Identification of the telomere in Trypanosoma cruzi reveals highly heterogeneous telomere lengths in different parasite strains.

Here we describe the cloning and characterisation of the Trypanosoma cruzi telomere. In the Y strain, it is formed by typical GGGTTA repeats with a mean size of approximately 500 bp. Adjacent to the telomere repeats we found a DNA sequence with significant homology to the T.cruzi 85 kDa surface antigen (gp85). Examination of the telomere in nine T.cruzi strains reveals differences in the organisation of chromosome ends. In one group of strains the size of the telomere repeat is relatively homogeneous and short (0.5-1.5 kb) as in the Y strain, while in the other, the length of the repeat is very heterogeneous and significantly longer, ranging in size from 1 to >10 kb. These different strains can be grouped similarly to previously existing classifications based on isoenzyme loci, rRNA genes, mini-exon gene sequences, randomly amplified polymorphic DNA and rRNA promoter sequences, suggesting that differential control of telomere length and organisation appeared as an early event in T. cruzi evolution. Two-dimensional pulsed field gel electrophoresis analysis shows that some chromosomes carry telomeres which are significantly larger than the mean telomere length. Importantly, the T.cruzi telomeres are organised in nucleosomal and non-nucleosomal chromatin.     

Phylogeny of Trypanosomatidae and Bodonidae (Kinetoplastida) based on 18S rRNA: evidence for paraphyly of Trypanosoma and six other genera

Phylogenetic analysis of 18S rRNA sequences from the families Trypanosomatidae and Bodonidae (Eugelenozoa: Kinetoplastida) was conducted using a variety of methods. Unlike previous analyses using unrooted trees and/or smaller numbers of sequences, the analysis did not support monophyly of the genus Trypanosoma, which includes the major human parasites T. cruzi (cause of Chagas' disease) and T. brucei (cause of African sleeping sickness). The section Salivaria of the genus Trypanosoma fell outside a cluster that includes the section Stercoraria of the genus Trypanosoma, along with members of the genera Leishmania, Endotrypanum, Leptomonas, Herpetomonas, Phytomonas, Crithidia, and Blastocrithidia. The phylogenetic analysis also indicated that the genera Bodo, Cryptobia, Leptomonas, Herpetomonas, Crithidia, and Blastocrithidia are polyphyletic. The results suggested that parasitism of vertebrates has probably arisen independently a number of times within the Trypanosomatidae.     

The tubulin genes of Trypanosoma cruzi

The organization of the alpha- and beta-tubulin genes in the genome of Trypanosoma cruzi have been analysed by Southern blotting using tubulin probes derived from Trypanosoma brucei. The tubulin array appears to be more complex in this organism than in other members of the same family. Some tubulin genes are tightly clustered in an alternating (alpha-beta)n array with a basic repeat unit length of 4.3 kb. However, other pairs of alternating alpha- and beta-tubulin sequences appear to be physically separated from the basic group. This finding indicates that the tubulin gene cluster present in T. cruzi is less perfectly conserved than in T. brucei. T. (Herpetosoma) rangeli is similar to T. (Schizotrypanum) cruzi in its tubulin gene organization whereas most of these genes are tandemly clustered in the genome of T. (Trypanozoon) evansi, with a basic repeat unit length of 3.6 kb as previously described for T. (Trypanozoon) brucei. Two overlapping recombinant clones containing T. cruzi tubulin sequences have been isolated from a genomic cosmid library of T. cruzi epimastigotes using the T. brucei tubulin probes. Partial sequencing of the T. cruzi beta-tubulin gene has confirmed its identity and shows more than 70% homology with the sea urchin, chicken and T. b. rhodesiense beta-tubulin reported gene sequences. Analysis of tubulin gene organization through the parasite life cycle does not show evidence of major rearrangements within the repeat unit. Several T. cruzi strains and cloned lines whilst sharing the 4.3-kb tubulin repeat unit, exhibited very variable tubulin gene organization with tubulin probes. These striking differences in the organization of this structural gene among T. cruzi strains and cloned lines suggest that the heterogeneity previously reported in parasite populations may be related to a very dynamic, diploid genome.     

Trypanosoma rangeli: discrimination from Trypanosoma cruzi based on a variable domain from the large subunit ribosomal RNA gene

306-314. Three synthetic oligonucleotides corresponding to sequences within the D7a divergent domain of the large subunit ribosomal RNA gene have been used to amplify the total DNA of Trypanosoma rangeli and Trypanosoma cruzi, two morphologically similar protozoa with overlapping geographical distribution and hosts. The two organisms may be distinguished by the electrophoretic mobilities of their respective amplification products. For T. rangeli a 210-bp product was obtained. The presence of this fragment was confirmed in 14 T. rangeli strains. For T. cruzi two possible amplification products were originated: a 265-bp DNA fragment for strains typed as lineage 1 and a 250-bp fragment for lineage 2 strains. Eleven unidentified trypanosome stocks, recently isolated from Amazonian vectors, could be discriminated using the proposed assay. The potential field application of multiplex PCR was further demonstrated by identification of the two parasite species in samples containing intestinal tract and feces of triatomines. In the present study we have also amplified the D7a domain of several trypanosomatids employing primers complementary to the conserved flanking regions. Size and sequence polymorphisms were observed, indicating that this region could also be explored as a target for specific detection of other members of the Trypanosomatidae family.     

Characterization of a Trypanosoma cruzi genomic fragment complementary to several species-specific mRNAs but different from the spliced leader sequence

We have isolated a clone of Trypanosoma cruzi genomic DNA, lambda 3b2-5, which contains sequences that are reiterated in the genome. Northern blot analysis showed that clone 3b2-5 hybridizes to 1,200-5,000 bases different mRNA species. The number of mRNAs species hybridized to clone 3b2-5 exceeds its coding capacity showing that this clone carries sequences that are common to several mRNAs species and conserved in the poly A(+) RNA. These sequences are not homologous to the T. cruzi spliced leader sequence, since clone 3b2-5 does not hybridize to a synthetic 20 nucleotide complementary to the spliced leader sequence. Clone 3b2-5 does not hybridize to DNA and RNA from several genera of Trypanosomatidae and other Trypanosoma species indicating that it carries T. cruzi species-specific sequences.     

Trypanosomes are monophyletic: evidence from genes for glyceraldehyde phosphate dehydrogenase and small subunit ribosomal RNA

The genomes of Trypanosoma brucei, Trypanosoma cruzi and Leishmania major have been sequenced, but the phylogenetic relationships of these three protozoa remain uncertain. We have constructed trypanosomatid phylogenies based on genes for glycosomal glyceraldehyde phosphate dehydrogenase (gGAPDH) and small subunit ribosomal RNA (SSU rRNA). Trees based on gGAPDH nucleotide and amino acid sequences (51 taxa) robustly support monophyly of genus Trypanosoma, which is revealed to be a relatively late-evolving lineage of the family Trypanosomatidae. Other trypanosomatids, including genus Leishmania, branch paraphyletically at the base of the trypanosome clade. On the other hand, analysis of the SSU rRNA gene data produced equivocal results, as trees either robustly support or reject monophyly depending on the range of taxa included in the alignment. We conclude that the SSU rRNA gene is not a reliable marker for inferring deep level trypanosome phylogeny. The gGAPDH results support the hypothesis that trypanosomes evolved from an ancestral insect parasite, which adapted to a vertebrate/insect transmission cycle. This implies that the switch from terrestrial insect to aquatic leech vectors for fish and some amphibian trypanosomes was secondary. We conclude that the three sequenced pathogens, T. brucei, T. cruzi and L. major, are only distantly related and have distinct evolutionary histories.     

Antigenic make-up of Trypanosoma cruzi culture forms: identification of a specific component.

A comparison of Trypanosoma cruzi water soluble antigens with those of stercorarian and salivarian trypanosomes, and Leishmania using immunoprecipitation in gels and immunoelectrophoresis, with the aid of hyperimmune rabbit serum and heterologous adsorptions showed the following. 1) There is a high complexity of soluble antigens of T. cruzi and T. rangeli. 2) At the intraspecific level our results demonstrated the antigenic stability of T. cruzi when maintained in vitro, and that there was quantitative antigenic consistency of the culture forms of different strains of T. cruzi from diverse geographic and parasite sources. At the interspecific level, the antigenic relationships between T. cruzi and the other Trypanosomatidae were established, as follows: 6/10ths of the antigens are shared by stercorarian species (T. dionisii, T. rangeli); 4/10ths by a salivarian trypanosome (T. brucei); and 3/10ths by Leishmania (L. donovani, L. mexicana). 3) Among the 4/10ths of antigenic components specific to T. cruzi, one component was characterized by its antigenicity and immunogenicity in natural and experimental infections, and in immunization experiments; this component was specific to T. cruzi when compared to the other Trypanosomatidae antigens.     

Karyotype variability in Trypanosoma cruzi

Like many other protozoam parasites, Trypanosoma cruzi (the causative agent of Chagas disease) has a plastic genome. Chromosome size polymorphisms occur in different strains of T. cruzi as well as among clones originating from the same strain, Despite this polymorphism, major interchromosomal rearrangements appear to be rare since several linkage groups of chromosomal markers are well conserved among different T. cruzi strains. In addition, some correlation has been found between karyotype variability and classification by multilocus enzyme electrophoresis. In this review, Jan Henriksson, Lena Aslund and Ulf Petterson discuss the genomic variability and suggest that amplication of repetitive sequences or members of gene families make a major contribution to the chromosomal size variation     

Molecular characterization of ribonucleoproteic antigens containing repeated amino acid sequences from Trypanosoma cruzi

Trypanosoma cruzi expresses several proteins containing antigenic amino acid repeats. Here we characterized TcRpL7a and TcRBP28, which carry similar repeat motifs and share homology to the eukaryotic L7a ribosomal protein and to a Trypanosoma brucei RNA binding protein, respectively. Analyses of the full length and truncated recombinant TcRpL7a showed that the humoral response of patients with Chagas disease is directed towards its repetitive domain. Sequence analyses of distinct copies of TcRpL7a genes present in the genome of six T. cruzi strains indicate that the number of repeats is higher in proteins from T. cruzi II than T. cruzi I strains. A serum panel of 59 T. cruzi infected patients showed that 73% reacted with TcRpL7a, 71% reacted with TcRBP28 and 80% reacted with 1:1 mixture of both antigens. Synthetic peptides harboring the TcRpL7a repeat motif reacted with 46% of the serum samples. Antibodies raised against both antigens identified equivalent amounts of the native proteins in all three stages of the parasite life cycle. Analyses of subcellular fractions indicated that TcRBP28 is present in the cytoplasm whereas TcRpL7a co-fractionates with polysomes. Confirming their predicted cellular localization, GFP fusions showed that, whereas GFP::TcRBP28 localizes in the cytoplasm, GFP::TcRpL7a accumulates in the nucleus, where ribosome biogenesis occurs.     

Post genomic analysis of permeases from the amino acid/auxin family in protozoan parasites

The "amino acid/auxin permeases" is probably the most represented family of transporters in the Trypanosoma cruzi genome. Using a high-throughput searching routine and preliminary data from the T. cruzi genome project, more than 15,000 sequences were iteratively assembled into contigs, and 60 open reading frames corresponding to different putative amino acid transporters, clustered in 12 groups, were detected and characterized in silico. T. cruzi genomic organization of such sequences showed that these putative amino acid transporter genes are in an unusually large number and arranged in repeat clusters comprising about 0.2% of the genome. These data suggest that the family has evolved following tandem duplication events and constitutes a novel family of variable proteins in protozoan organisms. The mRNA expression of the predicted genes was demonstrated in infective and non-infective parasite forms. Orthologous sequences were also identified in other unicellular parasites such as Leishmania spp., Plasmodium spp., and Trypanosoma brucei.     

Repertoire, genealogy and genomic organization of cruzipain and homologous genes in Trypanosoma cruzi, T. cruzi-like and other trypanosome species

Trypanosoma cruzi, the agent of Chagas disease, is a complex of genetically diverse isolates highly phylogenetically related to T. cruzi-like species, Trypanosoma cruzi marinkellei and Trypanosoma dionisii, all sharing morphology of blood and culture forms and development within cells. However, they differ in hosts, vectors and pathogenicity: T. cruzi is a human pathogen infective to virtually all mammals whilst the other two species are non-pathogenic and bat restricted. Previous studies suggest that variations in expression levels and genetic diversity of cruzipain, the major isoform of cathepsin L-like (CATL) enzymes of T. cruzi, correlate with levels of cellular invasion, differentiation, virulence and pathogenicity of distinct strains. In this study, we compared 80 sequences of genes encoding cruzipain from 25 T. cruzi isolates representative of all discrete typing units (DTUs TcI-TcVI) and the new genotype Tcbat and 10 sequences of homologous genes from other species. The catalytic domain repertoires diverged according to DTUs and trypanosome species. Relatively homogeneous sequences are found within and among isolates of the same DTU except TcV and TcVI, which displayed sequences unique or identical to those of TcII and TcIII, supporting their origin from the hybridization between these two DTUs. In network genealogies, sequences from T. cruzi clustered tightly together and closer to T. c. marinkellei than to T. dionisii and largely differed from homologues of T. rangeli and T. b. brucei. Here, analysis of isolates representative of the overall biological and genetic diversity of T. cruzi and closest T. cruzi-like species evidenced DTU- and species-specific polymorphisms corroborating phylogenetic relationships inferred with other genes. Comparison of both phylogenetically close and distant trypanosomes is valuable to understand host-parasite interactions, virulence and pathogenicity. Our findings corroborate cruzipain as valuable target for drugs, vaccine, diagnostic and genotyping approaches.     

Size fractionation of Trypanosoma brucei DNA: localization of the 177-bp repeat satellite DNA and a variant surface glycoprotein gene in a mini-chromosomal DNA fraction

We have size-fractionated intact DNA from Trypanosoma brucei into a major large DNA fraction (greater than 350S) and minor middle-sized (60-250S) and small (less than 60S) DNA fractions. Large DNA contains the rRNA genes, the basic copy genes for several variant surface glycoproteins (VSGs), including one which lies near a telomer, and the expression-linked copies of the two VSG genes. The middle-sized DNA contains at least one VSG gene, but the hybridization of this fraction with probes for the conserved repetitive sequences that mark the edges of the transposed segments of VSG genes, suggests that it may contain many VSG genes. The 177-bp repeat satellite DNA is also exclusively found in this fraction.     

In vitro growth kinetics of two Trypanosoma cruzi (Kinetoplastida: Trypanosomatidae) clones in myocardial cells from rodents of different susceptibility

In vitro growth kinetics of two Trypanosoma cruzi (Kinetoplastida: Trypanosomatidae) clones in myocardial cells from rodents of different susceptibility. Two Trypanosoma cruzi isolates, TCR-4 from Costa Rica and UES-1 from El Salvador, were studied in vitro to compare their infectivity or resistance and intracellular replication in myocardial cells in three strains of mice and rats: NGP white mice, C3 H mice and Sprague Dowley rats. Myocardial cells were cultured on coverslips at 37 degrees C in a humid 10% CO2 atmosphere and then infected at a ratio of one tripomastigote per cell. Samples were studied after 24, 72, 96 and 120 h of infection to determine parasite infection capacity and intracellular multiplication. Both parasites had the highest infection capacity in C3 H mice, followed by NGP mice cells with a very low infection rate. Lastly, almost no Trypanosoma cruzi multiplication was observed in Sprague Dowley rats, suggesting a strong natural resistance in this animal to both strains of the parasite. The UES-1 isolate presented higher multiplication and greater invasion than the TCR-4 strain, showing greater virulence of UES-1 in heart cells, at least in vitro.     

Trypanosomatidae codon usage and GC distribution.

A study of Trypanosomatidae GC distribution and codon usage is presented. The codon usage patterns in coincidence with the phylogenetical data are similar in Crithidia and Leishmania, whereas they are more divergent in Trypanosoma brucei and T. cruzi. The analysis of the GC mutational pressure in these organisms reveals that T. brucei, and to a lesser extent T. cruzi, have evolved towards a more balanced use of all bases, whereas Leishmania and Crithidia retain features of a primeval genetic apparatus. Tables with the approximated GC mutational pressure in homologous genes, and codon usage in Trypanosomatidae are presented.     

Molecular phylogenetics of Trypanosomatidae: contrasting results from 18S rRNA and protein phylogenies

Phylogenetic analyses of the family Trypanosomatidae have been conducted using both 18S rRNA gene sequences and a variety of protein sequences. Using a variety of phylogenetic methods, 18S rRNA phylogenies indicate that the genus Trypanosoma is not monophyletic. Rather, they suggest that the American and African trypanosomes constitute distinct clades. By contrast, phylogenetic analyses of available sequences in 42 protein families gene generally supported monophyly of the genus Trypanosoma. One possible explanation for these conflicting results is poor taxon sampling in the case of protein coding genes, most of which have been sequenced for only a few species of Trypanosomatidae.