DNA fingerprinting techniques for microorganisms

A whole array of DNA-fingerprinting techniques, which provide indirect access to DNA sequence polymorphism in order to assess species or clonal identity of bacterial organisms or in order to study bacterial genome composition, have been described during past decades. Nomenclature has been sometimes erroneous and/or confusing, also because of hybrid techniques that combine different approaches. It can be shown that most techniques study the sequence polymorphism of only the chromosome, or only the plasmid(s) or only a gene or gene fragment and that the sequence polymorphism is revealed by AFLP (amplified fragment length polymorphism) or by RFLP (restriction fragment length polymorphism) or by special electrophoresis techniques. Starting from these considerations, some taxonomy of techniques, which enables more appropriate nomenclature, can be developed.     

DNA fingerprinting in clonal organisms

The use of DNA fingerprinting to identify members of the same clone in completely or partially asexual organisms requires that the individuals within a clone share a recent common ancestor. By considering the expected distributions of band–sharing values in asexual and sexual organisms, it is shown that DNA fingerprinting may be effective in distinguishing members of the same clone, provided that the frequency of sexual reproduction is considerably greater than the minisatellite mutation rate.     

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.     

DNA fingerprinting in non-human populations

DNA fingerprinting of non-human populations is beginning to fulfill its early promise, and in the past year there has been a flush of papers on mammalian breeding systems. However, many people, particularly field workers, believe that progress in this area has been slow. Attention is now focused on two amenable alternatives: microsatellite polymorphisms and randomly amplified polymorphic DNA. Of these, it is probable that microsatellites hold the key to rapid, efficient and highly informative screening of the genetic variability that exists within natural populations.     

AFLP: a new technique for DNA fingerprinting.

A novel DNA fingerprinting technique called AFLP is described. The AFLP technique is based on the selective PCR amplification of restriction fragments from a total digest of genomic DNA. The technique involves three steps: (i) restriction of the DNA and ligation of oligonucleotide adapters, (ii) selective amplification of sets of restriction fragments, and (iii) gel analysis of the amplified fragments. PCR amplification of restriction fragments is achieved by using the adapter and restriction site sequence as target sites for primer annealing. The selective amplification is achieved by the use of primers that extend into the restriction fragments, amplifying only those fragments in which the primer extensions match the nucleotides flanking the restriction sites. Using this method, sets of restriction fragments may be visualized by PCR without knowledge of nucleotide sequence. The method allows the specific co-amplification of high numbers of restriction fragments. The number of fragments that can be analyzed simultaneously, however, is dependent on the resolution of the detection system. Typically 50-100 restriction fragments are amplified and detected on denaturing polyacrylamide gels. The AFLP technique provides a novel and very powerful DNA fingerprinting technique for DNAs of any origin or complexity.     

Evidence of transmission of tuberculosis by DNA fingerprinting.

OBJECTIVE--To determine whether a subject who had died of tuberculous meningitis had been infected by a neighbour. DESIGN--Retrospective comparison of isolates of Mycobacterium tuberculosis from the two cases and from 10 controls by DNA fingerprinting. SETTING--Public Health Service Reference Laboratory for Mycobacteria and bacterial molecular genetics unit of the London School of Hygiene and Tropical Medicine. SUBJECTS--Deceased and neighbour; 10 controls from the same city, from whom isolates had been collected over three months before the subject''s death. MAIN OUTCOME MEASURES--Identity and similarity values (SAB) between fingerprint patterns from different isolates obtained by hybridisation of restriction fragments produced by PvuII with a probe from the insertion element IS6110/986, present in multiple copies throughout the genome of M tuberculosis. RESULTS--Isolates from the two cases under investigation had identical fingerprints whereas those from the controls were all distinct. Two clusters of isolates with a similarity coefficient > 0.25 were identified: in one, four out of five patients were born in the midlands (the birth place of the fifth was not known) and in the other all three patients were born in the Indian subcontinent. CONCLUSIONS--The data are consistent with, but do not prove, transmission of tuberculosis from the neighbour to the deceased. Geographical separation of the pools of infection may have led to the evolution of distinct clusters of fingerprint patterns. DNA fingerprinting of M tuberculosis is a powerful new tool for study of the epidemiology and pathogenesis of tuberculosis.     

Forensic applications of DNA fingerprinting

In many ways, DNA profiling technology is very similar to the conventional techniques used for forensic identification. As with, for example, blood grouping techniques, the molecular characteristics of the scene of crime sample may be determined and compared with those of the scene of reference samples from suspects and victim. If the molecular characteristics of the crime sample and the suspect are different, then they cannot be from the same person, whereas if they match, then the possibility remains that they may be from a single source. Similar material, such as blood or semen stains, may be used for both biochemical and genetic tests, and the main applications of identification and relationship testing are shared by both techniques. At this point, the similarity ends; DNA profiling has the following characteristics:

1. It is more sensitive, being able to generate sound data from only a tiny amount of even partially degraded biological material.
2. It is capable of resolving mixtures of semen or tissue from up to several individuals.
3. It has a far greater power of discrimination between individuals—sometimes up to 1 millionfold higher than conventional techniques.
4. It provides considerably more information on the nature of relationships, particularly in cases of incest.

As such, the technique represents a quantum leap in forensic identification and relationship testing.     

DNA amplification fingerprinting of bacteria

Summary We have amplified short arbitrary stretches of total bacterial DNA to produce highly characteristic and complex DNA fingerprints. This DNA amplification fingerprinting (DAF) strategy involves enzymatic amplification of DNA directed by a single arbitrary oligonucleotide primer. Amplification produces a characteristic spectrum of products that is adequately resolved by polyacrylamide gel electrophoresis and visualized by silver staining. Although DAF is simple in concept, we found that amplification parameters must be within an optimal range for reproducibility. We establish a safe window for these parameters, which include magnesium, primer and enzyme concentration as well as cycle number. The refined procedure was used to distinguish between clinical isolates of Streptococcus uberis, Klebsiella pneumoniae, and Escherichia coli. The use of template DNA concentrations higher than 1 ng·l^–1 and high MgCl₂ levels was especially important for reproductibility when amplifying small bacterial genomes. We tested a truncated Thermus aquaticus DNA polymerase, the Stoffel fragment, and found it more tolerant of reaction conditions, more efficient in the amplification of short products, and able to produce more informative fingerprints when compared to the normal thermostable polymerase from which it was derived. Because DAF produces representative fingerprints quickly and reliably from bacteria regardless of prior genetic or biochemical knowledge, we anticipate the general use of this diagnostic tool for bacterial identification and taxonomy.Correspondence to: G. Caetano-Anollés     

Protein identification in DNA databases by peptide mass fingerprinting.

Proteins can be identified using a set of peptide fragment weights produced by a specific digestion to search a protein database in which sequences have been replaced by fragment weights calculated for various cleavage methods. We present a method using multidimensional searches that greatly increases the confidence level for identification, allowing DNA sequence databases to be examined. This method provides a link between 2-dimensional gel electrophoresis protein databases and genome sequencing projects. Moreover, the increased confidence level allows unknown proteins to be matched to expressed sequence tags, potentially eliminating the need to obtain sequence information for cloning. Database searching from a mass profile is offered as a free service by an automatic server at the ETH, Zürich. For information, send an electronic message to the address cbrg/inf.ethz.ch with the line: help mass search, or help all.     

Probing identity: the changing face of DNA fingerprinting.

DNA-fingerprinting technology has made a very rapid transition from being a research laboratory discovery to an applied science widely understood by, and of interest to, the general public. However, DNA fingerprinting is often portrayed as being a single generic technology, rather than a complex evolving mixture of methodologies, where specific applications demand selection of appropriate probes and techniques.