Novel identification of differences in the kinetoplast DNA of Leishmania isolates by recombinant DNA techniques and in situ hybridisation

Kinetoplast DNA (kDNA) was extracted from marker isolates of three 'Old World' cutaneous leishmania, L. tropica, L. aethiopica and L. major. Restriction endonuclease digestion followed by electrophoresis showed that each isolate produced a unique pattern of DNA fragments. The kDNA of each isolate was hybridised to Southern blots of digests of all three kDNAs. This showed that the kDNA of each isolate contained sequences unique to that isolate as well as sequences common to all three isolates. The kDNA sequences of L. tropica and L. aethiopica were more closely related than either were to those of L. major. kDNA of each isolate was cloned and plasmids selected which contained a fragment of DNA unique to the isolate from which the kDNA originated. Whole kDNA was hybridised to organisms fixed on a microscope slide. In each case the kDNA hybridised strongly to the kinetoplast of the organism from which the DNA had been extracted. There was a small amount of cross-hybridisation between L. tropica and L. aethiopica confirming the result of the Southern blot hybridisation. The feasibility of a method of isolate identification using recombinant DNA probes containing sequences unique to a particular isolate or group of isolates is discussed.     

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.     

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.     

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.     

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.     

Polymorphisms within minicircle sequence classes in the kinetoplast DNA of Trypanosoma cruzi clones

Four minicircle classes were analyzed using cloned minicircles as probes and single-cell cloned Trypanosoma cruzi parasites. The hybridization conditions used allowed identification of minicircle classes within kinetoplast DNA that were non-homologous to each other. Two of these minicircle classes, detected with probes pTckAWP-2 and -3, were present together in several of the CA 1 and Miranda clones, in spite of the fact that either pTckAWP-2 or both minicircle classes were undetectable in other isolates and clones of the parasite. The other two minicircle classes (pTckM-84 and -88) were located in some Miranda cloned parasites which were characterized by the simple restriction endonuclease pattern of their minicircles. Both pTckM-84 and -88 minicircle classes represented 52-71% of the kinetoplast DNA in the latter group of trypanosomes. Restriction endonuclease mapping allowed the identification of polymorphic minicircles in two of the four minicircle classes analyzed (pTckAWP-2 and pTckM-88). The polymorphisms were observed in part of the molecules of one minicircle class within a single trypanosome clone, as well as when different clones or even some of those obtained from the same isolate were compared. In addition, a different proportion of pTckM-88 type of minicircle sequence class was observed in the kinetoplast DNA from two of the Miranda clones analyzed. These observations demonstrated that similar molecules may evolve independently in sequence in each parasite. The polymorphic minicircles detected may arise from sequence variations before expansion of a future homogeneous minicircle sequence class.     

Evidence for kinetoplast and nuclear DNA homogeneity in Trypanosoma evansi isolates

The kinetoplast DNA minicircles from 13 stocks of trypanosomes designated as Trypanosoma evansi were digested with various restriction enzymes. We also examined the distribution of restriction site polymorphisms in the nuclear DNA of 9 of these stocks, using 7 different variable surface glycoprotein (VSG) and non-VSG probes. Restricted kinetoplast DNA (kDNA) fragments of some of these strains were cloned into M13 or PUC 18 vectors and sequenced. The restriction and sequence mapping showed that most of T. evansi isolates belonged to the A1 and A2 types of Borst and to two new closely related types A3 and A4. A notable exception was RoTat 4/1 derived from a Sudanese stock which was found to display a characteristic brucei-like minicircle heterogeneity. The T. evansi minicircles analysed are not only homogeneous in sequence but also the region similar to the conserved region in Trypanosoma brucei and Trypanosoma equiperdum is flanked on its 5' end by a palindromic repeat of part of the conserved region. The highly conserved sequence GGGCGGT which appears to correspond to the initiation of synthesis of one of the Okazaki fragments contains an additional G and is located as in T. brucei and T. equiperdum about 73 bp 5' from the ORI. The nuclear DNA analysis confirms the kDNA study in that all the T. evansi stocks are members of a very homogeneous group in terms of sequence divergence. Moreover, our analysis also confirms that T. evansi is more closely related to the West African T. b. brucei and T. b. gambiense than to other African trypanosomes.     

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.     

Serial quantitative PCR assay for detection, species discrimination, and quantification of Leishmania spp. in human samples

The Leishmania species cause a variety of human disease syndromes. Methods for diagnosis and species differentiation are insensitive and many require invasive sampling. Although quantitative PCR (qPCR) methods are reported for leishmania detection, no systematic method to quantify parasites and determine the species in clinical specimens is established. We developed a serial qPCR strategy to identify and rapidly differentiate Leishmania species and quantify parasites in clinical or environmental specimens. SYBR green qPCR is mainly employed, with corresponding TaqMan assays for validation. The screening primers recognize kinetoplast minicircle DNA of all Leishmania species. Species identification employs further qPCR set(s) individualized for geographic regions, combining species-discriminating probes with melt curve analysis. The assay was sufficient to detect Leishmania parasites, make species determinations, and quantify Leishmania spp. in sera, cutaneous biopsy specimens, or cultured isolates from subjects from Bangladesh or Brazil with different forms of leishmaniasis. The multicopy kinetoplast DNA (kDNA) probes were the most sensitive and useful for quantification based on promastigote standard curves. To test their validity for quantification, kDNA copy numbers were compared between Leishmania species, isolates, and life stages using qPCR. Maxicircle and minicircle copy numbers differed up to 6-fold between Leishmania species, but the differences were smaller between strains of the same species. Amastigote and promastigote leishmania life stages retained similar numbers of kDNA maxi- or minicircles. Thus, serial qPCR is useful for leishmania detection and species determination and for absolute quantification when compared to a standard curve from the same Leishmania species.     

Kinetoplast DNA analysis of four Trypanosoma evansi strains.

Kinetoplast DNA (kDNA), the mitochondrial DNA of trypanosomes, is a network of thousands of topologically interlocked DNA minicircles and about 50 maxicircles. In this study, we have analysed the kDNA molecules of 6 strains of Trypanosoma evansi from different geographical areas. 2 strains were found to be dyskinetoplastic mutants and other 4 kinetoplastic strains absent of maxicircles. The electrophoretic analysis of the minicircles digested with various restriction endonucleases clearly shows that all of the kinetoplastic strains lack profound minicircle heterogeneity typical of T. brucei. However, a slight restriction fragment length polymorphism could be observed with 2 enzymes (Dde I and HinfI) within the minicircle population of each cloned strain. We propose that this sequence diversity is the result of point mutations. Further analysis of the minicircles by nucleotide sequencing revealed that the 4 minicircles of T. evansi strains share extensive regions of homology with each other but only about 50% homology with other species. This homogeneity of T. evansi minicircle sequences may provide a useful tool for classification and identification.     

Presence of a bent helix in fragments of kinetoplast DNA minicircles from several trypanosomatid species

Some restriction fragments of kinetoplast minicircles from several trypanosomatid species (Leishmania tarentolae, Trypanosoma brucei, T. equiperdum, Herpetomonas muscarum, Crithidia fasciculata, but not T. cruzi) migrate anomalously on polyacrylamide gels. This behavior is probably due to a natural curvature of the helix. Bent helices appear to be a common property of kinetoplast minicircles, and may be important for minicircle function. In the case of T. equiperdum, we present evidence that each minicircle has a single bent region which resides in or near the 'conserved sequence.'     

Molecular karyotype of five species of Leishmania and analysis of gene locations and chromosomal rearrangements

The molecular karyotypes of five species of Leishmania were studied by pulsed field gradient gel electrophoresis (PFGGE) of chromosome-sized DNA bands. Each species exhibits a unique pattern of 22-28 bands in the size range approximately 200-2200 kb whereas strains of one species exhibit similar karyotypes. Analysis of the behaviour of kinetoplast DNA during PFGGE showed that minicircle DNA remains confined to the gel slot but a proportion of the maxicircle DNA fractionates as a low molecular weight band below band 1. The band location of genes for alpha and beta tubulin, the 5' spliced leader sequence (5'SL), heat shock proteins 70 (hsp 70) and 83 (hsp 83) and thymidylate synthase-dihydrofolate reductase (TS-DHFR) were analysed. Housekeeping genes are not clustered in Leishmania but are found on at least 7 bands in L. major. The hsp 83 gene is linked to the tandemly repeated beta tubulin allele on band 21 in L. major. Among different species, the location of the unlinked hsp 83 and hsp 70 genes is conserved whereas the TS-DHFR and 5'SL sequences are found on bands of varying size. The 5'SL gene may be rearranged in L. enriettii and two 5'SL loci were identified in L. donovani and L. tropica. The conservation of loci in strains of L. major suggests that the chromosomal genetic linkage map should be a reliable marker for identifying unknown isolates of Leishmania. Sequences on one band in L. mexicana sp. were shared among several bands and distributed on homologous and non-homologous bands in other species showing that DNA sequences are rearranged during speciation in Leishmania.     

Sequence diversity in the kinetoplast DNA minicircles of Trypanosoma cruzi

Minicircles are the most abundant component of the mitochondrially located kinetoplast DNA in the members of the order Kinetoplastida. Minicircle sequences differ among most trypanosomatid species. To learn about the molecular mechanisms that give rise to this diversity, we sequenced a complete minicircle (pTckAWP-2) and two homologous but polymorphic minicircle fragments isolated from different Trypanosoma cruzi clones. Comparison of these sequences revealed 23 point mutations, 19 of which were transitions. A single base pair insertion was also detected in one of the two minicircle fragments sequenced. Analysis of pTckAWP-2 sequence showed the following features: the presence of four internal 118 base pairs conserved regions with 80% or higher homology; the fact that these four conserved regions also differed mainly by point mutations, although in this case a bias in favor of transversions was observed; the existence in each of these four regions of the highly conserved 13 bp sequence 5'GGGGTTGGTGTAA3', detected in all trypanosomatid minicircles, which is thought to be the origin of replication; and the presence of several direct and inverted repeat sequences of 8 base pairs or longer, scattered throughout the minicircle molecule. Comparison of the T. cruzi conserved minicircle region with that of other trypanosomatids showed a higher homology of T. cruzi with T. lewisi, another stercorarian trypanosome, than with African trypanosomes or Leishmania.     

Schizodeme analysis of Trypanosoma cruzi stocks from South and Central America by analysis of PCR-amplified minicircle variable region sequences

Kinetoplast DNA (kDNA) was isolated from 56 stocks of Trypanosoma cruzi isolated from human patients, animals and insects from Brazil, Venezuela, Colombia and Costa Rica. Comparison of the patterns of digested kDNA on acrylamide gels led to the grouping of several stocks into two schizodemes. Schizodeme analysis was also performed using a set of 330-bp fragments representing all the variable regions of the minicircle DNA molecules, which were obtained by PCR amplification of the kDNA using conserved region primers. The results of this analysis were consistent with the analysis using total kDNA, but the more informative restriction profiles allowed the construction of additional schizodemes. In addition, two oligomers were generated from variable region sequences of cloned minicircles from a Y and a Cl strain, and these were used as schizodeme-specific probes to detect homologous sequences in the amplified minicircle DNAs. The results indicate that a combination of restriction enzyme fingerprinting and hybridization of amplified variable region minicircle DNA with schizodeme-specific probes can be used for both sensitive detection and classification of T. cruzi.     

Specific discontinuities in Leishmania tarentolae minicircles map within universally conserved sequence blocks

Specific discontinuities remaining in the daughter strands of newly synthesized minicircles from Crithidia fasciculata and Trypanosoma equiperdum have been shown to lie within conserved sequence blocks (CSBs) present in minicircles from all species of trypanosomes. The presence of ribonucleotides at the 5' ends of the L-strand in both cases suggests that the conserved sequences may constitute a replication origin. However, specific discontinuities have only been mapped in organisms having unusually homogeneous populations of minicircles. The specific nicks in minicircles from the heterogeneous population present in Leishmania tarentolae have now been mapped to predicted sites within the CSBs. These results are consistent with a universal mechanism of minicircle replication dictated by a conserve sequence motif present both in minicircles having a high degree of sequence heterogeneity as well as in relatively homogeneous populations.     

Sequences of two kinetoplast minicircle DNAs of Trypanosoma (Nannomonas) congolense

Random minicircle DNA molecules were released from isolated kinetoplast network DNA of Trypanosoma congolense by BamHI digestion and cloned into plasmid pUC19. The sequences of two cloned minicircles (958 bp and 964 bp) were determined. Both minicircles contain the 13 bp sequence, 5'-GGGGTTGGTGTAA-3', thought to be the replication origin of minicircles in other trypanosomatids. The two minicircles have extensive homology in the 120 bp preceeding, and the 20 bp following, this 13-mer but only scattered homology elsewhere. Both possess tandem repeats downstream of the 13-mer. Comparison of these minicircles with minicircle sequences from other trypanosomatids reveals that they have the same general sequence organization as the others although only the 13-mer and its flanking regions are homologous.     

Kinetoplast DNA minicircles are inherited from both parents in genetic crosses of Trypanosoma brucei

In the order Kinetoplastida, genetic exchange has been demonstrated only in the genus Trypanosoma. Analysis of kinetoplast DNA (kDNA) in genetic crosses of T. brucei has shown that whereas maxicircles are inherited uniparentally, minicircles are inherited from both parents. This result was confirmed for a new cross of T. b. brucei and T. b. rhodesiense by restriction enzyme digestion and Southern analysis of purified kDNA. By hybridisation with small minicircle-derived probes, we could demonstrate the presence of particular parental minicircles in the kDNA of hybrid progeny clones. All hybrid clones had inherited two minicircles from one parent despite two of the four clones having maxicircles from the other parent. The results suggest that rather than small-scale exchange of minicircles between parental networks, gross breakdown and reassembly of the minicircle network occurs during genetic exchange. Received: 26 October 1996 / Accepted: 12 December 1996     

Kinetoplast DNA signatures of Trypanosoma cruzi strains obtained directly from infected tissues.

We report here a polymerase chain reaction (PCR)-based DNA profiling technique that permits Trypanosoma cruzi strain characterization by direct study of infected tissues. This is based on application of a recently developed method of DNA fragment identification, called low-stringency single specific primer PCR (LSSP-PCR), to the study of the variable region of kinetoplast DNA (kDNA) minicircles from T. cruzi Thus, we can translate the intraspecific polymorphism in the nucleotide sequence of kDNA minicircles into a specific and highly reproducible kDNA signature. Comparison with the phenogram obtained by DNA fingerprinting analysis of a set of T. cruzi strains showed good qualitative correlation between the degree of divergence of the LSSP-PCR profiles and the genetic distance between the strains. kDNA signatures of heart tissue from acutely or chronically infected animals revealed perfect concordance with the patterns obtained from cultured parasites for the CL and Colombiana strains but not for the Y strain, which is known to be multiclonal. However, the match was perfect for studies with two clones of the Y strain. We take this as evidence that in some multiclonal strains there is heterogeneity among the clones in the degree of tropism for the heart tissue. Finally, we showed that it is possible to obtain a T. cruzi kDNA signature from the heart of a human patient with chronic Chagasic myocardiopathy. kDNA signatures obtained by LSSP-PCR of sequences amplified from infected tissues constitute a new tool to study the molecular epidemiology of Chagas' disease.     

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.