The M13 repeat probe detects RFLPs between two strains of the protozoan malaria parasite Plasmodium falciparum

Linkage of two distinct AT-rich minisatellites at multiple loci in the genome of Theileria parva

Minisatellite tandem repeat elements are well known components of vertebrate genomes, but have not yet been extensively characterized in lower eukaryotes. We describe two unusual, AT-rich minisatellites of the protozoan parasite Theileria parva whose sequences are unrelated to the G/C-rich i minisatellite superfamily' of vertebrate and plant genomes. The T. parva tandem repeats, one with a conserved sequence T2-5ACACA (6-17 copies), and the other with a 6-bp core sequence of either ACTATA or TATACT associated with additional variable sequences in repeats of 10-17bp (3-7 copies), were closely linked at more than 20 sites in the T. parva genome, separated by 390, 510 and 660bp at three loci analysed in detail. Such linkage is without precedent in minisatellites so far analysed in other organisms. The minisatellite loci were widely dispersed on 13 out of 33 genomic SfiI fragments, on all four T. parva chromosomes and did not exhibit a telomeric bias in their distribution. Analysis of flanking sequences revealed no obvious conserved sequences between the five loci, or other multicopy repeat sequences outside the minisatellite regions. The T2-5 ACACA minisatellite was highly effective as a multilocus fingerprinting probe for discrimination of T. parva isolates. Analysis of two individual minisatellite loci revealed variation between the genomic DNAs of two T. parva isolates in the copy number of the constituent repeats within the array, similar to that typical of vertebrate minisatellites. 1998 Elsevier Science B.V.

Differences and similarities between various tandem repeat sequences: minisatellites and microsatellites

Tandemly repetitive DNA sequences are abundantly interspersed in the genome of practically all eukaryotic species studied. The relative occurrence of one type of repetitive sequence and its location in the genome appear to be species specific. A common property of repetitive sequences within the living world is their ability to give rise to variants with increased or reduced number of repeats. This instability depends upon numerous parameters whose exact role is unclear: the number of repeats, their sequence content, their chromosomal location, the mismatch repair capability of the cell, the developmental stage of the cell (mitotic or meiotic) and/or the sex of the transmitting parent. It is now apparent that mutations in repetitive sequences are a common cause of human disease, including cancer and disorders which may exhibit a dominant mode of inheritance. Two mechanisms have been proposed to explain the instability of repetitive sequences: DNA polymerase slippage, which may account for the instability of short repeats and unequal recombination which reshuffles repeat variants and maintains repeat heterogeneity in minisatellites. The purpose of this review is to show that no general rule can explain the instability of repetitive sequence. Each sequence of repeats is under the influence of local and general biological activities that determine its level of instability.

Detection of Genomic Polymorphism in Plasmodium falciparum using an arbitrarily primed PCR assay

Modifications of the arbitrarily primed polymerase chain reaction assay (i.e. a low annealing temperature and a very slow increase in the temperature during the elongation steps during the amplification cycles) allowed it to be used with the AT-rich Plasmodium falciparum DNA. The analysis of the products by polyacrylamide-urea gels, after silver staining, resulted in high resolution and sensitivity. Eighteen single and six combined pairs of arbitrary primers were tested. Two produced polymorphic patterns complex enough to differentiate between close Colombian isolates in a single assay. This method may be useful in studying the distribution and migration of strains in endemic areas, and for identifying intralaboratory cross-contamination of cultures.

DNA-based methods for the identification of insect vectors

Many insect vectors are members of complexes composed of morphologically identical sibling species. The identification of individual species, a requirement of epidemiological studies and control programmes, has traditionally relied upon techniques such as chromosomal analysis or isoenzyme typing. Owing to the limitations of these techniques, the last few years have seen many developments in DNA-based technologies for identification. DNA-based protocols have advantages over the other techniques utilized, in that they may identify all insect stages of both sexes using alcohol-preserved, dried, fresh or frozen specimens. The methods ultimately rely upon either DNA probe hybridization or the polymerase chain reaction (PCR). This review describes a number of approaches taken towards the development of these techniques. The aim of these approaches, whether directed or random, is to produce a methodology that is cheap, accurate and easy to use. In this review, the DNA-based techniques developed for the identification of Anopheles gambiae complex mosquitoes are used to illustrate the power of these methods, although, as the review demonstrates, the technology is directly applicable to many other mosquito or insect vectors. In addition, the methods discussed may be utilized for generating additional epidemiological data, such as identification of parasites within the vector or origin of the bloodmeal. A comprehensive survey of the probe systems available for the identification of insect vectors and the disease-causing organisms they transmit to the human population is therefore included. Given further advances in this technology, it may be anticipated that DNA-based approaches to identification may eventually supersede more traditional methodologies in the fields of tropical medicine and parasitology.

Population and species variation of minisatellite DNA in Plantago

Three Plantago species were surveyed for within- and between-population variation at DNA sequences detected with the M13 minisatellite probe. The levels and patterns of variation detected by this probe correspond to those expected from the mating systems of the species. The highly-selfing species P. major has a relatively low variability of minisatellite sequences within populations and considerable differentiation between populations. The outcrossing species P. lanceolata exhibits higher minisatellite variability within populations and moderate differentiation between populations. P. coronopus, with a mixed mating system, has levels of variation intermediate between P. major and P. lanceolata. The levels of variation within and between populations corresponds, in general, to the levels of allozyme variation determined in an earlier study. Mating system and population structure appear to have a major influence on M13-detected fragment variation.

DNA fingerprinting of Trypanosoma cruzi: a new tool for characterization of strains and clones

Using nonradioactive hybridization, the human multilocus probe 33.15 was shown to recognize multiple minisatellite regions in nuclear DNA from Trypanosoma cruzi, producing complex banding patterns on Southern blots, typical of DNA fingerprints. The DNA fingerprints were stable and were capable of identifying different strains of the parasite. Individual clones of the Y strain showed different banding patterns, demonstrating that the strain is heterogeneous. In general, the sensitivity and specificity of DNA fingerprinting was similar to that obtained with kinetoplast DNA restriction analysis. However, it has the advantages of being technically simple and of studying nuclear rather than mitochondrial DNA. Thus, it is a useful new tool for the characterization and study of strains and clones of Trypanosoma cruzi.

Mini- and micro-satellites in the genome of rodent malaria parasites

Higher eukaryotes contain within their DNA numerous arrays of repetitive DNA, many of which are known as satellite DNAs and display extensive variability. The presence of these repeats has been demonstrated for various species and they have been used for genetic identification and classification. Here, it is demonstrated that Southern hybridisation of DNA from rodent malaria parasites allows detection of micro- and minisatellite sequences in the genome of Plasmodium species. Closely related lines of malaria parasites exhibit a monomorphic hybridisation pattern, which is in contrast to the allelic variation observed in higher eukaryotes. Among different species, however, restriction-fragment length polymorphism was observed. Pulsed-field gel electrophoretic chromosome separation showed that the probes used in this study [33.15, 33.6, (CAC)n and (GT)n] detect several loci spread over different chromosomes.

DNA fingerprints: a tool for identification and determination of the relationships between species and strains of Leishmania

Using nonradioactive hybridization, the multilocal probes 33.15, F10 and (CAC)5 were shown to recognize multiple minisatellite regions in nuclear DNA of Leishmania, producing on Southern blots complex banding patterns typical of DNA fingerprints. We used the 33.15 probe to study 14 different strains belonging to 6 different species from both the sub-genus Viannia and the Leishmania mexicana complex of the sub-genus Leishmania. Distinct DNA fingerprints were obtained for each strain, permitting their identification. On the other hand, each strain showed little or no clonal variation. The information from the fingerprinting maps could be used for constructing phenograms and cladograms of the species and strains of Leishmania.

Typing of methicillin-resistant Staphylococcus aureus with an M13 repeat probe

A bacteriophage M13 tandem repeat has been used to probe EcoRI digested genomic DNA of methicillin-resistant Staphylococcus aureus (MRSA). The patterns generated were found to be useful in typing MRSA and generally confirmed the relationships that had previously been recognized in other studies based on antimicrobial resistance and plasmid profiles. The epidemic MRSA of London hospitals (EMRSA) and the majority of the epidemic MRSA of eastern Australian hospitals (EA MRSA) gave the same pattern. However, two isolates previously classified as EA MRSA gave a different pattern and a third another pattern. One isolate from Dublin, two isolates from Nuneaton and two isolates from Singapore gave the same pattern as the two EA MRSA. With the exception of the early or classic MRSA all the other isolates examined gave their own distinctive patterns. With one exception the classic MRSA belonged to a separate group. The exception was of particular interest because it gave the same pattern as the majority of the EA MRSA. This suggests that there may be an evolutionary relationship between some of the classic MRSA and the EMRSA of London and the EA MRSA of Australia.

Improved resolution and sensitivity of human DNA fingerprinting by specific-primed labelling of M13 DNA

A method to label M13 DNA probe by primer extension using a specific oligonucleotide primer is described. The method specifically labels the two 15-bp repeats in M13 DNA which hybridize to target DNA giving rise to DNA fingerprinting patterns. The M13 probe labelled by this method gave superior DNA fingerprinting patterns that that labelled by random primers. As little as 0.25 microgram of target DNA was sufficient for DNA fingerprinting. Non-isotopic labelling by the specific primer also showed improved DNA fingerprinting pattern. The results demonstrate the methodology to improve DNA fingerprinting based on M13 DNA probe.

Genome scanning by two-dimensional DNA typing: the use of repetitive DNA sequences for rapid mapping of genetic traits

The existence of repetitive DNA sequences offers the possibility to assess the mammalian genome for individual variation in its entirety rather than at one or only a few sites. In order to fully explore the various sets of mammalian repeat sequences for this purpose, analytical tools are required which allow many if not all individual members of sets of repetitive elements to be resolved and identified in terms of location and allelic variation. We have applied and further developed an electrophoretic system, two-dimensional DNA typing, which may fulfill these requirements. The two-dimensional system combines separation of DNA fragments by size in a neutral gel, with separation by sequence composition in a denaturing gradient gel. By hybridization with minisatellite- and simple-sequence core probes and by inter-repeat polymerase chain reaction techniques, it is possible to obtain individual--and even chromosome-specific separation patterns that consist of hundreds of spots. Computerized image analysis and matching of such spot patterns allows the rapid assessment of multiple polymorphisms, spread over the genome, to monitor genetic variability in populations. When coupled to databases of polymorphic DNA markers with a known genomic location, two-dimensional DNA typing can greatly accelerate the mapping of genetic traits in humans, animals, and plants.

DNA fingerprinting of the human intestinal parasite Giardia intestinalis with hypervariable minisatellite sequences

Individual isolates of the Giardia duodenalis group of protozoan intestinal parasites were identified by DNA fingerprinting with hypervariable minisatellite sequences. A morphologically identical parasite is found in some forty different animal species. Although the species name intestinalis is reserved for the human isolates, electrophoretic karyotyping suggests that most duodenalis isolates fall into the same species grouping. Distinction based upon morphology, restriction endonuclease cleavage of genomic DNA or isoenzyme analysis has not been adequate to identify individual strains. The successful use of hypervariable sequences in the identification of individual human genomes encouraged us to examine the use of these same sequences for the possible identification of parasite isolates. We initially use as a fingerprinting probe the genome of the bacteriophage M13, which has repeated sequences recognising homologous hypervariable sequences in the human genome. The M13 probe recognises a weakly homologous set of hypervariable sequences in Giardia. The number of informative bands is comparable to those seen in mammals, since the lower molecular weight bands are also useful. There is considerable divergence in the sequences of individual Giardia minisatellites. Some cloned Giardia hypervariable sequences are more homologous to M13 than they are to each other. Similar results were observed with the hypervariable repeat sequences 3' to the human alpha-globin gene when they were used as a probe to distinguish Giardia isolates. The poly(dA-dC).poly(dG-dT) probe which recognises frequent TG tracts in a number of organisms also detects a few variable bands amidst a hybridisation background in the Giardia genome. Thus Giardia isolates which could not be distinguished by restriction endonuclease cleavage, antibody typing or isoenzyme analysis have been identified by DNA fingerprinting procedures. Detailed analysis of strain movement, resurgence, variation, host range and drug resistance is now possible. Similar families of sequences may be widespread in lower eukaryotes and useful for generating individual specific fingerprints. A procedure for detecting individual parasites is also presented. Since Giardia is regarded as the most ancient eukaryote before the occurrence of symbiosis with purple non-sulphur bacteria to generate mitochondria, the identification of hypervariable sequences in the Giardia genome should also aid in understanding the mechanism of generation and evolution of these sequences.

Malaria and Leishmania parasites share the knob-associated histidine-rich protein gene sequences

1. The main coding region of the knob-associated histidine-rich protein (KAHRP) gene of Plasmodium falciparum hydridized with genomic DNA of Leishmania donovani. 2. A total of five EcoRI fragments of various sizes (7.5, 5.5, 3.2, 0.75 and 0.56 Kb) were recognized by this probe, under lower stringent conditions. However, under a higher stringency of washing, two of the smallest fragments were washed away. 3. Out of these EcoRI fragments, the 5.5 Kb band showed a maximum homology with the probe which contains the histidine-rich coding sequences, whereas the 3.2 Kb band showed none. Thus there is a possibility that the Leishmania parasite also contains a KAHRP-like gene.

The Caenorhabditis elegans genome contains monomorphic minisatellites and simple sequences

Many species have been shown to contain tandemly repeated short sequence DNA known as minisatellites and simple sequence motifs. Due to allelic variation in the copy number of the repeat unit these loci are usually highly polymorphic. Here we demonstrate the presence of sequences in the genome of the nematode Caenorhabditis elegans which are homologous to two sets of short sequence DNA. However, when two independent strains were compared no polymorphism for these sequences could be detected.

Hypervariable minisatellites: recombinators or innocent bystanders?

It has become apparent in recent years that unexpectedly large numbers of minisatellites exist within the eukaryotic genome. Their use in genetics is well known, but as with any new class of sequence, there is also much speculation about their involvement in a range of biological processes. How much is known of their biology?