Elucidating the canonical and non-canonical functions of the autophagy protein TgATG8 in the apicomplexan parasite Toxoplasma gondii / Caractérisation des fonctions canoniques et non canoniques de la protéine d'autophagie TgATG8 chez le parasite apicomplexe Toxoplasma gondii

Leveque, Maude

07 October 2016

L'autophagie est un processus d'auto-dégradation conservé chez la plupart des eucaryotes. Généralement induit par un stress nutritif, il requiert la formation d'un compartiment à double membrane appelé l’autophagosome qui séquestre et transporte des composants intracellulaires dégradés et recyclés dans le lysosome. La protéine ATG8, qui occupe une position centrale dans ce processus, est recrutée aux membranes de l’autophagosome par un système de conjugaison très régulé. Toxoplasma gondii est un protozoaire parasite appartenant au phylum des Apicomplexes, qui contient une machinerie d'autophagie réduite. Suite à un stress nutritif, ce parasite intracellulaire obligatoire est néanmoins capable de générer des autophagosomes décorés par TgATG8. De façon surprenante, en condition normale de croissance intracellulaire, cette protéine se localise principalement à l’apicoplaste, un plaste non photosynthétique acquis par endosymbiose secondaire qui contient des voies métaboliques essentielles à la survie du parasite. Le but de ma thèse a été d’élucider les fonctions canoniques et non canoniques d‘ATG8 chez Toxoplasma. La première partie de cette étude porte sur la caractérisation fonctionnelle et spatio-temporelle de l'association de TgATG8 avec l’apicoplaste. Nous avons montré que TgATG8 est recrutée aux extrémités de l’apicoplaste en élongation, ce qui permet le maintien de l’organelle à travers les générations en le connectant aux centrosomes pour une répartition dans les deux cellules filles. La deuxième partie de ce travail vise à isoler et identifier par spectrométrie de masse des partenaires putatifs de TgATG8 qui seraient impliqués dans l’autophagie ou dans le rôle non-canonique à l’apicoplaste. Nous avons analysé la localisation subcellulaire de neuf candidats et des caractérisations fonctionnelles ont été entreprises pour trois protéines. Bien que nous n’ayons pas pu confirmer leurs interactions avec TgATG8, cela a permis l'identification de nouvelles protéines parasitaires: une phospholipase à l’apicoplaste essentielle à la survie du parasite, un régulateur potentiel du cycle cellulaire et un composant du cytosquelette du parasite. / Autophagy is a self-degradative process evolutionary conserved among eukaryotes. Typically induced by starvation, it involves the formation of a double membrane compartment called the autophagosome to sequester and deliver intracellular components for lysosomal degradation and recycling. The protein ATG8 occupies a central position in this process and is recruited to autophagosomal membranes by a highly regulated conjugation system. Toxoplasma gondii is a parasitic protist belonging to the Apicomplexa phylum, which possesses a reduced autophagy machinery. This obligate intracellular parasite is nevertheless able to generate TgATG8-decorated autophagosomes upon nutrient stress. Surprisingly, during normal intracellular parasite growth, TgATG8 mainly localizes to the apicoplast, a non-photosynthetic plastid acquired by secondary endosymbiosis which hosts essential metabolic pathways. My thesis aimed to elucidate the canonical and non-canonical roles of ATG8 in Toxoplasma. The first part of this study is the functional and spatio-temporal characterization of TgATG8 association with the apicoplast. We showed TgATG8 is recruited to both ends of the elongating plastid during parasite division, and allows the maintenance of the organelle across generations by permitting its centrosome-driven distribution into the two daughter cells. The second part of this work is the isolation and mass spectrometry-based identification of putative TgATG8-interacting proteins that would be involved in autophagy-related or non-canonical functions. We analyzed the subcellular localization of nine candidates and functional studies were conducted for three proteins. Although we were unable to confirm their interactions with TgATG8, this approach allowed the identification of novel and important parasite proteins: an essential apicoplast phospholipase, a potential regulator of the cell cycle, and a component of the parasite cytoskeleton.

Atg8

Toxoplasma gondii

Apicoplaste

Autophagosomes

Autophagie

Apicomplexe

Atg8

Toxoplasma gondii

Apicoplast

Autophagosomes

Autophagy

Apicomplexa

Maturation and Degeneration of the Fat Body in the Drosophila Larva and Pupa as Revealed by Morphometric Analysis

Butterworth, F. M., Emerson, L., Rasch, E. M.

01 January 1988

Using morphometric and cytochemical techniques we have described changes taking place in the fat body cells during three different stages of development. The cell number remains constant at about 2200 cells during larval life and then decreases gradually and continuously throughout metamorphosis and the first 3 days of the adult stage until no more cells can be observed. Cell size increases rapidly during the larval period and decreases steadily during metamorphosis and adult stage. The size of the nuclei increases during the larval instars and decreases during the pupal interval. The change in nuclear size is correlated with the amount of DNA present throughout development implying the nuclear DNA is synthesized during the larval period and degraded gradually during metamorphosis. The cell size changes are due in large part to accumulation or loss of reserve substances: lipid droplets, glycogen deposits and protein granules. During metamorphosis the amount of lipid decreases slightly whereas glycogen experiences two loss cycles. The protein granules in the form of lysosomes continue to increase in amount during the first day of metamorphosis because of a short period of massive autophagy. Then the lysosomes decrease in amount throughout the remainder of metamorphosis. The lysosomes stain positively for lipofuscin.

autophagosomes

cell death

DNA loss

fat body

Morphometry