A Novel Mammalian Retromer Component, Vps26B

The mammalian retromer protein complex, which consists of three proteins - Vps26, Vps29, and Vps35 - in association with members of the sorting nexin family of proteins, has been implicated in the trafficking of receptors and their ligands within the endosomal/lysosomal system of mammalian cells. A bioinformatic analysis of the mouse genome identified an additional transcribed paralog of the Vps26 retromer protein, which we termed Vps26B. No paralogs were identified for Vps29 and Vps35. Phylogenetic studies indicate that the two paralogs of Vps26 become evident after the evolution of the chordates. We propose that the chordate Vps26-like gene published previously be renamed Vps26A to differentiate it from Vps26B. As for Vps26A, biochemical characterization of Vps26B established that this novel 336 amino acid residue protein is a peripheral membrane protein. Vps26B co-precipitated with Vps35 from transfected cells and the direct interaction between these two proteins was confirmed by yeast 2-hybrid analysis, thereby establishing Vps26B as a subunit of the retromer complex. Within HeLa cells, Vps26B was found in the cytoplasm with low levels at the plasma membrane, while Vps26A was predominantly associated with endosomal membranes. Within A549 cells, both Vps26A and Vps26B co-localized with actin-rich lamellipodia at the cell surface. These structures also co-localized with Vps35. Total internal reflection fluorescence microscopy confirmed the association of Vps26B with the plasma membrane in a stable HEK293 cell line expressing cyan fluorescent protein (CFP)-Vps26B. Based on these observations, we propose that the mammalian retromer complex is located at both endosomes and the plasma membrane in some cell types.

A novel role for retromer in the control of epithelial cell polarity

The establishment and maintenance of epithelial cell polarity is essential throughout the development and adult life of all multicellular organisms. A key player in maintaining epithelial polarity is Crumbs (Crb), an evolutionarily conserved type-I transmembrane protein initially identified in Drosophila. Correct Crb levels and apical localization are imperative for its function. However, as is the case for many polarized proteins, the mechanisms of its trafficking and strict apical localization are poorly understood. To address these questions, we developed a liposome-based assay to identify trafficking coats and interaction partners of Crb in a native-like environment. Thereby, we demonstrated that Crb is a cargo for Retromer, a trafficking complex required for transport from endosomes to the trans-Golgi-network. The functional importance of this interaction was revealed by studies in Drosophila epithelia, which established Retromer as a novel regulator of epithelial cell polarity and verified the vast potential of this technique.

Retromer controls epithelial cell polarity by trafficking the apical determinant crumbs

The evolutionarily conserved apical determinant Crumbs (Crb) is essential for maintaining apicobasal polarity and integrity of many epithelial tissues [1]. Crb levels are crucial for cell polarity and homeostasis, yet strikingly little is known about its trafficking or the mechanism of its apical localization. Using a newly established, liposome-based system described here, we determined Crb to be an interaction partner and cargo of the retromer complex. Retromer is essential for the retrograde transport of numerous transmembrane proteins from endosomes to the trans-Golgi network (TGN) and is conserved between plants, fungi, and animals [2]. We show that loss of retromer function results in a substantial reduction of Crb in Drosophila larvae, wing discs, and the follicle epithelium. Moreover, loss of retromer phenocopies loss of crb by preventing apical localization of key polarity molecules, such as atypical protein kinase C (aPKC) and Par6 in the follicular epithelium, an effect that can be rescued by overexpression of Crb. Additionally, loss of retromer results in multilayering of the follicular epithelium, indicating that epithelial integrity is severely compromised. Our data reveal a mechanism for Crb trafficking by retromer that is vital for maintaining Crb levels and localization. We also show a novel function for retromer in maintaining epithelial cell polarity.

The retromer coat complex coordinates endosomal sorting and dynein-mediated transport, with carrier recognition by the trans-Golgi network

Early endosome-to-trans-Golgi network (TGN) transport is organized by the retromer complex. Consisting of cargo-selective and membrane-bound subcomplexes, retromer coordinates sorting with membrane deformation and carrier formation. Here, we describe four mammalian retromers whose membrane-bound subcomplexes contain specific combinations of the sorting nexins (SNX), SNX1, SNX2, SNX5, and SNX6. We establish that retromer requires a dynamic spatial organization of the endosomal network, which is regulated through association of SNX5/SNX6 with the p150(glued) component of dynactin, an activator of the minus-end directed microtubule motor dynein; an association further defined through genetic studies in C. elegans. Finally, we also establish that the spatial organization of the retromer pathway is mediated through the association of SNX1 with the proposed TGN-localized tether Rab6-interacting protein-1. These interactions describe fundamental steps in retromer-mediated transport and establish that the spatial organization of the retromer network is a critical element required for efficient retromer-mediated sorting.

A loss-of-function screen reveals SNX5 and SNX6 as potential components of the mammalian retromer

The mammalian retromer is a multimeric protein complex involved in mediating endosome-to-trans-Golgi-network retrograde transport of the cation-independent mannose-6-phosphate receptor. The retromer is composed of two subcomplexes, one containing SNX1 and forming a membrane-bound coat, the other comprising VPS26, VPS29 and VPS35 and being cargo-selective. In yeast, an additional sorting nexin--Vps17p--is a component of the membrane bound coat. It remains unclear whether the mammalian retromer requires a functional equivalent of Vps17p. Here, we have used an RNAi loss-of-function screen to examine whether any of the other 30 mammalian sorting nexins are required for retromer-mediated endosome-to-trans-Golgi-network retrieval of the cation-independent mannose-6-phosphate receptor. Using this screen, we identified two proteins, SNX5 and SNX6, that, when suppressed, induced a phenotype similar to that observed upon suppression of known retromer components. Whereas SNX5 and SNX6 colocalised with SNX1 on early endosomes, in immunoprecipitation experiments only SNX6 appeared to exist in a complex with SNX1. Interestingly, suppression of SNX5 and/or SNX6 resulted in a significant loss of SNX1, an effect that seemed to result from post-translational regulation of the SNX1 level. Such data suggest that SNX1 and SNX6 exist in a stable, endosomally associated complex that is required for retromer-mediated retrieval of the cation-independent mannose-6-phosphate receptor. SNX5 and SNX6 may therefore constitute functional equivalents of Vps17p in mammals.

Fonction de la protéine Ceroid lipofuscinosis neuronal 5 (CLN5) dans le tri et le recyclage à l’endosome

Le tri et le transport efficace des hydrolases acides vers le lysosome jouent un rôle critique pour la fonction des cellules. Plus de 50 maladies humaines sont dues à des mutations des enzymes lysosomales, des protéines régulant des processus-clés du transport vers le lysosome ou des enzymes effectuant des modifications posttraductionnelles importantes pour la fonction du lysosome. L’objectif de cette thèse est d’identifier des protéines et des mécanismes permettant à la cellule de réguler le transport des enzymes vers le lysosome. Nous avons formulé l’hypothèse que des protéines mutées dans des maladies lysosomales et dont les fonctions étaient inconnues pouvaient jouer un rôle dans le transport vers le lysosome. Les céroïdes-lipofuscinoses neuronales forment une famille de maladies lysosomales rares mais sont aussi les maladies neurodégénératives infantiles les plus fréquentes. Plusieurs gènes impliqués dans les NCL encodent des protéines aux fonctions inconnues. Les travaux présentés dans cette thèse ont identifié la protéine « ceroid lipofuscinosis neuronal-5 » (CLN5) qui est localisée à l’endosome et au lysosome comme élément nécessaire au recrutement et à l’activation de rab7. Rab7 est une protéine Rab-clé qui contrôle le trafic à l’endosome tardif. Cette petite GTPase est impliquée dans le recrutement de retromer, un complexe protéique qui régule le trafic de l’endosome vers l’appareil de Golgi des récepteurs de tri lysosomal comme sortilin et le récepteur du mannose-6-phosphate. Dans les cellules où CLN5 est déplété, les récepteurs de tri lysosomal sont moins recyclés plus rapidement dégradés. En utilisant des expériences de photomarquage nous avons aussi pu démontrer que Rab7 est moins activées en l’absence de CLN5. Pour exécuter leur fonction les protéines rabs doivent être recrutée à la membrane et activées par l’échange d’une molécule de GDP pour une molécule de GTP. Le recrutement des Rabs à la membrane nécessite une modification posttraductionnelle lipidique pour être facilités. En utilisant un modèle de levures nous avons démontré que l’homologue de Rab7, Ypt7 est palmitoylée. Nous avons aussi démontré que la palmitoyltransférase Swif1 est nécessaire au recrutement de Ypt7 à la membrane. Nous avons aussi remarqué que les sous- unités de retromer chez la levure sont moins recrutées lorsque les palmitoyltransférases sont déplétées. Dans les cellules de mammifères nous avons démontré que Rab7 est également palmitoylé et que cette palmitoylation est possiblement effectuée par les palmitoyltransférases DHHC1 et DHHC8. La palmitoylation de Rab7 a lieu sur les cystéines en C-terminal qui sont nécessaires au recrutement membranaire et qui auparavant étaient uniquement décrites comme prénylées. En utilisant la méthode de « click chemistry » nous avons découvert que lorsque la prénylation de Rab7 est bloquée le niveau de palmitoylation augmente. Pour caractériser l’interaction entre CLN5 et Rab7 nous avons performé des expériences afin d’établir définitivement la topologie de cette protéine. Nous avons ainsi démontré que CLN5 est une protéine hautement glycosylée qui est initialement traduite en protéine transmembranaire et subséquemment clivée par un membre de la famille des peptidase de peptide signal (SPP). Cette protéine soluble peut alors possiblement interagir avec CLN3 qui est aussi palmitoylée pour recruter et activer Rab7. Nos études suggèrent pour la première fois que CLN5 pourrait être un recruteur et un activateur de Rab7 qui agirait avec la protéine CLN3 pour séquestrer Rab7 avec les autres récepteurs palmitoylés et permettre leur recyclage vers l’appareil de Golgi.