Restriction fragment length polymorphism of 195 bp repeated satellite DNA of Trypanosoma cruzi supports the existence of two phylogenetic groups

New insights into Trypanosoma cruzi genetic diversity, and its influence on parasite biology and clinical outcomes

Chagas disease, caused by Trypanosoma cruzi, remains a serious public health problem worldwide. The parasite was subdivided into six distinct genetic groups, called "discrete typing units" (DTUs), from TcI to TcVI. Several studies have indicated that the heterogeneity of T. cruzi species directly affects the diversity of clinical manifestations of Chagas disease, control, diagnosis performance, and susceptibility to treatment. Thus, this review aims to describe how T. cruzi genetic diversity influences the biology of the parasite and/or clinical parameters in humans. Regarding the geographic dispersion of T. cruzi, evident differences were observed in the distribution of DTUs in distinct areas. For example, TcII is the main DTU detected in Brazilian patients from the central and southeastern regions, where there are also registers of TcVI as a secondary T. cruzi DTU. An important aspect observed in previous studies is that the genetic variability of T. cruzi can impact parasite infectivity, reproduction, and differentiation in the vectors. It has been proposed that T. cruzi DTU influences the host immune response and affects disease progression. Genetic aspects of the parasite play an important role in determining which host tissues will be infected, thus heavily influencing Chagas disease's pathogenesis. Several teams have investigated the correlation between T. cruzi DTU and the reactivation of Chagas disease. In agreement with these data, it is reasonable to suppose that the immunological condition of the patient, whether or not associated with the reactivation of the T. cruzi infection and the parasite strain, may have an important role in the pathogenesis of Chagas disease. In this context, understanding the genetics of T. cruzi and its biological and clinical implications will provide new knowledge that may contribute to additional strategies in the diagnosis and clinical outcome follow-up of patients with Chagas disease, in addition to the reactivation of immunocompromised patients infected with T. cruzi.

Trypanosoma cruzi: multiplex PCR to detect and classify strains according to groups I and II

A multiplex PCR was developed for simultaneous detection of Trypanosoma cruzi DNA and classification of the parasite strain into groups I and II. As little as 10fg of T. cruzi DNA could be detected by multiplex PCR. The technique was shown to be specific for T. cruzi DNA, since no PCR amplification products were obtained with DNA from other tripanosomatid species. Multiplex PCR was validated by assaying genomic DNA from 34 strains of T. cruzi that had been previously characterized; 24 blood samples from experimentally-infected mice and non-infected controls; 20 buffy coat samples from patients in the acute phase of Chagas disease and non-infected individuals, and 15 samples of feces from naturally-infected Triatoma infestans. T. cruzi samples from patients and from Y strain-infected mice were classified by multiplex PCR as T. cruzi II and samples from T. infestans and Colombiana strain-infected mice as T. cruzi I.

Trypanosoma cruzi: an analysis of the minicircle hypervariable regions diversity and its influence on strain typing

The current intraspecific nomenclature in Trypanosoma cruzi describes two major lineages, named T. cruzi I and T. cruzi II, and five sublineages within T. cruzi II, named IIa, IIb, IIc, IId and IIe. The polymorphism of minicircle hypervariable regions (mHVRs) of T. cruzi has been used in many studies for the molecular characterization of parasite populations directly from biological samples. However, the molecular bases that allow strain typing by these markers are still unclear. In this work we examined forty cloned mHVRs sequences of CL-Brener reference strain (IIe sublineage), and we found a predominant group of sequences, with 40% of frequency in this strain, with a 97% of identity among them. Out of the forty clones analyzed, we identified other less representative types, and a few unique ones. This predominant sequence is also present in different reference strains belonging to the other main T. cruzi lineages and sublineages (TcI, IIa, IIb, IIc and IId) although in a many thousand times lower frequency than in the CL-Brener strain, as shown by semiquantitative PCR. Similarly, predominant mHVR sequences previously described for TcIId strains, were clearly more frequent (many thousand times higher) in the IId reference strain analyzed by us (Mncl2) than within the reference strains belonging to the other lineages and sublineages. The analysis of the cloned sequences shows that more sequences than just the major one contribute to define the global pattern of mHVRs RFLP in the CL-Brener strain. The possible usefulness of these predominant sequences for typing TcIId and TcIIe sublineages by semiquantitative PCR, as well as the possible role of these sequences in genotype identification by mHVR probes are discussed.

Trypanosoma cruzi: Subtractive hybridization as a molecular strategy to generate new targets to distinguish groups and hybrids

RAPD analysis and sequences of the mini-exon and ribosomal genes show that Trypanosoma cruzi can be clustered into two phylogenetic groups-T. cruzi I and II. Herein, the Representational Difference Analysis (RDA) method was used, providing new targets specific for each group. After three rounds of RDA hybridizing F strain (tester) with Y strain (driver) and vice-versa, an F-specific (F#30) and Y-specific (Y#22) clone were obtained specifically recognizing isolates from Amazonas (T. cruzi I) and Piauí (T. cruzi II). These segments corresponded to an unspecified protein (F#30) and a trans-sialidase (Y#22). Analysis of the F#30 sequence in T. cruzi I, T. cruzi II and zymodeme 3 samples displayed negligible specific differences that distinguished each group. In addition this F#30 gene has great potential as a hybrid marker.

Molecular phylogeny of Trypanosoma cruzi from Central America (Guatemala) and a comparison with South American strains

Molecular phylogenetic analysis was carried out for 21 strains of Trypanosoma cruzi, nine of which were obtained from Guatemala and 12 from South America. Phylogenetic trees were constructed using the nucleotide sequences of two nuclear gene regions, dihydrofolate reductase-thymidylate synthase (DHFR-TS) and trypanothione reductase (TR), and contiguous portions of two mitochondrial genes, cytochrome oxidase subunit II (COII) and reduced nicotinamide adenine dinucleotide dehydrogenase subunit 1 (ND1). Possible genetic exchange between the rather divergent lineages of T. cruzi II from South America was suggested in the trees of the two nuclear genes. T. cruzi I strains obtained from Guatemala and Colombia were identical in all the genes examined, but other T. cruzi I isolates from South America were rather polymorphic in the DHFR-TS and mitochondrial genes. No genetic exchange was identified between T. cruzi I populations from Central and South America in the present study.

Identification of Trypanosoma cruzi sublineages by the simple method of single-stranded conformation DNA polymorphism (SSCP)

Fifty-eight stocks of Trypanosoma cruzi from Latin America were genetically characterized using the methods of the polymerase chain reaction (PCR) and the single-stranded conformation DNA polymorphism (SSCP) with four genes, mini-exon, 24Salpha rRNA, 18Sr RNA, cruzipain, and a RAPD fragment DNA region, P7-P8. All the isolates examined were assigned to T. cruzi I or subgroups of T. cruzi II by these methods. From these results, the SSCP analysis, which was simple to perform and highly sensitive to sequence variation, seemed to be a good modality for characterizing T. cruzi, particularly for subgroups of T. cruzi II. However, in several isolates of T. cruzi II, the subgroups determined with the SSCP of 24Salpha rRNA were not consistent with those determined with other genes, the SSCP of 18S rRNA and cruzipain, and the PCR of P7-P8, possibly because of the occurrence of rare genetic exchanges or mutations or both in natural populations of this parasite. The SSCP patterns of 24Salpha rRNA and 18S rRNA were highly variable in the T. cruzi I isolates; therefore, analyses using both genes are considered to be one possible method for the characterization of isolates within T. cruzi I.

Genotypic variation among lineages of Trypanosoma cruzi and its geographic aspects

Isozyme analysis with 18 enzyme loci was conducted on 146 isolates of Trypanosoma cruzi from Mexico, Guatemala, Colombia, Ecuador, Peru, Brazil, Bolivia, Paraguay and Chile. Forty-four different MLGs (groups of isolates with identical multilocus genotypes) were identified and a phylogeny was constructed. The phylogenetic tree consisted of two main groups (T. cruzi I, T. cruzi II), and the latter was further divided into two subgroups (T. cruzi IIa, T. cruzi IIb-e). Evidence of hybridization between different MLGs of T. cruzi II was found, which means that genetic exchanges seem to have occurred in South American T. cruzi. On the other hand, the persistence of characteristic T. cruzi I and T. cruzi II isozyme patterns in single small villages in Bolivia and Guatemala suggested that genetic exchange is very rare between major lineages. A significant difference in genetic diversity was shown between T. cruzi I and T. cruzi II from several indices of population genetics. Two possibilities could explain this genetic variation in the population: differences in evolutionary history and/or different tendencies to exchange genetic material. Broad-scale geographic distributions of T. cruzi I and T. cruzi IIb-e were different; T. cruzi I occurred in Central America and south to Bolivia and Brazil, while T. cruzi IIb-e occurred in the central and southern areas of South America, overlapping with T. cruzi I in Brazil and Bolivia.

Comparison of polymerase chain reaction methods for reliable and easy detection of congenital Trypanosoma cruzi infection

The polymerase chain reaction (PCR) is a potentially interesting diagnostic tool for detecting congenital Trypanosoma cruzi infection at birth. We have compared the sensitivity and capacity of a group of T. cruzi PCR primers in detecting the complete spectrum of known T. cruzi lineages, and to improve and simplify the detection of infection in neonatal blood. We found that the two primers, Tcz1/Tcz2 and Diaz1/Diaz2, which target the 195-basepair satellite repeat, detected all parasitic lineages with the same sensitivity. However, the intensity of the amplicon was somewhat higher with Tcz1/Tcz2. For other tested primers (nuclear DNA primers BP1/BP2, O1/O2, Pon1/Pon2, and Tca1/Tca2 and kinetoplast DNA primers S35'/S36' and 121/122), either the intensity of amplicons varied according to T. cruzi lineages or the PCR assay was less sensitive. The use of the Tcz1/Tcz2 primers, which target a tandem repetitive sequence, requires a careful determination of the appropriate amount of Taq polymerase to avoid the formation of smears and multiple amplicon bands. The Tcz1/Tcz2 primers resulted in an intense 200-basepair amplicon with DNA extracted from blood equivalent to 0.02 parasites per assay when used with a simple DNA extraction method and of a low amount of Taq polymerase from a standard PCR kit. To better assess such PCR protocol, we assayed 311 samples of neonatal blood previously tested by parasitologic methods. The reliability of our PCR test was demonstrated, since all the 18 blood samples from newborns with congenital T. cruzi infection were positive, whereas the remaining samples (30 from control newborns of uninfected mothers and 262 of 263 from babies born to infected mothers) were negative. Since our PCR method is simple, reliable, robust, and inexpensive, it appears suitable for the detection of T. cruzi infection in neonatal blood, even in laboratories that are not equipped for performing the PCR.

Evidence for multiple hybrid groups in Trypanosoma cruzi

A role for parasite genetic variability in the spectrum of Chagas disease is emerging but not yet evident, in part due to an incomplete understanding of the population structure of Trypanosoma cruzi. To investigate further the observed genotypic variation at the sequence and chromosomal levels in strains of standard and field-isolated T. cruzi we have undertaken a comparative analysis of 10 regions of the genome from two isolates representing T. cruzi I (Dm28c and Silvio X10) and two from T. cruzi II (CL Brener and Esmeraldo). Amplified regions contained intergenic (non-coding) sequences from tandemly repeated genes. Multiple nucleotide polymorphisms correlated with the T. cruzi I/T. cruzi II classification. Two intergenic regions had useful polymorphisms for the design of classification probes to test on genomic DNA from other known isolates. Two adjacent nucleotide polymorphisms in HSP 60 correlated with the T. cruzi I and T. cruzi II distinction. 1F8 nucleotide polymorphisms revealed multiple subdivisions of T. cruzi II: subgroups IIa and IIc displayed the T. cruzi I pattern; subgroups IId and IIe possessed both the I and II patterns. Furthermore, isolates from subgroups IId and IIe contained the 1F8 polymorphic markers on different chromosome bands supporting a genetic exchange event that resulted in chromosomes V and IX of T. cruzi strain CL Brener. Based on these analyses, T. cruzi I and subgroup IIb appear to be pure lines, while subgroups IIa/IIc and IId/IIe are hybrid lines. These data demonstrate for the first time that IIa/IIc are hybrid, consistent with the hypothesis that genetic recombination has occurred more than once within the T. cruzi lines.

Characterisation of large and small subunit rRNA and mini-exon genes further supports the distinction of six Trypanosoma cruzi lineages

It has been proposed that isolates of Trypanosoma cruzi, the agent of American trypanosomiasis, can be ordered into two primary phylogenetic lineages, first based on multilocus enzyme electrophoresis and random amplified polymorphic DNA, and subsequently based on the 24Salpha rRNA and mini-exon genes. Recent multilocus enzyme electrophoresis and random amplified polymorphic DNA data have additionally shown that the major multilocus enzyme electrophoresis/random amplified polymorphic DNA lineage II is further subdivided into five smaller lineages, designated IIa-IIe. In this study, the precise correspondence between the multilocus enzyme electrophoresis/random amplified polymorphic DNA and rRNA/mini-exon lineages was investigated. Using the 24Salpha rRNA and mini-exon markers in combination, five sets of strains were distinguished, corresponding to the multilocus enzyme electrophoresis/random amplified polymorphic DNA lineages I, IIa, IIc, IId and to lineages IIb/IIe together, respectively. The previous categorisation into only two primary lineages based on 24Salpha rRNA and mini-exon characterisation is explained, in part, by the lack of representativeness of the breadth of T. cruzi diversity in earlier study samples. Additionally, a PCR assay based on a length-variable region of the 18S rRNA gene distinguished lineage IIe from lineage IIb. Thus, the six multilocus enzyme electrophoresis/random amplified polymorphic DNA lineages could be readily identified by combining data from the 24Salpha rRNA, mini-exon and 18S rRNA characterisation assays, further supporting the relevance of these genetic units for T. cruzi strain classification and subspecific nomenclature. The recently proposed groups T. cruzi I and T. cruzi II correspond to multilocus enzyme electrophoresis/random amplified polymorphic DNA lineages I and IIb, respectively. Our findings show that T. cruzi lineage characterisation based on a single marker (either mini-exon or 24Salpha rRNA) has insufficient resolution, and leads to important reinterpretations of recent epidemiological and evolutionary studies based on the oversimplified rRNA/mini-exon dichotomic classification of T. cruzi isolates.

Selection of Trypanosoma cruzi clonal genotypes (clonet 20 and 39) isolated from Bolivian triatomines following subculture in liquid medium

Previous studies showed that two groups of Trypanosoma cruzi clonal genotypes named clonet 20 and clonet 39 were predominant in Triatoma infestans, the unique vector of Chagas disease in Bolivia. These groups of clones correspond to distinct genetic clusters. These clonets were detected in T. infestans and Rhodnius pictipes fecal samples before isolation and after culture by kDNA PCR (polymerase chain reaction) and hybridization of the amplified products with clonet specific kDNA probes named 20 and 39 as previously reported. Forty eight T. infestans and three R. pictipes infected insects captured at random in different Bolivian departments were proceeded. As previously reported the direct identification of the two major clonets in fecal samples allowed the detection of abundant mixed infections: 41% in the original sample, however after culture, only 6% of mixed infections were detected. Among the 21 parasite stocks isolated from digestive tracts where mixed infections were initially detected (clonet 20 + 39) clonet 20 alone was detected in 81% of them. This result clearly showed that the culture step selected clonet 20 parasites over those belonging to clonet 39. The taxonomic status of the isolated stocks was also confirmed by isoenzyme typing, and correlation was observed between clustering topology and hybridization patterns with the probes 20 and 39.

The ecotopes and evolution of triatomine bugs (triatominae) and their associated trypanosomes

Triatomine bug species such as Microtriatoma trinidadensis, Eratyrus mucronatus, Belminus herreri, Panstrongylus lignarius, and Triatoma tibiamaculata are exquisitely adapted to specialist niches. This suggests a long evolutionary history, as well as the recent dramatic spread a few eclectic, domiciliated triatomine species. Virtually all species of the genus Rhodnius are primarily associated with palms. The genus Panstrongylus is predominantly associated with burrows and tree cavities and the genus Triatoma with terrestrial rocky habitats or rodent burrows. Two major sub-divisions have been defined within the species Trypanosoma cruzi, as T. cruzi 1 (Z1) and T. cruzi 2 (Z2). The affinities of a third group (Z3) are uncertain. Host and habitat associations lead us to propose that T. cruzi 1 (Z1) has evolved in an arboreal, palm tree habitat with the triatomine tribe Rhodniini, in association with the opossum Didelphis. Similarly we propose that T. cruzi (Z2) and Z3 evolved in a terrestrial habitat in burrows and in rocky locations with the triatomine tribe Triatomini, in association with edentates, and/or possibly ground dwelling marsupials. Both sub-divisions of T. cruzi may have been contemporary in South America up to 65 million years ago. Alternatively, T. cruzi 2 (Z2) may have evolved more recently from T. cruzi 1 (Z1) by host transfers into rodents, edentates, and primates. We have constructed a molecular phylogeny of haematophagous vectors, including triatomine bugs, which suggests that faecal transmission of trypanosomes may be the ancestral route. A molecular clock phylogeny suggests that Rhodnius and Triatoma diverged before the arrival, about 40 million years ago, of bats and rodents into South America.

Evolutionary relationships in Trypanosoma cruzi: molecular phylogenetics supports the existence of a new major lineage of strains

For the purpose of investigating the evolutionary relationships among strains of the human parasite Trypanosoma cruzi, we have determined the nucleotide sequence, in 16 T. cruzi stocks, of a DNA fragment having approximately 1030 nucleotides in length. Phylogenetic analyses show the presence of at least three major groups of T. cruzi strains, a result that contradicts previous phylogenetic inferences based on polymorphism data. We also performed an analysis of the relative extent of nucleotide divergence among T. cruzi strains compared to the divergence between Leishmania species, using the gene encoding pteridine reductase. The results presented in this work show that the divergence among the most distant T. cruzi strains is at least as high as the divergence between two different species complexes of Leishmania, those containing L. major and L. mexicana.