Introduction

Disease imposes an important constraint on crop productivity and is most effectively and sustainably managed by breeding cultivars harboring genetic resistance. The ability of many pathogens to overcome host resistance means that the discovery of additional sources of resistance is a must for any crop improvement program. Since the gene pool of bread wheat (Triticum aestivum) has been so extensively narrowed by more than a century of intensive breeding (Feuillet et al. 2008), the search for novel resistance genes needs to be extended to older materials such as landraces and even to related cultivated and wild species (Mondal et al. 2016; Zamir 2001). Over many years, wheat cytogeneticists and breeders have succeeded in developing a diverse collection of germplasm harboring introgression segments of variable length, many of which have targeted the introduction of genes conditioning resistance to leaf pathogens (King et al. 2017; Valkoun 2001). Advances in genomic technologies have enabled a much greater precision than has been possible hitherto in the characterization of these materials (Abrouk et al. 2017; Tiwari et al. 2014; Winfield et al. 2016). A number of introgressed genes conferring resistance to a fungal pathogen have been successfully isolated in hexaploid wheat: these currently comprise two conferring resistance to Puccinia triticina (Huang et al. 2003; Thind et al. 2017), five to P. graminis (Mago et al. 2015; Periyannan et al. 2013; Saintenac et al. 2013; Steuernagel et al. 2016) and one to Blumeria graminis (Hurni et al. 2013). B. graminis (commonly referred to as powdery mildew) epiphytotics can induce significant yield losses (Conner et al. 2003; Leath and Bowen 1989). A number of major resistance genes (Pm genes) have been identified (www.wheat.pw.usda.gov/cgi-bin/GG3/browse.cgi?class=gene); as most of these confer race-specific resistance, they are prone to being overcome by the rapidly evolving pathogen. Often durable form of resistance, referred to as adult plant resistance (APR), is typically conditioned by multiple genes, each conferring a small, but cumulative effect. As a result, uncovering its genetic basis normally requires quantitative trait locus (QTL) analysis. A meta-analysis (Lillemo and Lu 2015) has revealed that such genes are dispersed over 24 QTL-harboring regions, located on 18 of the 21 wheat chromosomes.

The tetraploid bread wheat relative T. militinae (genome formula AtG) is generally considered to be a spontaneous mutant of T. timopheevii (Dorofeyev et al. 1976), although it has also been suggested to have arisen from an introgressive hybridization between T. timopheevii and the BAu tetraploid T. carthlicum (Järve et al. 2002). Derivatives of a wide cross between the bread wheat cultivar (cv.) Tähti (genome formula BAuD) and T. militinae include a selection (line 8.1) which harbors T. militinae segments incorporated within chromosomes 1A, 1B, 2A, 4A, 5A, 5B and 7A (Jakobson et al. 2006). Among other traits introduced from T. militinae, line 8.1 exhibits a marked improvement in the level of powdery mildew resistance expressed at both the seedling and adult plant stages. According to a QTL analysis, the genetic basis of this resistance is dominated (respectively, 33% and 54% of the variance shown by seedlings and adult plants) by a genes within a segment located near the distal end of chromosome arm 4AL, referred to as QPm.tut-4A (Jakobson et al. 2006). When present in a cv. Tähti background, the resistance decreases the number of secondary haustoria formed by the pathogen and enhances host cell apoptosis (Islamov et al. 2015). The gene (or genes) present within QPm.tut-4A, which acts in a race non-specific manner (Jakobson et al. 2012), is located in T. militinae itself on chromosome 7G (Abrouk et al. 2017). In a hybrid between wild-type bread wheat and the introgression line, little recombination occurs between the T. militinae segment and the segment of chromosome 4AL which has been replaced in line 8.1. However, it has been possible to define the genetic length and position of the segment to a 2.5 cM interval (Jakobson et al. 2012). Here, the focus was to isolate the gene(s) which determine the QPm.tut-4A resistance. By deploying a range of genetic and genomic strategies, it has proved possible to identify a small number of candidate genes and to characterize and contrast the sequences which originated from chromosome 7G with those which they replaced on 4A.

Materials and methods

Plant materials and mapping populations

The Jakobson et al. (2012) mapping population comprised 98 F2 progeny bred from the cross cv. Chinese Spring (CS) × line 8.1; this was extended for the purpose of increasing the level of resolution by self-pollinating F2 individuals which were heterozygous for QPm.tut-4A through to the F5. In addition, a second mapping population (hereafter referred to as the “ph1 population”) was created by crossing the CS ph1b mutant (Sears 1977) with T312.30.38.16, a derivative of introgressive line 8.1 in which the only T. militinae segment present was the one harboring QPm.tut-4A. In order to derive a parental plant which was both homozygous for the ph1b allele and heterozygous for the segment harboring QPm.tut-4A, the resulting F1 hybrid was back-crossed to the ph1b mutant. Marker-assisted selected BC1F1 individuals were then allowed to self-pollinate. Selection for the ph1b allele was performed using a multiplex PCR assay involving the markers AWJL3, PSR128, PSR2120 and PSR574 (Roberts et al. 1999), while the QPm.tut-4A harboring segment was marked by owm76 and owm96. The subsequent generations (BC1F3 and further) were not employed for this study due to their low viability and fertility presumably caused by extensive chromosomal rearrangements associated with the action of ph1. Doubled haploid line DH397 containing the T. militinae resistance locus only on 4AL was derived from cross Tähti × 8.1 (Jakobson et al. 2012). A bacterial artificial chromosome (BAC) library was constructed from the DNA of 4AL telosomic chromosome flow sorted from 4AL ditelosomic line carrying the 4A T. militinae introgression (Jakobson et al. 2012). Grain of the CS aneuploid stocks nullisomic 4A-tetrasomic 4B and nullisomic 4A-tetrasomic 4D, required to validate the chromosome specificity of newly developed markers, was provided by the National BioResource Centre (Kyoto, Japan). A doubled haploid line (DH81) carrying the same T. militinae translocations which determined the powdery mildew resistance as line 8.1 (Jakobson et al. 2012) served as a further control. Finally, the bread wheat cv. Kanzler was used a susceptible host in experiments involving powdery mildew inoculations.

Phenotyping for powdery mildew resistance

Seedling resistance to powdery mildew was scored using an assay based on detached first seedling leaves of 10-day-old plants. Each leaf was cut into four segments, each of which was then laid in a Petri dish containing 0.6% agar supplemented with 0.35% w/v benzimidazol. The leaf segments were inoculated with four different isolates (2.1, 9.8, 13 and 14), as described by Jakobson et al. (2012). The Petri dishes were held at 17.5 °C, and the response was evaluated after 10 days using the 0–9 scale devised by Lutz et al. (1992). For each self-pollinated recombinant line selected from F2-derived F3-5 families, up to 30 progeny homozygous in the QPm.tut-4A region were phenotyped. The resistance status of each recombinant line was verified by comparing its progeny scores with scores of 12–16 progeny of homozygous nonrecombinant sister line selected from the same self-pollination.

The development of markers used for high-density genetic mapping

The informativeness of a potential marker was first assessed via an in silico inspection of the chromosome-specific survey sequences of 4AL-7G (Abrouk et al. 2017) and the chromosome survey sequences (CSS) of 4ALCS generated by IWGSC (2014). The choice of sequences was governed by the need to saturate the genetic map of the QPm.tut-4A region, so it was based on a virtual gene order of the chromosome 4A represented by GenomeZippers (Abrouk et al. 2017, Hernandez et al. 2012). 4AL CSS scaffolds obtained from the GenomeZipper delimited by the markers flanking the QPm.tut-4A segment were aligned with 4AL-7G sequence scaffolds using the BlastN algorithm (Altschul et al. 1990). Only low-copy sequences associated with a nucleotide identity of > 95% were considered for marker development, and those containing short indels were preferred. Where no indel was identifiable, markers were based on single-nucleotide polymorphisms using the cleaved amplified polymorphic sequence approach (Michaels and Amasino 1999). PCR primers were designed using Primer3 software (Untergasser et al. 2012). To ensure specificity for 4AL, given the presence of homoeologous sequence on 7AS and 7DS, primers were positioned to ensure the presence of a variant nucleotide close to 3′ end in the homoeologous sequences. Finally, the specificity of the putative amplicons was verified by a BlastN search against the whole wheat genome CSS (IWGSC 2014). A second marker discovery strategy profited from a BAC library-based, established CS 4AL-specific physical map (IWGSC 2018, URGI; urgi.versailles.inra.fr/). BAC clones making up the set of contigs which covered the QPm.tut-4A region were selected from the minimal tiling path and sequenced. Subsequently, sequence scaffolds positioned at the target location were employed for marker development based on the first strategy. A final strategy designed to extend the saturated portion of the QPm.tut-4A region beyond what was achievable using the first two strategies was based on the sequence of the T. dicoccoides 7AS region (Avni et al. 2017) and on the CS reference sequence WGA v0.4 (www.wheatgenome.org); this also was informative for identifying additional 4ALCS scaffolds for targeted marker development. All primer pairs were tested on a template of CS, DH81, a CS/line 8.1 derivative heterozygous for QPm.tut-4A, nullisomic 4A-tetrasomic 4B and nullisomic 4A-tetrasomic 4D and DNA from flow-sorted chromosome arms 4ALCS and 4AL-7G amplified according to Šimková et al. (2008). The methods used for PCR amplification and electrophoretic separation are given in the following section, and the primer sequences and associated information are summarized in Table S1. Where the physical position of a marker was uncertain, it was determined by screening 62 three-dimensional pools prepared from the minimal tiling path of the CS 4AL-specific physical map.

Genetic mapping

DNA was extracted using Agencourt® Genfind® v2 magnetic beads (Beckman Coulter Life Sciences, Indianapolis, IN, USA) on a Beckman Coulter® Biomek® NXP workstation, as described by Ivaničová et al. (2016). Markers owm82 and Xgwm160 (Röder et al. 1998) were used to select lines in which a recombination event had occurred in the region of the introgression segment in the mapping populations. The full set of markers was applied to genotype those arising from the CS × line 8.1 population, while a subset of 19 selected markers was applied to those arising from the ph1 population. Each 15 µL PCR contained 0.01% (w/v) o-cresolsulphonephtalein, 1.5% (w/v) sucrose, 0.2 mM of each dNTP, 0.6 U Taq DNA polymerase, 1 µM of each primer, 10 mM Tris-HCl, 50 mM KCl, 1.5 mM MgCl2 and 0.1% (v/v) Triton X-100. The template comprised either 10–20 ng genomic DNA or 5 ng DNA amplified from 4ALCS or 4AL-7G. The reaction conditions consisted of an initial denaturation step of 95 °C/5 min, followed by 40 cycles of 95 °C/30 s, an optimized annealing temperature (Table S1) for 30 s and 72 °C for 30 s per 500 bp amplicon length; the reactions were completed with an elongation step of 72 °C/5 min. Cleaved amplified polymorphic sequence assays were completed with a digestion using the appropriate restriction endonuclease. The amplicons were electrophoretically separated through 4% non-denaturing polyacrylamide gels and visualized by ethidium bromide staining.

Construction of the physical map

Sequence scaffolds taken from IWGSC RefSeq v1.0 (IWGSC 2018) were used to span the genomic region of CS 4AL replaced by the QPm.tut-4A segment in line 8.1. To obtain the corresponding sequence from T. militinae, a chromosome walking approach was initiated. A chromosome-specific BAC library designated TaaPmt4ALhA (www.olomouc.ueb.cas.cz/dna-libraries/cereals) was constructed from flow-sorted 4AL-7G chromosome arms according to the Šimková et al. (2011) protocol. BAC library plate pools were generated by mixing 40 µL of the bacterial culture from each well of a given plate, centrifuging (10 min at 2700 g), suspending the precipitate in 0.5 mL TE and boiling for 30 min. The suspension was then re-centrifuged (60 min at 2700 g), and a 450-µL aliquot of the supernatant was diluted 100-fold. The subsequent PCRs used as template a 1.5-µL aliquot of the diluted plate pool DNA. The plate pools were screened with the markers owm169 and owm228, together with other codominant markers located within the CS 4AL segment replaced by QPm.tut-4A (owm156, owm136, owm221, owm209, owm227, owm236, owm139 and owm235). Row and column pools of positive plates were prepared and used in the same way as plate pools. Selected BAC clones were sequenced on a MiSeq instrument (Illumina Inc., San Diego, CA, USA) using a Nextera DNA Library Prep Kit (Illumina) according to the manufacturer’s protocol. Paired-end reads were assembled by Ray software (Boisvert et al. 2010). Insertion site-based polymorphism or site-specific presence/absence variation markers were developed from the ends of sequenced BAC clones and used for a further round of BAC library screening. The procedure was iterated until the physical map had been assembled.

The identification and sequence analysis of candidate genes

The gene content along the QPm.tut-4A segment on 4AL-7G was annotated using the TriAnnot pipeline (Leroy et al. 2011, www6.inra.fr/decodage/TriAnnot). Predicted genes were subjected to a BlastP search against the set of non-redundant protein sequences (www.ncbi.nlm.nih.gov/BLAST), and conserved domains of putative proteins were annotated using the NCBI Conserved Domain Database (Marchler-Bauer et al. 2017) and the MOTIF search tool (www.genome.jp/tools/motif/) based on the Pfam database (Finn et al. 2016). Searches for homologs and the comparison of candidate gene sequences were based on the BlastN algorithm, applying a threshold of 90% identity and 60% coverage.

Reverse transcription PCR

Segments of the first leaf of 10-day-old seedlings of the doubled haploid line DH397 and line T312.30.38.16 were collected 0-, 24- and 48-h post-inoculation with powdery mildew and snap frozen in liquid nitrogen. Leaf segments from three independent inoculations were bulked for the purpose of RNA extraction, and negative control samples were formulated from non-inoculated leaf segments. The leaf tissue was homogenized using ball mill MM 301 (Retsch, Haan, Germany) with three 3 mm tungsten beads at 30 Hz for 45 s, and total RNA was extracted using a miRNeasy Mini Kit (Qiagen Inc., Hilden, Germany) according to the manufacturer’s protocol. The synthesis of the first cDNA strand was achieved using a Transcriptor High Fidelity cDNA Synthesis Kit (Roche Life Sciences, Indianapolis, IN, USA) based on an anchored-oligo(dT)18 primer. Gene-specific primers were designed for all 12 candidate genes such that the amplicons derived from gDNA differed in length from those derived from cDNA (Table S2). A portion of the Actin gene (GenBank accession number AB181991.1) was used as the reference sequence. The procedures used for PCR and electrophoretic separation were as described above.

Results

High-resolution genetic mapping around QPm.tut-4A

A set of 102 new genetic markers was developed to saturate the genetic map in the region of QPm.tut-4A (Figs. 1, 2, Table S1). Majority of these were developed using GenomeZipper and 4AL-specific BAC clones. Besides markers owm16 and owm39, polymorphism was inferred using the 4AL-7G and 4ALCS survey sequences (Abrouk et al. 2017, IWGSC 2014). Segregation patterns observed in the extended CS × 8.1 mapping population were used to establish marker order. The genotyping of 8425 individuals with respect to owm82 and Xgwm160 revealed 30 new recombination events. Testing these recombinant individuals for their reaction to the four powdery mildew isolates showed that the resistance phenotype was fully correlated with the presence of the T. militinae segment—the disease scores for the four isolates were, respectively, 0.5, 0.4, 0.1, 1.1 in the presence of the segment, and 3.3, 2.5, 2.6, 3.8 in its absence. The net effect of the mapping was reducing the genetic length of the segment harboring QPm.tut-4A to 0.012 cM (Fig. 1). The ph1 population was derived from the self-pollination of 22 (out of 107 screened) BC1F1 ([line 8.1 × ph1b] × ph1b) selections which were simultaneously homozygous for the ph1b allele and heterozygous for the QPm.tut-4A segment. The genotyping of the resulting 1255 BC1F2 progeny revealed 155 recombination events between owm82 and Xgwm160, equivalent to a 33-fold increase in recombination as compared to the rate observed in the presence of Ph1. The 0.012 cM QPm.tut-4A region was thereby split into eight subregions (Fig. 1b).

Fig. 1
figure 1

A high-density genetic map of the region harboring QPm.tut-4A. a Marker segregation displayed by 8519 progeny bred from the CS × 8.1 mapping population (including the F2 generation described at Jakobson et al. 2012) defines the genetic length of the QPm.tut-4A segment (marked in red) to 0.012 cM, lying within a 0.18 cM window within chromosome 4AL. The flanking markers used for identification of recombination events within the segment are highlighted in yellow. b The level of mapping resolution achieved was enhanced through the use of the ph1 mapping population, which provided an additional 30 new recombination events, thereby splitting the QPm.tut-4A region into eight subregions

Fig. 2
figure 2

Physical maps showing the gene content of the 480.2 kbp QPm.tut-4A segment inherited from T. militinae and the 640.8 kbp segment of chromosome 4AL replaced by the introgression in line 8.1. The predicted genes (Tm1Tm12 and CS1CS16) are depicted by arrowheads indicating their orientation. The size of the arrowheads is proportional to the length of the gene, and their color reports the presence of conserved domains: green: CC-(LRR)-NB-ARC; yellow: PGG; orange: ANK and PGG; blue: LRR/MAL/PK; red: patatin-like; black: PMEI-like; and gray: uncharacterized protein. Tm and CS genes linked by gray lines share sequence identity in their coding region of at least 90% at a coverage of ≥ 60% (a coverage < 80% applied only to the putative pseudogene CS15). Tm genes which produced a detectable transcript are indicated by a red asterisk. Shared markers are linked by a blue dashed line, those marking T. militinae but not CS genomic sequence, or vice versa, are highlighted in, respectively, light green and light red. The T. militinae region bounded by owm227 and owm228 was present in CS as two tandemly arranged, tail-to-tail orientated copies, as indicated by the green arrows

The physical map of the QPm.tut-4A segment

Six additional markers for the QPm.tut-4A region were developed by inspection of the three CS reference sequence IWGSC WGA v0.4 scaffolds (134864, 108602 and 47761) (www.wheatgenome.org) selected on the basis of markers lying within the owm169owm158 interval (Table S1). The owm228 marker was derived from same scaffold (134864) which contained the QPm.tut-4A flanking marker owm169. The application of these markers to the set of recombinant segregants defined the physical length of the CS sequence replaced by the QPm.tut-4A introgression to 640.8 kbp (Fig. 2). A 4AL-7G-specific BAC library was constructed in an effort to acquire sequences in the QPm.tut-4A region of line 8.1; the mean insert size harbored by the 43,008 clones generated provided a 6.8-fold coverage of the 4AL-7G chromosome arm (www.olomouc.ueb.cas.cz/dnalib/taapmt4alha). Pools of the set of 112 plates were assembled to perform a PCR screen based on the flanking markers owm169 and owm228, along with eight codominant markers (owm156, owm136, owm221, owm209, owm227, owm236, owm139 and owm235) mapping within the region (Fig. 2). One to seven positive BAC clones per marker were sequenced so that their end sequences could be used for the next round of chromosome walking-based marker development: 17 new markers were designed in this way (Table S1). In total, 26 BAC clones were sequenced to provide a complete sequence of the QPm.tut-4A region in line 8.1: The physical length of the segment bounded by owm169 and owm228 was 480.2 kbp.

Annotation and comparative analysis of the QPm.tut-4A segment

The T. militinae region was 25% shorter than the CS one (480.2 vs. 640.8 kbp). Gene annotation suggested that the QPm.tut-4A segment harbored 12 high-confidence (HC) protein-encoding genes (denominated Tm1Tm12, Fig. 2, Table 1), while the 4AL region of CS harbored 16 HC genes (CS1CS16, Table 2). The intergenic regions displayed no sequence similarity. A comparison of the T. militinae and CS genes based on a threshold of 90% identity and 60% coverage implied that only four of the T. militinae genes (Tm7, Tm8, Tm10 and Tm12) shared an appreciable level of homology with members of the CS set (CS8, CS9, CS11, CS13, CS15 and CS16) (Table 1, Fig. 2). The sequence of the proximal ends of the CS and line 8.1 regions (beyond owm169) were quite distinct with respect to both their sequence and gene content: The segment from owm169 to owm220 was 228 kbp in line 8.1, but only 19 kbp in CS, and they contained, respectively, six (Tm1Tm6) and one (CS1) genes. The central part of the segment (owm220owm227 in line 8.1 and owm220owm216 in CS) was longer in CS (322 vs. 51 kbp) and contained no predicted gene in line 8.1 and CS2CS7 in CS. The distal region (owm227owm228 in line 8.1 and owm216owm228 in CS) was, respectively, of length 200 kbp (genes Tm7Tm12) and 299 kbp (CS8CS16) (Fig. 2). The proximal segment harboring Tm1Tm6 was not represented on CS chromosome 4A. However, four of these genes (Tm1, Tm2, Tm5 and Tm6) each have a strong homoeolog (Table 3) lying in reverse orientation within a ~ 410 kbp region of chromosome arm 7AS situated about 17.4 Mbp from the telomere. The position of the QPm.tut-4A region is 41.05 Mbp distant from the 4AL telomere. The distal part of the region (owm227owm228) has been duplicated in CS, and the gene content has been differentiated. The two copies are arranged tandemly in a tail-to-tail orientation, resulting in the non-syntenic location of the owm227 marker (Fig. 2).

Table 1 Predicted candidate genes present in the QPm.tut-4A segment introgressed from T. militinae into line 8.1
Table 2 Gene content of the segment of CS chromosome arm 4AL replaced by the QPm.tut-4A segment introgressed from T. militinae into line 8.1
Table 3 Homoeologs on CS chromosome arm 7AS of the NLR family genes present in the QPm.tut-4A segment introgressed from T. militinae into line 8.1

Functional characterization of the candidate genes for powdery mildew resistance

The five genes Tm1, Tm2 and Tm4Tm6 each encoded a coiled-coil (CC) domain and a nucleotide-binding (NB) domain, thereby being members of the NB-ARC family (van der Biezen and Jones 1998). Tm2, Tm4 and Tm6 also encode a leucine-rich repeat (LRR) domain, indicating them as members of the disease resistance-associated NLR gene family (Ye and Ting 2008). The shorter length of both Tm1 and Tm5 (Table 1) implies that both are incomplete genes. Tm10 is predicted to encode a protein harboring an LRR/malectin/protein kinase (LRR/MAL/PK) domain, also shared by a number of plant disease resistance gene products (Sekhwal et al. 2015); this gene lies in the distal part of the introgression segment and shares homology with both CS9 and the truncated CS15 (Fig. 2). The sequences of the other six Tm genes have little or no connection with disease resistance: Tm7Tm9 each encode multiple PGG domains, Tm11 features ankyrin repeats, while Tm12 encodes a protein belonging to the patatin-like phospholipase family (Table 1). Four of the 12 Tm genes (Tm1, Tm2, Tm5 and Tm7) produced a detectable level of mRNA, and three of them (Tm1, Tm2 and Tm5) encode NLR proteins: Tm2 appears to be the only one of these which is intact.

Discussion

The introduction into the bread wheat gene pool of genes harbored by species belonging to its secondary and tertiary gene pools represents an attractive strategy for broadening the genetic diversity of a crop which has been intensively bred for over a century. However, the success of the strategy has been not infrequently limited by the simultaneous introgression of linked genes which are deleterious to either productivity and/or product quality. This phenomenon of linkage drag results from the suppression of recombination around an introgressed segment, a phenomenon which also hampers positional cloning, since it magnifies the ratio between physical (in bp) and genetic (in cM) distance and prevents efficient high-density mapping. The T. militinae segment harboring QPm.tut-4A suffers from exactly this problem. Recent significant progress in the next-generation sequencing technologies allowed development of two new gene cloning approaches called MutRenSeq (Steuernagel et al. 2016) and MutChromSeq (Sánchez-Martín et al. 2016) which can bypass the high-density map construction in gene cloning process. The MutRenSeq approach employing exome capture and sequencing focusses on identification of simultaneous deleterious mutations in single NB-LRR-like gene within mutants with lost resistance. The MutChromSeq uses similar approach consisting in identification of knockout mutations in single gene within mutant lines, but it requires flow sorting of respective chromosomes from all mutant lines and their sequencing. This means that only single dominant major-effect genes can be identified by these approaches. However, the QPm.tut-4A locus is associated with race non-specificity and incomplete resistance which suggests the resistance may be encoded by gene different from major-effect R genes (predominantly NB-LRR-like genes) or by more than one gene (Jakobson et al. 2006, 2012). The MutRenSeq and MutChromSeq approaches are therefore not feasible for the QPm.tut-4A gene/genes cloning. Fortunately, recent advances in DNA technology and the development of sophisticated genomic resources have substantially eased the processes of constructing a high-density map and of acquiring relevant sequence from both the donor and the recipient genomes.

High-density mapping

According to the Wheat-Composite2004-4A map (wheat.pw.usda.gov/GG3), the markers flanking QPm.tut-4A (Xwmc232 and Xgwm160) are separated by ~ 9 cM, which led Jakobson et al. (2012) to suggest that a plant heterozygous for the introgression experiences suppression of recombination in the region, as has been documented for a number of other bread wheat introgression segments (Bariana et al. 2001; Järve et al. 2000; Jia et al. 1996; Lukaszewski 2015). Several genomic resources developed in CS were exploited here to saturate the region with markers in order to fine map the resistance locus, and these greatly enhanced the efficiency with which such markers could be elaborated, especially compared to conventional approaches to marker discovery such as microsatellite screening (Röder et al. 1998) or searching for sequence polymorphism in expressed sequence (e.g. Valárik et al. 2006). The GenomeZipper and chromosome-specific survey sequences (Abrouk et al. 2017, Hernandez et al. 2012, IWGSC 2014) were particularly effective in this context, but use was also made of sequence scaffolds developed in the tetraploid wheat T. dicoccoides (Avni et al. 2017) and the BAC contigs defining the chromosome 4AL physical map (IWGSC 2018). Initially, these resources allowed the genetic length of the target to be narrowed to just 0.012 cM (Fig. 1). In a fully homologous situation, such as occurs on wheat chromosome 3B, the mean ratio between cM and Mbp in distal regions varies from 0.60 to 0.96 (Choulet et al. 2014). If the recombination between the introgressed segment and the unaltered bread wheat region was unimpeded, the physical length of the segment would have been estimated to be no longer than 20 kbp. The fact that the segment’s length was measured in hundreds of kbp demonstrated that there was a substantial localized suppression of recombination.

Structural divergence and recombination in the QPm.tut-4A segment

The pairing of homoeologs in hexaploid wheat is strongly restricted by the action of the Ph1 locus (Riley and Chapman 1958). The intention of creating the ph1 population was to induce a higher rate of recombination between the introgression containing QPm.tut-4A and its presumed homoeologous segment of CS 4AL, since the rate of recombination achieved in the presence of Ph1 was < 0.4% (31 out of 8519) within the owm82-Xgwm160 region (Fig. 1): Although this represented a very small genetic distance (0.18 cM), the suppression of pairing/recombination meant that the physical distance involved was potentially rather large. The effect was enhancing the rate of recombination by 33-fold. A comparable elevation in the recombination rate induced by removal of the Ph1 locus has been reported in a variety of interspecific hybrids (Lukaszewski 1995, Luo et al. 2000). The availability of the genomic sequence of CS (IWGSC 2018) made it possible to identify that the length of the 4AL segment (0.012 cM) replaced by the owm169-owm228 QPm.tut-4A locus in line 8.1 was 640 kbp (Figs. 1, 2) and that it harbors 16 predicted genes (Table 2). The inferred relationship between genetic and physical distance in the segment was therefore only 0.019 cM per Mbp, which is much lower than the ratio (0.60–0.96 cM per Mbp) obtained in the distal region of chromosome 3B and is even below the ratio associated with the 3B centromeric region (0.05 cM per Mbp) in which recombination is known to be repressed (Choulet et al. 2014). This major suppression of recombination reflects the lack of homology between the native wheat and the introgressed QPm.tut-4A locus. The length of the introgressed QPm.tut-4A locus (owm169owm228) was 480 kbp (Fig. 2), and it harbored 12 predicted genes (Table 1), eight of which lacked a homolog in the CS segment (Table 1, Fig. 2). The CS homologs of the other four genes (Tm7, Tm8, Tm10 and Tm12) lay in a duplicated segment, and one of the duplicated copies was present in inverted orientation. The region was further disrupted by a number of indels, and all these changes suggest a high level of evolutionary dynamics of the wheat genome. While loss of synteny and sequence divergence are commonplace between homoeologous genomes (Saintenac et al. 2013; Wicker et al. 2003), they can also feature in comparisons made between homologous genomes of different hexaploid wheat cultivars (Mago et al. 2014; Tsõmbalova et al. 2016).

The introgressed QPm.tut-4A locus included three full-length and two truncated NLR family genes (Table 1). This class of genes is frequently arranged in clusters, which is thought to reflect the outcome of duplication events followed by sequence divergence (Michelmore and Meyers 1998). The coding sequences of the T. militinae NLR-like genes shared only a moderate to a high (73–89%) level of identity at the nucleotide level. Their putative homoeologs present on chromosome arm 7AS of CS displayed a similar level of sequence relatedness (71–85%). This chromosomal location confirms the conclusion of Abrouk et al. (2017) that in T. militinae itself, the QPm.tut-4A segment is present on chromosome 7G. The G genome donor is thought to be a member of the Sitopsis section of the genus Aegilops, as is also the donor of the bread wheat B genome (Gornicki et al. 2014). The bread wheat chromosome 4A itself is a restructured chromosome composed of a mosaic of segments derived from 4AL, 5AL and 7BS (Devos et al. 1995, Hernandez et al. 2012), and the QPm.tut-4A introgression appears to lie within a part of this region which originated from 7BS, consistent with its transfer following meiotic pairing.

The potential function of the QPm.tut-4A candidates

The resistance to powdery mildew associated with the presence of the QPm.tut-4A segment was race non-specific and in a cv. Tähti background, accounted for 40% of the variation in resistance (Jakobson et al. 2012). To date, only few wheat genes associated with APR have been isolated, so unlike the case for race-specific seedling resistance genes, many of which belong to the NLR family, it is not clear what functionality the product of such a gene might have. The Lr34/Yr18/Pm38 gene, which provides protection against three distinct foliar pathogens, has been shown to encode an ABC transporter (Krattinger et al. 2009), while Lr22a, which confers broad-spectrum APR to leaf rust, encodes an NLR-like protein (Thind et al. 2017), as does the rice NLR family Pb1 gene against panicle blast (Hayashi et al. 2010). Assuming that one of the three NLR family genes Tm2, Tm4 and Tm6 represents the most likely candidate for the QPm.tut-4A resistance, the possible basis of its resistance being race non-specific needs to be explored. In one scenario, it may be that either two or even all three of the Tm genes, which are each individually race-specific, act together to confer apparent race non-specificity. Alternatively, it is possible that one of the three genes is a “defeated” major resistance gene which has retained some residual broad-spectrum effect, as has been demonstrated for some other defeated major resistance genes (Li et al. 1999). The latter hypothesis is probably the more plausible, given that the only gene for which a mRNA was detected was Tm2, although surprisingly it was possible to detect transcript of the two NLR-like pseudogenes Tm1 and Tm5. However, the lack of an LRR domain in the Tm2-encoded protein implies that it would be difficult for its product to recognize the pathogen’s avirulence signal. An additional candidate is represented by Tm10 which encodes a protein containing an LRR, a MAL and a PK domain. A barley protein of this domain composition (HvLEMK1) is known to mediate non-host resistance to powdery mildew, while its wheat ortholog acts to enhance the level of wheat host resistance to powdery mildew (Rajaraman et al. 2016). A comparison of the TaLEMK1 and the Tm10 protein sequences showed that they share only a 34% level of identity; this rather low level of homology, combined with the observations that the wheat LEMK1 homoeologs map to the group 5 chromosomes and that no Tm10 transcript was detected, rules out the possibility that the QPm.tut-4A resistance is conferred by Tm10. None of the other Tm genes encode a product which has been directly associated with disease resistance to date. However, Tm12—which encodes a protein belonging to the patatin-like phospholipase family—remains a candidate since the patatin-like protein AtPLP2 has been shown to represent a component of the cell machinery delivering apoptosis, and therefore makes a contribution toward resistance against an obligate biotroph (La Camera et al. 2009).

Author contribution statement

KJ, JD and MV designed the study; MV, EJ, MŠ, HŠ, JŠ and IJ were responsible for marker development, genotyping, BAC library construction, chromosome sorting, data analysis and the construction of the mapping populations. HP performed the phenotypic evaluation and IJ the statistical analysis. The bioinformatics analyses were conducted by EJ and MA, who also contributed to data interpretation. Other experiments were conducted by EJ. The manuscript was drafted by EJ and MV, and all the authors contributed to its editing and proofreading.