Your search keyword '"Rita de Cássia Moreira de Souza"' showing total 2 results

1. Maxicircle architecture and evolutionary insights into Trypanosoma cruzi complex

Author

Florencia Díaz-Viraqué, Sebastián Pita, Paula Faral-Tello, Fernando Alvarez-Valin, Gustavo Adolfo Vallejo, Luisa Berná, Gonzalo Greif, Carlos Robello, and Rita de Cássia Moreira de Souza

Subjects

RC955-962, Protozoan Proteins, Biochemistry, Guide RNA, Arctic medicine. Tropical medicine, Coding region, Clade, Phylogeny, Energy-Producing Organelles, Data Management, Protozoans, Genetics, Phylogenetic tree, biology, NADH dehydrogenase, Eukaryota, Phylogenetic Analysis, Genomics, Mitochondria, Phylogenetics, Nucleic acids, Infectious Diseases, Cellular Structures and Organelles, Public aspects of medicine, RA1-1270, Research Article, Trypanosoma, Computer and Information Sciences, Nuclear gene, Trypanosoma cruzi, Bioenergetics, Minicircle, Evolution, Molecular, Trypanosoma Brucei, Humans, Chagas Disease, Evolutionary Systematics, Gene, Taxonomy, Evolutionary Biology, Organisms, Public Health, Environmental and Occupational Health, Genetic Variation, Biology and Life Sciences, NADH Dehydrogenase, Cell Biology, biology.organism_classification, Parasitic Protozoans, Kinetoplasts, biology.protein, RNA, Genome, Protozoan, Trypanosoma Brucei Gambiense

Abstract

We sequenced maxicircles from T. cruzi strains representative of the species evolutionary diversity by using long-read sequencing, which allowed us to uncollapse their repetitive regions, finding that their real lengths range from 35 to 50 kb. T. cruzi maxicircles have a common architecture composed of four regions: coding region (CR), AT-rich region, short (SR) and long repeats (LR). Distribution of genes, both in order and in strand orientation are conserved, being the main differences the presence of deletions affecting genes coding for NADH dehydrogenase subunits, reinforcing biochemical findings that indicate that complex I is not functional in T. cruzi. Moreover, the presence of complete minicircles into maxicircles of some strains lead us to think about the origin of minicircles. Finally, a careful phylogenetic analysis was conducted using coding regions of maxicircles from up to 29 strains, and 1108 single copy nuclear genes from all of the DTUs, clearly establishing that taxonomically T. cruzi is a complex of species composed by group 1 that contains clades A (TcI), B (TcIII) and D (TcIV), and group 2 (1 and 2 do not coincide with groups I and II described decades ago) containing clade C (TcII), being all hybrid strains of the BC type. Three variants of maxicircles exist in T. cruzi: a, b and c, in correspondence with clades A, B, and C from mitochondrial phylogenies. While A and C carry maxicircles a and c respectively, both clades B and D carry b maxicircle variant; hybrid strains also carry the b- variant. We then propose a new nomenclature that is self-descriptive and makes use of both the phylogenetic relationships and the maxicircle variants present in T. cruzi.

Published

2021

2. Nanopore sequencing significantly improves genome assembly of the eukaryotic protozoan parasite Trypanosoma cruzi

Author

Gonzalo Greif, Rita de Cássia Moreira de Souza, Gregorio Iraola, Carlos Robello, Sebastián Pita, and Florencia Díaz-Viraqué

Subjects

Transposable element, 0303 health sciences, 030231 tropical medicine, Sequence assembly, Computational biology, Biology, biology.organism_classification, Genome, 03 medical and health sciences, 0302 clinical medicine, Minion, parasitic diseases, Coding region, Nanopore sequencing, Trypanosoma cruzi, Gene, 030304 developmental biology

Abstract

Chagas disease was described by Carlos Chagas, who first identified the parasite Trypanosoma cruzi from a two-year-old girl called Berenice. Many T. cruzi sequencing projects based on short reads have demonstrated that genome assembly and downstream comparative analyses are extremely challenging in this species, given that half of its genome is composed of repetitive sequences. Here, we report de novo assemblies, annotation and comparative analyses of the Berenice strain using a combination of Illumina short reads and MinION long reads. Our work demonstrates that Nanopore sequencing improves T. cruzi assembly contiguity and increases the assembly size in ~16 Mb. Specifically, we found that assembly improvement also refines the completeness of coding regions for both single copy genes and repetitive transposable elements. Beyond its historical and epidemiological importance, Berenice constitutes a fundamental resource since it now represents the best-quality assembly available for TcII, a highly prevalent lineage causing human infections in South America. The availability of Berenice genome expands the known genetic diversity of T. cruzi and facilitates more comprehensive evolutionary inferences. Our work represents the first report of Nanopore technology used to resolve complex protozoan genomes, supporting its subsequent application for improving trypanosomatid and other highly repetitive genomes.

Published

2018