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The Microsporidian Polar Tube and Spore WallWeiss, Louis M., Delbac, Frédéric, Hayman, J. Russell, Pan, Guoqing, Dang, Xiaoqun, Zhou, Zeyang 20 October 2014 (has links)
All of the members of the microsporidia possess a unique, highly specialized invasion mechanism that involves the polar tube and spore wall. This chapter reviews the data on the organization, structure, and function of this invasion organelle. The application of immunological and molecular techniques and recent genome sequencing data has resulted in the identification of multiple polar tube and spore wall proteins (SWPs). The interactions of these identified proteins in the formation and function of the polar tube and spore wall remain to be determined. Inside the spore, the polar tube is filled with material and is often termed the polar filament; however, this chapter uses the term polar tube to refer to this structure when it is within the spore as well as when it forms a hollow tube after germination and is found outside the spore. The chapter presents details on the spore activation and discharge.
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Life in the nucleus : the genomic basis of energy exploitation by intranuclear MicrosporidiaWiredu Boakye, Dominic January 2016 (has links)
The Microsporidia are obligate intracellular parasites that have jettisoned oxidation phosphorylative capabilities during their early evolutionary history and so rely on ATP import from their host and glycolysis for their energy needs. Some species form tight associations with the host’s mitochondria and this is thought to facilitate ATP sequestration by the developing intracellular microsporidian. The human parasite, Enterocytozoon bieneusi has however lost glycolytic capabilities and may rely entirely on ATP import from its host for energy. E. bieneusi belongs to the Enterocytozoonidae microsporidian family and recent rDNA-based phylogenetic studies have suggested it has close evolutionary ties with Enterospora canceri, a crab-infecting intranuclear parasite. Such a close evolutionary relationship implied that glycolysis might also be absent in the intranuclear parasite raising questions as to how this parasite obtains energy from its unusual niche that is physically walled off from the host mitochondria, the main source of ATP in the host cell. In this study, draft genomes of four species of the Enterocytozoonidae namely, Ent. canceri, E. hepatopenaei, Hepatospora eriocheir and Hepatospora eriocheir canceri and one non-Enterocytozoonidae species, Thelohania sp. were assembled and annotated (The genome assembly of Hepatospora eriocheir was provided by Dr. Bryony Williams). Phylogenomics performed with this and publicly available genomic data confirmed the close evolutionary ties between Ent. canceri and E. bieneusi. Comparative genomic analyses also revealed that glycolysis is indeed lost in all members of the Enterocytozoonidae family sequenced in this study, hinting to the relaxation of evolutionary pressures to maintain this pathway at the base of this microsporidian family. Despite this absence, the hexokinase gene was retained in all aglycolytic genomes analysed, and that of Ent. canceri was fused to a PTPA gene. Functional assays and yeast complementation assays suggest that this chimera is able to recognise glucose as a substrate but the heterologously expressed homolog of H. eriocheir cannot. Finally, phylogenomics have been used here to demonstrate that despite the morphological differences between three Hepatospora-like organisms parasitizing different crab hosts, they are the same species. This finding adds more weight to current evidence suggesting that morphology is not an ideal marker for taxonomical classification in the Microsporidia.
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