Monophyletic origin of naked barley inferred from molecular analyses of a marker closely linked to the naked caryopsis gene (<Emphasis Type="Italic">nud</Emphasis>)

To elucidate the origin of naked barley, molecular variation of the marker sKT7 tightly linked to the nud locus was examined. A total of 259 (53 wild, 106 hulled domesticated, and 100 naked domesticated) barley accessions were studied. Restriction analysis of the sKT7 PCR-amplified product revealed the alleles I, II, III, and IV. All four alleles were found in wild barley, but allele IV was found only in a single accession from southwestern Iran. Hulled domesticated accessions showed alleles I, II, or III, but all naked domesticated accessions had allele IV. The distribution of allele IV in wild barley and its pervasive presence in naked domesticated lines support the conclusion that naked barley has a monophyletic origin, probably in southwestern Iran. The available results suggest two scenarios for the origin of naked barley: either directly from a wild barley with allele IV or from a hulled domesticated line with allele IV that later became extinct. Naked domesticated accessions from different regions of the world have extremely homogeneous DNA sequences at the sKT7 locus, supporting the monophyletic origin of naked barley. For allele IV, four haplotypes (IVb to IVe) were found in 30 naked accessions: IVb was predominant (66.7%) and widely distributed, while the other three haplotypes, differing by only one nucleotide at different positions relative to IVb, showed a localized distribution. The geographical distribution of the haplotypes of sKT7 allele IV suggests migration routes of naked domesticated barley in central and eastern Asia.Communicated by F. Salamini     

Genetic mapping of AFLP/AMF-derived DNA markers in the vicinity of the self-incompatibility locus in<Emphasis Type="Italic"> Ipomoea trifida</Emphasis>

Sporophytic self-incompatibility of diploid Ipomoea trifida is controlled by a single multiallelic locus, the S-locus. To make a fine linkage map around the S-locus, AFLP (amplified restriction fragment length polymorphism) and AMF (AFLP-based mRNA fingerprinting) analyses were performed using bulked genomic DNA and mRNA, respectively, from several plants of each S-haplotype in a segregating population. Putative S-haplotype-specific fragments were obtained and subjected to RFLP analysis of genomic DNA to confirm genetic linkage to the S-locus. Eight DNA markers co-segregating with the S-haplotype were identified and mapped in close proximity to the S-locus. One of them, AAM-68, was the most tightly linked to the S-locus, because no recombinants were detected in the 873 plants of the segregating population analyzed. The S-locus region was defined to be within 1.25 cM in the linkage map. These markers are useful for positional cloning of the S-locus genes in Ipomoea.     

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     

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     

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.     

A genetic linkage map of the diplosporous chromosomal region in<Emphasis Type="Italic"> Taraxacum officinale</Emphasis> (common dandelion; Asteraceae)

In this study, we mapped the diplosporous chromosomal region in Taraxacum officinale, by using amplified fragment length polymorphism technology (AFLP) in 73 plants from a segregating population. Taraxacum serves as a model system to investigate the genetics, ecology, and evolution of apomixis. The genus includes sexual diploid as well as apomictic polyploid, mostly triploid, plants. Apomictic Taraxacum is diplosporous, parthenogenetic, and has autonomous endosperm formation. Previous studies have indicated that these three apomixis elements are controlled by more than one locus in Taraxacum and that diplospory inherits as a dominant, monogenic trait (Ddd; DIP). A bulked segregant analysis provided 34 AFLP markers that were linked to DIP and were, together with two microsatellite markers, used for mapping the trait. The map length was 18.6 cM and markers were found on both sides of DIP, corresponding to 5.9 and 12.7 cM, respectively. None of the markers completely co-segregated with DIP. Eight markers were selected for PCR-based marker development, of which two were successfully converted. In contrast to all other mapping studies of apomeiosis to date, our results showed no evidence for suppression of recombination around the DIP locus in Taraxacum. No obvious evidence for sequence divergence between the DIP and non-DIP homologous loci was found, and no hemizygosity at the DIP locus was detected. These results may indicate that apomixis is relatively recent in Taraxacum.     

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     

Development of STS markers closely linked to the Ppd-H1 photoperiod response gene of barley (Hordeum vulgare L.)

A BC₂ population of 353 plants segregating for the Ppd-H1 photoperiod response gene was developed from a cross between the winter barley ’Igri’ and the spring barley ’Triumph.’ Bulk segregant analysis identified six AFLP markers closely linked to the Ppd–H1 gene and three strongly amplified AFLP bands that mapped 0.8-cM distal, 0.6-cM proximal and 2.3-cm proximal to Ppd-H1 were cloned and sequenced. Southern-blot analysis showed that the cloned fragments were single-copy sequences in ’Igri’, the variety from which they were derived. Two of the sequences were absent from ’Triumph’ while the third detected a single-copy sequence. The cloned fragments were used to design specific sequence tagged site (STS) primer pairs to assist in the construction of a high-resolution map of the Ppd-H1 region. Received: 22 March 2000 / Accepted: 10 April 2000     

A consensus map for <Emphasis Type="Italic">Cucurbita pepo</Emphasis>

Using random amplified polymorphic DNA (RAPD), amplified fragment length polymorphism (AFLP), simple sequence repeats (SSR), and morphological traits, the first genetic maps for Cucurbita pepo (2n=2x=40) were constructed and compared. The two mapping populations consisted of 92 F₂ individuals each. One map was developed from a cross between an oil-seed pumpkin breeding line and a zucchini accession, into which genes for resistance to Zucchini Yellow Mosaic Virus (ZYMV) from a related species, C. moschata, had been introgressed. The other map was developed from a cross between an oil-seed pumpkin and a crookneck variety. A total of 332 and 323 markers were mapped in the two populations. Markers were distributed in each map over 21 linkage groups and covered an average of 2,200 cM of the C. pepo genome. The two maps had 62 loci in common, which enabled identification of 14 homologous linkage groups. Polyacrylamide gel analyses allowed detection of a high number of markers suitable for mapping, 10% of which were co-dominant RAPD loci. In the Pumpkin-Zucchini population, bulked segregant analysis (BSA) identified seven markers less than 7 cM distant from the locus n, affecting lignification of the seed coat. One of these markers, linked to the recessive hull-less allele (AW11-420), was also found in the Pumpkin-Crookneck population, 4 cM from n. In the Pumpkin-Zucchini population, 24 RAPD markers, previously introduced into C. pepo from C. moschata, were mapped in two linkage groups (13 and 11 markers in LGpz1 and LGpz2, respectively), together with two sequence characterized amplified region (SCAR) markers linked to genes for resistance to ZYMV.     

A High-Resolution Map in the Chromosomal Region Surrounding theLpsLocus

TheLpslocus on mouse chromosome 4 controls host responsiveness to lipopolysaccharide, a major component of the outer membrane of Gram-negative bacteria. The C3H/HeJ inbred mouse strain is characterized by a mutantLpsallele (Lps^d) that renders it hyporesponsive to LPS and naturally tolerant of its lethal effects. To identify theLpsgene by a positional cloning strategy, we have generated a high-resolution linkage map of the chromosomal region surrounding this locus. We have analyzed a total of 1604 backcross mice from a preexisting interspecific backcross panel of 259 (Mus spretus× C57BL/6J)F1 × C57BL/6J and two novel panels of 597 (DBA/2J × C3H/HeJ)F1 × C3H/HeJ and 748 (C57BL/6J × C3H/HeJ)F1 × C3H/HeJ segregating atLps.A total of 50 DNA markers have been mapped in a 11.8-cM span overlapping theLpslocus. This positions theLpslocus within a 1.1-cM interval, flanked proximally by a large cluster of markers, including three known genes (Cd30l, Hxb,andAmbp), and distally by two microsatellite markers (D4Mit7/D4Mit178). The localization of theLpslocus is several centimorgans proximal to that previously assigned.     

Microcolinearity between a 2-cM region encompassing the grain protein content locus<Emphasis Type="Italic"> Gpc-6B1</Emphasis> on wheat chromosome 6B and a 350-kb region on rice chromosome 2

The conservation of the linear order (colinearity) of genetic markers along large chromosome segments in wheat and rice is well established, but less is known about the microcolinearity between both genomes at subcentimorgan distances. In this study we focused on the microcolinearity between a 2.6-cM interval flanked by markers Xcdo365 and Xucw65 on wheat chromosome 6B and rice chromosome 2. A previous study has shown that this wheat segment includes the Gpc-6B1 locus, which is responsible for large differences in grain protein content (GPC) and is the target of a positional cloning effort in our laboratories. Twenty-one recombination events between Xcdo365 and Xucw65 were found in a large segregating population (935 gametes) and used to map 17 genes selected from rice chromosome 2 in the wheat genetic map. We found a high level of colinearity between a 2.1-cM region flanked by loci Xucw75 and Xucw67 on wheat chromosome 6B and a 350-kb uninterrupted sequenced region in rice chromosome arm 2S. Colinearity between these two genomes was extended to the region proximal to Xucw67 (eight colinear RFLP markers), but was interrupted distal to Xucw75 (six non-colinear RFLP markers). Analysis of different comparative studies between rice and wheat suggests that microcolinearity is more frequently disrupted in the distal region of the wheat chromosomes. Fortunately, the region encompassing the Gpc-6B1 locus showed an excellent conservation between the two genomes, facilitating the saturation of the target region of the wheat genetic map with molecular markers. These markers were used to map the Gpc-6B1 locus into a 0.3-cM interval flanked by PCR markers Xucw79 and Xucw71, and to identify five candidate genes within the colinear 64-kb region in rice.     

Identification of a male-specific AFLP marker in a functionally dioecious fig,<Emphasis Type="Italic"> Ficus fulva</Emphasis> Reinw. ex Bl. (Moraceae)

A male-specific amplified fragment length polymorphism (AFLP) marker was identified in the functionally dioecious fig species, Ficus fulva. A total of 89 polymorphic fragments from three primer combinations were produced, of which one (246 bp) was present in all males (n=23) and absent in all females (n=24) of two populations. This strong association suggests a tight chromosomal linkage between the AFLP marker and the sex-controlling locus. Further analysis indicated that the marker segregated in open-pollinated progenies from natural populations in a 1:1 ratio (n=156), implying that males are the heterogametic sex. Chromosome preparations showed no evidence for morphologically distinct sex chromosomes. The low frequencies of associated markers argue against a morphologically cryptic non-recombining sex chromosome. The sex-locus is therefore likely to be autosomal. The male-specific AFLP marker was sequenced and converted into a sequence characterised amplified region (SCAR) marker. This SCAR marker produced a fragment of equal size in males and females, suggesting that sequence divergence between male- and female-specific chromosomal regions is low.Publication 3311 NIOO-KNAW Netherlands Institute of Ecology     

AFLP Linkage Map of the OomycetePhytophthora infestans

Here we present the first comprehensive genetic linkage map of the heterothallic oomycetous plant pathogenPhytophthora infestans.The map is based on polymorphic DNA markers generated by the DNA fingerprinting technique AFLP (Voset al.,1995,Nucleic Acids Res.23:4407–4414). AFLP fingerprints were made from single zoospore progeny and 73 F1 progeny from two field isolates ofP. infestans.The parental isolates appeared to be homokaryotic and diploid, their AFLP patterns were mitotically stable, and segregation ratios in the F1 progeny were largely Mendelian. In addition to 183 AFLP markers, 7 RFLP markers and the mating type locus were mapped. The linkage map comprises 10 major and 7 minor linkage groups covering a total of 827 cM. The major linkage groups are composed of markers derived from both parents, whereas the minor linkage groups contain markers from either the A1 or the A2 mating type parent. Non-Mendelian segregation ratios were found for the mating type locus and for 13 AFLP markers, all of which are located on the same linkage group as the mating type locus.     

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.     

BAC-derived diagnostic markers for sex determination in asparagus

A HindIII BAC (bacterial artificial chromosome) library of asparagus (Asparagus officinalis L.) was established from a single male plant homozygous for the male flowering gene (MM). The library represents approximately 5.5 haploid genome equivalents with an average insert size of 82 kb. A subset of the library (2.6 haploid genome equivalents) was arranged into DNA pools. Using nine sex-linked amplified fragment length polymorphism (AFLP) and two sequence-tagged site (STS) markers, 13 different BAC clones were identified from this part of the library. The BACs were arranged into a first-generation physical map around the sex locus. Four PCR-derived markers were developed from the BAC ends, one of which could be scored in a co-dominant way. Using a mapping population of 802 plants we mapped the BAC-derived markers to the same position close to the M gene as the corresponding AFLP and STS markers. The markers are useful for further chromosome walking studies and as diagnostic markers for selecting male plants homozygous for the M gene.Communicated by G. Wenzel     

A high-density molecular map for ryegrass (Lolium perenne) using AFLP markers

AFLP markers have been successfully employed for the development of a high-density linkage map of ryegrass (Lolium perenne L.) using a progeny set of 95 plants from a testcross involving a doubled-haploid tester. This genetic map covered 930 cM in seven linkage groups and was based on 463 amplified fragment length polymorphism (AFLP) markers using 17 primer pairs, three isozymes and five EST markers. The average density of markers was approximately 1 per 2.0 cM. However, strong clustering of AFLP markers was observed at putative centromeric regions. Around these regions, 272 markers covered about 137 cM whereas the remaining 199 markers covered approximately 793 cM. Most genetic distances between consecutive pairs of markers were smaller than 20 cM except for five gaps on groups A, C, D, F and G. A skeletal map with a uniform distribution of markers can be extracted from this high-density map, and can be applied to detect and map QTLs. We report here the application of AFLP markers to genome mapping, in Lolium as a prelude to quantitative trait locus (QTL) identification for diverse agronomic traits in ryegrass and for marker-assisted plant breeding. Received: 4 November 1998 / Accepted:15 March 1999     

Genetic linkage maps of white birches (<Emphasis Type="Italic">Betula platyphylla</Emphasis> Suk. and <Emphasis Type="Italic">B. pendula</Emphasis> Roth) based on RAPD and AFLP markers

A pseudo-testcross mapping strategy was used in combination with the random amplified polymorphism DNA (RAPD) and amplified fragment length polymorphism (AFLP) genotyping methods to develop two moderately dense genetic linkage maps for Betula platyphylla Suk. (Asian white birch) and B. pendula Roth (European white birch). Eighty F₁ progenies were screened with 291 RAPD markers and 451 AFLP markers. We selected 230 RAPD and 362 AFLP markers with 1:1 segregation and used them for constructing the parent-specific linkage maps. The resultant map for B. platyphylla was composed of 226 markers in 24 linkage groups (LGs), and spanned 2864.5 cM with an average of 14.3 cM between adjacent markers. The linkage map for B. pendula was composed of 226 markers in 23 LGs, covering 2489.7 cM. The average map distance between adjacent markers was 13.1 cM. Clustering of AFLP markers was observed on several LGs. The availability of these white birch linkage maps will contribute to the molecular genetics and the implementation of marker-assisted selection in these important forest species.     

SCAR and CAPS mapping of CRb, a gene conferring resistance to Plasmodiophora brassicae in Chinese cabbage ( Brassica rapa ssp. pekinensis)

Clubroot disease, caused by Plasmodiophora brassicae Wor., is highly damaging for Chinese cabbage. The CR (clubroot resistant) Shinki DH (doubled haploid) line of Chinese cabbage carries a single dominant gene, CRb, which confers resistance to the P. brassicae races 2, 4, and 8. An F₂ population derived from a cross between the CR Shinki DH line and a susceptible line, 94SK, was used to map the CRb gene. Inoculation of F₃ families with SSI (single-spore isolate) resulted in a 1:2:1 segregation ratio. Use of the AFLP technique combined with bulked segregant analysis allowed five co-dominant AFLP markers, and four and seven dominant AFLP markers linked in coupling and repulsion, respectively, to be identified. Six of the 16 AFLP markers showing low frequencies of recombination with the CRb locus among 138 F₂ lines were cloned. A reliable conversion procedure allowed five AFLP markers to be successfully converted into CAPS and SCAR markers. An F₂ population (143 plants) was analyzed with these markers and a previously identified SCAR marker, and a genetic map around CRb covering a total distance of 6.75 cM was constructed. One dominant marker, TCR09, was located 0.78 cM from CRb. The remaining markers (TCR05, TCR01, TCR10, TCR08, and TCR03) were located on the other side of CRb, and the nearest of these was TCR05, at a distance of 1.92 cM.Communicated by R. Hagemann     

Identification of AFLP molecular markers for resistance against Melampsora larici-populina in Populus

We have identified AFLP markers tightly linked to the locus conferring resistance to the leaf rust Melampsora larici-populina in Populus. The study was carried out using a hybrid progeny derived from an inter-specific, controlled cross between a resistant Populus deltoides female and a susceptible P. nigra male. The segregation ratio of resistant to susceptible plants suggested that a single, dominant locus defined this resistance. This locus, which we have designated Melampsora resistance (Mer), confers resistance against E1, E2, and E3, three different races of Melampsora larici-populina. In order to identify molecular markers linked to the Mer locus we decided to combine two different techniques: (1) the high-density marker technology, AFLP, which allows the analysis of thousands of markers in a relatively short time, and (2) the Bulked Segregant Analysis (BSA), a method which facilitates the identification of markers that are tightly linked to the locus of interest. We analyzed approximately 11,500 selectively amplified DNA fragments using 144 primer combinations and identified three markers tightly linked to the Mer locus. The markers can be useful in current breeding programs and are the basis for future cloning of the resistance gene.     

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.