The role of retromer in adipogenesis

Chaudhry, Hira

12 July 2017

Endocytosis is the process in which a cell engulfs extracellular cargo by creating invaginations within its plasma membrane. The cargo that has entered the cell enters an endosome and then is delivered to either the trans-Golgi network for recycling to the plasma membrane or to the lysosome for its degradation (Trousdale & Kim, 2015). Retromer is a peripheral membrane protein complex that plays a key role in sorting of these cargo molecules (Collins, 2008). More specifically, retromer deliver cargo from the endosome to the trans-Golgi Network, the process which is called retrograde transport of cargo molecules. Retromer dysfunction is strongly linked to neurodegenerative diseases such as Alzheimer’s and Parkinson’s Disease. However, recent Genome Wide Association Studies suggest that a mutation in retromer subunit VPS26a, has been linked to Type II Diabetes (Trousdale & Kim, 2015). A 2016 study published in The Faseb Journal attempts to characterize the role of retromer in adipocyte differentiation and insulin-stimulated uptake of glucose through transporter GLUT4 (Yang et al., 2016). The aim of this study is to further investigate the role of retromer in adipogenesis and to determine whether retromer plays a role at the transcriptional level or translational level. In this study, retromer’s VPS35 subunit was knocked down in four mouse 3T3-L1 fibroblast cell lines using the CRISPR-Cas9 approach. These cell lines were differentiated into mature adipocytes and analyzed by Oil-Red O staining, Western Blotting and quantitative PCR. The knockdown of retromer produced varying effects on adipocyte differentiation. In two of the knockdown cell lines, adipocyte differentiation was downregulated whereas adipocyte differentiation was upregulated in the other two cell lines. Although the results from Oil-Red O staining and Western Blot analyses complemented each other, results obtained from qPCR were not as straightforward and further analysis is needed to fully comprehend how retromer acts at the transcriptional level of cell differentiation. Based on the results of this study, retromer is involved in adipogenesis at both the transcriptional and translational level, however it’s mechanism of action remains unclear as both cases of impaired differentiation and upregulated differentiation were observed. Further studies are necessary to determine retromer’s exact role in adipogenesis.

Medicine

Adipogenesis

Retromer

Type II diabetes

A Composite Review of the Proposed Molecular Mechanisms and Genetic Components Underlying Parkinson’s Disease

Brodrick, Paige

01 January 2019

Parkinson’s disease (PD) is a progressive neurodegenerative disorder characterized by the progressive death of dopaminergic neurons present in the substantia nigra. The clinical presentation of PD includes tremors, slowed movement (bradykinesia), muscle and limb rigidity, and difficulty with walking and balancing. While many environmental factors can affect the onset and progression of the disease, genetic mutations have a large influence. Of the identified PD-linked genetic mutations, mutations in the leucine-rich repeat kinase 2 (LRRK2) are one of the most common genetic causes of PD. Located in endosomes, LRRK2 has been shown to play a role in the sorting and endocytosis of synaptic vesicles, a process that is largely mediated by the retromer complex. Mutations in Vps35, a core component of the retromer cargo-recognition complex, have also been identified as a significant cause of late-onset autosomal dominant familial PD. While the exact molecular mechanisms by which LRRK2 and Vps35 mutations induce PD remain largely unknown, their influence on several cellular processes, including vesicular trafficking and breakdown, and endosomal sorting and recycling, strongly implicate the retromer and autophagy in PD pathology. Recent findings that transgenic expression of Vps35 is able to rescue the PD-related phenotypes caused by LRRK2 mutant forms provide further insight into the interplay of these genes in the context of PD and point to these -genes as potential therapeutic targets. This review outlines the current studies involving these genetic mutations and their interactions with various cellular processes and pathways so as to gain a better understanding of the molecular mechanisms underlying PD pathology for the ultimate purpose of developing safe and effective treatments for PD.

Neuroscience

Parkinson's Disease

Autophagy

Retromer

Pathology

Biology

Molecular and Cellular Neuroscience

The functional role of the retromer complex in the pathogenesis of Alzheimer's disease in Down syndrome

Curtis, Mary

January 2022

Down syndrome (DS) is a congenital disorder caused by partial or complete triplication of human chromosome 21. By age 40, nearly all individuals with DS develop amyloid beta (Aβ) plaques and tau neurofibrillary tangles, the pathological hallmarks of Alzheimer’s disease (AD). This increased susceptibility to Alzheimer’s Disease in Down syndrome (AD-DS) has primarily been attributed to an over-dosage of the amyloid precursor protein (APP), which generates neurotoxic Aβ fragments when cleaved by β- secretase. However, the complete molecular mechanisms of AD-DS are not completely understood, as trisomy of chromosome 21 can induce AD-like neuropathology independently of APP triplication. In addition to classical AD neuropathology, enlarged, APP-positive early endosomes appear early in AD-DS pathogenesis and are the first site of Aβ accumulation. In AD, these endocytic abnormalities have been linked to dysfunction of the endosomal-sorting system known as the retromer complex. Mechanistically, retromer dysfunction can influence amyloid beta production by increasing interaction of the retromer cargo APP with beta-secretase. However, recent studies have also implicated the retromer complex in the development of tau pathology, both through regulation of tau phosphorylation and degradation via lysosomes. Given that retromer dysfunction is associated with the endosomal phenotype found in AD-DS, and that the retromer system can modulate key aspects of AD-DS neuropathology, the objective of the current study is to investigate the role of the retromer complex in the development of AD-DS. We first examined the retromer system in cortices and hippocampi from human patients with DS. Retromer recognition core proteins were significantly decreased in both the hippocampi and cortices of young and aged DS subjects compared to controls. Correlative analyses showed a significant inverse relationship between recognition core proteins and levels of soluble forms of Ab 1-40 and 1-42 in both hippocampus and cortex tissue, and phosphorylated tau epitopes PHF1 and PHF13 in the cortex of the same patients. While this does not indicate causation, these correlative analyses support the hypothesis that dysregulation of the retromer system and AD-like pathology are closely related. Next, we analyzed the retromer system in euploid and trisomic induced pluripotent stem cell (iPSC) -derived neurons and observed an age-related decrease in retromer proteins and elevation of Ab 1-40, Ab 1-42 and phosphorylated tau proteins in trisomic neurons compared to euploid controls. Additionally, we found that pharmacological stabilization of the retromer complex can reduce Ab and phospho-tau in trisomic iPSC-derived neurons. While total levels of retromer proteins are unaffected, we hypothesize that retromer function improves with TPT-172 treatment, as levels of early endosome proteins decrease while autophagy and lysosomal proteins increase with treatment. Treatment of trisomic neurons with TPT-172 also led to reductions in the neuronal tau kinase CDK5 and its activator p25, providing a potential mechanistic link between tau phosphorylation and pharmacological stabilization of the retromer system. Additionally, we examined the effects of genetic overexpression of VPS35, the backbone of the retromer core, in trisomic neurons. We observed similar decreases in AD pathology measures, however, the magnitude of the effect was smaller with genetic overexpression than with pharmacological stabilization using TPT-172. We hypothesized that trisomy 21 may can some inherent instability of the retromer system, possibly due to overabundance of retromer cargo protein APP, that is better overcome by enhancing stability of the complex rather than increasing VPS35 protein level via genetic overexpression. To further explore the role of the retromer system in the AD-DS phenotype, we performed a full characterization of cognitive function and the retromer complex at 2, 5, 9 and 12 months of age in the Ts65dn mouse model of DS. While we observed accelerated aging related cognitive and pathological changes in DS mice, we did not observe any protein levels changes in the retromer complex. However, because these mice do develop endosomal dysfunction that could be indicative of retromer dysfunction, we treated mice with TPT-172 from 4 to 9 months of age and examined cognitive function, the retromer system and AD pathology measures. We observed improvements in cognitive function tests and synaptic function in Ts65dn mice receiving TPT-172, as well as reductions in tau pathology, early endosome proteins, and early endosome size. Taken together, these data demonstrate that retromer complex deficiency occurs in human DS and may contribute to the development of AD-like pathology and cognitive decline in AD-DS. Because pharmacological stabilization of the retromer system improves AD-like pathology and cognitive function in models of DS, we conclude the retromer represents a potential therapeutic target for AD-DS. / Biomedical Sciences

Neurosciences

Biology

Alzheimer's disease

Down syndrome

Retromer complex

The Role of Retromer in Regulating the Apical-Basal Polarity and the Immune Response during Drosophila Development

Zhou, Bo

20 April 2012

No description available.

Biology

Retromer

apical-basal polarity

Crumbs

Toll pathway

vps35

Drosophila

La protéolyse de SNX2 par les caspases empêche l’assemblage du complexe rétromère et augmente la signalisation du récepteur Met / Caspase-mediated proteolysis of the sorting nexin 2 disrupts retromer assembly and potentiates Met/hepatocyte growth factor receptor signaling

Duclos, Catherine

January 2017

Durant l’exécution de l’apoptose, plus de 2 000 protéines sont protéolysées par les caspases, une famille de protéases à cystéine. Le clivage de plusieurs d’entre elles a pour effet d’interrompre les processus régulant le trafic intracellulaire. Durant mes études, je me suis intéressée à deux substrats potentiels des caspases, soit les sorting nexins SNX1 et SNX2. Leur clivage en N-terminal avait auparavant été identifié par protéomie dans des extraits cellulaires apoptotiques, respectivement aux sites LFAD91[flèche vers le bas]A et VSLD84[flèche vers le bas]S. Conjointement avec le complexe rétromère, SNX1 et SNX2 jouent un rôle essentiel dans le transport rétrograde de cargos, tel le récepteur lysosomal CI-MPR, des endosomes vers le TGN, évitant ainsi leur dégradation aux lysosomes. Notamment, l’association entre SNX1 et SNX2 et le complexe rétromère, via la sous-unité Vps35, requerrait leur domaine N-terminal, or, celui-ci est clivé durant l’apoptose. Dans le but de déterminer l’impact de la protéolyse de SNX1 et SNX2 sur la fonction du complexe rétromère et le transport rétrograde, nous avons étudié leur clivage par les caspases. Nos résultats indiquent qu’in vitro, les caspases initiatrices 8, 9 et 10 protéolysent SNX1 et SNX2 tandis que seule la caspase-6 exécutrice clive SNX2. Plusieurs fragments de SNX1 sont générés par le clivage à 16 sites, dont le site LFAD91[flèche vers le bas]A en N-terminal ainsi que plusieurs suivant un résidu glutamate. Durant l’apoptose, SNX2 est entre autres clivée par la caspase-6, et ce au site VSLD84[flèche vers le bas]S en N-terminal. Nous avons par la suite étudié l’effet de la protéolyse de SNX1 et SNX2 sur la fonction du complexe rétromère. Nos résultats démontrent que SNX2 tronquée, imitant le clivage au site VSLD84[flèche vers le bas]S, n’interagit plus avec Vps35, la sous-unité centrale du complexe rétromère. De plus, la déplétion de SNX1 et SNX2, récapitulant potentiellement leur protéolyse, a pour effet de délocaliser Vps26, une autre sous-unité du complexe rétromère. Par ailleurs, nous avons évalué l’effet de la protéolyse de SNX2 sur la régulation du récepteur Met, lequel serait régulé entre autres par SNX1 et SNX2. La déplétion de SNX2 induit une augmentation de la phosphorylation du récepteur Met et de ERK1/2 suivant sa stimulation. De plus, l’ARNm de SNX1 et SNX2 sont tous deux réduits dans les tissus de tumeurs de patients atteints du cancer colorectal (CCR) et une diminution des niveaux de SNX2 corrèle avec une hausse de mortalité chez ces patients. Pour conclure, notre étude démontre un effet direct de la protéolyse de SNX2 sur le complexe rétromère durant l’apoptose et suggère un lien entre SNX2 et la pathogenèse du CCR. / Abstract: During the execution of apoptosis, more than 2,000 proteins are proteolysed by caspases, a family of cysteine proteases. The cleavage of several of them results in the interruption of intracellular trafficking processes. During my studies, I investigated two potential caspases substrates, namely the sorting nexin SNX1 and SNX2. Their cleavage at their N-terminus has previously been identified in apoptotic cell lysates by proteomics, respectively at LFAD91[down arrow]A and VSLD84[down arrow]S sites. Together with the retromer complex, SNX1 and SNX2 play an essential role in the retrograde transport of cargos, such as the lysosomal receptor CI-MPR, from endosomes to TGN, thus avoiding their degradation by lysosomes. In particular, the association between SNX1 and SNX2 and the retromer complex, via the Vps35 subunit, seems to require their N-terminal domain, which is thought to be cleaved during apoptosis. To determine the impact of SNX1 and SNX2 proteolysis on the function of the retromer complex and retrograde transport, we have first studied their cleavage by caspases. Our results indicate that in vitro, initiator caspases 8, 9, and 10 proteolyze SNX1 and SNX2 while only executioner caspase-6 cleaves SNX2. Several fragments of SNX1 are generated by the cleavage of up to 16 sites, including at the N-terminus LFAD91[down arrow]A site and following glutamate residues. During apoptosis, SNX2 is directly cleaved by caspase-6 at the site VSLD84[down arrow]S in its N-terminus. We next investigated the effect of SNX1 and SNX2 proteolysis on the function of retromer complex. Our results demonstrate that truncated SNX2, mimicking cleavage at the VSLD84[down arrow]S site, no longer interacts with Vps35, the central subunit of retromer complex. Furthermore, depletion of SNX1 and SNX2, potentially recapitulating their proteolysis, redistributes Vps26, another retromer subunit. In addition, we evaluated the effect of SNX2 proteolysis on the regulation of Met receptor, which has been shown to be regulated by SNX1 and SNX2. SNX2 depletion induces an increase in Met and ERK1/2 phosphorylation after stimulation. In addition, both SNX1 and SNX2 mRNAs are reduced in tumor tissues of colorectal cancer patients and decreased expression levels of SNX2 correlates with increased mortality. In conclusion, our study demonstrates a direct effect of SNX2 proteolysis on retromer complex association during apoptosis and suggests a link between SNX2 and the pathogenesis of colorectal cancer.

SNX1

SNX2

Caspase

Apoptose

Rétromère

Met

Cancer colorectal

Apoptosis

Retromer

Colorectal cancer

Mechanismy regulace aktivity proteinu MTM-6 na endosomech. / Mechanismy regulace aktivity proteinu MTM-6 na endosomech.

Horázná, Monika

January 2013

Wnt signalling belongs to conserved pathways and mediates cell fate decision, development, regeneration and adult tissue homeostasis. Disruption or misregulation of Wnt signalling pathway often leads to disease. Wnt proteins are hydrophobic glycoproteins which need a special receptor for transport from Golgi Apparatus to cell surface, which is called MIG-14 in Caenorhabditis elegans and Wntless (Wls) in mammals. In this study, I focus on understanding mechanisms that regulate MTM-6 protein activity. MTM-6, a lipid phosphatase associated with endosomal membrane, has been recently identified as a regulator of MIG-14/Wls trafficking in Caenorhabditis elegans. Silencing of mtm-6 leads to misregulation of some Wnt-directed processes, such as migration of Q neuroblasts progeny. This study reports identification of novel mtm-6 genetic interactors that have been found to influence migration of Q neuroblasts progeny through Wnt signalling. New knowledge about mtm-6 genetic interactions bring us near to understanding of Wnt signalling regulation. Keywords: Caenorhabditis elegans, MTM-6, SEL-5, Wntless, Wnt, endosomes, phosphoinositides, retromer

Role proteinu CUP-4 ve Wnt signalizaci / The role of CUP-4 protein in Wnt signalling

Žídek, Radim

January 2012

Wnt signalling is indispensible for proper development of organisms and maintaining of adult tissue homeostasis. Its disruption often leads to disease. In nematode Caenorhabditis elegans, Wnt signalling governs vast array of developmental processes, among others also migration of the Q neuroblasts and their descendants. The sole Wnt acting in this process, EGL-20, triggers the canonical β-catenin Wnt signal transduction pathway in QL but not in QR which leads to QL remaining in the posterior while the QR migrates anteriorly. This represents a useful tool for studying Wnt signalling. Recently, mutation of gene cup-4 was found to disrupt migration of the QL neuroblast in a small proportion of the mutant population. cup-4 encodes a ligand-gated ion channel family homologue and it was shown to participate in endocytosis by coelomocytes, specialized phagocytic cells in the C. elegans body cavity. Here, I present the results of my effort to determine the place of CUP-4 action in Wnt signalling and to elucidate the mechanism of its function. I found that CUP-4 acts upstream of PRY- 1/Axin, which is involved in signal transduction in signal receiving cells, and most probably downstream of adaptin AP2, which is important for recycling of Wnt cargo receptor Wntless (Wls) in Wnt producing cell. cup-4 also...

Characterization Of A Novel Vps26c-Retromer Complex And Its Interaction With An Endosomal Trafficking Pathway Regulated By The Snare Vti13 In Controlling Polarized Growth And Cell Wall Organization In Arabidopsis Thaliana

Ghosh Jha, Suryatapa

01 January 2018

The endosomal trafficking system is a network of highly coordinated cellular pathways that control the growth and function of cells. The coordination of secretion and endocytosis in cells is one of the primary drivers of polarized growth, where new plasma membrane and cell wall components are deposited at the growing apex. In plants, one of the cell types exhibiting polarized growth are the root hairs. Root hairs are regulated extensions of epidermal cells called trichoblasts and are essential for anchorage, absorption of water and nutrients, and plant-microbe interactions. In this thesis, I characterize a previously undescribed protein involved in retromer function and endosomal trafficking pathways that regulate tip growth in root hairs of Arabidopsis thaliana. The large retromer complex functions in recycling receptors in endosomal trafficking pathways essential for diverse developmental programs including cell polarity, programmed cell death, and shoot gravitropism in the model plant, Arabidopsis thaliana. I have characterized VPS26C, a novel member of the large retromer complex, that is essential in maintaining root hair growth in Arabidopsis. We used Bimolecular Fluorescence Complementation (BiFC) analysis to demonstrate thatVPS26C interacts with previously characterized core retromer subunits VPS35A and VPS29. Genetic analysis also indicates that vps26c suppresses the root hair growth and cell wall organization phenotypes of a null mutant of the SNARE VTI13 that localizes to early endosomes and the vacuole membrane, indicating a crosstalk between the VPS26C-retromer and VTI13-dependent vesicular trafficking pathways. Phylogenetic analysis was used to show that VPS26C genes are present in most angiosperms but appear to be absent in monocot genomes. Moreover, using a genetic complementation assay, we have demonstrated that VPS26C shares deep conservation of biochemical function with its human ortholog (DSCR3/VPS26C). We also used an affinity purification-based proteomic analysis to identify proteins associated with VTI13 in young seedlings. Preliminary results suggest that a number of proteins linked to cell plate organization in plants are associated with the VTI13 proteome, emphasizing the potential role of this pathway in new cell wall biosynthesis/organization. Additionally, we have identified endoplasmic reticulum (ER)-body proteins, involved in plant defense response pathways, suggesting that either the VTI13 endosomal trafficking pathway is functioning in plant defense responses, or the ER-body proteins have additional independent function(s) in Arabidopsis roots that depend on VTI13. In summary, I have described a novel retromer complex essential for polarized growth in Arabidopsis. VPS26C is an ancient gene and shares sequence and functional homology between human and Arabidopsis. vps26c is a genetic suppressor of the vti13- dependent root hair growth and cell wall organization pathways. Proteomic analysis of VTI13 endosomes in young seedlings suggests that a number of proteins associated with cell plate formation are associated with VTI13 compartments, supporting the genetic analysis described here and serves as a starting point to further describe the role of this pathway in controlling polarized growth in plants.

Arabidopsis

Cell Biology

Endosomal trafficking

Polarized Growth

Retromer

Root hairs

Cell Biology

Genetics and Genomics

Plant Sciences

Role of the retromer complex and its interactors in Arabidopsis development / Rôle du complexe rétromère et de ses interacteurs dans le développement d’Arabidopsis

Santambrogio, Martina

17 December 2009

Chez la levure et les mammifères le complexe rétromère est impliqué dans différentes étapes de trafic intracellulaire qui modulent divers processus cellulaires et développementaux. Chez les mammifères, le rétromère se compose des protéines Vacuolar Protein Sorting (VPS) 35, VPS26, VPS29 et d’un dimere de Sorting Nexins (SNX). Les composants du rétromère sont conservés chez les plantes et sont localisés dans le même endosome de tri. Dans ce travail, nous avons étudié le mécanisme d’assemblage et de recrutement du complexe à la membrane et analysé le rôle du rétromère dans le développement d’Arabidopsis. Nos resultsts montrent que chez les plantes, contrairement aux mammifères, VPS35 recrute le sous-complexe VPS à la membrane, indépendamment des SNXs. Ceci nous a permis de proposer un modèle d’assemblage du rétromère très original. L’analyse de mutants perte de fonction pour le rétromère révèle que VPS26, VPS29 et VPS35 n’ont pas de fonctions indépendantes, mais agissent ensemble dans la régulation de processus développementaux. De plus, par un crible double hybride chez la levure, nous avons isolé un interacteur de VPS35 : Ethylene Insensitive 2 (EIN2). EIN2 est une protéine localisée au Réticulum Endoplasmique et impliquée dans la voie de signalisation d’une hormone végétale : l’éthylène. Nous montrons que des mutants perte de fonction pour le rétromère présentent des défauts dans la réponse à l’éthylène, indiquant un rôle du rétromère dans la perception de cette hormone par les plantes. Ces résultats, combinés avec nos données antérieures montrant que le rétromère est impliqué dans la voie de signalisation de l’auxine, révèlent un lien entre signalisation de l’auxine et de l’éthylènevia le complexe rétromère. / In yeast and mammals, the retromer complex mediates various steps of intracellular trafficking and regulates a variety of cellular and developmental processes. In mammals, it is composed of Vacuolar Protein Sorting (VPS) 35, VPS26, VPS29 and a dimer of Sorting Nexins (SNX). Retromer components are conserved in plants and we showed that they colocalize to the same sorting endosome. In this work, we have investigated the mechanism of assembly and recruitment of the retromer to the endosomal membrane and studied its function in Arabidopsis development. We report that, unlike animals, plant VPS35 recruits the other VPS retromer components to the membrane of endosomes, independently of SNXs. This data allowed us to propose an original model of assembly of the plant retromer complex. By analyzing a series of retromer loss-of-function mutants, we show that VPS26, VPS29 and VPS35 always act together in modulating developmental processes. To identify retromer partners, we carried out a Yeast-2-Hybrid (Y2H) screen using VPS35 as a bait. We found that VPS35 can bind, among other proteins, Ethylene Insensitive 2 (EIN2). EIN2 is an Endoplasmic Reticulum-located protein involved in the signaling pathway of a plant hormone: ethylene. We demonstrate that retromer mutants are affected in ethylene signaling, which indicates that the retromer complex participates in a proper perception of ethylene by plants. Combined with our previous data in which we showed that the retromer is involved in the auxin signalling pathway, our present work reveals a link between auxin and ethylene signaling through the retromer complex.

Complexe rétromère

Endosome

Transport rétrograde

Ethylène

Retromer complex

Endosome

Retrograde transport

Ethylene

571.6

Investigations into the Nature of the Endosomal System in Plasmodium falciparum

Krai, Priscilla M.

27 August 2013

The parasite Plasmodium falciparum causes the most virulent form of human malaria and is responsible for the vast majority of malaria-related deaths. During the asexual intraerythrocytic stage, the parasite must transport newly synthesized proteins and endocytosed cargo to a variety of organelles, many of which are formed de novo and have no human equivalent. This process in mammalian cells would utilize an endosomal protein trafficking system, but no endosomal structures or proteins have been described in the parasite. Prior work on the parasite genome indicated that several proteins, which could potentially coordinate an endosomal network, were encoded in the genome and expressed during the asexual parasite stages. In this study, we have localized and attempted to further characterize these proteins in the context of the endosomal system. Two well-conserved protein components of the late endosome, the retromer cargo-selective complex and Rab7, were found on a previously un-described inherited structure adjacent to the parasite Golgi apparatus and in close opposition to nascent rhoptries (specialized secretory organelles required for invasion). The retromer cargo-selective complex was also in close proximity to its putative cargo, a P. falciparum homolog of the sortilin family of protein sorting receptors, PfSortilin. Another protein, PfFCP, the sole FYVE domain-containing protein in the P. falciparum genome, was localized to the membrane of a specialized acidic organelle, known as the food vacuole, where the parasite catabolizes the majority of its host cell hemoglobin. We analyzed the effects of a PfFCP dominant negative mutant and found that it altered food vacuole morphology and trafficking. A previous report localized the early endosome phosphoinositide, phosphatidylinositol 3-phosphate, to the food vacuole membrane, and in conjunction with our studies on PfFCP, this has raised doubts about the food vacuole as a lysosome equivalent in the parasite. The combination of both early and late endosome protein homologs in the parasite, and their potential function, has led to a new model of protein trafficking within the parasite that includes the food vacuole as a terminal early endosome and the apical organelles as lysosome equivalents. / Ph. D.

Plasmodium falciparum

malaria

retromer complex

Rab7

FYVE domain

endosome

food vacuole

protein trafficking