The genomes of four tapeworm species reveal adaptations to parasitism

Isheng Jason Tsai; Magdalena Zarowiecki; Nancy Holroyd; Alejandro Garcíarrubio; Alejandro Sánchez‐Flores; Karen Brooks; Alan Tracey; Raúl J. Bobes; Gladis Fragoso; Edda Sciutto; Martin Aslett; Helen Beasley; Hayley M. Bennett; Jianping Cai; Federico Camicia; Richard Clark; Marcela Cucher; Nishadi De Silva; Tim A. Day; Peter Deplazes; Karel Estrada; Cecilia Fernández; Peter W. H. Holland; Junling Hou; Songnian Hu; Thomas Huckvale; Stacy Hung; Laura Kamenetzky; Jacqueline A. Keane; Ferenc Kiss; Uriel Koziol; Olivia J. Lambert; Kan Liu; Xuenong Luo; Yingfeng Luo; Natalia Macchiaroli; Sarah Nichol; Jordi Paps; John Parkinson; Natasha Pouchkina-Stantcheva; Nick Riddiford; Mara Cecília Rosenzvit; Gustavo Salinas; James D. Wasmuth; Mostafa Zamanian; Yadong Zheng; Xuepeng Cai; Xavier Soberón; Peter D. Olson; Juan Pedro Laclette; Klaus Brehm; Matthew Berriman

doi:10.1038/nature12031

The genomes of four tapeworm species reveal adaptations to parasitism

Isheng Jason Tsai(Wellcome Sanger Institute), Magdalena Zarowiecki(Wellcome Sanger Institute), Nancy Holroyd(Wellcome Sanger Institute), Alejandro Garcíarrubio(Universidad Nacional Autónoma de México), Alejandro Sánchez‐Flores(Wellcome Sanger Institute), Karen Brooks(Wellcome Sanger Institute), Alan Tracey(Wellcome Sanger Institute), Raúl J. Bobes(Universidad Nacional Autónoma de México), Gladis Fragoso(Universidad Nacional Autónoma de México), Edda Sciutto(Universidad Nacional Autónoma de México), Martin Aslett(Wellcome Sanger Institute), Helen Beasley(Wellcome Sanger Institute), Hayley M. Bennett(Wellcome Sanger Institute), Jianping Cai(Lanzhou Veterinary Research Institute), Federico Camicia(Consejo Nacional de Investigaciones Científicas y Técnicas), Richard Clark(Wellcome Sanger Institute), Marcela Cucher(Consejo Nacional de Investigaciones Científicas y Técnicas), Nishadi De Silva(Wellcome Sanger Institute), Tim A. Day(Iowa State University), Peter Deplazes(University of Zurich), Karel Estrada(Universidad Nacional Autónoma de México), Cecilia Fernández(Universidad de la República de Uruguay), Peter W. H. Holland(University of Oxford), Junling Hou(Lanzhou Veterinary Research Institute), Songnian Hu(Chinese Academy of Sciences), Thomas Huckvale(Wellcome Sanger Institute), Stacy Hung(University of Toronto), Laura Kamenetzky(Consejo Nacional de Investigaciones Científicas y Técnicas), Jacqueline A. Keane(Wellcome Sanger Institute), Ferenc Kiss(University of Würzburg), Uriel Koziol(University of Würzburg), Olivia J. Lambert(Wellcome Sanger Institute), Kan Liu(Chinese Academy of Sciences), Xuenong Luo(Lanzhou Veterinary Research Institute), Yingfeng Luo(Chinese Academy of Sciences), Natalia Macchiaroli(Consejo Nacional de Investigaciones Científicas y Técnicas), Sarah Nichol(Wellcome Sanger Institute), Jordi Paps(University of Oxford), John Parkinson(University of Toronto), Natasha Pouchkina-Stantcheva(Natural History Museum), Nick Riddiford(Natural History Museum), Mara Cecília Rosenzvit(Consejo Nacional de Investigaciones Científicas y Técnicas), Gustavo Salinas(Universidad de la República de Uruguay), James D. Wasmuth(University of Calgary), Mostafa Zamanian(McGill University), Yadong Zheng(Lanzhou Veterinary Research Institute), Xuepeng Cai(Lanzhou Veterinary Research Institute), Xavier Soberón(National Institute of Genomic Medicine), Peter D. Olson(Natural History Museum), Juan Pedro Laclette(Universidad Nacional Autónoma de México), Klaus Brehm(University of Würzburg), Matthew Berriman(Wellcome Sanger Institute)

Nature

March 12, 2013

10.1038/nature12031

Cited by 814Open Access

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Abstract

Tapeworms (Cestoda) cause neglected diseases that can be fatal and are difficult to treat, owing to inefficient drugs. Here we present an analysis of tapeworm genome sequences using the human-infective species Echinococcus multilocularis, E. granulosus, Taenia solium and the laboratory model Hymenolepis microstoma as examples. The 115- to 141-megabase genomes offer insights into the evolution of parasitism. Synteny is maintained with distantly related blood flukes but we find extreme losses of genes and pathways that are ubiquitous in other animals, including 34 homeobox families and several determinants of stem cell fate. Tapeworms have specialized detoxification pathways, metabolism that is finely tuned to rely on nutrients scavenged from their hosts, and species-specific expansions of non-canonical heat shock proteins and families of known antigens. We identify new potential drug targets, including some on which existing pharmaceuticals may act. The genomes provide a rich resource to underpin the development of urgently needed treatments and control. Genome sequences of human-infective tapeworm species reveal extreme losses of genes and pathways that are ubiquitous in other animals, species-specific expansions of non-canonical heat shock proteins and families of known antigens, specialized detoxification pathways, and metabolism that relies on host nutrients; this information is used to identify new potential drug targets. Tapeworms cause echinococcosis and cysticercosis, two of the most severe parasitic diseases found in humans, and both on the World Health Organization's list of neglected tropical diseases. The publication of four tapeworm genome sequences — human-infective tapeworm species Echinococcus multilocularis, E. granulosus, Taenia solium and the laboratory model Hymenolepis microstoma — and identification of potential new drug targets for treating tapeworm infections is therefore a welcome development. Analysis of the sequences provides insights into the evolution of parasitism and reveals extreme losses of genes and pathways ubiquitous in other animals on one hand and species-specific expansions of genes on the other. More than a thousand E. multilocularis proteins emerge as potential targets, and of these, close to 200 with the highest scores may be targeted with existing pharmaceuticals.

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