Your search keyword '"genome degradation"' showing total 2 results

1. Kinetoplast adaptations in American strains from Trypanosoma vivax.

Author

Greif, Gonzalo, Rodriguez, Matías, Reyna-Bello, Armando, Robello, Carlos, and Alvarez-Valin, Fernando

Subjects

*KINETOPLASTS, *BIOLOGICAL adaptation, *TRYPANOSOMA, *PHYSIOLOGIC strain, *PHOSPHORYLATION, *BIOLOGICAL evolution

Abstract

The mitochondrion role changes during the digenetic life cycle of African trypanosomes. Owing to the low abundance of glucose in the insect vector (tsetse flies) the parasites are dependent upon a fully functional mitochondrion, capable of performing oxidative phosphorylation. Nevertheless, inside the mammalian host (bloodstream forms), which is rich in nutrients, parasite proliferation relies on glycolysis, and the mitochondrion is partially redundant. In this work we perform a comparative study of the mitochondrial genome (kinetoplast) in different strains of Trypanosoma vivax . The comparison was conducted between a West African strain that goes through a complete life cycle and two American strains that are mechanically transmitted (by different vectors) and remain as bloodstream forms only. It was found that while the African strain has a complete and apparently fully functional kinetoplast, the American T. vivax strains have undergone a drastic process of mitochondrial genome degradation, in spite of the recent introduction of these parasites in America. Many of their genes exhibit different types of mutations that are disruptive of function such as major deletions, frameshift causing indels and missense mutations. Moreover, all but three genes (A6-ATPase, RPS12 and MURF2) are not edited in the American strains, whereas editing takes place normally in all (editable) genes from the African strain. Two of these genes, A6-ATPase and RPS12, are known to play an essential function during bloodstream stage. Analysis of the minicircle population shows that its diversity has been greatly reduced, remaining mostly those minicircles that carry guide RNAs necessary for the editing of A6-ATPase and RPS12. The fact that these two genes remain functioning normally, as opposed to that reported in Trypanosoma brucei -like trypanosomes that restrict their life cycle to the bloodstream forms, along with other differences, is indicative that the American T. vivax strains are following a novel evolutionary pathway. [ABSTRACT FROM AUTHOR]

Published

2015

2. Adaptation and genomic erosion in fragmented Pseudomonas aeruginosa populations in the sinuses of people with cystic fibrosis.

Author

Armbruster, Catherine R., Marshall, Christopher W., Garber, Arkadiy I., Melvin, Jeffrey A., Zemke, Anna C., Moore, John, Zamora, Paula F., Li, Kelvin, Fritz, Ian L., Manko, Christopher D., Weaver, Madison L., Gaston, Jordan R., Morris, Alison, Methé, Barbara, DePas, William H., Lee, Stella E., Cooper, Vaughn S., and Bomberger, Jennifer M.

Abstract

Pseudomonas aeruginosa notoriously adapts to the airways of people with cystic fibrosis (CF), yet how infection-site biogeography and associated evolutionary processes vary as lifelong infections progress remains unclear. Here we test the hypothesis that early adaptations promoting aggregation influence evolutionary-genetic trajectories by examining longitudinal P. aeruginosa from the sinuses of six adults with CF. Highly host-adapted lineages harbored mutator genotypes displaying signatures of early genome degradation associated with recent host restriction. Using an advanced imaging technique (MiPACT-HCR [microbial identification after passive clarity technique]), we find population structure tracks with genome degradation, with the most host-adapted, genome-degraded P. aeruginosa (the mutators) residing in small, sparse aggregates. We propose that following initial adaptive evolution in larger populations under strong selection for aggregation, P. aeruginosa persists in small, fragmented populations that experience stronger effects of genetic drift. These conditions enrich for mutators and promote degenerative genome evolution. Our findings underscore the importance of infection-site biogeography to pathogen evolution. [Display omitted] • Selection favors P. aeruginosa mutations that promote aggregation in the CF sinuses • Aggregation and bottlenecks fragment populations, amplifying effects of genetic drift • Mutators persist in small populations and drive early genome degradation • Population size and infection-site biogeography impact evolutionary trajectories Armbruster et al. find that infection-site biogeography impacts evolution of the opportunistic pathogen, Pseudomonas aeruginosa. In the sinuses of adults with cystic fibrosis, P. aeruginosa residing in large, dense aggregates adaptively evolves, whereas small, sparse aggregates experience greater effects of genetic drift and early stages of degenerative genome evolution. [ABSTRACT FROM AUTHOR]

Published

2021