Phylogenetic analysis of Bolivian bat trypanosomes of the subgenus schizotrypanum based on cytochrome B sequence and minicircle analyses

The aim of this study was to establish the phylogenetic relationships of trypanosomes present in blood samples of Bolivian Carollia bats. Eighteen cloned stocks were isolated from 115 bats belonging to Carollia perspicillata (Phyllostomidae) from three Amazonian areas of the Chapare Province of Bolivia and studied by xenodiagnosis using the vectors Rhodnius robustus and Triatoma infestans (Trypanosoma cruzi marenkellei) or haemoculture (Trypanosoma dionisii). The PCR DNA amplified was analyzed by nucleotide sequences of maxicircles encoding cytochrome b and by means of the molecular size of hyper variable regions of minicircles. Ten samples were classified as Trypanosoma cruzi marinkellei and 8 samples as Trypanosoma dionisii. The two species have a different molecular size profile with respect to the amplified regions of minicircles and also with respect to Trypanosoma cruzi and Trypanosoma rangeli used for comparative purpose. We conclude the presence of two species of bat trypanosomes in these samples, which can clearly be identified by the methods used in this study. The presence of these trypanosomes in Amazonian bats is discussed.     

Heterogeneity of the kinetoplast DNA molecules of Trypanosoma cruzi.

Kinetoplast DNA (kDNA) of the culture form of Trypanosoma cruzi is cleaved by restriction endonucleases (HpaII, HindII, EcoRI, and HaeIII). The analysis of the cleavage patterns proves that the minicircles (free circulargenome units) are heterogeneous in base sequences. The same results are obtained with the complex kDNA network which is composed of the association of minicircles and linear molecules. Kinetic studies of the renaturation of kDNA previously cleaved by HpaII into fragments of the genome unit size show at least two populations of molecules. About 75% of these molecules correspond to the fast renaturing population having the molecular complexity of the minicircles. The molecules of the slow renaturing population have a much higher molecular complexity than the minicircles and do not seem to be related to the majority of the long linear molecules.     

Characterization of isolates and clones of leishmania by analysis of kinetoplast DNA

The genetic characterization of pathogenic isolates of Leishmania was attempted by analysis of the molecular properties of kinetoplast DNA (kDNA) minicircles. Unit minicircle size is not conserved during speciation of Leishmania since the minicircles of strains and clones of L t major are smaller (700 bp) than those found in certain strains of L mexicana ssp (820 bp), L donovani (850 bp) or L t tropica (900 bp). Schizodeme analysis of minicircles reveals a high degree of sequence divergence in kDNA of Leishmania with the degree of microheterogeneity varying between species. This sequence divergence allows the discrimination of species, strains, and clones of Leishmania into schizodemes. Southern blot hybridization experiments reveal that at high stringency overall minicircle sequence homology is conserved among clones and strains of one species (L t major) 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 unknown Leishmania isolates. The properties of kDNA from an L t tropica strain LRC-L32 (a “recidiva” organism) are so diverged from those of L t major strains as to support the classification [22,23] of L t tropica and L t major as separate species of Leishmania rather than subspecies of L tropica.     

'Empty' minicircles and petB/atpA and psbD/psbE (cytb559 alpha) genes in tandem in Amphidinium carterae plastid DNA

Amphidinium carterae minicircle chloroplast DNA was separated from total DNA by centrifugation through a sucrose/NaCl gradient. Sequences of minicircles with psbA and 23S rRNA contained a common region of 67 bp. Primers designed from this generated numerous polymerase chain reaction products of 1.5-2.6 kb. These contained psaA and psaB as one gene/circle, and petB/atpA and psbD/psbE as two genes/circle. 'Empty' minicircles of 1.7-2.5 kb containing no identifiable genes or parts of genes were more abundant than gene-containing circles. From 15 minicircles a minimum common region of 48 bp was identified, with little identity to that from other dinoflagellate minicircles.     

Evidence that the entire length of a kinetoplast DNA minicircle is transcribed in Trypanosoma cruzi

A 1.3 kb cDNA (cDNA52) was derived from Trypanosoma cruzi trypomastigote mRNA. Using single stranded probes in Northern blots, we identified the putative coding strand of cDNA52. In addition, a minor band was detected in RNA from epimastigotes that was absent in RNA from trypomastigotes. Nucleotide sequence analysis revealed that cDNA52 was highly homologous to T. cruzi kinetoplast DNA minicircle sequences. All four conserved regions of T. cruzi minicircles were identified in cDNA52. Using several criteria, we demonstrated that the hybridization signals were not caused by contaminating minicircle DNA in the RNA preparations. The data provide direct evidence for the unprecedented finding that the entire length of a kDNA minicircle is transcribed in T. cruzi.     

Catenated dimers and knotted DNA structures: putative intermediates in the replication of T. cruzi kinetoplast minicircle DNA.

Upon centrifugation of gently lysed T. cruzi cells through a sucrose gradient, a free DNA fraction was shown to contain catenated dimers and knotted DNA structures. Southern hybridization and electron microscopic studies indicated that both of these structures derived from minicircle DNA, the major component of T. cruzi kinetoplast DNA. Partial denaturation analysis of a random population of catenated dimers suggests that these structures may have arisen from a late stage in the replication of minicircle DNA. On the other hand, the T. cruzi knotted minicircles we have isolated appear to be very similar to trefoil structures recently reported and implicated as replicative intermediates in two other trypanosoma species.     

The kinetoplast DNA of the Australian trypanosome,Trypanosoma copemani,shares features with Trypanosoma cruzi and Trypanosoma lewisi

Kinetoplast DNA (kDNA) is the mitochondrial genome of trypanosomatids. It consists of a few dozen maxicircles and several thousand minicircles, all catenated topologically to form a two-dimensional DNA network. Minicircles are heterogeneous in size and sequence among species. They present one or several conserved regions that contain three highly conserved sequence blocks. CSB-1 (10?bp sequence) and CSB-2 (8?bp sequence) present lower interspecies homology, while CSB-3 (12?bp sequence) or the Universal Minicircle Sequence is conserved within most trypanosomatids. The Universal Minicircle Sequence is located at the replication origin of the minicircles, and is the binding site for the UMS binding protein, a protein involved in trypanosomatid survival and virulence. Here, we describe the structure and organisation of the kDNA of Trypanosoma copemani, a parasite that has been shown to infect mammalian cells and has been associated with the drastic decline of the endangered Australian marsupial, the woylie (Bettongia penicillata). Deep genomic sequencing showed that T. copemani presents two classes of minicircles that share sequence identity and organisation in the conserved sequence blocks with those of Trypanosoma cruzi and Trypanosoma lewisi. A 19,257?bp partial region of the maxicircle of T. copemani that contained the entire coding region was obtained. Comparative analysis of the T. copemani entire maxicircle coding region with the coding regions of T. cruzi and T. lewisi showed they share 71.05% and 71.28% identity, respectively. The shared features in the maxicircle/minicircle organisation and sequence between T. copemani and T. cruzi/T. lewisi suggest similarities in their process of kDNA replication, and are of significance in understanding the evolution of Australian trypanosomes.     

Biological, biochemical and molecular features of Trypanosoma cruzi strains isolated from patients infected through oral transmission during a 2005 outbreak in the state of Santa Catarina, Brazil: its correspondence with the new T. cruzi Taxonomy Consensus (2009)

We examined strains of Trypanosoma cruzi isolated from patients with acute Chagas disease that had been acquired by oral transmission in the state of Santa Catarina, Brazil (2005) and two isolates that had been obtained from a marsupial (Didelphis aurita) and a vector (Triatoma tibiamaculata). These strains were characterised through their biological behaviour and isoenzymic profiles and genotyped according to the new Taxonomy Consensus (2009) based on the discrete typing unities, that is, T. cruzi genotypes I-VI. All strains exhibited the biological behaviour of biodeme type II. In six isolates, late peaks of parasitaemia, beyond the 20th day, suggested a double infection with biodemes II + III. Isoenzymes revealed Z2 or mixed Z1 and Z2 profiles. Genotyping was performed using three polymorphic genes (cytochrome oxidase II, spliced leader intergenic region and 24Sα rRNA) and the restriction fragment length polymorphism of the kDNA minicircles. Based on these markers, all but four isolates were characterised as T. cruzi II genotypes. Four mixed populations were identified: SC90, SC93 and SC97 (T. cruzi I + T. cruzi II) and SC95 (T. cruzi I + T. cruzi VI). Comparison of the results obtained by different methods was essential for the correct identification of the mixed populations and major lineages involved indicating that characterisation by different methods can provide new insights into the relationship between phenotypic and genotypic aspects of parasite behaviour.     

Mexican Trypanosoma cruzi stocks: analysis of minicircle kDNA homologies by cross-hybridization

Homologies of minicircle kDNA of 27 Mexican stocks were studied by cross-hybridization with four kDNA probes derived from three reference stocks belonging to groups Trypanosoma cruzi I (SO34 cl4 and Silvio) and T. cruzi II (MN) and one Mexican stock. High homologies were only observed with Silvio (six stocks) and Mexican probes (11 stocks). After 30 min exposure (low homology) additional stocks were recognized with SO34 cl4 (three stocks) and Silvio (six stocks) probes; with the Mexican probe only five stocks remained non-reactive. All the stocks were typed by isoenzyme (16 loci) and Mexican stocks belonged to T. cruzi I. Hybridization patterns were not strictly correlated with the observed clustering and cross-hybridization of kDNA minicircles is not available to distinct Mexican stocks.     

Visualization of the bent helix in kinetoplast DNA by electron microscopy

Kinetoplast DNA minicircles from the trypanosomatid Crithidia fasciculata contain a segment of approximately 200 bp which is probably more highly bent than any other DNA previously studied. Electron microscopy (EM) of relaxed minicircles (2.5 kb) revealed 200-300 bp loops within the larger circles, and the loops could also be detected on full-length linear molecules. Examination by EM of a 219 bp cloned fragment which contains the bent helix revealed that up to 70% of the molecules appeared circular whether or not the ends were cohesive. In contrast, a 207 bp fragment from pBR322 showed no circles and the fragments in general appeared much straighter than the kinetoplast fragments. Treatment of the 219 bp bent kinetoplast fragment with the drug distamycin caused a striking reduction in curvature.     

DNA supercoiling changes the spacing requirement of two lac operators for DNA loop formation with lac repressor.

We have used a gel retardation assay to investigate the influence of DNA supercoiling on loop formation between lac repressor and two lac operators. A series of 15 DNA minicircles of identical size (452 bp) was constructed carrying two lac operators at distances ranging from 153 to 168 bp. Low positive or negative supercoiling (sigma = +/- 0.023) changed the spacing between the two lac operators required for the formation of the most stable loops. This reveals the presence of altered double helical repeats (ranging from 10.3 to 10.7 bp) in supercoiled DNA minicircles. At elevated negative supercoiling (sigma = -0.046) extremely stable loops were formed at all operator distances tested, with a slight spacing periodicity remaining. After relaxation of minicircle-repressor complexes with topoisomerase I one superhelical turn was found to be constrained in those minicircles which carry operators at distances corresponding to a non-integral number of helical turns. This indicates that DNA loop formation can define local DNA domains with altered topological properties of the DNA helix.     

Evidence of absence of Trypanosoma cruzi kinetoplast DNA methylation by restriction endonuclease analysis.

Eight kinetoplast DNA samples from very different T. cruzi zymodemes were digested with the isoschizomer group of enzymes (MspI-HpaII) and (MboI-Sau 3AI), able to detect DNA methylation on cytidine and adenine for the CCGG and GATC sequences, respectively. Restriction digestion analysis of each kDNA with both isoschizomer groups of enzymes did not display a different profile suggesting that maxicircles and minicircles on this trypanosomatid are not methylated.     

Atomistic simulations reveal bubbles, kinks and wrinkles in supercoiled DNA

Although DNA is frequently bent and supercoiled in the cell, much of the available information on DNA structure at the atomistic level is restricted to short linear sequences. We report atomistic molecular dynamics (MD) simulations of a series of DNA minicircles containing between 65 and 110 bp which we compare with a recent biochemical study of structural distortions in these tight DNA loops. We have observed a wealth of non-canonical DNA structures such as kinks, denaturation bubbles and wrinkled conformations that form in response to bending and torsional stress. The simulations show that bending alone is sufficient to induce the formation of kinks in circles containing only 65 bp, but we did not observe any defects in simulations of larger torsionally relaxed circles containing 110 bp over the same MD timescales. We also observed that under-winding in minicircles ranging in size from 65 to 110 bp leads to the formation of single stranded bubbles and wrinkles. These calculations are used to assess the ability of atomistic MD simulations to determine the structure of bent and supercoiled DNA.     

Changes in Trypanosoma cruzi Kinetoplast DNA Minicircles Induced by Environmental Conditions and Subcloning

ABSTRACT. Reversible changes in kinetoplast DNA (kDNA) minicircles sequences were observed in clones of Trypanosoma cruzi strain Y, following a number of passages during exponential growth phase or after subcloning in blood-free medium. kDNA restriction patterns of clones were similar to those of the original uncloned strain, while subclones presented distinct kDNA restriction patterns. Homology experiments demonstrated strong hybridization between kDNA with the same electrophoretic mobility patterns while only weak signals were observed with kDNA of different patterns. The changes observed, which are unprecedented in T. cruzi clones, characterize transkinetoplastidy, and seem to be associated with similarly reversible changes both in zymodeme and in infectivity.     

Molecular cloning and characterization of the DNA mismatch repair gene class 2 from the Trypanosoma cruzi

Genes with homology to the bacterial mutS gene, which encodes a protein involved in post-replication DNA mismatch repair, are known in several organisms. Using a degenerate PCR strategy, we cloned a Trypanosoma cruzi genomic DNA fragment homologous to the mutS gene class two (MSH2). This fragment was used as a probe to select the corresponding cDNAs from a T. cruzi cDNA library. The complete sequence of the gene (3304 bp), denominated TcMSH2, was obtained. The sequence contained an open reading frame of 2889 bp coding for a putative protein of 962 amino acids. Computational analyses of the amino acid sequence showed 36% identity with MSH2 proteins from other eukaryotes and revealed the presence of all functional domains of MutS proteins. Hybridization analyses indicated that the TcMSH2 gene is present as a single copy gene that is expressed in all forms of the T. cruzi life cycle. The role of the product of the TcMSH2 gene in mismatch repair was investigated by negative dominance phenotype analyses in Escherichia coli. When eukaryotic muts genes are expressed in a prokaryotic system, they increase the bacterial mutation rate. The same phenomenon was observed with the TcMSH2 cDNA, indicating that T. cruzi MSH2 interferes with the bacterial mismatch system. Phylogenetic analyses showed that the T. cruzi gene grouped with the MSH2 clade confirming the nature of the gene isolated in this work.     

Topoisomer gel retardation: detection of anti-Z-DNA antibodies bound to Z-DNA within supercoiled DNA minicircles.

Small DNA fragments of approximately 350 bp in length, either with or without d(CG)n tracts, are ligated into underwound DNA minicircles to generate topoisomeric rings with different topological linking numbers, Lk. These minicircles, differing by an Lk of one, can be separated by acrylamide gel electrophoresis. Furthermore, electrophoresis can be used to reveal DNA double helix conformational changes that are induced by supercoiling, such as left-handed Z-DNA. When anti-Z-DNA antibodies are added to such minicircles, their binding leads to a selective retardation of the electrophoretic migration of the Z-DNA containing circles. This effect is not seen with relaxed minicircles and those with insufficient torsional stress to induce a conformational transition. Thus the technique of 'topoisomer gel retardation' presents a very sensitive assay for the identification of proteins that selectively bind to DNA conformations stabilized by negative DNA supercoiling.     

Identification of PDZ5, a candidate universal minicircle sequence binding protein of Trypanosoma cruzi

The dodecamer universal minicircle sequence is a conserved sequence present in minicircles of trypanosomatid kinetoplast DNA studied so far. This sequence is recognised by a protein named universal minicircle sequence binding protein, described for Crithidia fasciculata, involved in minicircle DNA replication. We have identified a Trypanosoma cruzi gene homologue of the Crithidia fasciculata universal minicircle sequence binding protein. Similar to the Crithidia fasciculata universal minicircle sequence binding protein, the Trypanosoma cruzi protein, named PDZ5, contains five zinc finger motifs. Pulsed field gel electrophoresis indicated that the pdz5 gene is located in the chromosomal band XX of the Trypanosoma cruzi genome. The predicted amino acid sequence of PDZ5 shows a high degree of similarity with several trypanosomatid zinc finger proteins. Specific antibody raised against Crithidia fasciculata universal minicircle sequence binding protein recognises both the recombinant and endogenous PDZ5. The complete pdz5 coding sequence cloned in bacteria expresses a recombinant PDZ5 protein that binds specifically to the universal minicircle sequence dodecamer. These data strongly suggest that PDZ5 represents a Trypanosoma cruzi universal minicircle sequence binding protein.     

Kinetoplast DNA in the insect trypanosomes Crithidia luciliae and Crithidia fasciculata: II. Sequence evolution of the minicircles

Minicircle sequence evolution has been studied by comparison of the minicircles from Crithidia fasciculata and C. luciliae (C. fasciculata, var. luciliae) by restriction enzyme analysis and hybridization experiments. In contrast to the maxicircle sequence, the minicircle sequence of these trypanosomes evolves very rapidly. No conservation of restriction fragments has been observed and cross-hybridization of minicircles, minicircle fragments, and total kDNA is relatively weak. We conclude that no fragment larger than 550 bp is perfectly conserved between all minicircles of the two trypanosomes. Alterations in the minicircle fragment patterns of our stocks of trypanosomes were even apparent in a cultivation period of 1.5 to 2 years. The alterations suggest a random drift of the sequence which supports a noncodogenic function for the minicircles. Double restriction enzyme digestion experiments show that primary fragments are homogeneous with respect to cleavage by the second enzyme. This suggests that sequence rearrangements, rather than point mutations are the basis of the minicircle sequence heterogeneity.     

Analysis of sequences of two different classes of kinetoplast DNA minicircles of aLeishmania spp.

We have determined the nucleotide sequences of the minicircles representing a major (pLURkE3) and a minor (pLURkH13) class populations from the kinetoplast DNA ofLeishmania strain UR6. These minicircles have sequence organization similar to other kinetoplastid parasites, however, they have some unique structural features. These features include the following: (i) imperfect inverted repeat in the variable regions, similar to the conserved sequence elements of guide RNA genes in African trypanosomes, (ii) tandem and non-tandem direct repeats of 8 bp or longer scattered throughout the minicircles, (iii) non uniform strand distribution of bases throughout the minicircles and (iv) high TG content, more than half of the molecules being extremely (T + G) versus (A + C) strand biased. The heterogeneity of minicircle sequences in the variable regions may be exploited in developing recombinant DNA based diagnostic probes for detection and classification of Leishmania species. EMBL data base accession numbers X68026 and X68027. Part of this work was presented in the International Symposium on “Current Trends inLeishmania Research” held at Indian Institute of Chemical Biology, Calcutta on February 12–14, 1992.     

Changes in network topology during the replication of kinetoplast DNA.

Kinetoplast DNA of Crithidia fasciculata is a network containing several thousand topologically interlocked DNA minicircles. In the prereplicative Form I network, each of the 5000 minicircles is intact and linked to an average of three neighbors (i.e. the minicircle valence is 3). Replication involves the release of minicircles from the interior of the network, the synthesis of nicked or gapped progeny minicircles and the attachment of the progeny to the network periphery. The ultimate result is a Form II network of 10,000 nicked or gapped minicircles. Our measurements of minicircle valence and density, and the network's surface area, revealed striking changes in network topology during replication. During the S phase, the peripheral newly replicated minicircles have a density twice that of minicircles in Form I networks, which suggests that the valence might be as high as 6. Most of the holes in the central region that occur from the removal of intact minicircles are repaired so that the central density and valence remain the same, as in prereplicative networks. When minicircle replication is complete at the end of the S phase, the isolated network has the surface area of a prereplicative network, despite having twice the number of minicircles. During the G2 phase, the Form II network undergoes a remodeling in which the area doubles and the valence is reduced to 3. Finally, the interruptions in the minicircles are repaired and the double-sized network splits in two.