Utility of RAPD markers in identifying genetic linkages to genes of economic interest in peach

The identification of molecular markers linked to economically important traits for use in crop improvement is very important in long-lived perennial species. Three-hundred-and-sixty RAPD primers were used with bulked segregant analysis to identify markers linked to loci of specific interest in peach [(Prunus persica) L. Batch] and peach x almond [(Prunus dulcis) Batch] crosses. The traits analyzed included flesh color, adhesion, and texture; pollen fertility; plant stature; and three isozyme loci. The Mendelian behavior of the RAPD loci was established, and RAPD markers were mapped relative to the loci controlling flesh color, adhesion, and texture, and the isozyme loci Mdh-1, 6Pgd-2 and Aat-1, as well as the existing RFLP genetic linkage map constructed previously using a peach x almond F₂ population. This technique has facilitated rapid identification of RAPD and RFLP markers that are linked to the traits under study. Loci controlling these traits mapped predominantly to linkage groups 2 and 3 of the peach genetic linkage map. Linkages to genes with both dominant and co-dominant alleles were identified, but linkages to dominant genes were more difficult to find. In several crosses, RAPD marker bands proved to be allelic. One co-dominant RAPD formed a heteroduplex band in heterozygous individuals and in mixtures of alternate homozygotes. The Mendelian behavior of the RAPD loci studied was established and the results suggest that RAPD markers will be useful for plant improvement in peach.     

Genetical dissection of H3-mediated polygenic PCN resistance in a heterozygous autotetraploid potato population

Potato Cyst Nematodes (PCN) currently represent a serious threat to potato cultivation. However, many sources of resistance are known amongst primitive and wild relatives of cultivated potato, Solanum tuberosum ssp. tuberosum. Currently, in the UK, the major threat is due to Globodera pallida, resistance to which has not yet been effectively deployed in potato cultivars. We have performed linkage and QTL analysis of a tetraploid potato population segregating for the H3 source of resistance to G. pallida that was introgressed into cultivated potato from the primitive species, Solanum tuberosum ssp. andigena. This source is highly effective against the most common UK pathotype of G. pallida (Pa2/3) and its deployment in breeding material is a major goal. We adopted an approach involving bulked segregant analysis (BSA) as well as genome wide linkage analysis using AFLP and SSR markers. BSA provided a concentration of markers linked in coupling to a QTL on linkage group IV, and improved the accuracy of the QTL localisation. By performing an analysis on residual scores after removal of the effects due to the major QTL, we detected a second QTL on linkage group XI.     

Linkage analysis of er-1, a recessive Pisum sativum gene for resistance to powdery mildew fungus (Erysiphe pisi D.C.)

Linkage analysis was used to determine the genetic map location of er-1, a recessive gene conditioning resistance to powdery mildew, on the Pisum sativum genome. Genetic linkage was demonstrated between er-1 and linkage group 6 markers after analyzing the progeny of two crosses, an F₂ population and a set of recombinant inbred lines. The classes of genetic markers surrounding er-1 include RFLP, RAPD and allozyme markers as well as the morphological marker Gty. A RAPD marker tightly linked to er-1 was identified by bulked segregant analysis. After DNA sequence characterization, specific PCR primers were designed to convert this RAPD marker into a sequence characterized amplified region (SCAR).     

Identification of a RAPD marker linked to the pendula gene in Norway spruce (Picea abies (L.) Karst. f. pendula)

The pendula phenotype of Norway spruce [Picea abies (L.) Karst f. pendula] is characterized by narrow crowns and strong apical dominance and is controlled by a single dominant gene (P). This defined genetic control presents one of the few opportunities to map a single gene controlling a morphological trait in a forest tree. We used random amplified polymorphic DNA (RAPD) markers and bulked segregant analysis to identify one locus OPH10_720, linked to the pendula gene. The estimated recombination frequency (r) between OPH10_720 and P was 0.046 (SE _r =0.032). Mapping of the pendula gene is an important first step towards the ultimate identification and cloning of this gene.     

Identification of random amplified polymorphic DNA (RAPD) markers for self-incompatibility alleles in Corylus avellana L.

 Random amplified polymorphic DNA (RAPD) markers were identified for self-incompatibility (SI) alleles that will allow marker-assisted selection of desired S-alleles in hazelnut (Corylus avellana L.). DNA was extracted from young leaves collected from field-planted parents and 26 progeny of the cross OSU 23.017 (S₁S₁₂)×VR6-28 (S₂S₂₆) (OSU23×VR6). Screening of 10-base oligonucleotide RAPD primers was performed using bulked segregant analysis. DNA samples from 6 trees each were pooled into four ‘bulks’, one for each of the following: S₁ S₂, S₁ S₂₆ ^, S₂ S₁₂, and S₁₂ S₂₆. ‘Super bulks’ of 12 trees each for S₁, S₂, S₁₂, and S₂₆ were then created for each allele by combining the appropriate bulks. The DNA from these four super bulks and from the parents was used as a template in the PCR assays. A total of 250 primers were screened, and one RAPD marker each was identified for alleles S₂ (OPI07₇₅₀) and S₁ (OPJ14₁₇₀₀). OPJ14₁₇₀₀ was identified in 13 of 14 S₁ individuals of the cross OSU23×VR6 used in bulking and yielded a false positive in 1 non-S₁ individual. This same marker was not effective outside the original cross, identifying 4 of 5 S₁ progeny in another cross, ‘Willamette’×VR6-28 (‘Will’×VR6), but yielded false positives in 4 of 9 non-S₁ individuals from the cross ‘Casina’×VR6-28 (‘Cas’×VR6). OPI07₇₅₀ served as an excellent marker for the S₂ allele and was linked closely to this allele, identifying 12 of 13 S₂ individuals in the OSU23×VR6 population with no false positives. OPI07₇₅₀ was found in 4 of 4 S₂ individuals from ‘Will’×VR and 7 of 7 S₂ individuals of ‘Cas’×VR6 with no false positives, as well as 10 of 10 S₂ individuals of the cross OSU 296.082 (S₁S₈)×VR8-32 (S₂S₂₆), with only 1 false positive individual out of 21 progeny. OPI07₇₅₀ was also present in 5 of 5 cultivars carrying the S₂ allele, with no false-positive bands in non-S₂ cultivars, and correctly identified all but 2 S₂ individuals in 57 additional selections in the breeding program. In the OSU23×VR6 population, the recombination rate between the marker OPJ14₁₇₀₀ and the S₁ allele was 7.6% and between the OPI07₇₅₀ marker and the S₂ allele was 3.8%. RAPD marker bands were excised from gels, cloned, and sequenced to enable the production of longer primers (18 or 24 bp) that were used to obtain sequence characterized amplified regions (SCARs). Both the S₁ and S₂ markers were successfully cloned and 18 bp primers yielded the sole OPJ14₁₇₀₀ product, while 24-bp primers yielded OPI07₇₅₀ as well as an additional smaller product (700 bp) that was not polymorphic but was present in all of the S-genotypes examined. Received: 10 January 1998 / Accepted: 26 January 1998     

Identification of AFLP fragments linked to hydroxysafflor yellow A in Flos Carthami and conversion to a SCAR marker for rapid selection

Hydroxysafflor yellow A (HSYA), an important active compound in treating focal cardiac and cerebral ischemia, is uniquely present in flower petals of Carthamus tinctorius. In this study, inheritance and molecular marker analyses for HSYA trait in safflower were carried out. HSYA contents in parents, cross hybridized F₁ and F₂ individuals were analyzed by high performance liquid chromatography. Results revealed that the presence/absence of HSYA was controlled by one major nuclear gene termed HSya. A total of 48 AFLP primer combinations were screened, and bulked segregant analysis was performed by preparing two pools of 10 present-HSYA and ten absent-HSYA plants selected from the 498 individuals of the F₂ segregating population. Four AFLP markers, AFLP-5, AFLP-7, AFLP-15 and AFLP-16, were identified to be closely associated with HSya. Of those, AFLP-16 was the closest to HSya, estimated at about 9.4 cM in genetic distance. The dominant AFLP-16 marker was converted into a simple sequence characterized amplified region marker based on the sequence information of the cloned flanking regions of the AFLP fragment and was designated as SCM16. Our result has direct application for marker-assisted selection of quality breeding in safflower.     

Identification of AFLP fragments linked to seed coat colour in Brassica juncea and conversion to a SCAR marker for rapid selection

A Brassica juncea mapping population was generated and scored for seed coat colour. A combination of bulked segregant analysis and AFLP methodology was employed to identify markers linked to seed coat colour in B. juncea. AFLP analysis using 16 primer combinations revealed seven AFLP markers polymorphic between the parents and the bulks. Individual plants from the segregating population were analysed, and three AFLP markers were identified as being tightly linked to the seed coat colour trait and specific for brown-seeded individuals. Since AFLP markers are not adapted for large-scale application in plant breeding, our objective was to develop a fast, cheap and reliable PCR-based assay. Towards this goal, we employed PCR-walking technology to isolate sequences adjacent to the linked AFLP marker. Based on the sequence information of the cloned flanking sequence of marker AFLP8, primers were designed. Amplification using the locus-specific primers generated bands at 0.5 kb and 1.2 kb with the yellow-seeded parent and a 1.1-kb band with the brown-seeded parent. Thus, the dominant AFLP marker (AFLP8) was converted into a simple codominant SCAR (Sequence Characterized Amplified Region) marker and designated as SCM08. Scoring of this marker in a segregating population easily distinguished yellow- and brown-seeded B. juncea and also differentiated between homozygous (BB) and heterozygous (Bb) brown-seeded individuals. Thus, this marker will be useful for the development of yellow seed B. juncea cultivars and facilitate the map-based cloning of genes responsible for seed coat colour trait. Received: 2 October 1999 / Accepted: 11 November 1999     

Identification and mapping on chromosome 9 of RAPD markers linked to Sw-5 in tomato by bulked segregant analysis

Bulked segregant analysis was used to identify random amplified polymorphic DNA (RAPD) markers linked to the Sw-5 gene for resistance to tomato spotted wilt virus (TSWV) in tomato. Using two pools of phenotyped individuals from one segregating population, we identified four RAPD markers linked to the gene of interest. Two of these appeared tightly linked to Sw-5, whereas another, linked in repulsion phase, enabled the identification of heterozygous and susceptible plants. After linkage analysis of an F₂ population, the RAPD markers were shown to be linked to Sw-5 within a distance of 10.5 cM. One of the RAPD markers close to Sw-5 was used to develop a SCAR (sequence characterized amplified region) marker. Another RAPD marker was stabilized into a pseudo-SCAR marker by enhancing the specificity of its primer sequence without cloning and sequencing. RAPD markers were mapped to chromosome 9 on the RFLP tomato map developed by Tanksley et al. (1992). The analysis of 13 F₃ families and eight BC₂ populations segregating for resistance to TSWV confirmed the linkage of the RAPD markers found. These markers are presently being used in marker-assisted plant breeding.     

Detection and cloning of expressed sequences linked to a target gene

DNA markers tightly linked to a target gene are essential starting points for positional cloning. We combined ”differential display of mRNA” and ”bulked segregant analysis” in order to detect and clone ten expressed sequences as markers linked to a virus resistance gene in Phaseolus vulgaris. The combination of these two procedures could be used in lieu of positional cloning, provided polymorphisms detectable by differential display exist in the target gene. Isolation of expressed sequences from specific chromosome regions can also be accomplished by combining these procedures. Received: 8 July 1999 / Accepted: 21 March 2000     

Saturation mapping of a major gene for resistance to white pine blister rust in sugar pine

 The molecular basis of resistance to diseases in plants can be better understood if the genes coding for resistance can be cloned. The single major dominant gene (R) that confers resistance to the white pine blister rust fungus (Cronartium ribicola Fisch.) in sugar pine (Pinus lambertiana Dougl.) has been previously mapped. The objectives of the present study were to saturate the region flanking R with tightly linked markers and to construct genetic maps for each of four individual seed trees. Bulked segregant analysis (BSA) and haploid segregation analysis were employed to identify random amplified polymorphic DNA (RAPD) markers linked to R. Automated PCR analysis was used to assay 1115 primers with susceptible and resistant DNA pools from each of four seed trees (8920 PCR reactions). Thirteen RAPD loci were identified that were linked to R. The linkage analyses programs JoinMap 1.4 and Mapmaker 2.0 were used to order RAPD loci relative to R and to construct maps for each of the individual seed trees. Two seed trees, 5701 and 6000, had a large number of tightly linked markers flanking R. These trees will be used in subsequent high-resolution mapping experiments to identify very tightly linked markers to facilitate the eventual cloning of R. Received: 1 May 1998 / Accepted: 13 July 1998     

Molecular mapping of a rice gene conditioning thermosensitive genic male sterility using AFLP, RFLP and SSR techniques

The discovery and application of the thermosensitive genic male sterility (TGMS) system has great potential for revolutionizing hybrid seed production technology in rice. Use of the TGMS system in two-line breeding is simple, inexpensive, efficient, and eliminates the limitations associated with the cytoplasmic-genetic male sterility (CMS) system. An F₂ population developed from a cross between a TGMS indica mutant, TGMS–VN1, and a fertile indica line, CH1, was used to identify molecular markers linked to the TGMS gene and to subsequently determine its chromosomal location on the linkage map of rice. Bulk segregant analysis was performed using the AFLP technique. From the survey of 200 AFLP primer combinations, four AFLP markers (E2/M5–600, E3/M16–400, E5/M12–600, and E5/M12–200) linked to the TGMS gene were identified. All the markers were linked to the gene in the coupling phase. All except E2/M5–200 were found to be low-copy sequences. However, the marker E5/M12–600 showed polymorphism in RFLP analysis and was closely linked to the TGMS gene at a distance of 3.3 cM. This marker was subsequently mapped on chromosome 2 using doubled-haploid mapping populations derived from the crosses IR64×Azucena and CT9993×IR62666, available at IRRI, Philippines, and Texas Tech University, respectively. Linkage of microsatellite marker RM27 with the TGMS gene further confirmed its location on chromosome 2. The closest marker, E5/M12–600, was sequenced so that a PCR marker can be developed for the marker-assisted transfer of this gene to different genetic backgrounds. The new TGMS gene is tentatively designated as tms4(t). Received: 13 July 1999 / Accepted: 27 July 1999     

Efficient fine mapping of the naked caryopsis gene (<Emphasis Type="Italic">nud</Emphasis>) by HEGS (High Efficiency Genome Scanning)/AFLP in barley

The hulled or naked caryopsis character of barley (Hordeum vulgare L.) is an important trait for edibility and to follow its domestication process. A single recessive gene, nud, controls the naked caryopsis character, and is located on the long arm of chromosome 7H. To develop a fine map around the nud locus efficiently, the HEGS (High Efficiency Genome Scanning) electrophoresis system was combined with amplified fragment length polymorphism (AFLP). From bulked segregant analysis of 1,894 primer combinations, 12 AFLP fragments were selected as linked markers. For mapping, an F₂ population of 151 individuals derived from a cross between Kobinkatagi (naked type) and Triumph (hulled type) was used. Seven AFLP markers were localized near the nud region. A fine map was developed with one-order higher resolution than before, along with the seven anchor markers. Among the seven linked AFLP markers (KT1–7), KT1, KT2 and KT6 were co-dominant, and the former two were detected for their single-nucleotide polymorphisms (SNPs) in the same length of fragments after electrophoresis with the non-denaturing gels of HEGS. The nud locus has co-segregated with KT3 and KT7, and was flanked by KT2 and KT4, at the 0.3-cM proximal and the 1.2-cM distal side, respectively. Four of these AFLP markers were converted into sequence-characterized amplified region (SCAR) markers, one of which was a dominant marker co-segregating with the nud gene.Communicated by G. Wenzel     

RAPD markers linked to a gene for resistance to pine needle gall midge in Japanese black pine (Pinus thunbergii)

Linkage of RAPD markers to a single dominant gene for resistance to pine needle gall midge was investigated in Japanese black pine (Pinus thunbergii). Three primers that generated linked markers were found after 1160 primers were screened by bulked segregant analysis. The distances between the resistance gene, R, and the marker genes OPC06580, OPD01700, and OPAX192100 were 5.1 cM, 6.7 cM and 13.6 cM, respectively. OPC06580 was in coupling phase to R, whereas OPD01700 and OPAX192100 were in repulsion phase to R. A linkage map for a resistant tree was constructed using 96 macrogametophytes. In linkage analysis, 98 out of 127 polymorphic markers were assigned to 17 linkage groups and six linked pairs. The total length of this map was 1469.8 cM, with an average marker density of 15.6 cM. The genome length was estimated to be 2138.3 cM, and the derived linkage map covered 67.5% of the genome. Although the linked markers OPC06580, OPAX192100, and OPD01700, belonged to the same linkage group, no precise positions were found for OPC06580 or OPD01700. Received: 15 May 1999 / Accepted: 29 July 1999     

The potential of ISSR-PCR primer-pair combinations for genetic linkage analysis using the seasonal flowering locus in Fragaria as a model

ISSR-PCR has been widely used for genetic distance analysis and DNA fingerprinting but has been less well utilised for mapping purposes. A key limitation lies in the small number of primer designs available to generate useful polymorphisms. In this study, the potential of paired combinations of ISSR primers is evaluated using a test cross mapping population of 168 BC₁ individuals between Fragaria vesca f. vesca and a closely related line F. vesca f. semperflorens. Ten ISSR primers and all possible pairwise combinations between them were used to generate markers potentially linked to the locus controlling seasonal flowering in F. vesca. Band profiles of individual primers were found to be highly reproducible for band position and intensity, and only minor variation was noted in band intensity (but not in position) between different constituent mixes of primer-pair combinations. Overall, ISSR primers used in isolation produced 85 markers of which only five were specific to F. vesca. None of these markers were linked to the seasonal flowering locus. In contrast, the primer-pair combina-tions yielded 493 markers, including 14 specific to F. vesca. These markers included two located within 2.2 cM of the seasonality locus. The strengths and limitations of using pairs of ISSR primers in combination for mapping and other genetic analyses are briefly explored. Received: 12 October 2000 / Accepted: 19 January 2001     

Rapid identification of lettuce seed germination mutants by bulked segregant analysis and whole genome sequencing

Lettuce (Lactuca sativa) seeds exhibit thermoinhibition, or failure to complete germination when imbibed at warm temperatures. Chemical mutagenesis was employed to develop lettuce lines that exhibit germination thermotolerance. Two independent thermotolerant lettuce seed mutant lines, TG01 and TG10, were generated through ethyl methanesulfonate mutagenesis. Genetic and physiological analyses indicated that these two mutations were allelic and recessive. To identify the causal gene(s), we applied bulked segregant analysis by whole genome sequencing. For each mutant, bulked DNA samples of segregating thermotolerant (mutant) seeds were sequenced and analyzed for homozygous single‐nucleotide polymorphisms. Two independent candidate mutations were identified at different physical positions in the zeaxanthin epoxidase gene (ABSCISIC ACID DEFICIENT 1/ZEAXANTHIN EPOXIDASE, or ABA1/ZEP) in TG01 and TG10. The mutation in TG01 caused an amino acid replacement, whereas the mutation in TG10 resulted in alternative mRNA splicing. Endogenous abscisic acid contents were reduced in both mutants, and expression of the ABA1 gene from wild‐type lettuce under its own promoter fully complemented the TG01 mutant. Conventional genetic mapping confirmed that the causal mutations were located near the ZEP/ABA1 gene, but the bulked segregant whole genome sequencing approach more efficiently identified the specific gene responsible for the phenotype.     

Targeted mapping and linkage analysis of morphological isozyme,and RAPD markers in peach

Nine different F2 families of peach [Prunus persica (L.) Batsch] were analyzed for linkage relationships between 14 morphological and two isozyme loci. Linkage was detected between weeping (We) and white flower (W), 33 cM; double flower (Dl) and pillar (Br), 10 cM; and flesh color (Y) and malate dehydrogenase (Mdh1), 26 cM. A leaf variant phenotypically distinct from the previously reported wavy-leaf (Wa) mutant in peach was found in progeny of Davie II. The new willow-leaf character (designated Wa2) was closely linked (0.4 cM) to a new dwarf phenotype (designated Dw3). Two families derived from the pollen-fertile cultivar White Glory segregated for pollen sterility, but segregation did not follow a 31 ratio. Evidence is presented suggesting that White Glory possesses a pollen-sterility gene (designated Ps2) that is non-allelic to the previously reported pollen-sterility gene (Ps) in peach. Ps2 was linked to both weeping (We-Ps2, 15.5 cM) and white flower (Ps2-W, 25.3 cM). A genomic map of peach containing 83 RAPD, one isozyme, and four morphological markers was generated using an F2 family obtained by selfing an NC174RL x Pillar F1. A total of 83 RAPD markers were assigned to 15 linkage groups. Various RAPD markers were linked to morphological traits. Bulked segregant analysis was used to identify RAPD markers flanking the red-leaf (Gr) and Mdh1 loci in the NC174RL x Pillar and Marsun x White Glory F2 families, respectively. Three markers flanking Mdh1 and ten markers flanking Gr were identified. The combination of RAPD markers and bulked segregant analysis provides an efficient method of identifying markers flanking traits of interest. Markers linked to traits that can only be scored late in development are potentially useful for marker-aided selection in trees. Alternatives for obtaining additional map order information for repulsion-phase markers in large F2 populations are proposed.This work was supported in part by the McKnight Foundation, North Carolina Biotechnology Center, North Carolina State University Forest Biotechnology Research Consortium, and the North Carolina Agricultural Research Service, Raleigh, North Carolina     

与苹果Co基因紧密连锁的RAPD标记的筛选及其SCAR标记转换

以短枝富士(Spur Fuji)X舞姿(Telamon)的105株F1群体为试材,利用RAPD技术,结合集群分类分析法(BSA)进行了苹果柱型基因(Co)分子标记的研究。通过对300条随机引物的筛选,获得一个与Co基因紧密连锁的RAPD标记S1142682,连锁距离为2．86cM。对该标记片段进行序列测定,然后根据序列特点设计了4条特异引物(其中正向引物与反向引物各两条)。PCR结果显示,这4条引物的4种组合都可以扩增出柱型性状的特征带。选其中之一进行群体上的分析,结果表明该SCAR标记特征带与柱型性状的共分离行为与原RAPD标记表现一致。可见,此组合的引物可以作为该SCAR标记的特异引物。通过对S1142682标记片段序列分析发现,在 45～ 251区域含有一个可编码68个氨基酸残基的ORF。