Amplified fragment length polymorphism (AFLP): a review of the procedure and its applications

Amplified fragment length polymorphism (AFLP) is a novel molecular fingerprinting technique that can be applied to DNAs of any source or complexity. Total genomic DNA is digested using two restriction enzymes. Double-stranded nucleotide adapters are ligated to the DNA fragments to serve as primer binding sites for PCR amplification. Primers complementary to the adapter and restriction site sequence, with additional nucleotides at the 3′-end, are used as selective agents to amplify a subset of ligated fragments. Polymorphisms are identified by the presence or absence of DNA fragments following analysis on polyacrylamide gels. This technique has been extensively used with plant DNA for the development of high-resolution genetic maps and for the positional cloning of genes of interest. However, its application is rapidly expanding in bacteria and higher eukaryotes for determining genetic relationships and for epidemiological typing. This review describes the AFLP procedure, and recent, novel applications in the molecular fingerprinting of DNA from both eukaryotic and prokaryotic organisms. Received 19 December 1997/ Accepted in revised form 3 June 1998     

AFLP分子标记技术及其在动物学研究中的应用

扩增片段长度多态性技术(AFLP)基于选择性扩增完全酶切消化后的基因组DNA片段,包括酶切与连接、选择性扩增、检测分析等3个步骤。该技术的运用不需要预知基因组的序列特征,具有较高的多态分辨力,产生的标记是显性标记,可适用于任何来源和各种复杂度的DNA。自AFLP技术问世以来,在酶切、扩增体系、检测和分析方法等方面不断得到改进。本文将以线虫、昆虫、鱼类、鸟类、家畜、鼠、人等为例,介绍近年来AHLP技术在动物或人的遗传图谱构建和QTL(quantitative trait loci)定位、生物多样性、性别决定和繁殖行为研究、疾病及疾病诊断研究等上的应用。     

AFLP technology for DNA fingerprinting

The AFLP technique is a powerful DNA fingerprinting technology applicable to any organism without the need for prior sequence knowledge. The protocol involves the selective PCR amplification of restriction fragments of a total digest of genomic DNA, typically obtained with a mix of two restriction enzymes. Two limited sets of AFLP primers are sufficient to generate a large number of different primer combinations (PCs), each of which will yield unique fingerprints. Visualization of AFLP fingerprints after gel electrophoresis of AFLP products is described using either a conventional autoradiography platform or an automated LI-COR system. The AFLP technology has been used predominantly for assessing the degree of variability among plant cultivars, establishing linkage groups in crosses and saturating genomic regions with markers for gene landing efforts. AFLP fragments may also be used as physical markers to determine the overlap and positions of genomic clones and to integrate genetic and physical maps. Crucial characteristics of the AFLP technology are its robustness, reliability and quantitative nature. This latter feature has been exploited for co-dominant scoring of AFLP markers in sample collections such as F2 or back-cross populations using appropriate AFLP scoring software. This protocol can be completed in 2-3 d.     

Genomic typing of Escherichia coli O157:H7 by semi-automated fluorescent AFLP analysis

Escherichia coli serotype O157:H7 isolates were analyzed using a relatively new DNA fingerprinting method, amplified fragment length polymorphism (AFLP). Total genomic DNA was digested with two restriction endonucleases (EcoRI and MseI), and compatible oligonucleotide adapters were ligated to the ends of the resulting DNA fragments. Subsets of fragments from the total pool of cleaved DNA were then amplified by the polymerase chain reaction (PCR) using selective primers that extended beyond the adapter and restriction site sequences. One of the primers from each set was labeled with a fluorescent dye, which enabled amplified fragments to be detected and sized automatically on an automated DNA sequencer. Three AFLP primer sets generated a total of thirty-seven unique genotypes among the 48 E. coli O157:H7 isolates tested. Prior fingerprinting analysis of large restriction fragments from these same isolates by pulsed-field gel electrophoresis (PFGE) resulted in only 21 unique DNA profiles. Also, AFLP fingerprinting was successful for one DNA sample that was not typable by PFGE, presumably because of template degradation. AFLP analysis, therefore, provided greater genetic resolution and was less sensitive to DNA quality than PFGE. Consequently, this DNA typing technology should be very useful for genetic subtyping of bacterial pathogens in epidemiologic studies.     

应用限制性显示PCR技术构建细菌poly(A)化mRNA的cDNA文库

针对细菌mRNA poly(A)化位点的高度多态性,利用oligo(dT)与poly(A)特异结合的特性,以oligo(dT)一纤维素纯化mRNA,并以oligo(dT)18为引物逆转录合成cDNA,用限制性内切酶消化cDNA,所得的限制性内切酶片段与通用接头相连,通过10个选择性引物组合进行选择性PCR,使各片段得以扩增并分布于10个亚组中,并进行克隆,成功地克隆了100多个基因片段,已对其中40个进行了测序分析,探讨了限制性显示PCR技术在细菌poly(A)化mRNA cDNA库构建中的应用价值。     

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     

AFLP™ markers for DNA fingerprinting in cattle

This work reports on use of the recently described amplified fragment length polymorphism (AFLP) technology for DNA fingerprinting in cattle. The AFLP technology produces molecular markers through the high-stringency polymerase chain reaction (PCR)-amplification of restriction fragments that are ligated to synthetic adapters and amplified using primers, complementary to the adapters, which carry selective nucleotides at their 3' ends. While, for plants, the double digestion of genomic DNA with Eco RI and Mse I is suggested, in mammals the enzyme combination Eco RI/ Taq I produces clearer and more polymorphic AFLP patterns. In a sample of 47 Italian Holstein genotypes, 16 Eco RI/ Taq I primer combinations identified 248 polymorphic bands in a species known for its low level of restriction polymorphism. In spite of the low information content carried by each AFLP polymorphism (average polymorphism information content = 0·31), the number of fragments revealed by each primer combination increased significantly the level of genetic information gained in each experiment. AFLP patterns are reproducible in independent experiments and polymorphic fragments segregate in cattle families according to Mendelian rules.     

DNA fingerprinting based on microsatellite-anchored fragment length polymorphisms,and isolation of sequence-specific PCR markers in lupin (Lupinus angustifolius L.)

We report a method of microsatellite-anchored fragment length polymorphisms for DNA fingerprinting. The method combines the concept of AFLP and the microsatellite-anchor primer technique. Genomic DNA was digested by one restriction enzyme MseI. One AFLP adaptor (MseI adaptor) was ligated onto the restriction fragments. DNA fingerprints were produced by PCR using one microsatellite-anchor primer in combination with one MseI-primer. The method allows co-amplification of over 100 DNA fragments containing microsatellite motifs per PCR. Polymorphisms detected from lupin by this method included those arising from variation in the number of microsatellite repeat units targeted by the microsatellite-anchor primers, from variation on the annealing sites for the SSR-anchor primers, from insertions/deletions outside the SSR region, and from variation in restriction sites. The first three types of polymorphisms were readily converted into sequence-specific PCR markers suitable for marker-assisted breeding.     

DNA sequencing by a subcloning-walking strategy using a specific and semi-random primer in the polymerase chain reaction.

In its basic concept, in vitro DNA amplification by the polymerase chain reaction (PCR) is restricted to those instances in which segments of known sequence flank the fragment to be amplified. Recently, techniques have been developed for amplification of unknown DNA sequences. These techniques, however, are dependent on the presence of suitable restriction endonuclease sites. Here, we describe a strategy for PCR amplification of DNA that lies outside the boundaries of known sequence. It is based on the use of one specific primer, homologous to the known sequence, and one semi-random primer. Restriction sites in the 5' proximal regions of both primers allow for cloning of the amplified DNA in a suitable sequencing vector or any other vector. It was shown by sequence analysis that the cloned DNA fragments represent contiguous DNA fragments that are flanked at one side by the sequence of the specific primer. When omitting the semi-random primer, a single clone was obtained, which originated from PCR amplification of target DNA by the specific primer in both directions.     

Single-enzyme amplified fragment length polymorphism and its applicability for Salmonella epidemiology

Amplified fragment length polymorphism (AFLP) is a PCR-based DNA fingerprinting technique whereby restriction fragments may be visualized without prior knowledge of nucleotide sequences. In AFLP analysis, bacterial genomic DNA is digested with a restriction enzyme and ligated to adapter oligonucleotides. A subset of DNA fragments are then amplified using primers which contain adapter-defined sequences. Selective amplification is achieved by the use of primers containing adapter-defined sequences with one additional arbitrary nucleotide. We used four primers complementary to the adapter sequence, but each differing in the final 3' base that extended into the fragment DNA. The usefulness of these primers for fingerprinting Salmonella enterica was assessed in a hierarchical manner. Using a single-enzyme approach (SAFLP) we have used this method to fingerprint 30 strains of S. enterica, belonging to 14 different serotypes. SAFLP profiles derived from Hind III fragments differentiated between the serotypes. In addition, SAFLP profiles for each serotype differentiated between the phage types and individual strains. The technique is significantly faster to perform than other DNA-based methods and has given reproducible and discriminatory results. This hierarchical SAFLP technique may provide a valuable addition to existing methods for the DNA fingerprinting of S. enterica for epidemiological studies.     

High-resolution genotyping of Salmonella strains by AFLP-fingerprinting

High resolution AFLP fingerprinting, in which subsets of genomic restriction fragments are amplified by means of PCR, was used for the identification of different Salmonella serotypes to investigate whether this technique is applicable in epidemiological studies. Seventy-eight different Salmonella strains comprising 62 serotypes were genetically identified by AFLP. Primer combination M00 ( Mse I primer without additional 3' nucleotides) and E11 ( Eco RI primer with two additional 3' nucleotides) resulted in reproducible profiles containing approximately 50 bands. All serotypes were characterized by a unique profile. In addition, AFLP fingerprinting enabled phage type identification. Different strains previously identified as identical, using typing methods with lower resolution, could be distinguished, showing that AFLP fingerprinting is well suited for bacterial epidemiology and identification.     

A format for databasing and comparison of AFLP fingerprint profiles

Background  

Amplified fragment length polymorphism (AFLP) is a PCR-based technique that involves restriction of genomic DNA followed by ligation of adaptors to the fragments generated and selective PCR amplification of a subset of these fragments. The amplified fragments are separated on a sequencing gel and visualized by autoradiography or fluorescent sequencing equipment. AFLP allows high-resolution genotyping but the lack of a format for databasing and comparison of AFLP fingerprint profiles limits its wider applications in profiling large numbers of biological samples.     

New molecular screening tools for analysis of free-living diazotrophs in soil

Free-living nitrogen-fixing prokaryotes (diazotrophs) are ubiquitous in soil and are phylogenetically and physiologically highly diverse. Molecular methods based on universal PCR detection of the nifH marker gene have been successfully applied to describe diazotroph populations in the environment. However, the use of highly degenerate primers and low-stringency amplification conditions render these methods prone to amplification bias, while less degenerate primer sets will not amplify all nifH genes. We have developed a fixed-primer-site approach with six PCR protocols using less degenerate to nondegenerate primer sets that all amplify the same nifH fragment as a previously published PCR protocol for universal amplification. These protocols target different groups of diazotrophs and allowed for direct comparison of the PCR products by use of restriction fragment length polymorphism fingerprinting. The new protocols were optimized on DNA from 14 reference strains and were subsequently tested with bulk DNA extracts from six soils. These analyses revealed that the new PCR primer sets amplified nifH sequences that were not detected by the universal primer set. Furthermore, they were better suited to distinguish between diazotroph populations in the different soils. Because the novel primer sets were not specific for monophyletic groups of diazotrophs, they do not serve as an identification tool; however, they proved powerful as fingerprinting tools for subsets of soil diazotroph communities.     

New Molecular Screening Tools for Analysis of Free-Living Diazotrophs in Soil

Free-living nitrogen-fixing prokaryotes (diazotrophs) are ubiquitous in soil and are phylogenetically and physiologically highly diverse. Molecular methods based on universal PCR detection of the nifH marker gene have been successfully applied to describe diazotroph populations in the environment. However, the use of highly degenerate primers and low-stringency amplification conditions render these methods prone to amplification bias, while less degenerate primer sets will not amplify all nifH genes. We have developed a fixed-primer-site approach with six PCR protocols using less degenerate to nondegenerate primer sets that all amplify the same nifH fragment as a previously published PCR protocol for universal amplification. These protocols target different groups of diazotrophs and allowed for direct comparison of the PCR products by use of restriction fragment length polymorphism fingerprinting. The new protocols were optimized on DNA from 14 reference strains and were subsequently tested with bulk DNA extracts from six soils. These analyses revealed that the new PCR primer sets amplified nifH sequences that were not detected by the universal primer set. Furthermore, they were better suited to distinguish between diazotroph populations in the different soils. Because the novel primer sets were not specific for monophyletic groups of diazotrophs, they do not serve as an identification tool; however, they proved powerful as fingerprinting tools for subsets of soil diazotroph communities.     

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.     

A strategy for single site PCR amplification of dsDNA: priming digested cloned or genomic DNA from an anchor-modified restriction site and a short internal sequence

Amplification of dsDNA by polymerase chain reaction (PCR) has been limited to those instances in which segments of known sequence flank the fragment to be amplified. A strategy for the PCR amplification of cloned or genomic dsDNA that necessitates sequence information from only a single short segment (single site PCR) has been devised. The region of known sequence may be located at any position within or adjacent to the segment to be amplified. The basic procedure for amplification consists of 1) digestion of dsDNA with one or more restriction enzymes, 2) ligation with a universal anchor adaptor and 3) PCR amplification using an anchor primer and the primer for the single site of known sequence. The anchor adaptor is designed in such a way as to facilitate the amplification of only those fragments containing the sequence of interest. We have demonstrated the utility of this technique by specifically amplifying and directly sequencing antibody variable region genes from cloned dsDNA and from genomic DNA.     

Optimization of AFLP fingerprinting of organisms with a large-sized genome: a study on Alstroemeria spp.

 The recently introduced PCR-based DNA fingerprinting technique AFLP (amplified fragment length polymorphism) allows the selective amplification of subsets of genomic restriction fragments. AFLP has been used for multiple purposes such as the construction of linkage maps, marker saturation at specific genomic regions, analysis of genetic diversity and molecular phylogeny and cultivar identification. AFLP can be tailored by varying the number of selective nucleotides added to core primers and can allow accurate amplification, even in complex template mixtures generated from plant species with very large genomes. In this study Alstroemeria, a plant species with a very large genome, was tested for adapting the AFLP protocol. The results indicated that the estimated number of amplification products was close to the observed number when eight selective nucleotides were used but that seven selective nucleotides did not increase the number of amplification products fourfold. However, we found reproducibility in both +7 and +8 fingerprints. Various distributions of selective nucleotides over the various rounds of preamplifications were tested. Preamplification with four selective nucleotides followed by final amplification with eight selective nucleotides produced clear and reproducible AFLP patterns. The effects of GC content of primers and multiple preamplification steps were also discussed. Received: 16 March 1998 / Accepted: 14 July 1998     

Rapid amplification of genomic DNA ends bynla III partial digestion and polynucleotide tailing

We report a simple and efficient method, which combines restriction endonuclease digestion and deoxynucleotide tailing, for cloning unknown genomic sequences adjacent to a known sequence. Total genomic DNA is partially digested with the frequent-cutting restriction enzymeNla III. A homo-oligomeric cytosine tail is added by terminal transferase. The tailed DNA fragments are used as the template for cloning flanking regions from all sequences of interest. A first round PCR amplification is performed with a gene-specific primer and the selective (modified polyguanine) anchor primer complementary to the cytosine tail and theNla III recognition site, with a universal amplification primer sequence at its 5′ end. This is followed by another PCR amplification with a nested gene-specific primer and the universal amplification primer. Finally, the amplified products are fractionated, cloned, and sequenced. Using this method, we cloned the upstream region of a salt-induced gene based upon a partial cDNA clone (RSC5-U) obtained from sunflower (Helianthus annuus L.).     

ATG-anchored AFLP (ATG-AFLP) analysis in cotton

Amplified fragment length polymorphism (AFLP) marker system has had broad applications in biology. However, the anonymous AFLP markers are mainly amplified from non-coding regions, limiting their usefulness as a functional marker system. To take advantages of the traditional AFLP techniques, we propose substitution of a restriction enzyme that recognizes a restriction site containing ATG, called ATG-anchored AFLP (ATG-AFLP) analysis. In this study, we chose NsiI (recognizing ATGCAT) to replace EcoRI in combination with MseI to completely digest genomic DNA. One specific adaptor, one pre-selective primer and six selective amplification primers for the NsiI site were designed for ligation and PCR. Six NsiI and eight MseI primers generated a total of 1,780 ATG-AFLP fragments, of which 750 (42%) were polymorphic among four genotypes from two cultivated cotton species (Upland cotton, Gossypium hirsutum and Pima cotton, G. barbadense). The number of ATG-AFLP markers was sufficient to separate the four genotypes into two groups, consistent with their evolutionary and breeding history. Our results also showed that ATG-AFLP generated less number of total and polymorphic fragments per primer combination (2-3 vs. 4-5) than conventional AFLP within Upland cotton. Using a recombination inbred line (RIL) population, 62 polymorphic ATG-AFLP markers were mapped to 19 linkage groups with known chromosome anchored simple sequence repeat (SSR) markers. Of the nine ATG-AFLP fragments randomly chosen, three were found to be highly homologous to cotton cDNA sequences. An in-silico analysis of cotton and Arabidopsis cDNA confirmed that the ATG-anchored enzyme combination NsiI/MseI did generate more fragments than the EcoRI/MseI combination.