Identification of species, strains and clones of Leishmania by characterization of kinetoplast DNA minicircles

Molecular analysis of kinetoplast deoxyribonucleic acid (kDNA) minicircles has permitted the genotypic characterization of pathogenic isolates of Leishmania species. The apparent size in agarose gels of unit-length minicircles released by EcoRI digestion of kDNA networks is not conserved during speciation in this genus since the minicircles of strains and clones of L. major are smaller (710 base pairs, bp) than those found in certain strains of L. mexicana subspecies (820 bp), L. donovani (825, 865 bp) or L. tropica (900, 930 bp). EcoRI-cut minicircles within any one species of Leishmania are heterogeneous in mobility during electrophoresis in acrylamide gels. Schizodeme analysis of minicircles reveals a high degree of sequence divergence in kDNA with the degree of microheterogeneity varying between species. This sequence divergence allows the discrimination of closely related clones and strains within a given species. Southern blot hybridization reveals that overall minicircle sequence homology is conserved among clones and strains of one species (L. major or L. tropica) but not between different species. This property of minicircle DNA permits the use of kDNA probes as a species-specific diagnostic test for the identification of Leishmania isolates. The analysis of kDNA from two L. tropica strains isolated at 14 year intervals from a patient with leishmaniasis recidivans has shown that the two strains are closely related, suggesting that the individual suffered the cutaneous disease as a result of a resurgence of the same parasite which caused the initial infection. The differences in the properties of kDNA from the L. tropica and L. major strains studied support the taxonomic separation of L. tropica and L. major into distinct species.     

Biochemical identification of cutaneous leishmanias by analysis of kinetoplast DNA. II. Sequence homologies in Leishmania kDNA

Kinetoplast DNA (kDNA) has been isolated from the human cutaneous Leishmania isolates, L. tropica major, L. aethiopica and an unknown Kenyan isolate, Leishmania SP48. DNA sequence relationships among these isolates have been studied by restriction enzyme digestion and two phase hybridisation to Southern blots of kDNA covalently coupled to diazobenzyloxymethyl (DBM) paper. The results of this analysis confirm that rapid kDNA sequence evolution is occurring in the Old World leishmanias although some sequence conservation in defined regions of the mini-circle sequence is present. These results emphasise the danger of constructing a rigid Leishmania classification on buoyant density data alone. The covalent binding of kDNA electrophoretic separations to DBM paper permits the construction of a DNA sequence "library' which can be used in the classification and diagnosis of unknown Leishmania isolates.     

Generation of species-specific DNA probes for Leishmania aethiopica

We report here the cloning of kinetoplast DNA (kDNA) sequences from Leishmania aethiopica in order to develop a specific and sensitive method for the identification of the parasite. Analysis of the cloned kDNA sequences showed different taxonomic specificities demonstrating sequence diversity within the kinetoplast DNA. Cloned whole minicircle hybridized with all Old World Leishmania species tested. Some cloned fragments of minicircle kDNA hybridized with Leishmania species causing cutaneous leishmaniasis in the Old World, but not with the viscerotropic species. Two L. aethiopica-specific clones were found. These clones hybridized with all L. aethiopica isolates tested, but did not react with other Leishmania species. The nucleotide sequence of the L. aethiopica-specific R3 clone is presented. Clones hybridizing with only some of the L. aethiopica isolates were also identified, although none of them showed specificity only for isolates causing localized (LCL) or diffuse (DCL) form of cutaneous leishmaniasis in Ethiopia.     

A kinetoplast DNA probe diagnostic for Leishmania major: sequence homologies between regions of Leishmania minicircles

A restriction fragment from a cloned kinetoplast minicircle DNA has been shown to be diagnostic for Leishmania major. This 402-bp TaqI fragment has been used routinely (as a radiolabelled probe) to detect 10(4) parasites in simple dot blots, both experimentally and in epidemiological surveys. It positively identified all stocks of L. major tested (including all six known zymodemes) and showed very low homology to kinetoplast DNA (kDNA) and chromosomal DNA of Leishmania infantum and Leishmania tropica, two species commonly isolated from patients and wild hosts within foci of L. major in the Old World. DNA sequence analysis of a minicircle of L. major is reported for the first time, and it is demonstrated that this species shares with Leishmania aethiopica, Sauroleishmania tarentolae and several species of Trypanosoma a region of conserved sequence that is involved in DNA replication, a process that could present targets for selective chemotherapeutic attack. Sequence and restriction fragment analyses have indicated the difficulties of selecting species-specific sequences from kDNA which, even in the same parasite clone, contains several predominant minicircle classes, not all of which contain diagnostic sequences.     

Further studies and electron microscopic characterization of Plasmodium berghei DNA

The average length and the interspersion pattern of repetitive DNA sequences in the Plasmodium berghei genome have been studied by electron microscopy. Within the limitations posed by the relatively high genome complexity, analysis of partially renatured total DNA indicates that repetitive sequences do not occupy preferential positions along the genome, but are widely dispersed (one in approx. 8000 base pairs of unique DNA). Structures appearing as loops flanked by inverted repeats are present. Analysis of the repetitive fraction purified by hydroxyapatite chromatography shows that the average length of rapidly reassociating repetitive structures is around 800 base pairs with 90% of the length distribution between 400 and 1400 base pairs. Suitable extraction methods, preserving circularity of extrachromosomal DNA components, allow the detection of molecules which can be identified as mitochondrial DNA, 10.5 +/- 0.4 microns long.     

Isolation and characterization of DNA from Tritrichomonas foetus and Trichomonas vaginalis

High molecular weight DNA samples free of contaminating proteins or RNA were obtained from Tritrichomonas foetus or Trichomonas vaginalis by lysing the cells in 4 M guanidinium thiocyanate before centrifuging in CsCl density gradient and then purifying the DNA band by NACS-37 column chromatography. The bulk DNA from either organism acted as a single component in ion-exchange chromatography, agarose gel electrophoresis, CsCl density gradient centrifugation and thermal denaturation. T. foetus DNA showed a melting temperature (Tm) of 82 degrees C corresponding to a 31% GC content whereas T. vaginalis DNA melted at 84 degrees C to suggest 36% GC. Both DNA samples demonstrated 35 to 42% hyperchromicity when fully melted. Cot analysis revealed the presence of repetitive sequences in both DNAs: approximately 46.7% in T. foetus DNA and 53.3% in T. vaginalis DNA. The unique sequences of these two protozoan DNAs are of a similar size of about 2.5 X 10(7) base pairs. Agarose gel electrophoresis of restriction fragments of the two purified DNA samples gave distinct banding patterns that were characteristic of the two species of protozoan parasites.     

Identification of 'Old World' Leishmania by DNA recombinant probes

Leishmania are usually identified by iso-enzyme analysis. This method works well, but there is a need for an additional, more simple, method of identification. Here we present data that show that in a Southern blot analysis, recombinant DNA probes in combination with certain restriction enzymes can differentiate between taxa of Leishmania. Probes based on clones selected from a L. infantum cDNA library gave characteristic patterns on Southern blots for reference strains of the different types of Leishmania found in Europe, Africa and Asia. Within the different taxa little or no variation was observed. Although the L. infantum derived probes showed a somewhat stronger hybridization for strains of the L. donovani complex, the signal obtained with most probes was satisfactory for L. major, L. aethiopica and L. tropica. Within the L. donovani complex none of the selected probes differentiated between isolates belonging to L. infantum, L. chagasi or L. donovani. Probes containing kinetoplast DNA showed considerable variation in hybridization within a taxon.     

Further analysis of intraspecific variation in Trypanosoma brucei using restriction site polymorphisms in the maxi-circle of kinetoplast DNA

We have compared the maxi-circle kinetoplast DNA of 21 Trypanosoma brucei sp. stocks by analysis of restriction sites for nine restriction endonucleases. The analysis shows most of these stocks to have a maxi-circle sequence similar to that of 11 previously analysed stocks, with a difference of less than 3% between any two stocks. However, seven stocks stand out from the rest with at least two sites lost or gained for six of the nine restriction enzymes used. These seven distinctive stocks fall into two groups with some shared and some unique polymorphisms. One group had already been designated the kiboko group on the basis of isoenzyme patterns, but the relationship between nuclear markers and maxi-circle type is less clear-cut for the other group, designated sindo. Both groups seem to be in a wild animal-tsetse fly transmission cycle, with occasional infections in domestic stock, and may be reproductively isolated from the main T. brucei sp. population. The existence of the kiboko and sindo sub-groups shows that the maxi-circle is not shielded from evolutionary change. The lack of difference observed between the maxi-circles of the majority of T. brucei sp. stocks, including the gambiense and rhodesiense variants, must therefore reflect their close homology. Two geographical trends occur in T. brucei as a whole: (a) a trend in maxi-circle size, with increasing length of the variable region from West to East Africa, and (b) a greater frequency of certain restriction enzyme polymorphisms in East African stocks as compared to West African stocks.     

Molecular karyotype and chromosomal localization of genes encoding two major surface glycoproteins, gp63 and gp46/M2, hsp70, and beta-tubulin in cloned strains of several Leishmania species.

The molecular karyotypes of several Leishmania isolates (Leishmania amazonensis, Leishmania braziliensis, Leishmania guyanensis, Leishmania panamensis, Leishmania donovani, Leishmania major, Leishmania aethiopica, Leishmania tropica, Leishmania enriettii) have been analyzed by clamped homogeneous electric field (CHEF) gel electrophoresis. The chromosomal localization of genes encoding 2 major surface glycoproteins, gp63 and gp46/M2, heat shock protein 70 (hsp70), and beta-tubulin was determined for cloned isolates of 8 of these Leishmania species. The chromosome size class assignment of hsp70 genes was most conserved in that all species contained a single hybridizing DNA band of approximately 1200 kb. The beta-tubulin gene probe hybridized predominantly to large (1600-1750 kb) chromosome-size DNA and to 1-5 additional bands, the number of which depended on the species. The number and size of DNA bands hybridizing to gp63 or gp46/M2 gene probes were not uniformly conserved among species. In contrast to previous reports of gp63 genes being located on a single chromosome, using various CHEF gel conditions we observed a Leishmania major gp63 gene probe hybridizing to at least 2 chromosomal DNA bands in the New World species and in L. tropica. Gp46/M2 genes were located on 1 band in L. donovani, L. major, and L. aethiopica or 2 bands in L. tropica and L. amazonensis, but surprisingly, do not hybridize to any chromosomal DNA of species in the L. braziliensis complex or in L. enriettii. Whenever both genes were present in a species, gp63 and gp46/M2 genes were located on different chromosomal DNA bands.     

The establishment of genomic DNA libraries for the human malaria parasite Plasmodium falciparum and identification of individual clones by hybridisation

The DNA of Plasmodium falciparum has been purified and fragmented with the restriction endonucleases EcoRI and HindIII. The fragments have been incorporated in vitro into derivatives of bacteriophage lambda to make libraries in which most of the parasite DNA is represented. By Southern hybridisation we have been able to recover from these libraries specific clones containing (a) repetitive DNA sequences, (b) rRNA gene(s) and (c) sequences homologous to an actin gene probe. Parasite DNA from two independent sources differs markedly in the pattern of its repetitive DNA visualised by hybridisation to our repetitive clone. By contrast, the rRNA genes of the two isolates prove to be carried on identically sized fragments.     

The genome of Schistosoma mansoni: isolation of DNA, its size, bases and repetitive sequences

DNA has been prepared from adults and cercariae of Schistosoma mansoni utilizing a technique that involves centrifugation through cesium chloride. The DNA isolated from S. mansoni adults and that isolated from cercariae were found to be indistinguishable in all analyses. No modified bases were detected by chromatography or comparative endonuclease restriction. Cot analysis demonstrated that the haploid genome of S. mansoni is 0.26 pg (2.7 X 10(8) base pairs) and that the genome contains both moderately and highly repeated components. Some of the repetitive fraction of DNA consists of tandemly repeated ribosomal genes of which there are 500-1000 copies per genome (1.8-3.6% of the total DNA). Four other non-ribosomal repetitive sequences (comprising at least a further 2.0% of the total DNA) have been isolated from a DNA clone bank and their arrangement within the S. mansoni genome investigated by restriction and Southern blot analysis. These cloned segments of DNA appear in many different locations within the genome and thus are reminiscent of the interspersed DNA sequences described in higher eukaryotic organisms.     

Kinetoplast DNA and RNA of Trypanosoma brucei

Kinetoplast DNA (kDNA) and kinetoplast RNA (kRNA) were isolated from bloodstream and procyclic culture forms of two clonal strains of Trypanosoma brucei. No differences were observed in kDNA (maxicircle) restriction profiles between bloodstream or procyclic culture forms of the same strain. Some differences were observed in kDNA maxicircle restriction sites between the two strains. Buoyant density analysis of Pst I digested kDNA showed the release of a minor low density band representing unit length linearized maxicircle DNA. Pst I or Bam H1-linearized maxicircle DNA was isolated by the Hoechst 33258 dye--CsCl method and a restriction enzyme map of the maxicircle was constructed. Closed monomeric minicircles released from kDNA networks by sonication sedimented with a molecular size of around 1100 base pairs. A substantial minor length heterogeneity was evident in acrylamide gel electrophoresis of once cut minicircles. Several minicircle sequence classes and two Hind III maxicircle fragments representing approx. 50% of the maxicircle were cloned in the bacterial plasmid, pBR322, in Escherichia coli. A purified kinetoplast-mitochondrion fraction was isolated from procyclic culture forms by the Renografin flotation method. The major kRNA components were two small RNAs which comigrated with Leishmania tarentolae 9 and 12 S kRNAs in denaturing gels. These RNAs hybridized to the maxicircle component of the kDNA, specifically to the smaller cloned Hind III maxicircle fragment. This cloned fragment had substantial sequence homology with the cloned maxicircle fragment from L. tarentolae which contains the 9 and 12 S RNA genes, implying an evolutionary conservation of the 9 and 12 S gene sequences. Identical kRnAs were observed in cultured bloodstream forms of T. brucei.     

DNA sequence of Crithidia fasciculata kinetoplast minicircles

Kinetoplast DNA (kDNA) networks of the insect trypanosomatid Crithidia fasciculata strain CF-C1 contain a nearly homogeneous population of kDNA minicircles as judged by restriction enzyme cleavage analysis. We have determined the entire nucleotide sequence of the major class of minicircles by analyzing M13 phage clones carrying half-length segments of the kDNA minicircle molecules. The 12 nucleotide sequence d(G-G-G-G-T-T-G-G-T-G-T-A) is the longest sequence common to kDNA minicircles from several trypanosome species examined to date. Two copies of this universal minicircle sequence were identified 180 degrees apart as direct repeats within the C. fasciculata kDNA minicircles. In addition, these universal minicircle sequences are contained within direct repeats with nearly identical sequences of 173 and 177 base pairs (bp) in length. These sequences are also conserved in the same arrangement in minor sequence classes of minicircles from this strain. Site-specific discontinuities on both strands of the minicircle, identified previously in minicircle replication intermediates, were localized within the 173 and 177 bp conserved sequences. These sequences were also found to have extensive homology with similar conserved sequences in kDNA minicircles from Leishmania tarentolae. We suggest that the two conserved sequences, each containing a single copy of the universal minicircle sequence, represent replication origins in the Crithidia minicircles.     

Isolation and characterization of an alpha-tubulin gene from Leishmania enriettii

An alpha-tubulin gene of Leishmania enriettii has been identified in genomic Southern blots by hybridization with a heterologous alpha-tubulin gene from Drosophila melanogaster. A clone containing this gene has been isolated from a plasmid library of size-selected L. enriettii DNA. It was identified by hybridization with the D. melanogaster tubulin gene. The cloned DNA fragment was characterized by restriction analysis and partial DNA sequence analysis. The cloned DNA fragment is 2 kb in length, bounded by Pst I sites, and appears to contain the entire coding region of the alpha-tubulin gene.     

Identification of visceral Leishmania species with cloned sequences of kinetoplast DNA

Several efforts have been made in order to develop more precise and sensitive methods in the identification of Leishmania parasites. We report here the identification of cloned subfragments of minicircle kinetoplast DNA (kDNA) isolated from L. donovani, WR352, which show different taxonomic specificities. Analysis of these fragments demonstrates a significant sequence diversity within the kDNA minicircle. For example, one cloned fragment was found to be present in all visceral Leishmania species tested, but was not present in any of the cutaneous Leishmania species. Another cloned fragment was only found in the strain from which it had been derived, and was not present in any of the other strains tested. In similar experiments with the New World visceral leishmanias (L. chagasi, WR518) several different cloned kDNA fragments were found to react with all of isolates of the L. chagasi tested, but not with any cutaneous Leishmania species, either from the Old World or the New World. It is of interest to note that these cloned L. chagasi kDNA fragments reacted with isolates of African visceral Leishmania species but not with isolates from India.     

Genetic polymorphism of Leishmania species using kinetoplast DNA restriction fragment length polymorphism and cDNA probe of Leishmania donovani

Leishmaniasis represents a group of diseases that range from simple cutaneous lesions through metastasizing diffused cutaneous to severe systemic infection depending upon the taxon to which the causative parasite belongs. Therefore, it is important to identify the infecting Leishmania. Methods presently being used, including immunology, biochemistry and molecular biology have one or the other limitations, leaving scope for the search for newer probes. This study reports the characterization of leishmania isolates both by restriction fragment length polymorphism of kinetoplast DNA (kDNA) and genomic DNA. The genomic DNA was probed with a cDNA probe B₂a₁. Using a kDNA restriction pattern technique, different isolates of Leishmania donovani could be differentiated from the UR6 strain of L. tropica, but it was not possible to differentiate between newer local isolates of L. donovani with most of the restriction enzymes except AluI. However, the B₂a₁ cDNA probe was able to differentiate these isolates effectively. Both of these techniques could differentiate newer local isolates of L. donovani from the older isolates of L. donovani from India, i.e., DD8, RMRI and SS. The Indian isolates of L. donovani could also be differentiated from isolates of L. donovani from Jeddah and Germany using both techniques. The present study indicates that the cDNA probe B₂a₁ can be used as an important adjunct to kDNA restriction analysis for the characterization of Leishmania species. Received: 15 October 1996     

Rapid identification of causative species in patients with Old World leishmaniasis.

Conventional methods for the identification of species of Leishmania parasite causing infections have limitations. By using a DNA-based alternative, the present study tries to develop a new tool for this purpose. Thirty-three patients living in Marseilles (in the south of France) were suffering from visceral or cutaneous leishmaniasis. DNA of the parasite in clinical samples (bone marrow, peripheral blood, or skin) from these patients were amplified by PCR and were directly sequenced. The sequences observed were compared to these of 30 strains of the genus causing Old World leishmaniasis collected in Europe, Africa, or Asia. In the analysis of the sequences of the strains, two different sequence patterns for Leishmania infantum, one sequence for Leishmania donovani, one sequence for Leishmania major, two sequences for Leishmania tropica, and one sequence for Leishmania aethiopica were obtained. Four sequences were observed among the strains from the patients: one was similar to the sequence for the L. major strains, two were identical to the sequences for the L. infantum strains, and the last sequence was not observed within the strains but had a high degree of homology with the sequences of the L. infantum and L. donovani strains. The L. infantum strains from all immunocompetent patients had the same sequence. The L. infantum strains from immunodeficient patients suffering from visceral leishmaniasis had three different sequences. This fact might signify that some variants of L. infantum acquire pathogenicity exclusively in immunocompromised patients. To dispense with the sequencing step, a restriction assay with HaeIII was used. Some restriction patterns might support genetic exchanges in members of the genus Leishmania.     

Histidine-rich protein genes and their transcripts in Plasmodium falciparum and P. lophurae

The presence of histidine-rich protein (HRP) related genes and gene products in Plasmodium falciparum was demonstrated using a synthetic pentahistidine-encoding oligonucleotide and a cloned HRP cDNA probe prepared from the avian parasite P. lophurae. In Northern blotting experiments, two knobby clones of P. falciparum were found to contain a 3500 nucleotide RNA species that hybridized with the oligonucleotide and HRP cDNA probes. As this component had the expected size for an mRNA encoding an 80-90 kDa protein and was absent from two knobless clones of P. falciparum, we concluded that it represented a 'knob protein' mRNA. Using the restriction enzyme EcoRI, three identical cross-hydribizing HRP gene fragments were found in the DNA of both knobby and knobless clones of P. falciparum. These fragments differed in size from those present in P. lophurae. These results suggest that the absence of knob protein mRNA in knobless clones is not due to loss of the corresponding gene(s).     

Kinetoplast DNA and molecular karyotypes of Trypanosoma evansi and Trypanosoma equiperdum from China.

We compared 12 stocks of Trypanosoma evansi and 1 recently isolated stock of Trypanosoma equiperdum from different regions of China by analysis of kinetoplast DNA (kDNA), nuclear DNA and molecular karyotypes. The T. equiperdum stock was remarkably similar to the T. evansi stocks, except for the possession of kDNA maxi-circles, suggesting a very close evolutionary relationship between T. evansi and T. equiperdum. The maxi-circles of the Chinese T. equiperdum stock were approximately 14.3 kb in size, i.e., about half the size of those of Trypanosoma brucei. This stock is thus similar to an old laboratory stock of T. equiperdum, which also has maxi-circles with a sizeable deletion. Both T. equiperdum and T. evansi kDNA mini-circles hybridised with a T. evansi-specific mini-circle fragment isolated from a Kenyan T. evansi stock. Our results extend the generality that T. evansi and T. equiperdum mini-circles are microheterogeneous rather than homogeneous. Molecular karyotypes obtained by pulsed field gradient gel electrophoresis provided a more sensitive way of distinguishing the T. evansi stocks than isoenzymes or restriction fragment length polymorphisms in kDNA mini-circles, genes for ribosomal RNAs and variant surface glycoproteins. Our results fit the general idea that T. evansi stocks worldwide have a single origin.