCS5B02G032700 was linked to the marker ‘AX-94826800’ located on chromosome 5B which is associated with chlorophyll content, the gene encodes for Kinesin-like protein involved in microtubule binding. The gene TraesCS5B02G300100 was linked to the marker ‘wsnp_Ex_c6748_11659366’ located on chromosome 5B which is associated with biomass the gene encodes for Trigger_N domain-containing protein involved in peptidyl-prolyl cis-trans isomerase activity.

3. Discussion

3.1. Phenotypic Variability for Grain Yield and Yield-Related Traits

Bread wheat is a major crop in many parts of the world, particularly in Central and West Asia and North Africa (CWANA) as well as in Sub-Saharan Africa (SSA). In the CWANA region, water shortage is becoming a severe challenge for wheat production. The creation of novel drought-tolerant bread wheat genotypes might be a long-term solution for increasing wheat yield in challenged regions. ICARDA’s bread wheat breeding program targets generating genotypes that are abiotic and biotic stress-resistant and have acceptable end-use quality. Grain yield is a complicated property governed by numerous genes, the expression of which is controlled by environmental conditions. Therefore, this study was carried out to evaluate the drought-tolerance capacity of 200 bread wheat genotypes and to discover markers that are strongly related to grain yield and yield-related traits. Phenotype observations showed that wheat in rainfed conditions had lower GY and fewer DHE than wheat in irrigated conditions. The days to heading and maturity exhibited greater heritability than grain yield at all conditions, as previously reported [35,36]. As a result, grain yield heritability is often lower than that of other characteristics [37]. The correlation between days to heading and maturity was strongly positively correlated in both conditions which were consistent with previous research [38]. Biomass was positively correlated with grain yield in both conditions, but the correlation in irrigated conditions was upper than in rainfed conditions, this result is due to the ample irrigation and optimum conditions.

3.2. Marker Trait Association

GWAS has been used in several studies on bread wheat to uncover novel MTAs and QTLs linked with distinct traits in different conditions. We found a total of 104 significant markers under rainfed and irrigated conditions associated with agronomic traits across chromosomes in this study, where 44 MTAs found on the A genome, followed by the B and D genomes with 35 and 25, respectively, similar to another study that found the majority of MTAs for grain yield and yield-related traits on the A and B genomes, followed by the D genome [39]. Drought-stressed environments often have more major MTAs than non-stressed environments, which explains why drought tolerance is highly influenced by genotype by environmental factors [38]. Sixty-seven and thirty-seven MTAs at p < 0.001 were found associated with grain yield and agronomic traits under rainfed and irrigated conditions, respectively.
The highly significant marker for grain yield in rainfed conditions was identified on chromosome 2B with −Log10(p) = 3.81 at position 338 Mbp. We identified two other significant markers on chromosomes 2D and 4A. Several studies detected many MTAs/QTLs for grain yield in the same chromosomes [5,35]. In this study, we identified five MTAs for biomass in irrigated conditions, which are located on chromosomes 7A and 5B where the highest marker was ‘BS00022169_51’ located on chromosome 7A with −Log10(p) = 4.14 at position 691 Mbp, a previous study found the same marker on chromosome 7A [40]. On chromosome 5B, a highly significant marker associated with a number of seeds per spike under rainfed conditions was discovered with −Log10(p) = 4.85. Several MTAs/QTLs on chromosome 5B have been linked to NSS in dry conditions, according to a previous study [41]. Five MTAs were found under irrigated conditions located on chromosomes 4A and 5D for grain number per spike. Using 192 bread wheat genotypes planted at the same study site in Morocco, Alemu et al. [42] discovered that the marker ‘wsnp_Ex_c20386_29451037’ was linked to grain number per spike on chromosome 4A. Twelve MTAs regulating canopy temperature traits under rainfed conditions were found on chromosomes 1B, 2B, 3D, 5B, 6A, 6B, 6D, and 7A. MTAs for canopy temperature on chromosomes 7A and 2B were previously reported using different wheat panels cultivated in various settings [43]. Utilizing a population of 287 advanced elite lines of spring wheat, Sukumaran et al. [44] discovered the QTL RAC875_rep_c114561_587 associated with canopy temperature on chromosome 6A. The investigation was conducted using 90,000 wheat SNP created by Infinium iSelect SNP assays. The marker ‘BS00037225_51’ was associated with plant height on chromosome 3B with −Log10(p) = 7.1 at position 590 Mbp. Previously, numerous MTAs/QTLs associated with plant height were discovered on the same chromosome that we discovered [5]. The important markers were mapped to the bread wheat genome reference database at Ensemble Plant and UniProt in order to discover the probable genes linked with the many assessed features previously published. The findings indicated 46 genes involved in ATP binding, mRNA binding, protein serine kinase activity, protein heterodimerization activity, defense response, and oxidoreductase activity, among other biosynthetic pathways [45,46,47].

4. Materials and Methods

4.1. Plant Material and Experimental Conditions

This study employed a population of 200 bread wheat genotypes from the International Center for Agricultural Research in Dry Areas (ICARDA) (Supplementary Table S3). The field experiment was conducted at ICARDA’s experimental stations in Sidi El-Aidi, Morocco (33°07′27.6″ N 7°37′43.8″ W, 406 m a.s.l.) and Marchouch, Morocco (33°36′26.8″ N 6°42′43.9″ W) during the 2019–2020 and 2020–2021 cropping seasons. The genotypes were grown in a 3 m2 plot following an alpha lattice design with two replications. In Sidi EL-Aidi station the experiments were carried out in two different water regimes, rainfed and irrigated. For Marchouch station, the experiment was carried out under rainfed conditions. During the growth cycle in the irrigated experiment, the plots were watered by drip irrigation with three irrigations each week. The Sidi El-Aidi station is characterized by vertisol soil type with annual precipitation of about 300 mm over the two years. The Marchouch station is characterized by cambisol soil type with annual precipitation of about 400 mm over the two years. The stations are characterized by moderate humidity with an annual temperature ranging between 10 and 40 °C. The panel was seeded at a rate of 100 kg ha−1 during the first week of December.

4.2. Phenotyping and Statistical Analyses

The GWAS panel was phenotyped for 11 traits: grain yield (GY), days to heading (DHE), days to maturity (DMA), plant height (PLH), number of tillers per plant (NTP), number of plants in m2 (NPM), number of seeds per spike (NSS), biomass, chlorophyll content (CC), canopy temperature (CT), and thousand kernel weight (TKW). After threshing each plot, GY was measured in kg/plot and then converted to t/ha. When 50% and 90% of the plants reached the heading and maturity phases, respectively, DHE and DMA were recorded for each plot. When the plants reached maturity, the PLH in centimeters was recorded in each plot by measuring the distance from the soil surface to the top of the spike, without measuring the length of the awns. The biomass was measured for all plots in kilograms. The leaf chlorophyll content was measured on the flag leaf using a SPAD-502Plus chlorophyll meter at the heading stage on a clear day between 9:00 and 12:00. Canopy temperature was measured at the booting stage using a thermometer. TKW was calculated in grams using a grain counter. The “RcmdrMisc” package in R was used to determine the means, maximum, minimum, and standard deviation, as well as the coefficient of variance.

4.3. Genotyping

Fresh leaf samples were used to obtain genomic DNA from 2-week-old seedlings. Before extraction, the samples were frozen in glace liquid and maintained at −80 °C according to the methodology outlined in [48]. A total of 15,735 SNP markers were retained after quality filtering (the markers were used to generate the genotypic data for the panel used).

4.4. Linkage Disequilibrium Analyses and Population Structure

Linkage disequilibrium (LD) was calculated using Tassel software, where LD values of the 200 bread wheat genotypes were investigated using the SNP markers distributed across wheat genomes. Remington and his collaborator’s approach was used to conduct the LD decay study [49]. The population structure was estimated as a principal component (PC) analysis.

4.5. Genome-Wide Association Mapping and Genes Annotation

Genome-wide association analysis for grain yield and yield-related traits was carried out using Genomic Association and Prediction Integrated Tool version 3 (GAPIT 3) in the R environment [50]. A kinship K matrix and PCs (MLM: PCs+K) were used in the analysis. The important markers were shown on Manhattan plots, and markers with a −Log10(p) > 3.0 were designated as significant MTAs across the 21 chromosomes. Only significant markers (−log10p > 3.0) were traced using the CMplot program in the R environment [51]. Functional genes associated with grain yield and yield-related traits were identified using the Triticum aestivum genome annotation files downloaded from the Ensemble Plants database (http://plants.ensembl.org/Triticum aestivum/Info/Index , accessed on 5 April 2022 and the National Center for Biotechnology Information (NCBI) database. Uniport (https://www.uniprot.org, accessed on 6 April 2022) was used to identify protein function.

5. Conclusions

Some genotypes demonstrated good grain yield and acceptable agronomic performance in this study, and they were included in the worldwide nurseries given by ICARDA to national partners in the CWANA and SSA areas for release and future usage as crossing block parents. Using 200 spring bread wheat genotypes, we discovered 104 MTAs and 46 genes linked with various agronomic parameters under rain-fed and irrigated conditions. The markers discovered in this work will be utilized for marker-assisted selection after validation using a new set of elite genotypes.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/plants11202705/s1, Figure S1: Manhattan plots of 200 bread wheat genotypes of DHE (A), DMA (B), PLH (C), GY (D), CT (E), CC (F), NSS (G), NPM (H), NTP (I), Biomass (J), and TKW (K) under irrigation conditions at Sidi Al-Aidi station; Figure S2: Manhattan plots of 200 bread wheat genotypes of DHE (A), DMA (B), PLH (C), GY (D), CT (E), CC (F), NSS (G), NPM (H), NTP (I), Biomass (J), and TKW (K) under rainfed conditions at Sidi Al-Aidi station; Figure S3: Manhattan plots of 200 bread wheat genotypes of DHE (A), DMA (B), GY (C), GY (D), CT (E), CC (F), Biomass (G), TKW (H), under rainfed conditions at Merchouch station; Table S1: The top 10 elite genotypes for grain yield; Table S2: putative candidate genes; Table S3: 200 bread wheat genotypes from the International Center for Agricultural Research in Dry Areas (ICARDA).

Author Contributions

Conceptualization, Z.E.G.; methodology, Z.E.G. and W.T.; software, Z.E.G.; validation, Z.E.G., K.S. and W.T.; formal analysis, Z.E.G.; resources, W.T.; data curation, Z.E.G.; writing—original draft preparation, Z.E.G.; writing—review and editing, W.T.; visualization, K.S.; supervision, W.T. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by ICARDA and The APC was funded by ICARDA.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

We would like to thank the International Center for Agricultural Research in the Dry Areas (ICARDA) for its support and funding of this study.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Tadesse, W.; Nachit, M.; Abdalla, O.; Rajaram, S. Wheat Breeding at ICARDA: Achievements and Prospects in the CWANA Region. In A History of Wheat Breeding; Bonjean, A., Angus, B., van Ginkel, M., Eds.; Technique & Doc: Paris, France, 2016; ISBN 9978-2-7430-2091-0. [Google Scholar]
  2. Balla, K.; Rakszegi, M.; Li, Z.; Békés, F.; Bencze, S.; Veisz, O. Quality of winter wheat in relation to heat and drought shock after anthesis. Czech J. Food Sci. 2011, 29, 117–128. [Google Scholar] [CrossRef] [Green Version]
  3. Zhang, J.; Zhang, S.; Cheng, M.; Jiang, H.; Zhang, X.; Peng, C.; Lu, X.; Zhang, M.; Jin, J. Effect of Drought on Agronomic Traits of Rice and Wheat: A Meta-Analysis. Int. J. Environ. Res. Public. Health 2018, 15, 839. [Google Scholar] [CrossRef] [Green Version]
  4. Mohammadi, R. Breeding for increased drought tolerance in wheat: A review. Crop Pasture Sci. 2018, 69, 223. [Google Scholar] [CrossRef]
  5. El Gataa, Z.; El Hanafi, S.; Basheer, F.; Kehel, Z.; Bouhouch, Y.; El Messoadi, K.; Eddakir, K.; Ladraa, N.; Samir, K.; Tadesse, W. Genome wide association study of grain yield and yield related traits in spring bread wheat (Triticum aestivum L.) under drought and heat conditions in three different locations. J. Crop Sci. Biotechnol. 2021, 24, 361–373. [Google Scholar] [CrossRef]
  6. Bernardo, R. Molecular Markers and Selection for Complex Traits in Plants: Learning from the Last 20 Years. Crop Sci. 2008, 48, 1649–1664. [Google Scholar] [CrossRef] [Green Version]
  7. Risch, N.; Merikangas, K. The Future of Genetic Studies of Complex Human Diseases. Science 1996, 273, 1516–1517. [Google Scholar] [CrossRef] [Green Version]
  8. Appleby, N.; Edwards, D.; Batley, J. New Technologies for Ultra-High Throughput Genotyping in Plants. In Plant Genomics; Gustafson, J.P., Langridge, P., Somers, D.J., Eds.; Methods in Molecular BiologyTM; Humana Press: Totowa, NJ, USA, 2009; Volume 513, pp. 19–39. ISBN 978-1-58829-997-0. [Google Scholar]
  9. Zhu, J.; Kaeppler, S.M.; Lynch, J.P. Mapping of QTLs for lateral root branching and length in maize (Zea mays L.) under differential phosphorus supply. Theor. Appl. Genet. 2005, 111, 688–695. [Google Scholar] [CrossRef] [PubMed]
  10. Wang, S.; Wong, D.; Forrest, K.; Allen, A.; Chao, S.; Huang, B.E.; Maccaferri, M.; Salvi, S.; Milner, S.G.; Cattivelli, L.; et al. Characterization of polyploid wheat genomic diversity using a high-density 90,000 single nucleotide polymorphism array. Plant Biotechnol. J. 2014, 12, 787–796. [Google Scholar] [CrossRef] [Green Version]
  11. Allen, A.M.; Winfield, M.O.; Burridge, A.J.; Downie, R.C.; Benbow, H.R.; Barker, G.L.A.; Wilkinson, P.A.; Coghill, J.; Waterfall, C.; Davassi, A.; et al. Characterization of a Wheat Breeders’ Array suitable for high-throughput SNP genotyping of global accessions of hexaploid bread wheat (Triticum aestivum). Plant Biotechnol. J. 2017, 15, 390–401. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  12. Hu, P.; Zheng, Q.; Luo, Q.; Teng, W.; Li, H.; Li, B.; Li, Z. Genome-wide association study of yield and related traits in common wheat under salt-stress conditions. BMC Plant Biol. 2021, 21, 27. [Google Scholar] [CrossRef] [PubMed]
  13. Jordan, K.W.; Wang, S.; He, F.; Chao, S.; Lun, Y.; Paux, E.; Sourdille, P.; Sherman, J.; Akhunova, A.; Blake, N.K.; et al. The genetic architecture of genome-wide recombination rate variation in allopolyploid wheat revealed by nested association mapping. Plant J. 2018, 95, 1039–1054. [Google Scholar] [CrossRef] [Green Version]
  14. Lv, G.; Dong, Z.; Wang, Y.; Geng, J.; Li, J.; Lv, X.; Sun, C.; Ren, Y.; Zhang, J.; Chen, F. Identification of Genetic Loci of Black Point in Chinese Common Wheat by Genome-Wide Association Study and Linkage Mapping. Plant Dis. 2020, 104, 2005–2013. [Google Scholar] [CrossRef]
  15. Iannucci, A.; Marone, D.; Russo, M.A.; De Vita, P.; Miullo, V.; Ferragonio, P.; Blanco, A.; Gadaleta, A.; Mastrangelo, A.M. Mapping QTL for Root and Shoot Morphological Traits in a Durum Wheat × T. dicoccum Segregating Population at Seedling Stage. Int. J. Genom. 2017, 2017, 1–17. [Google Scholar] [CrossRef] [Green Version]
  16. Muqaddasi, Q.H.; Brassac, J.; Börner, A.; Pillen, K.; Röder, M.S. Genetic Architecture of Anther Extrusion in Spring and Winter Wheat. Front. Plant Sci. 2017, 8, 754. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  17. Qaseem, M.F.; Qureshi, R.; Shaheen, H.; Shafqat, N. Genome-wide association analyses for yield and yield-related traits in bread wheat (Triticum aestivum L.) under pre-anthesis combined heat and drought stress in field conditions. PLoS ONE 2019, 14, e0213407. [Google Scholar] [CrossRef] [Green Version]
  18. Arif, M.A.R.; Waheed, M.Q.; Lohwasser, U.; Shokat, S.; Alqudah, A.M.; Volkmar, C.; Börner, A. Genetic Insight Into the Insect Resistance in Bread Wheat Exploiting the Untapped Natural Diversity. Front. Genet. 2022, 13, 828905. [Google Scholar] [CrossRef] [PubMed]
  19. Francki, M.G.; Walker, E.; McMullan, C.J.; Morris, W.G. Evaluation of Septoria Nodorum Blotch (SNB) Resistance in Glumes of Wheat (Triticum aestivum L.) and the Genetic Relationship With Foliar Disease Response. Front. Genet. 2021, 12, 681768. [Google Scholar] [CrossRef] [PubMed]
  20. Wang, W.; Guo, H.; Wu, C.; Yu, H.; Li, X.; Chen, G.; Tian, J.; Deng, Z. Identification of novel genomic regions associated with nine mineral elements in Chinese winter wheat grain. BMC Plant Biol. 2021, 21, 311. [Google Scholar] [CrossRef]
  21. Nedelkou, I.-P.; Maurer, A.; Schubert, A.; Léon, J.; Pillen, K. Exotic QTL improve grain quality in the tri-parental wheat population SW84. PLoS ONE 2017, 12, e0179851. [Google Scholar] [CrossRef] [Green Version]
  22. Fowler, D.B.; N’Diaye, A.; Laudencia-Chingcuanco, D.; Pozniak, C.J. Quantitative Trait Loci Associated with Phenological Development, Low-Temperature Tolerance, Grain Quality, and Agronomic Characters in Wheat (Triticum aestivum L.). PLoS ONE 2016, 11, e0152185. [Google Scholar] [CrossRef]
  23. Thambugala, D.; Pozniak, C.J.; Kumar, S.; Burt, A.J.; Wise, I.L.; Smith, M.A.H.; Fox, S.L.; Costamagna, A.C.; McCartney, C.A. Genetic analysis of oviposition deterrence to orange wheat blossom midge in spring wheat. Theor. Appl. Genet. 2021, 134, 647–660. [Google Scholar] [CrossRef]
  24. Kertho, A.; Mamidi, S.; Bonman, J.M.; McClean, P.E.; Acevedo, M. Genome-Wide Association Mapping for Resistance to Leaf and Stripe Rust in Winter-Habit Hexaploid Wheat Landraces. PLoS ONE 2015, 10, e0129580. [Google Scholar] [CrossRef] [Green Version]
  25. Pretini, N.; Vanzetti, L.S.; Terrile, I.I.; Donaire, G.; González, F.G. Mapping QTL for Spike Fertility Related Traits in Two Double Haploid Wheat (Triticum aestivum L.) Populations. Plant Biol. 2020, 21, 1–18. [Google Scholar]
  26. Assanga, S.O.; Fuentealba, M.; Zhang, G.; Tan, C.; Dhakal, S.; Rudd, J.C.; Ibrahim, A.M.H.; Xue, Q.; Haley, S.; Chen, J.; et al. Mapping of quantitative trait loci for grain yield and its components in a US popular winter wheat TAM 111 using 90K SNPs. PLoS ONE 2017, 12, e0189669. [Google Scholar] [CrossRef] [Green Version]
  27. Soriano, J.M.; Colasuonno, P.; Marcotuli, I.; Gadaleta, A. Meta-QTL analysis and identification of candidate genes for quality, abiotic and biotic stress in durum wheat. Sci. Rep. 2021, 11, 11877. [Google Scholar] [CrossRef]
  28. Amalova, A.; Abugalieva, S.; Babkenov, A.; Babkenova, S.; Turuspekov, Y. Genome-wide association study of yield components in spring wheat collection harvested under two water regimes in Northern Kazakhstan. PeerJ 2021, 9, e11857. [Google Scholar] [CrossRef]
  29. Hitz, K.; Clark, A.J.; Van Sanford, D.A. Identifying nitrogen-use efficient soft red winter wheat lines in high and low nitrogen environments. Field Crops Res. 2017, 200, 1–9. [Google Scholar] [CrossRef] [Green Version]
  30. Chen, S.; Guo, Y.; Briggs, J.; Dubach, F.; Chao, S.; Zhang, W.; Rouse, M.N.; Dubcovsky, J. Mapping and characterization of wheat stem rust resistance genes SrTm5 and Sr60 from Triticum monococcum. Theor. Appl. Genet. 2018, 131, 625–635. [Google Scholar] [CrossRef] [Green Version]
  31. Liu, S.; Bai, G.; Lin, M.; Luo, M.; Zhang, D.; Jin, F.; Tian, B.; Trick, H.N.; Yan, L. Identification of candidate chromosome region of Sbwm1 for Soil-borne wheat mosaic virus resistance in wheat. Sci. Rep. 2020, 10, 8119. [Google Scholar] [CrossRef]
  32. van Frank, G.; Rivière, P.; Pin, S.; Baltassat, R.; Berthellot, J.-F.; Caizergues, F.; Dalmasso, C.; Gascuel, J.-S.; Hyacinthe, A.; Mercier, F.; et al. Genetic Diversity and Stability of Performance of Wheat Population Varieties Developed by Participatory Breeding. Sustainability 2020, 12, 384. [Google Scholar] [CrossRef] [Green Version]
  33. Colasuonno, P.; Lozito, M.L.; Marcotuli, I.; Nigro, D.; Giancaspro, A.; Mangini, G.; De Vita, P.; Mastrangelo, A.M.; Pecchioni, N.; Houston, K.; et al. The carotenoid biosynthetic and catabolic genes in wheat and their association with yellow pigments. BMC Genom. 2017, 18, 122. [Google Scholar] [CrossRef]
  34. Rollar, S.; Serfling, A.; Geyer, M.; Hartl, L.; Mohler, V.; Ordon, F. QTL mapping of adult plant and seedling resistance to leaf rust (Puccinia triticina Eriks.) in a multiparent advanced generation intercross (MAGIC) wheat population. Theor. Appl. Genet. 2021, 134, 37–51. [Google Scholar] [CrossRef]
  35. Mathew, I.; Shimelis, H.; Shayanowako, A.I.T.; Laing, M.; Chaplot, V. Genome-wide association study of drought tolerance and biomass allocation in wheat. PLoS ONE 2019, 14, e0225383. [Google Scholar] [CrossRef] [Green Version]
  36. Tadesse, W.; Suleiman, S.; Tahir, I.; Sanchez-Garcia, M.; Jighly, A.; Hagras, A.; Thabet, S.; Baum, M. Heat-Tolerant QTLs Associated with Grain Yield and Its Components in Spring Bread Wheat under Heat-Stressed Environments of Sudan and Egypt. Crop Sci. 2019, 59, 199–211. [Google Scholar] [CrossRef] [Green Version]
  37. Mathew, I.; Shimelis, H.; Mwadzingeni, L.; Zengeni, R.; Mutema, M.; Chaplot, V. Variance components and heritability of traits related to root: Shoot biomass allocation and drought tolerance in wheat. Euphytica 2018, 214, 225. [Google Scholar] [CrossRef]
  38. El Gataa, Z.; El Hanafi, S.; El Messoadi, K.; Samir, K.; Kehel, Z.; Tadesse, W. Genome wide association and prediction studies of agronomic and quality traits in spring beard wheat (Triticum aestivum L.) under rain-fed environment with terminal moisture stress. J. Cereal Sci. 2021, 101, 103278. [Google Scholar] [CrossRef]
  39. Tadesse, W.; Ogbonnaya, F.C.; Jighly, A.; Sanchez-Garcia, M.; Sohail, Q.; Rajaram, S.; Baum, M. Genome-Wide Association Mapping of Yield and Grain Quality Traits in Winter Wheat Genotypes. PLoS ONE 2015, 10, e0141339. [Google Scholar] [CrossRef] [Green Version]
  40. Zanke, C.D.; Ling, J.; Plieske, J.; Kollers, S.; Ebmeyer, E.; Korzun, V.; Argillier, O.; Stiewe, G.; Hinze, M.; Neumann, K.; et al. Whole Genome Association Mapping of Plant Height in Winter Wheat (Triticum aestivum L.). PLoS ONE 2014, 9, e113287. [Google Scholar] [CrossRef] [Green Version]
  41. Li, F.; Wen, W.; Liu, J.; Zhang, Y.; Cao, S.; He, Z.; Rasheed, A.; Jin, H.; Zhang, C.; Yan, J.; et al. Genetic architecture of grain yield in bread wheat based on genome-wide association studies. BMC Plant Biol. 2019, 19, 168. [Google Scholar] [CrossRef]
  42. Alemu, A.; Suliman, S.; Hagras, A.; Thabet, S.; Al-Abdallat, A.; Abdelmula, A.A.; Tadesse, W. Multi-model genome-wide association and genomic prediction analysis of 16 agronomic, physiological and quality related traits in ICARDA spring wheat. Euphytica 2021, 217, 205. [Google Scholar] [CrossRef]
  43. Ahmed, H.G.M.-D.; Naeem, M.; Zeng, Y.; Rashid, M.A.R.; Ullah, A.; Saeed, A.; Qadeer, A. Genome-wide association mapping for high temperature tolerance in wheat through 90k SNP array using physiological and yield traits. PLoS ONE 2022, 17, e0262569. [Google Scholar] [CrossRef]
  44. Sukumaran, S.; Dreisigacker, S.; Lopes, M.; Chavez, P.; Reynolds, M.P. Genome-wide association study for grain yield and related traits in an elite spring wheat population grown in temperate irrigated environments. Theor. Appl. Genet. 2015, 128, 353–363. [Google Scholar] [CrossRef] [PubMed]
  45. Michaletti, A.; Naghavi, M.R.; Toorchi, M.; Zolla, L.; Rinalducci, S. Metabolomics and proteomics reveal drought-stress responses of leaf tissues from spring-wheat. Sci. Rep. 2018, 8, 5710. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  46. Raza, M.A.S.; Saleem, M.F.; Shah, G.M.; Khan, I.H.; Raza, A. Exogenous application of glycinebetaine and potassium for improving water relations and grain yield of wheat under drought. J. Soil Sci. Plant Nutr. 2014, 14, 348–364. [Google Scholar] [CrossRef] [Green Version]
  47. Skalak, J.; Nicolas, K.L.; Vankova, R.; Hejatko, J. Signal Integration in Plant Abiotic Stress Responses via Multistep Phosphorelay Signaling. Front. Plant Sci. 2021, 12, 644823. [Google Scholar] [CrossRef] [PubMed]
  48. Ogbonnaya, F.C.; Seah, S.; Delibes, A.; Jahier, J.; López-Braña, I.; Eastwood, R.F.; Lagudah, E.S. Molecular-genetic characterisation of a new nematode resistance gene in wheat. Theor. Appl. Genet. 2001, 102, 623–629. [Google Scholar] [CrossRef]
  49. Remington, D.L.; Thornsberry, J.M.; Matsuoka, Y.; Wilson, L.M.; Whitt, S.R.; Doebley, J.; Kresovich, S.; Goodman, M.M.; Buckler, E.S. Structure of linkage disequilibrium and phenotypic associations in the maize genome. Proc. Natl. Acad. Sci. USA 2001, 98, 11479–11484. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  50. Lipka, A.E.; Tian, F.; Wang, Q.; Peiffer, J.; Li, M.; Bradbury, P.J.; Gore, M.A.; Buckler, E.S.; Zhang, Z. GAPIT: Genome association and prediction integrated tool. Bioinformatics 2012, 28, 2397–2399. [Google Scholar] [CrossRef]
  51. Li, L.-Y. CMplot: Circle Manhattan Plot; CRAN: Vienna, Austria, 2018. [Google Scholar]
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Figure 1. Scatter plots of grain yield under rainfed and irrigated conditions at Sidi El-Aidi station for 200 bread wheat genotypes grown during two seasons (2020 and 2021).
Figure 1. Scatter plots of grain yield under rainfed and irrigated conditions at Sidi El-Aidi station for 200 bread wheat genotypes grown during two seasons (2020 and 2021).
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Figure 2. Principal component bi-plot analysis of 200 bread wheat genotypes grown during two seasons (2020 and 2021) under the rainfed regime (A) irrigated regime, (B) at Sidi Al-Aidi station and rainfed regime at Merchouch station, (C) in Morocco.
Figure 2. Principal component bi-plot analysis of 200 bread wheat genotypes grown during two seasons (2020 and 2021) under the rainfed regime (A) irrigated regime, (B) at Sidi Al-Aidi station and rainfed regime at Merchouch station, (C) in Morocco.
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Figure 3. Cluster of 200 bread wheat genotypes grown during two seasons (2018 and 2019) under the rainfed regime (A) irrigated regime, (B) at Sidi Al-Aidi station, and rainfed regime at Merchouch station (C) in Morocco.
Figure 3. Cluster of 200 bread wheat genotypes grown during two seasons (2018 and 2019) under the rainfed regime (A) irrigated regime, (B) at Sidi Al-Aidi station, and rainfed regime at Merchouch station (C) in Morocco.
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Figure 4. Correlation for agronomic and physiology traits under rainfed (A) and irrigated (B) regime at Sidi Al-Aidi station and rainfed regime at Merchouch station (C) in Morocco.
Figure 4. Correlation for agronomic and physiology traits under rainfed (A) and irrigated (B) regime at Sidi Al-Aidi station and rainfed regime at Merchouch station (C) in Morocco.
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Figure 5. Linkage disequilibrium decay for A genome (A), B genome (B), and D genome (C) of 200 bread wheat genotypes.
Figure 5. Linkage disequilibrium decay for A genome (A), B genome (B), and D genome (C) of 200 bread wheat genotypes.
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Figure 6. Marker density on each bread wheat chromosome of 200 bread wheat genotypes.
Figure 6. Marker density on each bread wheat chromosome of 200 bread wheat genotypes.
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Figure 7. Manhattan plots and QQ plots of 200 bread wheat genotypes for grain yield under rainfed conditions at Sidi Al-Aidi station (A), irrigation conditions at Sidi Al-Aidi station (B), and rainfed conditions at Merchouch station (C).
Figure 7. Manhattan plots and QQ plots of 200 bread wheat genotypes for grain yield under rainfed conditions at Sidi Al-Aidi station (A), irrigation conditions at Sidi Al-Aidi station (B), and rainfed conditions at Merchouch station (C).
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Figure 8. Allele combination of average grain yield from two field experiments performed in (A) rainfed conditions and (B) irrigated conditions at Sidi Al-Aidi station with 200 bread wheat genotypes having four base–pair combinations of two independent single nucleotide polymorphism markers associated with grain yield: BobWhite_c2988_493 and Ex_c14755_1362 in rainfed (A) and AX-94653560 and wsnp_Ex_c6748_11659366 in irrigated (B).
Figure 8. Allele combination of average grain yield from two field experiments performed in (A) rainfed conditions and (B) irrigated conditions at Sidi Al-Aidi station with 200 bread wheat genotypes having four base–pair combinations of two independent single nucleotide polymorphism markers associated with grain yield: BobWhite_c2988_493 and Ex_c14755_1362 in rainfed (A) and AX-94653560 and wsnp_Ex_c6748_11659366 in irrigated (B).
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Table
Table 1. Phenotypic variation for grain yield and yield-related traits of the 200 bread wheat genotypes under rainfed and irrigated conditions.
Table 1. Phenotypic variation for grain yield and yield-related traits of the 200 bread wheat genotypes under rainfed and irrigated conditions.
LocationConditionTraitMeanMINMAXSDCVH2<0.001
Sidi Al-AidiIrrigatedDHE69.7962893.074.410.72***
DMA114.551081362.762.410.65***
PLH (cm)79.4467.5103.51.396.940.70***
C.T (°C)2321.326.40.723.130.52***
C.C (SPAD)11.510.6513.20.363.130.57***
NP/m232.6220608.462.590.53***
NTP5.39391.2523.280.67***
NSS59.21319712.1920.590.8***
Biomass (kg)2.971.385.40.8522.680.77***
GY (t/h)5.933.319.380.950.160.45***
TKW (g)38.623345.80.165.950.54***
Sidi Al-AidiRainfedDHE66.4754864.226.360.62***
DMA108.651061234.083.760.52***
PLH (cm)70.532385.56.969.860.65***
C.T (°C)23.9622.2732.670.853.570.42***
C.C (SPAD)47.8640.8253.052.194.580.51***
NP/m238.8630504.311.080.49***
NTP3.62350.4612.730.46***
NSS43.85227610.0222.850.63***
Biomass (kg) 1.10.611.880.2220.390.61***
GY (t/h)4.190.976.160.6315.040.32***
TKW (g)19.7014.424.61.648.330.48***
MerchouchRainfedDHE59.9053893.826.380.64***
DMA119.381111263.542.970.53***
PLH (cm)62.9742817.1611.370.67***
C.T (°C)25.6723.129.70.943.690.45***
C.C (SPAD)49.8941.9603.436.880.55***
NP/m242.2724546.0814.390.53***
NTP5.63480.84150.48***
Biomass (kg) 3.511.655.370.5916.850.70***
GY (t/h)4.092.326.850.7418.290.42***
TKW (g)34.3127432.958.590.51***
SD, standard of deviation; CV, coefficient of variation; H2, heritability; GY, grain yield, DHE, days to heading, DMA, days to maturity; PLH, plant height; NTP, number of tillers per plant; NPM, number of plants in m2; NSS, number of seeds per spike; CC, chlorophyll content; CT, canopy temperature; and TKW, thousand kernel weight; *** Significant at p ≤ 0.001.
Table
Table 2. List of the significant markers associated with Biomass, CC, CT, DHE, DMA, GY, NPM, NSS, NTP, and PLH from genome-wide association analysis of 200 bread wheat genotypes under the rainfed conditions at Sidi Al-Aidi station.
Table 2. List of the significant markers associated with Biomass, CC, CT, DHE, DMA, GY, NPM, NSS, NTP, and PLH from genome-wide association analysis of 200 bread wheat genotypes under the rainfed conditions at Sidi Al-Aidi station.
TraitSNP MarkerChromosomePosition (bp)MAFMarker EffectR2−Log10(p)Reference
BiomassEx_c14755_13622D20,769,4800.370.070.14.17[10]
BiomassBobWhite_c2988_4932B33,839,7420.37−0.070.14.17
BiomassAX-945137953A568,142,4430.03−0.200.083.39[11]
BiomassAX-948665413A568,383,3060.03−0.200.083.39
BiomassKukri_rep_c104865_575D562,121,9170.03−0.230.083.38[10]
Biomasswsnp_Ra_c19083_282152392B33,939,9280.32−0.070.083.32[10]
BiomassAX-951710822D28,417,6100.02−0.260.083.19[12]
BiomassRAC875_c41613_1246D163,836,0600.02−0.260.083.19[13]
BiomassTdurum_contig51605_1943B822,682,0750.04−0.160.083.02[14]
BiomassBS00071948_513A523,554,8270.04−0.160.083.02[10]
BiomassIACX60923A519,207,5900.04−0.160.083.02[10]
CCIAAV1085A601,615,6670.40.590.083.92
CCwsnp_Ku_c8400_142800213A659,159,8100.470.530.083.62[15]
CCKukri_c51474_3341B457,378,7260.24−0.600.083.58[16]
CTAX-944639827A53,911,1800.04−0.950.087.03
CTTdurum_contig49841_6185B38,166,7460.04−0.820.085.97[17]
CTRAC875_c43581_2806B199,014,7510.030.880.085.55[13]
CTTdurum_contig30403_4116D256,247,4500.030.880.085.55
CTAX-947418706B146,646,5550.040.810.085.5
CTTdurum_contig9584_4637A53,916,5320.05−0.720.085.5
CTGENE-4021_4966A610,349,8840.050.600.084.36[14]
CTTdurum_contig29607_2946A609,379,8920.050.580.084.12[18]
CTAX-946137041B579,797,7800.05−0.600.083.77
CTBS00064077_513D15,029,5340.07−0.430.083.33[13]
CTBS00074911_511B626,226,2130.08−0.440.083.29[10]
CTBobWhite_rep_c64068_2412B775,336,3690.33−0.220.083.09
DHEBS00065105_512B69,648,9430.11−1.570.083.78[19]
DHERAC875_c8271_13521B56,312,0900.44−1.230.083.68[20]
DMAAX-951037615B544,374,8230.052.500.083.99
DMAAX-943820817D553,220,2400.02−4.260.083.95
GYBobWhite_c2988_4932B33,839,7420.37−0.160.083.81[10]
GYEx_c14755_13622D20,769,4800.370.160.083.76
GYRAC875_c17918_3214A610,640,8060.250.160.083.92[10]
NPMRa_c29200_3001A546,044,4320.271.370.083.63
NPMAX-947119934A624,925,4530.35−1.210.083.28[11]
NPMAX-946900451D464,930,0940.27−1.260.083.26[11]
NPMAX-948220813A48,648,3590.27−1.260.083.26[11]
NPMRa_c5683_17621A551,461,6450.27−1.260.083.26[10]
NPMTdurum_contig18174_2831A566,484,6820.27−1.260.083.26[21]
NPMTdurum_contig56662_541A557,932,8380.27−1.260.083.26[22]
NPMwsnp_Ex_c23598_328269261A567,979,2100.27−1.260.083.26[21]
NPMwsnp_Ku_rep_c109724_942271361A564,302,4270.321.200.083.11[10]
NPMAX-950778031A569,947,7430.281.230.083.09
NPMExcalibur_c66_1471A572,350,7870.26−1.260.083.08[10]
NPMwsnp_CAP11_c146_1609031A572,350,8330.26−1.260.083.08[23]
NPMTdurum_contig81011_2441A572,350,8820.261.260.083.08[22]
NPMwsnp_Ra_c5433_96304953D603,264,0290.04−2.850.083.04[24]
NPMAX-951626731A545,528,5570.281.200.083.04
NSSExcalibur_c5329_13355B580,686,2530.224.240.084.85[25]
NSSBS00099719_515B580,103,2650.224.240.084.8[26]
NSSwsnp_Ra_c39562_472424555B580,103,3420.224.120.084.67[27]
NSSExcalibur_c9391_10165B580,085,1610.21−4.180.084.56[28]
NSSwsnp_Ex_c3834_69717125B536,516,2860.16−4.280.083.76
NSSCAP11_c991_1606B577,184,3210.057.410.083.72[10]
NSSAX-948149637D171,001,1000.12−4.490.083.6
NSSTA001769-05381D461,140,5790.094.690.083.3[29]
NSSBS00066944_511B587,048,0990.362.750.083.08
NSSTA005251-02781A532,251,6340.372.710.083.05
NSSAX-952576561B586,552,9150.37−2.710.083.05
NTPAX-951696253B54,757,9750.2−0.140.083.06
PLHBS00037225_513B590,294,6180.0213.790.087.1
PLHAX-945521251B11,692,1720.019.700.086.03
PLHBS00072156_515A540,611,5370.05−4.580.083.92
PLHBS00089597_515D552,040,0600.063.800.083.18
PLHAX-945320025B704,500,6600.21−2.360.083.1
PLHRa_c22675_5814A611,201,0880.21−2.360.083.1
PLHwsnp_Ku_c9763_162871326A581,748,3620.15−2.970.083.05
TKWAX-948646434D504,562,2000.02−2.730.083.5[11]
TKWAX-945124144A738,514,6550.032.030.083.28[11]
TKWBS00044443_517B498,149,7220.02−2.230.083.21[10]
TKWExcalibur_rep_c102136_2707B498,519,6450.022.230.083.21[10]
TKWAX-943898222A188,904,7850.022.620.073.08
TKWKukri_rep_c69627_9546A584,678,6860.04−1.660.073.05[10]
TKWAX-948268005B35,976,6750.022.140.073.01
MAF, minor allele frequency; bp, base pair.
Table
Table 3. List of the significant markers associated with Biomass, CC, CT, DHE, DMA, GY, NPM, NSS, NTP, PLH, and TKW from genome-wide association analysis of 200 bread wheat genotypes under the irrigated conditions at Sidi Al-Aidi station.
Table 3. List of the significant markers associated with Biomass, CC, CT, DHE, DMA, GY, NPM, NSS, NTP, PLH, and TKW from genome-wide association analysis of 200 bread wheat genotypes under the irrigated conditions at Sidi Al-Aidi station.
TraitSNP MarkerChromosomePosition (bp)MAFMarker Effect R2−Log10(p)Reference
BiomassBS00022169_517A691,259,6510.02−0.930.084.14[30]
Biomasswsnp_Ku_c4035_73630897A688,686,3240.02−0.930.084.14
Biomasswsnp_Ra_c19741_289656477A688,688,8260.02−0.930.084.14
BiomassAX-948700945B208,440,8680.03−0.670.063.18[11]
Biomasswsnp_Ex_c6748_116593665B484,735,5720.03−0.620.063.08
CCIAAV58193B72,716,4700.030.330.093.95[10]
CCAX-948268005B35,976,6750.02−0.330.073.26[11]
CCBobWhite_c15352_3947A667,214,2500.03−0.310.073.25
CCRAC875_c41731_3212A470,238,2260.39−0.090.073.05
CCBS00003816_511D435,801,5020.180.110.073.05[13]
CCBS00040568_511D435,928,2050.18−0.110.073.05[13]
CCKukri_c35426_5073A639,086,4630.31−0.090.073.01
CTIAAV58193B72,716,4700.030.670.093.95[10]
CTAX-948268005B35,976,6750.02−0.660.073.26
CTBobWhite_c15352_3947A667,214,2500.03−0.630.073.25
CTRAC875_c41731_3212A470,238,2260.39−0.190.073.05
CTBS00003816_511D435,801,5020.180.220.073.05[13]
CTBS00040568_511D435,928,2050.18−0.220.073.05[13]
CTKukri_c35426_5073A639,086,4630.31−0.190.073.01[10]
DHEKukri_rep_c106285_2951D4,235,8380.05−2.060.093.81[10]
DMABS00063748_512A76,344,9060.23−0.830.073.57[13]
DMABS00076261_512D76,580,0030.23−0.830.073.77[13]
DMAwsnp_BE488779D_Ta_1_22D76,639,7170.23−0.830.073.24
GYAX-946535602D552,989,4870.270.720.073.44[11]
GYwsnp_Ex_c6748_116593665B484,735,5720.03−1.220.063.15
GYAX-944305992D601,601,8960.47−0.420.063.10[11]
NPMExcalibur_rep_c69730_3915B566,504,6450.114.760.124.87
NPMKukri_c65380_4902D605,370,8850.065.400.14.12
NPMExcalibur_c23239_7832A735,005,9780.026.900.083.35
NPMExcalibur_c23239_9612D602,513,1200.026.900.083.35
NPMExcalibur_c5442_16916A16,571,2100.09−4.050.083.33
NPMAX-946376055A502,799,4090.08−4.200.083.25[11]
NSSKukri_c7786_815D546,689,1860.224.050.073.51[31]
NSSKukri_c19883_6294A732,519,0060.048.370.073.19
NSSBS00022036_515D547,273,7600.23−3.710.073.18[13]
NSSExcalibur_c64287_1454A622,200,7990.23−3.710.073.18
NSSCAP12_c5949_1045D546,650,8240.233.680.063.05[31]
NTPIAAV57761B675,560,9230.110.450.063.26[10]
NTPBS00063512_511B676,192,1030.09−0.480.063.69[13]
PLHJD_c1314_11847A706,832,1290.08−2.370.083.07
TKWBS00064829_511B12,813,2230.170.670.074.17[13]
TKWKukri_c2446_6831D7,353,1840.10−0.760.073.82
TKWKukri_rep_c69910_11531A11,937,6140.170.610.073.75
TKWBS00069300_511A12,006,1120.180.610.073.73[13]
TKWExcalibur_c44883_2441A11,940,1360.170.580.073.41
TKWBS00003761_511A16,390,7050.170.570.073.30[13]
TKWAX-947420211A14,361,0260.170.570.073.11[11]
TKWExcalibur_c25891_14023B554,033,8600.210.540.073.09
MAF, minor allele frequency; bp, base pair.
Table
Table 4. List of the significant markers associated with Biomass, CC, CT, DHE, DMA, GY, NPM, and TKW from genome-wide association analysis of 200 bread wheat genotypes under rainfed conditions at Merchouch station.
Table 4. List of the significant markers associated with Biomass, CC, CT, DHE, DMA, GY, NPM, and TKW from genome-wide association analysis of 200 bread wheat genotypes under rainfed conditions at Merchouch station.
TraitSNP MarkerChromosomePosition (bp)MAFMarker EffectR2−Log10(p)Reference
BiomassBS00099879_516A608,074,4500.09−0.340.014.10[13]
BiomassAX-952263096D460,572,4680.09−0.300.013.88[11]
BiomassKukri_c42895_5936B65,732,4540.360.170.013.31
CCAX-951267454A5,464,9910.49−1.080.074.48[11]
CCBobWhite_rep_c64913_3155A413,418,5960.381.050.073.38
CCExcalibur_rep_c108030_2604D108,902,8830.41−0.940.073.30[13]
CCExcalibur_c2171_27285A708,441,4040.27−1.150.073.24
CCAX-949741085A708,309,2440.261.150.073.23[11]
CCwsnp_Ex_c2171_40740035A708,442,3820.26−1.150.073.23
CCExcalibur_rep_c106790_1554D113,155,3460.4−0.930.073.18[13]
CCAX-944838854D98,582,1760.39−0.920.073.16[11]
CCAX-952315925A708,165,0830.251.130.073.12[11]
CCExcalibur_c42255_4255A702,166,6570.311.040.073.09[13]
CCKukri_c16087_2815A702,166,1000.311.040.073.09
CCwsnp_Ex_c3764_68536272B185,761,0880.490.950.073.00
CTAX-944194261B677,254,9710.01−1.400.0034.34[11]
CTAX-947960201A491,135,1960.01−1.400.0034.34[11]
CTAX-949752153D613,735,9620.01−1.400.0034.34[11]
CTAX-951525943B18,518,6290.03−0.780.0033.45[11]
CTwsnp_JD_c20555_182622607A674,276,7480.07−0.490.0033.41[32]
CTRAC875_c8565_9267A725,929,9020.040.650.0033.4
CTAX-945137953A568,142,4430.020.870.0033.4[11]
CTAX-948665413A568,383,3060.020.870.0033.4[11]
CTAX-946304106D249,961,1240.02−0.970.0033.2[11]
CTAX-950232312D640,215,4120.02−0.820.0033.07[11]
CTBS00043716_516A230,706,0860.02−0.810.0033.04
DHEIAAV23465B17,968,9690.04−2.890.043.63[10]
DHEAX-951680173B648,927,0530.033.530.043.49[11]
DHEBS00068817_513B607,812,6180.03−3.530.043.49[13]
DHEBS00068816_513B607,812,5790.023.420.043.43[13]
DHEExcalibur_c48047_903B617,682,8760.02−3.420.043.43
DHEBS00067651_515D521,522,8310.052.510.043.35[13]
DHEKukri_rep_c108378_525B583,178,2320.06−2.290.043.32
DHEAX-947926575A596,013,5180.062.290.043.32
DHEExcalibur_rep_c113405_1803B618,151,1650.032.800.043.32
DHEGENE-3207_6105B17,545,4610.04−2.460.043.11[33]
DHEBS00065543_515B17,575,0090.042.330.043.07
DHEExcalibur_c11605_1565B17,945,0280.042.330.043.07[13]
DHEGENE-3207_1345B17,545,7280.04−2.330.043.07[33]
DHEBS00039935_514B5,468,5200.03−2.890.043.01
DMAKukri_c8594_2034B17,255,1990.09−1.650.063.64
DMAtplb0035d20_5064D9,249,2270.09−1.650.063.64
DMAExcalibur_c45297_3165A571,784,8790.241.190.063.45[13]
DMAwsnp_Ex_rep_c69647_685984635A571,786,1040.24−1.190.063.45
DMAAX-948207535B689,950,3690.06−1.780.063.08[11]
DMAwsnp_RFL_Contig2914_27573722B740,805,1740.381.040.063.01
GYKukri_c264_4386A29,558,0200.030.570.013.06
NPMIACX117947D12,470,2340.162.540.034.04[34]
NPMExcalibur_c7255_6977D13,602,3270.11−2.790.033.61[13]
NPMD_GB5Y7FA02IDDA9_1837D13,487,4640.11−2.730.033.55[20]
NPMBS00022449_51UN89,193,1640.16−2.350.033.53[13]
NPMExcalibur_c833_14053D585,088,5280.112.650.033.4
NPMRAC875_rep_c74271_4145B696,492,7520.28−1.880.033.04
TKWAX-947127392B766,563,6140.01−3.370.0053.94[11]
TKWBobWhite_c14486_1225A615,864,2040.01−3.370.0053.8
MAF, minor allele frequency; bp, base pair.
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El Gataa, Z.; Samir, K.; Tadesse, W. Genetic Dissection of Drought Tolerance of Elite Bread Wheat (Triticum aestivum L.) Genotypes Using Genome Wide Association Study in Morocco. Plants 2022, 11, 2705. https://doi.org/10.3390/plants11202705

AMA Style

El Gataa Z, Samir K, Tadesse W. Genetic Dissection of Drought Tolerance of Elite Bread Wheat (Triticum aestivum L.) Genotypes Using Genome Wide Association Study in Morocco. Plants. 2022; 11(20):2705. https://doi.org/10.3390/plants11202705

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El Gataa, Zakaria, Karima Samir, and Wuletaw Tadesse. 2022. "Genetic Dissection of Drought Tolerance of Elite Bread Wheat (Triticum aestivum L.) Genotypes Using Genome Wide Association Study in Morocco" Plants 11, no. 20: 2705. https://doi.org/10.3390/plants11202705

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