1. Introduction
Bread wheat (Triticum aestivum) is one of the most important food crops for mankind and the security of wheat production benefits economic development and social stability. However, wheat production in China is continually challenged by diseases, including rusts, powdery mildew, and Fusarium head blight. Stripe rust, caused by Puccinia striiformis f. sp. tritici (Pst), is one of the most devastating fungal diseases in many areas around the world. Beddow et al. [1] estimated that up to 88% of the world’s wheat cultivars had become susceptible since 1960 and that annual losses amounted to 5.47 million tonnes. Resistance is recognized as the most effective, economic, and environmentally safe strategy for control of stripe rust, although fungicides can also effectively control the disease, provided they are used in a timely and safe manner [2,3].
Resistance to stripe rust is generally categorized as seeding (or all-stage) resistance and adult-plant resistance (APR, including high temperature APR) according to the growth stage at which it is expressed [2,4]. Up until now, seventy-nine genes for stripe rust resistance (Yr1 to Yr79) have been permanently named, but dozens of temporarily designated and hundreds of quantitative trait loci (QTL) have been reported and mapped to the wheat genome [5,6]. Among the formally designated stripe rust resistance genes, 55 confer seeding resistance and 24 genes are described as APR genes [6,7,8,9,10]. Some of these genes have been very widely deployed in agriculture by major epidemics following the emergence and increase of new virulent pathogen races. Examples of such occurrences of “boom and bust” situations in China include the use of Yr1 from the 1950s, Yr9 from the 1970s (overcome by Chinese yellow rust race CYR29), so-called Fan 6 resistance from the 1990s (race CYR31), and Yr24/Yr26 from the 2000s (CYR34). At the time of its downfall in the late 1990s, Yr9, present in a 1RS·1BL translocation, was deployed in more than 80% of the released cultivars in China [11]. The lessons learnt from these events were that widespread deployment of a single highly effective resistance gene ultimately leads to failure, with detrimental effects proportional to area of wheat cultivars bearing that gene. With the aim to avoid the overuse of individual resistance genes, avoid deployment of combinations of effective resistance genes, and to use resistance, sources with reputed durability were generally applied. It is therefore necessary to find new sources of stripe rust resistance to identify the underlying genes for resistance and to convince breeders that they are worthy of use in current breeding programs.
The stripe rust in Sichuan province is the most serious foliar disease affecting wheat production. Wheat cultivars Chuanmai 42 (CH42) and Chuanmai 55 (CH55) developed by the Crop Research Institute, Sichuan Academy of Agricultural Sciences, were released in 2004 and 2009, respectively. CH42 was a synthetic wheat derivative with YrCH42 (=Yr24/Yr26) [12] and maintained novel stripe rust resistance before 2010 in Sichuan [13]. As a new high-yielding and excellent quality variety, CH55 was selected from the cross SW3243/SW8688. It displayed a high level of resistance to stripe rust over a decade. However, the molecular genetic basis of CH55 for stripe rust resistance at adult plant stage has not been investigated.
Specific locus amplified fragment sequencing (SLAF-seq) is a recently developed, high-throughput strategy for large-scale single nucleotide polymorphism (SNP) discovery and genotyping, based on next generation sequencing (NGS) technology [14]. It is also cost-effective. SLAF-seq technology has been used in various species and different types of populations. For example, a high-density genetic map of cucumber (Cucumis sativus L.) spanning 845.87-cM with an average genetic distance of 0.45 cM was constructed for an F2 population [15]. Zhang et al. [16] similarly applied an SLAF-seq strategy in constructing a genetic map of 907.8 cM for a segregating Agropyron F1 population. Hu et al. [17] identified and cloned a candidate gene associated with thousand-grain weight (TGW) in wheat using DNA bulks of recombinant inbred lines (RILs). Yin et al. [18] fine-mapped the stripe rust resistance gene YrR39 to a 17.39 Mb segment on wheat chromosome 4B using SLAF-seq combined with bulked segregant analysis (BSA) of F2 and BC1 progenies. However, SLAF-seq has not been used to construct a high-density genetic map for an entire wheat RIL population and then identify QTLs for disease resistance.
In this study, an RIL population from a cross between CH42 and CH55 were developed for QTL mapping of stripe rust resistance and the SLAF-seq for individual RILs was used to construct a high-density genetic map for identifying the QTLs from CH55 and CH42 backgrounds.
2. Results 2.1. Fluorescence In Situ Hybridization (FISH) Analysis of CH55 and CH42
Non-denaturing FISH (ND-FISH) with the probes Oligo-pSc119.2-1 and Oligo-pTa535-1 was conducted to reveal the chromosome—composition of the two parents, CH55 and CH42. Compared with the standard FISH karyotype of wheat and rye chromosomes indicated by Tang et al. [19], we found that CH55 carried a pair of 1RS·1BL translocation and two pairs of 5B–7B reciprocal translocation chromosomes, whereas CH42 had a normal wheat karyotype (Figure 1).
2.2. Phenotypic Analysis
The frequency distributions of disease severities for stripe rust reaction at adult plant stages in each environment ranged over 0–100, 0–95, 2.5–100, and 0.5–100 at XD2016, XD2017, JT2017, and XC2017, respectively, showing continuous variation (Figure 2). The results indicated that stripe rust resistance in CH55 and CH42 was possibly controlled by multiple genes. In all four environments there was transgressive segregation in both directions (Table 1). Broad sense heritability (H2) was 0.88 (Table 1), indicating the data could be used for further QTL mapping.
2.3. Analysis of SLAF-Seq Data and SNP Markers
After SLAF library construction and sequencing, 354.218 Gb of data containing 1771.45 M paired-end reads were obtained; 94.82% of the bases were of high quality with Q30 (a quality score of 30 indicates a 1% chance of error, thus a 99% accuracy) and the guanine–cytosine (GC) content was 44.79% (Table 2). A total 2,825,198 SLAFs were developed. The SLAFs numbers for CH42 and CH55 were 862,053 and 863,835, and their corresponding average sequencing depths were 26.70 and 24.15, respectively. The average number of SLAFs for the RIL population was 493,537 and the average sequencing depth was 11.80 (Table 3). The range of reads in the RILs was 2,422,631 to 14,454,545.
The 1771.45 M paired-end reads, consisting of 2,825,198 SLAFs, contained 2,507,026 SNPs. After filtering 15,563 multiple mutation sites, 2,491,463 SNPs were used for subsequent analysis. Among those, the markers in which the bases were absent in the paternal or maternal parent were filtered, leaving 640,734 markers. Then, markers with average sequence depths < 4 were filtered, leaving 446,616 markers. Among the 446,616 SNP markers, 162,394 markers were polymorphic SNPs with a polymorphic rate of 36.36%. All the polymorphic SNP markers were classified into four genotypes—aa × bb, hk × hk, lm × ll, and nn × np. However, only the genotype aa × bb, consisting of 75,347 SNP markers, which accounted for 3.01% of the total SNP markers, was used for further analysis. Finally, markers with parental sequence depths of less than ten and significant segregation distortions of less than 0.01 (p < 0.01) were filtered and the remaining 6732 markers were used to construct the final genetic map (Table 4).
2.4. Genetic Map Construction and Consistency Analysis
The genetic map of 21 linkage groups was 2828.51 cM, with an average marker interval of 0.42 cM. The sub-genome statistics are provided in Table 5. The largest chromosome was chromosome 7B and the shortest was chromosome 6D. The largest gap in the map was 19.46 cM, which was located on chromosome 2B. The largest proportion of gaps less than 5 cM was 99.77% for chromosome 6A, whereas the smallest proportion of gaps, 93.85%, was for chromosome 4D (Figure 3).
The consistency analysis of the SNP loci between the genetic map and the physical map is shown in Table 6. Among all 21 linkage groups, there were 10 chromosomes with Spearman coefficients between 0.8 and 0.9, including 1A, 2D, 3A, 4B, 4D, 5B, 5D, 6A, 6D, and 7A. The Spearman coefficients for the other 11 chromosomes were between 0.9 and 1.0. The results indicated that the locations of most SNP loci on the genetic map were consistent with their corresponding physical locations in the Chinese Spring genome.
2.5. QTL Mapping of Stripe Rust Resistance of the RILs
Three QTLs were identified for stripe rust resistance using inclusive composite interval mapping (ICIM) with logarithm of odds (LOD) scores of 3.05–21.34, explaining 3.27–34.22% of the phenotypic variation (Figure 4, Table 7). These QTLs were identified on chromosomes 1B, 2A, and 7B and were temporarily designated Qyr.saas-1B, Qyr.saas-2A, and Qyr.saas-7B. Qyr.saas-7B was derived from CH42, whereas the other two QTLs were from CH55.
Qyr.saas-1B and Qyr.saas-7B were detected in all four environments, explaining 6.24%–34.22% and 3.27–20.64% of the phenotypic variation, respectively. Qyr.saas-1B was located in a 13.05 cM interval flanked by markers 90327 from XD2017 and 90695 from XD2016 and Qyr.saas-7B was located in a 13.16 cM interval flanked by markers 66151 from XD2017 and 66313 from XD2016. Qyr.saas-2A, with a smaller effect, was detected in only two environments and was located in a 12.12 cM region flanked by markers 71619 from XD2017and 71915 from JT2017, explaining 3.77–5.29% of the phenotypic variation.
2.6. Additive Effects of QTLs
The RILs were divided into 8 groups based on the genotypes of the closest markers for each of the three QTLs (Table 8). Significant additive effects were found in RILs with two or more resistance QTLs. Qyr.saas-1B and Qyr.saas-7B significantly reduced disease severity in all four environments when present alone. When present together in XC2017, they acted in an additive fashion and conferred lower severity than either QTL alone. A similar additive effect occurred in JT2017 in combinations of Qyr.saas-1B and Qyr.saas-2A. The lowest severities occurred when all three QTLs were combined in XD2016; the disease severities of many RILs approached immunity. Extremely low disease severity scores also occurred in XD2017 and XC2017, but were not apparent in JT2017.
3. Discussion
In order to determine the relationship between the three QTLs identified in the present study and other Yr genes and QTLs reported previously, we compared their physical locations by basic local alignment search tool (BLAST) analysis of the International Wheat Genome Sequencing Consortium (IWGSC) RefSeq v1.0 genome, which was shown in Figure 4 and Table 9.
Qyr.saas-1B, contributed by CH55, was significantly associated with resistance to stripe rust in all environments. It was physically located between 664.08 Mbp and 673.64 Mbp in the distal region of chromosome 1BL (Table 9, Table S1, Figure 4a). This region is rich in stripe rust resistance genes and QTLs, such as Yr21 [20], Yr24/Yr26 [21], and Yr29 [22,23]. The physical interval of Qyr.saas-1B overlapped with Yr29, QYr.cim-1BL1 [24], QYr.cim-1BL2 [25], QYr.spa-1B [26], QYr.ucw-1BL [23,27], and QYr.sicau-1B.3 [28]. We concluded that Qyr.saas-1B was most likely Yr29. However, more work is needed to conclude that Qyr.saas-1B is Yr29. The Yr29 is an APR gene first reported in cultivar Pavon 76 [29], but has since been identified in many different genetic backgrounds, including Pastor [30], Francolin#1 [24], and Klein Chajá [27]. In the present study, CH55 showed high resistance to stripe rust in all four environments with low disease severities of 15–40, with Qyr.saas-1B explaining 6.24%–34.22% of the phenotypic variation. This indicates that Qyr.saas-1B is relatively effective in Sichuan. Moreover, extremely low disease severity scores occurred when Qyr.saas-1B was combined with the other two QTLs with rather positive additive effects also being detected (Table 8). Therefore, the Qyr.saas-1B is considered to be a valuable component of resistance for use in Sichuan breeding programs combined with other genes.
Qyr.saas-7B, derived from CH42, also had consistent QTLs across the environments; it was physically located between 678.64 Mbp and 706.81 Mbp in the distal region of chromosome 7BL (Table 9, Table S1, Figure 4c). Several permanently- and temporarily-named stripe rust resistance genes have been mapped to chromosome 7BL (Table 9), including Yr2 [31], Yr39 [32], Yr52 [33], Yr59 [34], Yr67 (YrC591) [35], Yr79 [6], YrZH84 [36], and YrMY37 [7]. None of the physical intervals for these genes overlapped with Qyr.saas-7B (Table 9, Figure 4c). A number of QTLs were also mapped to chromosome 7BL (Table 9), including QTL-7B.1 [37], QTL-7B.2 [38], QTL-7B.3 [39], QYr.nsw-7B [40], QYr.caas-7BL.1, and QYr.caas-7BL.2 [33]. The physical interval of QYr.nsw-7B from Tiritea [40] overlapped with Qyr.saas-7B (Table 9, Figure 4c), suggesting they could be the same locus. Similar to the genetic variation across environments, both QYr.nsw-7B [40] and the present Qyr.saas-7B could be important as a component of multiple-gene resistance to stripe rust. Previous study has located a stripe rust resistance gene YrCH42 on the 1B chromosome of CH42 [12], but the QTL of Qyr.saas-7B from CH42 was not detected as it was in this study. It is possible that the stripe rust resistance of YrCH42 was overcome with the occurrence of Pst race CYR34, which was inoculated in this study [13]. There is another possibility that the present study used the high-throughput SLAF markers to screen an entire wheat RIL population between CH45 and CH42, which is higher resolution than the previous study for CH42 by SSR-PCR assay [12].
A minor QTL from CH55 was identified on chromosome 2AL. The Qyr.saas-2A was physically located between 677.90 Mbp and 701.74 Mbp in chromosome 2AL (Table 9, Table S1, Figure 4b). Yr1 [41], Yr32 [42], and YrJ22 [43] were mapped to 2AL, but these were genes of large effect. Qyr.saas-2A was likely to be a new stripe rust resistance locus based on its different physical location (Table 9, Figure 4b). This QTL was detected only in XD2017 and JT2017, which explained 3.77% and 5.29% of the phenotypic variation, respectively (Table 7). The effect of Qyr.saas-2A was much smaller than that of Qyr.saas-1B and Qyr.saas-7B. However, a significant additive effect in Qyr.saas-2A was observed. Singh et al. [44] indicated that an adequate level of slow rusting resistance could be achieved by the additive/complementary effects of three to five genes. This has been supported by many reports, including those of Yang et al. [45], Lan et al. [24], and Rosewarne et al. [46]. Similarly, the disease severities of RILs approached immunity when Qyr.saas-2A was combined with two other QTLs, Qyr.saas-1B and Qyr.saas-7B, in XD2016. There is repeated evidence that an effective and stable level of adult plant stripe rust resistance can be achieved by using combinations of genes that individually confer relatively small effects. Therefore, although the effect of Qyr.saas-2A was small, it provided enhancement effects and therefore could be useful in Sichuan wheat breeding for multiple gene resistance to stripe rust.
Based on the studies of chromosome composition of CH55 revealed by FISH analysis (Figure 1), we found that CH55 contained both 1RS·1BL and 5B-7B reciprocal translocation chromosomes. The 1RS·1BL translocation is still widely used in wheat breeding because of the superior genes for grain yield and stress tolerances in 1RS [47]. In the present study, the 1BL arm of 1RS·1BL in CH55 carried the stripe rust resistance QTL Qyr.saas-1B. According to a previous study, the alien chromatin suppresses the recombination between normal and translocated chromosomes [48]. Therefore, the selection of 1RS·1BL accumulates excellent agronomic characteristics and resistance with high frequency in breeding practice. Moreover, the 5B–7B reciprocal translocation is possibly of French origin according to the genealogy of CH55. It was found that the stripe rust resistance QTL QYr.ufs-5B was located on 5BS in the 5B–7B reciprocal translocation [49], which requires further validation by Pst races in different environments for CH55.
4. Materials and Methods 4.1. Plant Materials and Field Trials
A set of 200 F6 RILs developed from cross CH42/CH55 and parents were used to evaluate stripe rust responses in multiple environments. CH42 and CH55, developed by Crop Research Institute, Sichuan Academy of Agricultural Sciences, were released in 2004 and 2009, respectively. CH42 is a synthetic wheat derivative produced from cross SynCD768/SW3243//Chuan 6415 and CH55 was selected from the cross SW3243/SW8688. Chuanyu12, developed by Chengdu Institute of Biology of Chinese Academy of Sciences, is highly susceptible to the currently prevalent Pst races in Sichuan province and was used as spreader.
Field trials were conducted at the Xindu (Sichuan Province) research station in the 2015–2016 (XD2016) and 2016–2017 (XD2017) growing seasons and also at Jitian and Xichong (Sichuan Province) in 2016–2017 (JT2017, XC2017). Field trials were conducted in randomized complete blocks with two replications. Plots were sown as single 1 m rows, 25 cm apart, and about 30 seeds were sown in each row. Every 20th row was planted with the susceptible cultivar Chuanyu 12 as a spreader to produce an inoculum and as a control. The surrounding spreaders were inoculated with a mixture of currently prevalent Pst races, including CYR33, CYR34(V26), and G22-14. Adult-plant disease severities were visually recorded as 0–100% according to the modified Cobb Scale of Peterson et al. [50] when severities on Chuanyu 12 reached 90–100%, usually 1–2 weeks post-anthesis.
4.2. Broadsense Heritability
Phenotypic variance per plot in multi-trials can be written as σP2 = σG2 + σGE2 + σε2 , where σG2 is the genetic variance, σGE2 is the variance for genotype-environment interaction, and σε2 is the residual variation. Broad sense heritability in on an individual plot basis was calculated with the formula H2 = σG2σG2+σGE2+σε2 .
4.3. DNA Extractions
Young leaf tissues of 1 plant per parent and RILs were sampled in 2016, stored at −80 °C, and used for DNA extraction. The genomic DNA from each genotype was extracted using the cetyltrimethylammonium ammonium bromide (CTAB) method.
4.4. SLAF Library Construction and High-Throughput Sequencing
In this project, we used the wheat reference genome version IWGSC1.0 downloaded from ftp://ftp.ensemblgenomes.org/pub/plants/release-30/fasta/triticum_aestivum/dna/. SLAF-seq was used to genotype the 200 RILs and parents using the procedure designed by Sun et al. [14], with minor modifications. DNA was digested into 464–484 bp fragments using restriction enzyme RsaI. The digested fragments were modified by adding nucleotide A and Dual-index sequencing adapters were ligated to the A-tailed DNA, which was amplified and purified to the target fragments. The purified fragments were sequenced on an Illumina HiSeqTM platform.
4.5. Analysis of SLAF-Seq Data and Genetic Map Construction
SLAF marker identification and genotyping were performed following Sun et al. [14]. SNP loci in each SLAF locus were detected using the genome analysis toolkit (GATK) software. A genetic map was constructed for filtered markers using HighMap software and referring to the procedure detailed by Zhang et al. [51]. Spearman coefficients were used to analyze the consistency between the genetic and physical maps.
4.6. QTL Analysis
QTL IciMapping V4.0 [52,53] was used to identify QTLs by ICIM. A LOD score of 3.0 was used as a threshold for the declaration of linkage and the Kosambi mapping function was used to convert recombination frequencies into map distances. If a QTL was detected in a single environment, it was discarded. A positive additive effect indicated that the favorable allele was from the CH55 parent, whereas a negative additive effect indicated that the favorable allele was from CH42.
4.7. FISH Analysis
Root-tip metaphase chromosomes of wheat cultivars CH42 and CH55 were prepared, as described by Han et al. [54]. The probes Oligo-pSc119.2-1 and Oligo-pTa535-1 were used to detect structural variations in this study [19]. The Oligo-pSc119.2-1 was 5′-end-labeled with 6-carboxyfluorescein (6-FAM, green) and the Oligo-pTa535-1 was 5′-end-labeled with 6-carboxytetramethylrhodamine (TAMRA, red). The detailed process of FISH was performed following Tang et al. [19].
5. Conclusions
This study constructed a high-density genetic map and identified three QTLs for stripe rust resistance using the CH42/CH55 RILs via SLAF-seq technology. The genetic map of 21 linkage groups was 2828.51 cM, with an average marker interval of 0.42 cM. Qyr.saas-7B was derived from CH42, whereas Qyr.saas-1B and Qyr.saas-2A were from CH55. Qyr.saas-2A was likely to be a new stripe rust resistance locus. A significant additive effect was observed when all three QTL were combined. The combined resistance genes could be of value in breeding wheat for stripe rust resistance.
| Environment | Parent Mean | RIL Population Mean | H2 | |||
|---|---|---|---|---|---|---|
| CH55 | CH42 | Min | Max | Mean | ||
| XD2016 | 30 | 10 | 0 | 100 | 20.96 | 0.88 |
| XD2017 | 15 | 85 | 0 | 95 | 39.54 | |
| JT2017 | 35 | 95 | 2.5 | 100 | 66.91 | |
| XC2017 | 40 | 40 | 0.5 | 100 | 48.41 | |
| Sample | Total Reads | Total Bases | Q30 Percentage (%) | GC (%) |
|---|---|---|---|---|
| CH42 | 31,435,118 | 6,285,898,686 | 97.82 | 44.96 |
| CH55 | 33,764,850 | 6,752,071,114 | 97.96 | 44.85 |
| Offspring | 8,531,292 | 1,705,900,571 | 94.82 | 44.79 |
| Total | 1,771,458,398 | 354,218,084,068 | 94.82 | 44.79 |
The data of offspring in the table are averages.
| Sample | SLAFs Number | Total Depth | Average Depth |
|---|---|---|---|
| CH42 | 862,053 | 23,017,201 | 26.7 |
| CH55 | 863,835 | 20,864,394 | 24.15 |
| Offspring | 493,537 | 5,744,268 | 11.8 |
| Filtering Step | Number of SNPs |
|---|---|
| All reads | 1771.45 M |
| SLAFs in the reads | 2,825,198 |
| SNPs in the SLAFs | 2,507,026 |
| Filtered multiple mutation sites | 2,491,463 |
| SNP without base deletion in the paternal or maternal parents | 640,734 |
| Sequence depth of SNPs > 4 | 446,616 |
| Polymorphic SNPs | 162,394 |
| SNPs of genotype AA × BB | 75,347 |
| SNPs with parental sequence depth >10 and non-significant
segregation distortion (p > 0.01) | 6732 |
| Genome | Chromosome | Marker Number | Total Distance | Average Distance | Gap < 5 cM (%) | Largest Gap |
|---|---|---|---|---|---|---|
| A | 1A | 823 | 106.63 | 0.13 | 99.64 | 9.07 |
| 2A | 350 | 99.09 | 0.28 | 99.14 | 16.36 | |
| 3A | 290 | 181.75 | 0.63 | 97.58 | 12.77 | |
| 4A | 321 | 117.36 | 0.37 | 98.75 | 11.72 | |
| 5A | 242 | 170.73 | 0.71 | 97.10 | 12.31 | |
| 6A | 443 | 117.14 | 0.26 | 99.77 | 8.64 | |
| 7A | 142 | 88.56 | 0.62 | 98.58 | 6.85 | |
| Subtotal | 2611 | 881.26 | 0.34 | -- | -- | |
| B | 1B | 491 | 183.21 | 0.37 | 99.59 | 12.92 |
| 2B | 474 | 191.60 | 0.40 | 99.15 | 19.46 | |
| 3B | 565 | 155.65 | 0.28 | 99.11 | 13.94 | |
| 4B | 136 | 134.38 | 0.99 | 97.04 | 14.91 | |
| 5B | 762 | 180.01 | 0.24 | 99.74 | 18.20 | |
| 6B | 322 | 130.55 | 0.41 | 97.82 | 10.64 | |
| 7B | 557 | 215.86 | 0.39 | 99.64 | 7.98 | |
| Subtotal | 3307 | 1191.26 | 0.36 | -- | -- | |
| D | 1D | 159 | 138.40 | 0.87 | 96.20 | 9.35 |
| 2D | 151 | 99.31 | 0.66 | 98.00 | 6.60 | |
| 3D | 104 | 109.02 | 1.05 | 95.15 | 11.72 | |
| 4D | 66 | 83.00 | 1.26 | 93.85 | 13.77 | |
| 5D | 103 | 102.24 | 0.99 | 94.12 | 10.07 | |
| 6D | 83 | 82.98 | 1.00 | 93.90 | 8.52 | |
| 7D | 148 | 141.04 | 0.95 | 95.24 | 14.52 | |
| Subtotal | 814 | 755.99 | 0.93 | -- | -- | |
| Total | 6732 | 2828.51 | 0.42 | -- | -- | |
| Chromosome | Spearman 1 |
|---|---|
| 1A | 0.886 |
| 2A | 0.999 |
| 3A | 0.821 |
| 4A | 1.000 |
| 5A | 0.975 |
| 6A | 0.807 |
| 7A | 0.875 |
| 1B | 0.961 |
| 2B | 0.967 |
| 3B | 1.000 |
| 4B | 0.846 |
| 5B | 0.873 |
| 6B | 0.989 |
| 7B | 0.939 |
| 1D | 0.970 |
| 2D | 0.857 |
| 3D | 0.989 |
| 4D | 0.805 |
| 5D | 0.892 |
| 6D | 0.812 |
| 7D | 1.000 |
1 A value of 1 indicates perfect collinearity.
| QTL. | Trial | Position | Left Marker | Right Marker | LOD | PVE (%) | Add a |
|---|---|---|---|---|---|---|---|
| Qyr.saas-1B | XD2016 | 172 | Marker90692 | Marker90695 | 3.28 | 6.24 | 6.07 |
| XD2017 | 167 | Marker90327 | Marker90607 | 21.34 | 34.22 | 17.34 | |
| JT2017 | 169 | Marker90327 | Marker90607 | 12.47 | 22.07 | 11.73 | |
| XC2017 | 168 | Marker90327 | Marker90607 | 12.00 | 22.19 | 16.88 | |
| Qyr.saas-2A | XD2017 | 67 | Marker71619 | Marker72016 | 3.42 | 3.77 | 5.75 |
| JT2017 | 72 | Marker71914 | Marker71915 | 3.74 | 5.29 | 5.73 | |
| Qyr.saas-7B | XD2016 | 205 | Marker66294 | Marker66313 | 8.29 | 16.82 | −9.94 |
| XD2017 | 192 | Marker66151 | Marker66171 | 3.05 | 3.27 | −5.35 | |
| JT2017 | 205 | Marker66294 | Marker66313 | 3.22 | 4.45 | −5.28 | |
| XC2017 | 205 | Marker66294 | Marker66313 | 13.19 | 20.64 | −16.42 |
a A positive additive effect indicates that the favorable alleles came from CH55; a negative additive effect indicates that the favorable allele was from CH42. XD, JT, and XC, which are denoted Xindu, Jitian and Xichong, respectively.
| QTLs | No. of RILs with Corresponding QTL or QTL Combination | Mean Disease Severity | |||||
|---|---|---|---|---|---|---|---|
| 1BL | 2AL | 7BL | JT2017 | XD2016 | XD2017 | XC2017 | |
| + | + | + | 23 | 38.22 a | 3.95 a | 15.78 a | 12.09 a |
| + | + | - | 14 | 52.32 ab | 18.93 b | 24.64 ab | 45.89 b |
| + | - | + | 17 | 59.74 bc | 7.71 ab | 23.62 ab | 17.59 a |
| - | + | + | 14 | 68.93 cd | 11.79 ab | 42.18 cd | 37.68 b |
| + | - | - | 12 | 71.25 cd | 16.25 ab | 33.54 bc | 45.63 b |
| - | - | + | 21 | 72.62 cd | 14.52 ab | 56.90 de | 46.55 b |
| - | + | - | 19 | 77.50 de | 44.21 c | 54.21 d | 80.13 c |
| - | - | - | 14 | 90.00 e | 43.93 c | 70.36 e | 86.96 c |
The same letter within a column indicates no significant difference at p > 0.05. “+” means containing the corresponding QTL while “-“ means no QTL.
| Chromosome Arm | Genes/QTLs | Left Marker | Right Marker | Left Physical Position | Right Physical Position | Reference |
|---|---|---|---|---|---|---|
| 1BL | Qyr.saas-1B | Marker90327 | Marker90695 | 664079816 | 673644678 | This study |
| Yr21 | M1(Pto kin2/S2) | M2(Pto kin3/PtoFen-S) | None | None | [20] | |
| Yr24/Yr26/YrCh42 | WRS467 | CM1641 | 328642215 | 328642801 | [21] | |
| Yr29 | Xgwm44 | Xgwm140 | 662195228 | 684861809 | [22,23] | |
| QYr.sicau-1B.1 | Xwmc156 | Xwmc216 | 461685422 | 487427087 | [28] | |
| QYr.sicau-1B.3 | AX-108726041 | AX-111056129 | 667604743 | 667641255 | [28] | |
| QYr.cim-1BL1 | Xgwm259 | Xgwm140 | 672333339 | 684861809 | [24] | |
| QYr.cim-1BL2 | WPt-1770 | WPt-9028 | 671741402 | 681848783 | [25] | |
| QYr.spa-1B | Wsnp_Ra_c53181_56932563 | Wsnp_Ra_c53181_56932563 | 664804354 | 664804467 | [26] | |
| QYr.ucw-1BL | IWA8581 | csLV46G22 | 670389674 | None | [23,27] | |
| 7BL | Qyr.saas-7B | Marker66151 | Marker66313 | 678635912 | 706808017 | This study |
| Yr2 | WMC364 | WMC364 | 375022989 | 375023010 | [31] | |
| Yr39 | Xgwm131 | Xgwm43 | 604774088 | None | [32] | |
| Yr52 | Xcfa2040 | Xbarc182 | 718432553 | 732366237 | [33] | |
| Yr59 | Xbarc32 | Xwmc557 | 723876921 | 728084216 | [34] | |
| Yr67 (YrC591) | Xbarc32 | Xbarc182 | 723876921 | 732366237 | [35] | |
| Yr79 | Xbarc72 | Xwmc335 | 214059722 | 233160839 | [6] | |
| YrZH84 | Xcfa2040 | Xbarc32 | 718432553 | 723876921 | [36] | |
| YrMY37 | Xgwm297 | Xbarc267 | 237502276 | 377136685 | [7] | |
| QTL-7BL.1 | IWA3155 | IWA3416 | 732651049 | 732651181 | [37] | |
| QTL-7BL.2 | Xgwm577 | Xwmc166 | 711234115 | 719852469 | [38] | |
| QTL-7BL.3 | IWB58601 | IWB58601 | 732651454 | 732651554 | [39] | |
| QYr.nsw-7B | Xgwm611 | Xgwm611 | 700632085 | 700632104 | [40] | |
| QYr.caas-7BL.1 | Xbarc176 | XwPt8106 | 557048410 | None | [33] | |
| QYr.caas-7BL.2 | Xgwm577 | XwPt4300 | 711234115 | None | [33] | |
| 2AL | Qyr.saas-2A | Marker72016 | Marker71915 | 677899968 | 701739954 | This study |
| YR1 | Xgwm311 | None | 772967422 | None | [41] | |
| Yr32 | Xwmc198 | Xwmc181 | 707741852 | 728609562 | [42] | |
| YrJ22 | Xwmc658 | IWA1348 | 771166682 | None | [43] |
Supplementary Materials
Supplementary materials can be found at https://www.mdpi.com/1422-0067/20/14/3410/s1.
Author Contributions
E.Y., Z.Y., Z.P., and W.Y. designed the experiments. M.Y., G.L. and L.L. performed the experiments. M.Y., H.W. and J.L. analyzed the data. M.Y. wrote the manuscript.
Funding
This research was funded by the National Key Research and Development Program of China (No. 2017YFD0100900), the National Natural Science Foundation of China (No. 31671683), Science & Technology Department of Sichuan Province (No. 2016JY0070) and Sichuan Academy of Agricultural Sciences.
Acknowledgments
The authors are grateful to McIntosh R.A. at the Plant Breeding Institute, University of Sydney, for review of this manuscript. The authors are also grateful to Tao Lang at Institute of Biotechnology and Nuclear Technology Research, Sichuan Academy of Agricultural Sciences, and Shuyao Tang at Sichuan Agricultural University for handling bioinformatics data.
Conflicts of Interest
The authors declare no conflict of interest.
Abbreviations
Pst Puccinia striiformis f. sp. tritici
APR Adult-Plant Resistance
CYR Chinese Yellow Rust
QTL Quantitative Trait Loci
SNP Single Nucleotide Polymorphism
CH42 Chuanmai 42
CH55 Chuanmai 55
SLAF-seq Specific Locus Amplified Fragment Sequencing
NGS Next Generation Sequencing
TGW Thousand Grain Weight
RILs Recombinant Inbred Lines
BSA Bulked Segregant Analysis
FISH Fluorescence In Situ Hybridization
ND-FISH Non-denaturing FISH
DAPI 4',6-diamidino-2-phenylindole
GC Guanine Cytosine
ICIM Inclusive Composite Interval Mapping
LOD Logarithm of Odds
IWGSC International Wheat Genome Sequencing Consortium
CTAB cetyltrimethylammonium ammonium bromide
GATK Genome Analysis Toolkit
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1Crop Research Institute, Sichuan Academy of Agricultural Sciences, Chengdu 610066, China
2School of Life Science and Technology, University of Electronic Science and Technology of China, Chengdu 610054, China
3Chengdu Academy of Agricultural and Forestry Sciences, Wenjiang, Chengdu 611130, China
*Author to whom correspondence should be addressed.
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Abstract
Introduction Bread wheat (Triticum aestivum) is one of the most important food crops for mankind and the security of wheat production benefits economic development and social stability. Analysis of SLAF-Seq Data and SNP Markers After SLAF library construction and sequencing, 354.218 Gb of data containing 1771.45 M paired-end reads were obtained; 94.82% of the bases were of high quality with Q30 (a quality score of 30 indicates a 1% chance of error, thus a 99% accuracy) and the guanine–cytosine (GC) content was 44.79% (Table 2). [...]markers with parental sequence depths of less than ten and significant segregation distortions of less than 0.01 (p < 0.01) were filtered and the remaining 6732 markers were used to construct the final genetic map (Table 4). QTL Mapping of Stripe Rust Resistance of the RILs Three QTLs were identified for stripe rust resistance using inclusive composite interval mapping (ICIM) with logarithm of odds (LOD) scores of 3.05–21.34, explaining 3.27–34.22% of the phenotypic variation (Figure 4, Table 7).
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