Gene identification and comparative molecular modeling of a Trypanosoma rangeli major surface protease.

Trypanosoma rangeli is a hemoflagellate parasite which is able to infect humans. Distinct from Trypanosoma cruzi, the causative agent of Chagas disease, T. rangeli is non-pathogenic to the vertebrate host. The manner by which the T. rangeli interacts with the host is still unknown, but it certainly depends on the surface molecules. Major surface proteins (MSP) are GPI-anchored, zinc-dependent metalloproteases present in the surface of all trypanosomatids studied so far, which are implicated as virulence factors in pathogenic trypanosomatids, such as Leishmania spp and T. cruzi. The aims of this work were to generate the complete sequence of a T. rangeli MSP (TrMSP) gene and to determine the 3D-structure of the predicted protein by homology modeling. The plasmid bearing a complete copy of a TrMSP gene was completely sequenced and the predicted protein was modeled using Modeller software. Results indicate that TrMSP open reading frame (ORF) codes for a predicted 588 amino acid protein and shows all elements required for its posttranslational processing. Multiple sequence alignment of TrMSP with other trypanosomatids' MSPs showed an extensive conservation of the N-terminal and central regions and a more divergent C-terminal region. Leishmania major MSP (LmMSP), which had its crystal structure previously determined, has an overall 35% identity with TrMSP. This identity allowed the comparative molecular modeling of TrMSP, which demonstrated a high degree of structural conservation between MSPs from other trypanosomatids (TrypMSPs). All modeled MSPs have a conserved folding pattern, apart from structural divergences in the C-domain and discrete differences of charge and topology in the catalytic cleft, and present the same geometry of the canonical HEXXH zinc-binding motif. The determination of surface charges of the molecules revealed that TrMSP is a predominantly positive protein, whereas LmMSP and Trypanosoma cruzi MSP (TcMSP) are negative proteins, suggesting that substrates recognized by TcMSP and LmMSP could not interact with TrMSP. Moreover, the comparison between TrMSP and TcMSP protein sequences has revealed 45 non-neutral amino acid substitutions, which can be further assessed through protein engineering. The characteristics of TrMSP could explain, at least in part, the lack of pathogenicity of T. rangeli to humans and point to the necessity of identifying the biological targets of this enzyme.

Genome survey sequence analysis and identification of homologs of major surface protease (gp63) genes in Trypanosoma rangeli.

In this study, 222 genome survey sequences were generated for Trypanosoma rangeli strain P07 isolated from an opossum (Didelphis albiventris) in Minas Gerais State, Brazil. T. rangeli sequences were compared by BLASTX (Basic Local Alignment Search Tool X) analysis with the assembled contigs of Leishmania braziliensis, Leishmania infantum, Leishmania major, Trypanosoma brucei, and Trypanosoma cruzi. Results revealed that 82% (182/222) of the sequences were associated with predicted proteins described, whereas 18% (40/222) of the sequences did not show significant identity with sequences deposited in databases, suggesting that they may represent T. rangeli-specific sequences. Among the 182 predicted sequences, 179 (80.6%) had the highest similarity with T. cruzi, 2 (0.9%) with T. brucei, and 1 (0.5%) with L. braziliensis. Computer analysis permitted the identification of members of various gene families described for trypanosomatids in the genome of T. rangeli, such as trans-sialidases, mucin-associated surface proteins, and major surface proteases (MSP or gp63). This is the first report identifying sequences of the MSP family in T. rangeli. Multiple sequence alignments showed that the predicted MSP of T. rangeli presented the typical characteristics of metalloproteases, such as the presence of the HEXXH motif, which corresponds to a region previously associated with the catalytic site of the enzyme, and various cysteine and proline residues, which are conserved among MSPs of different trypanosomatid species. Reverse transcriptase-polymerase chain reaction analysis revealed the presence of MSP transcripts in epimastigote forms of T. rangeli.

Karyotype variability in KP1(+) and KP1(-) strains of Trypanosoma rangeli isolated in Brazil and Colombia.

In the present study, the molecular karyotypes of 12 KP1(+) and KP1(-) Trypanosoma rangeli strains were determined and 10 different molecular markers were hybridized to the chromosomes of the parasite, including seven obtained from T. rangeli [ubiquitin hydrolase (UH), a predicted serine/threonine protein kinase (STK), hexose transporter, hypothetical protein, three anonymous sequences] and three from Trypanosoma cruzi [ubiquitin-conjugating enzyme E2 (UBE2), ribosomal RNA methyltransferase (rRNAmtr), proteasome non-ATPase regulatory subunit 6 (PSMD6)]. Despite intraspecific variation, analysis of the karyotype profiles permitted the division of the T. rangeli strains into two groups coinciding with the KP1(+) and KP1(-) genotypes. Southern blot hybridization showed that, except for the hexose transporter probe, all other probes produced distinct patterns able to differentiate the KP1(+) and KP1(-) genotypes. The UH, STK and An-1A04 probes exclusively hybridized to the chromosomes of KP1(+) strains and can be used as markers of this group. In addition, the UBE2, rRNAmtr and PSMD6 markers, which are present in a conserved region in all trypanosomatid species sequenced so far, co-hybridized to the same T. rangeli chromosomal bands, suggesting the occurrence of gene synteny in these species. The finding of distinct molecular karyotypes in KP1(+) and KP1(-) strains of T. rangeli is noteworthy and might be used as a new approach to the study of genetic variability in this parasite. Together with the Southern blot hybridization results, these findings demonstrate that differences at the kDNA level might be associated with variations in nuclear DNA.

Human urine stimulates in vitro growth of Trypanosoma cruzi and Trypanosoma rangeli.

Previous studies conducted in Leishmania led us to test the hypothesis that addition of human urine (HU) to the Liver Infusion Tryptose (LIT) medium would stimulate the in vitro growth of Trypanosoma cruzi and Trypanosoma rangeli strains. Herein, we show that the addition of 3% HU to LIT medium (LIT-HU3) significantly stimulated the growth of all the T. rangeli strains studied when compared with the parasite growth in conventional LIT medium (p<0.05), and it was equivalent to the growth observed in LIT supplemented with fetal calf serum (FCS) in two parasite strains. Four out of the six T. cruzi strains analyzed showed a significant increase in parasite multiplication in LIT-HU3 (p<0.05). However, two parasite strains presented good growth in both LIT and LIT-HU, suggesting differences in the parasite's ability to grow in vitro. Furthermore, we have not observed differences in T. cruzi growth in LIT-HU3 and LIT supplemented with heat-denatured HU and in the metacyclogenesis of parasite strains cultured in LIT-HU3. These results allow concluding that the addition of HU to LIT medium stimulates the in vitro growth of T. rangeli and T. cruzi and can replace FCS as a supplement in culture medium.