Identification of molecular markers associated with leptine production in a population of Solanum chacoense Bitter

  Solanum chacoense Bitter, a wild relative of the cultivated potato, produces several glycoalkaloids, including solanine, chaconine, and the leptines. The foliar-specific leptine glycoalkaloids are believed to confer resistance to the Colorado Potato Beetle (CPB). Using two bulked DNA samples composed of high- and low-percent leptine individuals from a segregating F₁ population of S. chacoense, we have identified two molecular markers that are closely linked to high percent solanine+chaconine and, conversely, to nil/low percent leptine. One of these, a 1,500-bp RAPD product (UBC370-1500), had a recombination value of 3% in the F₁ progeny, indicating tight linkage. UBC370-1500 mapped to the end of the short arm of potato chromosome 1, in the region of a previously mapped major QTL for solanidine, from a S. tuberosum (solanidine)×S. berthaultii (solasodine) cross. Taken together, these results suggest that either (1) a major locus determining solanidine accumulation in Solanum spp. is on chromosome 1 in the region defined by the RFLP markers TG24, CT197, and CT233, or (2) this region of chromosome 1 may harbor two or more important genes which determine accumulation of steroidal aglycones. These findings are important for the genetics of leptine (as well as other glycoalkaloid) accumulation and for the development of CPB-resistant potato varieties. Received: 5 March 1998 / Accepted: 28 July 1998     

Die Wirking einiger Solanum-Alkaloidglykoside auf den Kartoffelk?fer, Leptinotarsa decemlineata say

Zusammenfassung Die kristallisierten Solanum-Alkaloidglykoside (Solanin, Chaconin, Leptinin I, Leptinin II, Leptin I, Demissin und Tomatin) und ein amorphes Leptin III — Präparat wurden im Fraßtest an Kartoffelkäfern geprüft. Die Resistenz von Solanum chacoense gene Leptinotarsa kann durch den Gehalt an Leptinen erklärt werden. Die Leptine gehen unter Abspaltung der Acetylgruppe in die Leptinine über und verlieren damit ihre hohe fraßabschreckende Wirksamkeit. DDT-resistente Käfer sind gegen Solanum chacoense, die Leptine und die Leptinine unempfindlicher als normale.

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Summary Different Solanum alkaloids (crystallized samples of solanine, chaconine, leptine I, leptinine I, leptinine II, demissine and tomatine, and an amorphous sample of leptine III) were examined by a feeding-test in the Colorado beetle. All were found to discourage uptake of food.The resistance of Solanum chacoense against Leptinotarsa is due to its content of leptines. Leptines are transformed into leptinines by loss of the acetyl group. They lose their high activity in this process. Beetles resistant to DDT are less sensitive towards Solanum chacoense, leptines and leptinines than normal beetles.

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1) Herrn Professor Dr. Richard Kuhn zum 60. Geburtstag gewidmet. Seine Frage nach dem Vergällungsstoff von Solanum chacoense führte zu diesen Untersuchungen.

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2) Anschrift: Homburg/Saar, Institut für Physiologie.     

Mapping of genes associated with leptine content of tetraploid potato

High content of leptine glycoalkaloids present in Solanum chacoense has been associated with genetic resistance to Colorado potato beetle (Leptinotarsa decemlineata [Say]). From an unrecorded accession of S. chacoense, the North Dakota State University breeding program has developed a tetraploid genotype, ND4382-19, that contains foliar leptines. In this study, using a segregating population, ND5873 (ND4382-19 × Chipeta), and GC-MS to analyze foliar content of alkaloids, two loci, involved in the synthesis of leptines were identified. They segregated as two complementary epistatic genes that allowed the synthesis of leptinidine (Lep) and acetyl-leptinidine (AL), respectively. Partial AFLP maps for both parents were developed using 97 individuals from population ND5873. The total lengths mapped for ND4382-19 and Chipeta were 1,883 and 1,021 cM, respectively. The marker for Lep was located at the distal end of simplex-coupling linkage group R37. Expansion of the initial mapping population and analysis of Lep-containing individuals allowed us to identify the linkage group (R35) that enabled synthesis of AL. By the use of simple sequence repeat markers, linkage group R37 (Lep) and linkage group R35 (AL) have been identified as homologs of chromosomes II and VIII, respectively.H. Casper (deceased)     

Colorado potato beetle resistant somatic hybrid potato plants produced via protoplast electrofusion

Leptines are natural glycoalkaloids found only in certain selections of the wild potato speciesSolanum chacoense. These rare glycoalkaloids have been identified to be phytochemical defensive agents against insect herbivores such as the Colorado potato beetle (CPB). In an attempt to introduce this CPB resistance into the cultivated potatoS. tuberosum, interspecific somatic hybrid plants were developed between a dihaploid ofS. tuberosum and a high leptine-producing germplasm selection ofS. chacoense. The somatic hybrid was fused using protoplast electrofusion and regeneration techniques. Selection of interspecies fusion cell lines was based on hybrid vigor in protoplast-callus (p-callus) growth, on shoot regeneration from p-calli, and on characteristic appearance of anthocyanin pigment. This selection system was highly efficient and 12 of 13 fully regenerated plants were identified as somatic interspecies hybrids, as determined by the analyses of morphologic biochemical, and isozyme markers. In vitro insect bioassays demonstrated that the hybrids averaged a threefold reduction in leaf consumption by the CPB when compared to cultivated potatoes.     

Combining genetic engineering and traditional breeding to provide elevated resistance in potatoes to Colorado potato beetle

The sustainable deployment of resistant crop varieties is a critical issue for the implementation of biotechnology in crop pest management. Feeding, biomass accumulation, and mortality were evaluated for susceptible, insecticide‐resistant, and Bacillus thuringiensis (Bt) Cry 3A‐selected Colorado potato beetle (Leptinotarsa decemlineata Say) (Coleoptera, Chrysomelidae) larvae fed on: cultivated potato, a Solanum chacoense line expressing leptine glycoalkaloids, a transformed line expressing Bt toxin, or the leptine line transformed to express Bt toxin. Larvae selected for resistance to Bt‐Cry3A performed better on Bt foliage, but not as well on the leptine foliage, compared to susceptible or insecticide‐resistant larvae. Neither leptine nor Bt toxin completely inhibited the feeding and growth of 3rd and 4th instars of all three strains of Colorado potato beetle. However, for all three strains of Colorado potato beetle on leptine + Bt foliage, feeding was almost zero, growth was zero or negative, and mortality was near 100%.     

Quantitative trait locus analysis of tuber dormancy in diploid potato (Solanum spp.)

Quantitative trait locus (QTL) analysis for tuber dormancy was performed in a diploid potato population (TRP133) consisting of 110 individuals. The female parent was a hybrid between haploid S. tuberosum (2x) and S. chacoense, while the male parent was a S. phureja clone. The population was characterized for ten isozyme loci, 44 restriction fragment length polymorphisms (RFLPs) and 63 random amplified polymorphic DNAs (RAPDs). Eighty-seven of these loci segregating from the female parent were utilized to develop a linkage map that comprised 10 of the 12 chromosomes in the genome. Dormancy, as measured by days-to-sprouting after harvest, ranged from 10 to 90 days, with a mean of 19 days. QTLs were mapped by conducting one-way analyses of variance for each marker locus by dormancy combination. Twenty-two markers had a significant association with dormancy, identifying six putative QTLs localized on each of chromosomes 2, 3, 4, 5, 7 and 8. The QTL with the strongest effect on dormancy was detected on chromosome 7. A multilocus model was developed using the locus with highest R² value in each QTL. This model explained 57.5% of the phenotypic variation for dormancy. Seven percent of possible epistatic interactions among significant markers were significant when tested through two-way analyses of variance. When these were included in the main-effects model, it explained 72.1% of the phenotypic variation for dormancy. QTL analysis in potato, the methodology to transfer traits and interactions into the 4x level, and QTLs of value for marker-assisted selection, are discussed.     

Mapping a new nematode resistance locus in Lycopersicon peruvianum

Accessions of the wild tomato species L. peruvianum were screened with a root-knot nematode population (557R) which infects tomato plants carrying the nematode resistance gene Mi. Several accessions were found to carry resistance to 557R. A L. peruvianum backcross population segregating for resistance to 557R was produced. The segregation ratio of resistant to susceptible plants suggested that a single, dominant gene was a major factor in the new resistance. This gene, which we have designated Mi-3, confers resistance against nematode strains that can infect plants carrying Mi. Mi-3, or a closely linked gene, also confers resistance to nematodes at 32°C, a temperature at which Mi is not effective. Bulked-segregant analysis with resistant and susceptible DNA pools was employed to identify RAPD markers linked to this gene. Five-hundred-and-twenty oligonucleotide primers were screened and two markers linked to the new resistance gene were identified. One of the linked markers (NR14) was mapped to chromosome 12 of tomato in an L. esculentum/L. pennellii mapping population. Linkage of NR14 and Mi-3 with RFLP markers known to map on the short arm of chromosome 12 was confirmed by Southern analysis in the population segregating for Mi-3. We have positioned Mi-3 near RFLP marker TG180 which maps to the telomeric region of the short arm of chromosome 12 in tomato.     

Allelic variation in genes contributing to glycoalkaloid biosynthesis in a diploid interspecific population of potato

Key message

Variation for allelic state within genes of both primary and secondary metabolism influences the quantity and quality of steroidal glycoalkaloids produced in potato leaves.

Abstract

Genetic factors associated with the biosynthesis and accumulation of steroidal glycoalkaloids (SGAs) in potato were addressed by a candidate gene approach and whole genome single nucleotide polymorphism (SNP) genotyping. Allelic sequences spanning coding regions of four candidate genes [3-hydroxy-3-methylglutaryl coenzyme A reductase 2 (HMG2); 2,3-squalene epoxidase; solanidine galactosyltransferase; and solanidine glucosyltransferase (SGT2)] were obtained from two potato species differing in SGA composition: Solanum chacoense (chc 80-1) and Solanum tuberosum group Phureja (phu DH). An F₂ population was genotyped and foliar SGAs quantified. The concentrations of α-solanine, α-chaconine, leptine I, leptine II and total SGAs varied broadly among F₂ individuals. F₂ plants with chc 80-1 alleles for HMG2 or SGT2 accumulated significantly greater leptines and total SGAs compared to plants with phu DH alleles. Plants with chc 80-1 alleles at both loci expressed the greatest levels of total SGAs, α-solanine and α-chaconine. A significant positive correlation was found between α-solanine and α-chaconine accumulation as well as between leptine I and leptine II. A whole genome SNP genotyping analysis of an F₂ subsample verified the importance of chc 80-1 alleles at HMG2 and SGT2 for SGA synthesis and accumulation and suggested additional candidate genes including some previously associated with SGA production. Loci on five and seven potato pseudochromosomes were associated with synthesis and accumulation of SGAs, respectively. Two loci, on pseudochromosomes 1 and 6, explained phenotypic segregation of α-solanine and α-chaconine synthesis. Knowledge of the genetic factors influencing SGA production in potato may assist breeding for pest resistance.     

Protoplast-fusion-derived Solanum cybrids: application and phylogenetic limitations

Summary We established interspecific Solanum cybrids in order to study the intrageneric nuclear-organelle compatibility and the introgression of advantageous plasmone-coded breeding traits into potato. Cybridization was performed by the donor-recipient protoplast-fusion procedure. We found that the plastomes of S. chacoense, S. brevidens, and S. etuberosum could be transferred into the cybrids having S. tuberosum nuclear genomes; chondriome components were likewise transferred from the former species into these cybrids. The combination with S. chacoense as organelle donor and potato as recipient resulted in green fertile plants with potato morphology. By using S. etuberosum as an organelle donor and potato as recipient, male-sterile cybrid plants, most of them having pigmentation abnormalities, were obtained. The combination of S. brevidens with potato resulted in palegreen (almost albino) regenerants. The latter albino plantlets had both the chloroplast DNA and the mitochondrial DNA of the donor (S. brevidens) and did not survive the transfer into the greenhouse. An immediately applicative result of this study is the de novo establishment of male-sterile plants in a potato cultivar. Such plants should be useful as seed parents in the production of hybrid, true-potato seeds.     

Isoenzymatic identification of quantitative traits in crosses between heterozygous parents: mapping tuber traits in diploid potato (Solanum spp.)

Eleven isozyme markers were utilized for quantitative trait loci (QTL) analysis in diploid potato. These markers are distributed among 7 of the 12 chromosomes and therefore give a representative, though sparse, survey of the potato genome. Tuber specific gravity and tuder dormancy were studied. Two segregating diploid populations were constructed from heterozygous self-incompatible parents. These two populations, TRP132 (127 individuals) and TRP133 (110 individuals), have a common maternal parent and combine genomes of Solanum tuberosum (haploid), S. chacoense, and S. phureja. The populations were planted at two locations in Michigan in 1990 using a randomized complete block design with three replications per location. After harvest they were characterized with the isozymes and evaluated for specific gravity and tuber dormancy. To test for QTLs, one-way analyses of variance were conducted for each locus by trait combination. Significant associations between markers and quantitative trait variation were identified, which accounted for a range from 4% to 15% of the phenotypic variation for specific gravity, and from 4.5% to 20.4% for tuber dormancy. Two-way analyses of variance between significant markers were used to identify epistatic interactions between markers. Multiple regression analyses were used to estimate the overall effect of the significant markers on the phenotypic variation for these traits. These values ranged from 15.3% and 32.3% for specific gravity. For dormancy, the significant loci accounted for 8.5% and 36.9% of the total phenotypic variation for each of the populations. We find that isozyme analysis is a useful tool for preliminary QTL studies in potato.     

Potato chromosomes IX and XI carry genes for resistance to potato virus M

Two new loci for resistance to potato virus M (PVM), Gm and Rm, have been mapped in potato. The gene Gm was derived from Solanum gourlayi, whereas, Solanum megistacrolobum is the source of the gene Rm. Gm confers resistance to PVM infection after mechanical inoculation. Rm induces a hypersensitive response in potato plants. Two diploid populations segregating for Gm and Rm, bulked segregant analysis (BSA) using random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR), and available potato molecular maps were instrumental for mapping the resistance loci. The novel locus Gm was mapped to a central region on potato chromosome IX. The locus Rm was placed on the short arm of chromosome XI, close to the marker loci GP250 and GP283, where a hotspot for monogenic and polygenic resistance to diverse pathogens is located in the potato and tomato genome.     

Characterization and high-resolution mapping of a late blight resistance locus similar to R2 in potato

Identification of resistance (R) genes to Phytophthora infestans is an essential step in molecular breeding of potato. We identified three specific R genes segregating in a diploid mapping population. One of the R genes is located on chromosome 4 and proved phenotypically indistinguishable from the Solanum demissum-derived R2, although S. demissum is not directly involved in the pedigree of the population. By bulked segregant analysis combined with a resistance assay, a genetic linkage map of the R2-like locus was constructed with 30 coupling and 23 repulsion phase AFLP markers. Two markers flanking the R2-like locus were applied to screen an extended population of 1,586 offspring. About 103 recombinants were selected, and an accurate high-resolution map was constructed. The R2-like resistance was localized in a 0.4 cM interval and was found co-segregating with four AFLP markers, which can be used to isolate the R2-like gene by map-based gene cloning. By analyzing race-specificity and R gene-specific molecular markers, we also found that an R1-like gene and an additional unknown R gene are segregating in the population.     

Development of a molecular marker associated with Verticillium wilt resistance in diploid interspecific potato hybrids

Verticillium wilt (VW) is a widespread and serious potato (Solanum tuberosum) disease caused by the soilborne fungi Verticillium dahliae and V. albo-atrum. Breeding for VW resistance in potato is challenging due to ambiguous symptom expression, a lack of high throughput screening techniques, and variability in colonization by the fungus among and within plants. Genetic studies have identified major genes that confer resistance in diploid Solanum chacoense (V _c ) and interspecific hybrids (V _w and V _t ). However, to date, these genes have not been used to develop molecular markers for the identification of resistant clones. Tomato Ve1 and Ve2 gene sequence information was used to amplify candidate Ve gene orthologs from both resistant and susceptible diploid potato hybrids. A CAPS marker was generated to track VW resistance in a backcross population segregating for resistance. The marker was also tested for its usefulness in other breeding lines. Our results indicate that this marker is effective for selection of the V _w gene in segregating breeding populations.     

A high-resolution map of the H1 locus harbouring resistance to the potato cyst nematode Globodera rostochiensis

The resistance gene H1 confers resistance to the potato cyst nematode Globodera rostochiensis and is located at the distal end of the long arm of chromosome V of potato. For marker enrichment of the H1 locus, a bulked segregant analysis (BSA) was carried out using 704 AFLP primer combinations. A second source of markers tightly linked to H1 is the ultra-high-density (UHD) genetic map of the potato cross SH × RH. This map has been produced with 387 AFLP primer combinations and consists of 10,365 AFLP markers in 1,118 bins (). Comparing these two methods revealed that BSA resulted in one marker/cM and the UHD map in four markers/cM in the H1 interval. Subsequently, a high-resolution genetic map of the H1 locus has been developed using a segregating F₁ SH × RH population consisting of 1,209 genotypes. Two PCR-based markers were designed at either side of the H1 gene to screen the 1,209 genotypes for recombination events. In the high-resolution genetic map, two of the four co-segregating AFLP markers could be separated from the H1 gene. Marker EM1 is located at a distance of 0.2 cM, and marker EM14 is located at a distance of 0.8 cM. The other two co-segregating markers CM1 (in coupling) and EM15 (in repulsion) could not be separated from the H1 gene.Communicated by J.G. Wenzel     

Physical mapping of RFLP markers on four chromosome arms in maize using terminal deficiencies

Terminal deficiencies (TDs) generated by the r-XI deletion system in maize were used to physically map RFLP markers on the short arm of chromosome 2 (2S) and the long arm of chromosome 6 (6L), chromosome 8 (8L), and chromosome 10 (10L). Five TDs on 2S, 8 on 6L, 10 on 8L, and 20 on 10L were isolated using the recessive morphological markers lg1, py1, j1(gl18), and sr2, respectively, for selection. Two exceptional TDs on 2S and 8L also have a second breakpoint on the long arm of chromosome 2 (2L) and 8L, respectively. The physical mapping of RFLP probes in relation to TD breakpoints was done by Southern hybridization. The five TDs on 2S divide chromosome 2 into four regions, all of which are distinguishable by RFLP markers. Likewise, three remaining chromosome arms are divided by TDs into RFLP-marked regions: 8 TDs divide 6L into five regions, 10 TDs divided 8L into seven regions, and 20 TDs divide 10L into three regions. The linear order of the physical map of 6L and 8L is consistent with that of the genetic maps, but that of 2L and 10L is not. Four groups of markers on 2S as well as 2L, and two on 10L are in reverse order in the physical map compared with the genetic maps. Other intriguing results are that breakpoints of TDs on 6L and 8L are distributed throughout the selected region, but most of those on 2L and 10L cluster in a region near the centromere; a single TD arose after fertilization. Received: 17 March 1997 / Accepted: 26 June 1997     

A Primary Genetic Linkage Map of 14 Polymorphic Loci for the Short Arm of Human Chromosome 8

A genetic linkage map of markers for the short arm of human chromosome 8 has been constructed with 14 polymorphic DNA markers on the basis of genotypes obtained in 40 CEPH reference families. This unbroken map spans 45 cM in males and 79 cM in females. The 14 markers include three genes, MSR, LPL, and NEFL, and one anonymous DNA segment that were previously assigned to chromosome 8. The other 10 marker had been isolated from a chromosome 8-specific cosmid library and physically localized to chromosomal bands by fluorescence in situ hybridization. The order of loci determined by genetic linkage was consistent with their physical locations. This map will facilitate efficient linkage studies of human genetic diseases that may be segregating on chromosome 8p and will provide anchor points for development of high-resolution maps for this chromosomal region.     

Multiple alleles for resistance and susceptibility modulate the defense response in the interaction of tetraploid potato (<Emphasis Type="Italic">Solanum tuberosum</Emphasis>) with <Emphasis Type="Italic">Synchytrium endobioticum</Emphasis> pathotypes 1, 2, 6 and 18

The obligate biotrophic, soil-borne fungus Synchytrium endobioticum causes wart disease of potato (Solanum tuberosum), which is a serious problem for crop production in countries with moderate climates. S. endobioticum induces hypertrophic cell divisions in plant host tissues leading to the formation of tumor-like structures. Potato wart is a quarantine disease and chemical control is not possible. From 38 S. endobioticum pathotypes occurring in Europe, pathotypes 1, 2, 6 and 18 are the most relevant. Genetic resistance to wart is available but only few current potato varieties are resistant to all four pathotypes. The phenotypic evaluation of wart resistance is laborious, time-consuming and sometimes ambiguous, which makes breeding for resistance difficult. Molecular markers diagnostic for genes for resistance to S. endobioticum pathotypes 1, 2, 6 and 18 would greatly facilitate the selection of new, resistant cultivars. Two tetraploid half-sib families (266 individuals) segregating for resistance to S. endobioticum pathotypes 1, 2, 6 and 18 were produced by crossing a resistant genotype with two different susceptible ones. The families were scored for five different wart resistance phenotypes. The distribution of mean resistance scores was quantitative in both families. Resistance to pathotypes 2, 6 and 18 was correlated and independent from resistance to pathotype 1. DNA pools were constructed from the most resistant and most susceptible individuals and screened with genome wide simple sequence repeat (SSR), inverted simple sequence region (ISSR) and randomly amplified polymorphic DNA (RAPD) markers. Bulked segregant analysis identified three SSR markers that were linked to wart resistance loci (Sen). Sen1-XI on chromosome XI conferred partial resistance to pathotype 1, Sen18-IX on chromosome IX to pathotype 18 and Sen2/6/18-I on chromosome I to pathotypes 2,6 and 18. Additional genotyping with 191 single nucleotide polymorphism (SNP) markers confirmed the localization of the Sen loci. Thirty-three SNP markers linked to the Sen loci permitted the dissection of Sen alleles that increased or decreased resistance to wart. The alleles were inherited from both the resistant and susceptible parents.     

Microsatellite mapping of the induced sphaerococcoid mutation genes in Triticum aestivum

The S1, S2 and S3 genes of the induced sphaerococcoid mutation in common wheat (Triticum aestivum) were mapped using three different F₂ populations consisting of 71–96 individual plants. Twenty-four microsatellite markers from homeologous group 3 of T. aestivum were used to map the S1, S2 and S3 genes on chromosomes 3D, 3B and 3A, respectively. The S1 locus was found to be closely linked to the centromeric marker Xgwm456 of the long arm (2.9 cM) and mapped not far (8.0 cM) from the Xgdm72 marker of the short arm of chromosome 3D. The S2 gene was tightly linked to 2 centromeric markers (Xgwm566, Xgwm845) of chromosome 3B. S3 was located between Xgwm2 (5.1 cM), the marker of the short arm, and Xgwm720 (6.6 cM), the marker of the long arm, both of chromosome 3A. Mapping the S1, S2 and S3 loci of the induced sphaerococcoid mutation near the centromeric regions supports the hypothesis that the sphaerococcum type may be due to gene duplication resulting from DNA recombination in the centromeric region. Received: 20 June 1999 / Accepted: 29 July 1999     

Molecular cytogenetic characterization of alien introgressions with gene Fhb3 for resistance to Fusarium head blight disease of wheat

Fusarium head blight (FHB) resistance was identified in the alien species Leymus racemosus, and wheat-Leymus introgression lines with FHB resistance were reported previously. Detailed molecular cytogenetic analysis of alien introgressions T01, T09, and T14 and the mapping of Fhb3, a new gene for FHB resistance, are reported here. The introgression line T09 had an unknown wheat-Leymus translocation chromosome. A total of 36 RFLP markers selected from the seven homoeologous groups of wheat were used to characterize T09 and determine the homoeologous relationship of the introgressed Leymus chromosome with wheat. Only short arm markers for group 7 detected Leymus-specific fragments in T09, whereas 7AS-specific RFLP fragments were missing. C-banding and genomic in situ hybridization results indicated that T09 has a compensating Robertsonian translocation T7AL·7Lr#1S involving the long arm of wheat chromosome 7A and the short arm of Leymus chromosome 7Lr#1 substituting for chromosome arm 7AS of wheat. Introgression lines T01 (2n = 44) and T14 (2n = 44) each had two pairs of independent translocation chromosomes. T01 had T4BS·4BL-7Lr#1S + T4BL-7Lr#1S·5Lr#1S. T14 had T6BS·6BL-7Lr#1S + T6BL·5Lr#1S. These translocations were recovered in the progeny of the irradiated line Lr#1 (T5Lr#1S·7Lr#1S). The three translocation lines, T01, T09, and T14, and the disomic addition 7Lr#1 were consistently resistant to FHB in greenhouse point-inoculation experiments, whereas the disomic addition 5Lr#1 was susceptible. The data indicated that at least one novel FHB resistance gene from Leymus, designated Fhb3, resides in the distal region of the short arm of chromosome 7Lr#1, because the resistant translocation lines share a common distal segment of 7Lr#1S. Three PCR-based markers, BE586744-STS, BE404728-STS, and BE586111-STS, specific for 7Lr#1S were developed to expedite marker-assisted selection in breeding programs.     

NBS-LRR sequence family is associated with leaf and stripe rust resistance on the end of homoeologous chromosome group 1S of wheat

A detailed RFLP map was constructed of the distal end of the short arm of chromosome 1D of Aegilops tauschii and wheat. At least two unrelated resistance-gene analogs (RGAs) mapped close to known leaf rust resistance genes (Lr21 and Lr40) located distal to seed storage protein genes on chromosome 1DS. One of the two RGA clones, which was previously shown to be part of a candidate gene for stripe rust resistance (Yr10) located within the homoeologous region on 1BS, identified at least three gene family members on chromosome 1DS of Ae. tauschii. One of the gene members co-segregated with the leaf rust resistance genes, Lr21 and Lr40, in Ae. tauschii and wheat segregating families. Hence, a RGA clone derived from a candidate gene for stripe rust resistance located on chromosome 1BS detected candidate genes for leaf rust resistance located in the corresponding region on 1DS of wheat. Received: 10 January 2000 / Accepted: 25 March 2000