Rab-Proteine kontrollieren die Chlamydien-induzierte Fragmentierung des Golgi-Apparates

Lipinski, Anette Rejman

28 August 2009

Weltweit kommt es jährlich zu 90 Mio. Neuinfektionen mit dem sexuell übertragbaren Erreger Chlamydia trachomatis. Allerdings sind die Faktoren, die eine erfolgreiche bakterielle Vermehrung ermöglichen, weitgehend unbekannt. Während ihrer obligat intrazellulären Entwicklung sind Chlamydien auf die Errichtung und Erhaltung ihrer Nische, der Inklusion, angewiesen. Durch Interaktionen mit vesikulären Transportwegen der Wirtszelle, welche z.B. Sphingolipide transportieren, sichern die Bakterien ihr Überleben. In der vorliegenden Arbeit konnte gezeigt werden, dass Chlamydien während einer Infektion die Auflösung der Struktur des Golgi-Apparates induzieren. Mit Hilfe der RNA-Interferenz-Technik (RNAi) wurden die Auswirkungen des Verlustes von Golgi-Strukturproteinen auf die bakterielle Vermehrung untersucht. Der funktionelle Ausfall von Golginen, wie z.B. Golgin-84 führte zu einer Fragmentierung des Golgi-Apparates. Diese begünstigte die chlamydiale Produktion neuer infektiöser Partikel, was eine verbesserte Versorgung mit Nährstoffen nahelegt. Im vesikulären Transport von Nährstoffen übernehmen Rab-Proteine eine Schlüsselrolle. Interessanterweise konnte in dieser Arbeit gezeigt werden, dass der Verlust von Rab6 und Rab11 durch RNAi zu einer signifikanten Verringerung der Anzahl infektiöser Nachkommen führte. In diesen Zellen wurde der Golgi-Apparat nicht fragmentiert und der Transport von Sphingolipiden zu den Bakterien war stark vermindert. Untersuchungen nach simultaner Herunterregulation von Golgin-84 und Rab6 oder Rab11 demonstrierten abschließend, dass eine Kontrolle der Golgin-84-induzierten Golgi-Fragmentierung über Rab-Proteine möglich sein könnte. Die Ergebnisse dieser Arbeit offenbaren einen neuen Zusammenhang zwischen der Struktur des Golgi-Apparates und dessen Kontrolle über Rab-Proteine und ermöglichen einen tieferen Einblick in die Funktion des Golgi-Apparates während einer Chlamydien-Infektion. / Worldwide, approximately 90 mio. people are infected with the obligate intracellular bacterium Chlamydia trachomatis. However the factors involved in its successful infection and replication remain unknown. Chlamydia survive and replicate within a membrane bound niche inside host cells, termed the inclusion. To ensure survival, the chlamydial inclusion intercepts vesicular trafficking pathways of the host cell to acquire essential nutrients, such as sphingolipids. However, the exact mechanisms by which Chlamydia acquire these lipids have not been elucidated. The present work established that infection of host mammalian cells with C. trachomatis induced fragmentation of the Golgi-apparatus, but details of the mechanism to the bacterium’s pathogenesis are still required. Using RNA-Interference the role of specific Golgi-apparatus structural proteins in bacterial infectivity was investigated. Knockdown of Golgins in host cells resulted in a fragmented Golgi-apparatus and an associated increase in chlamydial replication, suggesting an enhanced acquisition of nutrients. Since Rab-proteins are known to co-ordinate the intracellular vesicular transport of nutrients, their importance in chlamydial infectivity was also investigated. Interestingly, knock down of Rab6 and Rab11 led to a significant reduction in infectious progeny. Surprisingly, upon knock down of Rab6 or Rab11 the Golgi-apparatus remained intact and sphingolipid transport into the inclusion was severely perturbed. Finally, analysis of cells simultaneously depleted of golgin-84 and Rab6 or Rab11 suggested a possible role of Rab-proteins in the control of golgin-84-induced Golgi fragmentation. These data demonstrate a yet unknown relationship between the structure of the Golgi-apparatus and its regulation and control by Rab-proteins. Furthermore, this work contributes to the existing knowledge regarding the function of the Golgi-apparatus during chlamydial infections.

siRNA

Rab-Proteine

Chlamydia trachomatis

Golgi-Fragmentierung

siRNA

Rab proteins

Chlamydia trachomatis

Golgi fragmentation

570 Biowissenschaften, Biologie

32 Biologie

WE 3650

WL 2735

ddc:570

Rab Proteins and Alzheimer's: A Current Review of Their Involvement in Amyloid Beta Generation with Focus on Rab10 Expression in N2A-695 Cells

Arano Rodriguez, Ivan

01 March 2015

This thesis work describes the role of Rab proteins in amyloid processing and clearance in different cell pathways. It also describes an experimental approach used to analyze the expression effects of Rab10 in amyloid beta production. Since the main theory behind neurodegeneration in Alzheimer's disease claims that high levels of amyloid beta 42 (Aβ42) molecules trigger widespread neuronal death, control of Aβ42 has been a main target in Alzheimer's disease research. In addition, several studies show increased levels of particular Rab proteins in Alzheimer's pathogenesis. However, no review consolidates current findings in neurodegeneration of Alzheimer's with Rab protein dysfunction. The first chapter of this thesis aims to address this need by providing a current review of Rab proteins associated with APP and neurodegeneration. The second chapter constitutes an experimental approach used to characterize the effects of Rab10 and Sar1A GTPases in APP and amyloid processing. We found that Rab10 expression does not affect APP production but significantly changes Aβ generation, particularly the toxic Aβ42 and Aβ42:40 ratio. On the other hand, we found no significant effect of Sar1A expression on either APP or amyloid beta generation. These findings partially confirm the work done by Kauwe et al (2015) and provide preliminary evidence for two potential targets for protective effects in neurodegeneration.

Rab proteins

GTPases

Alzheimer's disease

gene

genetic variants

3' UTR

amyloid beta

neurodegeneration

endocytosis

anterograde transport

autophagy

amyloid precursor protein

transient transfection

overexpression

knockdown

Biology

THE EFFECTS OF AGING AND ALZHEIMER’S DISEASE ON RETROGRADE NEUROTROPHIN TRANSPORT IN BASAL FOREBRAIN CHOLINERGIC NEURONS / RETROGRADE NEUROTROPHIN TRANSPORT IN BASAL FOREBRIAN NEURONS

Shekari, Arman

January 2021

Basal forebrain cholinergic neurons (BFCNs) are critical for learning and memory. Profound and early BFCN degeneration is a hallmark of aging and Alzheimer’s disease (AD). BFCNs depend for their survival on the retrograde axonal transport of neurotrophins, proteins critical for neuronal function. Neurotrophins like brain derived neurotrophic factor (BDNF) and pro-nerve growth factor (proNGF) are retrogradely transported to BFCNs from their synaptic targets. In AD, neurotrophin levels are increased within BFCN target areas and reduced in the basal forebrain, implicating dysfunctional neurotrophin transport in AD pathogenesis. However, neurotrophin transport within this highly susceptible neuronal population is currently poorly understood. We began by establishing protocols for the accurate quantification of axonal transport in BFCNs using microfluidic culture. We then determined the effect of age on neurotrophin transport. BFCNs were left in culture for up to 3 weeks to model aging in vitro. BFCNs initially displayed robust neurotrophin transport, which diminished with in vitro age. We observed that the levels of proNGF receptor tropomyosin-related kinase-A (TrkA) were reduced in aged neurons. Additionally, neurotrophin transport in BFCNs derived from 3xTg-AD mice, an AD model, was also impaired. Next, we sought to determine a mechanism for these transport deficits. First, we determined that proNGF transport was solely contingent upon the levels of TrkA. We then found that elevation of oxidative stress, an established AD contributor, significantly reduced both TrkA levels and proNGF retrograde transport. TrkA levels are partially regulated by protein tyrosine phosphatase-1B (PTP1B), an enzyme whose activity is reduced by oxidation. PTP1B antagonism significantly reduced TrkA levels and proNGF retrograde transport in BFCNs. Treatment of BFCNs with PTP1B-activating antioxidants rescued TrkA levels, proNGF transport, and proNGF-mediated axonal degeneration. Our results suggest that oxidative stress contributes to BFCN degeneration in aging and AD by impairing retrograde neurotrophin transport via oxidative PTP1B-mediated TrkA loss. / Thesis / Doctor of Philosophy (PhD) / During aging and Alzheimer’s disease (AD), the connections between neurons, a type of brain cell, break down, causing memory loss. This breakdown begins in a brain area called the basal forebrain. Basal forebrain neurons rely upon the transport of nutrients along their connections with other neurons, called axons, for proper function. This transport process becomes impaired in AD. Our goal was to understand why this happens. First, we determined that axonal transport was impaired with age and in basal forebrain neurons of mice genetically predisposed to develop AD. We recreated these impairments by increasing the levels of harmful molecules called reactive oxidative species (ROS). ROS levels increase with age and become abnormally high during AD. We found that increased ROS impair axonal transport and contribute to the breakdown of basal forebrain neurons. Our work suggests that reducing ROS will help prevent the breakdown of basal forebrain neurons in AD.

Basal forebrain

Neurotrophin

proNGF

BDNF

TrkA

TrkB

Axonal Transport

Retrograde Transport

Aging

Alzheimer's Disease

p75

Oxidative Stress

PTP1B

Rab proteins

Rab5

Rab7

3xTg-AD

Mechanisms of exosome biogenesis and secretion / Mécanismes de biogénèse et sécrétion des exosomes

Colombo, Marina

22 November 2012

Les exosomes sont des vésicules membranaires de 30 à 100 nm de diamètre, formées dans les endosomes multivésiculaires et sécrétées par la plupart des cellules. Les propriétés biophysiques et biochimiques des exosomes ainsi que les mécanismes permettant leur biogénèse et sécrétion ont fait l’objet de nombreuses études. Cependant, ces derniers sont encore méconnus, limitant l'analyse des fonctions des exosomes in vivo. Au moins deux mécanismes ont été proposés pour la biogénèse des exosomes : un mécanisme nécessiterait l’action de protéines impliquées dans le tri endosomal, les ESCRT (« endosomalsorting complex required for transport »). Un autre mécanisme serait indépendant de leur fonction. La sécrétion des exosomes, une fois générés dans les endosomes, requiert la petite GTPase, Rab27a, comme montré dans un modèle cellulaire humain. Mes travaux de thèse ont porté sur l’étude des mécanismes moléculaires impliqués dans la biogénèse et la sécrétion des exosomes. Une première étude visant à analyser la fonction de Rab27a dans des cellules murines, m’a permis de mettre en évidence l’existence de différentes populations d’exosomes, dont la sécrétion dépend ou non de Rab27a. Une deuxième étude a eu pour objectif d’analyser l’implication des ESCRT dans la biogénèse des exosomes dans des cellules HeLa CIITA. Le criblage d’une librairie d’ARN d’interférence dirigés contre les différentes protéines ESCRT, a permis l’identification de 7 molécules potentiellement impliquées dans cette voie : HRS, STAM1, TSG101, leur inactivation induisant la diminution de la sécrétion des exosomes. L’inactivation de CHMP4C, VPS4B,VTA1 et ALIX, au contraire, l’augmente. L’inhibition de l’expression de ces candidats suivie de l’analyse des exosomes sécrétés a démontré l’hétérogénéité des vésicules sécrétées, et une modification de leur taille et de leur composition protéique par rapport aux cellules contrôle. Plus particulièrement, l’inactivation d’ALIX induit une augmentation de lasécrétion d‘exosomes de plus grande taille, et l’enrichissement sélectif en molécules de CMH de classe II. En accord, j’ai montré que les cellules inactivées pour ALIX, aussi bien des cellules HeLa que des cellules dendritiques humaines ont une plus forte expression de CMH de classe II à la surface et dans des compartiments intracellulaires. Ces résultats suggèrent l’implication de certains membres de la famille ESCRT dans la voie de biogenèse et sécrétion des exosomes, ainsi qu’un rôle potentiel d’Alix dans le trafic des molécules CMH de classe II, et dans la modulation de la composition protéique des exosomes. / Exosomes are small membrane vesicles with sizes ranging from 30 to 100 nm in diameter, which are formed in multivesicular endosomes and secreted by most cell types. Numerous studies have focused on the biophysical and biochemical properties of exosomes, as well as the mechanisms of biogenesis and secretion of these vesicles. However, these aspects are not fully understood, which limits the analysis of the functions of exosomes in vivo. At least two mechanisms have been proposed for the biogenesis of exosomes : one would rely on the function of proteins involved in endosomal sorting, the ESCRT family (for “endosomal sorting complex required for transport”). Another mechanism would be independent of their activity. Once exosomes are formed in endosomes, their secretion requires the small GTPase RAB27A, as shown in a human cell line. The objective of my PhD project was to gain insights into the molecular mechanisms that drive exosome biogenesis and secretion. A first study performed to analyze the function of Rab27a in murine cells allowed me to show the existence of different populations of exosomes, dependent or not on Rab27a for their secretion. A second study was aimed at analyzing the involvement of ESCRT proteins in exosome biogenesis in HeLa-CIITA cells. Seven molecules potentially involved in this process were identified on the basis of the screening of an RNA interference library directed against the different ESCRT proteins: the inactivation of HRS, STAM1 and TSG101 induced a decrease in exosome secretion, whereas the down regulation of CHMP4C, VPS4B, VTA1 and ALIX increased it. Gene expression of the different candidate proteins was inhibited and exosomes secreted by these cells were analyzed: we showed the heterogeneity of the secreted vesicles, as well as an alteration of their size and protein composition, as compared to control cells. In particular, the inactivation of ALIX induced an increase in the secretion of larger vesicles, and the selective enrichment of these vesicles in MHC class II molecules. Accordingly, I showed that both HeLa-CIITA and human primary dendritic cells inactivated for ALIX possess a higher expression of MHC class II molecules at the cell surface and in intracellular compartments. These results suggest that some members of the ESCRT family are involved in the exosome biogenesis and secretion pathway, and propose a potential role of ALIX in the trafficking of MHC class II molecules and in the modulation of the protein composition of exosomes.

Exosomes

Biogénèse

Sécrétion

Vésicules sécrétées

Protéines ESCRT

Protéines SNARE

Protéines RAB

Endosomes multivésiculaires

ALIX

CMH de classe II

Rab27a

Exosomes

Biogenesis

Secretion

Secreted vesicles

ESCRT proteins

SNARE proteins

RAB proteins

Multivesicular endosomes

ALIX

MHC class II

Rab27a