Mapping of AFLP markers linked to seed coat colour loci in<Emphasis Type="Italic"> Brassica juncea</Emphasis> (L.) Czern

Association mapping of the seed-coat colour with amplified fragment length polymorphism (AFLP) markers was carried out in 39 Brassica juncea lines. The lines had genetically diverse parentages and varied for seed-coat colour and other morphological characters. Eleven AFLP primer combinations were used to screen the 39 B. juncea lines, and a total of 335 polymorphic bands were detected. The bands were analysed for association with seed-coat colour using multiple regression analysis. This analysis revealed 15 markers associated with seed-coat colour, obtained with eight AFLP primer combinations. The marker E-ACA/M-CTG₃₅₀ explained 69% of the variation in seed-coat colour. This marker along with markers E-AAC/M-CTC₂₃₅ and E-AAC/M-CTA₂₅₀ explained 89% of the total variation. The 15 associated markers were validated for linkage with the seed-coat colour loci using a recombinant inbred line (RIL) mapping population. Bands were amplified with the eight AFLP primer combinations in 54 RIL progenies. Of the 15 associated markers, 11 mapped on two linkage groups. Eight markers were placed on linkage group 1 at a marker density of 6.0 cM, while the remaining three were mapped on linkage group 2 at a marker density of 3.6 cM. Marker E-ACA/M-CTG₃₅₀ co-segregated with Gene1 controlling seed-coat colour; it was specific for yellow seed-coat colour and mapped to linkage group 1. Marker E-AAC/M-CTC₂₃₅ (AFLP8), which had been studied previously, was present on linkage group 2; it was specific for brown seed-coat colour. Since AFLP markers are not adapted for large-scale applications in plant breeding, it is important to convert these to sequence-characterised amplified region (SCAR) markers. Marker E-AAC/M-CTC₂₃₅ (AFLP8) had been previously converted into a SCAR. Work is in progress to convert the second of the linked markers, E-ACA/M-CTG₃₅₀, to a SCAR. The two linked AFLP markers converted to SCARs will be useful for developing yellow-seeded B. juncea lines by means of marker-assisted selection.Communicated by H.F. Linskens     

Chromosome landing at the Arabidopsis TORNADO1 locus using an AFLP-based strategy

 The Arabidopsis tornado1 (trn1) mutation causes severe dwarfism combined with twisted growth of all organs. We present a chromosome landing strategy, using amplified restriction fragment length polymorphism (AFLP) marker technology, for the isolation of the TRN1 gene. The recessive trn1 mutation was identified in a C24 transgenic line and is located 5 cM from a T-DNA insertion. We mapped the TRN1 locus to the bottom half of chromosome 5 relative to visible and restriction fragment length polymorphism (RFLP) markers. Recombinant classes within a 3-cM region around TRN1 were used to build a high-resolution map in this region, using the AFLP technique. Approximately 300 primer combinations have been used to test about 26 000 fragments for polymorphisms. Seventeen of these AFLP markers were identified in the 3-cM region around TRN1. These markers were mapped within this region using individual recombinants. Four of these AFLP markers co-segregate with TRN1 whereas one maps at one recombinant below TRN1. We isolated and cloned three of these AFLP markers. These markers identified two yeast artificial chromosome (YAC) clones, containing the RFLP marker above and the AFLP marker below TRN1, demonstrating that these YACs span the TRN1 locus and that chromosome landing has been achieved, using an AFLP-based strategy. Received: 25 April 1996 / Accepted: 26 June 1996     

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     

Assessment of Genetic Diversity of Biodiesel Species <Emphasis Type="Italic">Pongamia pinnata</Emphasis> Accessions using AFLP and Three Endonuclease-AFLP

Efficacy of two dominant molecular markers, namely, amplified fragment length polymorphism (AFLP) and three endonuclease (TE)-AFLP, were assessed in 20 individuals of the biodiesel species Pongamia pinnata. Four primer combinations generated a total of 254 and 194 bands in AFLP and TE-AFLP, respectively. Both techniques could unequivocally identify each accession used in this study. The Jaccard’s similarity coefficient ranged from 0.30 to 0.90 for AFLP and from 0.25 to 0.85 for TE-AFLP. The correlation coefficient between AFLP and TE-AFLP dendrogram was 0.56 which was low but significant (P < 0.001). Values of effective multiplex ratio, marker index, and resolving power were markedly higher in AFLP than in TE-AFLP. However, the band intensities across different lanes were uniform in TE-AFLP leading to easy and accurate scoring of gels which resulted in slightly higher bootstrap values with TE-AFLP data as compared to AFLP data. Inferences based on TE-AFLP data had similar level of biological relevance as compared to AFLP data when location and diameter of trees were taken in to consideration. However, the easy scorability of TE-AFLP profiles is extremely important and especially desirable in studies requiring genotyping of large number of individuals distributed across many gels.     

Characterization and fine mapping of <Emphasis Type="Italic">RppQ</Emphasis>, a resistance gene to southern corn rust in maize

Southern corn rust (SCR) is a fungal disease caused by Puccinia polysora Underw, which can infect maize and may result in substantial yield losses in maize production. The maize inbred line Qi319 carries the SCR resistance gene RppQ. In order to identify molecular markers linked to the RppQ gene, several techniques were utilized including random amplified polymorphic DNA (RAPD), simple sequence repeat (SSR), and amplified fragment length polymorphism (AFLP). In addition, sequence characterized amplified region (SCAR) techniques combined with bulked segregant analysis (BSA) were used. Seven RAPD markers, eight SSR markers, and sixty-three AFLP primer combinations amplified polymorphisms between two parents and two bulk populations. A large F₂ population was used for genetic analysis and for fine mapping of the RppQ gene region. One AFLP polymorphic band, M-CAA/E-AGC₃₂₄, was converted to a SCAR marker, MA7, which was mapped to a position 0.46 cM from RppQ. Finally, the RppQ gene was mapped between the SCAR marker MA7 and the AFLP marker M-CCG/E-AGA₁₅₇ with distances of 0.46 and 1.71 cM, respectively.     

Conversion of AFLP markers to sequence-specific markers for closely related lines in rice by use of the rice genome sequence

DNA polymorphism between two major japonica rice cultivars, Nipponbare and Koshihikari, was identified by AFLP. Eighty-four polymorphic AFLP markers were obtained by analysis with 360 combinations of primer pairs. Nucleotide sequences of 73 markers, 29 from Nipponbare and 44 from Koshihikari, were determined, and 46 AFLP markers could be assigned to rice chromosomes based on sequence homology to the rice genome sequence. Specific primers were designed for amplification of the regions covering the AFLP markers and the flanking sequences. Out of the 46 primer pairs, 44 amplified single DNA fragments, six of which showed different sizes between Nipponbare and Koshihikari, yielding codominant SCAR markers. Eight primer pairs amplified only Nipponbare sequences, providing dominant SCAR markers. DNA fragments amplified by 13 primer pairs showed polymorphism by CAPS, and polymorphism of those amplified by 13 other primer pairs were detected by PCR-RF-SSCP (PRS). Nucleotide sequences of the other four DNA fragments were determined in Koshihikari, but no difference was found between Koshihikari and Nipponbare. In total, 40 sequence-specific markers for the combination of Nipponbare and Koshihikari were produced. All the SNPs identified by AFLP were detectable by CAPS and PRS. The same method was applicable to a combination of Kokoromachi and Tohoku 168, and 23 polymorphic markers were identified using these two rice cultivars. The procedure of conversion of AFLP-markers to the sequence-specific markers used in this study enables efficient sequence-specific marker production for closely related cultivars.     

Polymorphism, distribution, and segregation of AFLP markers in a doubled haploid rice population

We exploited the newly developed amplified fragment length polymorphism (AFLP) technique to study the polymorphism, distribution and inheritance of AFLP markers with a doubled haploid rice population derived from ‘IR64’/‘Azucena’. Using only 20 pairs of primer combinations, we detected 945 AFLP bands of which 208 were polymorphic. All 208 AFLP markers were mapped and distributed over all 12 chromosomes. When these were compared with RFLP markers already mapped in the population, we found the AFLP markers to be highly polymorphic in rice and to follow Mendelian segregation. As linkage map of rice can be generated rapidly with AFLP markers they will be very useful for marker-assisted backcrossing. Received: 11 April 1996 / Accepted: 14 June 1996     

Genetic Variation and Population Structure of Oriental Migratory Locust, Locusta migratoria manilensis, in China by Allozyme, SSRP-PCR, and AFLP Markers

Allozyme analysis, microsatellite primer PCR (SSRP-PCR), and amplified fragment length polymorphism (AFLP) techniques were used to assess genetic diversity and population structure of the Chinese oriental migratory locust, Locusta migratoria manilensis. A total of 299 PCR markers (67 SSRPs and 232 AFLPs) were detected in eight populations, of which 98.7% were polymorphic markers. The proportion of polymorphic loci (95.5–98.8%) by SSRP+AFLP markers indicated no significant differences between populations, and all populations exhibited a similar level of variability; results of the allozyme analysis demonstrated that 19 loci gave rise to a lower level of polymorphism (55.6–66.7%). The genetic distances between the populations were relatively low. Shannon’s index and Nei’s gene diversity showed low differentiation among the populations. Allozyme analysis, however, reflected greater similarity and smaller differentiation between the populations than those shown by SSRP and AFLP markers. Neighbor-joining dendrograms derived from both the allozyme and SSRP+AFLP markers showed that the genetic distances among Chinese oriental migratory locust populations were not greatly influenced by geographic distance and breeding habitats.     

Inheritance and usefulness of AFLP markers in channel catfish (Ictalurus punctatus ), blue catfish ( I. furcatus) , and their F1, F2, and backcross hybrids

Eight primer combinations were used to investigate the application of amplified fragment length polymorphism (AFLP) markers in catfish for genetic analysis. Intraspecific polymorphism was low among channel catfish or blue catfish strains. Interspecific AFLP polymorphism was high between the channel catfish and blue catfish. Each primer combination generated from 70 to more than 200 bands, of which 38.6–75.7% were polymorphic between channel catfish and blue catfish. On average, more than 20 polymorphic bands per primer combination were produced as quality markers suitable for genetic analysis. All AFLP markers were transmitted into channel catfish × blue catfish F1 hybrids, except rare markers that were heterozygous in the parents and therefore were segregating in F1 hybrids. The two reciprocal channel catfish × blue catfish F1 hybrids (channel catfish female × blue catfish male; blue catfish female × channel catfish male) produced identical AFLP profiles. The AFLP markers were inherited and segregated in expected Mendelian ratios. At two loci, E8-b9 and E8-b2, markers were found at significantly lower frequencies than expected with F2 and backcross hybrids which had been selected for increased growth rates. The reproducibility of AFLP was excellent. These characteristics of the catfish AFLP markers make them highly useful for genetic analysis of catfish, especially for construction of genetic linkage and quantitative trait loci maps, and for marker-assisted selection. Received: 10 September 1997 / Accepted: 10 December 1997     

Identification ofporphyra lines (rhodophyta) by AFLP DNA fingerprinting and molecular markers

Twenty-sevenPorphyra lines from 5 classes, including lines widely used in China, wild lines, and lines introduced to China from abroad in recent years, were screened by means of amplified fragment length polymorphism (AFLP) with 24 primer pairs. From the generated AFLP products, 13 bands that showed stable and repeatable AFLP patterns amplified by primer pairs M-CGA/E-AA and M-CGA/E-TA were scored and used to develop the DNA fingerprints of the 27Porphyra lines. Moreover, the DNA fingerprinting patterns were converted into computer language expressed with digitals 1 and 0, which represented the presence (numbered as 1) or absence (numbered as 0) of the corresponding band. On the basis of these results, computerized AFLP DNA fingerprints were constructed in which each of the 27Porphyra lines has its unique AFLP fingerprinting pattern and can be easily distinguished from others. Software called PGI-AFLP (Porphyra germ-plasm identification-AFLP) was designed for identification of the 27Porphyra lines. In addition, 21 specific AFLP markers from 15Porphyra lines were identified; 6 AFLP markers from 4Porphyra lines were sequenced, and 2 of them were successfully converted into SCAR (sequence characterized amplification region) markers. The developed AFLP DNA fingerprinting and specific molecular markers provide useful ways for the identification, classification, and resource protection of thePorphyra lines.     

AFLP linkage group assignment to the chromosomes of Allium cepa L. via monosomic addition lines

Two complete sets of Allium fistulosum L.– A. cepa monosomic addition lines (2n=2x+1=17) together with an AFLP linkage map based on a cross between A. cepa and A. roylei Stearn were used to re-evaluate the eight A. cepa linkage groups identified in the mapping study. The linkage groups could be assigned to individual, physical chromosomes. The low level of molecular homology between A. cepa and A. fistulosum enabled the identification of 186 amplified fragment length polymorphisms (AFLP™ markers) present in A. cepa and not in A. fistulosum with ten different primer combinations. With the monosomic addition lines the distribution of the markers over the eight chromosomes of A. cepa could be determined. Of these 186 AFLP markers 51 were absent in A. roylei and consequently used as markers in the mapping study (A. cepa ×A. roylei cross). Therefore, these 51 AFLP markers could be used to assign the eight A. cepa linkage groups identified in the mapping study to physical chromosomes. Seven isozyme and three CAPS markers were also included. Two of the linkage groups had to be split because they included two sets of markers corresponding to different chromosomes. A total of 20 (approx. 10%) of the A. cepa-specific AFLP markers were amplified in more than one type of the monosomic addition lines, suggesting unlinked duplications. The co-dominant isozyme and CAPS markers were used to identify the correspondence of linkage groupsoriginating from A. cepa or from A. roylei. Received: 16 April 1999 / Accepted: 13 August 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     

No sex‐specific markers detected in bluegill sunfish Lepomis macrochirus by AFLP

The amplified fragment‐length polymorphism (AFLP) technique was used to identify sex‐specific markers in bluegill sunfish. A total of 12 835 loci were produced by 256 primer combinations, of which nine (0·73‰) exhibited presumed sex‐associated amplifications in the pooled samples; however, none of which revealed sex specificity upon individual evaluation.     

Construction of an AFLP genetic map with nearly complete genome coverage in Pinus taeda

  De novo construction of complete genetic linkage maps requires large mapping populations, large numbers of genetic markers, and efficient algorithms for ordering markers and evaluating order confidence. We constructed a complete genetic map of an individual loblolly pine (Pinus taeda L.) using amplified fragment length polymorphism (AFLP) markers segregating in haploid megagametophytes and PGRI mapping software. We generated 521 polymorphic fragments from 21 AFLP primer pairs. A total of 508 fragments mapped to 12 linkage groups, which is equal to the Pinus haploid chromosome number. Bootstrap locus order matrices and recombination matrices generated by PGRI were used to select 184 framework markers that could be ordered confidently. Order support was also evaluated using log likelihood criteria in MAPMAKER. Optimal marker orders from PGRI and MAPMAKER were identical, but the implied reliability of orders differed greatly. The framework map provides nearly complete coverage of the genome, estimated at approximately 1700 cM in length using a modified estimator. This map should provide a useful framework for merging existing loblolly pine maps and adding multiallelic markers as they become available. Map coverage with dominant markers in both linkage phases will make the map useful for subsequent quantitative trait locus mapping in families derived by self-pollination. Received: 7 August 1998 / Accepted: 27 October 1998     

Genetic relatedness and genetic diversity of ornamental mei (Prunus mume Sieb. et Zucc.) as analysed by AFLP markers

The genetic diversity and genetic relatedness of mei (Prunus mume; 2n = 16) were studied using amplified fragment length polymorphism (AFLP) markers. Eight EcoRI–PstI AFLP primer combinations were applied to 121 distinct genotypes of mei cultivars and related species. A total of 508 AFLP product bands were produced, of which 382 were polymorphic. The unweighted pair group method with arithmetic averages analysis was carried out based on these AFLP markers. From this analysis, “Qugeng Mei,” “Yan Mei,” “Chaodou Mei,” and mei cultivars were seen to share the same P. mume genetic stem. The AFLP data were able to clearly discriminate P. mume from other species in the genus Prunus, with P. armeniaca aligning as its closest related species. Two major groups and nine subgroups of mei flower were identified, and there was a strong coincidence of these AFLP-based groupings with the respective morphological characters of the accessions. The genetic diversity of mei accessions was greatest in the Yunnan Province and decreased toward Eastern China and Japan, so supporting the hypothesis that the southwest of China represents the genetic diversity center of the species.     

Cleaved AFLP (cAFLP), a modified amplified fragment length polymorphism analysis for cotton

In certain plant species including cotton (Gossypium hirsutum L. or Gossypium barbadense L.), the level of amplified fragment length polymorphism (AFLP) is relatively low, limiting its utilization in the development of genome-wide linkage maps. We propose the use of frequent restriction enzymes in combination with AFLP to cleave the AFLP fragments, called cleaved AFLP analysis (cAFLP). Using four Upland cotton genotypes (G. hirsutum) and three Pima cotton (G. barbadense), we demonstrated that cAFLP generated 67% and 132% more polymorphic markers than AFLP in Upland and Pima cotton, respectively. This resulted in 15.5 and 25.5 polymorphic cAFLP markers per AFLP primer combination, as compared to 9.1 and 11.0 polymorphic AFLP. The cAFLP-based genetic similarity (GS) is generally lower than the AFLP-based GS, even though both marker systems are overall congruent. In some cases, cAFLP can better resolve genetic relationships between genotypes, rendering a higher discriminatory power. Given the high-resolution power of capillary-based DNA sequencing system, we further propose that AFLP and cAFLP amplicons from the same primer combination can be pooled as one sample before electrophoresis. The combination produced an average of 18.5 and 31.0 polymorphic markers per primer pair in Upland and Pima cotton, respectively. Using several restriction enzyme combinations before pre-selective amplification in combination with various frequent 4 bp-cutters or 6 bp-cutters after selective amplification, the pooled AFLP and cAFLP will provide unlimited number of polymorphic markers for genome-wide mapping and fingerprinting.     

Molecular mapping of the rf1 gene for pollen fertility restoration in sorghum (Sorghum bicolor L.)

We report the molecular mapping of a gene for pollen fertility in A1 (milo) type cytoplasm of sorghum using AFLP and SSR marker analysis. DNA from an F₂ population comprised of 84 individuals was screened with AFLP genetic markers to detect polymorphic DNAs linked to fertility restoration. Fifteen AFLP markers were linked to fertility restoration from the initial screening with 49 unique AFLP primer combinations (+3/+3 selective bases). As many of these AFLP markers had been previously mapped to a high-density genetic map of sorghum, the target gene (rf1) could be mapped to linkage group H. Confirmation of the map location of rf1 was obtained by demonstrating that additional linkage group-H markers (SSR, STS, AFLP) were linked to fertility restoration. The closest marker, AFLP Xtxa2582, mapped within 2.4 cM of the target loci while two SSRs, Xtxp18 and Xtxp250, flanked the rf1 locus at 12 cM and 10.8 cM, respectively. The availability of molecular markers will facilitate the selection of pollen fertility restoration in sorghum inbred-line development and provide the foundation for map-based gene isolation. Received: 22 August 2000 / Accepted: 18 October 2000     

Conversion of AFLP markers to sequence-specific PCR markers in barley and wheat

 Conversion of amplified fragment length polymorphisms (AFLPs) to sequence-specific PCR primers would be useful for many genetic-linkage applications. We examined 21 wheat nullitetrasomic stocks and five wheat-barley addition lines using 12 and 14 AFLP primer combinations, respectively. On average, 36.8% of the scored AFLP fragments in the wheat nullitetrasomic stocks and 22.3% in the wheat-barley addition lines could be mapped to specific chromosomes, providing approximately 461 chromosome-specific AFLP markers in the wheat nullitetrasomic stocks and 174 in the wheat-barley addition lines. Ten AFLP fragments specific to barley chromosomes and 16 AFLP fragments specific to wheat 3BS and 4BS chromosome arms were isolated from the polyacrylamide gels, re-amplified, cloned and sequenced. Primer sets were designed from these sequences. Amplification of wheat and barley genomic DNA using the barley derived primers revealed that three primer sets amplified DNA from the expected chromosome, five amplified fragments from all barley chromosomes but not from wheat, one amplified a similar-sized fragment from multiple barley chromosomes and from wheat, and one gave no amplification. Amplification of wheat genomic DNA using the wheat-derived primer sets revealed that three primer sets amplified a fragment from the expected chromosome, 11 primer sets amplified a similar-sized fragment from multiple chromosomes, and two gave no amplification. These experiments indicate that polymorphisms identified by AFLP are often not transferable to more sequence-specific PCR applications. Received: 30 June 1998 / Accepted: 26 October 1998     

Use of allele specificity of comigrating AFLP markers to align genetic maps from different potato genotypes

The allele specificity of AFLP markers was assessed in five relatively unrelated potato genotypes. To this end, two diploid mapping populations of potato, F₁SH × RH and F₁AM × RH, were analysed using four and six AFLP primer combinations, respectively, recently applied to the analysis of the genetically well characterized backcross population BC_C × E. The AFLP profiles of the five parents revealed 733 AFLP markers and, when identical primer combinations were used, 131 comigrating AFLP markers were identified. After construction of five parental maps, the genomic positions of these comigrating AFLP markers were compared and 117 markers (89%) which targeted the same genomic region were assumed to be homologous. Of these putative homologues, 20 markers, each cloned from at least two genotypes, were sequenced and 19 sets of amplification products were shown to be nearly identical. The number of AFLP markers previously mapped in population BC_C × E ranged from three to eleven per chromosome, which allowed a reliable assessment of chromosome numbers from individual linkage groups obtained in populations F₁SH × RH and F₁AM × RH. The high incidence of corresponding AFLP alleles was confirmed by using an additional set of five primer combinations. The 733 AFLP markers localized provide a valuable reference collection for future mapping studies in potato. As a consequence AFLP analysis may replace more laborious locus-specific marker techniques. Received: 26 July 1996 / Accepted: 30 January 1997     

Strain typing of shiitake (<Emphasis Type="Italic">Lentinula edodes</Emphasis>) cultivars by AFLP analysis,focusing on a heat-dried fruiting body

To validate strain typing by amplified fragment length polymorphism (AFLP) analysis in shiitake (Lentinula edodes) cultivars, the reproducibility of AFLP markers with DNA extracted from the heat-dried fruiting body was evaluated. DNAs were extracted from three different portions of the heat-dried fruiting body – the stipe, pileus, and gill – and AFLP analysis of all parts was carried out using two combinations of selected amplification primer pairs. AFLP profiles of DNA from the gill tissue of heat-dried fruiting body were almost identical to those of cultured mycelia in the same strains, although it was difficult to detect reproducible AFLP profiles from stipe and pileus DNA. These results indicated that AFLP analysis would be applicable for strain typing with heat-dried fruiting bodies of L. edodes by using the DNA extracted from gills.Contribution No. 364 of the Tottori Mycological Institute