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Long- and Short-Term Selective Forces on Malaria Parasite Genomes

Long- and Short-Term Selective Forces on Malaria Parasite Genomes

Authors :
Thomas D. Otto
Anders Krogh
Daniel C. Jeffares
Stijn van Dongen
Paul P. Gardner
Matthew Berriman
Sanne Nygaard
Gareth Malsen
Arnab Pain
Jon McAuliffe
Emmanouil T. Dermitzakis
Alexander Braunstein
Source :
PLoS Genetics, PLOS Genetics, Vol. 6, No 9 (2010), PLoS Genetics, Vol 6, Iss 9, p e1001099 (2010), Nygaard, S, Braunstein, A, Malsen, G, Van Dongen, S, Gardner, P P, Krogh, A, Otto, T D, Pain, A, Berriman, M, McAuliffe, J, Dermitzakis, E T & Jeffares, D C 2010, ' Long-and short-term selective forces on malaria parasite genomes ', P L o S Genetics, vol. 6, no. 9 . https://doi.org/10.1371/journal.pgen.1001099
Publication Year :
2010
Publisher :
Public Library of Science (PLoS), 2010.

Abstract

Plasmodium parasites, the causal agents of malaria, result in more than 1 million deaths annually. Plasmodium are unicellular eukaryotes with small ∼23 Mb genomes encoding ∼5200 protein-coding genes. The protein-coding genes comprise about half of these genomes. Although evolutionary processes have a significant impact on malaria control, the selective pressures within Plasmodium genomes are poorly understood, particularly in the non-protein-coding portion of the genome. We use evolutionary methods to describe selective processes in both the coding and non-coding regions of these genomes. Based on genome alignments of seven Plasmodium species, we show that protein-coding, intergenic and intronic regions are all subject to purifying selection and we identify 670 conserved non-genic elements. We then use genome-wide polymorphism data from P. falciparum to describe short-term selective processes in this species and identify some candidate genes for balancing (diversifying) selection. Our analyses suggest that there are many functional elements in the non-genic regions of these genomes and that adaptive evolution has occurred more frequently in the protein-coding regions of the genome.<br />Author Summary Malaria causes debilitating ill-health in millions of people and kills about one million people annually, mostly young children. It is caused by a single-cell Plasmodium parasite transmitted to humans via mosquito bites. It is difficult to control this parasite because variable genetic make-up enables it to evade detection by vaccines and because drug resistance has repeatedly evolved. Therefore any progress in our understanding of the evolution and genetic variation of the parasite will be central to controlling the parasite. Genic regions that encode proteins are comparatively easy to characterize, whereas non-genic regions are poorly understood. We compare the genomes of seven distantly-related Plasmodium species and find that some of the non-genic regions are very similar between species. The absence of significant evolutionary differences between these non-genic regions implies that they play an important role in the survival of the organism. We then compare the genomes of thirteen different strains of Plasmodium falciparum. It is currently accepted that several families of antigenic parasite genes evolve rapidly. However, using two methods we demonstrate that many other genes have also undergone adaptive evolution.

Details

ISSN :
15537404 and 15537390
Volume :
6
Database :
OpenAIRE
Journal :
PLoS Genetics
Accession number :
edsair.doi.dedup.....65fd9d1dec14964b6a02af43fd2b2e1b
Full Text :
https://doi.org/10.1371/journal.pgen.1001099