Technique / Molecular Biology / DNA analysis techniques / DNA fingerprinting

DNA fingerprinting (DNA testing, DNA typing, DNA profiling) is the DNA based identification technique for distinguishing between individuals of the same species.

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.

In this study, a total of 24 Listeria spp. strains were analyzed. Twenty-two isolates were obtained in San Luis (Argentina) from human, animal, and food samples. Two types of strains, Listeria monocytogenes CLIP 22762 and Listeria innocua CLIP 74915, were included as reference strains. All isolates were biochemically identified and characterized by serotyping, phage typing, and amplification of the flaA gene by polymerase chain reaction (PCR). Repetitive intergenic consensus (ERIC) sequence-based PCR was used to generate DNA fingerprints. On the basis of ERIC-PCR fingerprints, Listeria spp. strains were divided into three major clusters matching origin of isolation. ERIC-PCR fingerprints of human and animal isolates were different from those of food isolates. In addition, groups I and II included ten L. monocytogenes strains, and only one Listeria seeligeri strain. Group III included nine L. innocua strains and four L. monocytogenes strains. Computer evaluation of ERIC-PCR fingerprints allowed discrimination between the tested serotypes 1/2b, 4b, 6a, and 6b within each major cluster. The index of discrimination calculated was 0.94. This study suggests that the ERIC-PCR technique provides an alternative method for the identification of Listeria species and the discrimination of strains within one species.

We here analyze the population structure in the pig roundworm, Ascaris suum, among domestic pigs in Denmark using a whole-genome DNA fingerprinting technique, "amplified fragment length polymorphism" (AFLP) analysis. With these data, we can extract absolute gene frequency variance components and G-statistics for 135 independent nucleotide polymorphisms. The average proportion of total variance partitioned between Jutland and Zealand is less than 3% of the total variance, implying no restriction in gene flow between worms from different regions in Denmark. The average gene frequency difference between two farms widely separated in Jutland represents 5% of the total genetic variance of these two farms combined. Conversely, worms from different hosts within these two farms are more subdivided, with an average of 12% of the total variance in gene frequencies within farms being distributed between hosts. This result implies substantial single generation inbreeding due to founder effects in the establishment of adult worms in single hosts. Absolute variance components extracted from the gene diversities also showed significant differences, with the among-host variance being greater that the between-farm and between-region values. This little geographical variation is discussed in relation to the hierarchic structure of the Danish swine production system. Comparison of our results with other studies on parasitic roundworms, suggests that patterns of host dispersal effectively control patterns of worm gene flow. Furthermore, the potential spread of anthelminth resistance among A. suum may thus be rapid, due to the flow of infected hosts within the domestic swine stocks in Denmark.