Decay of the glycolytic pathway and adaptation to intranuclear parasitism within Enterocytozoonidae microsporidia

Summary Glycolysis and oxidative phosphorylation are the fundamental pathways of ATP generation in eukaryotes. Yet in microsporidia, endoparasitic fungi living at the limits of cellular streamlining, oxidative phosphorylation has been lost: energy is obtained directly from the host or, during the di...

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Bibliographic Details
Published in:Environmental microbiology 2017-05, Vol.19 (5), p.2077-2089
Main Authors: Wiredu Boakye, Dominic, Jaroenlak, Pattana, Prachumwat, Anuphap, Williams, Tom A., Bateman, Kelly S., Itsathitphaisarn, Ornchuma, Sritunyalucksana, Kallaya, Paszkiewicz, Konrad H., Moore, Karen A., Stentiford, Grant D., Williams, Bryony A. P.
Format: Article
Language:English
Subjects:
Animals
Base Sequence
Biological Evolution
Decapoda
Enterocytozoon
Enterocytozoon - genetics
Enterocytozoon - metabolism
Enterocytozoon - pathogenicity
Enterocytozoonidae
Genome, Protozoan - genetics
Genomes
Glycolysis - genetics
Hexokinase - genetics
Host-Parasite Interactions - physiology
Humans
Microsporidia
Microsporidiosis - parasitology
Mitochondrial DNA
Oxidative Phosphorylation
Pathogens
Penaeidae - parasitology
Phosphorylation
Phylogeny
Sequence Analysis, DNA
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Summary:Summary Glycolysis and oxidative phosphorylation are the fundamental pathways of ATP generation in eukaryotes. Yet in microsporidia, endoparasitic fungi living at the limits of cellular streamlining, oxidative phosphorylation has been lost: energy is obtained directly from the host or, during the dispersive spore stage, via glycolysis. It was therefore surprising when the first sequenced genome from the Enterocytozoonidae – a major family of human and animal‐infecting microsporidians – appeared to have lost genes for glycolysis. Here, we sequence and analyse genomes from additional members of this family, shedding new light on their unusual biology. Our survey includes the genome of Enterocytozoon hepatopenaei, a major aquacultural parasite currently causing substantial economic losses in shrimp farming, and Enterospora canceri, a pathogen that lives exclusively inside epithelial cell nuclei of its crab host. Our analysis of gene content across the clade suggests that Ent. canceri's adaptation to intranuclear life is underpinned by the expansion of transporter families. We demonstrate that this entire lineage of pathogens has lost glycolysis and, uniquely amongst eukaryotes, lacks any obvious intrinsic means of generating energy. Our study provides an important resource for the investigation of host‐pathogen interactions and reductive evolution in one of the most medically and economically important microsporidian lineages.
ISSN:1462-2912
1462-2920
DOI:10.1111/1462-2920.13734