First report of Fusarium ussurianum causing leaf spot on Hemerocallis citrina in Sichuan Basin of China.

Hemerocallis citrina is a popular vegetable crop in China, due to abundant nutrients in its edible flower buds. In March 2021, serious symptoms of leaf spot were observed on nearly 90% cultivated H. citrina seedlings in the fields of Dazhou city (31°17'56″ N, 107°31'59″ E), Sichuan, China. Symptomatic leaves were collected from 15 seedlings in five different sampling sites (3 seedlings per site). Small pieces (5 × 3 mm) of lesion margin were excised, surface disinfected in 70% ethanol for 20 s and 1% sodium hypochlorite (NaClO) for 40 s, washed, dried, placed on potato dextrose agar (PDA) amended with streptomycin sulfate (50 mg/L) and incubated in dark at 25 ℃ for two days. Finally, eight purified isolates, HHC-FL22, HHC-FL23, HHC-FL25, HHC-FL26, HHC-FL27, HHC-FL28, HHC-FL29 and HHC-FL30, showing similar morphology were obtained through transferring hyphal tips to fresh PDA plates. On PDA plates, mycelia were initially white but gradually became light yellow, and scarlet diffusible pigments were also produced with time. On carnation leaf agar, our isolates produced slightly curved macroconidia with 4 to 8 septa that measured 3.1 to 5.7 × 36.8 to 69.3 µm (n = 30). Microconidia and chlamydospores were not observed. Our isolates were initially identified as Fusarium species based on morphological features (Leslie and Summerell 2006). To further confirm accurate identity, primers EF1/EF2 (O'Donnell et al. 2010), TRI1015B/TRI1013E (Hao et al. 2017), RPB1-F5/RPB1-G2R (O'Donnell et al. 2010), and fRPB2-5F/fRPB2-11aR and RPB2-5f2/RPB2-7cr (O'Donnell et al. 2012) were used to amplify gene sequences of translation elongation factor-1 alpha (TEF1), 3-O-acetyltransferase (Tri101), and DNA-directed RNA polymerase II largest (RPB1) and second largest subunit (RPB2), respectively. Our sequences were deposited in GenBank under accession numbers OQ860946 to OQ860953 (TEF1), OR393245 to OR393252 (Tri101), OP131893 to OP131900 (RPB1), and OQ860954 to OQ860961 and OP131885 to OP131892 (RPB2), respectively. BLASTN searches of our sequences showed 99 ~ 100% identity with TEF1 (FJ240301.1), Tri101 (FJ240345.1), RPB1 (MW233297.1) and RPB2 (KM361666.1) of F. ussurianum NRRL 45681, and 99.05 ~ 100% identity with TEF1 (FJ240305.1) and Tri101 (FJ240349.1) of F. ussurianum NRRL 45833, respectively. Two independent maximum-likelihood phylogenetic trees based on different combined datasets of TEF1, Tri101, RPB1 and RPB2 of Fusarium species confirmed that our isolates were F. ussurianum. To test pathogenicity, conidial suspension from HHC-FL23 (106 conidia / mL) were sprayed to seedlings of cultivar "chuanhuanghua No.1" (n = 3) and incubated in a greenhouse (25°C under 90% relative humidity, 16/8 h light/dark cycle). Controls were treated with ddH2O. Ten days post-inoculation, natural symptoms appeared on leaves inoculated with HHC-FL23, but control group seedlings remained disease-free. This experiment was repeated three times. All re-isolated pathogens from diseased leaves were molecularly and morphologically identified using methods described above. Consequently, the re-isolated fungi were identical to these inoculated. The leaf spot disease could cause foliar damage and even drastic yield loss of flower buds under severe conditions. To our knowledge, this is the first report of F. ussurianum causing leaf spot in H. citrina worldwide. Our study will assist in monitoring causal agent diversity of leaf spot and breeding new resistant varieties in H. citrina.

First report of leaf spot caused by Epicoccum latusicollum on Hemerocallis citrina in China.

Hemerocallis citrina is a popular vegetable crop. Its eatable flower buds contain abundant nutrients, especially lecithin (Guo et al., 2022). In March 2021, leaf spot disease was observed on 90% cultivated H. citrina seedlings in Dazhou city (31°17'56″ N, 107°31'59″ E), Sichuan, China. Totally, 15 diseased seedlings were sampled (three samples per 666 m2). The symptomatic leaves were cut into pieces (5 × 3 mm), superficially disinfected with 70% ethanol for 20 s and 1% Sodium hypochlorite (NaClO) for 40 s, and washed with sterile distilled water six times. The disinfected tissues were incubated on PDA amended with streptomycin sulfate (50 mg/L) in dark at 25 ℃. Two days later, hyphal tips from the edges of growing colonies were transferred to fresh PDA plates. Finally, 40 purified isolates were obtained. Using primer pairs ITS1/ITS4 (Glass & Donaldson, 1995), amplified rDNA internal transcribed spacer (ITS) regions indicated that these isolates belonged to different genera, mainly including Epicoccum, Fusarium and Colletotrichum. Six isolates of Epicoccum genus similar in morphology, named HHC46, HHC47, HHC491, HHC492, HHC51 and HHC58, were selected for identification. Cultured on oatmeal agar for 7 days, colonies were initially white and villose. Fourteen days later, mycelia started to secrete scarlet pigment. The NaOH spot test showed color changed from green to red, identical to that in Epicoccum species (Boerema et al., 2004). Meanwhile, colonies produced abundant conidia. Conidia were ellipsoidal, aseptate, and 4.1 to 6.5 × 1.3 to 2.9 µm (n = 30). Chlamydospores were also observed, globose to subglobose. The morphological features were similar to those of Epicoccum latusicollum (Xu et al., 2022). The DNA sequences of Beta-tubulin (TUB2) and DNA-directed RNA polymerase II second largest subunit (RPB2) of six isolates were amplified and sequenced, using primer pairs Bt2a/Bt2b (Glass & Donaldson, 1995), and RPB2-5f2/RPB2-7cr (O'Donnell et al., 2012), respectively. BLASTN searches indicated our ITS (OP107240 - OP107245), TUB2 (OP131865 - OP131870) and RPB2 (OP131871 - OP131876) sequences except one TUB2 (OP131867), showed 100% identity to the corresponding sequences of E. latusicollum CGMCC:3.18346 (KY742101, KY742343 and KY742174, respectively). There was a nucleotide divergence between OP131867 and reference sequence. Based on concatenated ITS, TUB2 and RPB2 sequences, the constructed phylogenetic tree of Epicoccum species, confirmed that our isolates were E. latusicollum. To test pathogenicity, 2-year-old healthy seedlings of cultivar "chuanhuanghua No.1" were sprayed with conidial suspension of HHC51 (105 conidia/mL), with controls treated with sterile distilled water. Each treatment (biological replicates = 3) was incubated in a greenhouse (at 25°C under 90% relative humidity, 16/8 h light/dark cycle). The experiment was repeated twice. After 18 days, leaf spot symptom in inoculated seedlings appeared. Whereas, non-inoculated controls showed no symptom. The pathogens were re-isolated from diseased leaves and identified as E. latusicollum, based on morphology and molecular methods described above. E. sorghinum was previously reported as causal agent of leaf spot in H. citrina (Ma et al., 2021). To our knowledge, this is the first report of E. latusicollum causing leaf spot in H. citrina worldwide. Our study will assist with monitoring disease distribution in H. citrina and host diversity of E. latusicollum (Chen et al., 2017).

Genetic incorporation of genes for the optimal plant architecture in common wheat.

Wheat grain yield is affected by plant height, which is the total length of spike, the uppermost internode, and other elongated internodes. In this study, a population of recombinant inbred lines generated from a cross between two advanced winter wheat breeding lines were phenotyped over four locations/years and genotyped by using markers of genotyping-by-sequencing (GBS) and Diversity Array Technology (DArT) for mapping of genes for three traits, including spike length, the uppermost internode length, and plant height. Five genomic regions or quantitative trait loci (QTLs) were associated with candidate genes for these traits. A major QTL was associated with Q5A, and two novel haplotypes of Q5A were identified, one for a single nucleotide polymorphism (SNP) at position -2,149 in promoter region and the other for copy number variation. Compared with one copy Q5A on chromosome 5A in Chinese Spring, the novel haplotype of Q5A with two copies Q5A was found to generate spikes that are extremely compacted. A major QTL was associated with allelic variation in the recessive vrn-A1 alleles involving in protein sequences, and this QTL was associated with increased uppermost internode length but not with plant height. A major QTL for plant height was associated with Rht-B1b on chromosome 4B, but its effects could be compromised by two new minor QTLs on chromosome 7. Collectively, the favorable alleles from the four loci can be used to establish the optimal plant height in wheat. Supplementary Information: The online version contains supplementary material available at 10.1007/s11032-022-01336-2.

Identification and Evaluation of Wheat-Aegilops bicornis Lines with Resistance to Powdery Mildew and Stripe Rust.

Wheat pathogens, especially those causing powdery mildew and stripe rust, seriously threaten yield worldwide. Utilizing newly identified disease resistance genes from wheat relatives is an effective strategy to minimize disease damage. In this study, chromosome-specific molecular markers for the 3Sb and 7Sb chromosomes of Aegilops bicornis were developed using PCR-based landmark unique gene primers for screening wheat-A. bicornis progenies. Fluorescence in situ hybridization (FISH) was performed to further identify wheat-A. bicornis progenies using oligonucleotides probes Oligo-pSc119.2-1, Oligo-pTa535-1, and Oligo-(GAA)8. After establishing A. bicornis 3Sb and 7Sb chromosome-specific FISH markers, Holdfast (common wheat)-A. bicornis 3Sb addition, 7Sb addition, 3Sb(3A) substitution, 3Sb(3B) substitution, 3Sb(3D) substitution, 7Sb(7A) substitution, and 7Sb(7B) substitution lines were identified by the molecular and cytological markers. Stripe rust and powdery mildew resistance, along with agronomic traits, were investigated to evaluate the breeding potential of these lines. Holdfast and Holdfast-A. bicornis progenies were all highly resistant to stripe rust, indicating that the stripe rust resistance might derive from Holdfast. However, Holdfast-A. bicornis 3Sb addition, 3Sb(3A) substitution, 3Sb(3B) substitution, and 3Sb(3D) substitution lines showed high resistance to powdery mildew while Holdfast was highly susceptible, indicating that chromosome 3Sb of A. bicornis carries previously unknown powdery mildew resistance gene(s). Additionally, the transfer of the 3Sb chromosome from A. bicornis to wheat significantly increased tiller number, but chromosome 7Sb has a negative effect on agronomic traits. Therefore, wheat germplasm containing A. bicornis chromosome 3Sb has potential to contribute to improving powdery mildew resistance and tiller number during wheat breeding.

A universal karyotypic system for hexaploid and diploid Avena species brings oat cytogenetics into the genomics era.

BACKGROUND: The identification of chromosomes among Avena species have been studied by C-banding and in situ hybridization. However, the complicated results from several cytogenetic nomenclatures for identifying oat chromosomes are often contradictory. A universal karyotyping nomenclature system for precise chromosome identification and comparative evolutionary studies would be essential for genus Avena based on the recently released genome sequences of hexaploid and diploid Avena species. RESULTS: Tandem repetitive sequences were predicted and physically located on chromosomal regions of the released Avena sativa OT3098 genome assembly v1. Eight new oligonucleotide (oligo) probes for sequential fluorescence in situ hybridization (FISH) were designed and then applied for chromosome karyotyping on mitotic metaphase spreads of A. brevis, A. nuda, A. wiestii, A. ventricosa, A. fatua, and A. sativa species. We established a high-resolution standard karyotype of A. sativa based on the distinct FISH signals of multiple oligo probes. FISH painting with bulked oligos, based on wheat-barley collinear regions, was used to validate the linkage group assignment for individual A. sativa chromosomes. We integrated our new Oligo-FISH based karyotype system with earlier karyotype nomenclatures through sequential C-banding and FISH methods, then subsequently determined the precise breakage points of some chromosome translocations in A. sativa. CONCLUSIONS: This new universal chromosome identification system will be a powerful tool for describing the genetic diversity, chromosomal rearrangements and evolutionary relationships among Avena species by comparative cytogenetic and genomic approaches.

Molecular Mapping of the Stripe Rust Resistance Gene Yr69 on Wheat Chromosome 2AS.

Wheat is one of the major food crops in the world. Stripe rust, caused by Puccinia striiformis f. sp. tritici, is an economically important disease that affects wheat worldwide. The discovery of novel resistance genes and the deployment of effectively resistant cultivars are important for the ongoing control of wheat stripe rust and the maintenance of the agricultural productivity of wheat. CH7086, a new stripe rust-resistant wheat introgression line, was selected by crossing susceptible cultivars with the resistant Thinopyrum ponticum-derived partial amphiploid Xiaoyan 7430. The resistance of CH7086 is effective against all current Chinese P. striiformis f. sp. tritici races. CH7086 was crossed with the stripe rust-susceptible cultivars to develop F1, F2, F3, and BC1 populations for genetic analysis. Segregation in the F2 and BC1 populations and F2:3 lines were tested for resistance against the P. striiformis f. sp. tritici race CYR32. This test showed that CH7086 carries a single dominant gene for stripe rust resistance, which was temporarily designated YrCH86. The closest of the eight simple sequence repeat (SSR) and expressed sequence tag-SSR markers flanking the locus were X2AS33, which is 1.9 cM distal, and Xmag3807, which is 3.1 cM proximal. The resistance gene and its polymorphic markers were placed in deletion bin 2AS-0.78-1.00 using the 'Chinese Spring' nullisomic-tetrasomic, ditelosomic, and deletion lines. The tests of both allelism and resistance specificity suggested that the resistance gene found in CH7086 was not Yr17, which was the only current formally named Yr gene on chromosome 2AS. Thus, YrCH86 appeared to be a new locus and was permanently designated Yr69.

Mapping of Powdery Mildew Resistance Gene pmCH89 in a Putative Wheat-Thinopyrum intermedium Introgression Line.

Powdery mildew, caused by Blumeria graminis f. sp. tritici (Bgt), is a globally serious disease adversely affecting wheat production. The Bgt-resistant wheat breeding line CH09W89 was derived after backcrossing a Bgt resistant wheat-Thinopyrum intermedium partial amphiploid TAI7045 with susceptible wheat cultivars. At the seedling stage, CH09W89 exhibited immunity or high resistance to Bgt pathotypes E09, E20, E21, E23, E26, Bg1, and Bg2, similar to its donor line TAI7045 and Th. intermedium. No Th. intermedium chromatin was detected based on genomic in situ hybridization of mitotic chromosomes. To determine the mode of inheritance of the Bgt resistance and the chromosomal location of the resistance gene, CH09W89 was crossed with two susceptible wheat cultivars. The results of the genetic analysis showed that the adult resistance to Bgt E09 in CH09W89 was controlled by a single recessive gene, which was tentatively designated as pmCH89. Two polymorphic SSR markers, Xwmc310 and Xwmc125, were linked to the resistance gene with genetic distances 3.1 and 2.7 cM, respectively. Using the Chinese Spring aneuploid and deletion lines, the resistance gene and its linked markers were assigned to chromosome arm 4BL in the bin 0.68-0.78. Due to its unique position on chromosome 4BL, pmCH89 appears to be a new locus for resistance to powdery mildew. These results will be of benefit for improving powdery mildew resistance in wheat breeding programs.

Molecular characterization of a new wheat-Thinopyrum intermedium translocation line with resistance to powdery mildew and stripe rust.

A new wheat-Thinopyrum translocation line CH13-21 was selected from the progenies derived from a cross between wheat-Th. intermedium partial amphiploid TAI7047 and wheat line Mianyang11. CH13-21 was characterized by using genomic in situ hybridization (GISH), multicolor-GISH (mc-GISH), multicolor-fluorescence in situ hybridization (mc-FISH) and chromosome-specific molecular markers. When inoculated with stripe rust and powdery mildew isolates, CH13-21 displayed novel resistance to powdery mildew and stripe rust which inherited from its Thinopyrum parent. The chromosomal counting analyses indicated that CH13-21 has 42 chromosomes, with normal bivalent pairing at metaphase I of meiosis. GISH probed by Th. intermedium genomic DNA showed that CH13-21 contained a pair of wheat-Th. intermedium translocated chromosomes. Sequential mc-FISH analyses probed by pSc119.2 and pAs1 clearly revealed that chromosome arm 6BS of CH13-21 was replaced by Thinopyrum chromatin in the translocation chromosome. The molecular markers analysis further confirmed that the introduced Th. intermedium chromatin in CH13-21 belonged to the long arm of homoeologous group 6 chromosome. Therefore, CH13-21 was a new T6BS.6Ai#1L compensating Robertsonian translocation line. It concludes that CH13-21 is a new genetic resource for wheat breeding programs providing novel variation for disease resistances.

Genome-Wide Identification of NAC Family Genes in Oat and Functional Characterization of AsNAC109 in Abiotic Stress Tolerance.

The plant-specific NAC gene family is one of the largest transcription factor families, participating in plant growth regulation and stress response. Despite extensive characterization in various plants, our knowledge of the NAC family in oat is lacking. Herein, we identified 333 NAC genes from the latest release of the common oat genome. We provide a comprehensive overview of the oat NAC gene family, covering gene structure, chromosomal localization, phylogenetic characteristics, conserved motif compositions, and gene duplications. AsNAC gene expression in different tissues and the response to various abiotic stresses were characterized using RT-qPCR. The main driver of oat NAC gene family expansion was identified as segmental duplication using collinearity analysis. In addition, the functions of AsNAC109 in regulating abiotic stress tolerance in Arabidopsis were clarified. This is the first genome-wide investigation of the NAC gene family in cultivated oat, which provided a unique resource for subsequent research to elucidate the mechanisms responsible for oat stress tolerance and provides valuable clues for the improvement of stress resistance in cultivated oat.

Putative Thinopyrum intermedium-derived stripe rust resistance gene Yr50 maps on wheat chromosome arm 4BL.

Stripe rust-resistant wheat introgression line CH223 was developed by crossing the resistant partial amphiploid TAI7047 derived from Thinopyrum intermedium with susceptible cultivars. The resistance is effective against all the existing Chinese stripe rust races, including the most widely virulent and predominant pathotypes CYR32 and CYR33. Cytological analyses using GISH detected no chromosomal segments from Th. intermedium. It was presumed that the segment was too small to be detected. Normal bivalent pairing at meiosis in CH223 and its hybrids confirmed its stability. Genetic analysis of the F(1), F(2), F(3) and BC(1) populations from crosses of CH223 with susceptible lines indicated that resistance was controlled by a single dominant gene. The resistance gene was mapped using an F(2:3) population from Taichung 29/CH223. The gene was linked to five co-dominant genomic SSR markers, Xgwm540, Xbarc1096, Xwmc47, Xwmc310 and Xgpw7272, and flanked by Xbarc1096 and Xwmc47 at 8.0 and 7.2 cM, respectively. Using the Chinese Spring nulli-tetrasomic and ditelosomic lines, the polymorphic markers and the resistance gene were assigned to chromosome arm 4BL. As no permanently named stripe rust resistance genes had been assigned to chromosome 4BL, this new resistance gene is designated Yr50. The gene, together with the identified closely linked markers, could be used in marker-assisted selection to combine two or more resistance genes in a single genotype.

Genetic Incorporation of the Favorable Alleles for Three Genes Associated With Spikelet Development in Wheat.

The number of spikelets per spike is an important trait that directly affects grain yield in wheat. Three quantitative trait loci (QTLs) associated with spikelet nodes per spike (SNS) were mapped in a population of recombinant inbred lines generated from a cross between two advanced breeding lines of winter wheat based on the phenotypic variation evaluated over six locations/years. Two of the three QTLs are QSns.sxau-2A at the WHEATFRIZZY PANICLE (WFZP) loci and QSns.sxau-7A at the WHEAT ORTHOLOG OF APO1 (WAPO1) loci. The WFZP-A1b allele with a 14-bp deletion at QSns.sxau-2A was associated with increased spikelets per spike. WAPO-A1e, as a novel allele at WAPO1, were regulated at the transcript level that was associated with the SNS trait. The third SNS QTL, QSns.sxau-7D on chromosome 7D, was not associated with homoeologous WAPO-D1 or any other genes known to regulate SNS. The favorable alleles for each of WZFP-A1, WAPO-A1, and QSns.sxau-7D are identified and incorporated to increase up to 3.4 spikelets per spike in the RIL lines. Molecular markers for the alleles were developed. This study has advanced our understanding of the genetic basis of natural variation in spikelet development in wheat.

Molecular cytogenetic characterization of a new wheat-Thinopyrum intermedium homoeologous group-6 chromosome disomic substitution line with resistance to leaf rust and stripe rust.

Thinopyrum intermedium (JJJsJsStSt, 2n = 6x = 42), a member of tertiary gene pool of hexaploid wheat (Triticum aestivum L., AABBDD, 2n = 6x = 42), provides several beneficial genes for wheat improvement. In this study, line CH51 was developed from the BC1F8 progeny of a partial wheat-Th. intermedium amphiploid TAI8335 (2n = 56) and wheat cultivar (cv.) Jintai 170. Somatic metaphase chromosome counting showed that CH51 had stable 42 chromosomes. Genomic in situ hybridization (GISH) analysis showed that CH51 had 40 wheat chromosomes and two Th. intermedium chromosomes involving translocation between Js- and St-genome chromosomes. Non-denaturing fluorescence in situ hybridization (ND-FISH) analysis revealed that CH51 lacked a pair of wheat chromosome 6B. Wheat 55K SNP array analysis verified that chromosome 6B had the highest percentage of missing SNP loci in both CH51 and Chinese Spring (CS) nullisomic 6B-tetrasomic 6D (CS-N6BT6D) and had the highest percentage of polymorphic SNP loci between CH51 and cv. Jintai 170. We identified that CH51 was a wheat-Th. intermedium T6StS.6JsL (6B) disomic substitution line. Disease resistance assessment showed that CH51 exhibited high levels of resistance to the prevalent Chinese leaf rust and stripe rust races in the field. Therefore, the newly developed line CH51 can be utilized as a potential germplasm in wheat disease resistance breeding.

The Brittle Rachis Trait in Species Belonging to the Triticeae and Its Controlling Genes Btr1 and Btr2.

In many non-cultivated angiosperm species, seed dispersal is facilitated by the shattering of the seed head at maturity; in the Triticeae tribe, to which several of the world's most important cereals belong, shattering takes the form of a disarticulation of the rachis. The products of the genes Btr1 and Btr2 are both required for disarticulation to occur above the rachis nodes within the genera Hordeum (barley) and Triticum/Aegilops (wheat). Here, it has been shown that both Btr1 and Btr2 are specific to the Triticeae tribe, although likely paralogs (Btr1-like and Btr2-like) are carried by the family Poaceae including Triticeae. Aegilops tauschii (the donor of the bread wheat D genome) lacks a copy of Btr1 and disarticulation in this species occurs below, rather than above the rachis node; thus, the product of Btr1 appears to be required for disarticulation to occur above the rachis node.

[Development and application of a genome specific marker for Secale africanum].

Genome in situ hybridization (GISH) analysis of wheat-Secale africanum amphiploid revealed that the S. africanum genome displayed significant divergence to the Secale cereale genome. It is thus valuable to deploy genes from S. africanum. We performed the PCR analysis on S. africanum, wheat-S. afticanum amphiploid, T. eastivum cv. Anyuepaideng and other genetic stocks by 100 ISSR primers. A specific segment of 561 bp, named pSaUBC815561, was obtained from S. africanum using primer UBC815. This segment was not amplified from the control wheat lines. Primer UBC815 also am-plified fragments from wild species of genus Secale, including S. vavilovii, S. sylvestre, and other cultivated ryes. Based on the sequence of pSaUBC815561, a pair of special primers U815-F and U815-R was designed and was used to amplify the DNA of wheat related species in Triticeae aimed at validating the specificity of pSaUBC815561. PCR analysis indicated that this specific DNA fragment was amplified not only from a set of Chinese Spring wheat-Imperial rye chromosome addition lines but also from certain wheat-rye introgression lines. Therefore, pSaUBC815561 can be used as a specific marker for detection of chromosomes of Secale genome in wheat.

Chromosomal location and comparative genomics analysis of powdery mildew resistance gene Pm51 in a putative wheat-Thinopyrum ponticum introgression line.

Powdery mildew (PM) is a very destructive disease of wheat (Triticum aestivum L.). Wheat-Thinopyrum ponticum introgression line CH7086 was shown to possess powdery mildew resistance possibly originating from Th. ponticum. Genomic in situ hybridization and molecular characterization of the alien introgression failed to identify alien chromatin. To study the genetics of resistance, CH7086 was crossed with susceptible genotypes. Segregation in F2 populations and F2:3 lines tested with Chinese Bgt race E09 under controlled conditions indicated that CH7086 carries a single dominant gene for powdery mildew resistance. Fourteen SSR and EST-PCR markers linked with the locus were identified. The genetic distances between the locus and the two flanking markers were 1.5 and 3.2 cM, respectively. Based on the locations of the markers by nullisomic-tetrasomic and deletion lines of 'Chinese Spring', the resistance gene was located in deletion bin 2BL-0.89-1.00. Conserved orthologous marker analysis indicated that the genomic region flanking the resistance gene has a high level of collinearity to that of rice chromosome 4 and Brachypodium chromosome 5. Both resistance specificities and tests of allelism suggested the resistance gene in CH7086 was different from previously reported powdery mildew resistance genes on 2BL, and the gene was provisionally designated PmCH86. Molecular analysis of PmCH86 compared with other genes for resistance to Bgt in the 2BL-0.89-1.00 region suggested that PmCH86 may be a new PM resistance gene, and it was therefore designated as Pm51. The closely linked flanking markers could be useful in exploiting this putative wheat-Thinopyrum translocation line for rapid transfer of Pm51 to wheat breeding programs.