An improved technique for isolating codominant compound microsatellite markers

An approach for developing codominant polymorphic markers (compound microsatellite (SSR) markers), with substantial time and cost savings, is introduced in this paper. In this technique, fragments flanked by a compound SSR sequence at one end were amplified from the constructed DNA library using compound SSR primer (AC)₆(AG)₅ or (TC)₆(AC)₅ and an adaptor primer for the suppression-PCR. A locus-specific primer was designed from the sequence flanking the compound SSR. The primer pairs of the locus-specific and compound SSR primers were used as a compound SSR marker. Because only one locus-specific primer was needed for design of each marker and only a common compound SSR primer was needed as the fluorescence-labeled primer for analyzing all the compound SSR markers, this approach substantially reduced the cost of developing codominant markers and analyzing their polymorphism. We have demonstrated this technique for Dendropanax trifidus and easily developed 11 codominant markers with high polymorphism for D. trifidus. Use of the technique for successful isolation of codominant compound SSR markers for several other plant species is currently in progress.     

Major QTL for carrot color are positionally associated with carotenoid biosynthetic genes and interact epistatically in a domesticated × wild carrot cross

We performed QTL analyses for pigment content on a carotenoid biosynthesis function map based on progeny of a wild white carrot (QAL) which accumulates no pigments × domesticated orange carrot (B493), one of the richest sources of carotenoid pigments—mainly provitamin A α- and β- carotenes. Two major interacting loci, Y and Y ₂ on linkage groups 2 and 5, respectively, control much variation for carotenoid accumulation in carrot roots. They are associated with carotenoid biosynthetic genes zeaxanthin epoxidase and carotene hydroxylase and carotenoid dioxygenase gene family members as positional candidate genes. Dominant Y allele inhibits carotenoid accumulation. When Y is homozygous recessive, carotenoids that accumulate are either only xanthophylls in Y ₂ __ plants, or both carotenes and xanthophylls, in y ₂ y ₂ plants. These two genes played a major role in carrot domestication and account for the significant role that modern carrot plays in vitamin A nutrition.     

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     

Linkage relationships among molecular markers and storage root traits of carrot (Daucus carota L. ssp. sativus)

 A 109-point linkage map consisting of three phenotypic loci (P ₁, Y ₂, and Rs), six restriction fragment length polymorphisms (RFLPs), two random amplified polymorphic DNAs (RAPDs), 96 amplified fragment length polymorphisms (AFLPs), and two selective amplification of microsatellite polymorphic loci (SAMPL) was constructed for carrot (Daucus carota L. ssp. sativus; 2n=2x=18). The incidence of polymorphism was 36% for RFLP probes, 20% for RAPD primers, and 42% for AFLP primers. The overall incidence of disturbed segregation was 18%. Linkage relationships at a LOD score of 4.0 and θ=0.25 indicated 11 linkage groups. The total map length was 534.4 cM and the map was clearly unsaturated with markers spaced at 4.9 cM. AFLP P6B15 was 1.7 cM from P ₁, AFLP P1B34 was 2.2 cM from Y ₂, and AFLP P3B30XA was 8.1 cM from Rs. Received: 2 September 1998 / Accepted: 28 November 1998     

AFLP and PCR-based markers linked to Rf3, a fertility restorer gene for S cytoplasmic male sterility in maize

The Rf3 gene restores the pollen fertility disturbed by S male sterile cytoplasm. In order to develop molecular markers tightly linked to Rf3, we used amplified fragment length polymorphism (AFLP) technique with near isogenic lines (NILs) and bulk segregant analysis (BSA). A BC₁F₁ population from a pair of NILs with different Rf3 locus was constructed and 528 primer combinations was screened. A linkage map was constructed around the Rf3 locus, which was mapped on the distal region of chromosome 2 long arm with the help of SSR marker UMC2184. The closest marker E7P6 was 0.9 cM away from Rf3. Marker E3P1, 2.4 cM from Rf3, and E12M7, 1.8 cM from Rf3, were converted into a codominant CAPS and a dominant SCAR marker, and designated as CAPSE3P1 and SCARE12M7, respectively. These markers are useful for marker-assisted selection and map-based cloning of the Rf3 gene.     

Chromosome landing at the Mla locus in barley (Hordeum vulgare L.) by means of high-resolution mapping with AFLP markers

 The complex Mla locus of barley determines resistance to the powdery mildew pathogen Erysiphe graminis f. sp. hordei. With a view towards gene isolation, a population consisting of 950 F₂ individuals derived from a cross between the near-isogenic lines ‘P01’ (Mla1) and ‘P10’ (Mla12) was used to construct a high-resolution map of the Mla region. A fluorescence-based AFLP technique and bulked segregant analysis were applied to screen for polymorphic, tightly linked AFLP markers. Three AFLP markers were selected as suitable for a chromosome-landing strategy. One of these AFLP markers and a closely linked RFLP marker were converted into sequence-specific PCR markers. PCR-based screening of approximately 70 000 yeast artificial chromosome (YAC) clones revealed three identical YACs harbouring the Mla locus. Terminal insert sequences were obtained using inverse PCR. The derived STS marker from the right YAC end-clone was mapped distal to the Mla locus. Received: 17 July 1998 / Accepted: 9 August 1998     

Development and mapping of a codominant SCAR marker linked to the andromonoecious gene of melon

Monoecy is an important goal for melon breeding because of the agronomic advantages it provides to parental lines in that they do not require hand emasculation to develop monoecious F₁ hybrids, the latter producing fruits of higher quality. Monoecious phenotype is conferred by the dominant allele of the andromonoecious (a) gene, whereas recessive homozygous plants are andromonoecious. A bulked segregant analysis (BSA) approach performed in a set of 38 double-haploid lines has allowed us to identify an AFLP marker linked to the a gene at 3.3 cM. Following cloning and sequencing of the AFLP fragment, specific PCR primers were designed and used in the amplification of a codominant SCAR marker. Using a backcrossed mapping population of 530 plants, the SCAR marker could be mapped near the a locus (5.5 cM). Size difference between the two allelic SCAR fragments is 42 bp and might be due to a deletion/insertion. The SCAR marker is closest to the a gene identified to date, and can be useful in breeding programs, using marker-assisted selection procedures to screen for sexual types in melon.     

Amplified fragment length polymorphism (AFLP) in soybean: species diversity, inheritance, and near-isogenic line analysis

Amplified fragment length polymorphism (AFLP) analysis is a PCR-based technique capable of detecting more than 50 independent loci in a single PCR reaction. The objectives of the present study were to: (1) assess the extent of AFLP variation in cultivated (Gycine max L. Merr.) and wild soybean (G. soja Siebold & Zucc.), (2) determine genetic relationships among soybean accessions using AFLP data, and (3) evaluate the usefulness of AFLPs as genetic markers. Fifteen AFLP primer pairs detected a total of 759 AFLP fragments in a sample of 23 accessions of wild and cultivated soybean, with an average of 51 fragments produced per primer pair per accession. Two-hundred and seventy four fragments (36% of the total observed) were polymorphic, among which 127 (17%) were polymorphic in G. max and 237 (31%) were polymorphic in G. soja. F₂ segregation analysis of six AFLP fragments indicated that they segregate as stable Mendelian loci. The number of polymorphic loci detected per AFLP primer pair in a sample of 23 accessions ranged from 9 to 27. The AFLP phenotypic diversity values were greater in wild than in cultivated soybean. Cluster and principal component analyses using AFLP data clearly separated G. max and G. soja accessions. Within the G. max group, adapted soybean cultivars were tightly clustered, illustrating the relatively low genetic diversity present in cultivated soybean. AFLP analysis of four soybean near-isogenic lines (NILs) identified three AFLP markers putatively linked to a virus resistance gene from two sources. The capacity of AFLP analysis to detect thousands of independent genetic loci with minimal cost and time requirements makes them an ideal marker for a wide array of genetic investigations.     

Identification of AFLP markers in soybean linked to resistance to Meloidogyne javanica and conversion to Sequence Characterized Amplified Regions (SCARs)

Meloidogynejavanica is the most widely spread nematode pest on soybean in SouthAfrica. Only a few registered commercial South African cultivars are poor hostsof this nematode species and there is an urgent need for an efficient breedingprogramme for resistant cultivars of all maturity groups. However, breeding ishampered by laborious screening procedures for selection of poor host cultivarsand/or lines. The objective of this study was to develop an economically viablemolecular marker system for application in selection procedures. BothRestriction Fragment Length Polymorphism (RFLP) and Amplified Fragment LengthPolymorphism (AFLP) screening techniques identified markers linked togall-indexvariation in a segregating population of 60 F₂ progeny from a crossbetween a resistant cultivar (Gazelle) and a highly susceptible variety(Prima).A codominant RFLP marker( B212) was linked significantly to M.javanica resistance and explained 62% of the variation ingall-index.Seven AFLP markers were linked significantly to the resistance trait, of whichfour were linked in repulsion phase and three in coupling phase. All seven AFLPmarkers mapped to LG-F (Linkage Group F) on the public soybean molecular map.The major quantitative trait locus (QTL) for resistance mapped between markersE-ACC/M-CTC2(SOJA6) (linked in coupling phase), B212 and E-AAC/M-CAT1(SOJA7)(linked in repulsion phase). These two AFLP markers bracketing the majorresistance QTL were successfully converted to SCARs (Sequence CharacterizedAmplified Regions). Marker E-ACC/M-CTC2 was converted to a codominant SCARmarker SOJA6, which accounted for 41% of variation in gall-index in the mappingpopulation. Marker E-AAC/M-CAT1 was converted to a dominant SCAR marker (SOJA7)and explained 42% of gall-index variation in the mapping population. These twomarkers mapped approximately 3.8 cM and 2.4 cMrespectively from the resistance QTL. This study represents the first report ofthe development of PCR-based sequence specific markers linked to M.javanica resistance in soybean.     

Application of fluorescence-based semi-automated AFLP analysis in barley and wheat

Genetic mapping and the selection of closely linked molecular markers for important agronomic traits require efficient, large-scale genotyping methods. A semi-automated multifluorophore technique was applied for genotyping AFLP marker loci in barley and wheat. In comparison to conventional ³³P-based AFLP analysis the technique showed a higher resolution of amplicons, thus increasing the number of distinguishable fragments. Automated sizing of the same fragment in different lanes or different gels showed high conformity, allowing subsequent unambigous allele-typing. Simultaneous electrophoresis of different AFLP samples in one lane (multimixing), as well as simultaneous amplification of AFLP fragments with different primer combinations in one reaction (multiplexing), displayed consistent results with respect to fragment number, polymorphic peaks and correct size-calling. The accuracy of semi-automated co-dominant analysis for hemizygous AFLP markers in an F₂ population was too low, proposing the use of dominant allele-typing defaults. Nevertheless, the efficiency of genetic mapping, especially of complex plant genomes, will be accelerated by combining the presented genotyping procedures. Received: 10 April 1999 / Accepted: 11 May 1999     

A genetic linkage map of tef [Eragrostis tef (Zucc.) Trotter] based on amplified fragment length polymorphism

A genetic linkage map of tef was constructed with amplified fragment length polymorphism (AFLP) markers using F₅ recombinant inbred lines (RILs) derived by single seed descent from the intraspecific cross of ’Kaye Murri’×’Fesho’. A total of 192 EcoRI/MseI primer combinations were screened for parental polymorphism. Around three polymorphic fragments per primer combination were detected, indicating a low polymorphism level in tef. Fifty primer combinations were selected to assay the mapping population, and 226 loci segregated among 85 F₅ RILs. Most AFLP loci behaved as dominant markers (presence or absence of a band), but about 15% of the loci were codominant. Significant deviations from the expected Mendelian segregation ratio were observed for 26 loci. The genetic linkage map comprised 211 markers assembled into 25 linkage groups and covered 2,149 cM of genome. AFLP is an efficient marker system for mapping plant species with low polymorphism such as tef. This is the first genetic linkage map constructed for tef. It will facilitate the mapping of genes controlling agronomically important traits and cultivar improvement in tef. Received: 27 April 1998 / Accepted: 4 January 1999     

Identification of AFLP markers linked to the male fertility restorer gene of CMS (Moricandia arvensis) Brassica juncea and conversion to SCAR marker

We have developed a cytoplasmic male sterile (CMS) line of Brassica juncea through somatic hybridization with Moricandia arvensis and introgressed the fertility restorer gene into B. juncea. This fertility restorer locus is unique in that it is capable of restoring male fertility to two other alloplasmic CMS systems of B. juncea. As a first step toward cloning of this restorer gene we attempted molecular tagging of the Rf locus using the amplified fragment length polymorphism (AFLP) technique. A BC₁F₁ population segregating for male sterility/fertility was used for tagging using the bulk segregant analysis method. Out of 64 primer combinations tested in the bulks, 5 combinations gave polymorphic amplification patterns. Further testing of these primers in individual plants showed four amplicons associated with the male fertility trait. Polymorphic amplicons were cloned and used for designing SCAR primers. One of the SCAR primers generated amplicons mostly in the fertile plants. Linkage analysis using MAPMAKER showed two AFLP and one SCAR markers linked to the male fertility gene with a map distance ranging from 0.6 to 2.9 cM. All the markers are located on one side of the Rf locus.     

Detection of quantitative trait loci for carcass traits in the pig by using AFLP

For evaluation of the suitability of Amplified Fragment Length Polymorphism (AFLP) for detection of quantitative trait loci in farm animals, a combination of AFLP and selective genotyping has been applied as a rapid screening method for marker–QTL associations. Focusing on loci affecting eye muscle area, six extreme discordant sib pairs were selected from a Duroc × Berlin Miniature Pig F₂ experimental cross and examined by using 48 AFLP primer combinations. Two prominent AFLP markers were converted into simple codominant PCR markers (STS-Bo1 and STS-Bo3) and assigned to Sscr4 by physical and linkage mapping. Single marker analysis indicated association of the STS markers with a putative QTL influencing eye muscle area. Interval mapping confirmed the presence of a significant QTL for eye muscle area (P_genomewide < 0.01) on the Sscr4, with STS-Bo1 being the closer marker. At the same location, significant effects (P_genomewide < 0.01) on carcass length and backfat thickness were also detected. Our results demonstrate the capability of the combination of AFLP analysis and selective genotyping as a method for detection of genome regions containing QTL in livestock.     

Maize endopeptidase: Genetic control,chemical characterization,and relationship to an endogenous trypsin inhibitor

A single form of endopeptidase (EP-1) was found to be present at all stages of development and differentiation in all tissues of inbred maize. This endopeptidase occurs as two electrophoretically distinct variants which exist in different inbred maize lines. The gene coding for this endopeptidase has been tentatively located at or near the Y ₁ locus on chromosome 6. The EP-1 variants are under the control of two codominant alleles (Ep ₁ ^A and Ep ₁ ^B ) at the Ep ₁ locus. The two endopeptidase variants are similar with respect to molecular weight, heat stability, K _m, and metal ion inhibition, but are distinguishable by distinct isoelectric points as well as by different mobilities on starch gel electrophoresis. All attempts to hybridize the variants for purposes of determining subunit structure have failed. The endopeptidase is not inhibited by endogenous maize bovine trypsin inhibitor. During the development of seedlings, the endopeptidase is most active in immature liquid endosperm and in scutella, while the maize trypsin inhibitor is highest in starchy endosperm of mature kernels.Work supported by the U.S. Atomic Energy Commission under Contract No. AT(11-1)-1338.     

High-resolution genetic mapping of the pepper resistancelocus Bs3 governing recognition of the Xanthomonascampestris pv vesicatora AvrBs3 protein

The pepper (Capsicum annuum) Bs3 gene confers resistance to Xanthomonas campestris pv vesicatoria strains expressing the avirulence protein AvrBs3. Using amplified fragment length polymorphism (AFLP) and bulked DNA templates from resistant and susceptible plants we identified markers linked to Bs3 and defined a 2.1-cM interval containing the target gene. Bs3-linked AFLP fragments were cloned and conformity of isolated PCR products with the desired markers was determined by hybridisation to membrane-bound AFLP reactions. AFLP markers flanking the target gene were converted into locus-specific PCR-based markers. These markers were employed for the analysis of 790 plants segregating for Bs3, resulting in a linkage map with a genetic resolution of 0.13 cM. Mapping of Bs3-linked markers in tomato placed them to a syntenic interval on tomato chromosome 2. Received: 15 October 1999 / Accepted: 29 November 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     

An intersubspecific genetic map of<Emphasis Type="Italic"> Lens</Emphasis>

A Lens map was developed based on the segregational analysis of five kinds of molecular and morphological genetic markers in 113 F₂ plants obtained from a single hybrid of Lens culinaris ssp. culinaris × L. c. ssp. orientalis. A total of 200 markers were used on the F₂ population, including 71 RAPDs, 39 ISSRs, 83 AFLPs, two SSRs and five morphological loci. The AFLP technique generated more polymorphic markers than any of the others, although AFLP markers also showed the highest proportion (29.1%) of distorted segregation. At a LOD score of 3.0, 161 markers were grouped into ten linkage groups covering 2,172.4 cM, with an average distance between markers of 15.87 cM. There were six large groups with 12 or more markers each, and four small groups with two or three markers each. Thirty-nine markers were unlinked. A tendency for markers to cluster in the central regions of large linkage groups was observed. Likewise, clusters of AFLP, ISSR or RAPD markers were also observed in some linkage groups, although RAPD markers were more evenly spaced along the linkage groups. In addition, two SSR, three RAPD and one ISSR markers segregated as codominant. ISSR markers are valuable tools for Lens genetic mapping and they have a high potential in the generation of saturated Lens maps.Communicated by H.C. Becker     

Molecular markers residing close to the Rhg4 locus conferring resistance to soybean cyst nematode race 3 on linkage group A of soybean

 The restriction fragment length polymorphism (RFLP) clone pBLT65 is a 450-nt soybean cDNA encoding a portion of the bifunctional enzyme aspartokinase-homoserine dehydrogenase (AK-HSDH). pBLT65 maps within 3.5 cM of the i locus, conferring a pigmented seed coat, on linkage group A; hence, it is closely linked to the Rhg ₄ locus conferring resistance to race 3 of the soybean cyst nematode. From this useful RFLP we developed a PCR reaction yielding polymorphic bands for use in marker-assisted breeding programs to select progeny containing the Rhg ₄ allele. The polymorphic bands were sequenced to determine the cause of the polymorphisms. Using primers 548 and 563, PCR amplification of DNA from the soybean cultivar Peking (Rhg ₄ ) yielded three DNA fragments, 1a (1160 bp), 1b (1146 bp) and 3 (996 bp). Amplification of DNA from the cultivar Kent (rhg ₄) yielded DNA fragments 2 (1020 bp), 3 (996 bp) and 4 (960 bp). Fragments 1a, 1b, 2 and 4 were also polymorphic between the soybean lines PI 290136 and BARC-2(Rj ₄ ). A segregating population of 80 F₂ and F₃ plants derived from the cross PI 290136×BARC-2 (Rj ₄ ) was used to confirm the map position of the PCR polymorphisms near the i locus, and hence the Rhg ₄ locus on linkage group A. The nucleotide sequences of fragments 1b, 3 and 4 were determined. Large and small deletions in the intronic region were responsible for the size differences of the different fragments, whereas the exon was well conserved. Received: 8 January 1998 / Accepted: 15 July 1998     

Mapping of the genes for dioecism and monoecism in Spinacia oleracea L.: evidence that both genes are closely linked

Spinach is basically a dioecious species, with occasional monoecious plants in some populations. Sexual dimorphism in dioecious spinach plants is controlled by an allelic pair termed X and Y located on the short arm of the longest chromosome (x = 6). Ten AFLP markers, closely linked to the X/Y locus, were identified using bulked segregant analysis, four of which were revealed to co-segregate with Y in the present mapping population. We mapped the AFLP markers and two known male-specific DNAs to a 13.4 cM region encompassing the locus. These markers will be the basis for positional cloning of the sex-determination gene. We also showed that a single, incompletely dominant gene is responsible for the highly staminate monoecious character. The gene was found to be located at a distance of 4.3 cM from microsatellite marker SO4, which mapped 1.6 cM from the X/Y locus. This indicates that the monoecious gene seems not to be allelic to but closely linked to the X/Y gene pair. SO4 will enable breeders to efficiently select highly male monoecious plants for preferential use as the pollen parent for hybrid seed production.     

A new and versatile method for the successful conversion of AFLP markers into simple single locus markers

Genetic markers can efficiently be obtained by using amplified fragment length polymorphism (AFLP) fingerprinting because no prior information on DNA sequence is required. However, the conversion of AFLP markers from complex fingerprints into simple single locus assays is perceived as problematic because DNA sequence information is required for the design of new locus-specific PCR primers. In addition, single locus polymorphism (SNP) information is required to design an allele-specific assay. This paper describes a new and versatile method for the conversion of AFLP markers into simple assays. The protocol presented in this paper offers solutions for frequently occurring pitfalls and describes a procedure for the identification of the SNP responsible for the AFLP. By following this approach, a high success rate for the conversion of AFLP markers into locus-specific markers was obtained.